KR101404306B1 - Glasshouse having hot and cold water circulation structure using plaveneer panel - Google Patents

Abstract

The present invention relates to a greenhouse having a cold and hot water circulation structure using plaveneer panels. A greenhouse which blocks the outside air and enables cultivation of flowers, fruits, or vegetables is formed by installing a plurality of rows of plaveneer panels that have a plurality of flow paths at constant intervals, where cold and hot water circulates through iron frames which are main frames of the greenhouse. The greenhouse having the cold and hot water circulation structure according to the present invention can be easily assembled by preparing panels where cold and hot water circulates with plaveneer panels and can circulate cold and hot water through flow paths which are formed when the plaveneer panels are manufactured. Also, the assembly of the greenhouse is very simple, the maintenance and repair can be easy since damage to the panels according to temperature change is small, and plant damage or human injury can be minimized since the plaveneer panel are safer than existing glass panels.

Description

[0001] The present invention relates to a glasshouse having a hot and cold water circulation structure using a plastic panel,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a greenhouse having a cold and hot water circulation structure using a plastic panel, and more particularly, to a greenhouse having a circulation structure for circulating hot and cold water, The present invention relates to a greenhouse having a circulation structure of cold and hot water using a plastic panel made by arranging a plurality of panels (also referred to as "synthetic resin plywood") in multiple rows.

Generally, the use of a greenhouse is absolutely necessary for cultivating plants, fruits and vegetables regardless of the season. In such a greenhouse, it is possible to cultivate plants, fruits, and vegetables in the interior using vinyl or glass panels (Vinyl house) or glass greenhouse with a cultivation space.

In this case, the vinyl greenhouse is structured to be very vulnerable to natural phenomena such as wind, hail, and snow due to the nature of the structure using vinyl, and besides, it is necessary to perform separate cooling and heating in summer and winter There is a problem in that the maintenance cost is large.

On the contrary, in the case of the glasshouse, the glasshouse is not vulnerable to natural phenomena such as wind, hail, and snowfall due to its structural characteristics like the above-mentioned vinyl greenhouse. However, since the entire glasshouse, including the ceiling glass, is heated by solar heat, The inside of the glass greenhouse becomes very dry as it is evaporated by this heat, and it is very difficult to maintain a constant humidity. At the same time, water is frequently supplied as a method for preventing this.

In order to solve the problems of the greenhouses and the greenhouses, the present applicant has proposed Registration No. 10-0989766. The present invention relates to a glass greenhouse having a circulating structure of a colorless antifreeze, wherein a glasshouse is arranged in a steel frame frame constituting a skeleton so as to arrange a plurality of glass panels to shield the outside air and cultivate plants, fruits and vegetables, The panel is a double-layered glass panel formed by two panels separated from each other by an inner space, and a glass greenhouse is formed at the upper and lower ends of the glass greenhouse. And a supply and recovery water tank is provided at the inlet and outlet ends of the supply and recovery pipe, respectively, and the upper and lower ends of the multi-layer glass panels arranged in a row are connected to a supply pipe An inlet / outlet pipe through which the supplied colorless antifreeze circulates and circulates in a zigzag form in the inner space of each double-layer glass panel And the multi-layer glass panels are arranged to communicate with each other through the inlet / outlet pipe.

However, the double-layered glass panel disclosed in the above patent is constructed by fixing and fixing a space bar made of aluminum or stainless steel to the four sides of the reinforced glass so as to form an internal space between two tempered glass pieces each having a rectangular shape, There is a problem that the structure is complicated and the manufacturing cost is also high.

Especially, in the multi-layered glass panel using the reinforced glass or the laminated glass, since the weight of the reinforced glass panel is increased, the steel frame which forms the framework of the greenhouse must be rigidly designed.

