CN204907360U - Warmhouse booth heat transfer system - Google Patents

Abstract

The utility model discloses a warmhouse booth heat transfer system, including installing the solar collector outside warmhouse booth, install the water storage heat transfer jar in warmhouse booth, install the heat exchanger fin on the warmhouse booth inner wall, the ground that buries under the earth's surface in warmhouse booth buries the coil pipe, solar collector passes through the heat collector control valve, the heat collector circulating pump forms circulation circuit with water storage heat transfer jar intercommunication, the heat exchanger fin passes through the heat exchanger fin control valve, the heat exchanger fin circulating pump forms circulation circuit with water storage heat transfer jar intercommunication, bury the coil pipe through ground bury the coil pipe control valve, bury coil pipe circulating pump and water storage heat transfer jar intercommunication and form circulation circuit, the solar power ultraviolet ray mosquito killer further comprises a controller. Heat collector control valve, heat collector circulating pump, heat exchanger fin control valve, heat exchanger fin circulating pump, bury the coil pipe control valve, bury the coil pipe circulating pump and be connected with the controller respectively. The utility model discloses but utilize concurrent heating ambient temperature and soil temperature, energy -conserving high -efficient environmental protection provides suitable growing environment for the plant among the warmhouse booth.

Description

A kind of green house heat-exchange system

Technical field

The utility model relates to heat-exchange system, particularly relates to a kind of for the heat-exchange system in green house.

Background technology

Northern China winter temperature is lower, needs heater means in green house, improve the environmental temperature in green house, and soil temperature is on the low side equally, affects the growth of plant.At present, most of green house heating measures or only for ambient temperature, or only for soil temperature heating, environmental temperature and soil temperature can not be taken into account simultaneously.

Summary of the invention

For solving the problem, the utility model provides a kind of green house heat-exchange system not only having improved environmental temperature but also improved soil temperature.

The technical solution of the utility model is: a kind of green house heat-exchange system, comprise: be arranged on the solar thermal collector outside green house, be arranged on the water storage heat exchange tank in green house, be arranged on the heat exchanger fin on green house inwall, be embedded in the buried coil pipe under the earth's surface in green house;

Described solar thermal collector is communicated with water storage heat exchange tank by heat collector control valve, heat collector circulating pump and forms closed circuit; Described heat exchanger fin is communicated with water storage heat exchange tank by heat exchanger fin control valve, heat exchanger fin circulating pump and forms closed circuit; Described buried coil pipe is communicated with water storage heat exchange tank by buried coil pipe control valve, buried coil pipe circulating pump and forms closed circuit;

Also comprise: controller; Described heat collector control valve, heat collector circulating pump, heat exchanger fin control valve, heat exchanger fin circulating pump, buried coil pipe control valve, buried coil pipe circulating pump are connected with controller respectively.

Further, also comprise: well; Described well is communicated with water storage heat exchange tank by well control valve, well circulating pump; Described well control valve, well circulating pump are connected with controller respectively.

Further, also comprise: irrigation pipeline; Described irrigation pipeline is communicated with water storage heat exchange tank by the first irrigation control valve; Described first irrigation control valve is connected with controller.

Further, also comprise: the second irrigation control valve; Described irrigation pipeline is communicated with well by the second irrigation control valve, and described second irrigation control valve is connected with controller.

Further, be provided with water storage temperature sensor in described water storage heat exchange tank, described water storage temperature sensor is connected with controller.

Further, be provided with liquid level sensor in described water storage heat exchange tank, described liquid level sensor is connected with controller.

Further, also comprise: be arranged on the environment temperature sensor in green house, described environment temperature sensor is connected with controller.

Further, also comprise: be arranged on the soil temperature sensor under the earth's surface in green house, described soil temperature sensor is connected with controller.

