KR101161156B1 - Powder composition including rice flour and aliphatic polyester and manufacturing method for naturally decomposing disposable tableware thereof - Google Patents

Abstract

PURPOSE: A powder composition and a portable or multi-time usable container are provided to improve biogradability, intensity, and to increase production yield by improving heterogeneity. CONSTITUTION: A powder composition comprises 11-27 wt% of aliphatic polyester, 4-13 wt% of emulsion consists of vegetable oil, rosin, sodium hydroxide, dimethylaniline, dodecylalcohol, and ethylene oxide, 3-15 wt% of natural plant binder, 57-72 wt% of cereal powder, 2-7 wt% of plasticizer, 3-16 wt% of builder, 2-10 wt% of coumarone, and 1-5 wt% of softening agent. The natural plant binder consists of one or more of (MDHEU)dimethyloldihydroxy ethylene urea resin, Arabic gum, gelatin, colloidal silica, natural rubber, glue, chitosan, shellac, calcium carbonate, and casein.

Description

Powder composition including rice flour and aliphatic polyester and manufacturing method for naturally decomposing disposable tableware including finely divided grain powder and biodegradable aliphatic polyester

The present invention relates to a finely divided powder composition for preparing a biodegradable disposable or multi-use container including micronized (nano-powdered) grain flour (rice, corn, wheat) and biodegradable aliphatic polyester, and a method for preparing a disposable or multi-use container using the same. The present invention relates to a fine powder composition comprising a fine powder powder (rice, corn, wheat) and a binder including a biodegradable aliphatic polyester, which is molded by a semi-sintering reaction under high temperature and high pressure to obtain structural compactness and The present invention relates to a disposable or multi-use container composition and a method of manufacturing a container using the same, which increases the strength and thus causes less swelling to increase durability due to swelling problems during manufacturing of the container and swelling during microwave cooking.

Traditionally, food containers include pottery, glassware, and metals. However, there is a disadvantage that these conventional food containers are not suitable as food containers that are increasing due to the increase of instant foods and outdoor events due to the change in the diet according to the increase of income level. In other words, glass and pottery of the conventional food container has a disadvantage that the breakage rate and the manufacturing process is difficult, and the metal material is heavy with a large manufacturing cost and is not suitable. For this reason, single-use or multi-use products manufactured using synthetic resins (polystyrene and the like), pulp, and the like are required and are used in mass production.

However, products using synthetic resins contain harmful ingredients to the human body, and there is a limit to their use as the main culprit of environmental pollution due to post-treatment problems caused by an increase in the amount used.

In other words, the paper products using pulp are mostly imported pulp, and the economic problems caused by imports, and the environmental damage caused by logging the forest where the trees that are pulp are grown to produce pulp as raw materials, There is a problem of environmental pollution due to the addition of additives to the production of paper products using pulp and the collection thereof. Of course, recycled pulp may be used instead of pulp, but secondary environmental pollution problems still occur due to treatment and disposal of energy for recycling waste pulp and additives for various regeneration processes.

On the other hand, in order to solve the structural problems of the pulp material, the surface is waterproof coated with vinyl, and the undecomposed materials used for such coating work are not decomposed naturally, so if they are simply buried on the ground, the soil is contaminated. As a major culprit of environmental pollution, which emits environmental pollutants such as dioxins when incinerated, they are subject to various environmental regulations and are restricted in their use.In recent years, the demand for low carbon greenness in production and disposal of corporate products has increased. For this reason, there are inconveniences such as the fact that businesses using such containers must be collected separately after use.

Due to these problems, natural or degradable disposable or multi-use containers have recently been actively produced. Hereinafter, it looks at the conventional natural decomposition container technology.