In addition, since the tempered glass and the space bar are simply bonded to each other in the multilayer glass panel, the antifreeze is leaked due to the temperature difference due to the weather change or the phenomenon that the adhesion region between the tempered glass and the space bar is widened due to a change in circulation pressure of the antifreeze, There is also a risk of damage to the plant in the greenhouse due to breakage of the glass or safety risk of the worker.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a panel for forming a greenhouse for cultivation of plants and the like by applying a panel to a panel to form an inner space, The present invention is to provide a greenhouse having a cold and hot water circulation structure using a plastic panel that can prevent leakage of safe and circulating floating oil without fear of damage due to change.

Another object of the present invention is to provide a greenhouse which can be easily installed on a steel frame which forms a skeleton of a greenhouse and can be designed by lowering the safety standard of a steel frame which supports the panel as a whole, And to provide a greenhouse having a cold and hot water circulation structure using a plastic panel that can be constructed at a low cost.

In order to solve such a technical problem,

A greenhouse constructed in such a manner that plants, fruits and vegetables can be cultivated while blocking the outside air, wherein the greenhouse has a plurality of fl avian panels in which a plurality of flow paths through which cold and hot water circulate in a steel frame frame constituting a skeleton are formed at regular intervals, The present invention provides a greenhouse having a cold / hot water circulation structure using a plastic panel.

At this time, a frame member on which the plastic panel is installed is integrally fixed to the surface of the steel frame, and the frame member supports the edge portion of the plastic panel by forming the support tuck.

And a UV layer is further formed on the surface of the plastic panel.

In addition, a connection port for supplying cold / hot water to one end of the flow path of the plastic panel, a circulation connection port for guiding cold / hot water circulating through the channel to the adjacent channel, and a discharge connection port for discharging cold / And is fixed.

At this time, the supply connection port is connected to the supply pipe 22 of the supply water tank for supplying the cold / hot water, and the discharge connection port is connected to the discharge pipe of the recovery water tank for recovering the cold / hot water discharged through the circulation .

The supply water tank is characterized by comprising a cold water tank for supplying cold water and a hot water tank for supplying hot water.

In addition, the supply connector includes a first fitting part inserted into a flow path formed in the plastic panel and an inflow part into which the cold / hot water flows.

The circulation connector may include a second fitting part inserted into the flow path formed in the plastic panel and a third fitting part fitted in the adjacent flow path.

In addition, the discharge connector may include a fourth fitting portion inserted into the flow path and a discharge portion through which the cold / hot water is discharged.

In addition, the discharge portion is bent in a stepped manner in a crank shape, and the discharge portion is further provided with a check valve.

Further, a plurality of non-oil passages in which cold / hot water is not circulated is further formed between the flow paths, and a finishing member for finishing both ends of the non-oil passages is further attached.

In addition, the closing member is formed with a vent hole for keeping the air pressure inside the oil passage equal to the air pressure of the outside air.

In addition, a plurality of non-oil passages in which cold / hot water is not circulated is further formed between the flow paths, and the cross section of the flow passages is circular, and the cross section of the non-flow passages is rectangular.

And a tube body through which cold / hot water can flow is further inserted into the flow path.

The first panel may include a plurality of barrier ribs for forming a flow path, a first fastening protrusion may be formed on the barrier rib, and a second fastening protrusion may be formed on the second panel. A second fastening protrusion to be fastened to the first fastening protrusion is formed, and a tubular body through which cold / hot water flows can be inserted into the passage.

In addition, the above-mentioned plastic panel is a multi-layer structure in which the upper layer is formed of a non-oil furnace in which cold / hot water does not flow, and the lower layer is a multi-layer structure in which a channel through which cold / hot water flows and a non-

And a continuous connector is fastened to an end of the plastic panel, wherein the continuous connector includes an insertion portion to be inserted into and connected to the flow path of the plastic panel, an extension portion to which the connection tube to be connected to the adjacent continuous connector is inserted, And a finishing portion for finishing the non-oil furnace of FIG.

In addition, the first and second finishing members for finishing both sides of the plastic panel are integrally provided.

