KR20240109789A - Pulp mold biodegradable seedling pot and manufacturing method thereof - Google Patents

Abstract

The present invention aims to improve the fact that the existing method of producing biodegradable pots is very inefficient, resulting in a significant drop in productivity, and on the other hand, adds functionality to the biodegradable pot to create an environment in which seedlings can grow well during seedlings. We aim to provide a biodegradable seedling pot that has the function of promoting seedling establishment and growth after planting. For this purpose, a pulp production step (S1) of dissociating the used paper by adding and stirring the used paper, additives, and water to produce pulp; and a chest raw material storage step (S2) of moving the pulp manufactured in the pulp manufacturing step to a chest for production; And the pulp stored in the chest in the chess raw material storage step is supplied to the metal mesh mold provided in the molding machine, and then moisture is removed from the metal mesh mold using a suction unit, so that the pulp is formed into the metal. A biodegradable pot forming step (S3) in which a biodegradable pot in the shape of a net-shaped mold is manufactured; And a biodegradable pot drying step (S4) of separating the biodegradable pot molded in the biodegradable pot molding step from the mold and first drying it; and a spray coating step (S5) of spraying a surface strengthening agent on the surface of the biodegradable pot to increase the strength and moisture resistance of the biodegradable pot dried in the biodegradable pot drying step. and a secondary drying step (S6) of drying the biodegradable pot coated with the surface reinforcement agent in the spray coating step; and a product packaging step (S7) of packaging and shipping the secondary dried biodegradable pot so as not to contact moisture.
The composition of the invention as described above has the effect of producing crops that have a fast growth rate during seedlings and are easy to establish after planting.

Description

Pulp mold biodegradable seedling pot and manufacturing method thereof{.}

The present invention relates to a biodegradable seedling pot. More specifically, it relates to a pulp mold biodegradable seedling pot that can improve productivity and reduce the seedling period and a method of manufacturing the same.

As prior art prior to the application of the present invention, technology regarding biodegradable seedling pots using cellulose fibers has been disclosed. In this technology, WSA (wet strength agent), water-soluble wax, and AKD (alkyl ketene dimer) are included as internal additives in biodegradable seedling pots, and the surface of the seedling pot is coated with PLA, a biodegradable water repellent. It is starting.

Another prior art discloses a biodegradable and photodegradable composite resin composition for seedling pots and a method for manufacturing seedling pots using the same. In this technology, the main components of the seedling pot composition are biodegradable polymer compounds, photodegradable polymer compounds, and phosphoric acid, and the biodegradable polymer compounds include polylactic acid and polyhydroxybutyl, the terminal of which is substituted with potassium (K). A technology in which biodegradation and photodegradation occur simultaneously is disclosed by employing a rate (weight ratio 1:1) and a block copolymer (nitrogen component) of ethylene-carbon monoxide polymer and ethylenediamine polymer as the photodegradable polymer compound.

Registered Patent Publication No. 10-1286229 Registered Patent Publication No. 10-2335950

The invention of this application seeks to improve the fact that the existing method of producing biodegradable pots is very inefficient, resulting in a significant drop in productivity. On the other hand, by adding more functionality to biodegradable pots, an environment in which seedlings can grow well during seedlings is created. We aim to provide a biodegradable seedling pot that has the function of promoting seedling establishment and growth after planting.

The invention of this application provides the following problem-solving means to solve the above problems.

A pulp production step (S1) of dissociating the used paper, additives, and water and stirring to produce pulp; and

A chest raw material storage step (S2) of moving the pulp manufactured in the pulp manufacturing step to a chest for production; and

The pulp stored in the chest in the chess raw material storage step is supplied to the metal mesh mold provided in the molding machine, and then moisture is removed from the metal mesh mold using a suction unit, so that the pulp is molded into the metal mesh mold. A biodegradable pot forming step (S3) in which a biodegradable pot in the shape of a mold is manufactured; and

A biodegradable pot drying step (S4) of separating the biodegradable pot formed in the biodegradable pot molding step from the mold and first drying it; and

A spray coating step (S5) of spraying a surface strengthening agent on the surface of the biodegradable pot to increase the strength and moisture resistance of the biodegradable pot dried in the biodegradable pot drying step; and

A secondary drying step (S6) of drying the biodegradable pot coated with the surface reinforcement agent in the spray coating step; and

A method for manufacturing a biodegradable pot is provided, comprising a product packaging step (S7) of packaging and shipping the secondary dried biodegradable pot so as not to contact moisture.

