KR101921976B1 - Mushroom cultivation vessel - Google Patents

Abstract

The present invention relates to a mushroom cultivation container. The mushroom cultivation container comprises: a container body which has an internal space to accommodate a mushroom medium, and is opened upwards through an inlet; and a cap to cover the inlet of the container body. A guide wing unit is formed on the inner circumferential surface of the inlet of the container body to guide a flow of gas rising from the bottom of the container body to move upwards along an inner wall to move the gas towards the center of the inlet. A growth guide pipe is arranged on the center of the cap to open the internal space of the container body upwards and provide a growth passage of mushroom, has a shape of a vertically extended hollow pipe, and allows a lower end thereof to be extended downwards towards the internal space to form an air mixing area between the guide wing unit and the same. The mushroom cultivation container applies a physical effect when a mushroom grows to produce a high-grade mushroom with good appearance. Also, an objective of the present invention is to provide a mushroom cultivation container which effectively replaces heat and carbon dioxide produced therein with outside fresh air to maintain an optimal growth environment that allows active growth.

Description

Mushroom cultivation vessel

The present invention relates to a mushroom cultivation container used for cultivating mushroom, and more particularly, to a mushroom cultivation container that provides an internal environment suitable for mushroom growing conditions.

As a method of cultivating mushrooms, there is known a method of cultivating logs in trees using hardwoods or the like and cultivating them in a facility equipped with certain facilities. However, although the above-mentioned log production method has an advantage that it is easy to manage, it has a disadvantage in that productivity is not good, it is difficult to purchase logs and labor costs are high. Accordingly, recently, a method of cultivating a mushroom cultivation vessel in which a sawdust culture medium of wood logs is put and inoculated is cultivated has been proposed.

The mushroom cultivation method using the medium is a popular method of cultivation in recent years because the weight and size of the medium can be adjusted so as to be suitably handled by the operator and cultivation of the mycelium is easy.

On the other hand, there are various kinds of mushroom cultivation containers accommodating the culture medium. Such a mushroom cultivation vessel facilitates the discharge of heat or carbon dioxide generated during the growth of the mushroom, and is designed such that the temperature distribution inside the vessel is as uniform as possible. This is because the propagation of the seeds becomes vigorous only if the ventilation of the air is smooth.

In view of the above, the inventors of the present application have proposed a mushroom cultivation vessel (Korean Patent Registration No. 10-1710585). The mushroom cultivation vessel comprises a mushroom culture medium carrier in the form of a flat bowl and a mushroom culture lid covering the mushroom culture medium carrier and having a plurality of container air circulation units. Further, mushroom growth passages are formed in each of the container air circulation units.

However, since the conventional mushroom cultivation vessel can grow several mushrooms at a time, the productivity is good. However, since the container air circulation part is separated from the wall surface of the mushroom culture medium carrier part, Air exhaust is not smooth.

In addition, since the distance between the circulation flow hole and the bottom surface of the container is close to each other, external cool air can easily reach the bottom surface of the container.

Patent Registration No. 10-1710585 (mushroom cultivation vessel)

The present invention provides a mushroom cultivation vessel which is easy to discharge heat and carbon dioxide generated according to the growth of mushroom and blocks the descending of the introduced external air to provide optimal growth conditions. There is purpose in.

In order to accomplish the above object, a mushroom cultivation vessel of the present invention comprises a container body having an inner space for accommodating a mushroom culture medium, the container body being opened upward through an inlet portion, and a cap covering the inlet portion of the container body, Wherein a guide vane portion is formed on an inner circumferential surface of an inlet portion of the container body for guiding a flow of gas upwardly moving from the bottom of the container body to ride on the inner wall surface to allow the gas to move toward the center of the inlet portion, The cap has a central portion that opens upwardly into the interior space of the container body and provides a growth passageway for the mushroom. The cap has a hollow pipe extending in a vertical direction and a lower end extending downward toward the interior space, And a growth guide pipe for forming an air mixing zone therebetween.

In addition, a growth inducing protrusion for guiding the growth of the mushroom by applying a physical force to the mushroom passing through the growth path is formed in the inner side of the growth guide pipe.

In addition, a plurality of diaphragms extending in the radial direction around the growth guide pipe and forming a vortex in the gas by colliding with the gas around the growth guide pipe are provided on the bottom of the cap.

The diaphragm is a band-shaped member having a predetermined width, one end in the width direction is fixed to the bottom of the cap, and the other end of the diaphragm is formed with vortex-accelerating grooves for promoting vortex of the gas.

The inlet portion is formed with a plurality of fitting slits for accommodating the diaphragm therein when the cap is coupled to the container body so that the upper end of the inlet portion is brought into close contact with the bottom portion of the cap.

