Handbook on Coal, Coke, Cotton, Lignin, Hemicellulose, Wood, Wood-Polymer Composites, Lignocellulosic-Plastic Composites from Recycled Materials, Wood Fiber, Rosin and Rosin Derivatives
(Also Known as Handbook on Coal, Lignin, Wood and Rosin Processing)
Coal is the product of plants, mainly trees that died tens or hundreds of millions of years ago. Coal is a fossil fuel and is the altered remains of prehistoric vegetation that originally accumulated in swamps and peat bogs. The energy we get from coal today comes from the energy that plants absorbed from the sun millions of years ago. Coal is used primarily as an energy source, either for heat or electricity. It was once heavily used to heat homes and power locomotives and factories. Bituminous coal is also used to produce coke for making steel and other industrial process heating. Lignin is a constituent of the cell walls of almost all dry land plant cell walls. It is the second most abundant natural polymer in the world, surpassed only by cellulose. Lignin is found in all vascular plants, mostly between the cells, but also within the cells, and in the cell walls.
Wood is an aggregate of cells essentially cellulose in composition, which are cemented together by a substance called lignin. The cells are made of three substances called cellulose (about 50 percent), lignin (which makes up a fifth to a quarter of hardwoods but a quarter to a third of softwoods), and hemicellulose. Rosin refers to an extraction process that utilizes a combination of heat and pressure to nearly instantaneously squeeze resinous sap from your initial starting material
In India's energy sector, coal accounts for the majority of primary commercial energy supply. With the economy poised to grow at the rate of 8-10% per annum, energy requirements will also rise at a reasonable level. The Indian coal industry aspires to reach the 1.5 billion tonne (BT) mark by FY 2020. In fore-coming years, the industry will naturally need to focus on building on the success, and be on track for reaching the FY 2020 goal. One of the primary goals of the Government of India is to ensure that it is able to meet the country's power generation needs. Another aim is to lower the country's reliance on coal imports by boosting the coal production quickly.
The Major contents of the book are Coal, Analysis of Coal and Coke, Cotton, Lignin and Hemicelluloses, Degradation of Wood, CCA-Treated Wood, Wood-Polymer Composites, Lignocellulosic-Plastic Composites from Recycled Materials, Chemical Modification of Wood Fiber, Delignification of Wood with Pernitric Acid, Rosin and Rosin Derivatives, Polymerizable Half Esters of Rosin and Photographs of Plant & Machinery with Supplier’s Contact Details.
It will be a standard reference book for professionals, entrepreneurs, those studying and researching in this important area and others interested in the field of these industries.
Handbook on Coal, Coke, Cotton, Lignin, Hemicellulose, Wood, Wood-Polymer Composites, Lignocellulosic-Plastic Composites from Recycled Materials, Wood Fiber, Rosin and Rosin Derivatives
Author: Dr. Himadri Panda
Published: 2015
Format: paperback
ISBN: 9789381039861
Code: NI312
Pages: 512
$ 50.67
1875
Publisher: NIIR PROJECT CONSULTANCY SERVICES
Usually ships within 5 days
Contents
Chapter 1
Coal
Ethylene
Fischer –Tropsch Synthesis for Olefins
Direct Conversion of Synthesis Gas to Ethylene
Ethanol from Synthesis Gas
Olefins from Methanol
Methanol Homologation
Methanol to Acetic Acid
Ethylene Glycol
Acetic Anhydride
Vinyl Acetate
Other Chemicals
Coal Pyrolysis Processes
Acetylene
Production of Chemicals by
Coal Liquefaction Processes
Conclusion
Chapter 2
Analysis of Coal and Coke
Methods of Analysis
Sampling
Determination of Constitution and Physical Properties
Functional Group Analysis
Spectroscopy
Determination of Optical Constants
Electron Microscopy
Density
X-Ray Diffraction
Specification Tests
Proximate Analysis
Ultimate Analysis
Calorific Value
Fusibility of Coal Ash
Behaviour on Healing
Equilibrium Moisture of Coal at 96-97%
Relative Humidity and 39oC
Determination of Harcbgrobve Grindability
Index of Coal
Special Constituents
Coal Classification
Chapter 3
Cotton
Methods of Analysis
Modified Cottons
Finishing Agents
Separation and Identification
Spectroscopic Methods
Inorganic Constituents
Chemical Methods
Spectroscopic Methods
Chapter 4
Lignin and Hemicellulose
Hemicellulose
Assay systems
Classification
Thermophilic Hemicellulases
Alkaline active xylanases
ß - Xylosidase
Mannanases and galactanses
Accessory enzymes for Hemicellulose utilization
Lignin
Lignin-degrading enzymes
Lignin degradation in whole cell cultures
Degradation by cell-free enzyme systems
Role of glycosides in Lignin degradation
Lignin-carbohydrate complexes
Fractionation of Lignin and Carbohydrate in wood
Isolation of LCCs
Chemical characteristics of LC bonds
Ferulic and p-coimaric ester side chains
Frequency and stability of LC bonds
Residual lignin in kraft pulp
Biodegradation of LCCs
Residual LC structures after exhaustiveenzymatic digestion
Solubitization of LCC by microbial activity
Enzymatic treatments of pulps
Conclusion
Chapter 5
Degradation of Wood
Introduction
Gross Chemical Composition
Distribution of Wall Components
Component Chemistries
Microstructure and Porosity
Degradation of whole wood
Biodegradation of Lignin
Biodegradation of Cellulose
Biodegradation of Hemicellulose
Applications
Conclusion
Chapter 6
Cca-Treated Wood
Introduction
Materials and methods
Results and Discussion
Conclusion
Chapter 7
Wood-Polymer Composites
Introduction
Materials and Methods
Monomers
Wood specimens
Treatment of specimens with monomers
Volumetric swelling and moisture content
Result
Swelling of wood soaked in monomers
Polymer loading
Volumetric swelling of WPC specimens
Moisture content of WPC specimens
Conclusions
Chapter 8
Lignocellulosic-Plastic Composites from Recycled
Materials
Municipal Solid Waste as a Source of Lignocellulosic Fibre and Plastics
Thermoformable composites as Outlets for Waste Paper, Wood and Plastics
Recent Research on Wood Fiber-Thermoplastic Composites
Research and Development Needs
Concluding Remarks
Chapter 9
Chemical Modification of Wood Fiber
Introduction
Experimental Procedure
Esterification Procedure
Analyses of Esterification Products
Board Formation
Board Testing
Moisture sorption
Rate and extent of swelling
Results and Discussion
Esterification of Wood Fiber
Moisture Sorption of Esterified Fiberboards
Rate and Extent of Swelling of Fiberboards in Liquid Water
Plasticization of Esterified Fibers
Conclusions
Chapter 10
Delignification of Wood with Pernitric Acid
Generation of pernitric acid
Decomposition of pernitric acid
Delignification of aspen wood
Conclusions
Experimental
Chapter 11
Rosin and Rosin Derivatives
Composition
Reaction and derivatives
Isomerization
Maleation
Oxidation
Photosensitized oxidation
Hydrogenation
Hydrogenless Hydrogenation
Polymers of vinylesters of hydrogenated rosin
Prehydrogenation
Hydrocracking of Rosin
Dehydrogenation
Polymerisation
Analysis
Compatibility
Solubility
Instrumental analysis
Gas chromatography analysis
Infrared Spectroscope
Nuclear magnetic resonance
Ultraviolet spectroscopy
X-Ray Analysis
Mass Spectroscopy
Phenolic modification
Salt formation
With metals
With unsaturated cyclic and acyclic hydrocarbons
Example-2
Rosin-isoprene condensate (Example-3)
Rosin-isobutene condensate (Example-4)
Example –5
Rosin-styrene condensalt (Example-6)
Rosin-cyclopentadiene condensate (Example-7)
Rosin-coumarone-indene condensate (Example-8)
Rosin-divynylbenzene condensate (Example-9)
Example-10
Esterification
With Glycerol
With pentaerythritol and other polyhydric alcohols
With monoydric alcohols
Hydrogenolysis
Polyesterification
Copolyesters
Ammonolysis
Preparations
Dehydroabietylamine acetate
Dehydroabietylamine
Typical Uses
Asphalt additives
Chemical Intermediates
Corrosion Inhibitors
Flotation Reagents
Preservatives
Resolving agent
Chemical and physical properties of
Amine D acetate
Stability to heat and storage
Stability to heat and storage
Surface Activity
Chemical Reactivity
Chemical and Physical Properties of
Amine D acetate
Solubility
Note
Stability to Heat and Storage
Stability to Air and Sunlight
Surface Activity
Styrenation
Decarbxylation
Hydroxymethylation and hydroxylation
Methods of preparations
Nitrogenous intermediates
Methyl levopimarate (i)
Methyl neoabietate (ii)
Methyl photolevopimarate (iii)
Reaction of SSI with Methyl levomarate (i)
Reaction of Chlorosulphonyl isocyanate with methyl neoabietate (ii)
Reaction of Chlorosulphonyl isocyanate with methyl photolevopimarate (iii)
Fumaroniprile Adduct of levopimaric acid
Tetracyanoethylene Adduct of levopimaric acid
Acrylonitrile adducts of levopimaric acid
Polyoxyalkylation
Chapter 12
The Polymerizable Half Esters of Rosin
Expermental
Preparation and properties of monomers
Maleic rosin esters with reactive groups
Polymerization & Copolymerization
Aqueous Polymerization
Suspension Polymerization
Secondary reactions and graft copolymers
Reaction Involving Crosslinking
Applications
Coatings
Inks
Textiles
Conclusions
Chapter 13
Photographs of Plant & Machinery with Supplier’s
Contact Details
Sample Chapters
Coal
Coal carbonization byproducts (coal tar and coke-oven gas) were the
main sources for the production of organic chemicals till the Second
World War. However, the abundant availability of cheap petroleum and
natural gas caused a major shift from coal to these raw materials.
After the Second World War, there was a consistent increase in the
consumption of petrochemicals. In the last 10 years, with the
continuing rise in oil prices, and scarcity and uncertainty regarding
assured supplies of natural gas and petroleum oils, attention towards
achieving self-sufficiency in chemicals and production of fuels has
been focussed on exploring alternative feedstocks like coal and
biomass. In this context, there is a need for reassessing the
possibilities of obtaining organic chemicals from coal. It is
anticipated that it will be cheaper to make liquid and gaseous fuels
from coal than from oil before the end of this century.
The use of coal as a source of chemicals is at present confined mainly
to high temperature carbonization (HTC) through the recovery of by
products. A part from the traditional coking route, concerted efforts
are being made to obtain various chemicals by other coal conversion
processes, such as direct hydrogenation or solvent extraction of coal
followed by cracking, hydrotreating or hydrocracking of the products
and by synthesis of hydrocarbons via synthesis gas produced by coal
gasification.
Ethylene
Ethylene is an important basic building block of the petrochemical
industry. The production and recovery of large quantities of olefins
from petroleum refinery off-gases first started with the advent of
catalytic cracking. Rapid growth in the demand for petrochemicals
necessitated the setting up of plants to produce ethylene and other
olefin monomers by thermal cracking of a wide range of petroleum
feedstocks.
The routes considered for the production of ethylene from coal include:
(i) Fischer-Tropsch synthesis, (ii) direct conversion of synthesis gas,
(iii) conversion of coal-derived methanol, (iv) homologation of
methanol to ethanol followed by dehydration, (v) cracking of dimethyl
ether which again is derived from synthesis gas or methanol, and (vi)
cracking of synthetic liquids produced in direct liquefaction
processes.
Fischer – Tropsch Synthesis for Olefins
Fischer – Tropsch (FT) synthesis for the production of fuels from coal
has been in operation on a commercial scale since 1955 in Sasolburg,
South Africa. It is known that through proper choice of reactor,
catalyst and operating conditions, the product pattern can be changed
in FT synthesis. The dilute fluid bed or Kellogg type of reactor
(Synthol) shifts the product spectrum to lower hydrocarbons. It gives
an ethylene yield of 4.4% and also C3 and C4 olefins. Ethane produced
in the process can also be converted to ethylene. The cost of ethylene
from the recovery process is about 30 cents/lb compared to 18-19
cents/lb from the conventional gas oil cracking. In the steam cracking
of FT product, the cost of ethylene is estimated at 30 - 50cents/lb. In
the Sasol 2 plant in South Africa, the annual production of 1.5 million
tones of automotive fuels, 1,60,000 tonnes of ethylene and 50,000
tonnes of chemicals, 1,00,000 tonnes of ammonia, 90,000 tonnes of
sulphur and 2,00,000 tonnes of tar products, including tar acids, is
envisaged.
Direct Conversion of Synthesis Gas to Ethylene
Direct conversion of synthesis gas from coal to ethylene and ethanol is
now attracting attention. Efforts to get ethylene by passing synthesis
gas (CO: H2 ratio, 74:24:8) in a copper tube at 550ºC resulted in 5.6%
ethylene in the product gas, whereas when synthesis gas containing 0.6%
ethylene was passed over a CuO (3%) – Al2O3 catalyst at 250ºC and 20 –
40 atm pressure, the ethylene content increased to 7.6%. On the other
hand, Peters used a four-component catalyst system to convert synthesis
gas (46.4% CO, 42.5% H2 and 11.1% inert) to ethylene. Several iron and
cobalt-based FT catalysts have been evaluated for the conversion of
synthesis gas to C2 – C4 olefins. As the copper and the alkali contents
were increased in iron-copper-kieselguhr-K2O catalysts, the product
distribution shifted towards lower molecular weight hydrocarbons.
The activity and selectivity of Ni- or Co-based bimetallic catalysts
containing several other metals as promoters have been evaluated. The
bimetallic catalysts give a somewhat different product distribution
compared to Ni or Co catalysts. The addition of Re to Ni favours the
formation of ethane (22% at 185ºC), that of Ru favours the long chain
hydrocarbons, while addition of lr favours the formation of dimethyl
ether at 210ºC (40% at 190ºC). Co - Mn gives products containing a
higher proportion of olefins which is higher at lower temperatures and
lower H2 - CO ratios.
The favourable olefin selectivity obtained on the addition of basic
promoters to the conventional iron catalysts suggests that metal
interactions with basic or electron-donor sites in zeolites may have an
important influence on selectivity. A marked increase in the olefin
selectivity of ruthenium is observed as sodium ions in the zeolite are
replaced by potassium or caesium ions.
The work done at Pittsburgh Energy Research Center indicated that a
fused iron catalyst is particularly effective in giving high yields of
olefins. Experiments were conducted in a microreactor with temperature
range 250 - 350ºC, pressure range 20 - 68 atm, synthesis gas having
composition of 1:1, 2:1 and 3:1 of H2: CO and also mixtures containing
CO2 and hourly space velocities of 500-5000.
Ethanol from Synthesis Gas
Synthesis gas has been converted to ethanol at 250-290ºC, 50 atm and a
space velocity of 1000-4000 hr-1 in a bench scale unit using a special
rhodium cluster catalyst. The conversion of CO was 10% and the reaction
product contained 75-80% ethanol. The activity of the catalyst during
one month period of operation (8 hr-a-day) remained almost constant.
Work done at the Union Carbide Corporation showed that addition of Fe
to Rh increased the yield of ethanol at 68 atm. On the other hand,
large proportions of ethane and dimethyl ether were obtained with
alumina-supported platinum.
Olefins from Methanol
Conversion of coal-based methanol to ethylene and propylene offers an
attractive route to the use of coal as a basic raw material. The
formation of C2 - C5 olefins (1.6 mole%) was noticed by Mattox during
methanol dehydration over NaX zeolites. Similar results have been
reported by several investigators using various catalysts. The product
distribution suggests that an a-elimination process (H-CH2-OH !®H2O +
CH2) is occurring in the methanol adsorbed on the zeolite surface. The
carbene methylene species so formed can polymerize to form simple low
molecular weight olefins.
