CN217178687U - Split geothermal energy solar energy wind-solar-electricity integrated heating system - Google Patents

Abstract

The utility model relates to the technical field of heating systems, concretely relates to household geothermal energy solar energy scene electricity integrative heating system, including geothermal energy heat exchange tube, solar collector, water source heat pump and power supply subassembly, the water inlet end of geothermal energy heat exchange tube communicates with the water source heat pump through the first pipeline, the drainage end of geothermal energy heat exchange tube communicates with the water source heat pump through the second pipeline, the water source heat pump still is connected with the delivery pipe that is used for heating and the wet return that is used for heating, the water inlet end and the drainage end of solar collector communicate with the second pipeline through third pipeline and fourth pipeline respectively, and the junction of third pipeline and second pipeline is provided with first motorised valve; the utility model discloses a set up geothermal energy heat exchange tube, solar collector, water source heat pump and power supply unit, during the heat supply, can adopt the geothermal energy heat exchange tube to realize the heat transfer between the ground to can utilize solar collector to heat simultaneously, realize the high-efficient utilization of the two heat sources of ground source heat and solar thermal energy.

Description

Split geothermal energy solar energy wind-solar-electricity integrated heating system

Technical Field

The utility model relates to a heating system technical field, concretely relates to integrative heating system of family style geothermal energy solar energy scene electricity.

Background

In the world today, a great deal of petroleum resources are consumed, the world faces an energy crisis, meanwhile, due to the use of fossil raw materials, the greenhouse effect is increased due to the emission of a great deal of carbon dioxide gas, and the emission of various nitride sulfides also causes serious pollution to the atmosphere. Under the circumstance, solar energy and wind energy geothermal energy is used as inexhaustible renewable clean energy and is widely applied, most of the traditional hot water heating modes, especially in northern areas, are centralized boiler heating, and because a large amount of coal or natural gas is consumed by boiler heating, the atmosphere is polluted to different degrees, and especially a large amount of harmful substances such as dust nitride, sulfide and the like are discharged into the air by using a large amount of coal.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a divide family formula geothermal energy solar energy scene electricity integrative heating system, not only the heating is high-efficient, moreover energy saving, energy-concerving and environment-protective.

In order to solve the technical problem, the utility model provides a household geothermal energy solar energy wind-solar-electricity integrated heating system, which comprises a geothermal energy heat exchange tube, a solar heat collector, a water source heat pump and a power supply component;

the water inlet end of the geothermal energy heat exchange pipe is communicated with a water source heat pump through a first pipeline, the water discharge end of the geothermal energy heat exchange pipe is communicated with the water source heat pump through a second pipeline, and the water source heat pump is also connected with a water supply pipe for heating and a water return pipe for heating;

the solar water heater is characterized in that the water inlet end and the water outlet end of the solar heat collector are respectively communicated with the second pipeline through a third pipeline and a fourth pipeline, and a first electric valve is arranged at the joint of the third pipeline and the second pipeline.

Furthermore, a solar heat-supplementing direct-current water pump is further arranged on the second pipeline, a water inlet end of the solar heat-supplementing direct-current water pump is communicated with a water discharge end of the geothermal energy heat exchange tube, and a water discharge end of the solar heat-supplementing direct-current water pump is communicated with a water source heat pump.

Furthermore, a heating heat source side circulating water pump is further arranged on the second pipeline, a water inlet end of the solar heat-supplementing direct-current water pump is communicated with a water inlet end of the heating heat source side circulating water pump, and a water outlet end of the solar heat-supplementing direct-current water pump is communicated with a water outlet end of the heating heat source side circulating water pump.

Further, a second electric valve is further arranged on the second pipeline and is respectively communicated with the third pipeline and the fourth pipeline.

Further, the power supply assembly comprises a wind power generation and solar photovoltaic power generation board.

Furthermore, one end of the second pipeline close to the geothermal energy heat exchange tube, one end of the second pipeline close to the water source heat pump, one end of the first pipeline close to the water source heat pump, one end of the fourth pipeline close to the solar heat collector, and one ends of the water supply pipe and the water return pipe close to the water source heat pump are all provided with temperature displays.

The utility model discloses an above-mentioned technical scheme's beneficial effect as follows:

1. the utility model discloses a set up geothermal energy heat exchange tube, solar collector, water source heat pump and power supply unit, during the heat supply, can adopt the geothermal energy heat exchange tube to realize the heat transfer between the ground to can utilize solar collector to carry out the heating simultaneously, realize the high-efficient utilization of the two heat sources of ground source heat and solar thermal energy.