First, studies are being actively conducted to replace polystyrene with natural polymers obtained from grain starch or wheat flour and the skin of grain. In the example of using the powder of grains, the method of forming, freezing and coating the wheat flour, starch, baking powder and salt mixture dough (Korean Patent Publication No. 10-1994-0003477) and the starch and wheat flour of the grains, A method of aging, extruding, molding, and freeze-drying the mixed dough in purified water at a suitable temperature using fragrances and yeasts as auxiliary materials (Korean Patent Publication No. 10-1999-0047173).

In addition, look at the example using the epidermis of grains, a method of manufacturing by stirring, forming and coating the skin and starch, such as crushed rice, barley, crude, sorghum (Korean Patent Publication No. 10-2001-54666) There is a method of preparing by squeezing edible bridges and mixing them with a molding agent using the plant particles made by grinding various seedlings as a basic raw material (Korean Patent Publication No. 10-2001-26593).

However, although the conventional food container products which are naturally decomposed as described above have a positive advantage that they can be naturally decomposed to prevent environmental pollution, they are heavy and fragile in terms of the food containers themselves, and are restricted in use due to shrinkage due to outside temperature. many.

Moreover, the conventional naturally decomposable disposable or multi-use container as described above has a structural aspect of the biodegradable container itself in actual container manufacture since the main point is to focus only on the biodegradable portion to overcome the environmental destruction problem of the conventional plastic disposable or multi-use container. There is a problem in that denseness or durability is weak and swelling may occur. In other words, due to component sound, the mold release property is poor, and the yield of the final container is poor, and the unit price is high. Also, after the container is filled with contents containing moisture in the container, there is no content when cooking in a microwave oven. Since there is a disadvantage that the site is not suitable as a cooking container due to swelling occurs, there is an urgent need for a disposable or multi-use container composition and a method for producing a container using the same that can solve the swelling problem and the releasability problem.

An object of the present invention for solving the above problems is to increase the structural density and strength of the disposable or multi-use container as well as finely divided grain powder (fine powder such as rice, corn, wheat) The container composition comprising a binder containing a biodegradable aliphatic polyester and the container composition are molded by a semi-sintering reaction under high temperature and high pressure using the container composition to solve the problem of swelling during container manufacturing and swelling during microwave cooking. The present invention provides a method for producing a disposable or multi-use container.

The present invention to achieve the object as described above and to perform the problem for eliminating the conventional defects of the aliphatic polyester 11 ~ 27wt%; 4 to 13 wt% of an emulsion consisting of vegetable oil, rosin, caustic soda, dimethylaniline, dotasil alcohol, and ethylene oxide of palm oil or palm kernel oil; 3-15 wt% natural plant binder consisting of at least one selected from dimethylol dihydroxy ethylene urea resin, arabic gum, gelatin, colloidal silica, natural rubber, glue, chitosan, shellac, calcium carbonate and casein; 57 ~ 72wt% of finely divided grain powder of more than 99% purity consisting of any one selected from rice, corn, wheat; 2 to 7 wt% of any one of plasticizers selected from animal and vegetable fatty acids, palmitic acid, stearic acid and oleic acid; 3 to 16 wt% Builder consisting of at least one selected from potato, sweet potato, soybean busy, glucoside, pectin, ligrin, and protein; Coumaron 2-10 wt%; It is achieved by providing a biodegradable finely divided powder composition comprising finely divided grain powder and biodegradable aliphatic polyester, characterized in that it is formulated with one or more softeners 1 ~ 5wt% selected from among bark, rice straw, chaff.

In a preferred embodiment of the present invention, the aliphatic polyester may be composed of at least one of unsaturated monoglycerol 3 to 7: ethylene oxide 2 to 5: oleic acid, castor fatty acid, stearic fatty acid in a weight ratio of 0.1 to 1.5. .

The present invention is a preferred embodiment, the emulsion is vegetable oil (palm oil or palm kernel oil) 56 ~ 64wt% rosin 1 ~ 3 wt%, caustic soda 1 ~ 3 wt%, dimethylaniline 1 ~ 3 wt%, dotasil alcohol It may be composed of 20 to 40wt% and 1 to 15wt% of ethylene oxide.