In addition, a method for manufacturing a biodegradable pot is provided, wherein a nutrient for seedlings can be added to the additive to promote rooting of the biodegradable pot and growth of seedlings after planting.

In addition, the additive is a PLA-coated seedling nutrient to promote the attachment of the biodegradable pot and the growth of the seedlings after planting. A biodegradable pot characterized in that the seedlings are decomposed 1 to 3 months after planting and can be used by the seedlings. Provides a manufacturing method.

In addition, a method for manufacturing a biodegradable pot is provided, wherein additional ingredients that help seeds sprout and grow can be added to the surface reinforcement agent.

In addition, the biodegradable pot manufactured by the biodegradable pot manufacturing method maintains a gap between the portholes on the back of the biodegradable porthole so that the biodegradable pot can support its shape during the seedling process of up to 90 days. and provides a biodegradable pot characterized in that it is further provided with support ribs that can maintain strength.

In addition, the above paper uses one or more of recycled paper, waste newspaper, waste corrugated cardboard, waste printing paper, and mixed waste paper, and to further strengthen the fiber, rice straw, barley straw, wheat straw, coarse straw, A biodegradable pot is provided, further comprising one or more natural fibers selected from the group consisting of sorghum stalks, corn stalks, silver grass, reeds, coco peat, and peat moss.

In addition, the biodegradable pot is provided with a cutting hole between the portholes, so that the potholes are separated at the time of planting and planted together with the pothole, thereby providing the seedlings with an environment similar to that of seedlings for a certain period of time even after the potholes are planted. A biodegradable pot is provided, characterized in that further growth of the hair is promoted by additional use of additives provided during decomposition.

In addition, in the case of crops that require a lot of moisture, decomposition of the biodegradable seedling pot may occur due to excessive water during the seedling process, so the porthole of the biodegradable seedling pot is separately added inside the porthole of the biodegradable seedling pot. Provides a biodegradable pot.

The invention of the present application has the effect of producing crops that have a fast growth rate during seedlings and are well established after planting by using the above-mentioned configuration of the invention. Additionally, by improving the manufacturing process, there is an effect of saving energy and producing biodegradable pots at high speed.

Figure 1 is a front view and a back view of a biodegradable pot produced with the pulp mold of the present invention.
Figure 2 shows an example in which part of the biodegradable pot of the present invention is cut and used.
Figure 3 shows a pulp mold for producing the biodegradable pot of the present invention.
Figure 4 shows the production process for producing the biodegradable seedling pot of the present invention using a pulp mold.
Figure 5 shows a comparison of the sizes of seedlings grown using the biodegradable seedling pot of the present invention and those produced using the existing seedling pot.
Figure 6 shows the configuration of the jamming prevention protrusion provided in the biodegradable seedling pot of the present invention.

In the pulp mold biodegradable seedling pot of the invention of this application, the pulp mold refers to a three-dimensional paper product that is specified, and a three-dimensional paper product can be produced by introducing pulp into a mesh-shaped mesh mold and removing moisture.

In general, the growth process of germinating seeds and growing seedlings until planting can be done by germinating seeds in a greenhouse or nursery to reduce the risk of cold damage due to temperature changes in weak seedlings and to ensure rapid growth of crops under appropriate conditions. It is used to produce seedlings. Seeds are sown in seedling pots in greenhouses where an environment suitable for cultivation is maintained and intensive management is performed to reduce labor and costs and produce seedlings.

