JP2008307688A - Plastic corrugated cardboard and its disposal system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To inexpensively provide a plastic corrugated cardboard which has antistatic function, and also can preserve the global environment. <P>SOLUTION: The plastic corrugated cardboard, which is a sheet material made of a resin and has a hollow structure, comprises: a resin main component; and at least starch of 25 to 70 wt.% compounded in the resin main component. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a plastic corrugated cardboard that is a resin plate and has a hollow structure, and relates to a technology that considers the preservation of the global environment from production to disposal.

Plastic corrugated cardboard (hereinafter referred to as “plastic corrugated board”) has features such as light weight, water resistance, and durability, and many uses have been proposed to replace conventional paper cardboard. In particular, the use as a returnable box in which this plastic stage is formed into a box shape and repeatedly used in logistics is widely put into practical use as it contributes to cost reduction and is environmentally friendly.
On the other hand, the problem of easy charging, which is one of the disadvantages of the plastic stage, has been solved by adding conductivity by adding carbon particles or the like. Such a container with antistatic is used as a returnable box for distributing electronic parts and the like that are resistant to dust and static electricity (for example, Patent Document 1).

JP 2000-289133 A (paragraphs 0010 to 0013)

  By the way, even if it is said that the durability is excellent, the plastic stage is a consumable material because the number of times of repeated use is generally limited to several to several tens of times. For this reason, plastic stages that have passed a certain number of times of use (period) are discarded in a short period without being stocked. Conventional methods for disposing of such plastic stages include (1) a method of melting and reusing a resin material, (2) a method of incineration, and (3) a method of landfilling.

  However, with regard to the melting reuse in (1), in the plastic stage where a low-priced resin material is originally used, the cost for the recovery and the melting treatment becomes a cost increase factor and is not realistic. The incineration method (2) is inappropriate from the viewpoint of global environmental conservation because it emits a large amount of carbon dioxide. Regarding the landfill method of (3), since the resin main component that constitutes the plastic stage is difficult to be decomposed by microorganisms, if a large quantity of plastic stage is circulated and discarded in large quantities, the landfill disposal site will be opened for a short period of time. There is a problem of saturating.

On the other hand, in addition to the above-mentioned problems, the plastic stage having an antistatic function is limited in coloring to black or a similar color inherent to the added carbon particles, so that a multistage plastic stage with an antistatic function is produced. There are problems that are technically difficult to do.
Furthermore, it is inevitable that forming the plastic stage by uniformly dispersing the carbon particles in the resin main component will cause a significant cost increase.

  An object of the present invention is to solve the above-described problems, and to provide a plastic corrugated cardboard that contributes to the preservation of the global environment and has an antistatic function at low cost.

In order to solve the above-mentioned problems, the present invention is characterized in that starch is blended in the plastic corrugated board as a filler with respect to the resin main ingredient.
As the invention is configured as described above, the starch starch as a filler is a compound synthesized by absorbing carbon dioxide in the atmosphere by photosynthesis of plants. It can be fixed on the ground.
As a result, the plastic stage can be contributed to the reduction of carbon dioxide emissions through repeated production and consumption. Furthermore, the amount of the resin main ingredient manufactured from fossil fuel can also be reduced. Moreover, an antistatic function is added to the plastic stage by containing starch in the resin main component.
Furthermore, since the plastic stage containing starch is easily decomposed by soil microorganisms, the landfill site is not saturated. For this reason, the system which collect | recovers a used plastic stage in a set-up landfill site, landfills there, and disposes of plastic cardboard can be operated semipermanently.

Furthermore, the plastic corrugated board of the present invention is characterized by containing 25 to 70% by weight of the starch.
As the invention is configured in this way, starch forms a dispersed phase with the resin main component as a matrix. As a result, the structure composed of the resin main component is generally superior in mechanical properties to the structure composed of starch, and the continuous structure of the resin main component supports the external force applied to the plastic stage. . Thereby, the mechanical strength of the plastic stage is maintained. Furthermore, even when the used plastic stage is incinerated, the starch component is carbonized and taken into the residue of the incinerator, so that carbon dioxide discharged into the atmosphere can be greatly suppressed.

Furthermore, in the plastic corrugated cardboard of the present invention, the compounded starch is a plant containing this starch as a component, heat-kneaded with the inherently contained moisture or appropriately added moisture, and the resin main ingredient, and dispersed. It is characterized by being.
Thus constituted, the starch contained in the plant is gelatinized by reacting with moisture during heating and kneading and finely mixed with the molten resin main ingredient. Thereby, the plastic stage formed by applying a general resin molding method can obtain a structure in which the dispersed phase of starch is finely and uniformly dispersed at the molecular chain level in the matrix of the resin main component.
Thereby, even when the used plastic stage is landfilled in the soil, the decomposition rate by the microorganisms is increased, and therefore, the interval between repeated landfills in the same landfill disposal site can be shortened.

