JP6259387B2 - Air conditioning equipment for house for plant cultivation - Google Patents

Description

TECHNICAL FIELD The present invention relates to an air conditioning apparatus for a plant cultivation house suitable for forcing and restraint cultivation in a house for plant cultivation such as a greenhouse, and in particular, a house for plant cultivation that uses natural energy such as groundwater and solar heat to grow plants. It is related with the air-conditioning and heating apparatus.

For example, in forcing cultivation of strawberries, in a greenhouse for greenhouses or greenhouses such as greenhouses, a sheet such as mulching is placed on the soil and covered with seedlings to heat the room. It has been known that it is possible to produce fruit even in winter by heating the ground temperature.
However, when cultivating vegetables, fruits, etc. in winter in cold regions, the outside air temperature is particularly low, so it is necessary to perform heating using fossil fuels such as heavy oil and light oil, which greatly increases the cost. Along with the rise, it has become a factor causing global warming and air pollution.

Therefore, in Japanese Patent Laid-Open No. 11-235130 (see Patent Document 1), a solar water heater in which a large number of pipes for feeding groundwater to be pumped are disposed in a place where sunlight hits, and hot water heated by this solar water heater are provided. A heat storage tank for storing, and a pump for supplying to a heating pipe in a greenhouse and / or soil in which a plant to be cultivated with hot water stored in the heat storage tank is planted Plant cultivation equipment has been proposed.
However, in the above prior art, the main purpose is to use the pumped-up groundwater after being heated by a solar water heater and stored in a heat storage tank, and no consideration is given to using it for cooling in summer.
Especially in winter, the water temperature may fluctuate greatly according to the surrounding temperature. Especially in cold regions, even in the case of well water, the water temperature is low, and it is not preferable for plants to grow if it is sprinkled as it is without heating to a certain temperature. We intend to solve the problem.
Therefore, the content is far from the air conditioner of the plant cultivation house.

JP 2007-333360 A (refer to Patent Document 2) and JP 2009-127982 A (refer to Patent Document 3) disclose that air that has been subjected to heat exchange by a heat exchange pipe embedded in the ground is indoors. A geothermal air conditioning system that has been incorporated has been proposed.
In addition, in FIG. 34 (see the Geothermal Utilization Promotion Association website, Non-Patent Document 1), water or antifreeze is circulated between the heat exchanger embedded in the ground and the heat pump, and the heated or cooled air is circulated. A heat pump system using geothermal heat that is taken in indoors has been proposed.
However, even if a heat pump is used, it has been found that air-conditioning of a greenhouse using air has a significant problem in terms of efficiency.

JP 11-235130 A JP 2007-333360 A JP 2009-127982 A

Geothermal Utilization Promotion Association website (http://www.geohpaj.org/introduction/index1/types)

Therefore, the present inventor conducted the following preliminary experiment.
<1. Preliminary experiment results>
1 (a) and 1 (b) show a cubic small-sized experimental chamber, (a) is a state in which the lid is opened, (b) is a schematic perspective view of the mounted state, and (c) is a large-sized experimental chamber. FIG.
For the experiment, first, a side wall panel 201 capable of passing a small 50 cm square groundwater as shown in FIG. Then, the inner wall for heat exchange is constructed by connecting four side wall panels 201, a urethane rubber sheet is pasted on the bottom plate 202, and the ceiling is covered with a two-layer acrylic transparent plate 203, and then covered. An almost cubic sealed chamber 200 was produced.
This was installed in a normal glass house greenhouse, and groundwater at 14.0 ° C. was poured into the side wall panel 201. As for the temperature, the outside air temperature, the temperature inside the house, and the temperature inside the chamber were measured every hour.
Similarly, as shown in FIG. 1C, a large experiment chamber 300 of 90 cm × 180 cm was produced, and winter experiments were performed under the same conditions as the small chamber 200.

FIG. 2 is a graph showing an example of an autumn experiment result in a small chamber.
In this experiment, groundwater (temperature: 13.4 ° C.) was allowed to flow through a small chamber at a flow rate of 300 ml / min from October 27 to 28, 2013 in Tsuru City, Yamanashi Prefecture. The number table on the left shows measured values of the outside air temperature, the temperature inside the house, and the temperature inside the chamber every hour. On the right side is a line graph of the time series changes, where no mark is the outside air temperature, round points are the house temperature, and triangular points are the chamber temperature.
The experiment started flowing groundwater into the side wall panel at 10:00 on the 27th. At this time, the outside temperature was 15.9 ° C. and the inside of the house was 31.7 ° C., but the inside of the small chamber rose to 36.6 ° C. due to sunlight. However, after 1 hour, the temperature dropped to 22.4 ° C. due to the influence of water flow. After that, outside temperature rose to 21.3 ° C until 14:00, but the inside of the house rose to 40.5 ° C due to sunlight. However, although the inside of the small chamber was exposed to sunlight, 23.9 ° C was the highest. It should be noted that the temperature in the chamber is stable at about 14.5 ° C. ± 1 ° C. from 17:00 to the next morning and is leveling off. Although it was cold in autumn, the minimum outside temperature dropped to 5.5 ° C and the temperature in the house dropped to 8.5 ° C at midnight, but the inside of the chamber fell below 13.4 ° C, the groundwater temperature that passed through. No results were obtained.

