KR102498104B1 - A Variable Greenhouse System for Plant Cultivation Using Aquaponics - Google Patents

Abstract

The present invention relates to a variable greenhouse house system for plant cultivation using aquaponics, and more specifically, to a variable greenhouse house system for plant cultivation using aquaponics, which enables plant cultivation in a greenhouse using an aquaponics technique, and has a rail installed in the greenhouse to enable variation. The present invention has the advantage of facilitating the management of illuminance, temperature, and the like in a greenhouse by providing a greenhouse house system capable of being opened and closed. In addition, the variable greenhouse system according to the present invention is formed to be opened and closed, so that plants, which are cultivated in a structure arranged in a greenhouse in an aquaponics manner, can be smoothly grown, and a separation prevention stopper is installed in the greenhouse to firmly hold a house moving member of a variable house together with the rail, thereby enduring ferocious winds, vibrations, and the like, and the house moving member is prevented from separating from the rail so that it is possible to prevent safety accidents.

Description

A Variable Greenhouse System for Plant Cultivation Using Aquaponics}

The present invention relates to a variable greenhouse house system for plant cultivation using aquaponics. It relates to a variable greenhouse house system for plant cultivation using aquaponics.

A greenhouse is a type of greenhouse, and is a structure covered with a transparent film on a steel frame. It is used to increase yield by trapping solar heat inside with a transparent film and creating a high-temperature environment so that plants (usually crops and flowers) can grow actively.

A greenhouse made of plastic (vinyl) or sheet (film) instead of glass is called a vinyl house. In fact, polyvinyl chloride (PVC) has more than half of the market share. It's vinyl in name only, and it's not actually another material. Of course, films such as polyethylene or EVA are often used, and it is not that they are not called vinyl greenhouses because they are made of these materials, but the initial investment is much cheaper than glass greenhouses. Since it is advantageous to continuously cultivate a small area of arable land regardless of temperature, the case of covering greenhouses with vinyl was mainly developed in Japan and Korea.

The vinyl used in the greenhouse is transparent (translucent). It is never covered with another vinyl. In the case of a black vinyl or tent, it is installed to block a warehouse for growing crops or excessive light with a shading screen. In addition, it is covered with insulation material such as cotton to make it advantageous for temperature control. There are vinyl tunnels and glass greenhouses as derivatives of greenhouses.

In these greenhouses, it is important to maintain a constant level of illumination and temperature in order to grow plants inside, but in the case of a typical greenhouse, it is inconvenient to control it by covering the skin.

Korean Registered Patent Publication No. 10-2233067 Korean Registered Patent Publication No. 10-1623563

An object of the present invention is to maintain a constant level of illumination in a greenhouse house by providing a variable greenhouse house system having a moving structure.

In addition, by installing an aquaponics-type structure in the variable greenhouse house, the purpose is to enable aquaponics-type plant cultivation in the greenhouse house.

Lastly, by installing a breakaway stopper in the greenhouse house, the house movable member of the variable type house is firmly held together with the rail so that it can withstand steel and vibration, and the purpose is to prevent the house movable member from escaping from the rail. am.

In order to solve the above problems, the present invention is formed by including a fixed house body 140 and a house movable member 150 formed to a size that can be covered by the house body 140 but movable by a rail. The variable house 100 has a bottom part 110 formed in a plate shape of a predetermined size and a first fixed length formed along one side of the bottom part 110. The rail 120, the second fixed rail 130 formed with a predetermined length along the other side of the bottom part 110, and the house body having a predetermined size located on the upper surface of one side of the bottom part 110 ( 140) and the house body 140 are formed to an acceptable size, and one floor is coupled to the first moving wheel 160 and moved by the first fixed rail 120, and the other floor is moved by the second moving wheel 170 The house movable member 150 is coupled to and moved by the second fixed rail 130, and the first house movable member 150 is installed on the floor on one side of the house movable member 150 and is formed to move along the first fixed rail 120. It includes a moving wheel 160 and a second moving wheel 170 installed on the bottom of the other side of the house moving member 150 and formed to move along the second fixed rail 130, and the house body 140 A body frame 141 formed with a predetermined number of pillars to form a rectangular parallelepiped shape and formed to have a roof shape on the upper part of the rectangular parallelepiped, and a body panel portion 142 formed to cover one side of the body frame 141 and , It is located inside the body frame 141, but the second floor bottom portion 143 formed at a predetermined height to divide the layers and the body panel portion 142 cover one side of the uncovered body frame 141 It includes a house vinyl unit 144 and an opening and closing window 145 formed on one side of the house vinyl unit 144, and the house moving member 150 is formed with a predetermined number of pillars to form a rectangular parallelepiped shape. The movable member frame 151 formed to have a roof shape on the upper part of the rectangular parallelepiped and to accommodate the house body 140, and the movable member frame 151 It is characterized in that it comprises a moving member panel portion 153 forming the outer surface of,