Methanol cannot dehydrate to form an olefin unless recombination of
one-carbon fragments takes place. Aromatics are produced by
dimerization and cyclization of C3, C4 and C5 olefins.
Laboratory scale experiments were conducted using tungstic acid
impregnated on zeolites, MgO or Al2O3. Zeolites exchanged with rare
earths gave higher yields ranging from 16 to 30% ethylene and 29 to 30%
propylene with methanol conversion of 80 – 90%. Dimethyl ether formed
in the process can also be converted to olefins using the same
catalyst. The reaction mechanism involves three consecutive surface
reactions. Adsorbed methanol is dehydrogenated to formaldehyde followed
by dimerization of formaldehyde and dehydration of the dimer to give
adsorbed ethylene.
The possibilities of producing ethylene and propylene from coal-based
methanol on a laboratory scale have been explored by BASF. In 1979,
BASF constructed a pilot plant with 15 tonnes per month capacity at a
cost of $ 1.5-1.6 million at Ludwigshafen, West Germany to produce
olefins from methanol. In this process, 3-4 lb of methanol is
catalytically converted (catalyst, ZSM-5 zeolite) to give 1 lb of
olefins. Methanol is first converted to dimethyl ether, which, in turn,
gives ethylene by dehydration. Propylene and C4 olefins are also
produced in varying amounts, depending on the reaction conditions.
Methanol Homologation
The best potential approach to the production of ethylene from
synthesis gas appears to be through its reaction with methanol to form
ethanol and subsequent dehydration of ethanol to ethylene. Wender
showed that methanol reacts with synthesis gas in the presence of
dicobalt octacarbonyl [CO2(CO)8] catalyst to give ethanol, but higher
alcohols, including ethanol, are relatively unreactive in this system.
The reaction was carried out in batch autoclaves at 183 – 185oC and 275
atm at 75% conversion to give about 40% of ethanol in the product.
About 4% propanol was formed together with 0.3% butanols.
The methanol homologation reaction as catalysed by Co2(CO)8 is a very
complex one, highly dependent on a variety of reaction parameters and
variables. The initial carbonylation product, acetaldehyde, is obtained
in high selectivity by proper ligand modification. A selectivity of
62.3% was obtained at 200oC and 270 atm for 3 hr process time using a
cobalt-iodine catalyst. High iodine/cobalt ratios lead to undesirable
reaction by products and catalyst deactivation. The active form of Co
in the iodine – promoted system is Co(CO)4–, as indicated by high
pressure IR spectroscopy.
Methanol to Acetic Acid
Liquid phase carbonylation of methanol has become an important
industrial process which uses iodide or carbonyl of cobalt as a
catalyst and an organic or inorganic iodide, such as methyl iodide,
hydrogen iodide or potassium iodide, as promoter.
Nickel carbonyl and some other nickel compounds are also effective at
low pressures of about 50 atm in the presence of iodide in the liquid
reaction media of some organic amines of phosphines.
In the process developed by Monsanto, a new iodide-promoted rhodium
catalyst which exhibits high activity for methanol carbonylation even
at atmospheric pressure is used. The yield of acetic acid is 99% based
on methanol and 90% based on carbon monoxide. A plant with a current
annual capacity of 143 million kilograms is now operating. About 40% of
the world’s capacity for acetic acid is based on Monsanto process.
Ethylene Glycol
The most promising route to ethylene glycol involves direct conversion
of synthesis gas using rhodium catalyst.
High yields of ethylene glycol were reported. The reaction takes place
at about 2000C and 1400 - 3000 atm over a rhodium carbonyl catalyst,
but comparatively lower pressures of the order of 400 atm may be
sufficient to achieve a reasonable degree of conversion. Such a low
pressure process using a more specific catalyst promises to be a
commercial success. In the work carried out by Union Carbide, a solvent
having a high dielectric constant to ensure ion separation and/or
complex the cations to prevent pairing with a anionic centers has been
used.
Vinyl Acetate
Halcon International has nearly completed the development of a methanol
carbonylation route to vinyl acetate. In this process, methanol is
reacted with recycled acetic acid to make methyl acetate; the methyl
acetate is reacted with synthesis gas to produce ethylidene diacetate,
which is subjected to cracking to produce vinyl acetate and acetic acid
for recycle.
Other Chemicals
Monsanto reported a method for the alkylation of toluene with methanol
over modified zeolite catalyst to produce a mixture of ethylbenzene and
styrene. At present, the product concentrations are very low (5 mol% of
styrene and ethylbenzene) and frequent catalyst regeneration is
necessary. Both BASF and Rohm and Haas have been investigating the base
catalysed addition of formaldehyde (as acetal) to methyl propionate to
form methyl methacrylate.
Coal Pyrolysis Processes
Coal tar is an inevitable byproduct in the production of metallurgical
coke. Important chemicals, such as benzene, toulene and xylenes (BTX),
can be produced from the benzole recovered from coke oven gas as well
as from the light oil obtained by the distillation of coal tar. The
other main constituents of high temperature coal tar are naphthalene
(10%), anthracene (1.8%), phenanthrene (5.0%), fluorine (2.0%),
fluoranthene (3.3%), phenol (0.4%) and pyridine (0.02%). Bulk products,
such as creosotes and pitches, are also produced from coal tar.
With the exception of limited quantities produced in USA through
dealkylation of aromatic petroleum fractions, naphthalene is almost
exclusively obtained from coal tar. Methyl naphthalene and dimethyl
naphthalenes are present in the heavier coal tar fractions (250 –
3500C). The dealkylation of these methyl naphthalenes can yield further
quantities of naphthalene.
The Coalite and Chemicals Products Ltd, UK, are processing the tar from
LTC into valuable chemicals (pure phenols, chlorinated phenols) and
chemical intermediates for plasticizers, pharmaceuticals and adhesives.
A phenol-free middle oil fraction was processed into diesel oil till
1965.
The pyrolysis of tars or vapours from LTC of coal is considered as a
possible route for producing olefins. Laboratory scale investigations
were conducted on cracking of vapour and tars obtained by LTC of Texas
and North Dakota lignites. When Texas lignite was carbonized at 5500C
and the tar vapours were cracked at 8000C, the yields of ethylene,
propylene and benzene were 40, 7.6 and 6 lb respectively per tonne of
lignite. However, the process was not considered economically viable.
LTC of cannel coals from West Virginia in the presence of superheated
steam followed by cracking of the vapours at 800 – 9000C gave 191-245
lb of ethylene, 20-41 lb of propylene and 21-47 lb of benzene per tonne
of coal (MAF).
Acetylene
Acetylene is an important chemical intermediate for the production of
acetaldehyde, vinyl acetate, vinyl chloride, acrylonitrile, etc. It is
generally obtained by high temperature pyrolysis of natural gas or
naphtha fractions in addition to the conventional calcium carbide
route. A process to make acetylene by pyrolysing coal in an electric
arc has been developed by Avco Everett Research Laboratory, Everett,
Mass. In this process, pulverized coal is injected into a stabilized
arc, the pyrolysis products are quenched and acetylene is separated
from the product. Pyrolysis is conducted in hydrogen atmosphere, which
increases the yield of acetylene. The process has been tested in a unit
that operates at 75-100 kW producing 0.15-0.20 lb/min of acetylene. A
pilot plant to process 10 tonnes/day of coal that would yield 3-3.35
tonnes/day of acetylene has been proposed.
Production of Chemicals by Coal Liquefaction Processes
Several investigations have been made to study the possibilities of
producing chemicals from coal liquefaction products. Dow Chemical
Company studied the feasibility of producing chemical feedstocks from
coal-derived liquids from COED, Synthoil, H-Coal and Solvent Refined
Coal (SRC) processes.
In the Exxon Donor Solvent (EDS) process, which provides a technically
feasible route to the production of liquid products from various types
of coal, the byproducts form a potential source of petrochemical
feedstock. The major source of ethylene and propylene is derived by
cracking the light gas product blend containing ethane, propane and
mixed butanes.
Analysis of Coal and Coke
Coal is a readily combustible rock containing more than 50% by weight
and more than 70% by volume of carbonaceous material, formed from
compaction or induration of variously altered plant remains similar to
those of peaty deposits. Differences in the kinds of plant materials
(type), in degree of metamorphosis (rank), and range in impurity
(grade) are characteristic of the varieties of coal. In lump form, coal
appears to be black or brownish black. The luster, fracture, and
texture vary according to type, rank, and grade. Chemically, coal
consists mainly of carbon, hydrogen, and oxygen, with minor amounts of
nitrogen, sulfur, silica, alumina, iron, and trace amounts of
fifty-three other elements. The composition varies to such an extent
that Hendricks states that no two coals are absolutely the same. Some
of the elements are inherent in the original plants; others have been
incorporated during the coalification process; and others have been
picked up as extraneous matter in mining, preparation, and
transportation.
That types, ranks, and grades of coal are dependent on the
characteristics of the original plants and the chemical, biological,
and physical processes involved in metamorphosis. Variations in the
combination of processes and the materials processed produce end
products varying in chemical and physical properties. Analytical
techniques that will consistently show numerical differences between
these products provide data with which the types, ranks, and grades can
be determined.
Each of the principal coal producing countries in the world has a
series of procedures or national standards. The Technical Committee 27
on Solid Mineral Fuels of the International Standards Organisation
(ISO) consists of representatives of Australia, Austria, Belgium,
Canada, Denmark, Spain, France, Germany, India, Italy, Netherlands,
Poland, Romania, Switzerland, Czechoslovakia, Turkey, United Arab
Republic, United Kingdom, United States, Soviet Union, and Yugoslavia
collaborating on the international standardization for coal and coke.
Even though the coke was produced and used by metallurgical plants, the
specifications were maintained by chemical and physical tests.
Uniformity is very essential in the various Processes.
Methods of Analysis
In this section, the methods for coal are discussed in detail. Testing
methods for coke are the same as for coal except the procedures for
stability, porosity, and density. More detailed information on the
testing methods can be found in the publications of the U.S. Bureau of
Mines, British Standards Institution, and the American Society for
Testing and Materials.
Sampling
Preliminary to any chemical or physical testing of coal in the
laboratory it is essential that a representative sample be provided.
The most carefully conducted analysis is meaningless unless the sample
be truly representative of the lot. This means that increments are
specified in number, weight, frequency, and method of extraction. The
properly collected gross sample must be reduced in particale size and
mass to laboratory size by a method that retains the representativeness
without gain or loss of such fleeting substances as moisture.
Determination of Constitution and Physical Properties
Knowledge of the constitution and physical properties of coal is of
great value in combustion, carbonization, gasification, and in the
utilization of coal in making nonsolid fuels and in chemical syntheses.
A number of techniques have been developed and other are in development
status to provide this vital information.
Functional Group Analysis
Essentially all of the functional groups recognized as being present in
coal are associated with oxygen. Both the nitrogen and organic sulfur
are considered to be present primarily as parts of heterocyclic systems
since there is no satisfactory evidence for any functional groups
containing either element.
Carboxyl groups, both free and as salts, are present in lignites and
brown coals and may represent as much as 14wt % of the dry lignite.
Determination of free carboxyl group generally has been carried out by
ion exchange between coal and barium or calcium acetate, followed by
titration of the liberated acetic acid. Methoxyl groups also are
present only in low-rank coals. Zeisel determination of methoxyl
contents of lignites and brown coals indicates a maximum of 2% for
lowest-rank coals. The number of carbonyl groups also decreases with
increating rank, although no satisfctory procedures have been developed
for quantitative determination of this functionalgroup in coal. Some
oxygen is also presentin heterocyclic rings.
Acetynlation. Several different acetylation procedures have been used
on coal. The one which is most widely used utilizes acetic anhydride in
pyridine
Procedure
Add a weighed sample (500-800mg) of dried coal to 10 ml of a 1:2
mixture of acetic anhydride and pyridine in a 200-ml flask. Reflux the
mixture for 24 hr, cool, and dilute with 100 ml of water. Filter the
mixture and wash the residue until free of acid Boil the acetylated
coal for 5hr in a 150-ml flask with 2 g of barium hydroxide in 40 ml of
water and keep on a steamplate overnight. Add 2 ml of 85% phosphoric
acid, and distill 24 ml into a titration flask. Titrate the acetic acid
in the distillate with sodium hydroxide. Add increments of water to the
residue and distill into the titration flask until no more acid is
observed upon titration.
Trimethylsilylation. A second method for determining the hydroxyl
content of coal involves treatment of the coal with
hexamethyldisilazane, and trimrthylchlorosilane in pyridine. This
results in the conversion of the hydroxyl groups to trimethylsilyl
ethers. Silicon analysis of the resultant coal ethers affords a
quantitative value from which the hydroxyl content can be calculated.
Alternatively, the trimethylsilyl ether content can be estimated from
the extinction coefficient of the trimethylsilyl group measured at
8.0µm.
Spectroscopy
Various spectral techniques are now applied to the study of coal. The
methods discussed here include infrared, ultraviolet and visible
absorption, mass, nuclear magnetic resonance, and electreon
paramagnetic resonance spectroscopy. A good general reference is that
of Silverstein and Bassler. Although considerable coal research work is
done by spectral methods there are as yet not many analytical
applications of spectroscopy in the coal industry.
Infrared Spectroscopy. Infrared spectroscopy is the most universally
applicable spectral method. With the exception of monatomic gases, all
substances have infrared spectra. Historically, infrared has been
applied principally to organic materials, but it is being used
increasingly on inorganic substances. Of all spectral methods infrared
has most earned the right to the title of “fingerprint method”.
Ultraviolet and Visible Absorption Spectroscopy. The principal use of
ultraviolet and visible spectroscopy is the study of aromatic compounds
particularly polynuclear condensed aromatic compounds. Because of the
prolific and characteristic spectral fine structure that results from
the electronic excitation of polynuclear condensed aromatics,
ultraviolet and visible spectroscopy is the best spectral method for
establishing identification of these compounds. Similar aromatic
compounds have radically different characteristic spectra- for
example, anthracene and phenanthrene, chrysene and benz-phenanthrene,
pyrene and fluoranthene. Also the derivatives of the parent compounds
display.
Mass Spectroscopy. Since the first mass spectral studies of coal a
considerable amount of work has been done, principally at the
Pittsburgh Energy Research Center of the U.S. Bureau of Mines. Mass
spectra of pyridine extracts of bituminous coal have shown the presence
of thirteen types of aromatic compounds having molecular weights from
78 to 400.
Research investigations of various oils and pitches from coal tar have
been carried out. Many aromatic hydrocarbon types were identified along
with several nitrogen and a few oxygen compounds. Also, average
molecular weights, aromaticities, and mean size of aromatic nuclei of
these samples were calcutated from the mass spectra of oils and
pitches.
Nuclear Magnetic and Electron Paramagnetic Resonance Spectroscopy. The
application of NMR or EPR in the coal utilization industries is
limited. One development appears to be approaching the application
stage; the analysis of water in coal is being carried out on moving
conveyor belts. Belt speeds are low and throughput is small as yet but
the method has promise.
Free radicals exist in coals in relatively large amounts and are easily
detected by EPR. Unfortunately, no fine structure has been detected in
coal spectra it is therefore difficult to characterize structures.
However, considerable characterizing information is obtainable from
free radical concentrations, line widths, and spectral g-values.
Peltrographic Analysis
Coal petrography deals with descriptions of different physical parts of
coals that can be distinguished best by microscopic observation. These
small parts of coals look different because they are of different size
and shape and they modify in different ways the light that they reflect
or transmit to the eyes. Coal petrography relates these different parts
to the plants or plant parts from which they were derived and deduces
something about the changes that have occurred from plant to coal.