Furthermore, the plastic corrugated board of the present invention is characterized in that a saturated carboxylic acid, an unsaturated carboxylic acid or a derivative thereof is further blended as a compatibilizing agent for improving the affinity between the resin main ingredient and the starch.
As the invention is configured in this way, the affinity between the resin main agent and starch is improved by the presence of the compatibilizing agent, and the dispersed phase of starch is further refined to obtain a dense plastic stage structure. . Thereby, the mechanical properties of the plastic stage are improved, and the water resistance and chemical resistance are also improved.

Furthermore, in the plastic corrugated cardboard of the present invention, the starch is derived from rice.
By configuring the invention in this way, it is possible to effectively use surplus rice produced for food and to use a high-quality and high-quality starch raw material at low cost.

  According to the present invention, a plastic cardboard having an antistatic function is provided at a low cost. Furthermore, if the plastic corrugated cardboard disposal system of the present invention is established, the function of fixing atmospheric carbon dioxide recovered by plant photosynthesis to the soil will be demonstrated, reducing the carbon dioxide gas concentration in the atmosphere and reducing the global environment. Conserve.

FIG. 1 is an external view showing an embodiment of a plastic cardboard (hereinafter simply referred to as “plastic cardboard”) according to the present invention.
As represented by the figure, the plastic stage is a plate-like body configured by supporting a pair of thin plates arranged in parallel at a predetermined interval at both ends of a plurality of partitions. The plastic stage configured in this way receives the stress applied in the deflection direction in the direction in which the thin plate is pulled and the direction in which the partition is refracted, and the rigidity is ensured, and the section defined by the partition is hollow. The light weight and heat insulation are ensured.
The cross-sectional shape of the plastic stage is not limited to that shown in the figure, and includes, for example, the case where the cross section of the cavity is sinusoidal or sawtooth.

  The plastic stage having such a structure is generally formed by extrusion molding in which a thermoplastic resin heated and melted is passed through a die having a through-hole having the same shape as the cross section and cooled and solidified. However, the method for forming the plastic stage according to the present invention is not particularly limited, and the pair of thin plates and the partition are separately formed, and the both are bonded in separate steps. In some cases.

  In addition, such a plastic stage is used for a box that is assembled into a box (returnable) using its remarkable properties such as water resistance (chemical), abrasion resistance, corrosion resistance, light weight, and ease of processing. Boxes, storage boxes), signboards for posters, packaging materials / buffer materials for articles, curing sheets used in civil engineering / architecture / agriculture, soundproof sheets, heat insulation sheets, and the like.

The plastic stage of the present invention is composed of a starch-resin composite material obtained by blending starch with a thermoplastic resin main ingredient.
As such a resin main component, any general-purpose thermoplastic resin that can be extruded can be applied, and polypropylene is preferred, and mechanical strength is required. In this case, polycarbonate is preferable.

  On the other hand, if the resin main component is biodegradable, such as polylactic acid (PLA), polybutylene succinate (PBS), polycaprolactone (PCL), the rate of reduction to the soil is improved and environmental conservation is achieved. From the viewpoint of In addition, environmental protection can be achieved by using polyolefin resin to which additives that impart biodegradability such as Tegranobon (trade name) and Macrotech Research (USA) ECM Masterbatch (trade name) are used. It is preferable from the viewpoint.

The starch compounded in the plastic stage is a carbohydrate (polysaccharide) represented by the molecular formula (C ₆ H ₁₀ O ₅ ) _n , and is a natural polymer in which a number of α-glucose molecules are polymerized by glycosidic bonds. . This starch is structurally classified into linear amylose having a relatively small molecular weight and amylopectin having many branches and a relatively large molecular weight.

  Plants that are the raw materials for this starch include potato, wheat, corn, sweet potato, rice, cassava, kuzu, kataguri and mung beans. Then, these roots, stems, and seeds are subjected to simple treatments such as removal or cutting of the epidermis so as not to greatly increase the production cost, and are applied as raw materials for the plastic composite material. If there is no problem from the viewpoint of production cost, an extracted starch extracted from these plants may be used.