The second floor bottom portion 143 is located on one side of the second floor bottom portion 143, characterized in that it includes a checkered hole portion 143a in which a plurality of perforated holes having a predetermined size are formed,

The first stopping part 310 is installed to prevent the house movable member 150 of the variable house 100 from being separated, and is formed on both lower sides of the house movable member 150 of the variable house 100. And a departure prevention stopper 300 including a second stopper 320 formed at the end of the first fixed rail 120 and the end of the second fixed rail 130, respectively, but the first stopper The part 310 is formed in the form of a plate of a predetermined size located at the lower part of one side and the lower part of the other side of the house moving member 150, and is formed with a wall surface and a bottom surface, so that it is formed in a 'b' shape when viewed from the side. 1 stopping frame portion 311, a stopping rod portion 312 located on one side of the wall surface of the first stopping frame portion 311 and having a predetermined length, and the first stopping frame portion ( 311), but includes a first house departure prevention part 313 formed in a triangular roof shape, and the second stopping part 320

The second fixed rail 120 and the second fixed rail 130, each located at one end, perpendicular to each of the first fixed rail 120 and the second fixed rail 130 and formed in a plate shape of a predetermined size. A stopping frame part 321, a third stopping frame part 322 formed perpendicular to one side of the second stopping frame part 321 and formed in a plate shape of a predetermined size, and the third stopping It is located on the lower surface of the frame part 322 and is formed in a triangular roof shape corresponding to the first house departure prevention part 313 to accommodate the first house departure prevention part 313 of the first stopping part 310. It is characterized in that it includes a second house departure prevention part 323 and a reinforcing part 324 formed in a triangular roof shape formed along one side of the second stopping frame part 321, and a variable house It is installed inside the 100 and includes an aquaponics unit 200 for plant cultivation, and the aquaponics unit 200 has a filtration unit 210 for filtering impurities and organic particles of water introduced from the outside. ), and a water tank 220 provided to receive water supplied from the filtering part 210 through the first connection pipe 201 and store it therein so that aquatic organisms can live therein, and the water tank part 220 In order to remove impurities from the water supplied from the second connection pipe 202 connected to the vortex chamber portion 231 in the form of a pipe of a predetermined size, a shape larger than the size of the vortex chamber portion 231 so that microorganisms can be cultured Water passing through the filtering and culturing unit 230 in which the culture unit 232 is formed in the form of a tube and the third connection pipe 203 connected to the filtering and culturing unit 230 is supplied and plants can be grown. Including a first plant cultivation unit 240 provided,

The filtration and culture unit 230 is formed in the form of a tube of a predetermined size, and is formed in a tube shape larger than the vortex chamber unit 231 and the vortex chamber unit 231 so that water is introduced and cycled therein. The culture part 232 formed so that the vortex chamber part 231 is located in the water tank 220 is formed in a tubular shape so that the water is received in the vortex chamber part 231, but one end is the culture part ( 232) to be connected to the outside and the other end passing through the vortex chamber 231 to be accommodated into the vortex chamber 231, and the inlet 233, and one end to the vortex chamber 231 The other end is connected to the vortex chamber drain pipe 234 located on one side inside the culture unit 232 located outside the vortex chamber unit 231, and connected to one side of the culture unit 232, but the filtered water is supplied to the outside. A final water discharge unit 235 for discharging to and one end located on one side of the lower part of the vortex chamber unit 231 so that floating matter is discharged from the vortex chamber unit 231, but the other side extends outside the culturing unit 232. A floating matter discharge portion 236 formed by being formed,

A predetermined number is located inside the vortex chamber unit 231, characterized in that it includes a filtration filter unit 237 for filtering water, and the fourth connection pipe connected to the first plant cultivation unit 240 The water passing through 204 is moved and accommodated, and the seed germination unit 260 has a seed germination unit 250 formed in a predetermined size to incubate seeds germinated, and a space of a predetermined size, but seeds for germination It is characterized in that it includes a seed germination unit 260 for planting and a fourth connection pipe 204 formed so that one end is connected to the first plant cultivation unit 240 and the other end is connected to the breeding unit 250, , A plurality of tubes of a predetermined length are formed, and one side is supplied with water from the fifth connection pipe 205 connected to the cultivation unit 250, and the pipe cultivation unit 270 formed for transplanting and cultivating sprouts It is characterized in that it includes, and water is supplied through the seventh connection pipe 207 connected to the pipe cultivation unit 270 or the sixth connection pipe 206 connected to the first plant cultivation unit 240, and plants are grown. It is characterized in that it includes a growth bed portion 280 formed with an inner space of a predetermined size so as to