Another physical component of coals that may observed microscopically
is inorganic mineral matter. These mineral constituents may have been
present in the original plants, may have deposited as the peat beds
formed, or crystallized from waters percolating through the coal bed.
The principal ones are quartz, kaolinite, calcite, and pyrite. Traces
of many mineral elements are present.
Some attempts have been made to separate or concentrate different coal
components on a commercial basis to take advantage of properties
favorable to various uses. These usually depend upon differences in
resistance to breakage or differences in density.
Thin-Section Analysis. Petrographic thin– section analysis is usually
made on specimens obtained from column samples cut out of a coal bed
from top to bottom. The specimens are small blocks measuring
approximately 1× 0.8× 0.5 in. The 0.8- in. dimension is in the vertical
direction of the column or bed, so that the total of the 1×
0.8-in./faces represents a ribbon area over the entire height of the
bed, excluding the material lost in cutting between the blocks.
Microscope analysis of thin coal sections is conducted with a
biological microscope equipped with binocular eyepieces. A pair of 15×
eyepieces is used with 16 and 32 mm objectives to attain magnifications
of 60× and 150×. Anthraxylon is measured at 150× and opaque attritus,
fusain, and mineral at 60×. Translucent attritus is determined by
difference. Measurements are made by means of a Whipple micrometer disc
inserted in one of the eyepieces. This a glass disc on which is
centered a 7 mm square field divided into one hundred 0.7 mm squares
with the central one subdivided into twenty-five 0.14 mm squares. The
effective sizes of these squares under different magnification
conditions are determined by comparison with a stage micrometer.
A detailed study of the errors involved in this type of thin-section
analysis showed that the percentages of components in a column sample
of a coal bed as determined by this technique usually should not be in
error by more than 2%.
Figure l illustrates the results of thin-section analysis on a complete
vertical column of a coal bed.
polished surface analysis. Petrographic polished surface analysis is
usually made on briquets of granular coal molded with a binder. The
granular sample, usually of –20 mesh size, is representative of much
larger lots of broken coal.
A variety of grinding and polishing steps may be used. A detailed
grinding plan would include the use of 240, 400, and 600 grit papers in
succession. Similarly, a careful polishing procedure might involve
successive use of 3 mm alumina on chemotextile cloth, 1mm on
chemotextile, and 0.05 mm on two or three layers of cloth, the top
being silk or cotton. Some of these steps may be omitted, depending on
experience or the desired quality of the polish. After polshing most
coal briquets should be dried in a desiccator for a period of about 15
hr. More details or variations in specimen preparation procedures can
be found in References 54 and 55.
Reflectance Measurement. This measurement is important in petrographic
analysis and permits the determination of optical constants. Various
assemblages of equipment have been used for this purpose. A brief
description of one of these will serve to illustrate the general
principles of the measurement.
It has been found that, for accurate reflectance measurements, the
polised specimen surface must be precisely perpendicular to the optic
axis of the microscope. A commonly used hand-leveling press cannot be
relied on to attain this positioning. A reliable method involves
observation of focus preservation with an objective of at least a 60 ×
magnification as the specimen surface is traversed over about 1 in. in
two perpendicular directions. Mounting the specimen on a device capable
of controlled tilt in two directions permits adjustment of the surface
plane until the specimen remains in focus through all possible
displacements.
In this method, absolute reflectance is obtained by reference to a
standard of known refractive index and negligible absorption. The
reference to a standard of should be in the range of those of coal
components. Some investigators have used a series of glasses of
different reflectances in this range, although some surface changes by
oxidation have been encountered. Synthetic ruby and particularly
sapphire have proven satisfactory. The standard should be cut in a form
so that reflectance from the back face is not allowed to interfere with
the measurement. Measurements on several minerals of known refractive
index, in different media, provide an excellent means of checking the
accuracy of the method. If the indices calculated from the reflectance
measurements agree within an acceptable limit with the indices provided
by other means, the operation of the equipment is satisfactory.
Determination of Vol % of Macerals. Macerals commonly determined are
vitrinite, exinite, resinite, micrinite, semifusinite, and fusinite.
The equipment used is essentially that described for reflectance
measurement with the addition of devices for scanning the speciment and
for selection of areas to be identified and summed. The additional
devices are a Whipple ocular disc or a crosshair disc, a mechanical
stage, and a counter. The stage maybe operated manually or
electrically. In the latter case it maybe coupled to an electrically
actuated counter. The mechanical stage stage should be of such type
that the specimen can be advanced quickly by definite fixed increments
in two perpendicular directions. If an electrically operted stage is
used, increment steps in one direction across the specimen may be
actuated by the counter switches. The counter should be capable of
totalizing counts in at least six channels.
The specimens for automatic scanning microscopy are prepared in a way
very similar to those previously described for visual studies in
reflected light. However, because there is no element of human judgment
involved, the surfaces should be more carefully polished to attain the
least possible relief, pits, and scratches. This objective may require
modifications to the grinding and polishing steps, depending, for one
factor, on the relative importance of the results for the softer
organic components or the harder mineral, especially pyrite.
Determination of Optical Constants
Optical constants are of interest because they are the basis of the
optical descriptions of the petrographic components and because they
are related to structural atomic arrangements in coals.
One of the simplest methods of determining these optical constants
involves only the microscopic measurement of reflectance in two
different media. The measurements are made using objectives corrected
for air, oil or water immersion, preferably the first two.
The simple equation for transmission is the equation given above for
defining k. However, in practical measurements on thin sections of
coals and carbons, corrections must be made for reflections at
interfaces between the various media. The thin section usually is
supported on a transparent substrate and the radiation enters the
system on the substrate side. Reference light (Io) is usually measured
after transmission through the substrate. An equation governing
transmission through a system consisting of an absorbing medium on a
transparent substrate has been given by Born and Wolf.
Electron Microscopy
The principal procedure involved in the study of coal with an electron
microscope is the preparation of suitable specimens. At first, powdered
coal mounts were observed, but these supplied little useful
information. Replicas of polished or etched coal surfaces were later
tried with some interesting results, but these have been little used
recently. The most productive type of specimen for electron microscopy
is the ultrathin section, prepared as described previously. Preparation
of electron micrographs and electron diffraction patterns of coal
specimens involves no differences in procedure from those commonly
used.
Density
The true density of a somewhat porous material such as coal cannot be
determined in a simple way. Any satisfactory medium for displacement
should consist of molecules small enough to penetrate the pores but
should not react chemically with the coal. It has been found that
helium most satisfactorily meets these requirements. An approximation
for the density can be derived by measuring the displacement of water
by the coal, usually in granular form. However, it is questionable
whether the water molecules can penetrate into the minute pores of the
coal sufficiently to result in the determination of true density.
A blank run without a sample in a sample frame will give the scattering
due to air and background. Air scattering is appreciable only at low
angles. A few scans of the blank run are sufficient. The readings to be
subtracted must be normalized to the number of scans used in obtaining
the intensity with sample in place. An idea about the instrumental
broadening can be obtained by preparing a sample of 2.5mm diamond
powder and obtaining the scattered intensity for the diamond powder
under the same conditions. The widths of the diamond lines are largely
due to instrumental factors. If they are excessive, the observed
intensities with the coal sample can corrected by unfolding them with
those of diamond.
Consider an x-ray beam traversing a distance in the sample before
reaching a differential element of volume dV in the interior of the
sample and further consider the scattered beam traversing a distance y
in the sample before leaving it. The incident beam will undergo a
reduction in intensity by a factor exp (-mx). Where is the linear
absorption coefficient, and the scattered intensity will be reduced by
a factor exp (-my). The over all loss of intensity due to absorption
depends upon the scattering angle as well as the sample diffractometer
geometry, thus corrections must be made. Further, the scattered
intensity is polarized to a different degree at each scattering angle,
and correction must be made for polarization. Finally, the observed
intensities are in arbitrary units, they must be converted or
normalized into Thomson or atomic units.
This form of the Warren-Bodenstein equation also can be modified to
consider an assembly of stacks each containing different layers.
X-Ray Fluorescence Analysis. X-ray fluorescence analysis of elements of
relatively high atomic number is well developed. Presently the method
is practical for element down to, perhaps, fluorine, of atomic number
9. It has not yet been shown to be reliable for oxygen, nitrogen, and
carbon, although research in to these applications is progressing well.
Therefore, fluorescence analysis may now be used for virtually all the
mineral elements in coal, but cannot yet determine the composition of
the organic components.
The sample required for fluorescence analysis is about 2g. It must be
ground to an extremely fine particle size approximately 2 mm or less,
in order to minimize and to render less variable the absorption of the
fluorescence x rays by the mineral matter in the coal sample. This
extreme pulverization can be accomplished in a tungsten carbide pestle
by vibration for 5 min on a device similar to a Crescent Wig-L- Bug,
available from the Crescent Dental Manufacturing Co. Chicago. The
sample is then pressed into a frame with typical dimensions of 4cm.×
2.5 cm ×2.5 mm, under an applied pressure of about 150Kg/cm2.
For the analysis , a standard sample containing proportions of each of
the elements to be analyzed similar to those to be a expected in the
unknown samples is necessary. For coal analysis, this could be a
typical coal sample or a synthetic mixture of the various coal mineral
elements in carbon black.This sample is kept in one of the spectrometer
chambers. Reading on the standard sample are taken at regular intervals
so that those on unknown samples may normalized to minimize errors due
to variations in conditions.
Specification Tests
The American National Standards Institute, Inc. (ANSI) represents the
United States at the international standards level and corresponds in
part to the British Standards Institute (BSI) in the United Kingdom.
The ANSI is unlike the BSI in that it does not develop standards but
recognizes the work of some independent organization. For coal, the
American Society for Testing and Materials has been recognized as the
developing body. The committee for coal consists of approximately
seventy five experts equality divided in interest as producers,
consumers and general interest
The tests constituting coal analysis have been divided into three group
–Proximate, ultimate, and miscellaneous analysis. Some of the taste are
empirical and strict adherence to the specified conditions is required
in order to obtain meaningful results.
Proximate Analysis
Proximate analysis is the quantitative separation of the components of
a mixture. In the proximate analysis of coal, the amounts of moisture,
volatile matter, and are determined. The sum of the percentages of
these components is subtracted from 100 to calculate the amount of
fixed carbon present.
Moisture. The determination of the moisture content of coal is probably
the most important test. It is also one of the most difficult
components to determine accurately because of its several forms, its
fleeting nature during the collection and preparation of the gross
sample, and its strong affinity for the coal during the last stages of
drying.
Usually, three moisture values are required in the analysis of coal.
First, if the coal is too wet to crush and sieve without losing
moisture, it must be air-dried, which results in the value of air-dry
moisture. The air-dried coal is then crushed and prepared for the
laboratory where the residual moisture is determined. This laboratory
sample is used to prepare the analysis sample which is used for most of
the tests. The knowledge of the total moisture content of this sample
is necessary in order to express all items on a dry basis. The total
moisture is calculated from the air-dry and residual moisture values
and is used to convert the various dry analyses to the as-received
basis.
Residual Moisture. Two methods are given; the first is used for coals
known to be resistant to oxidation and the second is applicable to
coals subject to oxidation or to coals of unknown origin.
Procedures
oxidation-resistant coals. Transfer one of the air dried sample to a
shallow, weighed, noncorrodible metal pen to a depth of about 10 mm,
weight, and heat in a forced air circulation oven at 105-110oC to
constant weight. Calculate the % of residual moisture from the loss on
heating and weight of the air –dried sample.
other coals. Mix the air-dried sample well and place approximately 10 g
into a weighed capsule made of glass or noncorrodible metal with
close-fitting covers with a diameter of 60mm, cover, and weight to the
nearest mg. Place the cover in desiccator containing magnesium
perchlorate desiccant, and the capsule in an oven with a minimum free
space, capable of maintaining a temperature of 105-1100C and having
facilities for introducing nitrogen at a flow rate of three oven
changes per minute. Use a nitrogen containing less than 10 ppm of
oxygen. Heat the sample in the oven to constant weight; approximately 2
hr are required. Remove the capsule, cover and put on a metal plate for
10min.Transfer to desiccator until cooled to room temperature, then
weigh. Calculate the % residual moisture from the loss in weight and
weight of the air-dried sample.
Total Moisture. The % total moisture is calculated from the percentage
of air-dry and residual moistures, as follows:
% total moisture = % air-dry + % residual Moisture of Analysis Sample.
This moisture value is used to calculate other analyses made to a dry
basis, using the analysis sample of 250mm size coal.
Volatile Matter. Volatile matter refers to loss of weight, corrected
for moisture, that results when coal is heated in specified equipment
and under standard conditions. It is one of the more important items in
purchase specifications of coal; it is valuable for the fuel engineer
in setting up and maintaining burning rates, and is used with other
parameters in almost all coal classification systems.
The test given below is empirical and easily performed. However, it can
lead to erroneous results if all the vital factors are not observed
strictly. If carried out properly, duplicate tests by the same operator
and equipment should agree within 0.3% for anthracite, 0.5% for
semianthracite and bituminous coals, 0.7% for subbituminous coals, and
1.0% for lignite. For the test, special high-form crucibles made of
platinum, 31 mm high, with a 25.4 mm diameter at the top and 16 mm
diameter at the bottom, are used. The crucibles are equipped with
platinum covers, 10 mm high, with a 25.5 mm diameter at the top and
25.3 mm diameter at the bottom. The total weight of the crucible and
capsule is between 14 and 15g. The heating of the sample is to be
performed in an electrically heated vertical tube or muffle furnace.
The tube furnace heating zone should be approximately 38 mm ID by 100
mm long. The crucible is suspended in the heating zone by a platinum or
nichrome wire cradle. The size of the muffle furnace should be large
enough to insert and remove the crucible conveniently. It is essential
that the heating zone of the furnace be maintained as close as possible
to 9500 C , but must not vary more than 200C.
Ash. Coal ash is the residue remaining after the combustion of coal
under specified conditions. Ash should not be confused with mineral
matter. The ash can be more than, equal to, or less then the take place
during combustion.
The quantity of ash in coal is of prime importance in purchase
specifications, utilization, and classification. Ash represents an
impurity, adds to the cost of transportation of the coal, and is costly
to dispose to after utilization. In certain methods of utilization, ash
contributes to air pollution as well as corrosion of the burning
equipment.
Fixed Carbon. The fixed carbon is calculated by subtracting the sum of
moisture, volatile matter, and ash from 100. It consists mainly of
carbon but, also contains small amounts of hydrogen, sulfur, nitrogen,
and oxygen.
Ultimate Analysis
The ultimate analysis of coal expresses the elemental composition in
terms of the determined percentages of carbon, hydrogen, nitrogen,
sulfur, and the calculated value for oxygen. The five items are
generally calculated on moisture and ash free basis. A slight more
accurate value for oxygen is obtained if the analysis computed on a
moisture and mineral-matter-free basis.
Carbon and Hydrogen. These two elements contribute virtually all the
energy derived from coal. The carbon and hydrogen contents of coal are
utilized in certain classification systems and also permit an estimate
of the calorific values of coals.
All methods employ the same basic principle of burning the sample in
oxygen in a closed system and collecting and determining quantitatively
the combustion products. The standard U.S. method carries out the
combustion at 800-850oC. A high temperature (1350oC) combustion method
has been used successfully in a number of European laboratories.
The oxygen to the combustion tube flows through the other area of the T
connection by passing the above described pressure-safety device, and
passes through a U-tube. The first arm contains soda-lime, the bottom
contains a glass-wool plug , and the second arm is filled with
magnesium perchlorate. A one-hole rubber stopper is used to seal the
open end of the combustion tube. Metal or glass tubing is used to
connect this U-tube with the tee and the combustion tube. The joints
are sealed with flexible tubing.
