KR101855671B1 - Sprout cultivating device - Google Patents

Abstract

The present invention relates to a sprout cultivation apparatus capable of uniformly supplying a culture medium to a seed and maintaining the water temperature rising constantly according to germination of the seed to promote germination of the seed and growth of the sprout, and a cleaning method thereof.
To this end, the seed growing apparatus includes a plurality of seed housings in which seeds are cultured, a module housing in which the seed housings are detachably coupled, a cooling unit for cooling the culture liquid, a water storage space in which the module housing is detachably coupled, A circulation pump provided in the water storage space for pumping the culture liquid, and a circulation pump provided in the circulation pump for circulating the circulation pump, And a water supply vane that penetrates the module housing so as to move the culture liquid to the upper side of the seed housing and is connected to a water supply pipe and a water supply pipe rotatably coupled to the circulation pump and supplies the culture solution to the seed housing.

Description

{SPROUT CULTIVATING DEVICE}

The present invention relates to a sprout cultivation apparatus and a cleaning method thereof, and more particularly, to a seed sprout cultivation apparatus and a method of cleaning the sprout cultivation apparatus, And a method of cleaning the same.

In general, sprout vegetables are grown by germinating seeds. There are various kinds of sprouts such as bean sprouts, sprouts, mushrooms, buckwheat, broccoli and red cabbage. The contents of various nutrients such as vitamins and minerals are much higher than those of grown vegetables. It is in the limelight as food.

The sprout vegetable is a non-pollutant food that grows well without chemical fertilizer because of short cultivation period. It cleanses blood by reducing cholesterol on ingestion, prevents aging of the body, and has a unique flavor.

However, in the conventional sprout cultivation apparatus, water is not uniformly supplied to the seeds and the germination of the seeds is uneven. As the seed germinates, the temperature of the seeds is raised to decay the seeds before germination, and cold water of low temperature is supplied to the seeds And the germination of the seed is delayed or suppressed. In addition, since water is turbid due to the protein components contained in the seed, the number of times of water exchange in the bud growth apparatus increases, and the water is contaminated with the movement path, thereby deteriorating the quality of the bud.

Korean Registered Patent No. 10-1435976 (entitled: Multilayer Laminated Household Bud Grower, Apr. 2014, Announcement)

It is an object of the present invention to solve the problems of the prior art, and it is an object of the present invention to provide a sprout cultivation apparatus capable of uniformly supplying a culture medium to a seed and maintaining the water temperature rising constantly according to the germination of the seed to promote seed germination and sprout growth. And a cleaning method thereof.

It is another object of the present invention to provide a sprout cultivation apparatus and a cleaning method thereof that can prevent the culture liquid from being clouded by protein components contained in seeds, thereby keeping the path of the culture liquid clean.

According to a preferred embodiment of the present invention, the seedling cultivation apparatus of the present invention comprises: a plurality of seed housings in which seeds are cultured; A module housing in which the seed housing is detachably coupled; A cooling unit for cooling the culture liquid; Wherein the module housing is detachably coupled to the housing, wherein the module housing includes a water storage space in which the culture liquid is received, an installation space in which the cooling unit is installed, and a partitioning wall partitioning the storage space and the cooling unit, housing; A circulation pump provided in the water storage space to pump the culture liquid; A water supply pipe passing through the module housing and connected to the circulation pump so that the culture liquid pumped by the circulation pump is moved to the upper side of the seed housing; And a water supply vane rotatably coupled to the water supply pipe to supply a culture liquid to the seed housing, wherein the water supply vane includes a water supply header portion rotatably coupled to the water supply pipe, A plurality of water supply vanes branched from the water supply header portion; And a rotary spraying part provided at one side of the water supply part to discharge the culture solution contained in the water supply part.

Here, the partition wall is formed with a communication hole communicating the water storage space and the installation space, and the cooling unit includes a cooling plate coupled to the partition wall in the water storage space to cool the culture liquid in the water storage space, ; A sealing gasket closely inserted between the cooling plate and the partition wall; A noiseless condensing unit disposed in the installation space for discharging heat according to free circulation of the refrigerant; And a heat absorbing portion which is supported by the cooling plate and the silent condensing unit in close contact with each other via the communication hole and cools the cooling plate by a power source applied to the cooling plate in close contact therewith, And a heat dissipation unit for dissipating heat.

Here, the silencer condensing unit may include: a refrigerant tank main body having a refrigerant heat-radiating space in which refrigerant is stored; A first refrigerant pipe connected to the refrigerant heat radiating space to discharge refrigerant vaporized by heat emitted from the thermoelectric unit; A condenser connected to the first refrigerant pipe for condensing the refrigerant supplied from the first refrigerant pipe; And a second refrigerant pipe connecting the condenser to the refrigerant heat-radiating space so that the refrigerant condensed by the condenser is supplied to the refrigerant heat-radiating space.

The condensing and condensing unit may further include a condensation promoting unit provided in the refrigerant tank main body for promoting condensation of the refrigerant circulated in the refrigerant tank body, And at least one vent pipe passing through the tank body.

Here, a plurality of circulating radiating fins protrude from at least one of the refrigerant radiating space and the vent pipe.

Here, the cooling unit may further include a circulation fan provided at one side of the silent condensation unit so that air flows in the condensation unit and the ventilation pipe.

The cooling unit may further include a cooling duct connecting the silent condensation unit and the circulation fan so that air is concentrated in at least one of the condensation unit and the ventilation pipe.

Here, the culture solution housing may include a supply part communicating with the water storage space to supply the culture solution; And a discharge part communicating with the water storage space to discharge the culture liquid.

Here, the module housing may include a first module housing detachably coupled to the culture solution housing, and the seed housing detachably coupled to the inside of the module housing; And at least one second module housing detachably coupled to the first module housing and detachably coupled to the seed housing therein.

Here, the water supply pipe may include a first water supply pipe passing through the first module housing and coupled to the circulation pump so that the culture liquid pumped by the circulation pump is moved to the upper side of the seed housing; And a second water pipe passing through the second module housing while being connected to the first water pipe so that the culture liquid pumped by the circulation pump is moved to the upper side of the seed housing, And the second water pipe is rotatably coupled to the second water pipe or is rotatably coupled to the first water pipe and the second water pipe.

