KR20050107898A - Heat exchanging apparatus for greenhouse - Google Patents

Abstract

The present invention relates to a greenhouse heat exchange device that can promote the growth of cultivated plants by adjusting the temperature inside the greenhouse to be suitable for the growing conditions of horticultural plants in summer or winter, the characteristic configuration of the inside of both side walls of the greenhouse Circulating water installed on both sides of the greenhouse to store cooling plates circulating in the heat exchange chamber 10 in a longitudinal direction at inner centers of both sidewalls so that heat exchange chambers 10 are formed in the heat exchanger chambers; A storage tank 20, a pump 30 for pumping the circulation water stored in the circulation water storage tank 20 into the heat exchange chamber 10, and the circulation water pumped by the pump 30 is heated. A heat exchange chamber (40) installed in the lower portion of the heat exchange chamber (10) so as to be injected into the exchange chamber (10) in the longitudinal direction, and external air heat exchanged with the circulating water injected through the injection tube (40) ( 10) inhaling into the interior of A suction fan 50 provided on an outer sidewall of the lock heat exchange chamber 10 and a heat exchange chamber 10 to supply air, which is sucked by the suction fan 50 and heat exchanged with circulating water, into the greenhouse. It includes the air supply means and the recovery passage 90 formed in the longitudinal direction on the bottom surface of the heat exchange chamber 10 so that the circulating water heat exchanged in the heat exchange chamber 10 to the outside.

Description

Heat exchanging apparatus for greenhouse

The present invention relates to a greenhouse heat exchange apparatus, and more particularly, to a greenhouse heat exchange apparatus that can promote the growth of cultivated plants by adjusting the temperature inside the greenhouse to be suitable for growing conditions of horticultural plants in summer or winter. It is about.

In general, the greenhouse is divided into a tunnel type single-acting type with one roof and interlocking type by connecting several roofs together.

Single-acting greenhouse, as shown in Figure 1, providing a plurality of double arc-shaped frame 101 and interconnected the ends of them to create a single unit domed frame. After arranging a plurality of the domed frames at regular intervals along the longitudinal direction to form a greenhouse skeleton 100 having a tunnel shape, it is completed by covering the outer surface with vinyl.

The temperature inside the greenhouse is an important environmental factor for the growth of cultivated horticultural plants, and the temperature inside the greenhouse should be kept constant even during seasonal changes.

In other words, in a season when the temperature increases, such as summer, the temperature inside the greenhouse is rapidly increased, so that the plant cannot grow and die out (hereinafter referred to as "drying phenomenon"), which is too high than the air temperature.

In the season when the temperature is lowered, such as winter, the temperature inside the greenhouse is rapidly lowered, causing the plant to freeze (hereinafter referred to as "low temperature phenomenon").

Accordingly, in order to prevent the drying of the plant due to high temperature, the sprayed water flows along the outer surface of the greenhouse while spraying water on the outer surface of the greenhouse by providing a sprinkler on the outer upper surface of the greenhouse. The method of lowering the temperature is adopted.

However, the method of lowering the temperature of the greenhouse using the sprinkler may have some effect on the inner proximity of the greenhouse where water flowing down the outer surface of the greenhouse forms the boundary of the greenhouse, but the area in which the plant that needs to lower the temperature actually grows. There was a problem that the temperature is not evenly lowered up to the inner central part of the phosphorus greenhouse.

Therefore, there is a problem that the income is lowered due to the reduction in yield as well as causing a huge obstacle to the growth of the horticultural plants grown in the greenhouse.

In addition to the problems described above, the conventional method for lowering the temperature inside the greenhouse using a sprinkler is because the water sprayed from the sprinkler continuously flows down the outer surface of the greenhouse, causing a significant temperature difference inside and outside the greenhouse. Dew condensation occurred, resulting in a decrease in the amount of sunlight transmitted and consequently a huge obstacle to the growth of horticultural plants.

In addition, the conventional method of lowering the temperature inside the greenhouse, since the water sprayed from the sprinkler flows down the vinyl on the outer surface of the greenhouse and then permeates the ground, the ground of the area always has excessive moisture and is located at the edge of the greenhouse. There was a problem that the horticultural plants do not grow normally due to adverse effects on the plants.

In addition, conventionally by providing a separate heating means in the greenhouse to prevent the low temperature of the plant to supply a high temperature hot air to the inside of the greenhouse to supply the hot air circulating the inside of the greenhouse to increase the temperature inside the greenhouse The method is adopted.

However, the method of increasing the temperature of the greenhouse using the heating means may increase the temperature evenly to the inner central part of the greenhouse, which is a region in which plants which need to increase the temperature may be effective in the vicinity of the heating means. There was a problem that can not be.

