RU2404048C2 - Method of producing plate composite material from lignocelluloses - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to treatment of vegetable lignocelluloses raw material to produce plate construction materials to be used in construction and furniture production. Vegetable lignocelluloses raw material with high content of lignin and hemicelluloses is treated for 15 s - 10 min by water steam at not over 1 MPa and 150-250°C. Treatment by water steam is instantly terminated. Said vegetable lignocelluloses raw material thus treated is mixed with untreated fibrous vegetable lignocelluloses raw material. Content of vegetable lignocelluloses raw material treated by water steam in produced mix makes 2-60 wt %. Produced mix is formed into mats. Water is extracted from said mats. Vegetable lignocelluloses raw material treated by water steam can be dried to moisture content of 5-10%. Resultant matter is mixed with untreated vegetable lignocelluloses raw material. Mats are produced from obtained mix and subjected to hot pressing. To produced solid plate material.

EFFECT: lower production costs.

5 cl, 3 ex

Description

The invention relates to technologies for processing lignocellulosic plant materials into composite materials, such as slab building materials, and can be used mainly in the construction and furniture industries.

The manufacturing processes of plate composite materials are divided into dry, wet-dry and wet. The dry process includes the dry formation of a fiberboard or mat and dry pressing, the wet-dry process includes the wet formation of a fiberboard or mat and dry pressing, the wet process includes the wet formation of fiberboard or mat and wet pressing.

In a typical dry process, cellulosic fibers are mainly mixed with resin, the resulting mixture is formed into a mat, which is then pressed to obtain a plate material. Cellulose fibers may be first coated with a thermosetting resinous binder, such as phenol-formaldehyde resin, and then randomly formed into a mat by means of an air blowing agent. The fibers, either before or after the formation of the mat, can be pre-dried in a dryer. The mat, typically having a moisture content lower than 30%, preferably lower than 10%, is pressed by heating and pressure to vulcanize the thermosetting resin and compress the material into an integral composite structure.

In a typical wet-dry process, the cellulosic fibrous material is mixed with a large amount of water, acidity - pH less than 7 or neutral, resulting in a suspension. The suspension is further mixed with the resin-connector and the resulting mixture is placed in the form of a mat in a permeable supporting element, where a large amount of water is removed by vacuum drainage and pressing rolls, to a moisture content of 40-60%. Further, water is removed from the mat by evaporation, for example using heat, to a moisture content of less than 10%. The dried mat then goes to the press and is pressed under the influence of pressure and temperature, forming a composite material from wood raw materials, which can be a flat plate or shaped product. The plate material may have a different desired shape, depending on its further use.

In a typical wet process, mainly the cellulosic filler or fibers are mixed with a large amount of water to form a suspension. The amount of water in such a suspension is not less than 90%, mainly 96-98.5%. The suspension is placed together with a synthetic filler resin, for example phenol formaldehyde, on a permeable element, for example a thin screen, where most of the water is removed. The raw mat has about 110% water relative to the dry material. Then the raw mat is pressed under pressure and dried in a dryer to form a composite material from wood raw materials.

Cellulose fibers are used in every process described and their source is wood chips, or other low-quality wood raw materials. Upon receipt of these fibers, wood chips are first crushed to particles of the same size by preliminary grinding, measuring, sieving or otherwise. Then the chips are cleaned and softened, for example, by thermal steam. The softened chips are then mechanically processed by grinding and separation, resulting in higher quality cellulosic fibers.

However, with the depletion of wood resources on the planet, products based on wood fibers are becoming more expensive. In connection with these circumstances, the task of reducing the cost of composite slab material by replacing the original wood raw material in the production of various composite slabs with cheaper raw materials is extremely urgent.

So in the world there is an abundance of other plant raw materials: straw of cereal plants, cane stalks, rice and sunflower husks, etc., which relates to rapidly renewable resources, has a low cost relative to wood raw materials and is often a waste of food production, or agricultural waste . This raw material is very attractive for the production of materials where wood has traditionally been used.

For example, there is a known method for the production of cellulose fibers used for the production of fibrous plate materials from straw, including cutting straw into pieces 2-4 inches long, softening the straw by steam treatment at elevated pressure for 30 s-2 min, machining the softened straw to produce fibers suitable for the production of cellulose fiber boards [US Patent No. 5656129]. The straw used in this process may be straw of cereal crops. The method may include the step of wetting the straw with water before the softening step.

A known apparatus for dry forming pressed sheets from raw plant fibers, such as straw from cereal stems. The fibrous material is first dried to a moisture content of less than 15%, cleaned and destroyed to small fiber pieces of the same diameter. The dried and crushed material comes in the form of sheets through a conveyor to the compactor. A hammer periodically operates in the compactor, which compresses the fibrous material and directs it into the tunnel so that the fibrous material forms into a sheet of a certain length and width. After exiting the tunnel, the sheet enters the press, where heat and pressure are applied to its surface in order to increase the mechanical adhesion of individual fibers in the sheet [US Patent No. 4,451,322].