Repeat this procedure using an accurately weighed sample of standard
sucrose or benzoic acid. Several tests may have to be made before the
determined values for hydrogen and carbon are in satisfactory agreement
with the theoretical values. Repeat the procedure with an accurately
weighed sample of coal.
Duplicate determinations by the same operator using the same equipment
and the same analysis sample should not differ more than 0.07% for
hydrogen and 0.30% for carbon.
Nitrogen. Nitrogen occurs almost exclusively in the organic matter of
coal. The amount is rather constant and in most bituminous coals it
varies from 1.0 to 1.5 % in anthracite and low-rank coals.
The kjeldahl method is most commonly used, and consists of destructive
digestion of the coal with a mixture of concentrated sulfuric acid,
potassium sulfate, and mercury catalyst. The nitrogen is distilled from
alkaline solution as ammonia into a standard acid solution and
quantitatively determined titrimetrically.
Total Sulfur. Sulfur occurs in coal as the sulfide of iron and in
combination with the organic matter. In some weathered coals small
amounts of sulfate sulfur may also be found. Two chemical methods are
used for the determination of total sulfur. In the method given , the
coal is oxidized in an Eschka mixture. The resulting oxides of sulfur
are retained by an alkaline mixture, extracted with water, precipitated
high-temperature combustion in a closed system with oxygen, the sulfur
oxides are absorbed in aqueous hydrogen peroxide, and the sulfuric acid
formed is treated with a standard alkali. It is particularly applicable
where results are required in a very short time.
Oxygen. The oxygen content of coal can be used to estimate the degree
of oxidation of a weathered bituminous coal, and it is an indicator of
the lowest rank in the bituminous group that can be used for making a
satisfactory metallurgical coke.
Oxygen can be determated directly by a semimicro combustion method. For
most purposes it is estimated by subtracting from 100 the sum of the
percentage hydrogen, carbon, nitrogen, sulfur, moisture and ash. A more
accurate estimate can be made by converting the analysis to a
mineral-matter-free basis.
Colorific Value
The test consists of burning a weighed amount of the material in a
closed vessel under a pressure of oxygen. Heat is released and absorbed
in a fixed mass of water. The increase in temperature of the water is
directly related to the calorific value of the material. The manner of
absorbing this indicates the two principal types of calorimeters
commonly used in the isothermal calorimeter, the temperature of the
water bath surrounding the calorimeter is maintained at a contained at
a constant temperature. Since the temperature of the water surrounding
the combustion vessel or bomb varies, there is heat exchange between
the two systems, and the amount of heat gained or lost must be
determined between the two systems, and the amount of heat gained or
lost must be determined. Adiabatic calorimeters have the facilities to
adjust or raise the temperature of the outer water bath to the same
temperature of the water surrounding the combustion vessel.
Remove the bomb and release the pressure at a uniform rate in about
1min. Inspect the interior of the bomb for unburned carbon, and if it
is present discard the results and repeat the test. Wash the interior
of the bomb with water containing methyl orange indicator until all
acid is removed , collect the washings and titrate with a sodium
carbonate solution containing 20.90g/liter, 1 ml of this solution
corresponds to 10.0 Btu. If a combustible firing wire is used,
determine the weight of the unburned wire.
Fusibility of Coal Ash
This test gives an approximation of the temperatures at which the ash
remaining after the combustion of coal will sinter, melt and flow. The
correlation of the laboratory and utilization results is only
approximate, because of the homogeneity of the laboratory test piece
and the heterogeneity of the residue or ash from utilization. The
fusibility datas are of value in the procurement of coals that most
likely will perform satisfactorily.
The procedure given below consists of heating a molded trilateral
pyramid of the ash in a mildly reducing or oxidizing atmosphere and
observing the changes in shape and the temperatures at which the
changes occur. Four such temperatures are defined below.
Behavior on Healing
Some of the phenomena exhibited by coal on heating have been assigned
names that refer to essentially the same behavior; they differ only in
the rate of heating. These slight differences of operation become of
great importance when they are used in the classification of coals. The
various terms may be defined as follows:
Caking refers to the behavior of the coal when it is heated rapidly in
measuring the free-swelling index and Roga index or as the combustion
of coal. The agglomerating index refers to the behavior of coal when
heated rapidly in the volatile matter test.
Coking refers to the behavior of the coal when it is heated slowly in
the Audibert-Arnu dilatometer and Gray-King coke-type tests or as in
carbonization.
Plasticity, dilation , contraction, and agglutinating value are other
terms also used to describe the behavior of coal on heating.
Below, some of the tests used to investigate the behavior of coal
during heating are discussed more detail.
Free-Swelling Index or Crucible Swelling Number. The free-swelling
index is quite important in differentiating between groups in the
classification of coals; it also gives considerable information on the
combustion characteristics of coal. The test consists of heating the
coal under prescribed conditions and comparing the residue or button
with standard profiles as shown in Figure 5. Since the test is
empirical, the special apparatus is specified exactly.
Roga Index. The Roga index is an alternate procedure for measuring the
caking properties of coals. It requires a special drum tumbler and an
anthracite with specified properties to mix with the coal before
carbonizing. Because of the limited use of the Roga index and the
difficulty of getting the specific anthracite or suitable substitute,
the details of the test will not be given.
Agglomerating Index.The agglomerating index is required in the ASTM
classification of coals in order to differentiate between the
anthracitic and bituminous classes and between the bituminous and
subbituminous classes of coals.
The test is made by examining the residue from the platinum crucible in
the standard volatile matter determination. If the agglomerate button
shows a cell structure or swelling or supports a 500-g weight without
pulverizing, it is considered as agglomerating.
Gray-King Coke-Type Test. This test and the Audibert-Arnu dilatometer
are used alternatively for assessing the coking phenomena of coal in
the International Classification of Hard Coal by Type. The equipment
for the Gray-King coke test is more easily acquired and the technique
of operation less exacting than for the Audibert-Arnu dilatometer.
Consequently, only the procedure for the Gray-King test is given.
The test consists of heating pulverized coal out of contact with air in
a horizontal tube retort at a uniform and slow rate.
Plasticity of Coal Measured by the Gieseler Plastometer. The test is a
semiquantitative measurement of the plastic property or apparent
melting of coal on heating in the absence of air. The plasticity
phenomena have been quite closely related to carbonization and many
researchers have attempted to relate the Gleseler plasticity values
with the quality of coke produced from a particular coal or more often
a blend of coals. The detailed specifications of the testing equipment
and procedure of operation make this a very empiric test. The slightest
variation in equipmental detail or deviation in operation can results
in erroneous results.
At present, two types of equipment are in use, one utilizing a constant
torque of 40g-in. by suspended weight on the stirrer imbedded in coal,
and another which produces an equal torque by a magnetic clutch between
a constant speed motor and the stirrer. For more detailed information
on the procedures, the instruction manuals supplied with the equipment
should be consulted.
Equilibrium Moisture of Coal at 96-97% Relative Humidity and 300C
This test is used to restore wet coal and partially dried coal to the
moisture content it contained in the bed. The test results are used to
measure the degree of during and excess moisture, and in the
classification of coals by rank. It is applicable to all coals from
metaanthracite to lignite. The measurement is carried out in a moisture
oven maintained at 1050C and with provision in dry air or dry nitrogen
at a rate of two oven changes per minute. Air is used only with coals
known to be slowly oxidized.
Determination of Hardgrove Grindability Index of Coal
The Hardgrove grindability index (HI) of coal is a relative measure of
the ease of pulverizing. The test consists of grinding a specially
prepared sample in a laboratory mill of standardized design. The
Hardgrove grindability machine is available from Babcock &
Wilcox Co. Alliance, Ohio. An index is derived from a sieve analysis of
the ground product. For comparison, a standard coal sample with an
index of 100 is used.
Special Constituents
In addition to the determination of the carbon, hydrogen, nitrogen,
sulfur, and oxygen content of the coal, sometimes investigations are
carried out to determine the amount of sulfur present in various forms,
and the chlorine and mineral carbonate content of coal.
Froms of Sulfur. Sulfur occurs in coal as sulfate, pyrite, and in
combination with the organic material. Sulfate sulfur is usually less
than 0.1% except for weathered coal containing appreciable FeS2. The
pyritic sulfur content varies considerably more than the organic
sulfur, and is of more interest because it is the only form that can be
removed from coal by current preparation practices.
Chlorine. A considerable amount of the chlorine in coal is present as
sodium chloride and therefore the amount of chlorine present has been
used as an estimate of the sodium content. Sodium is suspected of
contributing to operational difficulties caused by deposits on the
heating surfaces Coals containing less than 0.15% chlorine are
considered as potentially trouble free. The chlorine content is used in
some system for the estimation of the amount of mineral matter from the
determined ash content.
In the method given, a muffle furnace, heated to 675± 250C and
ventilated at three to four air changes per minute, is used. The coal
sample is oxidized with an Eschka mixture, and the chlorine content
retained as chloride. The resulting mixture is dissolved in diluted
nitrate acid, the chloride is precipitated with silver nitrate, and the
excess of silver is titrated with potassium thiocyanate.
Mineral Carbonates. Infrequently, a coal contains mineral carbonates in
sufficient quantity to affect its carbon content, mineral matter, and
classification. The carbon dioxide of the mineral carbonates is
determined by heating the coal with dilute hydrochloric acid, absorbing
the evolved carbon dioxide in a suitable absorbent, and determining the
weight increase. Duplicate determinations by the same operator using
the same equipment and sample should not differ more than 0.05%
The second hole of the stopper in the Erlenmeyer flask is fitted with
the small end of a coil-type condenser, 300mm long. The open top end of
the condenser is connected with an approximately 300 mm long, 7 mm OD
glass tube. The top of a Stetser- Norton bulb is filled with 15 mm
glass-wool in the bottom and anhydrous calcium chloride on top. The
bottom connection of this bulb is connected with a short section of
rubber tubing to the bottom connection of a second Stetser-Norton bulb
filled two thirds full with granular pumice impregnated with anhydrous
copper sulfate; the remainder of this bulb is filled with anhydrous
calcium chloride.
Coal Classification
The wide variation in chemical and physical characteristics shown by
the several testing methods, methods, provides an opportunity to devise
numerous systems for the classification of coals. Some of the systems
have received only limited acceptance possibly because of little
practical applicability.
Three of the more widely known and used systems are briefly described
below. The British National Coal Board Coal Classification System is
based on the dry, mineral-matter-free, volatile matter and the
Gray-King coke-type test.
Cotton
Cotton is one of the plants utilized by mankind at the dawn of
civilization archeological evidence indicates that cotton was used in
the Indus Valley, in about 3000 BC, for making cloth. Cotton was
brought from India to Egypt by Alexander the Great in the fourth
century bc, and from there it spread to other countries around the;
Mediterranean Sea. Cotton was introduced from India to China during the
seventh century ad, first as a garden plant, and about 1000 ad for use
as a fiber. In America, remains of cotton bolls dating back to about
5000 bc have been found in Mexico, and discoveries indicate that it was
used for textile purposes about 2500 bc.
All wild and cultivated species of cotton plants belong to the
botanical genus gossypium. Most of the cultivated cotton belongs to
four species: Gossypium herbaceum and G. arboreum, which probably
originated in southern Arabia or northeastern Africa and were
introduced into India, G. hirsutum, which originated in southern Mexico
and Guatemala, and G. barbadense, which was found in the northern part
of South America but is also cultivated in Egypt and Sudan.
Chemical Properties. Cotton fiber, like most vegetable fibers, is
essentially cellulosic; however, the percentage of cellulose which it
contains is higher than in most other materials and may be as high as
96% of the dry weight of the unpurified fiber.
Methods of Analysis
Methods related to the identification and analysis of the nature of
cottons modified with organic reagents and organic finishings, as well
as the determination of trace inorganic elements present either as
contaminants or as additives, are discussed below.
Modified Cottons
As mentioned, superficial or partial reactions of the hydroxyl groups
of cotton cellulose produce valuable permanent finishes on cotton
products. These reactions include esterification and etherification,
further reaction with double or multiple bonds, and replacement
reactions resulting in specifically modified cottons.
Infrared Spectroscopy. The identification of the organic groups
introduced into the cellulose molecule, as well as the determination of
the degree of substitution, can be carried out by the use of infrared
spectroscopy.
The fact that infrared absorption spectra can be obtained without
modifying the crystallinity of even highly crystalline native cotton
because grinding of the sample is not required is a major advantage of
this procedure. O’Connor et al. showed that satisfactory spectra could
be obtained with very large pieces of native cotton cellulose, and
cutting 20 mesh was recommended in order to provide a reproducible
technique.
Two special methods are also of interest in the infrared investigation
of modified cotton products. The first developed by McCall, Miles, and
O’Conor utilizes the frustrated multiple internal reflectance (FMIR)
technique; the technique of Knight and co-workers permits the
measurement of cotton fibers without any cutting, grinding, sifting or
mixing with extraneous material.
The technique of direct pressing into parallel fibers was demonstrated
to give satisfactory spectra, and had the advantage that the cotton
fiber was subjected to no treatment other than mechanical pressing and
the highly oriented manner in which the fibers are aligned should be
helpful in polarization studies. This technique is the only
satisfactory manner in which the study of crystallinity by means of
deuterium and infrared measurements can be extended to include
crystallinities of short, staple cellulosic fibers of native or
modified cottons.
Finishing Agents
There are a great variety of subatances which are being used in the
chemical finishing of cotton fabric. Included in this list are
chemicals used to produce water repellency, fire resistance, resistance
to mildew, or protection from actinic radiation, lubricants,
plasticizers, softeners, antibacterial agents, deodorants, fungicides,
germicides, rot resistant agents, and resins used to obtain
durable-press or wash-and-wear characteristics. It is almost impossible
to establish a single coordinated procedure for the analysis of cotton
for any chemical finishing agent; however, two systematic methods
approach this goal.
Separation and Identification
The first systematic approach to separate and identify the chemical
agents used in cotton fabrics was developed by Skinkle in 1946. The
sample is successively extracted with five solvents, each selected to
remove by solubilizing certain classes of substances. Subsequent
evaporation of the solvent reveals the presence of the entire group.
Individual components of each group are subsequently identified either
by further separations, by application of additional solvents, or by
applying chemical tests which are valid in the presence of some or all
of the other substances within the specific group.
Spectroscopic Methods
Ultraviolet, visible, and infrared spectroscopy permit the
identification and quantitative analysis of a number of chemical
finishing agents used for cotton and cotton fabrics.
Ultraviolet and Visible Spectroscopy. The end points in the analysis of
several of the chemical finishes, after extraction and separation, as
by the scheme described above or by one of the many modifications of
this scheme, have been achieved through the production of a
characteristic color produced by reaction of the finishes in a single
group with a reagent which would produce a specific color with only one
constituent of the group. Often interfering colors, by reaction of the
selected reagent with other materials in the group or through a
reaction with the solvent, would necessitate further preseparations
before the color test could be applied.
Total Formaldehyde. An accurate quantitative method for the
determination of the total formaldehyde content of cotton fabrics
treated with a formaldehyde-containing resin is often of considerable
aid in the elucidation of the resin reactions involved. However, the
usual procedure involving distillation with dilute acid and estimation
of the formaldehyde in the distillate is not entirely satisfactory, as
it is difficult to distill formaldehyde completely from solution.
Melamine-Formaldehyde Resin. Hirt, described a method for the
determination of melamine resins used to impart wet strength to paper.
The method, which is applicable to extracted melamine resin from cotton
cellulose fabric, is based on the strong ultraviolet absorption of
melamine near 235 nm.
Cationic Surfactants. The method of Scott depends upon the chloroform
extraction of dye salt formed quaternary ammonium surfactant and excess
Orange II (p-(2-hydroxy-l-napthylazo) benzenesulfonate) in aqueous
solution. Advantage is taken of this last fact to establish a
standardization factor, related to molar absorptivity, obtained from
purified surfactants for the analysis of commercial surfactants.