However, most seedling pots widely used in Korea are plastic seedling pots made of non-degradable petroleum resin. It has the advantage of being low cost, light in weight, and able to be used repeatedly without being affected by physical properties due to moisture penetration.

However, plastic seedling pots that have reached the end of their useful life or are broken must be collected as they do not decompose naturally in the soil, but foreign substances such as soil and fertilizer are stuck together, making separation and disposal difficult. For this reason, most of it is landfilled or incinerated as agricultural waste, becoming a major cause of environmental pollution.

The present invention seeks to provide a biodegradable seedling pot using biodegradable pulp raw materials that are easily biodegradable in soil in order to solve the above problems.

As a conventional technology for manufacturing seedling pots using biodegradable raw materials, Korean Patent Publication No. 10-1997-25368 describes a seedling pot for sowing consisting of peat moss and paper rosette and a method for manufacturing the same. In Korea Registered Patent Publication No. 10-477272, there is a product for agricultural and horticultural use made mainly of organic matter such as mature compost, peat, and humus, and mineral powder such as zeolite, phyllite, and Uiwangseok. A method of manufacturing a biodegradable molded seedling pot is described. However, due to the nature of hydrophilic cellulose fibers, physical strength is reduced due to moisture penetration, which can change the shape of the seedling pot, which can cause problems in use. In addition, when biodegradable seedling pots were implemented in the form of existing trays, it was very cumbersome and cumbersome for workers to separate and plant multiple pot bodies one by one during planting work.

The invention of this application is intended to solve the above-mentioned problem by the above-mentioned configuration of the invention, and the operational effects of the invention by the above-mentioned configuration of the invention are as follows using the drawings.

Figure 1 is a front view and a back view of a biodegradable pot produced with the pulp mold of the present invention. The biodegradable pot of the present invention provides a tray-shaped pulp mold biodegradable seedling pot in which a main body provided with a plurality of ports (portholes) is integrated.

The biodegradable seedling pot of the invention of this application was manufactured using a pulp mold, and unlike the existing seedling pot made of hydrophilic cellulose fiber whose strength is reduced by water, the pulp mold biodegradable seedling pot has physical properties even if moisture penetrates. It has the characteristic of maintaining appropriate strength. In addition, a spray coating step of additionally spraying a surface strengthener to prevent moisture infiltration is included, allowing a seedling period of up to 90 days despite moisture contact during seedlings.

In addition, there was a problem that the ports (portholes) were not easily separated when planting, so the problem of delaying work was provided by equipping a cutting hole between the ports (portholes), and using external force (e.g., separation by hand during manual work, but not when using an automatic planting machine). It provides a tray-shaped pulp mold biodegradable seedling pot in which one port (porthole) can be completely separated from a plurality of ports (portholes) by a cutting device.

The tray-shaped pulp mold biodegradable seedling pot of the present invention is open on one side, and the other side is formed between a plurality of portholes and different portholes where the side portion in contact with the internal space and the bottom surface where the drain is formed are connected to each other. It includes a connecting portion in which a plurality of cutting holes are formed at a portion connecting different portholes, and is configured so that one porthole is completely separated from the plurality of portholes by an external force applied to the connecting portion. The plurality of portholes are characterized in that the width of the porthole becomes narrower from the open portion to the floor, and the floor surface in contact with the inner space of the plurality of portholes may be formed in a circular, square, or polygonal shape, and can be used to connect products to each other. When stacked in succession, an anti-jamming protrusion protruding downward is formed on the side part in contact with the inner space so that the biodegradable seedling pots do not get stuck together and are well separated from each other, and prevent sagging between pots when the seeded seedling pots are lifted. The support ribs are installed in a grid to increase the strength of the biodegradable seedling pot.