The seed cultivation apparatus according to the present invention comprises: a seed housing in which a seed is cultured; A cooling unit for cooling the culture liquid; Wherein the seed housing is detachably coupled to the seed storage compartment and includes a water storage space in which the culture liquid is received, an installation space in which the cooling unit is installed, and a partitioning wall partitioning the storage space and the cooling unit, housing; A circulation pump provided in the water storage space to pump the culture liquid; A water supply pipe passing through the seed housing and connected to the circulation pump so that a culture liquid pumped by the circulation pump is moved to the upper side of the seed housing; And a water supply vane rotatably coupled to the water supply pipe to supply a culture liquid to the seed housing, wherein the water supply vane includes a water supply header portion rotatably coupled to the water supply pipe, A plurality of water supply vanes branched from the water supply header portion; And a rotary spraying part provided at one side of the water supply part to discharge the culture solution contained in the water supply part.

Here, the seed housing may include a first laminated housing detachably coupled to the culture housing, and a seed is cultured; And at least one second laminated housing detachably laminated to the first laminated housing and in which the seeds are cultured.

Here, the water supply pipe may include a first water supply pipe connected to the circulation pump through the first laminated housing so that the culture liquid pumped by the circulation pump is moved to the upper side of the first laminated housing; And a second water supply pipe connected to the first water supply pipe and passing through the second laminated housing such that the culture liquid pumped by the circulation pump is moved to the upper side of the second laminated housing, And is rotatably coupled to the second water supply pipe or rotatably coupled to the first water supply pipe and the second water supply pipe.

Here, the water supply wing portions branched from the water supply header portion are respectively divided into two or more along the longitudinal direction, and the rotation jetting portion is installed in at least one of the partition regions of the water supply vane portion.

The cleaning method of the bud growth apparatus according to the present invention is characterized in that the cleaning liquid is supplied to the water storage space, the circulation pump is operated for a predetermined cleaning time so that the cleaning liquid is discharged from the water supply vane, The operation from the supply of the cleaning liquid to the discharge of the cleaning liquid is repeated one or more times.

In addition, the cleaning liquid is supplied to the water storage space, the circulation pump is operated for a preset cleaning time such that the cleaning liquid is discharged from the water supply vane, and then the cleaning liquid is discharged from the water storage space. The operation is repeated one or more times.

According to the sprout cultivation apparatus and the cleaning method thereof according to the present invention, the culture medium is uniformly supplied to the seeds, and the sprout cultivation which can promote the germination of the seeds and the growth of the sprouts by keeping the water temperature rising constantly according to the germination of the seeds And a cleaning method thereof.

In addition, according to the present invention, it is possible to rotate the water supply vane by the power of the culture liquid by non-dynamic force, and to supply the culture liquid to the seed housing substantially constantly.

In addition, the present invention can germinate a plurality of seeds through a plurality of seed housings.

Further, the present invention can smoothly discharge the culture liquid from the seed housing and prevent the culture liquid or the seed which is stagnated in the culture space from being corrupted.

Further, the present invention can smoothly discharge the culture liquid from the module housing, and prevent the culture liquid stagnating in the seating space from being corrupted.

Further, the present invention can reduce the power required for driving the cooling unit and can release the heat by natural convection of the refrigerant.

Further, the present invention can promote the condensation of the refrigerant and improve the heat exchange performance with the thermoelectric unit.

Further, the present invention can improve the heat dissipation in the coolant tank main body and facilitate the heat exchange between the coolant tank main body and the thermoelectric unit.

Further, the present invention can improve the contact area between the silent condenser unit and the air and maximize the heat radiating effect.

In addition, the present invention can automate the feeding and draining of the culture medium, the washing liquid and the washing liquid, and circulation thereof, and can uniformly cultivate the sprouts in the incubation period of the seeds.

In addition, the present invention smoothly discharges the culture solution even in one seed housing, and the culture solution can be uniformly supplied from one seed housing.

In addition, the present invention can prevent the culture liquid from being turbid due to the protein component contained in the seeds, thereby keeping the path of the culture liquid clear.

The present invention also relates to a method for removing protein components remaining in a culture space of a seed housing, a seating space of a module housing, a water storage space of a culture solution housing, a circulation pump, a water supply pipe and a water supply wing, can do.

1 is a perspective view showing a bud cultivation apparatus according to a first embodiment of the present invention.
2 is an exploded view showing a bud cultivation apparatus according to a first embodiment of the present invention.
3 is a cross-sectional view of a bud cultivation apparatus according to a first embodiment of the present invention.
4 is an enlarged cross-sectional view showing a coupled state of the cooling unit in the bud cultivation apparatus according to the first embodiment of the present invention.
5 is a cross-sectional perspective view showing the seed housing in the bud cultivation apparatus according to the first embodiment of the present invention.
6 is a cross-sectional perspective view showing a module housing in a bud cultivation apparatus according to the first embodiment of the present invention.
7 is a bottom perspective view showing a watering vane in a bud cultivation apparatus according to the first embodiment of the present invention.
8 is a plan view showing a modified example of a water supply blade in a bud cultivation apparatus according to the first embodiment of the present invention.
9 is a perspective view showing a silent condensation unit in the bud cultivation apparatus according to the first embodiment of the present invention.
10 is a cross-sectional view illustrating a coupled state according to a modification of the silent condensing unit in the bud cultivation apparatus according to the first embodiment of the present invention.
11 is a plan sectional view showing a coolant tank main body in the bud cultivation apparatus according to the first embodiment of the present invention.
12 is an exploded view showing a bud cultivation apparatus according to a second embodiment of the present invention.
13 is a cross-sectional view of a bud cultivation apparatus according to a second embodiment of the present invention.
FIG. 14 is an enlarged cross-sectional view illustrating a connection state of a water pipe in a bud cultivation apparatus according to a second embodiment of the present invention.
15 is a sectional view showing a bud cultivation apparatus according to a third embodiment of the present invention.
16 is a sectional view showing a bud cultivation apparatus according to a fourth embodiment of the present invention.
17 is an enlarged cross-sectional view showing a connection state of a water pipe in a bud cultivation apparatus according to a fourth embodiment of the present invention.