  Starch does not dissolve even when added to water in its natural crystalline state (called β-starch), but only suspends when heated, and β-starch crystals dissolve when heated further, and the solution becomes transparent and has a viscosity. It develops an increasing gelatinization reaction. This is because when water molecules enter the gaps in the molecular chain of β-starch, the hydrogen bond is broken, and the molecular chain of starch can move freely by itself (this state is called α-starch). . Further, such a unique property of α-starch is remarkable in amylose which is linear and has a small molecular weight.

  Further, starch has an inherent property that it is difficult to be charged, as is apparent from the fact that it contains water molecules in an integral multiple in the molecular formula described above. As a result, the plastic stage made of a composite material in which starch is filled in a resin base material that is easily charged becomes easy to transfer electrons and has an antistatic function.

The starch applied in the present invention is desirably derived from rice.
The first reason is that rice is suitable because it contains high-quality amylose in a high quality in a state where its outer shell (chaff, husk) has been removed, and can be obtained at a lower cost. Is mentioned.
The second reason is that rice as a plant produces a large amount of carbohydrates (starch) as harvested rice and a large amount of woody components (cellulose, hemicellulose, lignin, etc.) as other parts (such as strawberries and strawberries). Is generated in large quantities. Therefore, it can be said that the rice cultivation area has a very high ability to fix atmospheric carbon dioxide on the ground per unit area.
In other words, rice farming land contributes greatly to soil absorption in a certain carbon cycle that repeats atmospheric discharge of carbon dioxide (carbon) and soil absorption.
For this reason, establishing a means of consuming rice other than edible can greatly increase the rice production capacity and greatly contribute to the worldwide goal of reducing carbon dioxide emissions.

The starch blended in the plastic stage is desirably contained in the range of 25 to 70% by weight with respect to the total weight of the plastic stage, and particularly preferably occupies half or more of the total weight. .
When the amount of starch is less than 25% by weight, the rate of degradation by bacteria in the soil decreases when the used plastic stage is disposed of in landfill. Moreover, when the compounding quantity of starch is less than 25 weight%, when incinerating a used plastic stage, the ratio which burns and becomes a carbon dioxide will increase, and the component which carbonizes and remains will decrease. For this reason, the objective of preserving the global environment is not sufficiently achieved.
On the other hand, when the amount of starch is more than 70% by weight, the relationship between the resin main component and starch being the matrix phase and the dispersed phase, respectively, is reversed, and when the matrix composed of starch increases, There is a risk that the characteristics will deteriorate.
In addition, when the ratio of starch to the total weight of the plastic stage becomes more than half, the decomposition of the plastic stage in the soil proceeds rapidly.

  The resin main ingredient and starch are generally low in affinity because the former is hydrophobic and the latter is hydrophilic, and this also becomes an inhibiting factor in making the dispersed phase of starch fine and uniform. Therefore, it is desirable to add a compatibilizing agent that improves the affinity between the two at the interface. As a compatibilizing agent applied to the present invention, a saturated carboxylic acid, an unsaturated carboxylic acid or a derivative thereof is preferably applied.

  Examples of such saturated carboxylic acids include succinic anhydride, succinic acid, phthalic anhydride, phthalic acid, tetrahydrophthalic anhydride, and adipic anhydride. Examples of the unsaturated carboxylic acid include maleic acid, maleic anhydride, nadic anhydride, itaconic acid, itaconic anhydride, citraconic acid, citraconic anhydride, sorbic acid, acrylic acid and the like. As the derivative of the unsaturated carboxylic acid, a metal salt, amide, imide, ester or the like of the unsaturated carboxylic acid can be used. A suitable blending amount of the compatibilizing agent is obtained experimentally, and is suitably in the range of 0.2 to 20 parts by weight with respect to 100 parts by weight of the total amount of the resin main ingredient and starch. is there.

(Production method)
Next, regarding a method for easily and inexpensively producing a starch-resin composite material comprising such a matrix of the resin main component and a fine and uniform starch dispersed phase, polypropylene as a resin main component and starch as a raw material. A case where rice is employed will be described as an example.

  The production apparatus is not particularly limited as long as it can heat-knead polypropylene and rice at the melting temperature of the polypropylene. For example, a blender, kneader, mixing roll, Banbury mixer, uniaxial or biaxial An extruder etc. are mentioned.

  The case where an extruder is used will be described. Raw material polypropylene pellets, raw rice, and moisture are simultaneously directly introduced into the inlet of the extruder and heated and kneaded at a set temperature of 100 to 200 ° C. Then, raw starch β starch reacts with water to produce α starch. The produced α-starch is heated and kneaded to loosen the molecular chain and the surface thereof is chemically modified with a compatibilizing agent, and diffuses in the polypropylene melt. As a result, the affinity between polypropylene and starch is improved, and the refined starch is uniformly dispersed in the flowing polypropylene matrix.