It includes a lift elevator 180 installed on one side of the inside of the variable house 100, and the vortex chamber drain pipe 234 of the filtration and discharge unit 230 has a predetermined number of passage holes 234a at predetermined intervals on one side. Characterized in that it further comprises, the water flowing into the inside of the vortex chamber part 231 through the inlet 233 is cycled inside the vortex chamber part 231, and the water is filtered by the filtration filter part 237. Some of the filtered water is discharged through the vortex chamber drain pipe 234 (see arrow a3) and moved into the culture unit 232. Provided is a variable greenhouse house system characterized in that the water is discharged to the outside along the final water discharge unit 235.

The present invention has the advantage of facilitating the management of illumination, temperature, etc. in the greenhouse by providing a greenhouse system that can be opened and closed. In addition, it is formed to be opened and closed so that the plants grown in the structure arranged in the aquaponics method in the greenhouse house can grow smoothly, and by installing a stopper to prevent departure in the greenhouse house, the house movable member of the variable house is solid with the rail. It has the effect of preventing safety accidents by holding it tightly so that it can withstand steel products and vibrations, and preventing the house movable member from leaving the rail.

1 is a view showing the overall appearance of a variable greenhouse system according to the present invention.
2 is a view showing how the house moving member of the variable greenhouse system according to the present invention is moved.
3 is a view showing a greenhouse frame of a variable greenhouse system according to the present invention.
4 is a view showing a state in which aquaponics structures are installed in the greenhouse frame of the variable greenhouse house system of the present invention.
5 is a view showing the installation of the aquaponics structures of the present invention as a whole.
6 is a view of aquaponics structures installed on the first floor of the greenhouse house of the variable greenhouse system according to the present invention.
7 and 8 are views showing the filtering and cultivation unit 230 of the variable greenhouse system according to the present invention.
9 is a view showing the filtration and culture unit 230 of the variable greenhouse system of the present invention, excluding the culture unit 232.
10 is a view showing the operation of the filtering and cultivation unit 230 of the variable greenhouse system according to the present invention.
11 is a view of aquaponics structures installed on the second floor of the greenhouse house of the variable greenhouse system according to the present invention.
12 is a state in which a departure prevention stopper 300 is installed in the greenhouse of the variable greenhouse system according to the present invention.
13 is a view related to the departure prevention stopper 300 of the present invention.
14 is a view showing an operation example of the departure prevention stopper 300 of the present invention.

The terms or words used in this specification and claims should not be construed as being limited to ordinary or dictionary meanings, and the inventors can properly define the concept of terms in order to explain their invention in the best way. Based on the principle, it should be interpreted as a meaning and concept consistent with the technical idea of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention relates to a variable greenhouse house system for plant cultivation using aquaponics. It relates to a variable greenhouse house system for plant cultivation using aquaponics.

1 is a view showing the overall appearance of a variable greenhouse system according to the present invention.

2 is a view showing how the house moving member of the variable greenhouse system according to the present invention is moved.

Referring to FIGS. 1 and 2, the variable greenhouse house system for plant cultivation using aquaponics of the present invention includes a variable house 100, an aquaponics unit 200, and a departure prevention stopper 300. . A detailed description of each component is as follows.

The variable house 100 includes a fixed house body 140 and a house movable member 150 formed to a size that can be covered by the house body 140 and movable by a rail.

The variable house 100 includes a bottom part 110, a first fixed rail 120, a second fixed rail 130, a house body 140, a house moving member 150, and a first moving wheel 160. , It is configured to include a second moving wheel 170, an elevation elevator 180.

The bottom portion 110 is formed in a plate shape of a predetermined size.

The first fixed rail 120 is formed to have a predetermined length along one side of the bottom portion 110 .

The second fixed rail 130 is formed along the other side of the bottom portion 110 to have a predetermined length.

The house body 140 has a predetermined size and is located on the upper surface of one side of the bottom part 110 .

The house body 140 includes a body frame 141, a body panel portion 142, a second floor floor portion 143, a house vinyl portion 144, and an opening and closing window 145.

The body frame 141 forms a structural frame of the house body 140 . That is, a predetermined number of pillars are formed to form a rectangular parallelepiped, and the body frame 141 is installed on top of the rectangular parallelepiped to form a roof shape.