In this case, the first and second closing members are formed by first and second projecting portions and first and second groove portions on the side surfaces of the first and second cover portions surrounding the side surface of the plastic panel.

In the greenhouse having the cold / hot water circulation structure according to the present invention, the panel in which the cold / hot water circulates is made of the plastic panel and the cold / hot water can circulate through the channel formed in the production of the plastic panel, so that the greenhouse can be assembled as a whole.

In addition, even if the greenhouse is assembled easily and the cold / hot water circulates, it is less likely to damage the panel due to the external temperature change, which is advantageous for maintenance, and is safer than conventional glass panels, have.

In particular, since the greenhouse of the present invention uses a relatively lightweight plastic panel compared to glass, the load of the greenhouse as a whole is significantly reduced as compared with the case of using a double-layered glass, so that the structure of the steel frame forming the framework of the greenhouse can be simplified The cost of greenhouse production can be reduced.

1 is a perspective view illustrating a greenhouse having a cold and hot water circulation structure using a plastic panel according to the present invention.
2 is a front view showing a greenhouse having a cold / hot water circulation structure using a plastic panel according to the present invention.
FIG. 3 is a view illustrating the flow of an antifreeze in a greenhouse having a cold / hot water circulation structure using a plastic panel according to the present invention.
FIG. 4 is an exploded view of a greenhouse plastic panel having a cold / hot water circulation structure according to an embodiment of the present invention.
5 is a front view of a greenhouse plastic panel having a cold / hot water circulation structure according to the present invention.
6 is a cross-sectional view of a greenhouse plastic panel having a cold / hot water circulation structure according to the present invention.
7 is an exploded perspective view illustrating a continuous connection structure of a greenhouse plastic panel having a cold / hot water circulation structure according to the present invention.
FIG. 8 is a cross-sectional view illustrating the continuous connection structure of the green plastic container panel of FIG. 7;
9 is a view showing another embodiment of a greenhouse plastic panel having a cold / hot water circulation structure according to the present invention.
10 is a view showing still another embodiment of a greenhouse plastic panel having a cold / hot water circulation structure according to the present invention.
11 is a view showing still another embodiment of a greenhouse plastic panel having a cold / hot water circulation structure according to the present invention.
FIG. 12 is a view showing still another embodiment of a greenhouse-use plasticine panel having a cold / hot water circulation structure according to the present invention.
FIG. 13 is a view showing still another embodiment of a greenhouse-use plasticine panel having a cold / hot water circulation structure according to the present invention.
FIG. 14 is a view showing still another embodiment of a greenhouse plastic panel having a cold / hot water circulation structure according to the present invention.
FIG. 15 is a view showing still another embodiment of a greenhouse plastic panel having a cold / hot water circulation structure according to the present invention.
16 is a view showing still another embodiment of a greenhouse-use plastic panel having a cold / hot water circulation structure according to the present invention.
17 is a view showing still another embodiment of a greenhouse plastic panel having a cold / hot water circulation structure according to the present invention.

The characteristics of the greenhouse having the cold and hot water circulation structure using the plastic panel according to the present invention will be described with reference to the accompanying drawings.

1 to 3, the greenhouse 1 of the present invention includes a plurality of flabannia panels 100 on a steel frame 10 having a door 2 on the front and rear surfaces as a whole, It is constructed in the same structure as a normal house which has a cultivation space inside so as to cultivate flowers, fruits and vegetables while shielding the outside air by installing a multi-row arrangement.

The plurality of plastic panel 100 arranged on the steel frame 10 is generally called a PVC corrugated cardboard and the steel frame 10 forming the frame of the greenhouse 1 is formed of various steel members such as Hib beam or I- .

In the fl avenia panel 100, a plurality of flow paths 102 are formed at regular intervals, and the supplied cold and hot water circulates and flows, while maintaining indoor and outdoor temperatures by the temperature of the hot and cold water, The indoor temperature of the indoor unit 1 is uniformly formed to thereby provide an improved indoor environment, and the plant, fruit, and vegetables can be grown more smoothly.