It is known to use straw in a dry process for manufacturing a slab composite material. In this process, chopped straw is mixed with artificial resin at no more than 10% of the straw component, since with more straw the slab material will have extremely low strength.

There is also a method of obtaining a composite material from rice husks and phenolic resins of a special composition for its binding [US Patent No. 3850677]. In accordance with this method, rice husk boards are made with 8 to 10% water-immiscible, caustic-free, thermoset phenol-formaldehyde resin and pre-treated rice husk. Pre-treatment is a significant operation, as a result of which the peel of the rice husk is destroyed into separate particles, loose-bound surface materials are removed and small particles are sorted out. However, the inclusion of fine-grained materials obtained during pre-treatment increases the consumption of resin, and hence the cost of the material, and increases the fragility of the plate.

As follows from the above data, the traditional manufacture of composite plate materials from lignocellulosic raw materials is based on the use of synthetic resins as binders. Plate materials, such as particle board, oriented particle board and medium density fiber board, contain synthetic resins for bonding fibers — phenol formaldehyde, urea formaldehyde and others — as a binder. These resins are expensive because they are obtained from petrochemicals. The cost of such a resin is up to 60% of the cost of raw materials in the manufacture of plate materials. Therefore, an important task is the creation of new technologies for the production of composite materials without the use of synthetic resins as binders.

For example, there is a method of manufacturing composite plate materials from sugar-containing lignocellulosic raw materials, mainly from annual herbaceous plants such as sugarcane pulp, cereal stems, sorghum, sunflower, flax, etc., without the addition of adhesive binders of artificial origin [Canadian Patent No. 400405]. In this method, water-soluble free sugars contained in the raw materials are chemically converted in situ by applying heat and pressure to them into an insoluble and refractory polymer substance acting as a binding agent and filler for composite materials, and provide good mechanical strength and dimensional stability. It is believed that free sugars, carbohydrates or saccharides and water-soluble materials are chemically converted into furfural and other derivatives and further into thermosetting material under the influence of heat and pressure during the hot molding operation. However, this method is applicable only to lignocellulosic raw materials containing free sugars, and is not suitable for lignocellulosic raw materials not containing free sugars, such as wood, cereal straw, rice husks, etc.

There is also known a method of producing composite materials from lignocellulosic raw materials, including grinding the raw materials, drying, forming into a mat and hot pressing, in which lignocellulosic pulverized raw materials that do not contain essentially free sugars are pre-treated with steam under pressure at 190-260 ° C to release hemicellulose for 15 s-10 min, sufficient for decomposition and hydrolysis of hemicellulose into free sugars, polysaccharides, dehydrated carbohydrates, furfural products, organic acids and other decomposition products, followed by conversion and thermosetting of free sugars, polysaccharides, dehydrated carbohydrates, furfural products, organic acids and other decomposition products of lignocellulosic raw materials into a polymeric substance that binds to lignocellulosic material with the formation of a modified composite product [RF Patent No. 2075384].

This method of obtaining composite materials from lignocellulosic raw materials is the closest analogue of the proposed and adopted as a prototype of the invention.

Its disadvantages include the low strength of the resulting plate, its fragility with bending efforts.

The invention solves the problem of creating such a method for producing composite materials from natural raw materials, which would make it possible to obtain durable plates capable of maintaining their integrity under bending loads.

The problem is solved in that a method for producing a composite slab material is proposed, including grinding vegetable lignocellulosic raw materials, treating them with steam at elevated pressure and forming into mats, in which vegetable lignocellulosic raw materials with a high content of lignin and hemicellulose are treated with water vapor at a pressure not exceeding 1 MPa and a temperature of 150-250 ° C for 15 s-10 min, and the aforementioned treatment with water vapor is immediately stopped, after which the steam-treated vegetable lignocellulosic raw materials are mixed with untreated steam of fibrous plant lignocellulosic raw materials so that the content of the first plant lignocellulosic raw materials in the resulting mixture is 20-60% of the mass, and the resulting mixture is formed into mats.

In the case of the manufacture of soft plate material after the formation of mats, water from them can be removed naturally - by swelling, or forcedly - by vacuum drainage, or by evaporation, or drying.

In the case of the manufacture of solid plate material, plant lignocellulosic raw materials are dried to 5-10% moisture after steam treatment, and the mats formed from the resulting mixture are subjected to high-temperature pressing.