3 is a view showing a greenhouse frame of the variable greenhouse system according to the present invention. Referring to this diagram, the shape of the body frame 141 can be confirmed.

The body panel portion 142 has a plate shape formed to cover one side surface of the body frame 141 .

The second floor bottom portion 143 is located inside the body frame 141, but is formed at a predetermined height so as to divide the layers.

The second floor bottom portion 143 includes a checkered hole portion 143a, and the checkered hole portion 143a is located on one side of the second floor bottom portion 143, but a plurality of perforated holes having a predetermined size are formed. will be.

The house vinyl unit 144 is formed to cover one side of the body frame 141 that is not covered by the body panel unit 142 .

The opening and closing window 145 is formed on one side of the vinyl house part 144.

The house moving member 150 is formed to a size that can accommodate the house main body 140, and one side floor is coupled to the first moving wheel 160 and moved by the first fixed rail 120, and the other side floor is moved by the second moving wheel. It is coupled with (170) and moved by the second fixed rail (130).

The house moving member 150 includes a moving member frame 151, a floor separation frame 152, and a moving member panel part 153.

The movable member frame 151 is a frame constituting the skeleton of the house movable member 150 . The movable member frame 151 is formed larger than the size of the house body 140 in order to accommodate the house body 140 therein.

That is, a predetermined number of pillars are formed to form a rectangular parallelepiped, and the movable member frame 151 is installed on top of the rectangular parallelepiped to form a roof shape.

The layer separation frame 152 may be formed at a position corresponding to the position of the second floor bottom part 143 or may be omitted.

The moving member panel portion 153 forms the outer surface of the moving member frame 151 and is formed in a plate shape.

The first moving wheel 160 is installed on the bottom of one side of the house moving member 150 and is formed to move along the first fixed rail 120 .

The second moving wheel 170 is installed on the bottom of the other side of the house moving member 150 and is formed to move along the second fixed rail 130 .

Two or more of the first moving wheel 160 and the second moving wheel 170 may be formed as needed, and the number thereof is not limited.

The elevator 180 is installed on one side of the inside of the variable type house 100 and is installed to allow the first and second floors to go up and down.

4 is a view showing a state in which aquaponics structures are installed in the greenhouse frame of the variable greenhouse house system of the present invention.

5 is a view showing the installation of the aquaponics structures of the present invention as a whole.

The aquaponics unit 200 is installed inside the variable house 100, and includes a filtration unit 210, a water tank unit 220, a filtration and cultivation unit 230, a first plant cultivation unit 240, and a rearing unit. 250, a seed germination unit 260, a pipe cultivation unit 270, and a cultivation bed unit 280.

The variable house 100 is composed of two floors, and on the first floor, a filtration unit 210, a water tank unit 220, a filtration and cultivation unit 230, a first plant cultivation unit 240, and a rearing unit 250 , The seed germination unit 260 is located, and the pipe cultivation unit 270 and the cultivation bed unit 280 are located on the second floor.

In addition, it goes without saying that the components of the aquaponics 200 may be arranged all at once on the first floor.

In addition, each component of the aquaponics unit 200 is connected by the first connection pipe 201 to the eighth connection pipe 208.

That is, the first connection pipe 201 is formed so that one end is connected to the filtering unit 210 and the other end is connected to the water tank unit 220,

The second connection pipe 202 has one end connected to the water tank unit 220 and the other end connected to the filtration and culture unit 230,

The third connection pipe 203 has one end connected to the filtration and culture unit 230 and the other end connected to the first plant cultivation unit 240,

The fourth connection pipe 204 has one end connected to the first plant cultivation unit 240 and the other end connected to the rearing unit 250,

The fifth connection pipe 205 has one end connected to the growing unit 250 and the other end connected to the pipe cultivation unit 270,

The sixth connection pipe 206 has one end connected to the breeding unit 250 and the other end connected to the cultivation bed unit 280,

The seventh connection pipe 207 has one end connected to the pipe cultivation unit 270 and the other end connected to the cultivation bed unit 280,

The eighth connection pipe 208 has one end connected to the growth bed unit 280 and the other end connected to the filtering unit 210.

6 is a view of aquaponics structures installed on the first floor of the greenhouse house of the variable greenhouse system according to the present invention.

The filtering unit 210 is for filtering impurities and organic particles of water introduced from the eighth connection pipe 208 connected to the growth bed unit 280.

The water tank unit 220 receives water supplied from the filter unit 210 through the first connection pipe 201 and stores the water therein so that aquatic organisms can inhabit it.

7 and 8 are views showing the filtering and cultivation unit 230 of the variable greenhouse system according to the present invention.