Hereinafter, an embodiment of a bud cultivation apparatus and a cleaning method thereof according to the present invention will be described with reference to the accompanying drawings. Here, the present invention is not limited or limited by the examples. Further, in describing the present invention, a detailed description of well-known functions or constructions may be omitted for clarity of the present invention.

Prior to the description of the present invention, the culture medium may be water or a mixture of water and a fermentation extract of plants. The fermented extract of the plant has a deodorizing and deodorizing function and a protein component discharged from the seed is supplied to the seed housing 10, the module housing 20, the cooling plate 31, the culture housing 40, the circulation pump 50, (60) and the water vane (70).

The protein remover mixes the protein components into the seed housing 10, the module housing 20, the cooling plate 31, the culture housing 40, the circulation pump 50, The water supply pipe 60, and the water supply vane 70 to dilute them.

Further, the cleaning liquid may be made of water. The washing liquid may dilute the washing liquid remaining in the sprout cultivation apparatus during the washing process to discharge the washing liquid from the sprout cultivation apparatus and prevent the washing liquid from flowing into the seeds housed in the seed housing 10.

FIG. 1 is a perspective view showing a sprout cultivation apparatus according to a first embodiment of the present invention, FIG. 2 is an exploded view showing a sprout cultivation apparatus according to a first embodiment of the present invention, FIG. FIG. 4 is an enlarged cross-sectional view showing a cooling unit coupled state in a sprout cultivation apparatus according to a first embodiment of the present invention, and FIG. 5 is an enlarged cross- 6 is a cross-sectional perspective view showing a module housing in a bud cultivation apparatus according to a first embodiment of the present invention, and Fig. 7 is a cross-sectional perspective view showing a first embodiment of the present invention FIG. 8 is a plan view showing a modified example of a water supply blade in a bud cultivation apparatus according to the first embodiment of the present invention, and FIG. 9 is a cross- In the sprout cultivation apparatus according to one embodiment, 10 is a cross-sectional view showing a coupled state according to a modified example of the silence condensing unit in the bud cultivation apparatus according to the first embodiment of the present invention, and FIG. 11 is a cross- Sectional view showing the coolant tank main body in the sprout cultivation apparatus according to the example.

1 to 11, a sprout cultivation apparatus according to a first embodiment of the present invention includes a plurality of seed housings 10, and includes a plurality of seed housings 10, a module housing 20, A cooling unit 30, a culture liquid housing 40, a circulation pump 50, a water supply pipe 60, and a water supply vane 70.

The seed housing 10 is open at its upper part, and a plurality of seed openings are provided. The seed housing 10 is cultivated by the culture medium. The seed housing 10 is provided with a culture space 11 in which seeds are received, a support net 12 which is seated in the culture space 11 to support the seeds, And the drainage discharge portion 13 is formed. Further, a spacing bracket 15 may protrude from the lower surface of the seed housing 10 for attachment and detachment to / from the module housing 20.

Here, the supporting net member 12 is formed with holes for discharging the culture liquid. In addition, the supporting net member 12 is provided with a grip portion 121 to allow the supporting net member 12 to be inserted and removed in the culture space 11. The grip portion 121 may protrude from the supporting net body 12. [ In addition, the seed housing 10 may further include a spacing portion 122 so that the supporting network 12 is spaced apart from the bottom of the culture space 11. The spacing portion 122 may protrude from the bottom of the supporting net 12 or the bottom of the culture space 11.

The module housing 20 is detachably coupled to the seed housing 10. In the module housing 20, a plurality of seed housings 10 are spaced from each other with respect to the center.

The module housing 20 is provided with a seating space 21 into which the seed housing 10 is inserted, a removable bracket 22 detachably supporting the seed housing 10 in the seating space 21, And a communication discharge portion 23 formed through the bottom of the seating space 21 is included. A penetration hole portion 24 for penetrating and supporting the water supply pipe 60 is formed at the bottom center of the seating space 21. In addition, a fitting bracket 25 may be formed on the lower surface of the module housing 20 for fitting with the culture solution housing 40. The fitting bracket 25 can be fitted to the inlet of the water storage space 41 of the culture liquid housing 40. Particularly, the fitting bracket 25 is inserted and supported in the water storage space 41 of the culture liquid housing 40, thereby preventing leakage of the culture liquid.

The cooling unit (30) cools the culture liquid to a predetermined culture temperature. The cooling unit (30) is provided in the culture liquid housing (40). The cooling unit 30 can release heat through natural convection of the refrigerant.

The culture housing 40 is detachably coupled to the module housing 20. The culture solution housing 40 is provided with a water storage space 41 in which the culture liquid is contained, an installation space 42 in which the cooling unit 30 is provided, a cooling unit 30 (Not shown).

Here, a large number of installation ventilation holes 421 for air flow may be formed around the culture solution housing 40 surrounding the installation space 42. Further, a communication hole 431 for installing the cooling unit 30 is formed in the partitioning wall 43. The communication hole 431 communicates the water storage space 41 and the installation space 42.

The culture solution housing 40 is provided with a supply portion 44 for supplying the culture solution and a discharge portion 45 for discharging the culture solution to communicate with the water storage space 41, respectively. Particularly, the supply part 44 communicates with the upper part of the water storage space 41 and the discharge part 45 communicates with the bottom of the water storage space 41 or the bottom of the water storage space 41 to supply and discharge the culture liquid. And it is possible to prevent the culture liquid from remaining in the water storage space 41 in the discharge of the culture liquid.

Here, the supply unit 44 and the discharge unit 45 may each be equipped with a valve (not shown) for selecting whether to supply the culture liquid or to discharge the culture liquid. The supply unit 44 and the discharge unit 45 may be provided with a pump (not shown) for supplying or discharging the culture liquid, respectively. A valve (not shown) and a pump (not shown) may be controlled by the control unit 100 and applied to a cleaning method of a bud culturing apparatus described later.