<2. Results of winter experiments in a large chamber>
FIG. 3 is a graph showing an example of a winter experiment result in a large chamber. The measurement is a result of temperature measurement for 26 hours from 11:00 to February 12th, February 11, 2014. This is a line graph of the time series of measured values of outside air temperature, house temperature, chamber temperature, and running water temperature every hour. No marks are outside air temperature, round points are house temperature, and triangle points are chamber temperature. The square points are the groundwater temperatures that flowed through the panels. On the 11th, daytime Koharu weather was warm, and the daytime temperature rose to 15 ° C. However, in the afternoon, severe cold air masses entered the sky, the temperature dropped rapidly, and it cooled down to minus 8.6 degrees in the early morning of the 12th. Although the original groundwater temperature is around 14 ° C, it seems to be slightly affected by the outside air temperature in the water supply route to the house, but it was almost constant at 13.5 to 14.5 ° C. The outside air temperature at night fell to -8.6 ° C, but the inside of the chamber did not drop below 11.2 ° C, and leveled off at a temperature as low as 2 ° C as if it was dragged by the running water temperature. It was proved that the chamber temperature was kept constant by running water. The house around 14:00 exceeded 30 ° C due to sunshine. The chamber temperature is also rising slightly. Since the chamber has a transparent acrylic double plate on the top lid, this is also due to sunlight irradiation.
From the experimental results, it is considered that the groundwater temperature control technology has been proved to be sufficiently practical.

水１ｍ³に蓄えられる熱量は４１７７ＭＪ／（ｍ³・Ｋ）で、空気１ｍ³では１．１２６ＭＪ／（ｍ³・Ｋ）となり、計算すると３，７１０倍（約４千倍）もの差がある。つまり、１リットルの水は３，７１０リットルの空気と同じ量の熱量を持つことになる。言い換えると水１リットルで１℃分の熱量では空気３，７１０リットルを１℃上昇できる。
縦横５ｍ×１０ｍで高さが３ｍの標準的なビニールハウスの体積（空気量）は１５０，０００リットルになるので、ハウス内の温度を１℃上昇させるには約４０リットルの水がいることになる。もし仮に外気温が０℃の時、ハウス内温度を１５℃まで上昇させるとすると、４０×１５＝６００となり、６００リットルの地下水が必要となる。この量を１分間に流すと（仮に熱交換が効率よく行われるとする）、計算上は１分間で０℃から１５℃まで上がることになる。
流す量を１０分の１にすると１０分間となり、１００分の１にすると１００分間でハウス内は１５℃に達することになる。早い遅いはさておき、いずれにせよハウス内温度は最終的には１５℃になる計算である。外気温の気温変動はゆっくり緩慢に変わっていくので、流水量は多くする必要はない。ちなみに一般家庭の水道を例に考える。バケツに水を入れる時のように大きめに蛇口をひねった場合は水量が３０リットル／分位なので、ハウス内を２０分間で０℃から１５℃まで上昇させることになる。この計算で、地下水による温度調節での使用水量が大量なものではなく、極めて現実的で容易に実現できることものであることが解った。 <3. Examination of running water volume>
Next, we examined how much water flow has a temperature control effect.
Table 1 shows the physical property data of water and air and the calculation method of heat capacity.

The amount of heat stored in 1 m ³ of water is 4177 MJ / (m ³ · K), 1 m ^{3 of} air is 1.126 MJ / (m ³ · K), and there is a difference of 3,710 times (about 4,000 times) when calculated. . That is, 1 liter of water has the same amount of heat as 3,710 liters of air. In other words, with 1 liter of water, heat of 1 ° C can increase 3,710 liters of air by 1 ° C.
The volume (air volume) of a standard greenhouse with a height of 5m x 10m and a height of 3m is 150,000 liters, so there is about 40 liters of water to raise the temperature in the house by 1 ° C. Become. If the outside air temperature is 0 ° C. and the temperature inside the house is raised to 15 ° C., 40 × 15 = 600, which requires 600 liters of groundwater. If this amount is allowed to flow for 1 minute (assuming that heat exchange is performed efficiently), the calculation will increase from 0 ° C. to 15 ° C. in 1 minute.
If the flow rate is reduced to 1/10, it becomes 10 minutes, and if it is set to 1/100, the temperature in the house reaches 15 ° C. in 100 minutes. Aside from early and late, in any case, the temperature inside the house is finally calculated to be 15 ° C. Since the fluctuation of the outside temperature changes slowly and slowly, there is no need to increase the amount of water flow. By the way, let's consider a general household water supply as an example. When the faucet is twisted as in the case of putting water into the bucket, the amount of water is about 30 liters / minute, so the inside of the house is raised from 0 ° C. to 15 ° C. in 20 minutes. From this calculation, it was found that the amount of water used for temperature control by groundwater is not a large amount, but is extremely realistic and can be easily realized.

In the present invention, in order to realize a temperature control space for plant growth surrounded by groundwater, the groundwater circulation panel developed for the purpose of heat exchange by groundwater is pasted in combination on the inner surface, ceiling, and floor of a conventional house. The method was adopted.
The groundwater circulation panels were connected with pipes to allow groundwater to flow, and heat exchange was performed on the entire surface of the groundwater circulation panels. The groundwater circulation panel is premised on two types: a groundwater metal surface panel used for a floor or a side wall, and a transparent groundwater circulation panel for a ceiling.
As shown in FIGS. 4 (a) and 4 (b), it was found that the groundwater circulation panel is most effective when installed up and down due to the influence of convection of the internal air.
In the panel arrangement (in the case of heating) in FIG. 4A, when the panel is arranged upright on the side, the warmed air rises as it is from the side as shown by the arrow and accumulates at the top, I don't go. On the other hand, when the panel is arranged on the floor surface, the warmed air rises from the entire floor surface as shown by the arrow, so that the whole is warmed.
In the panel arrangement (in the case of cooling) in FIG. 4B, when the panel is arranged upright on the side surface, the air that has been lowered from the side surface and cooled as shown by the arrow is accumulated in the lower part, I don't go. On the other hand, when the panel is arranged on the ceiling surface, the cooled air descends from the entire ceiling surface as indicated by the arrows, so that the whole is cooled.

In view of the circumstances described above, the present invention can efficiently raise the room temperature in the winter season, and can effectively cool the summer season by effectively using spring water and groundwater. An object of the present invention is to provide an air conditioner for a plant cultivation house.