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In a preferred embodiment of the present invention, the finely divided grain powder may be finely divided powder not larger than 0.074 mm.

In another aspect, the present invention,

a) condensing ethylene oxide with unsaturated monoglycerol and then mixing any one or more of oleic acid, castor fatty acid, stearic acid, the mixing ratio of the unsaturated monoglycerol 3 ~ 7: ethylene oxide 2 ~ 5: oleic acid, Mixing at least one of castor fatty acid and stearic acid to 0.1 to 1.5 to produce an aliphatic polyester;

b) Compound produced by contact reduction by adding 1 to 3 wt% of caustic soda and 1 to 3 wt% of dimethylaniline to 56 to 64 wt% of vegetable oil of palm oil or palm kernel oil and 1 to 3 wt% of rosin Preparing an emulsion by adding 20 to 40 wt% of silalcohol to an autoclave and adding 1 to 15 wt% of ethylene oxide while heating;

c) 11-27 wt% aliphatic polyester; 4 to 13 wt% of an emulsion consisting of vegetable oil, rosin, caustic soda, dimethylaniline, dotasil alcohol, and ethylene oxide of palm oil or palm kernel oil; 3-15 wt% natural plant binder consisting of at least one selected from dimethylol dihydroxy ethylene urea resin, arabic gum, gelatin, colloidal silica, natural rubber, glue, chitosan, shellac, calcium carbonate and casein; 57 ~ 72wt% of finely divided grain powder of more than 99% purity consisting of any one selected from rice, corn, wheat; 2 to 7 wt% of any one of plasticizers selected from animal and vegetable fatty acids, palmitic acid, stearic acid and oleic acid; 3 to 16 wt% Builder consisting of at least one selected from potato, sweet potato, soybean busy, glucoside, pectin, ligrin, and protein; Coumaron 2-10 wt%; 1 to 5 wt% of one or more softeners selected from among bark, rice straw and rice hulls; and blending them in an autoclave to produce a composition;

d) powdered composition of step c) into a mold having a shape and size required, and then pressurized with a press to form a porcelain; and finely divided grain powder and biodegradable aliphatic poly It can be achieved by providing a method for producing a disposable or multi-use container using a naturally degradable powdered powder composition comprising an ester.

In a preferred embodiment of the present invention, the step a) is carried out while precipitating the mixed unsaturated monoglycerol, ethylene oxide, oleic acid, castor fatty acid, stearic acid at 80 to 150 rpm for 8 to 10 hours at 90 to 110 ℃. It may be a step of preparing an aliphatic polyester.

The present invention is a preferred embodiment, the step b) is an emulsion of heating the vegetable oil, rosin, caustic soda, dimethylaniline, dotasil alcohol, ethylene oxide of any of the mixed palm oil or palm kernel oil to 140 ℃ in an autoclave It may be a step of preparing.

In a preferred embodiment of the present invention, the step c) is a mixture of aliphatic polyester, emulsion, natural vegetable binder, finely divided grain, plasticizer, builder, coumaron, softener at 90-130 ° C. in an autoclave. Precipitating while mixing at a temperature and stirring speed of 80 ~ 150 rpm to form a fine powder, and then quenched and dried to prepare a powdered powder composition.

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In a preferred embodiment of the present invention, the finely divided grain powder may be finely divided powder not larger than 0.074 mm.

The present invention is a preferred embodiment, the step d) is a step of putting the composition of step c) in a mold heated in a high temperature (120 ~ 160 ℃) in a high pressure (pressure of 7 to 15 tons per 1g of raw material) Bonding in a sintered state may be a step of forming a ceramic by molding.

According to a preferred embodiment of the present invention, after step d), e) a polysiloxane coating step for water resistance reinforcement of the ceramic container may be further included.