In particular, the cold / hot water circulating through the flow path 102 of the plastic panel 100 may be colored cold / hot water containing various colors of paint or the like in accordance with characteristics of a plant weak to the sunlight. It is also possible to use antifreeze to prevent freezing of the flow path 102.

In the case of the steel frame 10 constituting the greenhouse 1 of the present invention having the above-described structure, the steel frame 10 is formed of a lattice-shaped frame for producing a house having a cultivation space therein, The frame member 11 on which the panel 100 is mounted is integrally fixed by welding or the like. The frame member 11 is formed with a support step 11a to support the edge portion of the plastic panel 100. Such a plastic panel 100 is integrally fixed to the frame member 11 by using a silicon 12 or the like.

In this case, as described above, the frame member 100 is provided with one piece of the plastic panel 100, and each of the plastic panels 100 is arranged adjacent to the top, bottom, left, The flange panel 100 is arranged in a state of being spaced apart from each other at an equal interval and the flange panel 100 is filled with the silicone 12 or a fibrous material such that the flange panel 100 has a thermal insulation effect, 14, and the cover 14 may be covered with the finishing lid 14 depending on the use.

In addition, the plastic panel 100 may be installed to constitute only the upper roof of the greenhouse.

In addition, a plurality of flow passages 2a may be formed in the door 2 so that cold and hot water can be circulated through the passageway. A plurality of flow passages, through which cold / hot water can circulate, The door 2 can be manufactured.

Here, the plastic panel 100 arranged on the frame member 11 is as shown in FIGS.

The plastic panel 100 is formed by partitioning a plurality of flow paths 102 through which cold and hot water can circulate so as to be spaced at regular intervals. The plastic panel 100 is made by extruding or injection molding a plastic material such as PC resin or PVC resin, Size.

Although the plurality of flow paths 102 may be vertically oriented, the plastic panel 100 may be installed so as to face the horizontal direction so as to lower the water pressure of the cold / hot water moving in the flow path 102 So that the cold / hot water circulates through the flow path 102. At this time, the oil passage (102) may be formed continuously, but the oil passage (104) in which cold / hot water is not circulated between the oil passages (102) is formed so as to maintain a constant interval. In this case, the channel 102 and the non-channel 104 may have the same rectangular cross section or may have different shapes.

A UV layer (101) is formed on the surface of the plastic panel (100) in order to solve the problem of discoloration or discoloration when the plastic panel (100) is exposed to sunlight for a long time. Of course, the UV layer 101 may be formed on both sides of the plastic panel 100.

At this time, the UV layer 101 is formed by coating a UV paint on the surface of the plastic panel 100 or attaching a UV film.

On the other hand, at one end of the plurality of flow paths 102 of the plastic panel 100, a supply connection port 110 for supplying cold / hot water, and cold / hot water circulating the flow path 102 to an adjacent flow path 102 ' And a discharge connection port 130 for discharging cold / hot water moving through the flow path 102 are fixed.

More specifically, the cold / hot water in the supply water tank 20 supplied along the supply pipe 22 through the supply connection port 110 connected to one side of the flow path 102 formed in the plastic panel 100 And is circulated through the oil line 102. [ The cold / hot water flowing through the flow path 102 is guided to the adjacent flow path 102 'through the circulation connection port 120 and moves. The cold and hot water circulating in this way circulates in the zigzag direction on the plastic panel 100 through a series of circulation processes in which the cold and hot water circulating through the circulation port 120 is moved to the adjacent channel 102 again. The cold / hot water flowing through the flow path 102 is finally discharged to the discharge pipe 32 through the discharge connection port 130.

At this time, the supply connection port 110 is provided with a first fitting part 112 inserted into the flow path 102 formed in the plastic panel 100 and an inflow part 114 through which the cold / hot water flows. The first fitting part 112 of the supply connection port 110 is integrally fixed to the flow path 102 of the plastic panel 100 using an adhesive.