The cooling unit 30 includes a cooling plate 31 coupled to the partitioning wall 43 in the water storage space 41 so as to cool the culture liquid in the water storage space 41, A silencer condenser unit 33 disposed in the installation space 42 for discharging heat in accordance with the natural convection of the refrigerant, and a communication hole 431, And a thermoelectric unit 34 that is closely contacted and supported by the cooling plate 31 and the noiseless condensing unit 33. Both sides of the thermoelectric unit 34 are respectively provided with a heat absorbing portion for cooling the cooling plate 31 by a power source which is closely attached to the cooling plate 31 and a power source for heating the cooling plate 31 in close contact with the noiseless condensing unit 33, ≪ / RTI >

The cooling plate 31 is composed of a cooling part exposed in the water storage space 41 and an extension part extending from the cooling part and coming into close contact with the heat absorbing part.

The hermetically sealed gasket 32 is closely inserted into the cooling part and the partition wall 43 in a ring shape or a ring shape so as to enclose the extended part.

The cooling gasket 32 and the cooling part of the cooling plate 31 can be fixed to the partitioning wall 43 through a fastening member (not shown).

The silencer condenser unit 33 includes a refrigerant tank main body 331 in which a refrigerant radiating space 331c is formed in which refrigerant is stored and a refrigerant heat radiating space 332 in which refrigerant vaporized by heat emitted from the thermoelectric unit 34 is discharged, A condenser 333 connected to the first refrigerant pipe 332 to condense the refrigerant supplied from the first refrigerant pipe 332 and a condenser 333 connected to the condenser 333, And a second refrigerant pipe 334 connecting the condenser 333 and the refrigerant heat-radiating space 331c so that the refrigerant condensed by the condenser 333 is supplied to the refrigerant radiating space 331c.

The coolant tank main body 331 includes a tank body 331a formed with a coolant radiating space 331c and closely contacting the heat radiating portion of the thermoelectric unit 34 and a wing body 331b extending from the tank body 331a . The cooling plate 31, the thermoelectric unit 34, and the coolant tank main body 331 are brought into close contact with each other by fixing the blade body of the coolant tank main body 331 to the partition wall 43 via the fastening member (not shown) .

The condenser 333 may include a condensing tube connecting the first refrigerant pipe 332 and the second refrigerant pipe 334 and a condensing radiating fin protruding from the outer circumferential surface of the condensing pipe.

The noiseless condensing unit 33 may further include a condensation promoting unit 335 provided in the refrigerant tank main body 331 for promoting the condensation of the refrigerant circulated in the refrigerant tank main body 331.

At this time, the condensation promoting unit 335 includes at least one ventilation pipe 3351 penetrating the refrigerant tank main body 331 so that the refrigerant is brought into contact. The ventilation pipe 3351 is in the form of a hollow tube and is fixed to the refrigerant tank main body 331 through the refrigerant radiating space 331c. The condensation promoting unit 335 may further include a tank heat radiating space 3352 formed in the refrigerant tank body 331 so as to be spaced apart from the refrigerant radiating space 331c. The tank heat-radiating space 3352 may be formed through the blade body 331b of the coolant tank body 331.

Here, at least one of the inner wall of the refrigerant radiating space 331c and the inner and outer walls of the vent pipe 3351 is formed with a plurality of circulating radiating fins 335a to maximize the radiating effect. A large number of circulating radiating fins 335a may be formed on the inner wall of the tank radiating space 3352. [

The cooling unit 30 may further include a circulation fan 35 provided at one side of the silent condensation unit 33 so that air flows in the condensation unit 333, the ventilation pipe 3351, and the tank heat radiation space 3352 have.

The cooling unit 30 further includes a cooling duct 36 connecting the silent condensation unit 33 and the circulation fan 35 so that air is concentrated in at least one of the condensation unit 333 and the ventilation pipe 3351 . When the air is concentrated in the vent pipe 3351, the air may be concentrated in the tank heat radiation space 3352 as well.

For example, the cooling duct 36 may include a support bracket 361 and a guide bracket 362.

The support bracket 361 is coupled to the circulation fan 35 and the guide bracket 362 extends from the support bracket 361 so as to surround the condenser 333. Here, the guide bracket 362 is provided with the induction bracket 363, so that the air can be concentratedly introduced in the condenser 333. At this time, a flow of air is generated in the ventilation pipe 3351 and the tank heat dissipation space 3352 by the air introduced from the condensing portion 333, and a heat radiation effect can be exhibited.

As another example, the cooling duct 36 may include a support bracket 361 and an auxiliary bracket 364.

The support bracket 361 is coupled to the circulation fan 35 and the auxiliary bracket 364 extends from the support bracket 361 so as to surround one side of the ventilation pipe 3351 and the tank radiation space 3352. The auxiliary bracket 364 includes a first bracket 365 extending toward the lower side of the coolant tank main body 331, a second bracket 366 extending from the first bracket 365, a coolant tank body 331 And a third bracket 367 extending from the second bracket 366 so as to surround the lower side of the refrigerant tank body 331. A fourth bracket 368 for guiding air between the circulation fan 35 and the lower side of the coolant tank body 331 ). ≪ / RTI > Here, a large number of circulation holes may be formed in the fourth bracket 368 to guide air in the condenser 333. At this time, a flow of air is generated in the condenser 333 by the air introduced from the ventilation pipe 3351 and the tank heat radiation space 3352, so that the heat radiation effect can be exhibited.

As another example, the cooling duct 36 may include a support bracket 361, a guide bracket 362, and an auxiliary bracket 364 as shown in Fig.

The circulation pump (50) is provided in the water storage space (41) to pump the culture liquid. The circulation pump 50 can also pump the cleaning liquid or the cleaning liquid accommodated in the water storage space.

The water supply pipe 60 is coupled to the circulation pump 50 through the module housing 20 so that the culture liquid pumped by the circulation pump 50 is moved to the upper side of the seed housing 10. The water supply pipe (60) penetrates the through hole (24) formed through the center of the module housing (20) and can be separated and attached to each other by two or more.