That is, the air conditioner for a plant cultivation house according to the present invention includes a plant cultivation house in which a groundwater circulation panel is disposed at least on the floor, and a transparent groundwater circulation panel is disposed on the ceiling, the plant cultivation house, Necessary by installing a temperature control system that can mix and supply hot water heated by a boiler and groundwater, and connecting the groundwater circulation panel and transparent groundwater circulation panel to the temperature control system with a circulation pipe. According to this, hot water and / or cold water is circulated.

In the air conditioner for a house for plant cultivation according to the present invention, the temperature control system includes a ground water supply pipe and a hot water hot water pipe, a mixing tap connected to the water supply pipe and the hot water supply pipe, a mixing tap and the ground water circulation panel. Temperature control that collects temperature data from temperature sensors attached to the pipes for the mixed water, the solenoid valves attached to the water supply pipes and the hot water supply pipes, the temperature sensors attached to the pipes and the house for plant cultivation, respectively. With
The temperature control unit instructs a solenoid valve attached to the water supply pipe and the hot water supply pipe to turn on / off the supply of hot water or cold water at a constant temperature, thereby supplying hot water or cold water at a desired temperature to the groundwater circulation panel and transparent groundwater. It is also characterized by being circulated through the circulation panel.

In the air conditioner for a house for plant cultivation of the present invention, the groundwater circulation panel on the floor surface is characterized in that a partition wall is formed in the panel, and a flow path is formed by the partition wall. .

In the air conditioner for a house for plant cultivation according to the present invention, the groundwater circulation panel on the floor surface has a partition wall formed in the panel, and a flow path is formed by a flexible tube disposed on the partition wall. It is a feature.

In the air conditioner for a plant cultivation house according to the present invention, the flexible tube disposed in the groundwater circulation panel on the floor surface is connected by a connector attached to an end thereof, and is formed to have a desired length. It is what.

In the air conditioner for a plant cultivation house according to the present invention, the groundwater circulation panel on the floor surface is provided with a water supply port and a drain port at diagonal positions of the panel so that a flow path is formed in the panel without a partition wall. Is also a feature.

In the air conditioner for a plant cultivation house according to the present invention, the groundwater circulation panel on the floor surface is also characterized in that a water bag provided with a partition is accommodated so that a flow path is formed in a panel without a partition wall. It is what.

In the air conditioner for a plant cultivation house according to the present invention, the groundwater circulation panel on the floor surface is also characterized in that a water pipe is meandered and stored so that a flow path is formed in a panel without a partition wall. Is.

In the air conditioner for a house for plant cultivation according to the present invention, the groundwater circulation panel on the floor surface includes a plurality of hollow square members juxtaposed on the bottom panel, and a water pipe is disposed in the hollow square member to adjoin adjacent water pipes. It is also characterized by connecting the end portions.

In the air conditioning apparatus for a plant cultivation house according to the present invention, the groundwater circulation panel on the floor has juxtaposed water pipes made of a plurality of hollow square members on the bottom panel, and the ends of the water pipes are connected together. Is also a feature.

In the air conditioner for a plant cultivation house according to the present invention, the groundwater circulation panel on the floor surface is characterized in that a plurality of flexible tubes are juxtaposed on the bottom panel, and ends of the flexible tubes are connected together. To do.

In the air conditioner for a house for plant cultivation according to the present invention, the groundwater circulation panel on the floor has a depth that allows the bottom panel to collect water, and a water outlet and a drain outlet are provided at both ends in the length direction. It is also characterized in that it is possible to arrange and pass water.

In the air conditioner for a plant cultivation house according to the present invention, the groundwater circulation panel on the floor is characterized in that a floating lid is mounted on the water accumulated in the bottom panel.

In the air conditioning apparatus for a house for plant cultivation according to the present invention, the groundwater circulation panel on the floor surface is characterized in that a heat exchange part is formed on the outer surface of the panel so that the room temperature can be controlled more effectively. To do.

In the air conditioner for a plant cultivation house according to the present invention, the transparent groundwater circulation panel of the ceiling part is characterized in that a partition wall is formed in the transparent panel, and a flow path is formed by the partition wall. It is.

In the air conditioner for a house for plant cultivation according to the present invention, the transparent groundwater circulation panel of the ceiling part has a bottom frame made of vertical and horizontal crosspieces, and a water bag having a partition for water conveyance formed on the bottom frame. It is also characterized by being housed.

In the air conditioner for a plant cultivation house according to the present invention, the transparent groundwater circulation panel of the ceiling portion has a water supply port and a drain port at diagonal positions of the transparent panel so that a flow path is formed in the transparent panel without a partition wall. It is also characterized by the provision.

In the air conditioner for a house for plant cultivation according to the present invention, the transparent groundwater circulation panel of the ceiling portion has a plurality of water pipes juxtaposed on the ceiling panel that transmits light, and ends of the water pipes are collectively connected. It is also characterized by this.

In the air conditioning apparatus for a house for plant cultivation according to the present invention, the transparent groundwater circulation panel of the ceiling part has juxtaposed water pipes made of a plurality of transparent flexible materials on the ceiling panel that transmits light, and ends of the water pipes It is also characterized by the fact that they are connected together.

In the air conditioner for a plant cultivation house according to the present invention, the groundwater circulation panel and the transparent groundwater circulation panel include a water bag made of a plurality of flexible films on a floor panel, a wall, and a ceiling panel that transmits light. A water inlet is connected to the end of the bag.

As described above, according to the present invention, the temperature of the house for plant cultivation can be efficiently controlled with spring water and groundwater. That is, hot water or cold water at a desired temperature can be circulated to the groundwater circulation panel by instructing a solenoid valve attached to the water supply pipe and hot water supply pipe from the temperature controller to turn on / off the supply of hot water or cold water at a constant temperature. As a result, plants can be cultivated in winter and in cold regions, and temperature can be controlled very efficiently using spring water and groundwater in summer.