2. The utility model discloses a set up wind power generation and solar photovoltaic power generation board, the electric energy of production can drive solar energy concurrent heating water pump and carry out the concurrent heating, and extra energy consumption is not additionally spent in non-heating season, and is energy-concerving and environment-protective, sustainable.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

In the figure: 1. a geothermal energy heat exchange pipe; 2. a solar heat collector; 3. a water source heat pump; 4. a power supply assembly; 41. wind power generation; 42. a solar photovoltaic power generation panel; 5. a first conduit; 6. a second pipe; 7. a water supply pipe; 8. a water return pipe; 9. a third pipeline; 10. a fourth pipe; 11. a first electrically operated valve; 12. a second electrically operated valve; 13. a solar heat-supplementing direct-current water pump; 14. a circulating water pump on the heating heat source side; 15. and a temperature display.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the following description will be made with reference to fig. 1 of the embodiments of the present invention to clearly and completely describe the technical solutions of the embodiments of the present invention. It is to be understood that the embodiments described are only some of the embodiments of the present invention, and not all of them. All other embodiments, which can be derived from the description of the embodiments of the present invention by a person skilled in the art, are within the scope of the present invention.

As shown in fig. 1: a household geothermal energy solar energy wind-solar-electricity integrated heating system comprises a geothermal energy heat exchange tube 1, a solar heat collector 2, a water source heat pump 3 and a power supply assembly 4;

the water inlet end of the geothermal energy heat exchange tube 1 is communicated with a water source heat pump 3 through a first pipeline 5, the water discharge end of the geothermal energy heat exchange tube 1 is communicated with the water source heat pump 3 through a second pipeline 6, an auxiliary heating water pump is further arranged between the second pipeline 6 and the water source heat pump 3, and the water source heat pump 3 is further connected with a water supply tube 7 for heating and a water return tube 8 for heating;

the water inlet end and the water outlet end of the solar heat collector 2 are respectively communicated with the second pipeline 6 through a third pipeline 9 and a fourth pipeline 10;

specifically, the household geothermal energy solar energy wind, light and electricity integrated heating system comprises a geothermal energy heat exchange tube 1, a solar heat collector 2, a water source heat pump 3 and a power supply assembly 4;

the water inlet end of the geothermal energy heat exchange tube 1 is communicated with a water source heat pump 3 through a first pipeline 5, the water discharge end of the geothermal energy heat exchange tube 1 is communicated with the water source heat pump 3 through a second pipeline 6, an auxiliary heating water pump is further arranged between the second pipeline 6 and the water source heat pump 3, the auxiliary heating water pump comprises a solar energy heat compensation direct current water pump 13 and a heating heat source side circulating water pump 14, and the water source heat pump 3 is further connected with a water supply tube 7 for heating and a water return tube 8 for heating;

the water inlet end and the water outlet end of the solar heat collector 2 are respectively communicated with the second pipeline 6 through a third pipeline 9 and a fourth pipeline 10, and a first electric valve 11 is arranged at the joint of the third pipeline 9 and the second pipeline 6.

In the embodiment, by arranging the geothermal energy heat exchange tube 1, the solar heat collector 2, the water source heat pump 3 and the power supply assembly 4, during heat supply, the geothermal energy heat exchange tube 1 can be adopted to realize heat exchange between the ground, and the solar heat collector 2 can be simultaneously used for heating, so that the high-efficiency utilization of double heat sources of geothermal heat and solar heat is realized.

According to one embodiment of the present invention, as shown in figure 1,

the power supply assembly 4 comprises a wind power generation 41 and a solar photovoltaic power generation board 42;

the second pipeline 6 is also provided with a solar heat-supplementing direct-current water pump 13, the water inlet end of the solar heat-supplementing direct-current water pump 13 is communicated with the water discharge end of the geothermal energy heat exchange tube 1, and the water discharge end of the solar heat-supplementing direct-current water pump 13 is communicated with the water source heat pump 3;

in the embodiment, the wind power generation 41 and the solar photovoltaic power generation panel 42 are arranged, the generated electric energy can drive the solar heat compensation direct-current water pump 13 to perform heat compensation, energy is not additionally consumed in non-heating seasons, and the solar heat compensation direct-current water pump is energy-saving, environment-friendly and sustainable.

According to another embodiment of the present invention, as shown in figure 1,

a heating heat source side circulating water pump 14 is further arranged on the second pipeline 6, the water inlet end of the solar heat-supplementing direct-current water pump 13 is communicated with the water inlet end of the heating heat source side circulating water pump 14, and the water discharge end of the solar heat-supplementing direct-current water pump 13 is communicated with the water discharge end of the heating heat source side circulating water pump 14;

according to the embodiment, when the solar heat compensation direct-current water pump 13 cannot work, the heating source side circulating water pump 14 can be started to perform auxiliary heating, and flexibility is improved.

In one embodiment of the present invention, as shown in figure 1,

a first electric valve 11 is arranged at the joint of the third pipeline 9 and the second pipeline 6;

the second pipeline 6 is also provided with a second electric valve 12, and the second electric valve 12 is respectively communicated with the third pipeline 9 and the fourth pipeline 10;

in the embodiment, by arranging the first electric valve 11 and the second electric valve 12, when only the geothermal energy heat exchange tube 1 is needed for heating, the first electric valve 11 is closed, the second electric valve 12 is kept in a normally open state, and at the moment, the geothermal energy heat exchange tube 1 can be used for independently supplying heat; when the solar heat collector 2 is required to be used for auxiliary heating, the first electric valve 11 is opened, the second electric valve 12 is closed, and water after heat exchange of the geothermal energy heat exchange tube 1 can be heated for the second time through the solar heat collector 2, so that the temperature is further increased, and the heating efficiency is increased.

