KR102698744B1 - Pretreatment device for mushroom mycelium pad - Google Patents

Abstract

The present invention relates to a pretreatment device for producing a mushroom mycelium sheet, comprising: a tank portion for receiving pretreatment water; a support portion for supporting the mushroom mycelium pad immersed in the pretreatment water; and a bubble supply portion coupled to the tank portion for supplying air bubbles to the mushroom mycelium pad.

Description

{PRETREATMENT DEVICE FOR MUSHROOM MYCELIUM PAD}

The present invention relates to a technology for a pretreatment device for a mushroom mycelium pad.

The so-called 'mushroom leather' made using mushroom mycelia is attracting attention as the sustainable leather of the future. The advantage of mushroom leather is that it can be made and used as it is in nature without causing environmental pollution by utilizing materials and technology provided by nature. Unlike animal leather that uses toxic chemicals or synthetic leather that uses polyurethane (PU) or polyvinyl chloride (PVC), mushroom leather does not create pollutants during the manufacturing process and is biodegradable after use and can be used as compost, so it is known as vegan leather and eco-friendly leather.

Accordingly, the inventor of the present invention studied a technique for manufacturing a high-quality mushroom mycelium sheet for a long time and completed the present invention through trial and error.

The present invention provides a device for pretreatment of a mushroom mycelium pad capable of obtaining a high-quality mushroom mycelium sheet.

Meanwhile, other unspecified purposes of the present invention will be additionally considered within a range that can be easily inferred from the following detailed description and its effects.

According to an embodiment of the present invention, a pretreatment device for producing a mushroom mycelium sheet is provided, comprising: a tank portion for receiving pretreatment water; a support portion for supporting the mushroom mycelium pad immersed in the pretreatment water; and a bubble supply portion coupled to the tank portion for supplying air bubbles to the mushroom mycelium pad.

The above support member may include clamps that respectively grip the upper and lower ends of the mushroom mycelium pad so that the mushroom mycelium pad remains smooth within the tank.

The above support member may further include a connecting member connecting a plurality of the clamps, each of which holds a plurality of the mushroom mycelium pads.

It may further include a lifting unit for raising and lowering the above-mentioned support unit.

The above bubble supply unit may include a pipe arranged on the bottom of the tank to move air; and a plurality of nozzles coupled to the pipe.

The above bubble supply unit may further include a blower coupled to the pipe; and a control unit controlling the blower.

The direction of the above nozzle can be variable.

The above pretreatment water may include distilled water.

A pretreatment device for manufacturing mushroom mycelium sheets.

The mushroom mycelium pad can be economically and effectively pretreated by the pretreatment device of the mushroom mycelium pad according to the present invention.

The high-quality mushroom mycelium sheet according to the present invention can be utilized as a high-quality leather substitute.

Meanwhile, it is added that even if an effect is not explicitly mentioned herein, the effect and its provisional effect described in the following specification expected by the technical features of the present invention are treated as described in the specification of the present invention.

FIG. 1 is a drawing showing a mushroom mycelium bed and a mushroom mycelium pad according to an embodiment of the present invention.
Figure 2 is a flow chart showing a method for manufacturing a sheet using a mushroom mycelium pad according to an embodiment of the present invention.
Figures 3 to 6 are drawings showing a preprocessing device according to an embodiment of the present invention.
FIGS. 7 to 10 are drawings showing a plasticizer treatment device according to an embodiment of the present invention.
Figures 11 to 13 are drawings showing a thermocompression device according to an embodiment of the present invention.
It is to be understood that the attached drawings are provided for reference only to help understand the technical concept of the present invention, and the scope of the rights of the present invention is not limited thereby.

In describing the present invention, if it is judged that the detailed description of related known functions that are obvious to those skilled in the art and may unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

The terminology used in this application is only used to describe specific embodiments and is not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly indicates otherwise. In this application, it should be understood that the terms "comprises" or "has" and the like are intended to specify the presence of a feature, number, step, operation, component, part or combination thereof described in the specification, but do not exclude in advance the possibility of the presence or addition of one or more other features, numbers, steps, operations, components, parts or combinations thereof.

Hereinafter, an embodiment of a pretreatment device for a mushroom mycelium pad according to the present invention will be described in detail with reference to the attached drawings. When describing with reference to the attached drawings, identical or corresponding components are assigned the same drawing numbers and redundant descriptions thereof will be omitted.

FIG. 1 is a drawing showing a mushroom mycelium bed and a mushroom mycelium pad according to an embodiment of the present invention. FIG. 2 is a flow chart showing a method for manufacturing a sheet using a mushroom mycelium pad according to an embodiment of the present invention. FIGS. 3 to 6 are drawings showing a pretreatment device according to an embodiment of the present invention. FIGS. 7 to 10 are drawings showing a plasticizer treatment device according to an embodiment of the present invention. FIGS. 11 to 13 are drawings showing a thermocompression device according to an embodiment of the present invention.

The method for manufacturing a sheet using a mushroom mycelium pad according to the present invention is a method for manufacturing a mushroom mycelium sheet. The mushroom mycelium sheet is a sheet with mushroom mycelium as its main component, and can be used as a substitute for leather in automobile interiors, small items such as bags, etc., but the uses of the mushroom mycelium sheet in the present invention are not limited.

'Mushroom mycelium' refers to the organ that mushrooms absorb nutrients to survive. Mushrooms are composed of mycelium, which is the vegetative organ, and fruiting bodies, which contain spores, which are the reproductive organs. Compared to general plants, mycelium corresponds to roots/stems/leaves, and fruiting bodies correspond to flowers.

The cell wall of mushroom mycelia has a structure in which an amorphous gel-like matrix of polysaccharides (α-1,3-glucan) and glycoproteins (mainly mannan or galactomannoproteins) is linked to a membrane in which chitin and β-glucan microfibrils are woven. Chitin and β-glucan are essential components that maintain the structure of the cell wall, and chitin in particular is a very important component for the mechanical strength of mycelial fibers.