In the filtering and culturing unit 230, a tubular vortex chamber unit 231 of a predetermined size is formed to remove impurities from the water supplied from the second connection pipe 202 connected to the water tank unit 220, and microorganisms are cultured. The culture unit 232 is formed in the form of a tube larger than the size of the vortex chamber unit 231 so as to be able to do so.

The filtration and culture unit 230 includes a whirlpool chamber unit 231, a culture unit 232, an inlet unit 233, a whirlpool chamber drain pipe 234, a final water discharge unit 235, a floating matter discharge unit 236, It is configured to include a filtration filter unit 237.

The vortex chamber unit 231 and the culturing unit 232 of the filtering and culturing unit 230 can filter and culture water by the siphon principle, and each component will be described in detail as follows.

The vortex chamber part 231 is formed in the form of a tube of a predetermined size and is a cycling tube operated in a cycling manner by introducing water therein.

The culture unit 232 is formed in a tubular shape larger than the vortex chamber unit 231, and the vortex chamber unit 231 is located therein.

The bottom part 232 is formed to accommodate the filtered water inside the vortex chamber part 231 so that beneficial bacteria in the water can proliferate.

The inlet part 233 is formed in a tubular shape so that water is introduced from the water tank part 220 and the water is received in the vortex chamber part 231, but one end is formed to penetrate the culture part 232 and be connected to the outside, and the other end is formed to be connected to the outside. It is formed to pass through the vortex chamber part 231 and be accommodated into the inside of the vortex chamber part 231.

The whirlpool chamber drain pipe 234 has one end connected to the whirlpool chamber unit 231 and the other end located on one side inside the culturing unit 232 located outside the whirlpool chamber unit 231.

The vortex chamber drain pipe 234 circulates water accommodated in the vortex chamber unit 231 and water accommodated in the culture unit 232 by the siphon principle.

Referring to FIG. 9, referring to a view showing a filtration and cultivating unit 230 of the variable greenhouse system of the present invention, except for the culturing unit 232, the vortex chamber drain pipe 234 passes a predetermined number at predetermined intervals on one side. A hole 234a may be formed.

The passage hole 234a is formed to allow water to circulate more smoothly, and allows water to move not only to the end of the whirlpool chamber drain pipe 234 but also to the passage hole 234a so that the inside can be operated smoothly.

The final water discharge unit 235 is connected to one side of the culture unit 232 and is formed in a tube shape having a predetermined length to discharge filtered water to the outside.

The floating matter discharge unit 236 has one end located on one side of the lower part of the vortex chamber 231 so that the floating matter is discharged from the vortex chamber 231, but the other side extends outside the culture unit 232.

One side of the floating matter discharge unit 236 is located at the lower end of the culturing unit 232 and the other side extends upward along the side of the culturing unit 232 .

After being filtered in the vortex chamber 231, the floating matter sinks to the bottom and is moved to the floating matter discharge part 236. It is formed so that it can be pulled out.

A predetermined number of filter units 237 are located inside the vortex chamber unit 231 and are filters for filtering water. Due to the filtration filter unit 237, it is possible to filter foreign substances such as bacteria in the water.

10 is a diagram showing the operation of the filtering and cultivation unit 230 of the variable greenhouse system according to the present invention.

The water flowing into the vortex chamber 231 through the inlet 233 (refer to the direction of arrow a1) is moved in a cycling manner inside the vortex chamber 231 (see arrow a2) to filter the filter unit (see arrow a2). 237), the water is filtered, and some of the filtered water is discharged to the whirlpool chamber drain pipe 234 (see arrow a3) and moved into the culture unit 232.

The water in which beneficial bacteria proliferate after staying in the culture unit 232 for a predetermined time is discharged to the outside along the final water discharge unit 235 (a4).

In addition, if necessary, the water filtered in the vortex chamber unit 231 through the vortex chamber drain pipe 234 is moved to the culture unit 232, or the water cultured in the culture unit 232 is returned to the inside of the vortex chamber unit 231. It can be moved to can be repeated, and through this, the work of filtering and culturing the water is repeated, so that more and more beneficial bacteria in the water can be proliferated.

The first plant cultivation unit 240 is provided so that water passing through the third connection pipe 203 connected to the filtering and culturing unit 230 is supplied and plants can be grown.

The first plant cultivation unit 240 is for growing root vegetables by filling the inside with pebbles, so that water can be filtered by the pebbles.

In the breeding unit 250, the water passing through the fourth connection pipe 204 connected to the first plant growing unit 240 is moved and accommodated, and the seeds germinated from the seed germination unit 260 are nurtured to a predetermined size. will be formed

The seed germination unit 260 has a space of a predetermined size and is for planting seeds for germination. In addition, the seed germination unit 260 is a place for germinating seeds before seeding the seeds in the breeding unit 250.