As described above, the present invention has a fine powder composition comprising a fine powder of finely divided grains (rice, corn, wheat, etc.) and a binder including a biodegradable aliphatic polyester, so that the biodegradability of the container as well as structural density and strength Increases the durability of the container,

In addition, the container composition having such an advantage is excellent in mold release property during molding by quasi-sintering reaction under high temperature and high pressure, and thus the production cost is high and the production cost can be lowered.

In addition, it is a useful invention having the advantage that a stable cooking is possible by producing less swelling during microwave cooking of the manufactured container is an invention that is expected to be greatly used in the industry.

1 is a process chart showing a manufacturing sequence according to an embodiment of the present invention,
2a to 2g is an exemplary view showing a container manufactured according to an embodiment of the present invention,
3A to 3J are exemplary views showing biodegradation states for each period of a container manufactured according to one embodiment of the present invention.

Hereinafter, the configuration and the operation of the embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

Disposable or multi-use composition according to the invention is 11 to 27wt% aliphatic polyester; 4 to 13 wt% of an emulsion consisting of vegetable oil, rosin, caustic soda, dimethylaniline, dotasil alcohol, and ethylene oxide of palm oil or palm kernel oil; 3-15 wt% natural plant binder consisting of at least one selected from dimethylol dihydroxy ethylene urea resin, arabic gum, gelatin, colloidal silica, natural rubber, glue, chitosan, shellac, calcium carbonate and casein; 57 to 72 wt% of finely divided grain powder having a purity of 99% or more composed of any one selected from rice, corn and wheat; 2 to 7 wt% of any one of plasticizers selected from animal and vegetable fatty acids, palmitic acid, stearic acid and oleic acid; 3 to 16 wt% Builder consisting of at least one selected from potato, sweet potato, soybean busy, glucoside, pectin, ligrin, and protein; Coumaron 2-10 wt%; 1-5 wt% of any one or more softeners selected from among bark, rice straw and rice husk;

The aliphatic polyester is viscous to the binding and emulsion of cellulose, amino acids, amino resins, starch to improve the flowability at high temperature and at the same time increase the biodegradability, and also when combined with grain flour (rice, corn, wheat) structural density Due to the less swelling is less than 11wt% bonding force is lost, the deformation occurs when the microwave passes through the microwave. In addition, when more than 27% wt, the decay period is long and the biodegradation time is long.

In addition, the composition of the aliphatic polyester of the present invention is at least one of unsaturated monoglycerol 3-7: ethylene oxide 2-5: oleic acid, castor fatty acid, stearic fatty acid 0.1 to 1.5 by weight ratio. When the aliphatic polyester having such a composition is composed in the range of 11 to 27wt% in the disposable or multi-use composition, it is viscous to bond and emulsion of fibrin, amino acid, amino resin, and starch as described above, so that the flowability is high even at high temperature. It improves biodegradability and at the same time, it also reduces swelling due to its structural density when combined with grain powder (fine powders such as rice, corn, wheat, etc.).

The emulsion is a sizing agent that facilitates the flowability and high temperature and high pressure molding of the entire mixed composition. If the emulsion is less than 4 wt%, the emulsion is not well formed. If the emulsion is more than 13 wt%, a large amount of the autoclave is used. Sediment occurs. Such emulsions include latex emulsions, silicone emulsions, fluorine emulsions, rosin emulsions, wax emulsions, etc., which are excellent in water resistance and harmless to humans.

Particularly preferred emulsions used in the present invention include 56-64 wt% vegetable oil (palm oil or palm kernel oil), 1-3 wt% rosin, 1-3 wt% caustic soda, 1-3 wt% dimethylaniline, dodecyl alcohol 20 An emulsion composed of ˜40 wt% and ethylene oxide 1-15 wt% is used.

By providing an emulsion having such numerical conditions, the flowability of the whole composition and the high temperature and high pressure molding are easily acted as a sizing agent, so that the moldability is good and the durability is improved. do.