The circulation connector 120 includes second and third fitting portions 122 and 123 inserted into the flow path 102 formed in the plastic panel 100. In this case, the second fitting portion 122 is fitted in the oil passage 102, and the third fitting portion 123 is fitted in the adjacent oil passage 102 '. That is, the circulation connector 120 is formed as a whole and connects the flow paths 102 and 102 'through which cold / hot water circulates. The second and third fitting portions 122 and 123 of the circulation connector 120 are integrally fixed to the flow path 102 of the plastic panel 100 using an adhesive.

In this case, the interval between the flow path 102 and the non-flow path 103 can be maintained to be constant when the plastic panel 100 is continuously arranged, so that the second and third fitting portions 122 and 123 of the circulation connection port 120, It is preferable to sandwich the above- For this purpose, it is preferable that extension portions are formed on both sides of the plastic panel 100 so as to be half (w / 2) of the width w of the non-flow path 103.

In addition, when the circulation connection ports 120 are continuously connected, the cold / hot water moves in a zigzag manner. A separate closure member 140 for finishing the end of the non-circulation path 104 in which the cold / .

Of course, the closing member 140 may be integrally formed with the supply connection port 110, the circulation connection port 120, and the discharge connection port 130, So that both ends of the non-circulating passage 104 are closed.

At this time, when the air pressure inside the non-oil path (104) is increased in the closure member (140) by forming a plurality of vent holes (142) so that the plastic panel (100) (142) so as to be maintained at the same level as the air pressure of the outside air. Of course, when the air pressure inside the non-oil passage 104 is lowered due to the cold weather, it is obvious that the outside air flows in.

The discharge port 130 includes a fourth fitting portion 132 inserted into the flow path 102 formed in the plastic panel 100 and a discharge portion 134 through which the cold and hot water is discharged. The fourth fitting portion 132 of the discharging connector 130 is integrally fixed to the flow path 102 of the plastic panel 100 using an adhesive. At this time, the discharge part 134 is bent in a crank shape so as to prevent the cold and hot water inside the flow path 102 from being discharged naturally. The discharge unit 134 may further include a check valve 135 to prevent the discharge of the hot and cold water in the flow path 102 due to the inflow of air when the supply of the hot and cold water is interrupted.

On the other hand, the supply water tank 20 comprises a cold water tank 20a for supplying cold water and a hot water tank 20b for supplying hot water. At this time, a heater 20c is provided inside the hot water tank 20b to heat the hot water inside.

The inlet pipe 21a and the water outlet pipe 21b of the cold water tank 20a are provided with open / close valves 21c and 21d, respectively. The inlet pipe 21e and the water outlet pipe 21f of the hot water tank 20b, Closing valves 21g and 21h, respectively.

According to this structure, the cold water or hot water of the cold water tank 20a and the hot water tank 20b is selectively supplied to the supply pipe 21c or 21d or the hot water supply pipe 21b or 21h according to the opening / (22), and the cold / hot water in the recovery water tank (30) can be recovered through the inlet pipe (34). The hot water of the hot water tank 20b is circulated to the plastic panel 100 during the winter and the cold water of the cold water tank 20a is circulated to the plastic panel 100 during the summer to maintain a constant temperature.

The cold water in the cold water tank 20a is circulated to the plastic panel 100 during the daytime during the daytime in the spring or autumn when the daylight is intense, So that the temperature in the greenhouse can be kept constant.

The plastic panel 100 having such a structure has a structure in which the cold and hot water supplied from the supply water tank 20 through the supply pipe 22 through the one end feeds the flow path 102 of the plastic panel 100 in a zigzag form, Respectively. In this case, the plastic panel 100 is integrally fixed to the steel frame 10 by fastening means such as bolts and nuts.

The cold and hot water supplied from the water supply tank 20 and circulated through the flange panel 100 and discharged through the discharge connection port 130 is recovered to the recovery water tank 30 through the discharge pipe 32.