Mushroom mycelia growing are nutrient-receptive, and they grow by expanding their tips and taking up nutrients. After the hyphae expand, a tip is formed in the cell wall, which can cause branches, and they extend in a continuous and characteristic radial pattern. These branches extend in various directions, and numerous fusions occur between hyphae. The fusion between hyphae is uniform in terms of material, and in terms of mechanical aspect, the mechanical strength is increased by the formation of a micro-network of hyphae.

Mushroom mycelia are made up of intertwined mycelia forming a network layer, which has a microstructure similar to the dermis layer of animal skin. However, the density of mycelia is not high, so durability and strength are weak.

Mycelia can be broadly classified into three types: aerial hyphae, biofilm hyphae, and penetrative hyphae. Aerial hyphae exchange oxygen and carbon dioxide required for mycelial growth, and biofilm hyphae are located between aerial hyphae and penetrative hyphae and have a dense mat shape. Biofilm hyphae prevent moisture loss from the medium, prevent the invasion of other fungi, and store moisture for mycelial growth. As the thickness and density of the biofilm increase, nutrient transfer (mass transfer) in the medium becomes difficult, and the growth of biofilm and aerial hyphae stops. Meanwhile, penetrative hyphae secrete enzymes to decompose nutrients in the medium and consume the decomposed nutrients.

In the present invention, ‘mushroom mycelium’ refers to aerial hyphae, biofilm hyphae, and penetrative hyphae, and in a narrow sense, refers to biofilm hyphae, and in a broad sense, refers to a concept including aerial hyphae and biofilm hyphae.

In the present invention, the mushroom mycelia may be one kind of mushroom mycelia selected from the group consisting of Laetiporus sulphureus, Microporus affinis, Ganoderma lucidum, Schizophyllum commune, Trametes versicolor, Daedaleopsis tricolor, Elfvingia applanata, Mycoleptodonoides aitchisonii, Fomitopsis pinicola, Agaricus arvensis, Lentinula edodes, Wolfiporia extensa, and Trametes orientalis, but is not limited thereto.

Referring to FIG. 1, the 'mushroom mycelium pad (10)' in the present invention is collected from a 'mushroom mycelium bed (1)' produced by culturing mushroom mycelium as shown in FIG. 1(a), and may be prepared by separating an upper part of the mushroom mycelium bed (1) as shown in FIG. 1(b). A mushroom mycelium pad (20) may be prepared by collecting a biofilm of the mushroom mycelium bed (1). The mushroom mycelium pad (10) may be formed in a thin plate shape. The mushroom mycelium pad (10) has a high density as aerial hyphae and biofilm hyphae of the mushroom mycelium grow.

A mushroom mycelia bed (1) can be prepared by cultivating liquid-cultured mushroom mycelia in a dark room under conditions of a certain temperature and humidity for a certain period of time. Cultivation can be performed in a dark room under conditions of 28°C and 80-90% humidity for 28 days, but is not limited thereto.

Referring to FIG. 2, a method for manufacturing a sheet using a mushroom mycelium pad according to the present invention may include a mushroom mycelium pad preparation step (step 1) (S100), a mushroom mycelium pad pretreatment step (step 2) (S200), a mushroom mycelium pad surface modification step (step 3) (S300), a mushroom mycelium pad plasticizer treatment step (step 4) (S400), and a mushroom mycelium pad heat compression step (step 5) (S500).

The mushroom mycelium pad preparation step (step 1) (S100) may include a step of collecting a mushroom mycelium pad from a mushroom mycelium bed.

As described above, the mushroom mycelium bed can be prepared by culturing the mushroom mycelium, and the upper part thereof can be separated to provide a mushroom mycelium pad. Here, the upper part of the mushroom mycelium bed can be peeled. Additionally, the user can peel the upper part of the mushroom mycelium bed by hand or by a separate tool.

One mushroom mycelium pad can be obtained from one mushroom mycelium bed. The residual mushroom mycelium bed from which the mushroom mycelium pad is peeled can be recycled for cultivation. The residual mushroom mycelium bed from which the mushroom mycelium pad is peeled can be crushed, inserted into a mold, and processed into a desired shape to be used as a plastic substitute.

The mushroom mycelium pad pretreatment step (second step) (S200) is a step of pretreating the mushroom mycelium pad using pretreatment water (e.g., distilled water). By this step, the structure of the mushroom mycelium pad can be weakened (loose), and thus the permeability of the material used in the next step can be improved.

The mushroom mycelium pad pretreatment step (second step) (S200) may include a step of immersing the mushroom mycelium pad in distilled water. That is, the mushroom mycelium pad is immersed in distilled water, and the surface of the mushroom mycelium pad may come into contact with the distilled water.

The mushroom mycelium pad pretreatment step (second step) (S200) may include a step of supplying air bubbles to the mushroom mycelium pad. That is, the mushroom mycelium pad is immersed in distilled water, and air bubbles are supplied into the distilled water, so that the air bubbles move toward the mushroom mycelium pad and can come into contact with the mushroom mycelium pad. The air bubbles can strike the mushroom mycelium pad. Accordingly, the inter-mycelium entanglement structure is weakened and loosened, so that the action of a material used thereafter can be made smooth.

In the mushroom mycelium pad pretreatment step (second step) (S200), the mushroom mycelium pad can be pretreated by immersing the mushroom mycelium pad in a distilled water tank containing distilled water and supplying air bubbles.

The mushroom mycelium pad pretreatment step can be performed by a pretreatment device.

FIG. 3 shows the overall appearance of a mushroom mycelium pad pretreatment device according to an embodiment of the present invention. Referring to FIG. 3, a mushroom mycelium pad pretreatment device according to an embodiment of the present invention is a device for pretreating a mushroom mycelium pad before modifying the surface of the mushroom mycelium pad, and may include a water tank portion (210) (also referred to as a first water tank portion), a support portion (220), and a bubble supply portion (230).

The tank (210) may have an internal space formed to accommodate pre-treated water. The tank (210) may be formed in a rectangular hexahedron shape, but is not limited thereto. The tank (210) may have a height greater than the width or length. Accordingly, the tank (210) may provide sufficient space to accommodate the bubble supply unit (230) below. The tank (210) may be formed in a size of 1200 mm X 1200 mm X 21500 mm, but is not limited thereto.