In order to solve this problem, when increasing the temperature of the hot air generated in the heating means so that the temperature of the central portion can be raised, there was a problem that a dry shape occurs in the plant close to the heating means.

Therefore, there is a problem that the income is lowered due to the reduction in yield as well as causing a huge obstacle to the growth of the horticultural plants grown in the greenhouse.

The present invention has been made to solve the above problems, the object of the present invention is to provide a greenhouse heat exchange apparatus that can adjust the temperature inside the greenhouse to suit the growth conditions of the horticultural plants regardless of summer or winter.

Referring to the characteristic configuration of the present invention for achieving the above object is as follows.

The greenhouse heat exchange apparatus of the present invention has both sides of the greenhouse to store a barrier plate installed in a longitudinal direction at the inner center of both side walls so that heat exchange chambers are formed inside both side walls of the greenhouse, and coolant circulating inside the heat exchange chamber. A circulating water storage tank installed outside, a pump for pumping the circulated water stored in the circulating water storage tank into the heat exchange chamber, and a lower portion of the heat exchange chamber such that the circulated water pumped by the pump is injected into the heat exchange chamber. A suction pipe installed on the outer sidewall of the heat exchange chamber so as to suck the external air heat exchanged with the circulating water injected through the injection pipe into the heat exchange chamber, Air supply means formed in the heat exchange chamber to supply air exchanged with the circulating water to the inside of the greenhouse, and in the heat exchange chamber The number of exchange cycle will include the hayeoseo recovered as formed longitudinally on the lower surface of the heat exchange chamber to be discharged to the outside.

Referring to the present invention having such characteristics in detail as follows.

2 is a perspective view showing a state in which a heat exchange device according to the present invention is installed in a greenhouse, FIG. 3 is a cross-sectional view showing a heat exchange device according to the present invention, and FIG. 4 illustrates an operating state of the heat exchange device according to the present invention. It is sectional drawing for doing.

As referred to herein, the heat exchange chamber 10 is formed at both inner sidewalls of the sidewalls in a longitudinal direction such that heat exchange chambers 10 are formed at both sidewalls of the greenhouse. 10 is provided with a circulation water storage tank 20 for storing the cooling water circulating in the interior, and one side of the circulation water storage tank 20 is pumped to supply the stored circulation water into the heat exchange chamber 10. The pump 30 is provided.

On the other hand, the lower portion of the heat exchange chamber 10, the injection pipe 40 is installed in the longitudinal direction so that the circulated water pumped by the pump 30 into the heat exchange chamber 10, the injection pipe 40 A plurality of spray nozzles 41 are provided at equal intervals on the upper surface of the spray nozzle 41, and the spray nozzles 41 preferably use spray nozzles capable of spraying circulating water in a mist state.

In addition, a suction fan 50 is installed on the outer sidewall of the heat exchange chamber 10 to suck outside air, which may be heat exchanged with the circulating water injected through the injection pipe 40, into the heat exchange chamber 10. One side of the heat exchange chamber 10 is provided with air supply means for supplying air, which is sucked by the suction fan 50 and heat exchanged with circulating water, into the greenhouse, and the heat exchange chamber 10 The bottom surface of the recovery passage 90 for discharging the circulating water heat exchanged in the heat exchange chamber 10 to the outside is formed in the longitudinal direction.

On the other hand, the air supply means for supplying the heat-exchanged air to the side of the greenhouse as shown in Figure 3 spaced apart a predetermined distance from the side wall to the upper portion so that the moving hole 61 is formed in the lower end of the inner wall surface of the heat exchange chamber 10 The support rod 62 is installed to support the lower end of the inner vinyl 60 of the greenhouse, and the blocking vinyl 70 is installed in the longitudinal direction so that the moving hole 61 is wrapped on the inner wall surface of the inner vinyl 60. It is.

In addition, a plurality of air supply holes 71 are formed above the blocking vinyl 70 such that the air supplied between the blocking vinyl 70 and the inner vinyl 60 is supplied into the greenhouse. Above the space where the 70 and the inner vinyl 60 come into contact with each other, a gap holder 72 is provided to separate the blocking vinyl 70 and the inner vinyl 60 from each other.

Referring to the operating state of the present invention configured as described in detail as follows.

First, to control the temperature of the circulating water stored in the circulating water storage tank 20 to adjust the internal temperature of the greenhouse, in this case, it is possible to adjust the temperature of the circulating water using a separate temperature control means, summer In the winter, it is preferable to use groundwater having a temperature lower than the temperature of the air and having a temperature higher than the temperature of the air.

In this case, when the pump 30 is operated, the circulating water stored in the circulating water storage tank 20 is pumped as shown in FIG. 4, and the circulated water pumped is supplied to the injection pipe 40, and the injection pipe 40 Circulated water supplied to the circulating water is injected into the heat exchange chamber 10 through a plurality of injection nozzles 41 provided on the surface of the injection pipe 40, and thus the circulating water in the mist state is in the heat exchange chamber 10. It will be filled.