(A) and (b) show a cubic small laboratory chamber, (a) shows a state in which the lid is opened, (b) shows a schematic perspective view of the mounted state, and (c) shows a large laboratory chamber. It is a schematic perspective view, respectively. It is a graph which shows an example of the experimental result of the autumn in a small chamber. It is a graph which shows an example of the experimental result of the winter in a large chamber. (A) is the schematic which shows the change of the airflow in each panel arrangement | positioning (in the case of heating), (b) is the schematic which shows the change of the airflow in each panel arrangement | positioning (in the case of cooling). It is a schematic sectional drawing of the house for plant cultivation. It is a sketch inside a plant factory. (A) is a schematic perspective view of the groundwater circulation panel single-piece | unit for floor surfaces, (b) is a schematic perspective view of the see-through state. It is a schematic perspective view of the state which removed the lid of the groundwater circulation panel simple substance for floors. (A) is a perspective view which shows the partition wall of the groundwater circulation panel for floors, (b) is a perspective view of the state which accommodated the flexible tube in the partition wall, (c) is a schematic enlarged view of a flexible tube. (A) is the schematic of the state in which the inside of a flexible tube is empty, (b) is the schematic of the state which let water flow in the flexible tube. (A) is a schematic diagram of a state in which the flexible tube is empty in a state in which the flexible tube is accommodated in the partition wall, (b) is a schematic diagram of a state in which water has passed through the flexible tube, and (c) is a state during heat exchange. FIG. It is a schematic enlarged view of the connection part of a flexible tube. The other example of the groundwater circulation panel for floors is shown, (a) is a schematic perspective view of the state which removed the cover, (b) It is a schematic sectional drawing of a water flow state. The following example of the groundwater circulation panel for floors is shown, (a) is the schematic perspective view, (b) is the schematic plan view of the water bag with the meandering partition which is accommodated in the groundwater circulation panel for floors. . It is a schematic perspective view which shows the following example of the groundwater circulation panel for floors, and has shown the state which carried out the meandering of the water pipe instead of the said tank with a partition, and was accommodated. The following example of the groundwater circulation panel for the floor surface is shown, (a) is a perspective view showing a water pipe of a hollow square material, (b) is arranged a plurality of water pipes, and connects the ends of adjacent water pipes (C) is a schematic perspective view of a state where the plurality of water pipes are juxtaposed in the frame body. The following example of the groundwater circulation panel for floors is shown, (a) is a perspective view showing a water pipe of a cylindrical square member, and (b) is a schematic perspective view showing a state where a plurality of water pipes are to be stored in a frame body. (C) is a schematic perspective view of a storage state, (d) is the schematic for demonstrating the water flow state to the said water flow pipe. The following example of the groundwater circulation panel for floors is shown, (a) is a perspective view showing a water pipe made of a flexible material, and (b) is a schematic perspective view showing a state where a plurality of water pipes are to be stored in a frame body. (C) is a schematic perspective view of a storage state, (d) is a schematic perspective view of a state in which ends of adjacent water pipes are connected together, and (e) is a water flow state to the water pipe. It is the schematic for doing. The following example of the groundwater circulation panel for floors is shown, (a) is a schematic perspective view of a groundwater circulation panel in which the frame itself is a water flow body, and (b) is a schematic cross-sectional view in a water flow state. The modification of the groundwater circulation panel for floors is shown, (a) is a schematic perspective view of a groundwater circulation panel in which the frame itself is a water flow body, and a floating lid is arranged in the frame body, and (b) is a schematic view of the water flow state. It is sectional drawing. (A) is a schematic perspective view at the time of attaching the heat exchange part which consists of a radiation fin to the outer surface of the groundwater circulation panel for floors, (b) is the schematic of the attachment state. It is a schematic perspective view of the state which showed one example of the groundwater circulation panel for ceiling parts using the frame which consists of a transparent board, and opened the lid. The following example of a groundwater circulation panel for a ceiling using a frame made of a transparent plate is shown, (a) is a schematic plan view of a transparent water bag in which a partition for guiding water is formed, and (b) is water. FIG. 2 is a schematic perspective view showing a state where the bag is to be stored in the frame body, and FIG. The following example of the groundwater circulation panel for a ceiling part using the frame body which consists of a transparent board is shown, (a) is a schematic perspective view of the groundwater circulation panel which used the frame body as a water body, (b) is a water flow state FIG. The following example of a ceiling groundwater circulation panel using a frame made of a transparent plate is shown, and cylindrical water pipes are arranged side by side at predetermined intervals in a frame provided with supporting horizontal rails at predetermined intervals. It is a schematic perspective view of a state. (A) is a schematic perspective view of a state in which cylindrical water pipes are juxtaposed at predetermined intervals in a frame body provided with horizontal bars for support at predetermined intervals, and (b) is a case where the ends of the water pipes are bundled with a water guiding unit. The schematic perspective view of the connected state, (c) is a schematic view for explaining the water flow state to the water pipe. The following example of the groundwater circulation panel for a ceiling part is shown, (a) is a perspective view showing a water pipe made of a transparent flexible material, and (b) shows a state where a plurality of water pipes are to be stored in the frame. (C) is a schematic perspective view in a storage state, (d) is a schematic perspective view in a state where end portions of adjacent water pipes are connected together, and (e) is a water flow state to the water pipe. It is the schematic for demonstrating. It is a perspective view which shows the next example of the groundwater circulation panel for ceiling parts, and shows the state which has arrange | positioned the water conveyance bag which consists of a transparent flexible film in the ceiling part. It is a perspective view which shows the state which has arrange | positioned the water conveyance bag which consists of a flexible film on the wall. It is a perspective view which shows the state which provided the water conveyance groove | channel in the floor part with the water conveyance bag which consists of a flexible film, and laid the water conveyance bag in this water conveyance groove | channel. It is a perspective view which shows the state which laid the water conveyance bag which consists of a flexible film directly on the floor part. It is a perspective view which shows the state which laid the water conveyance bag which consists of a flexible film in the coffin cover. It is the schematic of the temperature control system used for the air conditioning apparatus of the house for plant cultivation of this invention. It is the schematic which shows the heat pump system of the conventional geothermal utilization.