The water tank (210) may include an inlet pipe (not shown) for supplying pretreated water and/or a discharge pipe (211) for discharging pretreated water. The inlet pipe (not shown) and the discharge pipe (211) may be formed on the side of the water tank (210). The inlet pipe (not shown) and the discharge pipe (211) may be equipped with a valve to selectively open and close the water passage inside.

The water tank (210) may include an inlet pipe (not shown) for supplying pretreated water and/or a discharge pipe (211) for discharging pretreated water. The inlet pipe (not shown) and the discharge pipe (211) may be formed on the side of the water tank (210). The inlet pipe (not shown) and the discharge pipe (211) may be equipped with a valve to selectively open and close the water passage inside.

A stand (212) may be combined inside the water tank (210). The stand (212) may support a support (220) inserted into the water tank (210) to be immersed in pretreatment water. The stand (212) may be formed on the inner wall of the water tank (210). The stand (212) may be formed long along the inner wall of the water tank (210). The stand (212) may be formed so as not to cover the bubble supply part (230) of the water tank (210). The stand (212) may be formed in multiples. The stand (212) may be formed on two inner walls of the water tank (210) facing each other.

The pretreatment water may contain distilled water.

FIG. 4 illustrates a support (220) of a mushroom mycelium pad pretreatment device according to an embodiment of the present invention. Referring to FIG. 4, the support (220) can support a mushroom mycelium pad (10) immersed in pretreatment water. The support (220) can support the upper and/or lower portion of the mushroom mycelium pad (10). The support (220) is formed in multiples, and each support (220) can support one mushroom mycelium pad (10).

The support member (220) may include a clamp (221). The clamp (221) may be capable of holding at least a portion of the mushroom mycelium pad (10). The clamp (221) is formed with a structure capable of opening and closing, and the clamp (221) may include a pair of members capable of opening and closing each other. The mushroom mycelium pad (10) is placed between the pair of members that are opened from each other, and the mushroom mycelium pad (10) may be fixed as the pair of members close to each other.

The support member (220) may include a pair of clamps (221) (upper clamp and lower clamp) that respectively grip the upper and lower portions of the mushroom mycelium pad (10). Accordingly, the mushroom mycelium pad (10) may be maintained smoothly within the tank member (210). The pair of clamps (221) may be formed in multiples.

A plurality of mushroom mycelium pads (10) can be immersed in the pretreatment water at once by the support member (220). The support member (220) is formed in multiple numbers, and each support member (220) supports one mushroom mycelium pad (10), and a plurality of mushroom mycelium pads (10) can be inserted into the water tank member (210) at once. The plurality of mushroom mycelium pads (10) can be arranged in parallel to each other.

The support member (220) may include a clamp (221) and a connecting member (222).

As described above, the clamp (221) can grip at least a portion of the mushroom mycelium pad (10). The clamps (221) can be formed in multiples. The clamps (221) can be formed in a pair. The clamps (221) can include an upper clamp that grips an upper portion of the mushroom mycelium pad (10) and a lower clamp that grips a lower portion of the mushroom mycelium pad (10). Each of the upper clamps and the lower clamps can be formed in multiples.

A plurality of mushroom mycelium pads (10) can be supported by the support member (220), and each of the mushroom mycelium pads (10) can be fixed by the upper clamp and the lower clamp. The plurality of mushroom mycelium pads (10) can be arranged parallel to each other. The plurality of mushroom mycelium pads (10) can be arranged spaced apart from each other.

The connecting portion (222) can connect a plurality of clamps (221) to each other. The connecting portion (222) can include at least one of an upper connecting portion and a lower connecting portion. The upper connecting portion can connect a plurality of upper clamps, and the lower connecting portion can connect a plurality of lower clamps. According to the connecting portion (222), a plurality of mushroom mycelium pads (10) can be easily immersed in pretreatment water at once.

In Fig. 4, the connecting portion (222) is depicted as a square ring, but the shape of the connecting portion (222) is not limited in the present invention.

FIG. 5 is a side view of a mushroom mycelium pad pretreatment device according to an embodiment of the present invention.

Referring to FIGS. 3 and 5, the bubble supply unit (230) is coupled to the water tank unit (210) and can supply air bubbles (A) to the mushroom mycelium pad (10). That is, the bubble supply unit (230) can supply air bubbles (A) to the mushroom mycelium pad (10) immersed in the pretreatment water.

The bubble supply unit (230) may include a pipe (231) and a nozzle (232). The bubble supply unit (230) may further include a blower (233).

The pipe (231) is arranged on the bottom of the water tank (210) and can move air. The pipe (231) is formed by a plurality of pipes, and each of the pipes can be connected to each other. For example, the pipe (231) can include a plurality of horizontal pipes and a vertical pipe connecting the plurality of horizontal pipes. At least a part (231a) of the pipe (231) can be connected to the outside of the water tank (210). That is, at least a part (231a) of the pipe (231) can penetrate the side surface of the water tank (210). At least a part (231a) of the pipe (231) can protrude outward from the side surface of the water tank (210).

Referring to FIG. 5, the pipe (231) may be positioned below the stand (212) installed in the water tank (210). Accordingly, the pipe (231) can effectively supply air bubbles (A) to the mushroom mycelium pad (10) positioned above the stand (212).

FIG. 6 is a top view of a mushroom mycelium pad pretreatment device according to an embodiment of the present invention. Referring to FIG. 6, a pipe (231) and a mushroom mycelium pad (10) may be arranged vertically. In addition, a pipe (231) and a clamp (221) may be arranged vertically. In particular, a cross-section of the pipe (231) and a clamp (221) may be arranged vertically. A plurality of mushroom mycelium pads (10) may be arranged to be spaced apart from each other along the extension direction of the pipe (231). Accordingly, air bubbles (A) may be supplied to the spaced apart spaces between the mushroom mycelium pads (20), and the probability of contact between the mushroom mycelium pads (10) and the air bubbles (A) may be increased.

