CN218627359U - Multi-energy complementary cold and heat energy supply system - Google Patents

Abstract

The utility model discloses a complementary cold and hot energy of multipotency provides system relates to clean energy technical field, can require relatively higher to the climatic temperature for solving current air, and is extremely cold and extremely hot area energy-conserving effect does not almost, therefore the regional problem that has the limitation that uses very much. A switch door is fixedly arranged at the middle position of the front end surface of the multi-energy complementary cold and heat energy mechanism through a hinge; further comprising: the PVT photovoltaic panel is fixedly arranged above the multi-energy complementary cold and heat energy mechanism through screws, a PVT conveying pipe is fixedly arranged below the PVT photovoltaic panel through a flange, and the PVT conveying pipe is fixedly arranged above the inner part of the multi-energy complementary cold and heat energy mechanism through a hoop; and the plate heat exchanger is fixedly arranged at the middle position of the inner wall of the multi-energy complementary cold and heat energy mechanism through screws, and one end of the plate heat exchanger is fixedly provided with a second heat exchanger connecting pipe through a flange.

Description

Multi-energy complementary cold and heat energy supply system

Technical Field

The utility model relates to a clean energy technical field specifically is complementary cold and hot energy of multipotency provides the system.

Background

Clean energy, i.e. green energy, refers to energy which does not discharge pollutants and can be directly used for production and living, and comprises nuclear energy and 'renewable energy'; the solar energy utilization rate limit value of solar power generation is 21% relative or lower, and 80% of heat is dissipated in the power generation process, and the power generation efficiency is continuously reduced along with the temperature rise of the solar panel; the early construction of the ground source heat pump is complex, the underground drilling cost is high, the underground energy in a region is exhausted due to different energy requirements in winter and summer in many regions, the use effect is gradually reduced year by year, and the underground drilling is abandoned finally; air energy has relatively high requirement on climate temperature, and almost no energy-saving effect exists in extremely cold and hot areas, so that the used area has limitation.

Therefore, the existing requirements are not met, and a multi-energy complementary cold and heat energy supply system is provided for the system.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a complementary cold and hot energy of multipotency provides the system to solve the current air that proposes in the above-mentioned background art and can require relatively higher to climate temperature, do not have at utmost point cold and the energy-conserving effect in extremely hot area almost, the regional problem that has the limitation very much that consequently uses.

In order to achieve the above object, the utility model provides a following technical scheme: multi-energy complementary cold and heat energy supply system, comprising: the multifunctional complementary cold and heat energy mechanism is fixedly provided with a switch door at the middle position of the front end surface of the multifunctional complementary cold and heat energy mechanism through a hinge;

further comprising:

the PVT photovoltaic panel is fixedly arranged above the multifunctional complementary cold and heat energy mechanism through screws, PVT conveying pipes are fixedly arranged below the PVT photovoltaic panel through flanges, and the PVT conveying pipes are fixedly arranged above the inner part of the multifunctional complementary cold and heat energy mechanism through clamps;

the plate heat exchanger is fixedly arranged at the middle position of the inner wall of the multi-energy complementary cold and heat energy mechanism through screws, and a second heat exchanger connecting pipe is fixedly arranged at one end of the plate heat exchanger through a flange;

the ground source heat pump is fixedly arranged below the plate heat exchanger through screws, and a first heat exchanger connecting pipe is fixedly arranged between the ground source heat pump and the second heat exchanger connecting pipe through a flange;

and the embedded grounding pipe is fixedly installed at the lower end of the second heat exchanger connecting pipe through a flange and extends into the surface soil, and one end of the embedded grounding pipe is fixedly connected with the ground source heat pump through the flange.

Preferably, one end of the ground source heat pump is fixedly provided with a heat pump connecting pipe through a flange, and the outer wall of the heat pump connecting pipe is fixedly provided with a temperature control mechanism.

Preferably, a plurality of pipe heaters are fixedly installed in the temperature control mechanism through screws, and two ends of each pipe heater are fixedly connected with the heat pump connecting pipe through a combined flange.

Preferably, a control mechanism is fixedly mounted at the middle position of the pipeline heater through a screw, and the output end of the control mechanism is electrically connected with the input end of the pipeline heater.