The water vane (70) is rotatably coupled to a water supply pipe (60) to supply the culture liquid to the seed housing (10). The water supply vane 70 includes a water supply header portion 71 rotatably coupled to the water supply pipe 60, a plurality of water supply vanes 72 branched from the water supply header portion 71, And a rotary spraying part 73 provided at one side of the water supply part 72 for discharging the culture liquid accommodated in the water supply part 72. Then, when the culture liquid is discharged from the rotary jetting section 73 in accordance with the configuration of the water supply vane 70, the water supply header section 71 can be rotated about the water supply pipe 60 without power.

Particularly, the water supply wing portions 72 branched from the water supply header portion 71 are respectively divided into two or more along the longitudinal direction, and the rotary jetting portions 73 are formed in at least one of the division regions of the water supply wing portion 72 Respectively.

The culture liquid discharged from the rotary spraying unit 73 can be uniformly supplied to the entire seed housing 10 or the module housing 20 as the water supply vane 70 is rotated.

In the water supply vane 70, two or more water supply vanes 72 are branched from one water supply header portion 71. At this time, the two or more water vanes 72 are arranged at regular intervals along the rotation direction of the water vane 70. In the first embodiment of the present invention, the three water supply vanes 72 are branched from the water supply header 71. At this time, the rotary jetting part 73 may be provided only in a part of the partition area from one side of each water supply vane part 72. And the culture liquid is discharged to all the compartment areas in accordance with the rotation of the water supply vane part (72).

For example, as shown in FIG. 8, three rotary jetting portions 73a, 73b, and 73c are provided in only one portion of one side of the water supply vane portion 72 with respect to the three water supply vanes 72, respectively. More specifically, the first rotary jetting portion 73a is formed in the inlet region of the water supply vane portion 72 adjacent to the water supply header portion 71 with respect to one water supply vane portion 72. [ The second rotary jetting portion 73b is formed in the middle region of the water supply vane portion 72 with respect to the other water supply vane portion 72. [ The third rotary jetting portion 73c is formed in the free end region of the water supply vane portion 72 with respect to the other water supply vane portion 72. [ In this case, the culture liquid can be discharged from all the compartments of the water supply vane portion 72 as the water supply vane portion 72 rotates.

In addition, since the rotation jetting section 73 is formed for each of the partition areas, the rotation of the water supply vane 70 can be stabilized, the discharge of the culture liquid can be made uniform, and the supply amount of the culture liquid can be maintained constant.

The sprout cultivation apparatus according to the first embodiment of the present invention may further include at least one of the bottom closure member 80 and the module opening / closing member 90.

The bottom closing member 80 opens and closes an installation space 42 that opens to the lower side of the culture liquid housing 40. The bottom closing member 80 may include a support member 81 that keeps the culture liquid housing 40 away from the floor and keeps it flat. The opening / closing bracket 82 can open / close the installation space 42 at the periphery of the culture liquid housing 40. The opening and closing bracket 82 may be integrally formed with the bottom closing member 80. The opening and closing bracket 82 can be separated from the bottom closing member 80 to open and close the installation space 42 on the periphery of the culture liquid housing 40. [ The opening and closing bracket 82 may be formed with a plurality of opening and closing air holes through which the air in the installation space 42 flows.

The module opening / closing member 90 opens and closes the seating space 21 opened to the upper side of the module housing 20. The module opening and closing member 90 can prevent foreign matter from flowing into the seed housing 10. [ A plurality of breathing air holes 91 may be formed in the module opening / closing member 90 so as to allow air in the seating space 21 to flow therethrough.

The sprout cultivation apparatus according to the first embodiment of the present invention may further include a control unit 100. The control unit (100) controls the operation of the circulation pump (50) and the cooling unit (30).

Hereinafter, the operation of the bud cultivation apparatus through the control unit 100 will be described.

When the culture liquid is received in the water storage space 41, the control unit 100 operates the circulation pump 50 continuously or intermittently in accordance with the preset circulation time. Further, the control unit 100 senses the temperature of the culture liquid accommodated in the water storage space 41 and operates the cooling unit 30 continuously or intermittently according to a predetermined culture temperature in comparison with a predetermined culture temperature.

Then, the culture liquid has a predetermined culture temperature and is circulated by the circulation pump 50 to be supplied to the culture space 11 of the seed housing 10, thereby promoting the germination and growth of the seeds. In the seed housing, Can be prevented.

The sprout cultivation apparatus according to the second embodiment of the present invention will now be described.

In the bud cultivation apparatus according to the second embodiment of the present invention, the same components as those of the bud cultivation apparatus according to the first embodiment of the present invention are denoted by the same reference numerals, and a description thereof will be omitted.

FIG. 12 is an exploded view showing a bud cultivation apparatus according to a second embodiment of the present invention, FIG. 13 is a sectional view showing a bud cultivation apparatus according to a second embodiment of the present invention, FIG. 1 is an enlarged cross-sectional view showing a connection state of a water pipe in a bud cultivation apparatus according to an embodiment.

12 to 14, the sprout cultivation apparatus according to the second embodiment of the present invention includes a plurality of seed housings 10, and includes at least two module housings 20 described above, .

The module housing 20 then includes a first module housing 210 and a second module housing 220.

The first module housing 210 is detachably coupled to the culture medium housing 40. The first module housing 210 is detachably coupled to the seed housing 10 therein. The first module housing 210 is provided with a seating space 21, a detachable bracket 22, and a through hole 24. The first module housing 210 may have a through hole 24 and a fitting bracket 25 for coupling the culture solution housing 40 to the first module housing 210.

At least one second module housing 220 is detachably coupled to the first module housing 210. The second module housing 220 is detachably coupled to the seed housing 10 therein. The second module housing 220 is provided with the above-described seating space 21, the detachable bracket 22, and the communicating discharge unit 23. The second module housing 220 is formed with a penetration elongated hole portion 241 for supporting the second water supply pipe 62 of the water supply pipe 60 therethrough. The second module housing 220 may be provided with an insertion bracket 26 for coupling with the first module housing 210 or coupling between the second module housings 220.