In addition, the upper part of the cap is provided with a collecting disk which is kept attached to the cap until collecting the mushroom, and is separated from the cap together with the mushroom when collecting the mushroom. On the upper surface of the cap, A plurality of disk spacing protrusions spaced apart from the upper surface of the disk are formed.

The mushroom cultivation vessel of the present invention having the above-described structure can produce a mushroom of the upper grade having a good appearance by applying a physical influence upon the growth of the mushroom, and it is also possible to replace the heat and carbon dioxide generated inside, The present invention is directed to a mushroom cultivation vessel capable of maintaining vigorous growth by maintaining an optimal growth environment.

1 is a partially cutaway perspective view of a mushroom cultivation vessel according to an embodiment of the present invention.
Fig. 2 is a sectional view of the mushroom cultivation vessel shown in Fig. 1. Fig.
3 is a perspective view showing a modified example of the cap shown in FIG.
4 is an exploded perspective view showing another example of a mushroom cultivation container according to an embodiment of the present invention.
FIG. 5 is a view showing a cultivation of mushroom using a mushroom cultivation container according to an embodiment of the present invention.

Hereinafter, one embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

Basically, the mushroom cultivation vessel 11 according to the present embodiment is excellent in the heat exchange efficiency between the gas such as heat or carbon dioxide generated inside the vessel body 13 and the fresh air flowing into the vessel 11 Even if new air flows into the container, the temperature inside the container 11 can be maintained at the ambient temperature or higher.

The fact that the internal temperature does not fall even when fresh outside air flows into the container 11 means that the growth temperature of the mushroom can be maintained at an optimum level. The mushroom cultivation vessel of this embodiment having such a structure can naturally be used for the cultivation of various mushrooms, and in particular, it can be efficiently used for cultivation of the mushroom.

FIG. 1 is a partially cutaway perspective view of a mushroom cultivation vessel according to an embodiment of the present invention, and FIG. 2 is a sectional view of the mushroom cultivation vessel shown in FIG. 1.

As shown in the figure, the mushroom cultivation vessel 11 according to the present embodiment includes a container body 13 having an internal space 13a for accommodating a mushroom culture medium (not shown) and opening upward through an inlet portion 13b, And a cap 17 covering the container body 13 and providing the growth path 17a of the mushroom.

The mushroom growing from the mushroom culture medium accommodated in the container body 13 passes through the growth passage 17a according to its growth and is placed on the upper part of the collecting disk 21 to be described later. When the collecting disk 21 is lifted from the cap 17, the mushroom (A in Fig. 5) is collected.

First, the container body 13 takes the form of a cylinder and is opened upward through an inlet portion 13b. The inlet portion 13b is a passage for opening the inner space 13a and has a support protrusion 13d on the outer circumferential surface thereof.

The support jaw 13d is a protrusion extending along the circumferential direction on the outer circumferential surface of the inlet portion 13b and serves to hang the engagement protrusion 17d formed on the cap 17 thereunder. When the cap 17 is completely engaged with the inlet portion 13b, the engagement protrusion 17d is caught by the lower portion of the support protrusion 13d to prevent the cap 17 from being released.

Particularly, the guide wing 13c is located at the upper end of the inlet 13b. The guide vane 13c is curved inwardly toward the upper side, for example, a gas such as heat or carbon dioxide rising from the bottom of the container main body 13 (hereinafter referred to as an internally generated fluid) is guided toward the center side . The central portion is a central portion of the inlet portion 13b and is a portion where the growth guide pipe 17b is located when the cap 17 is placed on the container body 13. [

The reason why the guide vane portion 13c bent inward at the upper end of the inlet portion 13b is positioned is that the inner generated fluid rising from the bottom of the container main body 13 flows into the container main body 13 due to the nature of the gas, And that it is easy to ascend on the inner wall of the wall. In fact, in a situation where the mushroom medium occupies the inner space 13a, the internally generated fluid generated from the lower part of the mushroom medium can not pass through the space between the mushroom medium and the inner wall surface of the container body, Rise.

The guide vane portion 13c may have a flexible property. For example, the cap 17 may be left standing up to some extent before the cap 17 is put on the cap 17, and may be pressed by the base 17n of the cap to bend the cap 17 in the direction of arrow a. In addition, the inward curved surface of the guide vane 13c, that is, the width of the guide surface, may also vary depending on the case.

On the other hand, the cap 17 is a lid which covers the inlet 13b of the container body 13 and has a growth guide pipe 17b at its center. The growth guide pipe 17b provides a growth passage 17a as a vertically extending hollow pipe member. The upper end of the growth guide pipe 17b projects at a height of 5 mm or less from the upper surface of the cap 17.

The growth passage 17a is a passage having a predetermined inner diameter, and serves as a passage through which mushrooms grow as well as through which air flows. The mushroom grown from the mushroom culture medium is placed at the top of the cap 17 through the growth path 17a.