Preferably, one side fixed mounting of temperature control mechanism has the flow distribution control cabinet, and installs a plurality of flow divider and the flowmeter that are used for the pipeline reposition of redundant personnel in the flow distribution control cabinet, one side of flow distribution control cabinet has a plurality of outer takeovers through flange fixed mounting.

Preferably, an aluminum alloy protective layer is fixedly mounted on the outer wall of the multi-energy complementary cold and heat energy mechanism, and a phenolic aldehyde insulation board is fixedly mounted on the inner wall of the aluminum alloy protective layer.

Preferably, a control valve and a thermometer are fixedly mounted on the outer wall of the first heat exchange connecting pipe through screws.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the utility model discloses a set up PVT photovoltaic board, plate heat exchanger, ground source heat pump and pre-buried ground pipe play the effect of the complementary cold and hot energy of multipotency, PVT photovoltaic board collects the heat that the sun shines the production, it passes through the plate heat exchanger heat transfer and carries to ground source heat pump department to collect the heat source, ground source heat pump leading principle is the air from the nature, acquire low-grade heat energy in water or the soil, through the electric power acting, then provide the high-grade heat energy that can be utilized to people again, make it can carry heat energy to user's department and supply the user to use, another part heat energy is sent into to pre-buried ground in through the second heat exchanger connecting pipe, it leads to the earth's surface temperature to reduce in continuous use ground source heat pump to touch the relative extremely cold area, can circulate the heat of collecting when generating in summer and utilize the underground surface layer soil department as energy storage medium (below the frozen soil layer) to reach the effect of crossing season energy storage, later when needing to use, send out through the heat pump acting once more, the problem that the air can receive regional restriction easily has been solved.

2. The temperature control mechanism has the effect of temperature control, the pipeline heater heats up for the electric heating element heating mode commonly used in the field, makes the intraductal medium temperature that does not satisfy the temperature improve, conveniently reaches the discharge demand, and the combined mode of combination flange can improve the leakproofness when pipeline medium carries, also makes things convenient for the follow-up dismantlement of user to overhaul pipeline heater.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the external structure of the multi-energy complementary cold and heat energy mechanism of the present invention;

FIG. 3 is a schematic view of a partial structure of the temperature control mechanism of the present invention;

FIG. 4 is a schematic view of a partial structure of the multi-energy complementary cold and heat energy mechanism of the present invention;

in the figure: 1. a multi-energy complementary cold and heat energy mechanism; 2. opening and closing the door; 3. a PVT photovoltaic panel; 4. a PVT duct; 5. a plate heat exchanger; 6. a first heat exchanger connecting pipe; 7. a ground source heat pump; 8. a second heat exchanger connecting pipe; 9. embedding a grounding pipe; 10. surface soil; 11. a heat pump connecting pipe; 12. a temperature control mechanism; 13. a pipe heater; 14. a combined flange; 15. a control mechanism; 16. a shunt control cabinet; 17. an external connection pipe; 18. an aluminum alloy protective layer; 19. a phenolic aldehyde insulation board; 20. a control valve; 21. a thermometer.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-4, the present invention provides an embodiment: a multi-energy complementary cold and heat energy supply system comprising: the multifunctional complementary cold and heat energy mechanism 1 is characterized in that a switch door 2 is fixedly arranged at the middle position of the front end face of the multifunctional complementary cold and heat energy mechanism 1 through a hinge;

further comprising:

the PVT photovoltaic panel 3 is fixedly arranged above the multifunctional complementary cold and heat energy mechanism 1 through screws, a PVT conveying pipe 4 is fixedly arranged below the PVT photovoltaic panel 3 through a flange, and the PVT conveying pipe 4 is fixedly arranged above the inner part of the multifunctional complementary cold and heat energy mechanism 1 through a hoop;

the plate type heat exchanger 5 is fixedly arranged at the middle position of the inner wall of the multi-energy complementary cold and heat energy mechanism 1 through screws, and a second heat exchanger connecting pipe 8 is fixedly arranged at one end of the plate type heat exchanger 5 through a flange;

the ground source heat pump 7 is fixedly arranged below the plate type heat exchanger 5 through screws, and a first heat exchanger connecting pipe 6 is fixedly arranged between the ground source heat pump 7 and a second heat exchanger connecting pipe 8 through a flange;