The green house heat-exchange system that the utility model provides, during heat supply in winter, controller opens heat collector control valve and heat collector circulating pump, solar thermal collector is by the water heating in water storage heat exchange tank; Controller opens heat exchanger fin control valve and heat exchanger fin circulating pump, heated water enters heat exchanger fin circulation, improves environmental temperature; Controller opens buried coil pipe control valve and buried coil pipe circulating pump, heated water enters the circulation of buried coil pipe, improves soil temperature.The utility model utilizes solar thermal collector heating environment temperature and soil temperature simultaneously, and energy-saving high-efficiency environment-friendly, for the plant in green house provides suitable growing environment, not only cuts operating costs but also provide plant products.

Accompanying drawing explanation

Fig. 1 is the utility model specific embodiment structural representation.

In figure, 1-green house, 2-environment temperature sensor, the buried coil pipe of 3-, 4-soil temperature sensor, 5-heat exchanger fin, 6-irrigation pipeline, 7-solar thermal collector, 8-first irrigation control valve, the buried coil pipe circulating pump of 9-, the buried coil pipe control valve of 10-, 11-water storage heat exchange tank, 12-water storage temperature sensor, 13-liquid level sensor, 14-heat exchanger fin control valve, 15-heat exchanger fin circulating pump, 16-heat collector control valve, 17-heat collector circulating pump, 18-second irrigation control valve, 19-well, 20-well circulating pump, 21-well control valve.

Embodiment

Below in conjunction with accompanying drawing, also by specific embodiment, the utility model is elaborated, and following examples are to explanation of the present utility model, and the utility model is not limited to following embodiment.

As shown in Figure 1, the green house heat-exchange system that the utility model provides, comprises the solar thermal collector 7 be arranged on outside green house 1, is arranged on the water storage heat exchange tank 11 in green house 1, be arranged on the heat exchanger fin 5 on green house 1 inwall, be embedded in the buried coil pipe 3 under the earth's surface in green house 1; Solar thermal collector 7 is communicated with water storage heat exchange tank 11 by heat collector control valve 16, heat collector circulating pump 17 and forms closed circuit; Heat exchanger fin 5 is communicated with water storage heat exchange tank 11 by heat exchanger fin control valve 14, heat exchanger fin circulating pump 15 and forms closed circuit; Buried coil pipe 3 is communicated with water storage heat exchange tank 11 by buried coil pipe control valve 10, buried coil pipe circulating pump 9 and forms closed circuit; Wherein heat collector control valve 16, heat collector circulating pump 17, heat exchanger fin control valve 14, heat exchanger fin circulating pump 15, buried coil pipe control valve 10, buried coil pipe circulating pump 9 are connected with controller respectively.

Native system also comprises the well 19 be communicated with water storage heat exchange tank 11 by well control valve 21, well circulating pump 20, and well 19 controller and well circulating pump 20 are controlled to open by controller, can quickly and easily for water storage heat exchange tank 11 provides water source.And when environmental temperature or soil temperature too high time, the controller cold water that can control in well 19 enters in water storage heat exchange tank 11, reduce water temperature so that environmental temperature and soil temperature reach suitable temperature.

Native system also comprises irrigation pipeline 6, and irrigation pipeline 6 is communicated with water storage heat exchange tank 11 by the first irrigation control valve 8, and controller controls the first irrigation control valve 8 and opens, can in the winter time time warm water be plant irrigation, reduce soil temperature decline, be beneficial to plant growth.In addition, the water storage temperature sensor 12 be connected with controller is provided with in water storage heat exchange tank 11, when the water temperature that water storage temperature sensor 12 detects in water storage heat exchange tank 11 is higher be not suitable for irrigate time, controller controls well control valve 21 and well circulating pump 20 is opened, cold water in well 19 to enter in water storage heat exchange tank 11 and hot water in water storage heat exchange tank 11, until the water temperature in water storage heat exchange tank 11 reaches suitable temperature of irrigating.Set temperature sensor can ensure the temperature of irrigation water be suitable for, and has both avoided water temperature over-high to water bad plant, avoids again that water temperature is too low does not utilize soil heat preservation.