Infrared Spectroscopy. Although the infrared absorption technique was
completely successful for the identification and quantitative
determination of the extent of chemical modification by reactions with
the active hydroxyl groups of cotton cellulose, its application for the
analysis of the chemical finishes encountered several difficulties.
These difficulties led to the development of complex methods. In one
such method, differential infrared spectroscopy accompanied by linear
scale expansion is utilized. The frustrated multiple internal
reflectance (FMIR) technique of McCall et al. already discussed for
chemically modified cotton fabrics also be applied for the
investigation of the cotton fabrics with chemical finishes.
Differential IR Spectroscopy. McCall, Miles, Tripp, and O’Connor
investigated cottons with chemical finish by comparing their spectra
with those obtained from untreated cotton. This method is only
practical if some estimate of the actual amount of the modifying
reagent (the so-called add-on) can be made.
The analytic scheme starts with the conventional potassium bromide disc
procedure. If this technique permits satisfactory detection,
identification, and quantitative determination of the resin finish, the
analysis is completed with minimum effort. If, however, sensitivity
problems are encountered, the same prepared sample is remeasured using
the differential and/or linear scale expansion techniques. If the resin
finish still cannot be identified or quantitatively determined, resort
is made to the acid hydrolysis procedure.
Inorganic Constituents
Because it is an agricultural product, cotton may contain a number of
metallic or nonmetallic elements or anions. These substances may also
contaminate the original native product during processing. Besides
this, a number of elements may be added in small amounts as inorganic
salts or oxides or as organometallic compounds to the cotton during
processing to produce a specific property not native to cotton.
Chemical Methods
The various elements (either metallic or nonmetallic) in cotton samples
may be identified by the chemical spot test methods developed
originally by Feigl.
These spot tests have one major disadvantage; a separate test is
required for the identification of each element. A second disadvantage
is that spot tests do not yield any real quantitative data regarding
the concentration of the specific element in the sample. For chemical
methods for the quantitative determination of the major inorganic
constituents, see Cellulose.
Spot tests have one advantage over spectroscopic techniques: they
permit distinguishing between various anion groups. Thus, tests can be
made to differentiate among sulfite, sulfate, or sulfide, between
nitrate and nitrite, chloride or chlorate, etc. The atomic
spectroscopic methods in current use permit only the identification
(and determination) of total elemental content. Thus, sulfur is
identified and measured as differentiation of the oxidation state of a
specific element as by induced electron emission are not impossible,
they have not been developed to the point where they can be said to be
tools for the use of the analytical chemist engaged in the analysis of
cotton and cellulose.
Spectroscopic Methods
Although there are about a dozen spectroscopic techniques which are of
potential application to the determination of elements, both metals and
nonmetals, only three, electronic emission, x-ray fluorescence, and
atomic absorption spectroscopy, have been used in the analysis of
cotton cellulose. It is of some importance, therefore, to consider the
respective merits and disadvantages of each of these three techniques.
The advantage of emission spectroscopy in cotton analysis is primarily
its ability to permit, with a single scan, a complete qualitative
analysis of a considerable portion of the entire spectrum. If the
photographic technique is being employed, such a spectrogram permits
the operator to investigate in detail the presence or absence of almost
all specific metals. In many large spectroscopic laboratories, the use
of emission spectroscopy is confined to such qualitative surveys, and
x-ray fluorescence or atomic absorption is used (often subsequent to
the qualitative survey) when quantitative values are required.
A limitation of x-ray fluorescence analysis is that light elements may
escape detection or accurate measurement. However, techniques and
selection of accessories such as x-ray tube, analyzing crystal, and
detector have pushed these analyses down to magnesium and, with special
vacuum spectrophotometers and specially designed analyzing crystals,
such as lead stearate, analyses are being made down to boron, leaving
very few elements which cannot be detected and determined by this
technique. These latter determinations, between magnesium and boron,
can be made, however, only by a significant increase in instrumental
sophistication and expense.
Another disadvantage of x-ray fluorescence is the sophistication and
the cost of the initial equipment, which is higher than the cost of the
equipment used in the other techniques.
Emission Spectroscopy. Emission spectroscopy consists of three more or
less independent steps. First, the proper preparation of the sample;
second, the technique for obtaining the raw data, the emitted atomic
lines of the desired constituents; and third, the evaluation of these
data to properly identify and quantitatively determine the element or
elements of interest.
In the original paper of O’Connor and Heinzelman, describing the
general method for the spectrochemical analysis of plant products, two
procedures were recommended, one for samples with an ash content of
less than 1% (where there could be no matrix effect from the
composition of the ash), and another for samples with ash content of
sample over 1% (where the composition of the ash might effect the
condition for constant matrix). In later works the second procedure was
used, mainly because the cotton samples being analyzed were fabrics
chemically modified by the introduction of metal-containing substances
to produce specifically desired effects. The two procedures are given
below.
Procedures
ash-content of sample less than 1%. Accurately weigh 16.67 of the
sample into a Vycor dish with 90-mm diameter, and add 2 ml of a
solution of 250 g of magnesium nitrate hexahydrate in 1 liter of 95%
ethanol. The ratio of sample weight to the magnesium nitrate buffer is
arbitrary and can be varied for different samples depending upon the
sensitivity required, if the ratio actually used is considered in
obtaining and using the working curves. The ratio suggested here will
permit analysis with a sensitivity of about 1 part of metal in
10,000,000 parts of sample for the more sensitive metals, copper and
iron, for most types of samples.
ash content of sample over 1%. Ash exactly 5 g of sample in a tared
Vycor dish as described in the earlier procedure, but without addition
of the magnesium nitrate solution. After removal from the furnace, cool
the dish and reweigh to determine the ash content of the sample. Add a
volume of a very dilute aqueous solution of germanium dioxide so as to
introduce a quantity of the dioxide equal to 4.14% of the ash. Grind
and thoroughly mix the ash prior to analysis.
Prepare a mixture of salts representing the major constituents of a
typical ash. A suggested composition is as follows: 65.18% potassium
carbonate, 0.95% sodium chloride, 11.02% calcium carbonate, 18.70%
magnesium carbonate, and 4.14% germanium oxide. Prepare working curves
by adding graduated amounts of elements to portions of this salt
mixture.
X-ray Fluorescence Analysis. When x rays strike any material, as any
analytical sample, one usually considers their penetration, as it is
their dominant characteristic. However, if the beam of x rays is
measured before and after striking the sample, a decrease in intensity
will be found. Some of the x rays have been absorbed by the material,
the amount, of course, depending upon the nature, particularly the
density of the material, and the thickness of the sample. These
absorbed x rays can be used as a successful method of spectroscopic
analysis in a manner essentially analogous to the use of the absorption
of photons, except that absorption of x rays is an atomic process, and
absorption by a given element is independent of the chemical
combination in which the particular element occurs. Thus, x-ray
absorption is a technique for elemental analysis.
An x-ray spectrometer consists of an x-ray tube capable of emitting an
intense x-ray beam that impinges upon the sample to be analyzed.
Fluorescent rays, which appear as secondary emission, are dispersed by
utilizing crystal with a known lattice constant, frequently a bent mica
crystal, to act as a diffraction grating. The diffracted fluorescent x
rays are detected by a Geiger counter goniometer, and their intensities
may be automatically recorded as a function of the foniometer angle
which is proportional to the wavelength or frequency of the x rays.
Sections of such a tabulation are reproduced in Table 11 for the five
elements, calcium, chromium, potassium, manganese, and zirconium. All
the lines in Table 11involve the innermost orbit, as indicated by the
letter K in column 3, although in more complete tables the L and
occasionally M and N lines may occur. ABS indicates the absorption line
or edge.
For the purpose of determination by x-ray fluorescence methods, the
elements introduced into cotton through chemical and additive
modification (which are the major purposes for such analyses) fall into
two broad categories; those of atomic number 22 and higher, and the
lighter elements. The heavier elements are used to impart protection
against degradation by outdoor exposure or microorganisms (copper,
mercury, lead, cadmium, selenium, zirconium), and to impart flame
resistance (tinbromine); they are also used in certain classes of dyes
and pigments (chromium, iron, titanium) and for miscellaneous purposes,
such as catalysts.
Count rates of equivalent discs usually show a maximum difference of
2%. The relationship of percentage composition to counting rate is
found to be linear over a range of 0.01 to about 3% for most of the
elements examined. In all cases, a loss in counting rate was noted at
concentrations above 3% indicating self- absorption. This loss of
counts becomes marked at concentrations of about 10% and dilution with
pure cellulose should be employed.
Lignin and Hemicellulose
The compositions and percentages of lignin and hemicellulose very from
one plant species to another so it is difficult to arrive at
generalizations concerning structure and abundance of these polymers.
Moreover, composition varies within a single plant (roots, stems,
leaves), with age (heartwood versus sapwood), stage of growth (early
wood versus late wood in annual rings) and with the conditions under
which the plant grows. Study over many decades has elucidated the major
structural features of wood hemicelluloses and lignin’s along with the
biochemical mechanisms for their degradation. Most recently attention
has turned to the molecular characteristics of these enzymes. It is
beyond the scope of the present review to recapitulate these findings
in detail. Rather, the focus will be on specialized or recently
revealed aspects.
II. Hemicellulose
Softwoods (gymnosperms), hardwoods (angiosperms), and grasses
(graminaceous plants) have evolved separately, and they contain
different lignin and hemi cellulose constituents. Moreover their
specialized tissues have varying proportions of cellulose,
hemicellulose, lignin, pectins, proteins, and extractives. Lignin is
deposited during maturation of cell walls, and some carbohydrates
become cross linked to it. Because the lignin and hemicellulose
constituents differ, the crosslinks between these polymers differ form
plant to plant and from tissue to tissue.
A. Assay systems
Hemicellulases are most commonly assayed by measuring the rate of
reducing group formation under optimum conditions. A suitable
polysaccharide substrate is suspended in buffer and mixed with an
enzyme solution that is appropriately diluted to yield a linear
response over time Alternately, several successive two-fold dilutions
are assayed for a single fixed time (10 to 30 min), and the enzyme
titer is calculated from the average of several successive dilutions
that exhibit a consistent enzyme activity. This approach is necessary
because at very low dilutions (or long assay times) the substrate is
exhausted, and the calculated activity is not representative of the
actual value.
B. Classification
Hemicellulases are classified according to the substrates they act
upon, by the bonds they cleave and by their patterns of product
formation, Table 1, but greater variety exists among the endo-xylanases
and ß- glucosidases than is reflected in this simple classification
system. One notable distinction is made between endo-1,4-b-xylanase (EC
3.2.1.8) and xylan 1,4-b-xylosidase (EC 3.2.1.37). While the former
produces oligosaccharides from random cleavage of xylan , the latter
acts principally on xylan oligosaccharides producing xylose. Some
endo-xylanases appear to have greater specificity for straight chain
substrates, and others appear to be able to accommodate more frequent
side chains of branching.
Deacetylation makes native xylans much less soluble in water, which is
an observation that causes some consternation to trained organic
chemists. Even though acetylation makes the xylan polymer more
hydrophobic, it also blocks extensive intrachain hydrogen bonding. When
the acetyl groups are removed, hydrogen bonding leads to xylan
precipitation. Even though the substrate is less soluble, deactylation
generally increases susceptibility of the substrate to enzyme attack.
Some acetylesterses, however, show specificity for the native
acetylated substrate.
C. Thermophilic hemicellulases
Thermostable enzymes are often of interest for biotechnological
applications, and hemicellulases are no exception. Thermophilic
xylanases have been recognized for several years. Ristoph described an
extra cellular xylanase produced by the thermophilic actinomycete
Thermonospora that was stable for approximately 1 month at 55 °C and
could withstand up to 80°C in a 10 min assay. Gruninger described a
highly thermos table xylanase form a thermophilic bacillus that has a
catalytic optimum of 78° and a half life of 15 h at 75°. Both enzymes
were predominantly endo in activity and produced only trace quantities
of xylose after long periods of incubation. The thermophilic fungus
Thermoascus aurantiacus produces an extra cellular endo-xylanase that
has a temperature optimum of 80°C. At that temperature, the half life
is 54 min. These characteristics are fairly similar to thermos table
xylanases from Talaromyces emersonii, another thermophilic fungus that
grows on straws and pulps.
D. Alkaline active xylanases
An alkaline active enzyme was also purified and characterized from an
alkalophilic actinomycete. Tsujibo et al. purified three endo-xylanases
from the culture filtrate of Nocardopsis dassonvillei subsp. alba OPC-
18. The molecular weights were 23,000, 23,000 and 37,000 for
X-1,X-11,and X-111, respectively.
E. ß- Xylosidase
Endo-xylanases are much more common than ß-xylosidases, but the latter
are necessary in order to produce xylose. Most ß-xylosidases are cell
bound, and the enzymes are large relative to endo-xylanases. The
ß-xylosidase of Bacillus sterothermophilus has a molecular weight of
about 150,000 and is stable at up to 70°C Utt described a novel
bifunctional ß- xylosidase from the ruminal bacterium Butyrivibrio
fibrisolvens was cloned in E. coli and shown to consist of a 60,000Mr
protein with dual glycosidase activity.
F. Mannanases and galactanses
Mannanases and galactanses are described far less frequently than
xylanases. It is not known whether this is attributable to their lower
prevalence in nature or simply because they are sought less often.
Bacterial species known to produce mannanases include Aeromonas
hydrophila, Cellulomonas sp. and Strepromyces olivochromogenus.
Multiple endo – ß-mannanases are found in the extra cellular broth of
Polyporous versicolor.
G. Accessory enzymes for hemicellulose utilization
A number of enzymes appear to be critical in the early steps of
hemicellulose utilization. These include acetyl xylan esterases,
ferulic and p-coumaric esterases,a-l a rabinofuranosidases, and
a-4-O-methyl glucuranosidases.
Acetyl xylan esterase was first described by Biely in several species
of fungi known to degrade lignocellulose and most especially in A.
pullulans. Acetyl xylan esterase was subsequently described in a number
of different micres different microbes including (Schizophylum commune,
Aspergillus niger and Trichoderma reesei, Rhodotorula mucilaginosa and
Fibrobacter succinogenes. Acetyl xylan esterase acts in a cooperative
manner with endoxylanase to degrade xylans. This enzyme is not involved
in breaking LCbonds because the acetyl esters are terminal groups.
The ferulic acid esterase of S. commune exhibits specificity for its
substrate, and it has been separated form other enzymes. Borneman et
al. assayed feruloyl and p- coumaryl esterase activities form culture
filtrates of anaerobic fungi using dried cell walls of Bermuda grass as
a substrate. The enzyme preparations released ferulic acid more readily
than they released p-courmaric acid from plant cell walls. Assays using
methyl ferulate or methyl p-coumarate as substrates in place of dried
cell walls showed the presence of about five times as much enzyme
activity. McDermid employed ethyl esters of p-coumarate and ferulate as
substrates for these activities.
111. Lignin
Lignin is an aromatic polymer with the substituents connected by both
ether and carbon-carbon linkages. It is composed of three principal
building blocks: p-coumaryl alcohol (p-hydroxyphenyl propanol),
coniferyl alcohol (guaiacyl propanol), and sinapyl alcohol (syringyl
propanol)
A. Lignin-degradingenzymes
Recent years have witnessed an increasing interest in the enzymatic
mineralization and depolymerization of lignin. No dougbt this stemmed
in part form the description of a family of peroxidase-like enzymes
from active lignin-degrading cultures of Phanerochaete chrysosporium.
These enymes, termed lignin peroxidases (LiP) are capable of degrading
a number of lignin model compounds- including the b- aryl ether
model-and are closely associated with the mineraliation of 14C-
labelled lignin to CO2. Of particular note is the ability of enzyme
preparations from p.chrysosporium to depolymerize methylated spruce
lignin.