The nozzle (232) is a part that ejects air bubbles (A), is connected to the pipe (231), and may be formed in multiple numbers. The nozzle (232) may include an ejection hole. A plurality of nozzles (232) may be spaced apart from each other. In FIG. 3, etc., the nozzle (232) is illustrated as protruding from the outer surface of the pipe (231), but is not limited thereto, and the nozzle (232) may be formed on the same plane as the outer surface of the pipe (231) and may not protrude. In this case, the ejection hole of the nozzle (232) may be formed directly in the pipe (231).

The direction of the nozzle (232) may be variable. Here, the direction of the nozzle (232) may be the direction pointed by the ejection hole. The direction in which the air bubbles (A) are supplied may change depending on the direction of the nozzle (232). The plurality of nozzles (232) may operate independently of each other, and the directions of the plurality of nozzles (232) may be changed independently of each other. For example, the amount of air bubbles (A) contact may be small for the mushroom mycelium pad (10) located at the very end (or adjacent to the inner surface of the tank portion (210)), and to compensate for this, the direction of a part of the nozzle (232) may be changed so that the amount of air bubbles (A) supplied to the mushroom mycelium pad (10) located at the very end (or adjacent to the inner surface of the tank portion (210)) increases.

To change the direction of the nozzle (232), the nozzle (232) may include a driving unit. Here, the nozzle (232) may include a main body, a jet hole, and a driving unit. The main body may be a pipe extending from the pipe (231). The jet hole may be formed inside the main body so as to communicate with the inside of the pipe (231). The driving unit may be coupled to the main body to change the angle of the main body (angle with respect to the pipe (231)).

A blower (233) can be connected to a pipe (231) to supply air. The blower (233) can be coupled to at least a portion (231a) of a pipe (231) connected to the outside of the water tank (210). At least one of an on/off state of air supply, air flow rate, air pressure, and air flow rate can be changed by the operation of the blower (233).

The bubble supply unit (230) may further include a control unit. The control unit may control the blower (233). The control unit may control the blower (233) to change at least one of the on/off state of the air supply, the air movement speed, and the air pressure. The control unit may control the direction of the nozzle (232). The control unit may control the driving unit of the nozzle (232) to change the direction of the nozzle (232).

According to an embodiment of the present invention, a mushroom mycelium pad pretreatment device may further include an elevating unit (240). The elevating unit (240) may elevate the support unit (220) up and down. The elevating unit (240) may include a hook unit (241) and a wire unit (242). The elevating unit (240) may include a ceiling unit (240a), a hook unit (241), and a wire unit (242).

The ceiling part (240a) may be located on the upper part of the water tank part (210). The ceiling part (240a) may be formed in a flat plate shape. The ceiling part (240a) may be coupled to a frame (240b) installed on the water tank part (210). The water tank part (210) and the frame (240b) may be detachable from each other.

The hook part (241) can be installed so as to be liftable on the ceiling part (240a). If the lifting part (240) does not include the ceiling part (240a), the hook part (241) can be coupled to the end of the crane. The hook part (241) can include a hook shape. A separate driving device is coupled to the hook part (241), and the driving device can lift the hook part (241) up and down.

The wire portion (242) can be coupled to the support portion (220). Specifically, the wire portion (242) can be coupled to the connection portion (222) of the support portion (220). The wire portion (242) can be coupled to at least one point of the connection portion (222). The wire portion (242) and the connection portion (222) can be detachable. However, the present invention is not limited thereto, and the wire portion (242) can be fixed to the connection portion (222).

The wire part (242) can be hooked by the hook part (241), and accordingly, the hook part (241) and the support part (220) can move together. As the hook part (241) rises and falls, the support part (220) coupled to the wire part (242) can rise and fall together with the hook part (241).

The mushroom mycelium pad (10) can be mounted on the support member (220) while the hook member (241) is raised. Once the mounting is complete, the hook member (241) is lowered and the mushroom mycelium pad (10) can be pretreated with pretreatment water within the water tank member (210).

Referring to FIG. 5, the hook portion (241) may be lowered to position the support portion (220) within the water tank portion (210). Here, the support portion (220) may be positioned on the stand (212) of the water tank portion (210). In this case, the load applied to the hook portion (241) and the wire portion (242) may be eliminated. The wire portion (242) may be removed from the support portion (220) as needed. Alternatively, the hook portion (241) may terminate the hooking of the wire portion (242).

However, the stand (212) is not an essential component, and the stand (212) may not be provided within the tank (210). At this time, the hook part (241) can continuously hold the support part (220) so that the support part (220) is in a fixed position within the tank (210), and the support part (220) can be fixed at a predetermined position.

Meanwhile, after the preprocessing is completed, the hook part (241) hooks the wire part (242), and the hook part (241) rises to detach the support part (220) from the tank part (210). The mushroom mycelium pad (10) can be detached from the raised support part (220).

The mushroom mycelium pad surface modification step (third step) (S300) is a step for imparting various functional groups to the mushroom mycelium pad by modifying the surface of the pretreated mushroom mycelium pad, thereby changing the physical properties. For example, a functional group including an amine group (-NH ₂ ) can be imparted to the surface of the mushroom mycelium pad.

The mushroom mycelium pad surface modification step (third step) (S300) may include a step of contacting the mushroom mycelium pad with ammonia. The ammonia may be provided in the form of ammonia gas or ammonia water. For example, ammonia gas may be sprayed onto the mushroom mycelium pad. Accordingly, an amine group (-NH2) may be provided to the surface of the mushroom mycelium pad.

In the mushroom mycelium pad surface modification step (third step) (S300), the mushroom mycelium pad is positioned in a chamber, and ammonia gas is supplied into the chamber to modify the surface of the mushroom mycelium pad. The ammonia gas may be ammonia water sprayed. The temperature in the chamber may be 30 to 50°C, and the ammonia contact time (supply time) may be 3 to 8 hours.

The mushroom mycelium pad surface modification step can be performed by a surface modification device. The surface modification device can include a chamber and a material supply unit.

The chamber can accommodate a mushroom mycelium pad and provide a space where the mushroom mycelium pad and the surface modifying material can come into contact with each other. It can be formed to a predetermined size capable of accommodating the mushroom mycelium pad. The mushroom mycelium pad can be fully inserted into the chamber. A holder on which the mushroom mycelium pad can be placed can be combined within the chamber. The holder can be detachable, but is not limited thereto.