The seed germination unit 260 includes a lighting unit 261, and the lighting unit 261 is located above and below the seed germination unit 260. The lighting unit 261 is installed to help germinate the seeds located in the seed germination unit 260 by installing lighting such as LED.

11 is a view of aquaponics structures installed on the second floor of the greenhouse house of the variable greenhouse system according to the present invention.

The pipe cultivation unit 270 is formed of a plurality of tubes of a predetermined length, and one side receives water from the fifth connection pipe 205 connected to the cultivation unit 250, and is formed for transplanting and cultivating sprouts.

The pipe cultivation unit 270 includes a first pipe connection part 271, a pipe body part 272, and a second pipe connection part 273.

The first pipe connection part 271 is formed on one side of the pipe body part 272 and is connected to the fifth connection pipe 205 connected from the meat farming part 250 to serve as a passage through which water introduced from the meat farming part 250 passes. is to do

The pipe body part 272 is formed in the form of a pipe of a predetermined length, and is for transplanting and cultivating sprouts, and is for moving water as water is introduced from the first pipe connection part 271 connected to one side.

The second pipe connection part 273 is formed on the other side of the pipe body part 272 and is formed to be connected to a connection pipe connected to the bed part 280.

The cultivation bed unit 280 uses a seventh connection pipe 207 connected to the second pipe connection unit 273 of the pipe cultivation unit 270 or a sixth connection pipe 206 connected to the first plant cultivation unit 240. It is formed with an internal space of a predetermined size to receive water through and grow plants.

12 is a state in which the departure prevention stopper 300 is installed in the greenhouse of the variable greenhouse system according to the present invention, and FIG. 13 is a view showing the departure prevention stopper 300 alone according to the present invention.

The departure prevention stopper 300 is installed to prevent the house movable member 150 of the variable house 100 from being separated, and is formed on both sides of the lower part of the house movable member 150 of the variable house 100. It includes the first stopping part 310 and the second stopping part 320 formed at the end of the first fixed rail 120 and the end of the second fixed rail 130, respectively.

The first stopping part 310 includes a first stopping frame part 311, a stopping rod part 312, and a first house departure prevention part 313.

The first stopping frame part 311 is formed in the form of a plate of a predetermined size located at the lower part of one side and the lower part of the other side of the house moving member 150, respectively, and is formed with a wall surface and a bottom surface, so that it has a 'b' shape when viewed from the side. It is formed into a shape.

The stopping rod portion 312 is located on one side of the wall surface of the first stopping frame portion 311 and is formed to have a predetermined length. The stopping rod part 312 is preferably formed to have the same length as the length of the first house departure prevention part 313.

The first house departure prevention part 313 is located on the bottom surface of the first stopping frame part 311 and is formed in a triangular roof shape.

The second stopping part 320 is formed to be positioned on the same line as the first stopping part 310 .

The second stopping part 320 includes a second stopping frame part 321, a third stopping frame part 322, a second house departure prevention part 323, and a reinforcing part 324. .

The second stopping frame portion 321 is located at one end of the first fixed rail 120 and the second fixed rail 130, but is perpendicular to the first fixed rail 120 and the second fixed rail 130, respectively. It is formed in a plate shape of a predetermined size.

The third stopping frame portion 322 is formed to be perpendicular to one side of the second stopping frame portion 321 and has a plate shape of a predetermined size.

The second house departure prevention part 323 is located on the lower surface of the third stopping frame part 322 and accommodates the first house departure prevention part 313 of the first stopping part 310 in the first house. It is formed in a triangular roof shape corresponding to the departure prevention unit 313.

The reinforcing part 324 is formed in a triangular roof shape formed along one side of the second stopping frame part 321 .

14 is a view showing an operation example of the departure prevention stopper 300 of the present invention, and it can be seen that the first stopping part 310 and the second stopping part 320 are fastened.

The control unit 400 is to control the movement of the first moving wheel 160 and the second moving wheel 170.

The embodiments described in this specification and the configurations shown in the drawings as described above are merely the most preferred embodiments of the present invention and do not represent all of the technical spirit of the present invention, so various equivalents and modifications that can replace them It should be understood that there may be examples.