Above-mentioned irrigation pipeline 6 is also communicated with well 19 by the second irrigation control valve 18, second irrigation control valve 18 is connected with controller, preferably, well circulating pump 20 is arranged near well 19 one end, well control valve 21 is arranged on water storage heat exchange tank 11 one end, the import of the pipeline that irrigation pipeline 6 is communicated with well 19 is arranged between well circulating pump 20 and well control valve 21, when needing pouring cold water summer, controller controls the first photocontrol valve 8, second irrigation control valve 18, well circulating pump 20 is opened, cold water in well 19 is extracted in irrigation pipeline 6 by well circulating pump 20, now well control valve 21 is closed, in order to avoid cold water enters water storage heat exchange tank 11 waste water resource.

Native system also comprises the liquid level sensor 13 be arranged in water storage heat exchange tank 11, liquid level sensor 13 is connected with controller, for the water level in Real-Time Monitoring water storage heat exchange tank 11, when water level is not enough, controller controls well control valve 21, well circulating pump 20 is opened to supply water source.

The environment temperature sensor 2 be connected with controller is also provided with, for the environmental temperature in Real-Time Monitoring temperature booth, to adjust environmental temperature in time in green house 1.The soil temperature sensor 4 be connected with controller is also provided with, for Real-Time Monitoring soil temperature, to adjust soil temperature in time under earth's surface in green house 1.

The above is only preferred embodiment of the present utility model; be noted that for those skilled in the art; under the prerequisite not departing from the utility model principle; can also make some improvements and modifications, these improvements and modifications also should be considered as protection domain of the present utility model.

Claims (8)

1. a green house heat-exchange system, it is characterized in that, comprise: be arranged on green house (1) solar thermal collector outward (7), be arranged on the water storage heat exchange tank (11) in green house (1), be arranged on the heat exchanger fin (5) on green house (1) inwall, be embedded in the buried coil pipe (3) under the earth's surface in green house (1);

Described solar thermal collector (7) to be communicated with water storage heat exchange tank (11) by heat collector control valve (16), heat collector circulating pump (17) and to form closed circuit; Described heat exchanger fin (5) to be communicated with water storage heat exchange tank (11) by heat exchanger fin control valve (14), heat exchanger fin circulating pump (15) and to form closed circuit; Described buried coil pipe (3) to be communicated with water storage heat exchange tank (11) by buried coil pipe control valve (10), buried coil pipe circulating pump (9) and to form closed circuit;

Also comprise: controller; Described heat collector control valve (16), heat collector circulating pump (17), heat exchanger fin control valve (14), heat exchanger fin circulating pump (15), buried coil pipe control valve (10), buried coil pipe circulating pump (9) are connected with controller respectively.

2. green house heat-exchange system according to claim 1, is characterized in that, also comprise: well (19); Described well (19) is communicated with water storage heat exchange tank (11) by well control valve (21), well circulating pump (20); Described well control valve (21), well circulating pump (20) are connected with controller respectively.

3. green house heat-exchange system according to claim 2, is characterized in that, also comprise: irrigation pipeline (6); Described irrigation pipeline (6) is communicated with water storage heat exchange tank (11) by the first irrigation control valve (8); Described first irrigation control valve (8) is connected with controller.

4. green house heat-exchange system according to claim 3, is characterized in that, also comprise: the second irrigation control valve (18); Described irrigation pipeline (6) is communicated with well (19) by the second irrigation control valve (18), and described second irrigation control valve (18) is connected with controller.

5. green house heat-exchange system according to claim 3, is characterized in that, is provided with water storage temperature sensor (12) in described water storage heat exchange tank (11), and described water storage temperature sensor (12) is connected with controller.

6. green house heat-exchange system according to claim 1 and 2, is characterized in that, be provided with liquid level sensor (13) in described water storage heat exchange tank (11), described liquid level sensor (13) is connected with controller.

7. green house heat-exchange system according to claim 1 and 2, is characterized in that, also comprise: be arranged on the environment temperature sensor (2) in green house (1), described environment temperature sensor (2) is connected with controller.

8. green house heat-exchange system according to claim 1 and 2, is characterized in that, also comprise: be arranged on the soil temperature sensor (4) under the earth's surface in green house (1), described soil temperature sensor (4) is connected with controller.