Figure 2 shows an example in which part of the biodegradable pot of the present invention is cut and used. There is a difference in formalization and survival when formalizing by removing the existing port and when formalizing by including the port. This can also be verified by the photo in Figure 5, but if it is removed from an unknown pot and planted, the cultivation environment will change in an instant, causing the crop to feel stress. However, when planted with a biodegradable seedling pot, the growth environment around the seedling roots is the same, and after planting, the biodegradable pot decomposes and is naturally connected to the surrounding environment, so growth stress is reduced, resulting in a higher establishment rate and faster growth. Benefits arise quickly.

Figure 3 shows a pulp mold for producing the biodegradable pot of the present invention. The pulp mold is composed of a mesh shape, and after a pump is introduced into the pulp mold, the moisture of the pulp introduced by suction is removed to create a biodegradable pot in the form of the pulp mold.

This is a big difference from the existing method of making a biodegradable pot. The existing biodegradable pot is made by introducing pulp into the pulp mold as described above and then pressing the upper mold to the pulp mold and heating the upper mold. It is taken out in this way. When using this method, it takes about 40 to 50 seconds to produce by pressing and heating once.

As in the invention of this application, when pulp is introduced into a pulp mold, moisture is removed by suction, and the pulp is separated and dried, there is an advantage in that a biodegradable pot can be produced every 10 to 20 seconds in the pulp mold.

Figure 4 shows the production process for producing the biodegradable seedling pot of the present invention using a pulp mold. The hot air drying method production process of the invention of this application involves dissociating water, waste paper, and various additives into a pulper to loosen the fibers; Pulper raw materials with a concentration of about 5% to 7% are transferred to the chest; From the chest, raw materials with a concentration of about 3% to 7% are supplied to the molding machine; In the molding machine, the mold is immersed in the pulp, then sucked and dehydrated with a vacuum for a certain period of time (about 3 to 5 seconds), and then the biodegradable seedling pot is demolded using air pressure and vacuum; Place products with a moisture content of approximately 60% to 85% on the conveyor; Pass through a dryer for primary drying (drying rate 95%); After the spraying process of spraying a surface strengthening agent on the surface of the biodegradable pot to increase the strength and moisture resistance of the biodegradable pot; The process of manufacturing a biodegradable seedling pot by drying a coated biodegradable pot is shown.

Figure 5 shows a comparison of the sizes of seedlings grown using the biodegradable seedling pot of the present invention and those produced using the existing seedling pot. Figure 5 is a photo comparing the growth of seedlings planted by cutting the biodegradable seedling pots together at the time of planting using biodegradable seedling pots.

Figure 6 shows the configuration of the jamming prevention protrusion provided in the biodegradable seedling pot of the present invention. When multiple biodegradable seedling pots are stacked, an anti-jamming protrusion is provided on the outer side of the pothole to facilitate separation.

The structure of the invention to demonstrate the effects of the invention as described above is as follows.

A pulp production step (S1) of dissociating the used paper, additives, and water and stirring to produce pulp; and

A chest raw material storage step (S2) of moving the pulp manufactured in the pulp manufacturing step to a chest for production; and

The pulp stored in the chest in the chess raw material storage step is supplied to the metal mesh mold provided in the molding machine, and then moisture is removed from the metal mesh mold using a suction unit, so that the pulp is molded into the metal mesh mold. A biodegradable pot forming step (S3) in which a biodegradable pot in the shape of a mold is manufactured; and

A biodegradable pot drying step (S4) of separating the biodegradable pot formed in the biodegradable pot molding step from the mold and first drying it; and

A spray coating step (S5) of spraying a surface strengthening agent on the surface of the biodegradable pot to increase the strength and moisture resistance of the biodegradable pot dried in the biodegradable pot drying step; and

A secondary drying step (S6) of drying the biodegradable pot coated with the surface reinforcement agent in the spray coating step; and

A method for manufacturing a biodegradable pot is provided, comprising a product packaging step (S7) of packaging and shipping the secondary dried biodegradable pot so as not to contact moisture.

In addition, a method for manufacturing a biodegradable pot is provided, wherein a nutrient for seedlings can be added to the additive to promote rooting of the biodegradable pot and growth of seedlings after planting.