Hereinafter, a preferred embodiment of a cooling and heating apparatus for a plant cultivation house according to the present invention will be described in detail with reference to the accompanying drawings.
5 and 6, respectively, a groundwater circulation panel 12 on the floor and a transparent groundwater circulation panel 13 on the ceiling are disposed above and below the plant cultivation house 11 and the plant factory 11 ′, respectively, and a heat insulating wall 14 is disposed on the side wall. It shows the installed structure. The plant cultivation house 11 is provided with a temperature control system which will be described later, and the groundwater circulation panel 12 and the temperature control system are connected by a circulation pipe so that hot water and / or cold water is circulated. It is.

7 (a), 7 (b) and FIG. 8, the groundwater circulation panel 12 on the floor surface is formed with a plurality of partition walls 15 whose ends are alternately opened in the panel 12, and thus a plurality of partitions. A space between the walls 15 is sewn to form a meandering flow path as indicated by an arrow. Reference numeral 16 denotes a lid.
Further, the floor surface groundwater circulation panel 12 shown in FIG. 9 is provided with a partition wall 15 in the panel 12 as shown in FIG. 9A, and between the partition walls 15 as shown in FIG. 9B. The flexible tube 21 is sewed and arranged to meander to form a flow path. Reference numeral 16 denotes a lid. FIG. 9C is a schematic enlarged view of the flexible tube 21.
The partition wall 15 may be integrally formed when the groundwater circulation panel 12 is molded from plastic, or the partition wall 15 may be bonded to the groundwater circulation panel 12 formed from a lightweight metal such as plastic or aluminum. You may arrange by.

FIGS. 10A and 10B are diagrams for explaining the flexible tube 21 disposed so as to meander in the groundwater circulation panel 12. FIG. 10A shows an empty state of the flexible tube 21, and FIG. 10B shows a flexible tube 21. It shows the state of water passing through.
FIG. 11 is a diagram for explaining the behavior of the flexible tube 21 in the partition wall 15, and FIG. 11A shows the state in which the flexible tube 21 is empty in the state of being housed in the partition wall 15. (B) is a schematic sectional drawing which shows the state which let water flow in the flexible tube 21, and (c) is a state at the time of heat exchange.
In this way, by using the flexible tube 21 arranged to meander in the groundwater circulation panel 12, only the flexible tube 21 needs to be replaced even when it deteriorates over time.

FIG. 12 is a schematic enlarged view of the connecting portion 22 of the flexible tube 21. As shown in the figure, the connecting portion 22 has a structure in which a connector 21a is attached to the end portion of the flexible tube 21, and the connectors 21a are connected to each other.
The connecting means for the connector 21a may employ a screw structure or a structure in which a flange is formed on the connector 21a and is fastened with a clip. Of course, the connector 21a needs to have a watertight structure using an O-ring packing or the like.

FIG. 13 shows a second example of the groundwater circulation panel 12, in which there is no partition wall 15 in the panel, and a water supply port 31 and a drain port 32 are simply provided at diagonal positions of the panel 12. . FIG. 13A shows a state where the lid 16 is removed, and FIG. 13B shows a state where water has passed. In this example, the water injected from the water supply port 31 is stored in the panel 12 and flows so as to be pushed out from the drain port 32 by the water injection pressure.
FIG. 14 shows a third example of the groundwater circulation panel 12, in which there is no partition wall 15 in the panel 12, and a water bag 33 provided with a meandering partition 34 is accommodated to form a flow path. It is a thing. 14A is a perspective view showing a state in which the water bag 33 is stored in the panel 12, and FIG. 14B is a plan view showing the water bag 33 itself.
FIG. 15 shows a fourth example of the groundwater circulation panel 12, in which the partition wall 15 is not provided in the panel 12, and a hard or soft water pipe 35 is disposed so as to meander in the panel 12. Thus, a flow path is formed.

FIG. 16 shows a fifth example of the groundwater circulation panel 12, and a hollow rectangular partition tubular body 43 shown in FIG. 16 (a) is prepared, and FIGS. 16 (b) and 16 (c). As shown in the figure, a plurality of partitioning tubular bodies 43 are juxtaposed on a bottom panel 41 with side walls 42 raised on both sides, and water pipes 44 are disposed in the partitioning tubular body 43. In addition, the end portions of the adjacent water pipes 44 are connected by the connecting body 45, and are arranged in parallel in the panel 12 to form a flow path. FIG. 16C shows a water flow state in a state where the plurality of cylindrical bodies 43 are juxtaposed in the bottom panel 41.
FIG. 17 shows a sixth example of the groundwater circulation panel 12. As shown in FIGS. 17 (b) and 17 (c), a hollow square water passage pipe 53 shown in FIG. 17 (a) is prepared. A plurality of water pipes 53 that are slightly shorter than the bottom panel 51 are juxtaposed on the bottom panel 51 having a side wall 52 raised around it. FIG. 17 (d) shows a water flow state in a state where the plurality of water flow tubes 53 are juxtaposed in the bottom panel 51. In the figure, 55 is a water flow opening provided in the bottom panel 51, and 56 is a water discharge port, which flows from the water flow port 55 only in one direction.