The supply water tank 20 and the recovery water tank 30 are located at the upper and lower ends of the greenhouse 1 while being connected to the inlet and outlet ends of the supply pipe 22 and the return pipe 32, Hot water is supplied from the recovery water tank 30 to the water supply tank 20 side along the inflow pipe 34 by driving the pump 33 because a potential head due to a difference in height is formed.

According to the structure described above, cold and hot water is supplied into the plastic panel 100 to flow the plastic panel 100 in a zigzag form from the lower side to the upper side, and is recovered to the recovery water tank 30 through the recovery pipe 32 And the cold air outside is blocked by the cold / hot water forming the heat insulating layer, so that the temperature inside the greenhouse 1 can be prevented from being lowered and the temperature of the plants, fruits and vegetables can be maintained at a suitable temperature.

7 and 8, the greenhouse plastic panel 100 having the cold / hot water circulation structure according to the present invention can be continuously connected in the longitudinal direction. According to this, the flange panel 100 is connected to the frame member 11 in the longitudinal direction when installed on the frame member 11, and uses the continuous connector 150 so that the cold and hot water can circulate along the flow path 102. The continuous connector 150 includes an insertion portion 151 to be inserted into and connected to the channel 102 of the plastic panel 100 and an extension portion to which the connection tube 160 connected to the adjacent continuous connector 150 ' And a finishing unit 153 for finishing the non-feeding path 104 of the plastic panel 100. [

After the continuous connection 150 is connected, the connection tube 160 is fitted to the outer circumferential surface of the extension part 152 and is fixed to the frame member 11 while being pressed by a clip 162 having elasticity of metal The flange panel 100 is filled with silicone 12 or a fibrous material such that the flange panel 100 has a thermal insulation effect and is then covered with a covering lid 14 to finish the sealing process. It is possible to finish only the cover.

At this time, a plurality of ventilation holes 153a are formed on the surface of the closing portion 153 of the continuous connector 150 so that the air pressure inside the non-passage passage 104 can be maintained equal to the air pressure of the outside air. do.

FIG. 9 is a view illustrating a flavinella panel according to another embodiment of the present invention. According to this, the flow path 102 and the non-flow path 104 through which the cold and hot water circulates are formed in the flange panel 100. The cross section of the flow path 102 is formed in a circular shape and the cross section of the non-

By forming the cross section of the flow path 102 in a circular shape, the pressure of the cold / hot water as the fluid is uniformly dispersed to the inner wall surface, so that the deformation or breakage of the flange panel 100 due to the rise of the pressure of the cold / hot water can be reduced to some extent.

10 is a view illustrating a flavinella panel according to another embodiment of the present invention. As shown in FIG. 9, the cold / hot water can flow through a channel 102 having a circular cross section of a plastic panel 100 as shown in FIG. The tubular body 105 made of various materials such as a metal tube, silicone, hose made of plastic or the like can be inserted to further reduce deformation or breakage of the plastic panel 100 due to a rise in the pressure of the cold / hot water.

And FIG. 11 is a view illustrating a plastic panel according to another embodiment of the present invention. According to this, the plastic panel 100 is divided into first and second panels 106 and 107, and assembled into a plurality of layers.

At this time, the first panel 106 is provided with a plurality of partition walls 106a for separating the passage 102 and the non-passage passage 104, and the first fastening protrusion 106b is formed on the partition wall 106a . The second panel 107 is formed with a non-oil passage 104 through which cold / hot water does not flow, and a second fastening protrusion 107a corresponding to the first fastening protrusion 106b is formed at a lower portion thereof. According to this structure, the tube 105, through which the cold and hot water can flow, is in close contact with the portion where the flow path 102 is formed between the partition walls 106a of the first panel 106, The flange panel 100 can be assembled by fastening the fastening protrusion 107a to the first fastening protrusion 106b.