In addition, the additive is a PLA-coated seedling nutrient to promote the attachment of the biodegradable pot and the growth of the seedlings after planting. A biodegradable pot characterized in that the seedlings are decomposed 1 to 3 months after planting and can be used by the seedlings. Provides a manufacturing method.

In addition, a method for manufacturing a biodegradable pot is provided, wherein additional ingredients that help seeds sprout and grow can be added to the surface reinforcement agent.

In addition, the biodegradable pot manufactured by the biodegradable pot manufacturing method maintains a gap between the portholes on the back of the biodegradable porthole so that the biodegradable pot can support its shape during the seedling process of up to 90 days. and provides a biodegradable pot characterized in that it is further provided with support ribs that can maintain strength.

In addition, the above paper uses one or more of recycled paper, waste newspaper, waste corrugated cardboard, waste printing paper, and mixed waste paper, and to further strengthen the fiber, rice straw, barley straw, wheat straw, coarse straw, A biodegradable pot is provided, further comprising one or more natural fibers selected from the group consisting of sorghum stalks, corn stalks, silver grass, reeds, coco peat, and peat moss.

In addition, the biodegradable pot is provided with a cutting hole between the portholes, so that the potholes are separated at the time of planting and planted together with the pothole, thereby providing the seedlings with an environment similar to that of seedlings for a certain period of time even after the potholes are planted. A biodegradable pot is provided, characterized in that further growth of the hair is promoted by additional use of additives provided during decomposition.

100: Biodegradable port
110: porthole (port)
120: Cutting tool
130: support rib
140: Anti-jamming protrusion
200: molding machine
210: molding frame
220: suction part

Claims (5)

A pulp manufacturing step (S1) of dissociating the used paper by adding and stirring the used paper, additives, and water to produce pulp; and
A chest raw material storage step (S2) of moving the pulp manufactured in the pulp manufacturing step to a chest for production; and
The pulp stored in the chest in the chess raw material storage step is supplied to the metal mesh mold provided in the molding machine, and then moisture is removed from the metal mesh mold using a suction unit, so that the pulp is molded into the metal mesh mold. A biodegradable pot forming step (S3) in which a biodegradable pot in the shape of a mold is manufactured; and
A biodegradable pot drying step (S4) of separating the biodegradable pot molded in the biodegradable pot molding step from the mold and first drying it; and
A spray coating step (S5) of spraying a surface strengthening agent on the surface of the biodegradable pot to increase the strength and moisture resistance of the biodegradable pot dried in the biodegradable pot drying step; and
A secondary drying step (S6) of drying the biodegradable pot coated with the surface reinforcement agent in the spray coating step; and
A method for manufacturing a biodegradable pot, comprising a product packaging step (S7) of packaging and shipping the secondary dried biodegradable pot so as not to contact moisture. According to paragraph 1,
A method of manufacturing a biodegradable pot, characterized in that the additive can be added as a nutrient for seedlings to promote the rooting of the biodegradable pot and the growth of the seedlings after planting. According to paragraph 2,
The additive includes a PLA-coated seedling nutrient to promote the attachment of the biodegradable pot and the growth of the seedlings after planting. Manufacture of a biodegradable pot, characterized in that the seedlings are decomposed 1 to 3 months after planting and can be used by the seedlings. method. The biodegradable pot manufactured by the method for manufacturing a biodegradable pot according to any one of claims 1 to 3 has a shape of the biodegradable porthole so that the biodegradable pot can support its shape during the seedling process of up to 90 days. A biodegradable port, characterized in that it is further provided with support ribs on the rear side to maintain the gap between the port holes and maintain strength. According to paragraph 4,
The biodegradable pot is equipped with a cutting hole between the potholes, and when planting, the pothole is separated and planted together with the pothole, thereby providing the seedlings with an environment similar to that of seedlings for a certain period of time even after the pothole is planted. As the pothole decomposes, the biodegradable pot is provided with a cutting hole. A biodegradable pot characterized in that further growth of the hair is promoted by additional use of the provided additives.