When the suction fan 50 is operated in this state, the outside air is sucked by the suction fan 50, and the sucked outside air is exchanged with the circulating water in the mist state filled in the heat exchange chamber 10. , The heat-exchanged air is moved through the moving hole 61 formed in the lower end of the inner wall surface of the heat exchange chamber (10).

On the other hand, the air moved through the moving hole 61 is moved between the inner vinyl 60 and the blocking vinyl 70, when the air is moved between the inner vinyl 60 and the blocking vinyl 70 Moisture contained in is separated by the inner vinyl (60) and the blocking vinyl (70), the air is separated from the water is a greenhouse through a plurality of air supply holes 71 formed on the upper side of the blocking vinyl (70) It will be supplied to the inside of.

In addition, the water separated by the inner vinyl (60) and the blocking vinyl (70) and the circulating water injected into the heat exchange chamber (10) is moved downward by its own weight is collected in the recovery path (90), The circulating water collected in the recovery path 90 is continuously pumped by the pump 30 after being moved to the circulating water storage tank 20.

On the other hand, the heat exchange chamber 10 may be installed outside both sides of the greenhouse as shown in FIG.

In the state in which the heat exchange chamber 10 is installed on the side of the greenhouse, as shown in FIG. 6, the through-hole 64 is formed in the inner vinyl 60, and the through-hole 64 of the inner vinyl 60 is wrapped. The induction pipe 65 may be attached to the inner side, and the induction pipe 65 is preferably made of a vinyl material.

Therefore, when the heat exchanged air in the heat exchange chamber 10 is discharged through the through hole 64, the air is guided by the induction pipe 65 is discharged to the center of the greenhouse, so that the temperature is constant while circulating the air inside the greenhouse Will be maintained.

On the other hand, when the air is not discharged through the through hole 64, the guide pipe 65 is moved to the lower, so that the through hole 64 is blocked.

In addition, the air supply means for supplying the heat-exchanged air to the upper portion of the plurality of air discharge holes (11a) at equal intervals in the blocking plate 11 forming the upper surface of the heat exchange chamber 10 as shown in FIG. ) Is formed, and a plurality of air supply holes 63 are formed at the upper end of the inner vinyl 60 of the greenhouse so that the air discharged through the air discharge holes 11a is supplied to the upper portion of the greenhouse.

At this time, in order to separate the water contained in the air discharged through the air discharge hole (11a) to install the water separation vinyl 80 on the upper surface of the inner vinyl 60 so that the air supply hole 63 is covered, The lower end of the water separation vinyl 80 is to be installed in an open state so that air can be introduced.

Referring to the operating state of the present invention configured as described in detail as follows.

When the pump 30 is operated, the circulating water stored in the circulating water storage tank 20 is pumped as shown in FIG. 6, wherein the circulated water pumped is supplied to the injection pipe 40, and the injection pipe 40 is Since the circulating water supplied to the water is injected into the heat exchange chamber 10 through the plurality of injection nozzles 41 installed on the surface of the injection pipe 40, the circulation water in the mist state is filled in the heat exchange chamber 10. You lose.

When the suction fan 50 is operated in this state, the outside air is sucked by the suction fan 50, and the sucked outside air is exchanged with the circulating water in the mist state filled in the heat exchange chamber 10. , The heat-exchanged air is discharged through the air discharge hole (11a) formed in the blocking plate (11).

On the other hand, the air discharged through the air discharge hole (11a) is moved between the water separation vinyl 80 and the inner vinyl 60, the air is moved between the water separation vinyl 80 and the inner vinyl (60). When the moisture contained in the air is separated by the water separation vinyl 80 and the inner vinyl 60, the air is separated water is a plurality of air supply holes 63 formed on the upper side of the inner vinyl (60) Will be supplied into the greenhouse.

In addition, the water separated by the water separating vinyl 80 and the inner vinyl 60 and the circulating water injected into the heat exchange chamber 10 is moved to the lower by its own weight is collected in the recovery path (90). In addition, the circulated water collected in the recovery path 90 is continuously pumped by the pump 30 after being moved to the circulating water storage tank 20.

As described above, the heat-exchanged air may be configured to be supplied through either one or both sides of the greenhouse or simultaneously supplied to both sides and the upper surface.

As described above, the present invention has an effect of easily controlling the temperature in the greenhouse where the horticultural plants are grown at any time as needed.

In particular, the present invention can adjust the temperature in the greenhouse during the summer or winter to suit the growing conditions of the horticultural plants to cultivate the plant can produce a high quality fruit and at the same time have the effect of increasing the yield.