The module opening / closing member 90 can open and close the uppermost second module housing 220.

The water supply pipe 60 is connected to the circulation pump 50 through the first module housing 210 so that the culture liquid pumped by the circulation pump 50 is moved to the upper side of the seed housing 10, And a second water pipe (61) passing through the second module housing (220) while being connected to the first water pipe (61) so that the culture liquid pumped by the circulation pump (50) is moved to the upper side of the seed housing 62). At least one second water pipe 62 may be provided corresponding to the second module housing 220. The second water pipe 62 may be provided with a connection pipe 621 for connection to the first water pipe 61 or for connection between the second water pipes 62. The connection pipe 621 can be inserted into the water supply header portion 71 of the water supply vane 70. At this time, the connection pipe 621 may be formed with a water supply hole 622 so as to communicate with the water supply header portion 71.

The water vane 70 is rotatably coupled to the second water supply pipe 62 or rotatably coupled to the first water supply pipe 61 and the second water supply pipe 62, respectively. When two or more second water pipes 62 are provided, the water supply vane 70 may be coupled to the uppermost second water pipe 62.

When the water vane 70 is rotatably coupled to the first water pipe 61 and the second water pipe 62 respectively, the water vane 70 is connected to the first water pipe 61, And a second water supply vane 720 rotatably coupled to the second water supply pipe 710 and the second water supply pipe 62. A connection hole 711 for insertion of the connection pipe 621 is formed in the water supply header portion 71 of the first water supply vane 710 and the second water supply vane 720. The connection hole 711 can be opened and closed by an opening / closing cap 74.

The sprout cultivation apparatus according to the third embodiment of the present invention will now be described.

15 is a sectional view showing a bud cultivation apparatus according to a third embodiment of the present invention.

Referring to FIG. 15, the sprout cultivation apparatus according to the third embodiment of the present invention includes one seed housing 10, and includes one seed housing 10 in which seeds are cultured, a cooling unit A water storage space 41 in which the seed storage unit 10 is detachably coupled and in which a culture liquid is received, an installation space 42 in which the cooling unit 30 is provided, a water storage space 41, A culture liquid housing 40 containing a partition wall 43 to which the cooling unit 30 is bound while partitioning the space 42, a circulation pump 50 provided in the water storage space 41 to pump the culture liquid, A water supply pipe 60 connected to the circulation pump 50 through the seed housing 10 so that the culture liquid pumped by the pump 50 is moved to the upper side of the seed housing 10, And a water supply vane (70) for supplying the culture solution to the seed housing (10).

The water supply vane 70 includes a water supply header portion 71 rotatably coupled to the water supply pipe 60, a plurality of water supply vanes 72 branched from the water supply header portion 71, And a rotary spraying part 73 provided at one side of the water supply part 72 for discharging the culture liquid housed in the water supply blade part 72.

In the third embodiment of the present invention, the same reference numerals are assigned to the same components as those of the first embodiment or the second embodiment of the present invention, and a description thereof will be omitted.

However, in the third embodiment of the present invention, the inclined portion 10a is formed at the bottom of the culture space 11 of the seed housing 10 so as to be inclined downward from the edge of the culture space 11 toward the center of the culture space 11 . The spacing bracket 15 is provided under the seed housing 10 so that the seed housing 10 can be detachably coupled to the culture solution housing 40 through the spacing bracket 15, Can be prevented from leaking.

The insertion hole 14 is formed at the center of the bottom of the seed housing 10 and the support hole 123 is formed through the center of the supporting net 12 or the grasping portion 121, And penetrate through the insertion hole portion 14 and the support hole portion 123 to be coupled to the circulation pump 50.

The module opening / closing member 90 opens and closes the culture space 11.

A sprout cultivation apparatus according to a fourth embodiment of the present invention will now be described.

In the fourth embodiment of the present invention, the same reference numerals are assigned to the same components as those of the first through third embodiments, and a description thereof will be omitted.

FIG. 16 is a cross-sectional view illustrating a sprout cultivation apparatus according to a fourth embodiment of the present invention, and FIG. 17 is an enlarged cross-sectional view illustrating a connection state of a water pipe in a bud cultivation apparatus according to a fourth embodiment of the present invention.

Referring to FIGS. 16 and 17, the seed cultivation apparatus according to the fourth embodiment of the present invention includes a plurality of seed housings 10, which are stacked.

Then, the seed housing 10 includes a first laminated housing 110 and a second laminated housing 120.

The first laminated housing 110 is detachably laminated to the culture housing 40.

The first laminated housing 110 may be provided with a culture space 11, a support net 12, and a drain discharge unit 13. The first laminated housing 110 may be provided with an insertion hole portion 14 and a support hole portion 123 for supporting the first water pipe 61 through the water pipe 60. In addition, the first laminated housing 110 may be provided with a spacing bracket 15 for coupling with the culture housing 40.

The second laminated housing 120 is at least one of which is detachably laminated to the first laminated housing 110. The second laminated housing 120 may be provided with the culture space 11, the support net 12, and the drainage unit 13 described above. The second laminated housing 120 may be provided with an insertion extension hole 141 and a support hole 123 for supporting the second water supply pipe 62 of the water supply pipe 60. The second laminated housing 120 may be provided with a lamination bracket 16 for coupling with the first laminated housing 110 or coupling between the second laminated housings 120.

The module opening and closing member 90 can open and close the uppermost second laminated housing 120.

The water supply pipe 60 is connected to the circulation pump 50 through the first stacked housing 110 so that the culture liquid pumped by the circulation pump 50 is moved to the upper side of the first stacked housing 110, The water supply pipe 61 and the circulation pump 50 are connected to the first water supply pipe 61 so as to move the culture liquid pumped by the circulation pump 50 to the upper side of the second laminated housing 120, And a second water supply pipe (62). At least one second water pipe 62 may be provided corresponding to the second laminated housing 120. The second water pipe 62 may be provided with a connection pipe 621 for connection to the first water pipe 61 or for connection between the second water pipes 62. The connection pipe 621 can be inserted into the water supply header portion 71 of the water supply vane 70. At this time, the connection pipe 621 may be formed with a water supply hole 622 so as to communicate with the water supply header portion 71.