FIG. 18 shows a seventh example of the groundwater circulation panel 12, in which a plurality of flexible tubes 57 are juxtaposed on a bottom panel 51 with side walls 52 raised on both sides, and the ends of the flexible tubes 57 are connected to each other. The water guide unit 58 is connected together.
First, a flexible tube 57 shown in FIG. 18 (a) is prepared, and a plurality of flexible tubes 57 are juxtaposed on the bottom panel 51 as shown in FIGS. 18 (b) and 18 (c). As shown, the ends of the flexible tube 57 are connected together by a water guide unit 58. FIG. 18 (e) shows a water flow state in a state where the plurality of flexible tubes 57 are juxtaposed in the bottom panel 51. In the figure, 59 is a water outlet provided in the water guide unit 58, and 60 is a drain.

FIG. 19 shows an eighth example of the groundwater circulation panel 12 in which water accumulates in a bottom panel 61 with a side wall 62 raised around it.
First, as shown in FIG. 18A, a bottom panel 61 is prepared in which a side wall 62 is raised around the periphery and a water passage 63 and a drain 64 are provided at the end in the length direction. Reference numeral 65 denotes a metal mesh upper lid. FIG.18 (b) shows a water flow state.
In this example, the water poured from the water flow port 63 is stored in the bottom panel 61 and flows so as to be pushed out from the drain port 64 by the water pressure.

FIG. 20 shows a modification of the groundwater circulation panel 12 of FIG. 19, and a side wall 62 is raised around the same as in FIG. 18 (a), and a water inlet 63 and a drain outlet are provided at the end in the length direction. A bottom panel 61 provided with 64 is prepared. 65 is an upper lid made of wire mesh, and 66 is an aluminum floating lid made to float on water. FIG.18 (b) shows a water flow state.
In the examples of FIGS. 19 and 20, complicated piping work is not required, and the water itself directly exchanges heat, so the heat exchange efficiency is very good.

FIG. 21 illustrates a case where a heat exchanging portion is formed on the outer surface of the groundwater circulation panel 12. (A) shows a state in which a heat exchanging portion 71 provided with a large number of radiating fins 72 is attached to the outer surface of the lid 16, and (b) shows heat obtained by providing a large number of radiating fins 72 on the outer surface of the lid 16. The state which attached the exchange part 71 is shown.
The heat radiation fins 72 have an effect of greatly increasing the heat radiation area of the heat exchange surface.

The example of the transparent groundwater circulation panel 13 of a ceiling part is shown below.
In FIG. 22, the transparent groundwater circulation panel 13 at the ceiling has a partition wall 15 formed in the transparent panel 13 with a frame attached to the periphery, and a meandering flow path is formed by the partition wall 15. .
Therefore, since the irradiation of sunlight is not disturbed so much, the sunlight can be sufficiently distributed in the greenhouse.

FIG. 23 shows a second example of the transparent groundwater circulation panel 13 in the ceiling part, and a transparent water bag 83 having a water introduction partition 84 shown in FIG. 23 (a) is prepared. As shown in (b) and (c), a water bag 83 in which a partition 84 for water conveyance is formed on a bottom frame 81 provided with vertical and horizontal crosspieces 82 constituting the transparent groundwater circulation panel 13 of the ceiling portion. Is stored.
Therefore, since the irradiation of sunlight is not disturbed so much, the sunlight can be sufficiently distributed in the greenhouse.

FIG. 24 shows a third example of the transparent groundwater circulation panel 13 in the ceiling part, and the groundwater circulation panel 13 in the ceiling part shown in FIG. 24 (a) is a partition wall sealed with a lid 16. A water supply port 91 and a drain port 92 are provided at diagonal positions of the transparent panel 13 so that a flow path is formed in the transparent panel 13 that is not present. FIG. 24B shows a water flow state.

25 and 26 show a fourth example of the transparent groundwater circulation panel 13 in the ceiling portion. As shown in FIG. 26A, the cylindrical water pipe 103 shown in FIG. 25 is prepared. It is set at a predetermined interval on the bottom panel 101 with the side walls 102 raised on both sides. Reference numeral 100 denotes a lid made of a transparent material.
Then, as shown in FIG. 26 (b), the ends of the cylindrical water pipe 103 are connected together by a water guide unit 104. FIG. 26 (c) shows a water flow state in a state where the plurality of cylindrical water flow tubes 103 are juxtaposed in the bottom panel 101. In the figure, 105 is a water passage and 106 is a drain.

FIG. 27 shows a fifth example of the transparent groundwater circulation panel 13 in the ceiling, and the groundwater circulation panel 13 in the ceiling prepares the transparent flexible tube 107 in FIG. 27 (b) and 27 (c), a plurality of transparent flexible tubes 107 are juxtaposed on a transparent bottom panel 101 with side walls 102 raised on both sides, and the flexible tubes are arranged as shown in FIG. 27 (d). The ends of 107 are connected together by a water guide unit 108. FIG. 27 (e) shows a water flow state in a state where the plurality of transparent flexible tubes 107 are juxtaposed in the bottom panel 101.

FIG. 28 shows a sixth example of the transparent groundwater circulation panel 13 in the ceiling portion, and the groundwater circulation panel 13 in the ceiling portion is provided with a plurality of water conveyance bags 112 made of a transparent tubular flexible film. The water passage 113 is attached to one end of the water bag 113 and juxtaposed on the ceiling frame 111, and the end of the water bag 112 is hung on the side wall of the house or plant factory. The drained water can be processed at once by a water guide unit or the like, or can be allowed to flow directly into the drainage channel.
The rising portion of the ceiling frame 111 may be about 3 cm. Of course, the bottom surface of the ceiling frame 111 needs to use a material that transmits light, and a crosspiece, a transparent plate, a wire mesh, or the like with a predetermined interval can be suitably used.
As described above, when the plurality of water conveyance bags 112 are simply arranged, it is not necessary to prepare each of the panels, and it is very low cost, and even if a problem occurs, it is only necessary to replace the water conveyance bags 112. There is a remarkable merit that the maintenance is very easy.