100 Variable House
110 Bottom
120 1st fixed rail
130 2nd fixed rail
140 house body
141 body frame
142 body panel
143 2nd floor floor
143a checkered hole
144 House Vinyl Part
145 open window
150 house moving member
151 moving member frame
152 Floor Separation Frame
153 moving part panel part
160 1st moving wheel
170 2nd moving wheel
180 Elevator
200 Aquaponics Division
210 filter unit
220 water tank
230 Filtration and culture department
231 vortex chamber part
232 culture department
233 inlet
234 Vortex Chamber Drain Pipe
235 final water discharge
236 float discharge
237 filter unit
240 1st Plant Cultivation Division
250 Meat Division
260 Seed Germination Department
261 lighting unit
270 Pipe Farming Division
271 first pipe connection
272 pipe body
273 2nd pipe connection
280 cultivation bed
201 first connector
202 second connector
203 third connector
204 fourth connector
205 fifth connector
206 sixth connector
207 7th connector
208 8th connector
300 departure prevention stopper
310 first stopping part
311 first stopping frame part
312 Stopping Rod
313 1st House Leaving Prevention Department
320 second stopping part
321 second stopping frame part
322 third stopping frame part
323 Second House Escape Prevention Department
324 reinforcement
400 control unit

Claims (10)

A house main body 140 that is fixed and has a space of a predetermined size, and a house movable member 150 formed to a size that can be covered by the house main body 140 but movable by a rail (100). ),

The variable house 100 is
A bottom part 110 formed in a plate shape of a predetermined size on which the house body 140 is located on one upper surface,
A first fixed rail 120 formed to have a predetermined length along one side of the bottom portion 110;
A second fixed rail 130 formed to have a predetermined length along the other side of the bottom portion 110,
The house body 140 is formed to an acceptable size, and one floor is coupled with the first moving wheel 160 and moved by the first fixed rail 120, and the other floor is coupled with the second moving wheel 170 to The house moving member 150 moved by the 2 fixed rails 130,
A first moving wheel 160 installed on the floor of one side of the house moving member 150 and formed to move along the first fixed rail 120;
It includes a second moving wheel 170 installed on the bottom of the other side of the house moving member 150 and formed to move along the second fixed rail 130,

The house body 140 is
A body frame 141 formed with a predetermined number of pillars to form a rectangular parallelepiped shape and having a roof shape at the top of the rectangular parallelepiped;
A plate-shaped body panel portion 142 formed to cover one side of the body frame 141;
A second floor bottom portion 143 located inside the body frame 141 but formed at a predetermined height to divide the layers;
A house vinyl part 144 formed to cover one side of the body frame 141 that is not covered by the body panel part 142;
Including an opening and closing window 145 formed on one side of the house vinyl unit 144,