Meanwhile, FIG. 12 is a view illustrating a plastic panel according to another embodiment of the present invention. As shown in the figure, the upper layer is used as a non-oil path 104 in which cold / hot water does not flow, and the lower layer is used as a channel 102 in which cold / hot water flows, And the non-flow path 104 is used separately. This maximizes the adiabatic effect and keeps the temperature inside the greenhouse stable and constant.

13 is a view showing a plastic panel according to another embodiment of the present invention. This is because the cold and hot water of the supply water tank 20 supplied along the supply pipe 22 is supplied through the supply connection port 110 connected to one end of the flow path 102 formed in the plastic panel 100, And is directly discharged to the discharge pipe 32 through the discharge connection port 130 connected to the other end of the flow path 102. [ That is, the hot and cold water is circulated only in one direction in the plastic panel 100 without circulating zigzag.

FIGS. 14 to 17 are views showing the plasticine panels according to another embodiment of the present invention. According to this, the first and second closure members 170 and 180 for closing both sides of the flange panel 100 are integrally formed on both sides.

In this case, as shown in Figs. 14 and 16, both side surfaces of the single-layered type plastic panel 100 may be used for finishing, or the first and second panels 106 and 107 may be divided The present invention is also applicable to the plastic panel 100 assembled.

At this time, in the case of the double-layered plastic panel 100, the first panel 106 forms only the non-flow path 104 in which the cold and hot water does not flow as the upper layer, and the second panel 107 forms the flow path 102, And a non-oil passage 104 in which no cold / hot water flows. This maximizes the adiabatic effect and keeps the temperature inside the greenhouse stable and constant.

Accordingly, the first and second closure members 170 and 180 can close both sides of the multi-layered or monolayered flabana panel 100, and the first and second closure members 170 and 180 can be made from a plastic panel The first and second protrusions 172 and 182 and the first and second trenches 173 and 183 are formed on the side surfaces of the first and second cover parts 171 and 181 surrounding the side surface of the first cover part 100.

The first projection 172 of the first closing member 170 is seated in the second groove 182 of the second closing member 180 fitted to the side of the adjacent flange panel 100 ' And is seated on the second projection 182 of the second closing member 180 in the first groove 172 of the first closing member 170.

Of course, the contact portions between the first and second protrusions 172 and 182 and the first and second trenches 173 and 183 are integrally joined by applying an adhesive. In this case, as shown in FIGS. 14 and 15, the first and second protrusions 172 and 182 and the first and second trenches 173 and 183 are formed in a Z- As shown in FIG. 17, the cross-section of the flap panel 100 can be prevented from being deviated upwardly and downwardly.

By using the first and second closing members 170 and 180, the flange panel 100 can be firmly and continuously connected in the lateral direction.

Although the embodiments of the present invention have been described in detail in the foregoing, the scope of the present invention is not limited thereto, and the scope of the present invention extends to substantially the same range as the embodiments of the present invention.

1: Greenhouse 10: Steel frame
11: frame member 14: finishing cover
20: feed tank 22: feed pipe
30: Recirculating water tank 32: Exhaust pipe
33: Pump 100: Plavana panel
101: UV layer 102:
104: Diagram 105: Tube
106: first panel 107: second panel
110: Feed connector 120: Circular connector
130:

Claims (19)