The water vane 70 is rotatably coupled to the second water supply pipe 62 or rotatably coupled to the first water supply pipe 61 and the second water supply pipe 62, respectively. When two or more second water pipes 62 are provided, the water supply vane 70 may be coupled to the uppermost second water pipe 62.

When the water vane 70 is rotatably coupled to the first water pipe 61 and the second water pipe 62 respectively, the water vane 70 is connected to the first water pipe 61, And a second water supply vane 720 rotatably coupled to the second water supply pipe 710 and the second water supply pipe 62. A connection hole 711 for insertion of the connection pipe 621 is formed in the water supply header portion 71 of the first water supply vane 710 and the second water supply vane 720. The connection hole 711 can be opened and closed by an opening / closing cap 74.

Hereinafter, the cleaning method of the bud cultivation apparatus according to the first to fourth embodiments of the present invention will be described.

First, the culture liquid contained in the water storage space 41 is discharged. At this time, the culture liquid can be discharged through the discharge portion 45 by the operation of a valve (not shown) and a pump (not shown). In addition, the circulation pump 50 may be operated to discharge the culture liquid contained in the water supply pipe 60 and the water supply vane 70.

Next, the cleaning liquid is supplied to the water storage space 41. At this time, the cleaning liquid can be supplied through the supply unit 44 by the operation of a valve (not shown) and a pump (not shown). After the washing liquid is supplied to the water storage space 41, the circulation pump 50 is operated for a predetermined washing time so that the washing liquid is discharged from the water vane 70. Next, the cleaning liquid is discharged from the water storage space 41. At this time, the cleaning liquid can be discharged through the discharge portion 45 by the operation of a valve (not shown) and a pump (not shown). In addition, the circulation pump 50 may be operated to discharge the cleaning liquid contained in the water supply pipe 60 and the water supply vane 70.

By repeating the operation from the supply of the washing solution to the discharge of the washing solution at least once, the protein components remaining in the bud growing apparatus can be separated or decomposed and discharged.

In addition, after the cleaning liquid is discharged from the water storage space 41, the cleaning liquid is supplied to the water storage space 41. At this time, the cleaning liquid can be supplied through the supply part 44 by the operation of a valve (not shown) and a pump (not shown). After the cleaning liquid is supplied to the water storage space 41, the circulation pump 50 is operated for a predetermined cleaning time such that the cleaning liquid is discharged from the water supply vane 70. Next, the cleaning liquid is discharged from the water storage space 41. At this time, the cleaning liquid can be discharged through the discharge portion 45 by the operation of a valve (not shown) and a pump (not shown). Further, the circulation pump 50 may be operated for discharging the cleaning liquid contained in the water supply pipe 60 and the water supply vane 70.

Then, the operation from the supply of the cleaning liquid to the discharge of the cleaning liquid is repeated one or more times, whereby the cleaning liquid remaining in the bud growing apparatus can be diluted and discharged. It is possible to prevent the washing liquid from remaining in the bud growing apparatus.

Next, the culture liquid is supplied to the water storage space 41, the seed housing 10 containing the seeds is installed, and the seeds can be cultured by operating the circulation pump 50 and the cooling unit 30.

According to the above-described sprout cultivation apparatus and its cleaning method, it is possible to uniformly supply the culture liquid to the seeds and maintain the water temperature rising constantly according to the germination of the seeds, thereby promoting seed germination and sprout growth. In addition, the feed vanes 70 can be rotated with no power by the soil power of the culture liquid, and the culture liquid can be supplied to the seed housing 10 substantially constantly.

In addition, seeds of various kinds can be germinated through a plurality of seed housings 10.

In addition, it is possible to smoothly discharge the culture liquid from the seed housing 10, and to prevent the culture liquid or the seed stagnating in the culture space 11 from being corrupted.

In addition, it is possible to smoothly discharge the culture liquid from the module housing 20 and prevent the culture liquid stagnating in the seating space 21 from being corrupted.

Further, the power required for driving the cooling unit 30 can be reduced, and the heat can be released by natural convection of the refrigerant. Further, the condensation of the refrigerant can be promoted and the heat exchange performance with the thermoelectric unit 34 can be improved. In addition, heat release from the coolant tank main body 331 can be improved, and heat exchange between the coolant tank main body 331 and the thermoelectric unit 34 can be smoothly performed. Further, it is possible to improve the contact area between the silent condenser unit 33 and the air, and to maximize the heat radiation effect.

In addition, it is possible to automate the watering and drainage of the culture medium, the washing liquid and the washing liquid, and the circulation thereof, regulate the period of cultivation of the seeds, and uniformly grow the shoots.

Also, even in one seed housing 10, the culture liquid can be smoothly discharged, the culture liquid can be uniformly supplied from one seed housing 10, and the above-mentioned effect can be maintained.

In addition, it is possible to prevent the culture liquid from becoming turbid due to the protein components contained in the seeds, thereby keeping the path of the culture liquid clear. The culture space 11 of the seed housing 10, the seating space 21 of the module housing 20, the water storage space 41 of the culture liquid housing 40, the circulation pump 50, the water supply pipe 60, It is possible to remove residual protein components in the wings 70 and inhibit or prevent the mixing of the protein components in the culture solution.

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 embodiments, but, on the contrary, Modify or modify the Software.