The material supply unit is a means for supplying a surface-modifying material (a material required for surface modification) into the chamber. The material supply unit may include a sprayer. The material supply unit may supply ammonia. Accordingly, the mushroom mycelium pad may be provided with an amine group.

The mushroom mycelium pad plasticizer treatment step (step 4) (S400) is a step of imparting flexibility and/or elasticity to the mushroom mycelium pad by plasticizing the surface-modified mushroom mycelium pad.

The mushroom mycelium pad plasticizer treatment step (step 4) (S400) may include a step of immersing the mushroom mycelium pad in a plasticizer. That is, the mushroom mycelium pad is immersed in the plasticizer, and the surface of the mushroom mycelium pad may come into contact with the plasticizer.

The mushroom mycelium pad plasticizer treatment step (step 4) (S400) may include a step of supplying air bubbles to the mushroom mycelium pad. That is, the mushroom mycelium pad is immersed in a plasticizer, and air bubbles are supplied into the plasticizer, so that the air bubbles move toward the mushroom mycelium pad and can come into contact with the mushroom mycelium pad. The air bubbles can strike the mushroom mycelium pad. Accordingly, the inter-mycelium entanglement structure is weakened and loosened, so that the plasticizer can function smoothly.

The plasticizer may include at least one of propylene carbonate and ethyl alcohol. The plasticizer may include propylene carbonate at a concentration of 100%. The plasticizer may include ethyl alcohol at a concentration of 70%. The volume ratio of propylene carbonate and ethyl alcohol contained in the plasticizer may be 6.5:3.5 to 7.5:2.5. Most preferably, the volume ratio of propylene carbonate and ethyl alcohol may be 7:3.

In the mushroom mycelium pad plasticizer treatment step (step 4) (S400), the mushroom mycelium pad is immersed in a plasticizer tank (210) that accommodates a plasticizer, and air bubbles are supplied to perform plasticizer treatment on the mushroom mycelium pad. Meanwhile, after the plasticizer treatment, the mushroom mycelium pad can be washed and/or dried. For example, the plasticizer-treated mushroom mycelium pad can be washed with distilled water and then dried at 60° C. for 1 hour.

The mushroom mycelium pad plasticizer treatment step can be performed by a plasticizer treatment device.

The mushroom mycelium pad plasticizer treatment device can be very similar to the pretreatment device described above. The pretreatment device and the plasticizer treatment device can be used together, provided there is no problem with mixing the solutions.

FIG. 7 shows the overall appearance of a mushroom mycelium pad plasticizer treatment device according to an embodiment of the present invention. Referring to FIG. 7, a mushroom mycelium pad plasticizer treatment device according to an embodiment of the present invention is a device that plasticizes a mushroom mycelium pad after modifying the surface of the mushroom mycelium pad, and may include a water tank (210) (also called a plasticizer water tank or a second water tank), a support part (220), and a bubble supply part (230).

The tank (210) may have an internal space formed to accommodate a plasticizer (solution for plasticizer treatment). The tank (210) may be formed in a rectangular parallelepiped shape, but is not limited thereto. The tank (210) may have a height greater than the width or length. Accordingly, the tank (210) may provide sufficient space to accommodate the bubble supply unit (230) below. The tank (210) may be formed in a size of 1200 mm X 1200 mm X 21500 mm, but is not limited thereto.

The water tank (210) may include an inlet pipe (not shown) for supplying a plasticizer and/or a discharge pipe (211) for discharging the plasticizer. The inlet pipe (not shown) and the discharge pipe (211) may be formed on the side of the water tank (210). The inlet pipe (not shown) and the discharge pipe (211) may be combined with a valve to selectively open and close the water passage inside.

The water tank (210) may include an inlet pipe (not shown) for supplying a plasticizer and/or a discharge pipe (211) for discharging the plasticizer. The inlet pipe (not shown) and the discharge pipe (211) may be formed on the side of the water tank (210). The inlet pipe (not shown) and the discharge pipe (211) may be combined with a valve to selectively open and close the water passage inside.

A stand (212) may be combined inside the tank (210). The stand (212) may support a support (220) inserted into the tank (210) to be immersed in a plasticizer. The stand (212) may be formed on an inner wall of the tank (210). The stand (212) may be formed to be long along the inner wall of the tank (210). The stand (212) may be formed so as not to cover the bubble supply part (230) of the tank (210). The stand (212) may be formed in multiples. The stand (212) may be formed on two inner walls of the tank (210) facing each other.

The plasticizer may include at least one of propylene carbonate and ethyl alcohol. The plasticizer may include propylene carbonate at a concentration of 100%. The plasticizer may include ethyl alcohol at a concentration of 70%. The volume ratio of propylene carbonate and ethyl alcohol contained in the plasticizer may be 6.5:3.5 to 7.5:2.5. Most preferably, the volume ratio of propylene carbonate and ethyl alcohol may be 7:3.

FIG. 8 illustrates a support (220) of a mushroom mycelium pad plasticizer treatment device according to an embodiment of the present invention. Referring to FIG. 8, the support (220) can support a mushroom mycelium pad (10) immersed in a plasticizer. The support (220) can support the upper and/or lower portion of the mushroom mycelium pad (10). The support (220) is formed in multiples, and each support (220) can support one mushroom mycelium pad (10).

The support member (220) may include a clamp (221). The clamp (221) may be capable of holding at least a portion of the mushroom mycelium pad (10). The clamp (221) is formed with a structure capable of opening and closing, and the clamp (221) may include a pair of members capable of opening and closing each other. The mushroom mycelium pad (10) is placed between the pair of members that are opened from each other, and the mushroom mycelium pad (10) may be fixed as the pair of members close to each other.

The support member (220) may include a pair of clamps (221) (upper clamp and lower clamp) that respectively grip the upper and lower portions of the mushroom mycelium pad (10). Accordingly, the mushroom mycelium pad (10) may be maintained smoothly within the tank member (210). The pair of clamps (221) may be formed in multiples.