The natural plant-based binder is combined with the whole composition and at the same time to give biodegradability is less than 3wt% molding is not good, if more than 15wt% a large amount of precipitate is generated in the autoclave. Such natural binders include dimethylol dihydroxy ethylene urea resins, which have been gelatinized as described above. Any one or more selected from arabic gum, gelatin, colloidal silica, natural rubber, glue, chitosan, shellac, calcium carbonate and casein may be used.

Starch contained in a large amount of the finely divided grains (rice, corn, wheat) is well combined with aliphatic polyester to have structural compactness and low component noise to facilitate container molding. When the finely divided grain powder is less than 57wt%, there is a problem in binding force, and the price of pollution-free container becomes high due to the increase of other ingredients, and when it is more than 72wt%, it is difficult to mold due to poor releasability due to cracking and swelling of the container. Because.

The level of micronization of the grain flour is enough to pass through 200 mesh, i.e., less than 0.074 mm. This is because particles larger than this have a rough surface of the container during molding, and a phenomenon due to a semi-sintered state during molding is unlikely to occur. However, if too much micronization work is performed, it is difficult to form the powder form and there is a problem of blowing, so there is no need to continue to micronize more than 500 or 600 mesh.

The reason is that the finely divided grains (rice, corn, wheat) are physically bonded, i.e., semi-sintered, to the respective materials in a high temperature (120 to 160 ° C) high pressure (7 to 15 tons per gram of raw material). Because it is essential to pottery.

In addition, in the present invention, the reason for using the rice flour, in particular, is to make a pollution-free container by stably supplying old old rice (Korean government non-stocked rice, disposal after 5 years of stock disposal) at a low price, so that the price of the pollution-free container is higher than that of existing contaminated disposable containers. By supplying cheaply, it is possible to solve the failure of commercialization due to the high price of disposable container price, and it is a great help to the national interests as one stone that plays a role in the government's bend processing.

The plasticizer is a component that makes the composition and formability good by smoothly bonding the respective composition materials at high temperature and high pressure molding. At this time, if the plasticizer is less than 2wt%, the container molding is not soft, the flowability is poor, and if more than 7wt%, bubbles are generated. As such a plasticizer, animal and vegetable fatty acids, palmitic acid, stearic acid, oleic acid and the like may be used as described above.

The builder is to improve the adhesion, coating effect and miscibility if less than 3wt% polymerization and co-polymerization of each of the ingredients and polymer emulsion constituting the present invention is difficult, more than 16wt% copolymer is unstable and binding force As it falls, changes in concentration and interfacial tension occur.

Such builders include potatoes, sweet potatoes, Use at least one selected from soybean busy, glucoside, pectin, ligrin, and protein.

The Kumaron is for smoothly bonding the respective composition materials at high temperature and high pressure molding, and to increase the adhesive strength. When the Kumaron is less than 2wt%, the coomalon is insufficient to cope with heat at a high temperature (120 to 160 ° C).

The softener is less flexible than less than 1wt% in order to make the pollution-free container more flexible and not easily broken, and more than 5wt% causes structural problems. As the softener, at least one selected from among bark, rice straw, and chaff is used as described above.

Hereinafter, the manufacturing method of the present invention will be described.

First, the process for producing aliphatic polyester and emulsion constituting the composition of the present invention will be described.

1) aliphatic polyester manufacturing step (S100)

The aliphatic polyester according to the present invention is composed of 0.1 to 1.5 of any one or more of unsaturated monoglycerol 3-7: ethylene oxide 2-5: oleic acid, castor fatty acid, stearic fatty acid in weight ratio. According to the specific manufacturing method, condensation of ethylene oxide with unsaturated monoglycerol and mixed with one or more selected from oleic acid, castor fatty acid, stearic acid, and then heated to 90 ~ 110 ℃ while precipitating at 80 ~ 150 rpm for 8 to 10 hours Make aliphatic polyester.