1 is a perspective view showing a typical greenhouse

Figure 2 is a perspective view showing a state in which the heat exchange apparatus according to the invention installed in the greenhouse.

3 is a cross-sectional view of a heat exchange device according to the present invention.

4 is a cross-sectional view for explaining an operating state of the heat exchange device according to the present invention.

5 is a cross-sectional view showing another embodiment of a heat exchange device according to the present invention.

6 is a cross-sectional view showing yet another embodiment of a heat exchange device according to the present invention.

7 is a cross-sectional view showing another embodiment of a heat exchange device according to the present invention.

8 is a cross-sectional view for explaining an operating state of the heat exchange device according to the present invention shown in FIG.

※ Explanation of symbols about main part of drawing ※

10 heat exchange room 11: blocking plate

11a: air outlet hole 20: circulating water storage tank

30: pump 40: injection pipe

41: injection nozzle 50: suction fan

60: inner vinyl 61: moving ball

62: support rod 63, 71: air supply hole

64: through-hole 65: induction pipe

70: blocking vinyl 80: water separation vinyl

90: recovery furnace

Claims (9)

Circulating water storage tanks installed on both sides of the greenhouse and installed on both sides of the greenhouse to store cooling water circulating inside the heat exchange chamber 10 and a heat exchange chamber 10 having a blocking plate 11 on the upper surface thereof. (20), a pump 30 for pumping the circulated water stored in the circulating water storage tank 20 to the inside of the heat exchange chamber 10, and the circulated water pumped by the pump 30 10) the injection pipe 40 installed in the longitudinal direction in the lower portion of the heat exchange chamber 10 so as to be injected into the interior of the heat exchange chamber 10, and the external air heat exchanged with the circulating water injected through the injection pipe 40 A suction fan 50 installed on an outer sidewall of the heat exchange chamber 10 to suck into the inside of the heat exchange chamber, and a heat exchange chamber to supply air, which is sucked by the suction fan 50 and heat exchanged with circulating water, into the greenhouse. Air supply means formed in the 10, and the heat exchange in the heat exchange chamber (10) The Greenhouse heat exchanger, characterized in that it comprises a number of times (90) formed longitudinally on the lower surface of the heat exchange chamber 10 is discharged to the outside. The greenhouse heat exchange apparatus according to claim 1, wherein the heat exchange chamber (10) is installed inside both sidewalls of the greenhouse. 2. The greenhouse heat exchange apparatus according to claim 1, wherein the heat exchange chamber (10) is installed on outer surfaces of both sidewalls of the greenhouse. The greenhouse heat exchange apparatus according to claim 1, wherein a plurality of spray nozzles (41) are provided at equal intervals on the upper surface of the spray tube (40). According to claim 1, wherein the air supply means is a support rod installed on the bottom surface of the inner vinyl 60 of the greenhouse spaced apart a predetermined distance from the side wall so that the moving hole 61 is formed in the lower end of the inner wall surface of the heat exchange chamber (10) 62 and a blocking vinyl 70 installed in the longitudinal direction on the inner wall surface of the inner vinyl 60 so that the moving hole 61 is wrapped, and supplied between the blocking vinyl 70 and the inner vinyl 60. Greenhouse heat exchange apparatus characterized in that it comprises a plurality of air supply holes (71) formed on the upper side of the blocking vinyl (70) so that air is supplied to the interior of the greenhouse. The space holder 72 is installed on the upper side of the space where the blocking vinyl 70 and the inner vinyl 60 are in contact with each other so that the blocking vinyl 70 and the inner vinyl 60 are separated from each other. Greenhouse heat exchanger. The air supply means according to claim 1, wherein the air supply means includes a through hole 64 formed in the inner vinyl 60 so as to penetrate the heat exchange chamber 10, and the air discharged through the through hole 64 to the inside of the greenhouse. Greenhouse heat exchange device characterized in that it comprises an induction tube (65) attached to the inner vinyl (60) so that the through (64) is wrapped. According to claim 1, wherein the air supply means is a plurality of air discharge holes (11a) formed at equal intervals in the blocking plate 11 forming the upper surface of the heat exchange chamber 10, and through the air discharge hole (11a) Greenhouse heat exchange device characterized in that it comprises a plurality of air supply holes (63) formed in the upper end of the inner vinyl (60) of the greenhouse so that the discharged air is supplied to the upper portion of the greenhouse. The water separation vinyl (80) of claim 8, wherein the water separation vinyl (80) is installed on the upper surface of the inner vinyl (60) to cover the air supply hole (63) to separate the water contained in the air discharged through the air discharge hole (11a). Is provided, the lower end of the water separation vinyl 80 is a greenhouse heat exchange device, characterized in that the air is installed in such a state that is opened to enter.