A plurality of mushroom mycelium pads (10) can be immersed in a plasticizer at once by means of a support member (220). The support members (220) are formed in plurality, and each support member (220) supports one mushroom mycelium pad (10), and a plurality of mushroom mycelium pads (10) can be inserted into the tank member (210) at once. The plurality of mushroom mycelium pads (10) can be arranged in parallel to each other.

The support member (220) may include a clamp (221) and a connecting member (222).

As described above, the clamp (221) can grip at least a portion of the mushroom mycelium pad (10). The clamps (221) can be formed in multiples. The clamps (221) can be formed in a pair. The clamps (221) can include an upper clamp that grips an upper portion of the mushroom mycelium pad (10) and a lower clamp that grips a lower portion of the mushroom mycelium pad (10). Each of the upper clamps and the lower clamps can be formed in multiples.

A plurality of mushroom mycelium pads (10) can be supported by the support member (220), and each of the mushroom mycelium pads (10) can be fixed by the upper clamp and the lower clamp. The plurality of mushroom mycelium pads (10) can be arranged parallel to each other. The plurality of mushroom mycelium pads (10) can be arranged spaced apart from each other.

The connecting portion (222) can connect a plurality of clamps (221) to each other. The connecting portion (222) can include at least one of an upper connecting portion and a lower connecting portion. The upper connecting portion can connect a plurality of upper clamps, and the lower connecting portion can connect a plurality of lower clamps. According to the connecting portion (222), a plurality of mushroom mycelium pads (10) can be easily immersed in a plasticizer at once.

In Fig. 8, the connecting portion (222) is depicted as a square ring, but the shape of the connecting portion (222) is not limited in the present invention.

FIG. 9 is a side view of a mushroom mycelium pad plasticizer treatment device according to an embodiment of the present invention.

Referring to FIGS. 7 and 9, the bubble supply unit (230) is coupled to the water tank unit (210) and can supply air bubbles (A) to the mushroom mycelium pad (10). That is, the bubble supply unit (230) can supply air bubbles (A) to the mushroom mycelium pad (10) immersed in a plasticizer. As a result, the plasticizer can effectively act on the mushroom mycelium pad (10).

The bubble supply unit (230) may include a pipe (231) and a nozzle (232). The bubble supply unit (230) may further include a blower (233).

The pipe (231) is arranged on the bottom of the water tank (210) and can move air. The pipe (231) is formed by a plurality of pipes, and each of the pipes can be connected to each other. For example, the pipe (231) can include a plurality of horizontal pipes and a vertical pipe connecting the plurality of horizontal pipes. At least a part (231a) of the pipe (231) can be connected to the outside of the water tank (210). That is, at least a part (231a) of the pipe (231) can penetrate the side surface of the water tank (210). At least a part (231a) of the pipe (231) can protrude outward from the side surface of the water tank (210).

Referring to FIG. 9, the pipe (231) may be positioned below the stand (212) installed in the water tank (210). Accordingly, the pipe (231) can effectively supply air bubbles (A) to the mushroom mycelium pad (10) positioned above the stand (212).

FIG. 10 is a top view showing a mushroom mycelium pad plasticizer treatment device according to an embodiment of the present invention. Referring to FIG. 10, a pipe (231) and a mushroom mycelium pad (10) may be arranged vertically. In addition, a pipe (231) and a clamp (221) may be arranged vertically. In particular, a cross-section of the pipe (231) and a clamp (221) may be arranged vertically. A plurality of mushroom mycelium pads (10) may be arranged to be spaced apart from each other along the extension direction of the pipe (231). Accordingly, air bubbles (A) may be supplied to the spaced apart spaces between the mushroom mycelium pads (20), and the probability of contact between the mushroom mycelium pads (10) and the air bubbles (A) may be increased.

The nozzle (232) is a part that ejects air bubbles (A), is connected to the pipe (231), and may be formed in multiple numbers. The nozzle (232) may include an ejection hole. A plurality of nozzles (232) may be spaced apart from each other. In FIG. 7, etc., the nozzle (232) is illustrated as protruding from the outer surface of the pipe (231), but is not limited thereto, and the nozzle (232) may be formed on the same plane as the outer surface of the pipe (231) and may not protrude. In this case, the ejection hole of the nozzle (232) may be formed directly in the pipe (231).

The direction of the nozzle (232) may be variable. Here, the direction of the nozzle (232) may be the direction pointed by the ejection hole. The direction in which the air bubbles (A) are supplied may change depending on the direction of the nozzle (232). The plurality of nozzles (232) may operate independently of each other, and the directions of the plurality of nozzles (232) may be changed independently of each other. For example, the amount of air bubbles (A) contact may be small for the mushroom mycelium pad (10) located at the very end (or adjacent to the inner surface of the tank portion (210)), and to compensate for this, the direction of a part of the nozzle (232) may be changed so that the amount of air bubbles (A) supplied to the mushroom mycelium pad (10) located at the very end (or adjacent to the inner surface of the tank portion (210)) increases.

To change the direction of the nozzle (232), the nozzle (232) may include a driving unit. Here, the nozzle (232) may include a main body, a jet hole, and a driving unit. The main body may be a pipe extending from the pipe (231). The jet hole may be formed inside the main body so as to communicate with the inside of the pipe (231). The driving unit may be coupled to the main body to change the angle of the main body (angle with respect to the pipe (231)).

A blower (233) can be connected to a pipe (231) to supply air. The blower (233) can be coupled to at least a portion (231a) of a pipe (231) connected to the outside of the water tank (210). At least one of an on/off state of air supply, air flow rate, air pressure, and air flow rate can be changed by the operation of the blower (233).

The bubble supply unit (230) may further include a control unit. The control unit may control the blower (233). The control unit may control the blower (233) to change at least one of the on/off state of the air supply, the air movement speed, and the air pressure. The control unit may control the direction of the nozzle (232). The control unit may control the driving unit of the nozzle (232) to change the direction of the nozzle (232).