B. Lignin degradation in whole cell cultures
There are essentially two approaches to understanding the roles of
these various enzymes in lignin degradation. One approach is to
reconstitute a lignin- degrading system in vitro using crude, purified,
or cloned enzyme constitutents. The other is to regulate the cellular
metabolism of lignin- degrading fungi in vivo so as to produce either
LiP or MnP, and then to observe the cultures for depolymerization and
mineralization.
Studies by Perez showed that both the appearance of lignin- degrading
enzymes and mineralization of lignin are affected by the presence of
manganese. The effects, however, vary with the organisms and test
systems employed. In p.chrysosporium, elevated Mn concentrations
represses LiP while inducing MnP, and in phlebia brevispora,Mn
represses LiP while inducing both MnP and laccase. In both cases, high
rates of mineralization correlate with the appearance of LiP at low Mn
concentrations and not with the appearance of MnP or laccase D.
squalens produces only MnP and laccase, and in this organism,
mineralization correlates with the appearance of MnP.
C. Degradation by cell-free enzyme systems
Complete catalytic depolymerization of lignin has not been demonstrated
in vitro with a cell-free enzyme system. Extracellular proteins form
p.chrysosporium, Coriolis versicolor, and phlebia radiata were reported
to increase the number of hydroxyl groups, decrease the mean molecular
weight, or otherwise chemically alter various lignin preparations. Kern
investigated the action of crude and partially purified LiP form p.
chrysosporium on the molecular size distribution of 14C – labelled
lignins, and he further used pyrolysis GC mass spectrometry to
investigate changes in substrate characteristics.
The mechanism of lignin depolymerization may not be the same in all
organisms. Galliano studied lignin degradation (solubilization) by
Rigidoporous lignosu, an organism that does not produce LiP, but rather
synthesizes MnP and laccase. When the tow enzymes were puriried and
their properties studied in vitro,neither enzyme was able to solubilize
radioactive lignins. When both enzymes were added to the reaction,
mixture at the same time, lignin solubilization was extensive; the MnP
and the laccase acted synergistically. In addition, glucose oxidase
enhanced lignin solubilization by preventing repolymerization of the
radicals formed by the two oxidative enzymes.
D. Role of glycosides in lignin degradation
One of the first enzymes implicated in lignin biodegradation was
cellobiose: quinone oxidoreductase(CBQase). This enzyme catalyzes the
reduction of a quinone and the simultaneous oxidation of cellobiose
discovered this enzyme and proposed that its tole might be to prevent
repolymerization of lignin during degradation. Recent studies have not
borne this out, but the enzyme may be important monetheless. The CBQase
of P.chrysosporium binds very tightly to microcrystalline cellulose,
but such binding does not block its ability to oxidize cellobiose,
indicating that the binding and catalytic sites are in two different
domains.
An essential feature of lignin biodegradation is that degradation
products resulting form the activity of extracellular enzymes must be
taken up by the mycelium; glycosylation by b-glucosidase seems to be an
important part of this process. Whether or not sugars attached to
lignin in the native substrate by nonglycosidic linkages play a similar
role has not been addressed.
1V. Lignin-carbohydrate complexes
Lignin-carbohydrate complexes (LCCs) are heterogeneous, poorly defined
structures that are found in many plant species. Lignin is directly or
indirectly bound covalently to carbohydratate, and the resulting
complexes present a barrier to biological degradation. LLCs have proven
to be highly intractable materials that are in large part responsible
for limiting the biodegradation rate of plant materials.
A. Fractionation of lignin and carbohydrate in wood
The existence and character of LC bonds have long been studied and
debated. In 1956, Bjorkman published techniques for liberating MWL form
finely ground wood. He also obtained an LCC by exhaustive milling and
extraction. Aqueous dioxane was used to extract MWL, and
dimethylformamide, dimethylsulfoxide, and aqueous acetic acid were used
to extract LCC. The lignin contents of LCCs are similar to that of the
MWLs except that the latter contain less carbohydrate. Despite many
attempts Bjorkman could not separate carbohydratae from LCC without
resorting to chemical degradation.
B. Isolation of LCCs
The LCCs are highly heterogenous and difficult to study. Many
conventional chemical treatment, such as alkali, readily disrupt some
of the most prevalent LC bonds. The best approaches employ neutral
solvents and purified enzyme preparations. Most research has focused on
the isolation of water- soluble lLCCs, because they can be
fractionated, sized, and subjected to spectroscopic study. Larger,
insoluble LCCs exist and may even account for the bulk of LC bonds in
the substrate, but less is lnown about them. Most evidence suggests
that the chemical linkages are similar to those of the soluble LCCs.
C. Chemical characteristics of LC bonds
Existence of chemical bonds between lignin and carbohydrate has been
questioned because of the intimate physical intergration between the
lignin and carbohydrate constituents, the possibility of entrapment or
adsorption, and lability of many linkages. Several different types of
LC bonds have been proposed based on knowledge about changes in sugar
composition following digestion and about hemicellulose structures. The
proposed LCbonds include bonds to xylan, glucomannan, cellulose,
various other hemicellulosic sugars, and pectin.
D. Ferulic and p-coimaric ester side chains
Grass and bamboo lignins differ from those of hardwoods and softwoods
in that they are formed not only from guiacyl and syringyl units, but
also from p-hydroxyphenyl units. Esterified p-coumaric acid can
comprise 5% to 10% of the total weight of isolated lignin. The
participation of p-hydroxphenyl glycerol-b-aryl ether structures is of
minor importance.Based on methanolysis and spectral studies, Shimada
proposed that the majority of p-coumaric acid molecules in bamboo and
grass lignin are ester-linked to the terminal g carbon of the side
chain of the lignin molecule Fig.11. Ferulic acid is also present in
small amounts. The p-coumaric ester linkages are extremely stable as
they are not removed by methanolysis, thioglycolic acid treatment, or
catalytic hydrogenolysis.
E. Frequency and stability of LC bonds
The amount of carbohydrate remaining on the lignin can measured by
sugar analysis following acid hydrolysis. Obst found 10.8% carbohydrate
in a MWEL from loblolly pine. Afraction of this amount (11%) was
removed by dilute alkali.
F. Residual lignin in kraft pulp
Kraft pulping removes large quantities of hemicellulose and lignin and
disrupts ester linkages between lignin and carbohydrate and between
hemicellulose chains. Even so, significant amounts of carbohydratae
remain bound to the residual lignin after kraft pulping. As the
reaction progresses, however, residual lignin becomes harder to remove.
Lignin remaining in the kraft pulp cannot be removed without
unacceptable large yield losses.
to the O-6 of galactoglucomannan. Although this structure is in accord
with what is known about native LC bonds, the bonds in kraft pulp can
be very different. The nature of the covalent linkages in kraft pulp
have not been fully characterized because (1) many rearrangements occur
during pulping (2) difficulties are encountered in isolating the
residual lignin, and (3) reliable degradation and characterization
methods are lacking. At least some changes appear to result from the
formation of alkali- and acid- stable carbon- carbon bonds between
lignin and carabohydratae Several rearrangements are possible.
Particularly, primary hudroxyls of glucose and mannose can react with
the a, b or g carbons of phenylpropane units to form ether linkages.
The reducing –end groups can also react. Glucose is the most prevalent
sugar bound to residual lignins form kraft pulps, and it seems probable
that this results form the reaction of cellulose with lignin during the
pulping process. This conclusion is supported, but not proven, by the
observation that the glucose content of lignins from wood. Reactions
with the b and g hydroxyls of the phenyl propane are particularly acid
and alkali- stable and may ascape detection in methylation analysis.
Minor used methylation analysis to determine the characteristics of
polysaccharides attached to residual lignin in loblolly pine kraft
pulps. The total carbohydrate content of the residual MWEL was only
about 8%. As compared to the 12% abtained with MWEL from nataive wood,
but methylation data indicated that the carbohydratae bonding was
similar in kraft and native wood. The primary O-6 position was most
frequently found for hexans and the primary O-5 for arabinan. Xylan was
bonded to lignin at O-3, with a small amount at O-2 The predominant
methylated derivatives obtained from glactose and arabinose indicated
1®4 and 1® 5 linkages, respectively. The apparent DP ranged from 4 for
xylan to almost 13 for galactan. Because of the small differences in
methylation patterns between carbohydrates form MWELs of pine and pine
kraft pulp. Minor was not able to confirm the possible formation of LC
bonds during pulping.
G. Biodegradation of LCCs
Most carbohydrate chains or side groups appear to be attached to lignin
through the nonreducing moieties. Because exo-splitting enzymes
generally attack a substrate form the nonreducing end of a
polysaccharide, removing substituents progressively toward the reducing
end of the molecule, complete degradation is not possible. Even when
cargohydrates are attached to the lignin by the O-1 hydroxyl, a single
sugar residue could remain attached even after complete attack by
exo-splitting glycosidases.
I. Residual LC structures after exhaustive enzymatic digestion
The presence of lignin, aromatic acid, and other modifications of
hemicellulose clearly retards digestion of cellulose and hemicellulose
by ruminants. Phenolic acids associated with forage fibre are known to
decrease fibre digestion when they are in the free state. p- Coumaric,
ferulic, and sinapic acids inhibit the activity of rumen bacteria and
anaerobic fungi.
The influence of LCCs on ruminant digestion was studied by examining
the solubilization of LCCs using cell- free hemicellulase complexes
from the rumen. LCCs from grasses of increasing maturity were isolated
and treated with cell-free rumen hemicellulases. As the lignin content
increased, the extent of degradation declined, indicating that the
lignin content of the LC was the overriding factor in determining its
digestibility.
2. Solubilization of LCC by microbial activity
In recent years, studies on the solubilization of lignin from grasses
or wood labelled with 14C phenylalanine have proliferated.The bulk of
the radioactive label is incorporated into the lignin rather than into
carbohydrate or protein of the plant, but it is clear that lignin
purified from the labelled plant tissue contains significant amounts of
carbohydrate. This material is probably closer to the structure of
native lignin than is synthetic lignin prepared by in vitro
dehydrogenative polymerization of coniferyl alcohol.
In summary, research on the solubilization of LCC by microbial activity
has periodically shown that cellulases, hemicellulases, esterases, and
perhaps peroxidases all correlate with lignin solubilization. The
mineralization rates and extents reported for streptomyces are
relatively low, and the solubilized lignin is not extensively modified.
Lignin mineralization and solubilization could, therefore be
sttributable to two (or more) different enzymes. These studies require
additional rigorous clarification.
V. Enzymatic treatments of pulps
For many applications, residual lignin in kraft pulp must be removed by
bleaching. Successive chlorination and alkali extraction remove the
remaining lignin to leave a bright, strong pulp suitable for printing
papers and other consumer products. Although chlorine bleaching solves
the immediate problem of residual lignin, the chlorinated aromatic
hydrocarbons produced in the bleaching step are are recalcitranat and
toxic. These chlorinated products are hard to remove from waste
streams, and trace quantities are left in the paper, so other bleaching
processes were devised. One approach is to use hemicellulases to
facilitate bleaching.
V1. Conclusions Lignin and hemicellulose are complex polymers occuring
in plant materials. Either polymer alone presents a formidable
challenge to microbial degradation. In native substrates, however,
lignin and hemicellulose are intermeshed and chemically bonded through
covalent corss-linkages. As such they are even more resistant. Covalent
lignin – corbohydrate linkages can be divided into two types: ester
linkages through the free carboxy terminus of uronic and aromatic acids
and ether linkages through sugar hydroxyls.
Degradation of Wood
Introduction
Microbial degradation of wood should be considered on two levels. From
an organismic point of view degradation concerns the interaction of the
cell with its microenvironment. At this level, degradation is strongly
affected by diffusion of the degradative agents and the uptake of the
oligomeric products. From a biochemical perspective, degradation
concerns the molecular architecture of the biopolymers, the capacities
of the enzymatic catalysts to bind to them and the catalytic turnover
rates. Lignin reactivity is limited by the accessibility,
heterogeneity, and stability of the polymeric linkages; cellulose
reactivity is limited mostly by accessibility and crystallinity; and
hemicellulose reactivity is limited by substitution.
Distribution of Wall Components
The three principal components of wood are found throughout the wall.
Cellulose is organized into laminar crystallites which are bundled into
the microfibrils. Each micro-fibril contains regions of amorphous
cellulose interspersed and intertwined with hemicellulose, Fig. 1. The
latter is in turn crosslinked to lignin. Most of the cellulose is in
the secondary wall layers. Its concentration depends on the relative
portions of hemicellulose and lignin.
Component Chemistries
Lignin is a stable, highly cross-linked aromatic macromolecule arising
through dehydrogenative free radical polymerization of p-coumaryl,
coniferyl; and sinapyl alcohols. Gymnosperm lignin is made up
principally of coniferyl alcohol (guaiacyl lignin) whereas angiosperm
lignin is made up from approximately equal amounts of coniferyl and
sinapyl alcohols (syringyl/guaiacyl lignin). p-Coumaryl alcohol is
found principally as a precursor to the lignin of grasses and in
reaction wood. Cellulose microfibrils are the most conspicuous element
of the plant cell wall. The b-(1,4)-D-glucose chains which make up the
cellulose polymer can be arranged in both parallel and antiparallel
crystallites; but based on what we now know about the biosynthetic and
biodegradative mechanisms and x-ray crystallographic studies, the
parallel arrangement is almost certainly the form found in nature.
Microstructure and Porosity
Porosity and microstructure are critical in determining accessibility
of enzymes to their polyumeric substrates. The relationship between
enzyme diffusion and substrate accessibility has been shown in the
number of ways. For example, reducing particle size greatly increases
surface area and speeds up the enzymatic hydrolysis of cellulose.
Grinding or cutting wood to open all the lumina to attack will expose
considerably more surface than is available in whole wood. The total
surface area reaches about 1 m2 g-1. Once the lumina are accessible,
however, relatively little further increase in surface area occurs
following further grinding, because the cell wall thickness is very
small compared to its length. Particle size is not the only factor
important in enzymatic depolymerization. Enzymatic accessibility
depends on the structure of the wall itself.
Degradation of whole wood
Microbial degradation of whole wood occurs principally by fungi.
Although bacteria apparently possess much of the biochemical machinery
necessary for biodegradation of the wood components, they do not form
mycelia, and hence, cannot propagate through the tissue structure or
translocate nutrients into the wood or from one region to another as
decay progresses.
Biodegradation of Lignin
Biodegradation of lignin has been studied for more than 80 years with
only incremental progress over much of the time. Early assays employed
the disappearance of acid-insoluble Klason lignin. The development of
Synthetic 14C-labelled lignins enabled rapid radiorespirometric
determination of lignin degradation under controlled conditions, and a
series of experiments using this assay led to improved understanding of
the cultural and nutritional conditions under which lignin
biodegradation occurs.
Other aspects of lignin biodegradation such as the roles of oxidative
species details of biochemical mechanisms, regulation and bacterial
lignin degradation have been reviewed elsewhere.
Biodegradation of Cellulose
The biodegradation of cellulose has probably attracted more attention
world-wide than any other single biochemical event outside the filed of
medicine, yet the mechanism of cellulose hydrolysis is still
imperfectly understood. The cellulase complex from Trichoderma reesei
has been studied most thoroughly, but it is not yet clear exactly how
this complex works to depolymerize cellulose. The focus here is placed
on the biochemical mechanisms involved in hydrolysis.
When all of the cellulases are present, Valonia crystals undergo a
delamination to form bundles of microcrystallite fibrils. A similar
delamination has been observed with the purified bacterial cellulose
from Acetobacter xylinum. Although no direct evidence is available, the
delamination probably occurs between the sheets adjacent van der
Waals-bonded sheets rather than between adjacent hydrogen bonded
chains.