The house moving member 150 is
A moving member frame formed so that a predetermined number of pillars are formed to form a rectangular parallelepiped shape and have a roof shape on the top of the rectangular parallelepiped and have a size larger than the size of the house body 140 to accommodate the house body 140 ( 151) and,
A variable greenhouse house system comprising a plate-shaped movable member panel portion 153 forming an outer surface of the movable member frame 151. According to claim 1,
The second-floor bottom part 143 is located on one side of the second-floor bottom part 143 and includes a checkered hole part 143a in which a plurality of perforated holes of a predetermined size are formed. According to any one of claims 1 or 2,
The first stopping part 310 is installed to prevent the house movable member 150 of the variable house 100 from being separated, and is formed on both lower sides of the house movable member 150 of the variable house 100. And a departure prevention stopper 300 including a second stopper 320 formed at an end of the first fixed rail 120 and an end of the second fixed rail 130, respectively,
The first stopping part 310 is
The first stopping frame part is formed in a plate shape of a predetermined size located at the lower part of one side and the lower part of the other side of the house moving member 150, and is formed with a wall surface and a bottom surface and is formed in an 'B' shape when viewed from the side. (311) and
A stopping rod portion 312 located on one side of the wall surface of the first stopping frame portion 311 and having a predetermined length;
A first house separation prevention part 313 located on the bottom surface of the first stopping frame part 311 and formed in a triangular roof shape,
The second stopping part 320 is
The second fixed rail 120 and the second fixed rail 130, each located at one end, perpendicular to each of the first fixed rail 120 and the second fixed rail 130 and formed in a plate shape of a predetermined size. A stopping frame part 321,
A third stopping frame portion 322 formed to be perpendicular to one side of the second stopping frame portion 321 and formed in a plate shape of a predetermined size;
A triangle located on the lower surface of the third stopping frame part 322 and corresponding to the first house leaving preventing part 313 so as to accommodate the first house leaving preventing part 313 of the first stopping part 310. A second house departure prevention unit 323 formed in a roof shape;
The variable greenhouse house system, characterized in that it includes a reinforcing part 324 formed in a triangular roof shape formed along one side of the second stopping frame part 321. According to claim 1,
It is installed inside the variable house 100 and includes an aquaponics unit 200 for plant cultivation,
The aquaponics unit 200
A filtering unit 210 for filtering impurities and organic particles of water introduced from the outside;
An aquarium unit 220 provided to receive water supplied from the filtering unit 210 through the first connection pipe 201 and store it therein so that aquatic organisms can inhabit;
In order to remove impurities from the water supplied from the second connection pipe 202 connected to the water tank unit 220, a tubular vortex chamber 231 of a predetermined size is formed, and the vortex chamber 231 is formed so that microorganisms can be cultured. ) A filtration and culturing unit 230 in which the culture unit 232 is formed in the form of a tube larger than the size of the
A variable greenhouse house system characterized in that it includes a first plant cultivation unit 240 provided to supply water passing through the third connection pipe 203 connected to the filtration and cultivation unit 230 and to grow plants. . According to claim 4,
The filtration and culture unit 230
A vortex chamber part 231 formed in the form of a tube of a predetermined size and operated in a cycling manner by introducing water into the inside;
A culture unit 232 formed in a tubular shape larger than the vortex chamber unit 231 so that the vortex chamber unit 231 is located therein;
Water is introduced from the water tank unit 220 and is formed in a tubular shape so that water is received in the vortex chamber unit 231, and one end is formed to pass through the culture unit 232 to be connected to the outside, and the other end is formed to be connected to the vortex chamber unit 231 An inlet 233 formed to pass through and be accommodated into the vortex chamber 231;
A vortex chamber drain pipe 234 having one end connected to the vortex chamber unit 231 and the other end located on one side inside the culture unit 232 located outside the vortex chamber unit 231;
A final water discharge unit 235 connected to one side of the culture unit 232 and formed in a tube shape of a predetermined length to discharge filtered water to the outside;
A floating matter discharge part 236 having one end located on one side of the lower part of the vortex chamber part 231 so that the floating matter is discharged from the vortex chamber part 231, but the other end extending to the outside of the culture part 232,
A variable greenhouse house system characterized in that it is configured to include a filter unit 237 for filtering water while a predetermined number is located inside the vortex chamber unit 231. According to claim 4,
The water that has passed through the fourth connection pipe 204 connected to the first plant cultivation unit 240 is moved and accommodated, and the seed germinating unit 260 is formed to a predetermined size to grow the germinated seeds (250). )and,
A variable greenhouse system characterized in that it has a space of a predetermined size and includes a seed germination unit 260 for planting seeds for germination. According to claim 6,
A plurality of tubes of a predetermined length are formed, and one side is supplied with water from the fifth connection pipe 205 connected to the cultivation unit 250, and includes a pipe cultivation unit 270 formed to transplant and cultivate sprouts. A variable greenhouse house system, characterized in that for doing. According to claim 7,
An internal space of a predetermined size is provided to receive water through the seventh connection pipe 207 connected to the pipe cultivation unit 270 or the sixth connection pipe 206 connected to the first plant cultivation unit 240 and grow plants. A growth bed portion 280 formed with
A seventh connection pipe 207 having one end connected to the pipe cultivation unit 270 and the other end connected to the cultivation bed unit 280;
A variable greenhouse house system comprising an eighth connection pipe 208 having one end connected to the cultivation bed unit 280 and the other end connected to the filtering unit 210. According to claim 8,
It includes an elevator 180 installed on one side of the inside of the variable house 100,
By further comprising a whirlpool chamber drain pipe 234 having a predetermined number of passing holes 234a formed at predetermined intervals on one side of the filtering and culturing unit 230,
The water introduced into the vortex chamber 231 through the inlet 233 is filtered by the filtration filter 237 inside the vortex chamber 231 operated in a cycling manner, and the water is filtered. Some of the water is discharged to the vortex chamber drain pipe 234 and moved to the inside of the culture unit 232, and the water in which beneficial bacteria proliferate by staying in the culture unit 232 for a predetermined time goes to the outside along the final water discharge unit 235. Characterized in that it is discharged as
The pipe cultivation unit 270
A first pipe connection part 271 formed on one side of the pipe body part 272 and connected to the fifth connection pipe 205 connected from the fleshing part 250 so that the water flowing in from the fleshing part 250 passes ,
A pipe body portion 272 formed in the form of a tube of a predetermined length, for transplanting and cultivating sprouts, and for moving water as water flows in from the first pipe connection portion 271 connected to one side;
The variable greenhouse house system characterized in that it includes a second pipe connection part 273 formed on the other side of the pipe body part 272 and connected to a connection pipe connected to the bed part 280.

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