And the water | moisture content contained in the mixed melt of the polypropylene-starch formed by heat-kneading with an extruder is discharged | emitted outside from the vent port provided downstream. Thus, after the dehydrated polypropylene-starch mixed melt is discharged from the exit of the extruder, the plastic melt is passed through a plastic forming die and cooled to room temperature, and a plastic stage is formed.
In addition, the plastic stage made of the polypropylene-starch composite thus obtained may be further subjected to a step of coating its surface with a resin layer for the purpose of modifying according to its use.

In addition, the mixed melt of polypropylene-starch discharged from the exit of the extruder may be once pelletized by a granulator, and the pellet may be remelted in another process and passed through a die to form a plastic stage. .
In addition, the moisture introduced from the inlet of the extruder is preliminarily absorbed by immersing the starch material in water if the starch material introduced together has a low water content like rice. In some cases, water may be poured separately from the faucet. On the other hand, there is a case where it is not necessary to add moisture to a potato such as a potato having a high specific water content.

  The plastic stage blended with the starch produced by the above-described production method has an antistatic function while its mechanical strength is almost equal to that of a normal plastic stage. Furthermore, various colors of antistatic containers can be prepared by blending pigments or dyes of various colors. Moreover, since the starch material that exhibits such an antistatic function can be purchased in large quantities at a low cost, a plastic stage with an antistatic function is provided at a low price.

(Plastic cardboard disposal system)
Next, a plastic stage disposal system in which used plastic stages are collected, landfilled, and decomposed in soil will be described.
In general, the resin main component constituting the plastic stage has a slow degradation rate due to underground bacteria even if it is buried in soil.
However, the plastic stage has an inherent characteristic that the specific surface area (surface area per unit volume) has a large shape as shown in the figure.
Furthermore, in the plastic stage composed of the matrix of the resin main ingredient and the dispersed phase of fine starch, first, the dispersed phase is preferentially decomposed into underground bacteria in a short period of time in the soil. Then, the plastic base resin part of the plastic stage will be further decomposed in the soil in a very short time because the surface area exposed to the attack of underground bacteria is further increased.

Thus, since the plastic stage of the present invention is decomposed in a very short time when buried in soil, it can be used semipermanently without saturating the landfill site. And since the plastic stage of this invention has the decomposition | disassembly speed | rate large because the structure | tissue of the starch dispersed phase is fine, when it burys repeatedly in the same landfill disposal site, the space | interval can be shortened.
Further, it is desirable that the used plastic stage to be landfilled is cut into a chip shape and reduced in volume by a known method as a pretreatment. Furthermore, it is desirable that this cutting is performed such that the partition portion is cut so that the pair of thin plates in FIG. 1 are separated and the partitioned hollow portion becomes the outer surface.

  If such a plastic corrugated cardboard disposal system is established, starch synthesized by absorbing carbon dioxide in the atmosphere by photosynthesis of plants will be used industrially as a plastic stage material and will be reduced to the soil after use. The As a result, if the use of the plastic stage of the present invention expands, it will be recovered, landfilled, established a plastic stage disposal system that decomposes in the soil, absorbs carbon dioxide in the atmosphere and fixes it to the soil, It can contribute to the preservation of the global environment.

1 is an external view showing an embodiment of a plastic corrugated cardboard according to the present invention.

Claims (8)

  A plastic cardboard comprising at least a resin main ingredient and 25 to 70% by weight of starch. The plastic corrugated cardboard according to claim 1,
The blended starch is characterized in that a plant containing this starch as a component is heat-kneaded and dispersed together with water inherently contained or appropriately added water and the resin main ingredient. Plastic cardboard. The plastic cardboard according to claim 1 or 2,
A plastic corrugated cardboard further comprising a saturated carboxylic acid, an unsaturated carboxylic acid or a derivative thereof as a compatibilizing agent for improving the affinity between the resin main ingredient and the starch. The plastic corrugated cardboard according to any one of claims 1 to 3,
A plastic corrugated cardboard characterized in that the starch is derived from rice. The plastic corrugated cardboard according to any one of claims 1 to 4,
A plastic corrugated cardboard characterized in that its outer surface is coated with a resin layer. The plastic corrugated cardboard according to any one of claims 1 to 5,
A plastic corrugated cardboard characterized in that the compounding ratio of the starch occupies more than half of the total weight.   An antistatic container made of the plastic corrugated cardboard according to any one of claims 1 to 6.   A plastic cardboard disposal system, wherein used plastic cardboard according to any one of claims 1 to 7 is collected, landfilled, and decomposed in soil.