The reason for limiting the ratio is that the composition of each aliphatic polyester is produced at the mixing ratio of 3-7: 2-5: 0.1-1.5, and the viscosity is good even at high temperature, biodegradability, In addition, when combined with grain flour (fine powders such as rice, corn, wheat, etc.), there is less swelling due to the structural compactness.

The reason for the temperature limitation at the time of mixing is that the fatty acids are not easily mixed when the temperature is lower than 90 ° C. and the fatty acids evaporate when the temperature is higher than 110 ° C.

This is because the time is less released if it is shorter than 8 hours, and becomes less viscous if it is longer than 10 hours.

In addition, the rotational speed is less than the rotational speed of less than 80 rpm because the precipitation effect is lowered and 150 rpm or more because it is sufficiently precipitated because it does not need to rotate any more quickly.

2) Emulsion manufacturing step (S200)

Compound produced by contact reduction by adding 56 ~ 64wt% of vegetable oil (palm oil or palm kernel oil), 1 ~ 3wt% of caustic soda, and 1 ~ 3wt% of dimethylaniline to 1 ~ 3wt% of rosin, and dotasil alcohol 20 ~ 40 wt% is placed in an autoclave and heated to 140 ° C. under reduced pressure to slowly add 1 to 15 wt% of ethylene oxide to form an emulsion.

In the above description, the interval values are described, but in a specific embodiment, the emulsion may be prepared after the composition so that the compounding ratio of each composition satisfies 100wt%.

3) powder composition manufacturing step (S300)

When the emulsion is prepared, 11 to 27 wt% of the prepared aliphatic polyester; 4 to 13 wt% of an emulsion consisting of vegetable oil, rosin, caustic soda, dimethylaniline, dotasil alcohol, and ethylene oxide of palm oil or palm kernel oil; 3-15 wt% natural plant binder consisting of at least one selected from dimethylol dihydroxy ethylene urea resin, arabic gum, gelatin, colloidal silica, natural rubber, glue, chitosan, shellac, calcium carbonate and casein; 57 ~ 72wt% of finely divided grain powder of more than 99% purity consisting of any one selected from rice, corn, wheat; 2 to 7 wt% of any one of plasticizers selected from animal and vegetable fatty acids, palmitic acid, stearic acid and oleic acid; 3 to 16 wt% Builder consisting of at least one selected from potato, sweet potato, soybean busy, glucoside, pectin, ligrin, and protein; Coumaron 2-10 wt%; One or more softeners selected from among bark, rice straw and rice hulls are mixed in a range of 1 to 5 wt%, and then precipitated while mixing at an autoclave at a temperature of 90 to 130 ° C. and a stirring speed of 80 to 150 rpm to make fine powder. Then, by quenching and drying to prepare a composition of the present invention through a powder machine.

4) container molding step (S400)

The powdered composition of the present invention was put into a mold molded into a shape and size required, and then heated to a high temperature (120 to 160 ° C.) to a physical bond with each material in a high pressure (7 to 15 ton per 1 g of raw material) environment. In combination with the semi-sintered state, it is ceramicized and molded.

That is, the raw material supplied from the main raw material hopper to the heated mold and mixed in the mixer is supplied to the feeder. The number of molds can be increased to produce several at the same time as needed.

The reason for limiting the temperature and pressure is that there is a problem that the molding is not lower than the numerical value, and if it is higher than the numerical value, there is a problem that it is baked because it is made of natural ingredients to limit the numerical value.

The total compression time in the press should be within 1 minute.

5) Polysiloxane Coating Step (S500)

In addition, the present invention may further be coated on the surface of the container polysiloxane (poly siloxane) for the water resistance reinforcement of the pottery container through the container forming step. Such coating further increases the water resistance of the present invention, thereby increasing the functionality as a multi-use container. In addition, polysiloxane also has a high degree of natural decomposition does not lower the biodegradability according to the composition of the present invention.