According to an embodiment of the present invention, a mushroom mycelium pad plasticizer treatment device may further include an elevating unit (240). The elevating unit (240) may elevate the support unit (220) up and down. The elevating unit (240) may include a hook unit (241) and a wire unit (242). The elevating unit (240) may include a ceiling unit (240a), a hook unit (241), and a wire unit (242).

The ceiling part (240a) may be located on the upper part of the water tank part (210). The ceiling part (240a) may be formed in a flat plate shape. The ceiling part (240a) may be coupled to a frame (240b) installed on the water tank part (210). The water tank part (210) and the frame (240b) may be detachable from each other.

The hook part (241) can be installed so as to be liftable on the ceiling part (240a). If the lifting part (240) does not include the ceiling part (240a), the hook part (241) can be coupled to the end of the crane. The hook part (241) can include a hook shape. A separate driving device is coupled to the hook part (241), and the driving device can lift the hook part (241) up and down.

The wire portion (242) can be coupled to the support portion (220). Specifically, the wire portion (242) can be coupled to the connection portion (222) of the support portion (220). The wire portion (242) can be coupled to at least one point of the connection portion (222). The wire portion (242) and the connection portion (222) can be detachable. However, the present invention is not limited thereto, and the wire portion (242) can be fixed to the connection portion (222).

The wire part (242) can be hooked by the hook part (241), and accordingly, the hook part (241) and the support part (220) can move together. As the hook part (241) rises and falls, the support part (220) coupled to the wire part (242) can rise and fall together with the hook part (241).

The mushroom mycelium pad (10) can be mounted on the support member (220) while the hook member (241) is raised. Once the mounting is complete, the hook member (241) is lowered and the mushroom mycelium pad (10) can be plasticized with a plasticizer within the water tank member (210).

Referring to FIG. 9, the hook portion (241) may be lowered to position the support portion (220) within the water tank portion (210). Here, the support portion (220) may be positioned on the stand (212) of the water tank portion (210). In this case, the load acting on the hook portion (241) and the wire portion (242) may be eliminated. The wire portion (242) may be removed from the support portion (220) as needed. Alternatively, the hook portion (241) may terminate the hooking of the wire portion (242).

However, the stand (212) is not an essential component, and the stand (212) may not be provided within the tank (210). At this time, the hook part (241) can continuously hold the support part (220) so that the support part (220) is in a fixed position within the tank (210), and the support part (220) can be fixed at a predetermined position.

Meanwhile, after the plasticizer treatment is completed, the hook part (241) hooks the wire part (242), and the hook part (241) rises to detach the support part (220) from the tank part (210). The mushroom mycelium pad (10) can be detached from the raised support part (220).

The mushroom mycelium pad thermocompression step (step 5) (S500) is a step of thermocompression-bonding a plasticized mushroom mycelium pad. Accordingly, the moisture content of the mushroom mycelium pad can be reduced, and the thickness of the mushroom mycelium pad can be reduced. In addition, the density of the mushroom mycelium pad can be increased, and the strength of the mushroom mycelium pad can be increased. The thermocompression step can be performed at 100 to 120°C, 500 to 1000 psi, and for 5 to 15 minutes, but is not limited thereto.

In the mushroom mycelium pad thermocompression step (step 5) (S500), the mushroom mycelium pad is placed between a pair of thermocompression plates, and the mushroom mycelium pad can be thermocompression-bonded as force is applied to at least one of the pair of thermocompression plates.

The mushroom mycelium pad thermocompression step can be performed by a thermocompression device.

Fig. 11 shows a cross-section of a thermocompression device according to an embodiment of the present invention. Referring to Fig. 11, a mushroom mycelium pad thermocompression device according to an embodiment of the present invention may include a pair of thermocompression plates (310, 320) and a waste liquid receiving tank (330).

A pair of thermocompression plates (310, 320) is configured to thermocompression-bond a mushroom mycelium pad (10). The pair of thermocompression plates (310, 320) are in close contact with each other with the mushroom mycelium pad (10) interposed therebetween, and may include an upper thermocompression plate (310) positioned at the top and a lower thermocompression plate (320) positioned at the bottom. Each thermocompression plate may be formed as a square plate, but is not limited thereto. Each thermocompression plate may be formed of metal, but is not limited thereto.

At least one of the upper thermocompression plate (310) and the lower thermocompression plate (320) can provide heat to the mushroom mycelium pad (10). That is, at least one of the upper thermocompression plate (310) and the lower thermocompression plate (320) can include a heat plate to which heat is supplied.

One of the upper thermocompression plate (310) and the lower thermocompression plate (320) can be pressed inward. For example, a mushroom mycelium pad (10) can be positioned on the lower thermocompression plate (320) and the upper thermocompression plate (310) can be pressed downward. Accordingly, the mushroom mycelium pad (10) can be hardened.

A pair of thermocompression plates (310, 320) may be coupled with a rotary drive unit (340). By the rotary drive unit (340), the upper thermocompression plate (310) and/or the lower thermocompression plate (320) may rotate, and the upper thermocompression plate (310) and the lower thermocompression plate (320) may be brought into close contact with each other.

Fig. 12 shows a lower thermocompression plate (320) of a thermocompression device according to an embodiment of the present invention. As shown in Fig. 12, a through hole (321) may be formed in the lower thermocompression plate (320). The through hole (321) may penetrate the lower thermocompression plate (320) in the thickness direction. A plurality of through holes (321) may be formed, and the plurality of through holes (321) may be arranged to be spaced apart from each other.

The waste liquid receiving tank (330) is located at the bottom of the lower thermocompression plate (320) and can receive waste liquid (F) generated during thermocompression of the mushroom mycelium pad (10). The waste liquid receiving tank (330) can include a space (S) capable of receiving waste liquid (F) and a bottom and side walls surrounding the space (S). The bottom of the waste liquid receiving tank (330) can be formed to be inclined.

When the mushroom mycelium pad (10) is thermo-compression-bonded, moisture contained in the mushroom mycelium pad (10) can be discharged, and waste liquid (F) derived therefrom can be discharged to the outside of the edge of the lower thermo-compression plate (320). The waste liquid receiving tank (330) can receive this waste liquid (F), and for this purpose, the waste liquid receiving tank (330) can be formed with a larger area than the lower thermo-compression plate (320). That is, the waste liquid receiving tank (330) can be formed larger than the lower thermo-compression plate (320) so as to receive the waste liquid (F) flowing out between the upper thermo-compression plate (310) and the lower thermo-compression plate (320) during thermo-compression.