In one embodiment of the present invention, as shown in figure 1,

one end of the second pipeline 6 close to the geothermal energy heat exchange tube 1, one end of the second pipeline 6 close to the water source heat pump 3, one end of the first pipeline 5 close to the water source heat pump 3, one end of the fourth pipeline 10 close to the solar heat collector 2, and one end of the water supply pipe 7 and one end of the water return pipe 8 close to the water source heat pump 3 are all provided with a temperature display 15.

This embodiment, through setting up temperature display 15, the temperature of water source in the time of can showing each stage is convenient for monitor the temperature, and the practicality is strong.

The utility model discloses a theory of operation:

when only the geothermal energy heat exchange tube 1 is used for heat exchange, the geothermal energy heat exchange tube 1 can be used for heat exchange between the ground, the solar heat collector 2 can be used for heating at the same time, the double heat sources of ground source heat and solar heat can be efficiently utilized, in addition, when the modes are used for heat supply, the wind power generation 41 and the solar photovoltaic power generation plate 42 can generate electric energy which can drive the solar heat compensation direct current water pump 13 to perform heat compensation, no energy is additionally consumed in non-heating seasons, and the solar energy heat compensation direct current water pump is energy-saving, environment-friendly and sustainable.

In the present invention, unless otherwise explicitly specified or limited, for example, it may be fixedly connected, detachably connected, or integrated; can be mechanically or electrically connected; the terms may be directly connected or indirectly connected through an intermediate medium, and may be used for communicating the inside of two elements or for interacting with each other, unless otherwise specifically defined, and the specific meaning of the terms in the present invention will be understood by those skilled in the art according to the specific circumstances.

The foregoing is a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of improvements and decorations can be made without departing from the principle of the present invention, and these improvements and decorations should also be regarded as the protection scope of the present invention.

Claims (6)

1. The utility model provides a sub-family formula geothermal energy solar energy scene electricity integrative heating system which characterized in that: the device comprises a geothermal energy heat exchange tube (1), a solar heat collector (2), a water source heat pump (3) and a power supply assembly (4);

the water inlet end of the geothermal energy heat exchange pipe (1) is communicated with a water source heat pump (3) through a first pipeline (5), the water discharge end of the geothermal energy heat exchange pipe (1) is communicated with the water source heat pump (3) through a second pipeline (6), and the water source heat pump (3) is also connected with a water supply pipe (7) for heating and a water return pipe (8) for heating;

the solar water heater is characterized in that the water inlet end and the water outlet end of the solar heat collector (2) are respectively communicated with the second pipeline (6) through a third pipeline (9) and a fourth pipeline (10), and a first electric valve (11) is arranged at the joint of the third pipeline (9) and the second pipeline (6).

2. The household geothermal energy solar wind-solar-electricity integrated heating system as claimed in claim 1, characterized in that: the solar energy heat-supplementing direct-current water pump (13) is further arranged on the second pipeline (6), the water inlet end of the solar energy heat-supplementing direct-current water pump (13) is communicated with the water outlet end of the geothermal energy heat exchange pipe (1), and the water outlet end of the solar energy heat-supplementing direct-current water pump (13) is communicated with the water source heat pump (3).

3. The household geothermal energy solar wind-solar-electricity integrated heating system as claimed in claim 2, characterized in that: and a heating source side circulating water pump (14) is further arranged on the second pipeline (6), the water inlet end of the solar heat-supplementing direct-current water pump (13) is communicated with the water inlet end of the heating source side circulating water pump (14), and the water outlet end of the solar heat-supplementing direct-current water pump (13) is communicated with the water outlet end of the heating source side circulating water pump (14).

4. The household geothermal energy solar wind-solar-electricity integrated heating system as claimed in claim 1, characterized in that: the second pipeline (6) is also provided with a second electric valve (12), and the second electric valve (12) is respectively communicated with the third pipeline (9) and the fourth pipeline (10).

5. The household geothermal energy solar wind-solar-electricity integrated heating system as claimed in claim 1, characterized in that: the power supply assembly (4) comprises a wind power generation (41) and a solar photovoltaic power generation board (42).

6. The household geothermal energy solar wind-solar-electricity integrated heating system as claimed in claim 1, characterized in that: one end of the second pipeline (6) close to the geothermal energy heat exchange tube (1), one end of the second pipeline (6) close to the water source heat pump (3), one end of the first pipeline (5) close to the water source heat pump (3), one end of the fourth pipeline (10) close to the solar heat collector (2), and one ends of the water supply pipe (7) and the water return pipe (8) close to the water source heat pump (3) are all provided with a temperature display (15).

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