A bending protrusion 17f is formed at the lower end of the inner circumferential surface of the growth guide pipe 17b and a plurality of growth inducing protrusions 17c are located on the inward surface of the bending protrusion 17f.

The bending protrusion 17f serves to support the growth inducing protrusion 17c so as to protrude further in the direction of the center axis of the growth path 17a and to prevent the mushroom passing through the growth path 17a from being in contact with the growth path 17a Thereby preventing tight contact with the inner circumferential surface. Due to the presence of the bending protrusion 17f, at least the portion that extends over the bending protrusion 17f is spaced from the inner circumferential surface of the growth guide pipe 17b.

The growth inducing protrusions 17c serve to guide the growth of mushrooms. For example, when the mushroom grows and passes through the growth pathway (17a), it exerts a physical force on the mushroom to prevent the structure of the mushroom stem from being entangled. And the mushroom stem is made straight by the growth inducing protrusion 17c.

A plurality of ventilation holes 17p may be formed in the growth guide pipe 17b. The ventilation hole 17p is a through hole connecting the inside and the outside of the growth guide pipe 17b, and an internally generated fluid or fresh new incoming air can pass through the through hole. The number of the ventilating holes 17p is determined according to the size of the mushroom cultivation container 11 and the type of the mushroom, because heat loss may occur if the number of the ventilating holes 17p is increased.

Particularly, as shown in FIG. 2, the lower end of the growth guide pipe 17b extends vertically downward to form an air mixing zone 13e between the inner periphery of the inlet and the inner circumference.

The air mixing zone 13e is a space in which the internally generated fluid coming from the bottom of the container body 13 and the air flowing downward from the outside through the growth channel 17a are mixed.

The air newly introduced from the outside flows out to the lower portion of the growth guide pipe 17b and spreads in the radial direction, and almost all of the air flows into the upward flow of the internally generated fluid and is guided to the air mixing zone 13e.

The air introduced into the air mixing zone 13e is heat-exchanged with the internally generated fluid and heated. The air heated in the air mixing zone 13e is lower in temperature than the temperature of the internally generated fluid coming from the bottom portion, so that the air moves down to the bottom portion of the container main body 13.

As a result, the temperature of the upper end portion of the container body 13 can be kept at least higher than the outside air due to the above-described air mixing zone 13e. It goes without saying that when the temperature inside the container body 13 is lowered, normal growth of the mushroom becomes difficult.

The internally generated fluid that is stirred in the air mixing zone 13e passes through the ventilation hole 17p or bypasses the lower end of the growth guide pipe 17b and is discharged upward through the growth path 17a . Particularly, due to the action of the ventilation hole 17p, the stagnation phenomenon of the fluid in the air mixing zone 13e does not occur, and rapid discharge is possible.

The above-mentioned circulation of the gas is based on the principle that ventilation of air inside and outside the building is performed when the window of the building is opened.

On the other hand, a plurality of latching protrusions 17d are formed on the inward-facing wall portion 17m formed at the rim of the cap 17. As shown in Fig. 2, the latching jaw 17d is engaged with the lower portion of the supporting jaw 13d, and maintains the engagement of the cap 17 with respect to the container body 13.

In addition, a plurality of disk spacing protrusions 17e are disposed on the upper surface of the cap 17. The disk spacing protrusion 17e is a protruding portion disposed on the opposite side of the growth guide pipe 17b with respect to the center of the growth guide pipe 17b. The disk spacing protrusion 17e serves to float the collecting disk 21 from the cap 17 at regular intervals.

The reason why the collecting disk 21 is not brought into close contact with the cap 17 is to allow air to communicate with the lower portion of the collecting disk 21. 5, when the mushroom A supported on the collecting disk 21 grows and the inside of the container body 13 is opened, Is not transmitted.

The collecting disk 21 is a transparent plastic disk covering the top of the cap 17, and has a support hole 21a at the center thereof. The support hole 21a is a hole for receiving a growth guide pipe 17b protruding to the top of the cap.

The harvesting disc 21 is held in the upper portion of the cap 17 until the mushroom is picked up, and is separated from the cap 17 as shown in FIG. 5 when the mushroom is picked up. And is used as a tool for removing mushrooms from the container body 13.

3 is an inverted perspective view showing a modified example of the cap 17 shown in Fig.

As shown in the drawing, a plurality of partition plates 17g are integrally formed on the bottom surface portion 17n of the cap 17. [ The diaphragm 17g takes the form of a strip or a rectangular plate having a constant width and is formed in the bottom face 17n in a widthwise direction. That is, one end in the width direction is fixed to the bottom surface portion 17n and the other end is directed to the inner space of the container main body 13.