As plant lignocellulosic raw materials with a high content of lignin and hemicellulose can be used, for example, chopped wood, or bark, or tree branches of predominantly coniferous species.

As a fibrous plant lignocellulosic raw material, fibrous in its structure, one can use, for example, reed stalks, or straw of cereal plants, or flax, or thin long chips along the wood fibers of coniferous or deciduous trees.

The first plant material is pre-crushed to a technologically acceptable size, if necessary. Also, the second plant material can, if necessary, be pre-crushed so that its fibrous structure is preserved.

As you know, any lignocellulosic feedstock includes three main components: cellulose, hemicellulose and lignin.

Cellulose is the main structural component of the cell walls of all plants and makes up about 40-60 wt.% Lignocellulosic raw materials. It is a crystalline substance - a linear polysaccharide of the general formula (C ₆ H ₁₀ O ₅ ) _n .

Low molecular weight non-cellulose polysaccharides are called hemicellulose, with the general formula (C ₅ H ₈ O ₄ ) _n1 (C ₆ H ₁₀ O ₅ ) _n2 bound in plant tissues with cellulose in lignocellulosic materials. Hemicellulose makes up about 20-35% of lignocellulosic raw materials and, as a rule, is an amorphous substance.

Lignin (from lat. Lignum - wood, wood) is a natural polymer that is part of almost all land plants and is second only to polysaccharides in prevalence among natural high-molar compounds. By the number of lignin, it takes the second place after cellulose in highly organized plants. For example, its content in coniferous and deciduous wood is 23-38 and 14-25 wt.%, Respectively. Lignin is located in the cell walls and intercellular space of plants, holding cellulose fibers together. Together with hemicellulose, it determines the mechanical strength of the trunks and stems. In addition, lignin reduces the permeability of cell walls to water.

The proposed method uses the natural properties of these components of plant materials. The method is as follows.

The first plant material with a high content of lignin and hemicellulose, for example wood chips from coniferous trees, which contains, as indicated above, a large amount of lignin and hemicellulose, is crushed to a homogeneous composition. Next, the crushed raw materials are placed in an autoclave and treated with steam at a pressure of up to 1 MPa and a temperature of 150-250 ° C for 15 s-10 minutes. At the end of this stage, the vapor pressure is sharply released, resulting in the release of lignin, which is a natural polymer, and hemicellulose, which undergoes decomposition and hydrolysis. Since hemicellulose is largely amorphous in nature, it has a high solubility in water. Thus, hemicellulose decomposes about 100 times faster than cellulose, and therefore, hemicellulose can be hydrolyzed selectively without destroying the cellulose. The general hydrolysis reaction is: (C ₅ H ₈ O ₄ ) _n1 (C ₆ H ₁₀ O ₅ ) _n2 + n ₁ (H ₂ O) + n ₂ (CH ₂ O _n1 ) C ₅ H ₁₀ O ₅ + n ₂ C ₆ H ₁₂ O ₆ , yielding 5- and 6-carbon sugars. These free sugars can be decomposed by the action of heat on furfural and other decomposition products, which can then be converted into a polymeric substance, which provides binding of lignocellulosic raw materials through, for example, the application of heat and pressure during the pressing operation.

Next, the processed first raw material is removed from the autoclave in a hot and wet state and mixed with the second plant lignocellulosic raw material - not treated with steam and fibrous, so that the content of the first plant raw material in the mixture is not less than 20 wt.% And not more than 60 wt.% . The second plant material may be, for example, straw, pre-crushed into pieces of a certain length, for example 5-20 mm

The resulting mixture is formed into mats, leveled and dried. Drying can be forced, for example, by a stream of hot air, or mats can form on a moisture-permeable surface through which water flows naturally, leaving the composite material, or using vacuum drainage. Polymeric substances in the plate, formed during hydrolysis and released during a sharp pressure relief, harden and fasten the fibers of the second plant material to each other.

The dried composite material is cut into slabs of the required size. The resulting plates belong to soft plate composite materials and are mainly intended for thermal insulation.

To obtain solid plate materials, the first plant material after steam treatment is dried to a moisture content of 5-10% and only then mixed with the second plant material. Next, the mixture is placed in mats and subjected to hot pressing in order to increase the mechanical adhesion of individual fibers in the plate with a polymer binder and to obtain a strong consolidated material.

Steam-treated lignocellulosic raw materials are the main source of free radicals for polymerization processes, which take place primarily on the basis of lignin, hemicellulose, and free sugars. Released lignin, as a natural polymer substance, is the main binding agent for the filler - the second plant material. The output of the binder from lignin is greater than from cellulose (13-14% versus 4-5% for cellulose under ordinary conditions).