the embedded grounding pipe 9 is fixedly installed at the lower end of the second heat exchanger connecting pipe 8 through a flange and extends from the surface soil 10, and one end of the embedded grounding pipe 9 is fixedly connected with the ground source heat pump 7 through the flange;

the PVT photovoltaic panel 3 collects heat generated by solar irradiation, a heat source is collected to be subjected to heat exchange through the plate heat exchanger 5 and is conveyed to the ground source heat pump 7, the ground source heat pump 7 is mainly based on the principle that low-grade heat energy is obtained from air, water or soil in the nature, and is subjected to electric power work application to provide usable high-grade heat energy for people, so that the heat energy can be conveyed to users for use, the other part of the heat energy is conveyed into the embedded grounding tube 9 through the second heat exchanger connecting tube 8, when the ground source heat pump 7 is continuously used in relatively extremely cold areas to reduce the surface temperature, the collected heat energy is circulated to the underground to be used as an energy storage medium (below frozen ground) to achieve the effect of storing energy in a cross-season soil layer during power generation in summer, and then is conveyed out through the heat pump work application again when the ground source heat pump is used, and the problem that the air energy is easily limited by areas is solved.

Referring to fig. 1 and fig. 3, a heat pump connection pipe 11 is fixedly installed at one end of the ground source heat pump 7 through a flange, a temperature control mechanism 12 is fixedly installed on an outer wall of the heat pump connection pipe 11, and the temperature control mechanism 12 plays a role in temperature control.

Referring to fig. 3, a plurality of pipe heaters 13 are fixedly installed inside the temperature control mechanism 12 through screws, two ends of each pipe heater 13 are fixedly connected with the heat pump connecting pipe 11 through a combination flange 14, the pipe heaters 13 are commonly used in the field of heating by electric heating elements, so that the temperature of the medium in the pipe which does not meet the temperature is increased, the discharge requirement is conveniently met, the sealing performance during conveying the pipe medium can be improved by the combination mode of the combination flange 14, and the pipe heaters 13 can be conveniently dismounted and overhauled by a user.

Referring to fig. 3, a control mechanism 15 is fixedly installed at a middle position of the pipe heater 13 through a screw, an output end of the control mechanism 15 is electrically connected to an input end of the pipe heater 13, and the control mechanism 15 plays a role in controlling heating of the pipe heater 13, and belongs to a conventional matching component of the pipe heater 13 in the field.

Referring to fig. 1, a distribution control cabinet 16 is fixedly installed at one side of the temperature control mechanism 12, a plurality of distribution valves and flow meters for distributing the flow of the pipeline are installed in the distribution control cabinet 16, a plurality of external pipes 17 are fixedly installed at one side of the distribution control cabinet 16 through flanges, and the distribution control cabinet 16 is used for distributing and conveying the transmitted medium to each external pipe 17, so that the external pipe 17 is sent to the use of the user for use.

Referring to fig. 1, 2 and 4, an aluminum alloy protective layer 18 is fixedly mounted on the outer wall of the multi-energy complementary cold and heat energy mechanism 1, a phenolic aldehyde insulation board 19 is fixedly mounted on the inner wall of the aluminum alloy protective layer 18, the aluminum alloy protective layer 18 can play a role in external protection, and the phenolic aldehyde insulation board 19 can improve the heat preservation performance of the interior and reduce the loss of an internal heat source.

Referring to fig. 1, a control valve 20 and a thermometer 21 are fixedly mounted on an outer wall of the first heat exchange connecting pipe through screws, the control valve 20 and the thermometer 21 perform the effects of controlling the opening and closing of the pipes and detecting the temperature of a medium in the pipes, and preferably, the control valve 20 and the thermometer 21 can be mounted on each pipe in the equipment according to requirements.