The diaphragm 17g is equiangularly disposed in the radial direction around the growth guide pipe 17b. Particularly, a wing portion inserting space 17k is secured between each of the partition plates 17g and the inward wall portion 17m. The wing portion inserting space 17k is a free space into which the guide wing portion 13c is inserted when the cap 17 is put on the container body 13. [

The diaphragm 17g collides with the gas inside the periphery of the growth guide pipe, that is, inside the air mixing zone 13e, thereby forming a vortex in the gas, thereby enhancing heat exchange efficiency. The gas in the air mixing zone 13e has a very complicated turbulent flow, and sometimes even revolves around the growth guide pipe 17b, which collides with the revolving gas to form a vortex.

In addition, vortex-accelerating grooves 17h are formed in each of the diaphragms 17g in order to facilitate the generation of the vortex. The vortex-accelerating groove 17h is a groove formed by recessing a part of the partition plate 17g, allowing the gas to more easily pass through the partition plate and generate a vortex.

4 is an exploded perspective view showing another example of a mushroom cultivation container according to an embodiment of the present invention.

The same reference numerals as those of the above-mentioned reference numerals indicate the same members having the same function.

Referring to the drawing, it can be seen that the diaphragm 17g extends further in the radial direction and contacts the inward wall 17m. Since the both end portions of the diaphragm 17g are fixed to the inward wall portion 17m and the growth guide pipe 17b as described above, the diaphragm 17g functions as a rib. That is, the structural strength of the cap 17 is reinforced. When the strength of the cap 17 is reinforced, the durability is improved, and even if the cap 17 is used many times, it is free from deformation.

As the diaphragm 17g has the above structure, a plurality of fitting slits 13f are formed at the inlet portion of the container body 13. [ The fitting slit 13f is a groove for receiving the diaphragm 17g when the cap 17 is coupled to the container body 13. [ By forming the fitting slit 13f in this manner, the upper end portion of the guide vane portion 13c can be brought into close contact with the bottom face portion 17n without any abnormality.

FIG. 5 is a view showing reference to a cultivation of mushroom (A) using a mushroom cultivation vessel 11 according to an embodiment of the present invention.

As shown in the drawing, the mushroom A is placed on the upper part of the collecting disk 21. The mushroom A is connected to a medium placed inside the container body 13, but the stem portion is cut off as the collecting disk 21 is separated from the cap 17.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

11: mushroom cultivation vessel 13: vessel body
13a: Inner space 13b:
13c: guide wing 13d: support jaw
13e: air mixing zone 13f: fitting slit
17: cap 17a: growth path
17b: Growth guide pipe 17c: Growth inducing protrusion
17d: engaging jaw 17e: disc-separating projection
17f: bending protrusion 17g: diaphragm
17h: vortex acceleration groove 17k: wing portion insertion space
17m: inward wall portion 17n: bottom wall portion
17p: Ventilation hole 21: Collection disc
21a: Support hole

Claims (6)

1. A mushroom cultivation container comprising a container body having an interior space for accommodating a mushroom culture medium and being opened upward through an inlet portion, and a cap covering the inlet portion of the container body,
An inner circumferential surface of the inlet portion of the container body is provided with a guide vane portion for guiding the flow of the gas rising from the bottom of the container body and moving upward on the inner wall surface to move the gas toward the center of the inlet portion,
The cap having a hollow pipe extending vertically and having a lower end extending downward toward the inner space so as to open the inner space of the container body upwardly and to provide a growth passage of the mushroom, And a growth guide pipe for forming an air mixing zone between the mushroom cultivation vessel and the mushroom cultivation vessel. The method according to claim 1,
Wherein a growth inducing protrusion for guiding the growth of the mushroom is formed on the inner side of the growth guide pipe by applying a physical force to the mushroom passing through the growth path. The method according to claim 1,
In the bottom portion of the cap,
And a plurality of divergent plates extending in the radial direction around the growth guide pipe and forming a vortex in the gas by colliding with gas around the growth guide pipe. The method of claim 3,
Wherein the diaphragm is a strip-shaped member having a predetermined width, one end in the width direction is fixed to the bottom of the cap, and the other end of the diaphragm is formed with vortex-accelerating grooves for promoting vortex of the gas. The method of claim 3,
In the inlet portion,
Wherein when the cap is coupled to the container body, a plurality of fitting slits are formed to accommodate the diaphragm therein so that an upper end of the inlet portion is brought into close contact with a bottom surface portion of the cap. The method according to claim 1,
The cap is further provided at the upper part thereof with a collecting disk which is attached to the cap until the mushroom is collected and is separated from the cap together with the mushroom when the mushroom is collected,
Wherein a plurality of disk spacing protrusions are formed on an upper surface of the cap to separate the sampling disc from an upper surface of the cap.

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