At this time, the coating method is freely performed in various ways. For example, it may be coated with a thin film using a laminating coating method. Of course, the polysiloxane can be coated using other known coating methods.

Figures 2a to 2g is an illustration showing a container manufactured according to an embodiment of the present invention, showing the various forms of the container according to the composition and the manufacturing method according to the present invention. The illustrated vessels are containers prepared through the steps according to the present invention described above, and swelling does not occur well even in a portion not containing moisture during cooking in a microwave oven.

3A to 3J are exemplary views showing biodegradation states for each period of a container manufactured according to one embodiment of the present invention. Figure 3a shows the type of container used for landfill, Figure 3 shows that it is buried underground, then two weeks after landfill (see Figure 3c), four weeks (see Figure 3d), six weeks (see Figure 3e) Figure 8 shows the state removed from the landfill after 8 weeks (see Figure 3f), 10 weeks (see Figure 3g), 12 weeks (see Figure 3h), 14 weeks (see Figure 3i), 18 weeks (see Figure 3j). to be. As shown, the degree of natural decomposition after landfilling of the containers manufactured according to the present invention shows that the shape of the container is almost lost by microorganisms such as bacteria when it is left in natural state for 14 weeks or more, and the container is buried when about 18 weeks. When external force is applied to it, it is broken and almost completely decomposed, so it can be seen that biodegradability is high.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

Claims (14)