Also, free sugars in lignocellulosic raw materials, soluble in water, are chemically converted by the action of temperature and pressure into an insoluble and refractory polymer substance that acts as a bonding agent to form a composite material with good mechanical strength and dimensional stability. As the first raw material, it is preferable to use raw materials with a high content of lignin and hemicellulose. Fibrous vegetable raw materials that have not been steamed, the second vegetable raw material, is the main material that provides strength characteristics, namely bending strength, tensile strength and hardness, as well as the geometric stability of the composite plate material.

It should be noted that the composite plate material obtained by the described method does not contain expensive artificial resins associated with petrochemistry and therefore environmentally unsafe. It is completely natural and environmentally friendly, which refers to its exceptional advantages in comparison with existing plate materials used in construction and furniture production. In addition, since in the production of plate material a significant part of the feedstock is not subjected to heat treatment under pressure, the energy consumption for its production is significantly reduced. Also, the plate material obtained by the described method has great bending strength, therefore it is preferable to use it in construction.

Since the processed lignocellulosic raw material is almost completely free of hemicellulose, the materials obtained by this method are much less hygroscopic and, therefore, have good dimensional stability.

Example 1

Pine chips are milled into fibers in two steps. The first grinding stage is performed on defibrators. In this case, a coarse wood pulp is obtained. The second stage of grinding is performed on refiners, where there is a more complete separation of the wood pulp into fibers and its alignment.

The ground wood raw material is placed in an autoclave and treated with high pressure steam at 250 ° C for 15 seconds and then the pressure is sharply released. The resulting pulp-like mass contains a high proportion of sugars, lignin and water-soluble substances. Wood raw materials are mixed with straw chopped into 6 mm long pieces, the amount of which is 40 wt.%, And mixed thoroughly. Next, a mat is formed using a casting machine as a result of successive carrying out the following operations: mass expiration to the forming mesh, free filtration of water through the mesh, and water suction using a vacuum installation. Next, the resulting plate is kept in air for 30 minutes. The resulting plate material has a flexural strength of 3.2 MPa.

Example 2

Pine chips are milled into fibers in two steps. The first grinding stage is performed on defibrators. In this case, a coarse wood pulp is obtained. The second stage of grinding is performed on refiners, where there is a more complete separation of the mass into fibers and its alignment.

The milled wood raw material is placed in an autoclave and treated with high pressure steam at 150 ° C for 70 seconds and then the pressure is sharply released. The resulting pulp-like mass contains a high proportion of sugars, lignin and water-soluble substances. After drying to 10% moisture, the wood raw material is mixed with straw chopped into pieces 2 mm long, the amount of which is 50 wt.%, And mixed thoroughly. Next, a mat is formed by placing the mixture on a forming mesh and subjected to hot pressing at 210 ° C and a pressure of 100 kg per square cm for 8 minutes. Next, the resulting plate is kept in air for 30 minutes. The resulting plate material has a bending strength of 3.3 MPa.

Example 3 (prototype)

Pine chips are milled into fibers in two steps. The first grinding stage is performed on defibrators. In this case, a coarse wood pulp is obtained. The second stage of grinding is performed on refiners, where there is a more complete separation of the mass into fibers and its alignment.

The milled wood raw material is placed in an autoclave and treated with high pressure steam at 150 ° C for 70 seconds and then the pressure is sharply released. The resulting pulp-like mass contains a high proportion of sugars, lignin and water-soluble substances. Next, a mat is formed by placing the mixture on a forming mesh, which is held in air for 30 minutes. The resulting plate material has a bending strength of 2.3 MPa.

Claims (5)

1. A method of producing a composite slab material, including grinding vegetable lignocellulosic raw materials, treating them with steam at elevated pressure and forming them into mats, characterized in that the plant lignocellulosic raw materials with a high content of lignin and hemicellulose are treated with steam for 15 s-10 min at a pressure not exceeding 1 MPa and a temperature of 150-250 ° C, moreover, the aforementioned treatment with water vapor is immediately stopped, after which the water-treated plant lignocellulosic raw materials mixed with untreated fibrous plant lignocellulosic raw materials so that the content of water-treated plant lignocellulosic raw materials in the resulting mixture was 20-60 wt.%, and the resulting mixture is formed into mats. 2. The method according to claim 1, characterized in that water is removed from the formed mats. 3. The method according to claim 1, characterized in that the steam-treated plant lignocellulosic raw materials are pre-dried to 5-10% moisture, and the mats formed from the resulting mixture are hot pressed. 4. The method according to claim 1, characterized in that as plant lignocellulosic raw materials with a high content of lignin and hemicellulose use: crushed wood, or tree bark, or tree branches. 5. The method according to claim 1, characterized in that as the fibrous plant lignocellulosic raw materials used are: reed stalks, or straw of cereal plants, or flax, or thin long wood shavings of trees.