10: seed housing 110: first laminated housing 120: second laminated housing
11: culture space 12: supporting network 121:
122: spacing part 123: support hole part 13: drainage part
14: insertion hole portion 141: insertion extension hole portion 15: spacing bracket
16: laminated bracket 10a: inclined portion 20: module housing
210: first module housing 220: second module housing 21: seating space
22: desorption bracket 23: communicating discharge part 24: penetration hole part
241: through extension hole portion 25: fitting bracket 26: insertion bracket
30: cooling unit 31: cooling plate 32: sealing gasket
33: Noiseless condenser unit 331: Coolant tank body 331a: Tank body
331b: wing body 331c: refrigerant radiating space 332: first refrigerant tube
333: condenser 334: second refrigerant tube 335: condensation promoting unit
3351: vent pipe 3352: tank heat dissipation space 335a: circulating heat dissipation pin
34: thermoelectric unit 35: circulating fan 36: cooling duct
361: support bracket 362: guide bracket 363: guide bracket
364: auxiliary bracket 365: first bracket 366: second bracket
367: third bracket 368: fourth bracket 40: culture housing
41: water storage space 42: installation space 421: installation ventilation hole
43: partitioning partition wall 431: communication hole 44:
45: discharge part 50: circulation pump 60: water supply pipe
61: first water pipe 62: second water pipe 621: connecting pipe
622: water supply hole 70: water supply wing 710: first water supply wing
720: second water supply blade 71: water supply header part 711: connection hole
72: water feed wing 73: rotary jetting part 74:
80: bottom finishing member 81: support member 82: opening / closing bracket
90: module opening / closing member 91: breathing air vent 100: control unit

Claims (15)

A plurality of seed housings in which seeds are cultured;
A module housing in which the seed housing is detachably coupled;
A cooling unit for cooling the culture liquid;
The module housing includes a water storage space in which the module housing is detachably coupled, the water storage space in which the culture liquid is received, the installation space in which the cooling unit is installed, and the partitioning wall in which the cooling unit is coupled while partitioning the water storage space and the installation space A culture medium housing;
A circulation pump provided in the water storage space to pump the culture liquid;
A water supply pipe passing through the module housing and connected to the circulation pump so that the culture liquid pumped by the circulation pump is moved to the upper side of the seed housing; And
And a water supply vane rotatably coupled to the water supply pipe to supply a culture liquid to the seed housing,
The water-
A water supply header portion rotatably coupled to the water supply pipe;
A plurality of water supply vanes branched from the water supply header portion; And
And a rotary jet part provided at one side of the water supply vane part and discharging the culture liquid accommodated in the water supply vane part,
And a cooling unit disposed in the installation space to discharge heat in accordance with free circulation of the refrigerant,
Wherein the noiseless condensing unit includes a refrigerant tank main body having a refrigerant heat radiating space in which refrigerant is stored; And a condensation promoting unit provided in the refrigerant tank main body for promoting condensation of the refrigerant circulated in the refrigerant tank main body,
Wherein the condensation promoting unit includes at least one vent pipe passing through the coolant tank main body so as to be in contact with the coolant. The method according to claim 1,
In the partition wall,
A communication hole communicating with the water storage space and the installation space is formed to pass through,
The cooling unit includes:
A cooling plate coupled to the partition wall in the water storage space to cool the culture liquid in the water storage space;
A sealing gasket closely inserted between the cooling plate and the partition wall; And
A heat absorbing portion which is supported by the cooling plate and the silent condensation unit in close contact with each other through the communication hole and cools the cooling plate by a power source applied to the cooling plate in close contact therewith, And a thermoelectric unit having a heat radiating portion for radiating heat. 3. The method of claim 2,
The silencer /
A first refrigerant pipe connected to the refrigerant heat radiating space to discharge refrigerant vaporized by heat emitted from the thermoelectric unit;
A condenser connected to the first refrigerant pipe for condensing the refrigerant supplied from the first refrigerant pipe; And
And a second refrigerant pipe connecting the condensing unit and the refrigerant heat-radiating space so that the refrigerant condensed by the condensing unit is supplied to the refrigerant heat-radiating space. delete The method of claim 3,
Wherein at least one of the refrigerant heat-radiating space and the air-
Wherein a plurality of circulating heat dissipating fins are protruded and formed. The method of claim 3,
The cooling unit includes:
Further comprising a circulation fan installed at one side of the silent condensation unit so that air flows through the condensation unit and the ventilation pipe. The method according to claim 6,
The cooling unit includes:
Further comprising a cooling duct for connecting the silent condensation unit to the circulation fan so that air is concentrated in at least one of the condensation unit and the ventilation pipe. The method according to claim 1,
In the culture solution housing,
A supply part communicating with the water storage space to supply a culture liquid; And
And a discharge part communicating with the water storage space and discharging the culture liquid. The method according to claim 1,
The module housing comprises:
A first module housing detachably coupled to the culture medium housing and detachably coupled to the seed housing; And
And at least one second module housing detachably coupled to the first module housing and detachably coupled to the seed housing therein. 10. The method of claim 9,
The water supply pipe,
A first water pipe passing through the first module housing to be coupled to the circulation pump so that the culture liquid pumped by the circulation pump is moved to the upper side of the seed housing; And
And a second water supply pipe passing through the second module housing in a state of being connected to the first water supply pipe so that the culture liquid pumped by the circulation pump is moved to the upper side of the seed housing,
Wherein the water vane is rotatably coupled to the second water supply pipe or is rotatably coupled to the first water supply pipe and the second water supply pipe. delete The method according to claim 1,
The seed-
A first laminated housing detachably laminated to the culture housing and cultured in seed; And
And at least one second laminated housing detachably laminated to the first laminated housing and in which the seeds are cultivated. 13. The method of claim 12,
The water supply pipe,
A first water supply pipe connected to the circulation pump through the first laminated housing so that the culture liquid pumped by the circulation pump is moved to the upper side of the first laminated housing; And
And a second water supply pipe connected to the first water supply pipe and passing through the second laminated housing so that the culture liquid pumped by the circulation pump is moved to the upper side of the second laminated housing,
Wherein the water vane is rotatably coupled to the second water supply pipe or is rotatably coupled to the first water supply pipe and the second water supply pipe. 14. A method according to any one of claims 1 to 3, 5 to 10, 12 and 13,
Wherein the water supply vanes branching from the water supply header portion are respectively divided into two or more along the longitudinal direction,
And the rotary spraying unit is installed in at least one of the partition areas of the water supply vane. delete

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