Aliphatic polyester 11-27 wt%;
4 to 13 wt% of an emulsion consisting of vegetable oil, rosin, caustic soda, dimethylaniline, dotasil alcohol, and ethylene oxide of palm oil or palm kernel oil;
3-15 wt% natural plant binder consisting of at least one selected from dimethylol dihydroxy ethylene urea resin, arabic gum, gelatin, colloidal silica, natural rubber, glue, chitosan, shellac, calcium carbonate and casein;
57 to 72 wt% of finely divided grain powder having a purity of 99% or more composed of any one selected from rice, corn and wheat;
2 to 7 wt% of any one of plasticizers selected from animal and vegetable fatty acids, palmitic acid, stearic acid and oleic acid;
3 to 16 wt% Builder consisting of at least one selected from potato, sweet potato, soybean busy, glucoside, pectin, ligrin, and protein;
Coumaron 2-10 wt%;
1-5 wt% of one or more softeners selected from among bark, rice straw and rice hulls; natural degradable powder composition comprising finely divided grain powder and biodegradable aliphatic polyester, characterized in that the composition is formulated.
The method according to claim 1,
The aliphatic polyester is undifferentiated grain flour and biodegradation, characterized in that at least one of unsaturated monoglycerol 3 to 7: ethylene oxide 2 to 5: oleic acid, castor fatty acid, stearic fatty acid is 0.1 to 1.5 by weight ratio A naturally degradable powder composition comprising a sex aliphatic polyester.
The method according to claim 1,
The emulsion may contain 56 to 64 wt% of vegetable oil of palm oil or palm kernel oil, 1 to 3 wt% of rosin, 1 to 3 wt% of caustic soda, 1 to 3 wt% of dimethylaniline, and 20 to 40 wt% of dodecyl alcohol. , Naturally degradable powder composition comprising finely divided grain powder and biodegradable aliphatic polyester, characterized in that it is composed of 1 to 15wt% ethylene oxide.
delete delete The method according to claim 1,
The finely divided grain powder is a micronized powder composition comprising micronized grain powder and biodegradable aliphatic polyester, characterized in that the finely divided powder not greater than 0.074mm.
a) condensing ethylene oxide with unsaturated monoglycerol and then mixing any one or more of oleic acid, castor fatty acid, stearic acid, the mixing ratio of the unsaturated monoglycerol 3 ~ 7: ethylene oxide 2 ~ 5: oleic acid, Mixing at least one of castor fatty acid and stearic acid with 0.1 to 1.5 to produce an aliphatic polyester;
b) Compound produced by contact reduction by adding 1 to 3 wt% of caustic soda and 1 to 3 wt% of dimethylaniline to 56 to 64 wt% of vegetable oil of palm oil or palm kernel oil and 1 to 3 wt% of rosin Preparing an emulsion by adding 20 to 40 wt% of silalcohol to an autoclave and adding 1 to 15 wt% of ethylene oxide while heating;
c) 11-27 wt% aliphatic polyester; 4 to 13 wt% of an emulsion consisting of vegetable oil, rosin, caustic soda, dimethylaniline, dotasil alcohol, and ethylene oxide of palm oil or palm kernel oil; 3-15 wt% natural plant binder consisting of at least one selected from dimethylol dihydroxy ethylene urea resin, arabic gum, gelatin, colloidal silica, natural rubber, glue, chitosan, shellac, calcium carbonate and casein; 57 ~ 72wt% of finely divided grain powder of more than 99% purity consisting of any one selected from rice, corn, wheat; 2 to 7 wt% of any one of plasticizers selected from animal and vegetable fatty acids, palmitic acid, stearic acid and oleic acid; 3 to 16 wt% Builder consisting of at least one selected from potato, sweet potato, soybean busy, glucoside, pectin, ligrin, and protein; Coumaron 2-10 wt%; Preparing a composition by mixing the mixture in an autoclave in a range of 1 to 5 wt% of at least one softener selected from mulberry bark, rice straw, and chaff;
d) powdered composition of step c) into a mold having a shape and size required, and then pressurized with a press to form a porcelain; and finely divided grain powder and biodegradable aliphatic poly Disposable or multi-use container manufacturing method using a natural decomposition powder composition comprising an ester.
The method of claim 7,
Step a) is a step of preparing an aliphatic polyester by heating the mixed unsaturated monoglycerol, ethylene oxide, oleic acid, castor fatty acid, stear fatty acid while precipitating at 80 ~ 150 rpm for 8 to 10 hours at 90 ~ 110 ℃ Method for producing a disposable or multi-use container using a naturally-degradable fine powder composition comprising finely divided grain powder and biodegradable aliphatic polyester.
The method of claim 7,
Step b) is a step of preparing an emulsion while heating the vegetable oil, rosin, caustic soda, dimethylaniline, dotasil alcohol, ethylene oxide of the mixed palm oil or palm kernel oil at 140 ℃ in an autoclave Method for producing a disposable or multi-use container using a naturally decomposed fine powder composition comprising finely divided grain powder and biodegradable aliphatic polyester.
The method of claim 7,
Step c) is a mixture of aliphatic polyester, emulsion, natural vegetable binder, finely divided grain, plasticizer, builder, coumaron, softener in the autoclave at a temperature of 90 ~ 130 ℃ and 80 ~ 150 rpm stirring Precipitating while mixing at a rate to form a fine powder, and then quenched and dried to prepare a powdered composition using a naturally decomposed fine powder composition comprising finely divided grain powder and biodegradable aliphatic polyester Method of making disposable or multi-use containers.
delete The method of claim 7,
The finely divided grain powder in step c) is a fine or finely divided powder, characterized in that the finely divided powder, characterized in that the production method of disposable or multi-use container using a naturally decomposed fine powder composition comprising biodegradable aliphatic polyester .
The method of claim 7,
In step d), the composition of step c) is placed in a mold and heated to a high temperature (120 to 160 ° C.), which is combined with a semi-sintered state in a high pressure (pressure of 7 to 15 tons per 1 g of raw material) in an sintered state, Method of producing a disposable or multi-use container using a naturally-degradable fine powder composition comprising finely divided grain powder and biodegradable aliphatic polyester, characterized in that the molding step.
The method of claim 7,
After step d), e) a polysiloxane coating step for water resistance reinforcement of the earthenware container; the micronized powder including biodegradable aliphatic polyester and micronized grain powder further comprising a; Disposable or multi-use container manufacturing method using the composition.

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