A greenhouse (1) which is adapted to grow plants, fruits and vegetables while blocking the outside air,
The greenhouse 1 is formed by arranging a plurality of plastic panels 100 having a plurality of flow paths 102 through which cold and hot water circulates in a steel frame frame 10, A greenhouse with cold and hot water circulation structure using a plastic panel.
The method according to claim 1,
A frame member 11 on which a plastic panel 100 is installed is integrally fixed to the surface of the steel frame 10 and the frame member 11 is formed with a support frame 11a, Wherein the support member supports the edge portion of the plastic panel.
The method according to claim 1,
Wherein the plastic panel (100) further comprises a UV layer (101) on the surface thereof.
The method according to claim 1,
One end of the flow path 102 of the plastic panel 100 is provided with a supply connection port 110 for supplying cold and hot water and a circulation connection port 110 for guiding cold / hot water circulating through the flow path 102 to an adjacent flow path 102 ' And a discharge connection port (130) for discharging cold / hot water moving through the flow path (102) is fixed to the greenhouse (120).
5. The method of claim 4,
The supply connection port 110 is connected to a supply pipe 22 of a supply water tank 20 for supplying cold and hot water and the discharge connection port 130 collects cold and hot water circulated through the flow path 102 And a discharge pipe (32) of the recovery water tank (30).
6. The method of claim 5,
Wherein the supply water tank (20) comprises a cold water tank (20a) for supplying cold water and a hot water tank (20b) for supplying hot water.
5. The method of claim 4,
Wherein the supply connection port 110 is provided with a first fitting part 112 inserted into the flow path 102 formed in the plastic panel 100 and an inflow part 114 through which the cold / A greenhouse with cold and hot water circulation structure using veneer panel.
5. The method of claim 4,
The circulation connector 120 includes a second fitting part 122 inserted into the flow path 102 formed in the plastic panel 100 and a third fitting part 123 fitted to the adjacent flow path 102 ' And a circulation system for circulating the hot and cold water.
5. The method of claim 4,
The discharge connector 130 is provided with a fourth fitting part 132 inserted into the flow path 102 and a discharge part 134 through which the cold and hot water is discharged. greenhouse.
10. The method of claim 9,
Wherein the discharge part (134) is formed in a stepped shape in a crank shape, and the discharge part (134) is further provided with a check valve (135).
5. The method of claim 4,
Wherein a plurality of non-oil passages (104) in which cold / hot water is not circulated are further formed between the oil passages (102), and a closing member (140) for closing both ends of the oil passageway A greenhouse with cold and hot water circulation structure using veneer panel.
12. The method of claim 11,
Wherein the closing member 140 is formed with a vent hole 142 for keeping the air pressure inside the non-passage path 104 equal to the air pressure of the outside air. Having a greenhouse.
The method according to claim 1,
A plurality of non-oil passages 104 are formed between the oil passages 102 so that cold and hot water are not circulated. The oil passages 104 are formed in a circular shape in cross section, Wherein the greenhouse has a cold and hot water circulation structure using a plastic panel.
The method according to claim 1,
Wherein a tubular body (105) through which cold / hot water can flow is further inserted into the flow path (102).
The method according to claim 1,
The flavanic panel 100 comprises first and second panels 106 and 107,
The first panel 106 is provided with a plurality of partition walls 106a for forming a flow path 102. The partition wall 106a has a first fastening protrusion 106b and the second panel 107, A tubular body 105 through which cold / hot water can flow can be inserted into a second fastening protrusion 107a to be fastened to the first fastening protrusion 106b. Greenhouse with cold and hot water circulation structure.
The method according to claim 1,
The upper layer of the plastic panel 100 is formed of a non-oil chamber 104 in which cold and hot water does not flow, and the lower layer is a multi-layer structure in which a channel 102 through which cold / hot water flows and a non- A greenhouse having a cold and hot water circulation structure using a plastic panel.
The method according to claim 1,
The continuous connector 150 is fastened to the end of the plastic panel 100,
The continuous connector 150 includes an insertion portion 151 to be inserted into and connected to the channel 102 of the plastic panel 100 and an extension portion to which the connection tube 160 connected to the adjacent continuous connector 150 ' And a finishing part (153) for finishing the non-oil path (104) of the plastic panel (100). The greenhouse having a cold / hot water circulation structure using the plastic panel.
The method according to claim 1,
Wherein the plastic panel (100) is integrally provided with first and second closure members (170, 180) for closing both sides of the plastic panel (100).
19. The method of claim 18,
The first and second closure members 170 and 180 are provided on the sides of the first and second cover portions 171 and 181 surrounding the sides of the flange panel 100 and the first and second protrusions 172 and 182, And a groove portion (173, 183) are formed on the surface of the greenhouse.

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