The distinction between CBH I and II is not confined to T. reesei. CBH
I and II are also found in the cellulase complex of Penicillium
pinophilum and in Fusarium lini. In the later instance, CBH I was found
to be active against D-xylan, whereas CBH II was not. Given the
apparent importance of the C6 carbon in forcing the half-chair
conformation during the hydrolysis of the glycosidic bond by lysozyme,
it is apparent that substrates lacking this substituent may not be
appropriate for some cellulases.
Biodegradation of Hemicellulose
Because of the diversity of hemicelluloses, it is not possible to
survey here all of the different types known. Dekker have provided an
extensive, useful compilation of this sort. Likewise have recently
reviewed the literature on microbial xylanases. Mannanases have been
studied to a lesser extent, hence, the emphasis here is placed on
xylanases.
The characterization of hemicellulase mechanisms presents numerous
difficulties not encountered with cellulase because the substrate
employed is heterogeneous and branched. Moreover, the literature is not
definitive because substrates such as larch arabino – glucuronoxylan
commonly used for hemicellulose assays – presumably because of their
easy solubility – but they are not really representative of the bulk of
hemicellulose found in wood. Selection of an appropriate substrate is
critical because the apparent specific activity of a xylanase can vary
greatly depending on the xylan preparation used for assay. Substrate
variability is not confined to the type of xylan employed, because
different batches of xylan from the same supplier can lead to apparent
changes of as much as two-fold. Native xylans tend to be highly
acetylated. Acetyl groups increase colubility but decrease the rate of
enxymatic depolymerization so the method of substrate preparation can
have a profound affect on the apparent activity.
Many xylanases are not able to remove glucuronic acid resudies from the
xylan chain probably because of the 30-fold greater stability of
glucuroniside glycolytic linkages noted earlier. By comparison, the
ester linkages connecting acetyl groups to the xylan are exceedingly
unstable and most are removed ruing isolation of the polymer. Although
synergism is observed between xylan esterases and endoxylanases during
hydrolysis of partially acetylate4d xylan, it seems unlikely that
deacetylation would be a rate-limiting step in the enzymatic hydrolysis
of xylan under most practical conditions because of the extreme
lability of the ester linkages.
Applications
Technical developments, particularly the discoveries of
xylose-fermenting yeasts and lignin-degrading enzymes have paved the
way for specific removal of hemicellulose and lignin in order to
recover cellulosic fibers and to produce useful chemicals from the
hemicellulose and lignin fractions.
An alternative approach to biological pulping which permits more direct
control over the degradation activities is to employ isolated enzymes
for lignin or hemicellulose removal. Because the lignin is cross-linked
mostly into the hemicellulose is more readily depolymerized than
lignin, it has been the initial target of treatment. Removing only a
small portion of the hemicellulose might be sufficient to open up the
polymer and ease solvent removal for the residual lignin. The principal
problem in these studies has been in obtaining selective removal of
hemicellulose without degrading the cellulose. Selective inhibition of
cellulase activity can be realized by the addition of I mM HgCl2. Xylan
was specifically removed from delignified cell walls leading to a
decrease in energy demand during beating. Removing less than 2% of the
initial dry pulp weight gave better fiber bonding due to increased
flexibility. Therefore, enzymatic treatments of pulp hold the prospect
of both decreased cost and improved fiber qualities.
CCA-Treated Wood
Wood treated with CCA is widely used in outdoor architectural projects
such as decks, walkways, gazebos and retaining walls. Although this
material was originally marketed as a maintenance-free product, most
preservatives manufacturers and end users today recognize the
advantages of protecting and beautifying CCA-treated lumber with
surface finishes. As a consequence, it frequently becomes a substrate
for a variety of coatings products. Unfortunately, little published
information is available on the performance of surface finishes over
CCA-treated wood. This has led to some confusion among preservatives
manufacturers, coatings companies, the trade, and consumers as to the
compatibility of coatings with this material. Not surprisingly, there
are a number of misconceptions about the effects of CCA treatment on
coatings performance. This project was undertaken to help clarify some
of these issues.
All of this suggests that surface finishes applied over CCA-treated
lumber would perform better than those applied over untreated wood of
the same species.
The objective of this project was to evaluate the performance of a
variety of surface finishes over untreated and CCA-treated wood and to
determine the extent of the chromium enhancement effect.
Wood-Polymer Composites
Wood is a hygroscopic material that can sorb water as a liquid or as
vapor from its surroundings. The sorbed moisture can exist in wood as
liquid or vapor in all cavities and as water bound chemically within
cell walls. Moisture in the cell walls affects all wood properties, but
moisture in voids affects all wood properties, but moisture in voids
affects only weight. The amount of moisture held in cell walls varies
according the particular piece of wood and is a function of both the
relative humidity and temperature of the surrounding air. The fiber
saturation point is the point at which cell walls are empty. Wood is
subject to dimensional changes when its moisture content fluctuates
below the fiber saturation point.
One way wood-polymer composites (WPC) are made is by saturating wood
with monomers followed by in situ polymerization of the monomers. Many
monomers used to make WPC do not penetrate the cell walls and do not
completely fill the voids after polymerization, leaving voids in the
wood because of shrinkage of the polymer. Solvents can be used to help
swell wood and aid the penetration of monomers into cell walls,
resulting in moderately high dimensional stability. Methanol has been
used to swell the wood; after methanol treatment, the wood is then
heated.
The objectives of this research were to identify monomers that swell
and penetrate the cell wall without the use of solvents, measure the
extent of swelling in individual monomers, polymerize the monomer in
the wood, and measure the volumetric swelling and moisture content of
the WPC at 90% relative humidity (RH).
Materials and Methods
Monomers
Monomers selected for this study were acrylates and metacrylates, which
can be polymerized using the thermal polymerization initiator
2,2´-azobnis-(2-ethylbutyronitrile). All monomers were used as received
without further purification or removal of inhibitors added by the
manufacturers.
Wood specimens
Maple (Acer saccharum ), northern red oak (Quercus rubra), and southern
pine (Pinus sp.) woods were used. The wood was cut into specimens 2.5
by 2.5 by 0.6 cm (radial by tangential by longitudinal). Growth rings
were oriented parallel to one side of each specimen to minimize
distortion during shrinking and swelling.
Volumetric swelling and moisture content
The WPC specimens and untreated control specimens were conditioned in a
humidity chamber at 27 C and 30% relative humidity (RH) for 7 days. The
conditioned specimens were weighed, dimensions measured, and volumes
calculated. The specimens were then placed in a humidity chamber 27 C
and 90% RH. Specimens were weighed and measured after 2,4, 6, and 24 h,
and 2, 3, 4, and 7 days. The percentage of volumetric swelling based on
the treated oven-dry volumes was calculated based on the oven-dry
untreated weight.
Volumetric swelling of WPC specimens
The rate of swelling of WPC specimens was slow for the first few hours
at 90% RH, compared to that of the control specimens Tables 6 to 8
After 6 h in 90% RH, maple red oak, and southern pine control specimens
swelled 6.6, 6.1 and 7.0%, respectively. In contrast, all maple WPC
specimens swelled less than 3%, red oak WPC specimens less than 3.6%,
and the southern pine WPC specimens less than 4.0% during the same
period moisture into the wood, which lowered the rate of swelling
compared to that of controls during the first few hours at 90% RH.
Moisture content of WPC specimens
The moisture content of WPC specimens was calculated from specimen
weight at specified time intervals in 90% RH. The rate of moisture
sorption during the first few hours was slower than it was after 24 h
in 90%RH. After 7 days at 90% RH, the moisture content calculated on
the basis of only the wood in the specimens (untreated oven-dry weight)
excluding the weight of polymer, showed that many treated specimens
sorbed more moisture than did control specimens.
Conclusions
Certain monomers can swell wood at temperatures above room
temperatures. These monomers have low molecular weights and molecular
structures that facilitate hydrogen-bonding. For wood-polymer composite
(WPC) specimens that displayed some volumetric swelling after
polymerization, cell-walk bulking had the potential to reduce the
moisture-related swelling, but this potential was counteracted by the
hygroscopicity of the polymers. This attraction of moisture to the WPC
specimens resulted in some swelling that likely would not have occurred
had the polymers not been hygroscopic.
Lignocellulosic—Plastic Composites from Recycled Materials
Use of the word “waste” projects a vision of material with no value or
useful purpose. However, technology is evolving that holds promise for
using waste or recycled wood and plastics to make an array of
high-performance products that are, in themselves, potentially
recyclable. Preliminary research at Forest Products Laboratory (FPL),
and elsewhere indicates that recycled plastics such as polyethylene,
polypropylene, or polyethylene terephthalate can be combined with wood
fiber waste to make useful reinforced thermoplastic composites.
Advantages associated with these composite products include lighter
weight and improved acoustic, impact, and heat reformability
properties—all at a cost less than that of comparable products made
from plastics alone. In addition, previous research has shown that
composite products can possibly be reclaimed and recycled for the
production of second-generation composites.
Thermoformable Composites as Outlets for Waste Paper, Wood, and
Plastics
Two general types of thermoformable composites exist, distinguished by
their very different manufacturing processes. Both processes allow and
require differences in composition and in the lignocellulosic
component. The two processes used to produce thermoformable composites
are melt blending and air laying or nonwoven mat formation.
Currently, the primary application of the thermoformed composites, both
melt blended and air laid, is for interior door panels and trunk liners
in automobiles. As noted, additional large-volume, low-to-moderate cost
applications are expected in areas such as packaging (trays, cartons),
interior building panels, and door skins.
Recent Research on Wood Fiber-Thermoplastic Composites
The following is not intended to be a comprehensive review of recent
research on wood fiber-thermoplastic composites. Instead, we simply
illustrate the effects of some important composition and processing
variables in the composite processes, including preliminary indications
of the effects of recycled ingredients.
Composites Made by Melt Blending. The 1980s brought a resurgence of
research into various aspects of melt-blended composites made from
wood-based flour or fiber in virgin thermoplastic matrices. For
example, Kokta and his colleagues have published numerous papers in
this area, emphasizing improvements in the filler-matrix bond through
coupling agents and grafting of polymers on cellulosic fiber surfaces.
Composites Made by Nonwoven Mat Technologhy. Numerous articles and
technical papers have been written and several patents have been issued
on both the manufacture and use of nonwoven fiber webs containing
combinations of textile and cellulosic fibers. This technology is
particularly well-known in the consumer products industry. For example,
Sciaraffa and others have been issued a patent for producing a nonwoven
web that has both fused spot bonds and patterned embossments for use as
a liner material for disposable diapers. Bither has found that
polyolefin pulps can serve as effective binders in nonwoven products,
many additional references could be cited in this area.
Research and Development Needs
At the FPL and the UW, we are conducting a program aimed at developing
technology to convert recycled wood fiber and plastics into durable
products that are themselves recyclable, are environmentally friendly,
and will remove the raw materials from the waste stream. This program
is being conducted in cooperation with the U.S. Environmental
Protection Agency. In support of this goal, we have defined a number of
research and development needs.
Chemical Modification of Wood Fiber
The wood composite industry has an opportunity to follow this trend and
greatly expand markets for new materials based on blends and alloys
with other materials. The research program at the Forest Products
Laboratory is focusing on wood fiber/plastic blends and alloys in an
attempt to produce materials with consistent, uniform, continuous,
predictable, and reproducible properties.
The purpose of this paper, is to present some of the initial results in
the area of wood fiber thermoplasticization. The wood fiber is a
composite made up of a crystalline, thermoset polymer (cellulose) in a
thermoplastic matrix (lignin and the hemicelluloses). The melting point
of the thermoplastic matrix is too high to allow this phase to flow at
temperatures that do not degrade the wood fiber. If the glass
transition temperature of the thermoplastic matrix of wood is reduced
through chemical modification, it is possible to plasticize the wood
fiber allowing it to become more thermo-formable through
thermopressing, extrusion, or injection.
Experimental Procedure
Esterification Procedure
Modification of the fibers using maleic (MA) and succinic (SA)
anhydrides was performed using the following procedure. Hot xylene was
saturated with each of the anhydrides in a reaction vessel. When reflux
temperature was reached, the aspen fiber was added and allowed to react
for different lengths of time to give different levels of chemical
weight gain. Excess anhydride was removed by sohxlet extraction of the
esterified fiber with xylenes for four hours. Excess xylene was removed
by evaporation and then the fiber was oven dried overnight.
Analyses of Esterification Products
FTIR spectroscopy was performed using a Nicolet 6000 Spectrophotometer.
Samples of each modification were dried, ground, and mixed with
potassium bromide in a ratio of 1 mg; 200 mg and pressed under a vacuum
to form pellets. Absorbance was measured over a range from 4000 cm-1 to
400 cm-1with air as a reference.
Scanning electron micrographs (SEM) were taken with a jeol 840 scanning
electron microscope. All samples were coated with gold. A magnification
of 750x was used.
Acetyl contents were determined by saponifying the acetyl groups and
using gas-liquid chromatography (GLC) with propionic acid as a
standard. The ester content of the MA and SA modified fibers were
calculated from the acid and saponification values using a similar
technique to that used by Matsuda.Titration of the free carboxyl groups
in the esterified wood fiber and in ester groups saponified from the
esterified wood fiber gave determinations of the ester content based on
the acid and saponification values and indicated whether the anhydride
added as a monoester or diester.
Board Formation
Five percent of a liquid phenol-formaldehyde (PF) dryprocess hardboard
resin (GP2341.50% aqueous solution), was sprayed onto the esterified
fiber followed by attrition milling to distribute the resin. The fiber
was hand formed into a mat approximately 15 by 15 cm and then pressed
in a heated Carver press at 190°C for 10 minutes to a predetermined
thickness of 6 cm and specific gravity of 0.7. for the no resin boards,
controls AA, MA, and SA modified fibers were hand formed into fiber
mats and pressed in a heated carver press at 210°C for 5 minutes at 8.5
MPa (board pressure).
Board Testing
Moisture sorption
Fiberboards were cut into 5 by 5 cm specimens and placed in separate
rooms at 27°C and 30, 65,, or 90% relative humidity. Each specimen was
weighed at the end of 21 days and the equilibrium moisture content
determined. Triplicate samples were done and the results averaged.
Esterification of Wood Fiber
Figure 1 shows the extent of modification achieved with the three types
of anhydrides based on a molar addition. The reaction with AA results
in the splitting out of byproduct acetic acid during wood
esterification while the reactions with MA and SA result in 100%
anhydride carbon skeleton added to the wood. MA showed a much lower
reactivity than SA which has the same structure except for the double
bond in MA. A possible explanation for the molecule into the cell wall
as well as the instability of the reactivity MA chemical intermediate.
Moisture Sorption of Esterified Fiberboards
Figure 2 shows that the equilbrium moisture content (EMC) of the
esterified fiberboards is independent of the type of esterification,
but is dependent on the molar gain of reacted ester in the wood fiber.
A reduction in EMC was seen for each esterification as the level of
modification was increased.
Rate and Extent of Swelling of Fiberboards in Liquid Water
Figure 4 shows the rate of fiberboard swelling in liquid water at
equivalent levels of anhydride modification. while control boards
swelled almost 25% in thickness in the first 20 minutes, all types of
esterified boards swelled less than 10%. AA reduced the swelling to
less than half of the control specimens while MA and SA modifications
reduced the swelling further. The reduction in swelling can be
attributed to the bulking of the cell wall and the reduction in
hygroscopicity of wood especially with the larger MA and SA molecules.
Delignification of Wood with Pernitric Acid
Organic peroxides such as peracetic and performic acids will
effectively delignify wood and other lignocellulosics. The use of
performic acid as a pulping agent is under active investigation. We
recently found that the inorganic peroxide, peroxymonosulfuric acid,
will readily delignify these materials. Hydrogen perxide is quite
ineffective, however. On the basis of these findings, it seemed highly
likely that other inorganic peroxyacids might also be effective in
delignification. Consequently, we initiated an exploratory study on
delignification of wood with other inorganic peroxyacids.