FIG. 29 shows an example in which shelves 115 on which water conveyance bags 112 made of a tubular flexible film are mounted are circulated in multiple stages on a wall 114 of a plant cultivation house. Heat exchange with room air in the house can be enhanced.
Further, a wire mesh or iron lattice is arranged at the bottom of the shelf 115 and the water bag 112 is mounted thereon, and the bottom of the water bag 112 is exposed to increase the area in contact with the room air so as to increase the heat exchange rate. It may be.

FIG. 30 shows an example in which a water conveyance bag 112 made of a cylindrical flexible film is laid in a water conveyance groove 116 provided on the floor, and a lid 117 made of a metal mesh or an iron lattice is covered on the upper surface of the water conveyance groove 116. is there.
When the water bag 112 is laid in the water guide groove 116 provided on the floor in this way, cleaning is easier than in the case of flowing water directly into the water guide groove 116, which contributes to moss prevention and insect damage. This is a very good heat exchange method in terms of hygiene.

FIG. 31 shows an example in which a water bag 112 made of a cylindrical flexible film is directly laid on the floor.
In this way, if the water conveyance bag 112 is laid directly on the floor portion while avoiding the plants being cultivated, the cost can be greatly reduced as compared with the case where the water conveyance groove 116 is provided, which is very excellent in terms of maintenance and hygiene. This is a heat exchange system.
FIG. 32 shows an example in which a water bag 112 made of a flexible film is laid in a simple straw cover 118 for growing crops.
Thus, if the water conveyance bag 112 is laid in the simple paddle cover 118 while avoiding plants being cultivated, the cost can be greatly reduced, and the heat exchange system is very excellent in terms of maintenance and hygiene.
Of course, this simple cocoon cover is also included in the definition of a plant cultivation house.

According to the embodiment described above, the temperature of the plant cultivation house 11 can be efficiently controlled with spring water and groundwater, and hot water and groundwater heated by a boiler, a solar water heater, waste heat, etc. can be used. Since the temperature can be adjusted by mixing, plants can be cultivated in the winter and cold regions, and the temperature can be controlled very efficiently using spring water and groundwater in the summer. It was.

Next, in the air conditioner for a plant cultivation house according to each of the above embodiments, as shown in FIG. 33, the temperature control system 121 includes a groundwater water supply pipe 122 and a hot water hot water supply pipe 123, and the water supply pipe 122 and A mixing plug 124 is connected to a hot water supply pipe 123, and a mixed water pipe 125 is disposed between the mixing plug 124 and the groundwater circulation panel 12.
Electromagnetic valves 122a and 123a are attached to the water supply pipe 122 and the hot water supply pipe 123, temperature sensors 126a, 126b and 126c are attached to the pipes, and a temperature sensor 126d is attached to the plant cultivation house 11. is there. A temperature control unit 127 collects temperature data from the temperature sensors 126a, 126b, 126c, and 126d.
The air conditioner of the plant cultivation house of each of the above embodiments is basically adjusted by continuously flowing water at a target temperature through the groundwater circulation panel 12.
Of course, when there is a large temperature difference between the water temperature of the groundwater and the room temperature in the plant cultivation house, the temperature control unit 127 instructs the electromagnetic valves 122a and 123a attached to the water supply pipe 122 and the hot water supply pipe 123. By turning on / off the supply of hot water or cold water at a constant temperature, hot water and cold water at a desired temperature are circulated through the groundwater circulation panel 12 or mixed with hot water heated to circulate through the groundwater circulation panel 12. By doing so, the inside of the house 11 for plant cultivation can be appropriately controlled to a temperature.

Therefore, according to the air conditioner for a house for plant cultivation of the present invention, even if the outside air temperature is 35 ° C. or higher in summer, it can be cooled to about 15-25 ° C. using the spring water / ground water, and in winter Even if the outside air temperature is below freezing point, it can be heated to a certain temperature using the spring water and groundwater.

As described above, according to the present invention, groundwater is used and mixed with warmed hot water to be used for heating the house 11 for plant cultivation. Thus, heavy oil and light oil are used even in winter and cold regions. Etc. can be kept at a temperature of about 20 ° C. to about 25 ° C. without using a large amount as a fuel for heating, and various plants such as fruits, vegetables and flowers can be cultivated well.
Of course, by circulating spring water and groundwater to the groundwater circulation panel 12 installed in the plant cultivation house 11 in the summer, the room temperature can be cooled from about 15 ° C to about 25 ° C. Various plants such as vegetables and flowers can be grown well.

As described above, an example in which the present invention is applied to a plant cultivation house has been described. However, the present invention is not limited to a plant cultivation house. Needless to say, the present invention can also be applied to houses, factories, warehouses, and other structures. Absent.
The beginning of the form The beginning of the form

DESCRIPTION OF SYMBOLS 11 Plant cultivation house 11 'Plant factory 12 Ground water circulation panel 13 of a floor surface Transparent ground water circulation panel 14 of a ceiling part Thermal insulation wall 15 Partition wall 16 Lid 21 Flexible tube 21a Connector 22 Connection part 31 Water supply port 32 Drainage port 33 Water bag 34 Middle partition 35 Hard or soft water pipe 41 Bottom panel 42 Side wall 43 Partition tubular body 44 Water pipe 45 Connection body 51 Bottom panel 52 Side wall 53 Water pipe 55 Water inlet 56 Water outlet 57 Flexible tube 58 Water guide unit 59 Water outlet 60 Drain outlet 61 Bottom panel 62 Side wall 63 Water outlet 64 Drain outlet 65 Wire mesh 66 Floating lid 71 Heat exchange part 72 Radiation fin 81 Bottom frame 82 Vertical and horizontal crosspiece 83 Water bag 84 Partition 91 Water supply port 92 Drain outlet 100 Transparent lid 101 Bottom panel 102 Side wall 103 Cylindrical water pipe 104 Water guide unit 105 Water inlet 1 6 Drainage port 107 Transparent flexible tube 108 Water conveyance unit 111 Ceiling frame 112 Water conveyance bag 113 made of flexible film Water flow port 114 Wall 115 Shelf 116 Water conveyance groove 117 Lid 118 Simple dredge cover 121 Temperature control system 122 Groundwater water supply pipe 122a Solenoid valve 123 Hot water hot water supply pipe 123a Solenoid valve 124 Mixing plug 125 Mixed water piping 126a, 126b, 126c, 126d Temperature sensor 127 Temperature controller