The lower thermocompression plate (320) may include a plurality of through holes (321) penetrating the upper and lower portions so that waste liquid (F) generated during thermocompression can move to a waste liquid container (330).

When a through hole (321) is formed in the lower thermocompression plate (320), the waste liquid (F) can move toward the waste liquid receiving tank (330) through the through hole (321).

Fig. 13 shows another cross-section of a thermocompression device according to an embodiment of the present invention. Referring to Fig. 13, a stopper (360) may be formed on the lower thermocompression plate (320). The stopper (360) may be formed to be long along the perimeter of an edge of the lower thermocompression plate (320). According to the stopper (360), a predetermined space is provided between the upper thermocompression plate (310) and the lower thermocompression plate (320), and the waste liquid (F) may be confined inside the stopper (360) and may not be discharged to the outside beyond the edge of the lower thermocompression plate (320). The waste liquid (F) may move toward the through hole (321). In addition, in this case, the waste liquid holding tank (330) may be formed to have a size equal to or smaller than that of the lower thermocompression plate (320). Of course, it is not limited to this, and it is not excluded that the waste liquid holding tank (330) may be formed with a larger area than the lower thermocompression plate (320). That is, if a stopper (360) is formed on the lower thermocompression plate (320), the degree of freedom in the size of the waste liquid holding tank (330) may increase.

The waste liquid container (330) may further include a waste liquid discharge port (331). The waste liquid discharge port (331) may move the waste liquid (F) contained therein to the outside. The waste liquid discharge port (331) may be formed on a side wall of the waste liquid container (330). The waste liquid discharge port (331) is formed as a hole in the side wall of the waste liquid container (330), and the hole may be connected to a space (S) of the waste liquid container (330). The waste liquid discharge port (331) may include a protrusion (332) extending from the side wall of the waste liquid container (330), and the protrusion (332) may be formed to surround the hole. In one embodiment, a separate hose may be coupled to the protrusion (332), and the waste liquid (F) may be discharged to the outside along the hose.

The bottom of the waste liquid tank (330) may be formed to be inclined, and the inclined surface may face downward toward the waste liquid discharge port (331). Accordingly, the waste liquid (F) may move toward the waste liquid discharge port (331) by gravity.

The waste solution container (330) may further include a display unit (350). The display unit (350) may display at least one of a thermocompression temperature, a pressure, and a time. The thermocompression temperature may be the temperature of the thermocompression plates (310, 320). The thermocompression pressure may be the size of the force with which the thermocompression plates (310, 320) are pressed together. The thermocompression time may be the time for heating and/or pressurizing. The display unit (350) may be installed on the rear side of a pair of thermocompression plates (310, 320), but is not limited thereto.

The method for manufacturing a sheet using a mushroom mycelium pad according to the present invention may further include a post-processing step (S600). The post-processing step (S600) may include at least one of coating, dyeing, and painting. Coating is to coat the mushroom mycelium pad with a coating solution. Dyeing is to color the mushroom mycelium pad. Painting is to apply color to the surface of the mushroom mycelium pad.

According to the method for manufacturing a sheet using the mushroom mycelium pad according to the present invention described above, a mushroom mycelium sheet can be manufactured, and the mushroom mycelium sheet can be used as a substitute for leather.

The scope of protection of the present invention is not limited to the description and expression of the embodiments explicitly described above. In addition, it is added once again that the scope of protection of the present invention may not be limited due to obvious changes or substitutions in the technical field to which the present invention belongs.

10: Mushroom mycelium pad
110: Tank for pretreatment device
120: Support for preprocessing device
130: Bubble supply unit for pretreatment device
140: Lift for pre-treatment device
210: Tank for plasticizer treatment device
220: Support for plasticizer treatment device
230: Bubble supply unit for plasticizer treatment device
240: Lifting section for plasticizer treatment device
310: Upper thermocompression plate
320: Lower thermocompression plate
330: Wastewater treatment tank

Claims (8)

In a device for pretreating a mushroom mycelium pad before modifying the surface of the mushroom mycelium pad,
A tank section where pre-treated water is received;
A support member that collectively supports a plurality of mushroom mycelium pads immersed in the above pretreatment water; and
It includes a bubble supply unit that is connected to the water tank unit so as to be positioned on the lower side of the support unit and supplies air bubbles toward the mushroom mycelium pad.
The above support member,
A plurality of clamps for holding the upper and lower ends of each mushroom mycelium pad so that the plurality of mushroom mycelium pads are maintained smoothly within the tank while being completely immersed in the pretreatment water; and
Including a connecting part that supports and connects the above plurality of clamps,
The above-mentioned plurality of mushroom mycelium pads are arranged parallel to each other with one side facing each other and spaced apart from each other,
The air bubbles supplied from the bubble supply unit are supplied between the plurality of mushroom mycelium pads, and hit each mushroom mycelium pad so that the entanglement of the mushroom mycelium is loosened.
A pretreatment device for manufacturing mushroom mycelium sheets.
delete delete In the first paragraph,
Further including a lifting unit that raises and lowers the above support unit,
A pretreatment device for manufacturing mushroom mycelium sheets.
In the first paragraph,
The above bubble supply unit,
A pipe arranged on the bottom of the above tank to move air; and
Comprising a plurality of nozzles coupled to the above pipe,
A pretreatment device for manufacturing mushroom mycelium sheets.
In paragraph 5,
The above bubble supply unit,
A blower coupled to the above pipe; and
Further comprising a control unit for controlling the above blower,
A pretreatment device for manufacturing mushroom mycelium sheets.
In paragraph 5,
The direction of the above nozzle is variable,
A pretreatment device for manufacturing mushroom mycelium sheets.
In the first paragraph,
The above pretreatment water contains distilled water,
A pretreatment device for manufacturing mushroom mycelium sheets.

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