On the basis of this consideration, we decided to study the possibility
of delighifying wood with pernitric acid. We chose finely divided aspen
wood as the substrate for study because it delignifies easily. Success
with aspen delignification would suggest further pulping studies.
Generation of pernitric acid
There are several methods for preparing pernitric acid. We initially
chose the method described by Kenley, Trevor, and Lan that uses only
concentrated hydrogen peroxide and concentrated nitric acid. Several
attempts at generating pernitric acid by this method were unsuccessful.
After adding a drop of peroxide to the chilled nitric acid in an ice
bath, a puff of yellowish-brown vapor would occur arter a fraction of a
second. Apparently, when the drop of peroxide mixed with the acid, some
pernitric acid formed and then immediately decomposed to nitric acid
and oxygen.
On the basis of the large variability of the data and the ease of
obtaining explosive mixtures, it appeared that pernitric acid was quite
unstable and would readily decompose, especially at higher
concentration. If decomposition of pernitric acid in dilute aqueous was
too rapid, it might possess little ability to function as an oxidizing
agent. It would therefore lose the ability to degrade the lignin in
wood. Because of this consideration, we performed some experiments on
the decomposition of pernitric acid in dilute aqueous solutions.
Decomposition of pernitric acid
We generated pernitric acid by adding 1.35 g of chilled (from a
refrigerator) 70% hydrogen peroxide to 4.0 g 90% nitric acid in a vial
in an ice bath. After 60 min, the mixture was diluted with 24.6 g of
distilled to water. The solution was then analyzed and was 0.68 m
(5.4%) in pernitric acid. The total acidity of the solution was 1.93 m
based on the input of nitric acid. Half the solution remained at room
temperature (22°C) and the remaining half at refrigerator temperature
(6°C) with periodic analysis of each of the two samples.
Delignification of aspen wood
The generation procedure used in the decomposition work produced a 5.7%
solution of pernitric acid. Then 25 g of this solution was added to
1.00 g (o.d. basis) of finely divided aspen wood (passing a 40-mesh
screen, 6.0% moisture). The mixture was held at 22°C for 305 min. The
liquor was drained from the solid residue. The residue was washed
thoroughly with RO water, and air-dried. The residue was dried in a
vacuum oven overnight at 60% and its yield was determined. It was then
analyzes for lignin content, and its 0.5% cupriethylenediamine (CED)
viscosity was determined. Because the residue was not completely
soluble in the CED solution, it was delignified using the chlorite
procedure given in the Experimental section.
Rosin and Rosin Derivatives
Rosin is a complex mixture of mainly resin acids and small amount of
non-acidic components. Its colour, depending on the source and method
of processing, can vary from a water white through dark red to almost
black, with a tinge of red. It is generally translucent and brittle at
room temperature. The other properties which are of importance in
judging the quality of rosin are acid value, saponification value,
softening point, and unsaponification value,. However, entire rosin is
sold and purchased on the colour basis, the lightest colour bring the
highest price. Opacity in rosin some times degrades its value,
Sometimes rosin is upgraded to get better market price.
Composition
Resin acids are monocarboxylic acid having typical molecular formula
C20H30O2. The structural formulas of all the known resin acid are shown
in Fig.1, which may be divided into abietic and primaric type. The
pimaric type resin acid differs from those of abietic type, in that
they have two alkyl groups in the C-7 position in the place of
isopropyl group. When double bond occurs in one of these alkyl groups,
it can not conjugate with a cyclic double bond. Consequently the double
bonds in pimaric and isopimaric acid are not conjugated and so not
very reactive.
Reaction and derivatives
The resin acid molecule possesses two chemically reactive centers, the
double bonds and the carboxyl gorup. Through these, many modifications
in structure and numerous derivatives are obtainable. Abietic acid is
customatily and conveniently used to exemplify the structural and
chemical reaction products c, constitute the bulk of commercial
products. Although the molecular weight of pure acid is 303, for rosin,
the value is usually taken as 340 due to the presence of neutal for
calculation in involving carboxyl group.
Isomerization
Pure resin acids of the abietic type are isomerized thermally or by
treatment with dilute mineral acids. The equilibrium mixture from the
mineral acid isomerization of levopimaric acid was 4% palustire, 93%
abietic and 3% meoabietic. The equilibrium mixture of a thermally
isomerized levopimaric acid was 13% palustric acid, 80% abietic acid
and 7% meobietic acid. Methyl abietate isomerised to give the same
equilibrium distribution as abietic acid. A major difference between
the two was an extensive disproportionation reaction that occurred with
the ester.
Photosensitized oxidation
An alcoholic solution of levopimaric acid containing a sensitizing dye,
e.g., methylens blue, readily absorbs one mole of oxygen, when
contacted with air, to produce quantitatively a peroxide,
8,12-peroxide-13,14 dihydroabietic acid, by 1-4 addition.
Hydrogenation
Hydrogenation is one of the more satisfactory methods for decreasing
the susceptibility of rosin to air oxidation. Because of the structural
features of the resin acids, however more vigorous conditions are
necessary than with ordinary olefins. Reduction with heavy metals and
mineral acids or which sodium amalgam and water, accomplishes only
incomplete hydrogenation, even for one double bond. On the other hand
molecular hydrogen, in the presence of noble metal catalysts, such as
palladium or platinum, will saturate one or both double bonds,
depending on the polarity of the solvent employes. By taking advantage
of solvent effect, the desired selectivity can be obtained with
palladium carbon catalyst.
Hydrogenless Hydrogenation
Resin acids can be hydrogenated by the transfer of hydrogen from sodium
formate in the presence of water and a palladium carbon catalyst. The
primary product are the dihydro derivatives Incorporation of a polar
solvent (Methyl tertiary butyl in the solvent increases the reaction
rate. Although methyl neoabierate hydrogenates faster than abictatc,
the initial rate of formation of the dihydro compounds is practically
the same, same isomerization to methyl abietate (maximumabout 25%) and
slight dehydrogenation to methyl dehydroabietate occur. The reaction
product distribution is essentially the same as for abietate: only
trace amounts of 13(15)-abietenate are produced.
Polymers of vinyl esters of hydrogenated rosin
Vinyl esters were prepared and homopolymerized in emulsion and
copolymerized with vinyl acetate, vinyl chloride, and butadiene and
thus compared to vinyl tetrahydroabietatc (VTA) and vinyl
dehydroabietate (VDA).
Prehydrogenation
One of the double bonds of rosin acid containing conjugated
unsaturation, such as abietic acid, and the exocyclic double bonds of
dextropimaric and isodextropimaric acids are easily reduced. The
endocyclic double bonds of dihydroabietic acid and pimaric acids are
more difficult to hydrogenate, but they can be reduced over a nickel
catalyst, under severe conditions. Dehydro abietic acid, which contains
a highly hindered aromatic ring, cannot be reduced at a practical rate
over conventional catalyst.
Dehydrogenation
The dehydrogenation reaction is the second means of effectively
modifying rosins to render them less susceptible to oxidation by
atmosphcric oxygen. Part of the hydrogen that is removed is readily
absorbed by the pimaric type acids, present in rosin, to produce the
stable dihydropimaric acid. Because of the absorption of a part of the
hydrogen, this reaction frequently has been described as a
disproportionation. However, the appearance of only 2-3% of
dihydroabietic type acids and the absence of tetrahydro abietic acid,
show that the disproportionation of the abietic type acid is not
involved.
Thus disproportionated rosin is chemically stable, thermoplastic resin,
by the loss of conjugation or aromatization of the molecule. This
treatment converts its total oxidation prone AA content to highly
stabilised forms of resin acids, predominantly dehydroabietic acid. As
a result this DPR has a much greater resistance to discoloration,
embrittlement, and other effects of oxidation then do pale grades of
ordinary rosin. This improved oxidation resistance, together with a
wide compatibility with polymeric thermoplastic and elastomeric
materials, makes DPR especially suitable as an ingredient of hot melt
applied adhesives and coatings for paper and paper boards substrates,
and as a tackifier and processing aid for rubber based adhesives and
molding compounds.
Polymerization
In any application only reduction in acid value of rosin does not
satisfy the performance requirements of coatings. Rosin (abietic acid)
possesses active conjugated dienoic unsaturation, which is very much
susceptible to oxidation by atmospheric oxygen. Thus, when exposed to
air, rosin and its derivatives undergo discolouration to develop
ultimately dark brown colour, On oxidation rosin becomes more brittle
and friable and changes its solubility characteristics. Enhanced
performance of rosin derivatives with their pale colour and good colour
retention properties is obtained by proper nuclear modifications of
rosin, such that the oxidation susceptible unsaturation in rosin is
reduced to a greater extent or completely eliminated by definite
chemical reactions such as polymerization.
Phenolic modification
The phenolic modified rosin is made by adding to the hot rosin either
the phenol formaldehyde condensate or the phenol and the formaldehyde
separately. The phenols commonly used are bis-phenol, phenol and
creasols. The phenolic modified rosins are usually further modified by
esterification with glycerol or pentaerythritol. The condensation
reaction is an addition reaction that takes place between the methylol
phenol and rosin or rosin esters. These esters are used in oil soluble
varnishes.
Salt formation
With unsaturated cyclic and acyclic hydrocarbons
Metal salts of the condensates of resin with unsaturated hydrocarbons,
which salts are particularly valuable for use in protective coatings
such as varnishes, having excellent bodying and drying characteristics
and forming harder films of improved water resistance.
Drier metal salts of this rosin-butadiene condensates were pepared by
heating the condensate to 235°C and then gradually adding, with
intermittent stirring, during a period of about 40 minutes, the metal
salt, while simultaneously increasing the temperature to about 320 °C.
The hot, highly viscous resins was then cooled to room temperature and
analysed.
With pentaerythritol and other polyhydric alcohols
Glycols and diethylene glycols are also used to prepare esters by
heating rosin at 20-260oC in the presence of zinc, or boric acid
catalyst. The unreacted alcohol is removed from the ester at 300oC
under reduced pressure. One of the glycol ester is prepared by the
reaction with rosin, diglycol and acetic acid. The PVC sandals made
from these esters can fully meet the international specifications.
Hydrogenolysis
Rosin has been successfully hydrogenated to produce the hydroabietyl
alcohol of commerce. The alcohol may be produced by the hydrogenation
of the methyl esters of rosin at 300oC and 5000 psi, in the presence of
copper chromite catalyst. With soluble film formers, such as casein and
zein, the alcohol is used to impart improved tack, colour and
stability. Hydro abietyl alcohol produces esters with a wide range of
physical properties, when reacted with organic and inorganic acids.
Polyesterification
Unsaturated polyester modified rosin (UPER) are prepared by reacting
first with dibasic acid glycol, maleic anhydride and then with rosin.
The mechanical and physical properties of the castings, prepared by
copolymerization with styrene are good to excellent when compared with
accepted values of commercial styrenated polyester cast resins. Foams
prepared from these polyesters shows promising use in garments as a
fabric-foam laminated. This has been due to their ability to be flame
taminated directly to the fabric without the use of an adhesive.
Copolyesters
(Copolyesterification) copolysters belongs to broad class of organic
high molecular weight compounds, which are formed by repeated
esterification reaction. They constitute one of the most important
class of plastic material. The great scope lies in the powder coatings,
solventless convertible coatings, aqueous coatings etc. The film
properties of these polysters have high dimensional stability against
change in temperature.
Ammonolysis
The action of ammonia on dehydrogenated rosin at elevated temperatures,
yields a nitrile. It is a pale yellow, waxy solid with softening points
about 65o C, containing 85-95% of nitrile from which the nitrile of
dehydroabietic acid can be crystallized with mp 87-90oC. It is used in
the production of Amine D, by catalytic hydrogenation at elevated
temperature and pressure. The amine is relatively weak base that forms
salts with both mineral and organic acids, at room temperature, in
suitable solvents or at elevated temperature.
Preparations
Dehydroabietylamine acetate
To a solution of 2.85 kg. of Amine D dissolved in 4.71 lit. of toluene
was added a solution of 654 g. (10.8 mole) of glacial acetic acid in
1.56 lit. of toluene. The solution was stored at 10oC for 2 hour. The
crystalline salt was collected, washed with cold toluene and
recrystallized from 4.23 lit. of boiling toluene. The colourless
crystals were collected, washed several times with n-pentene and air
dried to obtain 1.365 kg. (78.5%).
Methods of preparation
Sulfuric acid catalyzed condensation of abietic acid with formaldehyde:
Abietic acid, 10 g. (0.033 mole) of formaldehyde (as paraformaldehyde)
were suspended in 50 ml. of purified dioxane. On addition of 3 g. of
conc. Sulfuric acid, the solution became homogeneous, and the
temperature rose spontaneously to 60oC. The darkened solution was
maintained at 60oC for 0.5 hr. On addition of 300 ml. of water, a cream
coloured precipitate was formed which was thoroughly washed with water
and dried in vacuum at 50oC.
Experiments similar to that above were run using 2,3 and 5 moles of
formaldehyde per mole of abietic acid. These products showed neutral
equivalent values of 357,394, and 419, respectively. The product from
condensation of abietic acid with 2 moles of formaldehyde showed no
maximum in the region 220-285 mµ.
Nitrogenous intermediates
The chlorosulphonyl isocyanate, acrylonitrile, fumaronitrile,
benzoquinone, tetracyano ethylene, and many dinitrile and diamine
adducts of levopimaric acid are reported here. Diamines and isocynates
from rosin have found many industrial applications, such as
polyurethane, ingredients for adhesives and corrosion inhibitors.
The Polymerizable Half Esters of Rosin
This commucation is concerned with the partial esters of the
polymerizable rosin adducts which have at least two carboxyl group.They
are some times referred to as half esters,but in at least one case a
trivalent acid is involved .Although they are quite well known, but
there is little information published in the literature to coordinate
their behaviour and properties.
The specific interest of the partial is that while maintaining acid
functionality a wide gradition of properties from hydrophilic to
hydrophobic can be obtained and also differential solubilities in
various solvents. These properties are transmitted to various
copolymers which may be formed from them, dependent on the amount of
partial ester included and the nature of the alcohol radical.
Experimental
All the chemical used are of comical type.
Preparation and properties of monomers
The simplest method of preparing the rosin ester is by reacting a
stoichiometric quantity of the requisite alcohol with an adduct being
by far the most utilized in this respect. The general object is to
avoid simultaneous formation of the diester and free acid.
Maleic rosin esters: Maleic rosin is refluxed with absolute alcohols
until the conversion to monoester is complete. Rp increases rapidly
with temperature till 80OC and is constant to 120oC. Heating above 80oC
tends to cause diester formation. Phenol methyl isohexyl alcohol and
tert-butanol react slowly. The above experiment was carried out under
pressure. Purification of the H rosin esters may be effected by first
neutralizing the ester with sodium carbonate solution. In order to
remove diesters, the sodium salt is extracted with the solvent. At
25oC, esterificition to the half ester in acetone is extremely rapid.
Secondary alcohols fail to esterify. Preparations are as flows.
Polymerization &Copolymerization
General and non-aqueous: The dibasic do not, except under special and
rather drastic conditions, homopolymer, but they are normally
copolymerizable although with rather low reactivities. The anhydride
salt, especially maleic rosin,can be made to homopolymerize under
drastic condition, but they copolymerize very readily with a strong
tendency to alternate, e.g., with vinyl acetate or styrene.The diesters
of the dibasic adducts copolymerize readily with vinly esters,e.g.,
vinly acetate, but the reactivity ratios are somewhat unfavourable for
monomers such as styrene.
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