Claims (19)

A plant cultivation house having at least a groundwater circulation panel on the floor and a transparent groundwater circulation panel on the ceiling is provided, and mixed with hot water heated by a boiler and groundwater is supplied to the plant cultivation house. A temperature control system that can perform the operation is installed, and the groundwater circulation panel and the transparent groundwater circulation panel and the temperature control system are connected by a circulation pipe to circulate hot water and / or cold water as necessary. An air conditioner for a plant cultivation house,
The temperature control system includes: a groundwater supply pipe and a hot water supply pipe; a mixing tap connected to the water supply pipe and the hot water supply pipe; a mixing water pipe disposed between the mixing stopper and the groundwater circulation panel; and the water supply pipe And a solenoid valve attached to each of the hot water supply pipes, a temperature sensor attached to each pipe line and the house for plant cultivation, and a temperature control unit for collecting temperature data from the temperature sensor, the water supply from the temperature control unit The hot water or cold water at a desired temperature is circulated through the groundwater circulation panel and the transparent groundwater circulation panel by controlling on / off the supply of hot water or cold water at a constant temperature by instructing a solenoid valve attached to the pipe and the hot water supply pipe. plant cultivation for house heating and cooling apparatus according to claim that it has. 2. The air conditioner for a plant cultivation house according to claim 1 , wherein the groundwater circulation panel on the floor has a partition wall formed in the panel, and a flow path is formed by the partition wall. The plant cultivation house according to claim 2 , wherein the groundwater circulation panel on the floor has a partition wall formed in the panel, and a flow path is formed by a flexible tube disposed on the partition wall. Air conditioning unit. Flexible tube disposed in groundwater circulation panel of the floor surface, the ends are connected by a connector attached to, the house for plant cultivation according to claim 3, characterized in that formed in the desired length Air conditioning unit. The plant cultivation according to claim 1 , wherein the groundwater circulation panel on the floor surface is provided with a water supply port and a drain port at diagonal positions of the panel so that a flow path is formed in the panel without a partition wall. House air conditioner. 6. The plant cultivation house according to claim 5 , wherein the groundwater circulation panel on the floor surface stores a water bag provided with an intermediate partition so that a flow path is formed in a panel without a partition wall. Air conditioning unit. 6. The air conditioner for a plant cultivation house according to claim 5 , wherein the groundwater circulation panel on the floor surface is housed with a water pipe meandering so that a flow path is formed in a panel without a partition wall. . The floor surface groundwater circulation panel is characterized in that a plurality of hollow square members are juxtaposed on a bottom panel, and a water pipe is disposed in the hollow square member to connect ends of adjacent water pipes. The air conditioning apparatus of the house for plant cultivation of 1 . 2. The plant cultivation according to claim 1 , wherein the groundwater circulation panel on the floor surface includes water pipes made of a plurality of hollow square members juxtaposed on a bottom panel, and ends of the water pipes are collectively connected. House air conditioner. Groundwater circulation panel of the floor surface, juxtaposing a plurality of flexible tubes on the bottom panel, air conditioning for plant cultivation house according to claim 1, characterized in that linked collectively the ends of the flexible tube apparatus. The groundwater circulation panel on the floor has a depth that allows the bottom panel to collect water, and a water inlet and a drain outlet are arranged at both ends in the length direction so that water can pass therethrough. The air conditioner for a house for plant cultivation according to claim 1 , wherein 13. The air conditioner for a house for plant cultivation according to claim 12, wherein the groundwater circulation panel on the floor has a floating lid mounted on the water stored in the bottom panel. The plant according to any one of claims 1 to 12 , wherein the groundwater circulation panel on the floor surface has a heat exchange part formed on the outer surface of the panel so that the room temperature can be controlled more effectively. Air conditioner for cultivation house. 2. The air conditioner for a house for plant cultivation according to claim 1 , wherein the transparent groundwater circulation panel of the ceiling part has a partition wall formed in the transparent panel, and a flow path is formed by the partition wall. Transparent groundwater circulation panels of the ceiling, the bottom frame is constituted by crosspieces aspect, according to claim 1, characterized in that accommodating the water bag to form a partition for water conveyance on said bottom frame Air conditioner for plant cultivation house. Transparent groundwater circulation panels of the ceiling portion, so that the flow path within the transparent panel without partition walls are formed, according to claim 1, characterized in that a water inlet and a water outlet diagonally position of the transparent panel Air conditioner for plant cultivation house. 2. The plant according to claim 1 , wherein the transparent groundwater circulation panel of the ceiling part has a plurality of water pipes juxtaposed on a ceiling panel that transmits light, and ends of the water pipes are collectively connected. Air conditioner for cultivation house. The transparent groundwater circulation panel of the ceiling part is characterized in that a water pipe made of a plurality of transparent flexible materials is juxtaposed on a ceiling panel that transmits light, and ends of the water pipe are collectively connected. Item 12. A cooling and heating apparatus for a plant cultivation house according to Item 1 . The groundwater circulation panel and the transparent groundwater circulation panel have a water bag made of a plurality of flexible films mounted on a floor panel, a wall, and a ceiling panel that transmits light, and a water passage is connected to an end of the water bag. The air conditioner for a house for plant cultivation according to claim 1 , wherein

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