The working principle is as follows: when the energy storage device is used, the PVT photovoltaic panel 3, the plate heat exchanger 5, the ground source heat pump 7 and the embedded grounding pipe 9 are arranged to achieve the effect of multi-energy complementary cold and heat energy, the PVT photovoltaic panel 3 collects heat generated by solar irradiation, the collected heat source exchanges heat through the plate heat exchanger 5 and is conveyed to the ground source heat pump 7, the ground source heat pump 7 mainly adopts the principle that low-grade heat energy is obtained from air, water or soil in the nature, does work through electric power, then provides available high-grade heat energy for people to enable the heat energy to be conveyed to users for use, the other part of heat energy is conveyed into the embedded grounding pipe 9 through the second heat exchanger connecting pipe 8, when the ground surface temperature is reduced due to continuous use of the ground source heat pump 7 in a relatively extremely cold area, the collected heat energy is circulated to the underground to utilize the ground surface layer soil 10 as an energy storage medium (below a frozen soil layer) in summer for achieving the effect of cross-season energy storage, then when the pipe heater needs to be used, the pipe heater 13 is heated by a common electric heating element heating mode in the field, so that the temperature of the medium in the pipe which does not meet the temperature is increased, the discharge requirement is conveniently met, the sealing performance during the conveying of the pipe medium can be improved by a combination mode of a combination flange 14, the pipe heater 13 is convenient to disassemble and overhaul by a user, one side of a shunt control cabinet 16 is fixedly provided with a plurality of external pipes 17 through flanges, the shunt control cabinet 16 is used for shunting and conveying the conveyed medium into each external pipe 17, so that the external pipes 17 are conveyed to the user for use, an aluminum alloy protective layer 18 can play an external protection effect, and the heat preservation performance of the interior can be improved by a phenolic insulation board 19, the loss of the internal heat source is reduced, and the control valve 20 and the thermometer 21 have the effects of controlling the opening and closing of the pipeline and detecting the temperature of the medium in the pipeline.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (7)

1. The multi-energy complementary cold and heat energy supply system comprises a multi-energy complementary cold and heat energy mechanism (1), wherein a switch door (2) is fixedly installed at the middle position of the front end face of the multi-energy complementary cold and heat energy mechanism (1) through a hinge;

the method is characterized in that: further comprising:

the PVT photovoltaic panel (3) is fixedly arranged above the multi-energy complementary cold and heat energy mechanism (1) through screws, a PVT conveying pipe (4) is fixedly arranged below the PVT photovoltaic panel (3) through a flange, and the PVT conveying pipe (4) is fixedly arranged above the inner part of the multi-energy complementary cold and heat energy mechanism (1) through a hoop;

the plate type heat exchanger (5) is fixedly arranged at the middle position of the inner wall of the multi-energy complementary cold and heat energy mechanism (1) through screws, and a second heat exchanger connecting pipe (8) is fixedly arranged at one end of the plate type heat exchanger (5) through a flange;

the ground source heat pump (7) is fixedly arranged below the plate type heat exchanger (5) through screws, and a first heat exchanger connecting pipe (6) is fixedly arranged between the ground source heat pump (7) and the second heat exchanger connecting pipe (8) through a flange;

and the embedded grounding pipe (9) is fixedly installed at the lower end of the second heat exchanger connecting pipe (8) through a flange and extends into the surface layer soil (10), and one end of the embedded grounding pipe (9) is fixedly connected with the ground source heat pump (7) through the flange.

2. A multi-energy complementary cold and heat energy supply system according to claim 1, wherein: one end of the ground source heat pump (7) is fixedly provided with a heat pump connecting pipe (11) through a flange, and a temperature control mechanism (12) is fixedly arranged on the outer wall of the heat pump connecting pipe (11).

3. A multi-energy complementary cold and heat energy supply system according to claim 2, wherein: a plurality of pipeline heaters (13) are fixedly installed in the temperature control mechanism (12) through screws, and two ends of each pipeline heater (13) are fixedly connected with the heat pump connecting pipe (11) through a combined flange (14).

4. A multi-energy complementary cold and heat energy supply system according to claim 3, wherein: the middle position of the pipeline heater (13) is fixedly provided with a control mechanism (15) through a screw, and the output end of the control mechanism (15) is electrically connected with the input end of the pipeline heater (13).

5. A multi-energy complementary cold and heat energy supply system according to claim 2, wherein: one side fixed mounting of accuse temperature mechanism (12) has shunt control cabinet (16), and installs a plurality of shunt valves and the flowmeter that are used for the pipeline reposition of redundant personnel in shunt control cabinet (16), there are a plurality of outer pipes (17) one side of shunt control cabinet (16) through flange fixed mounting.

6. A multi-energy complementary cold and heat energy supply system according to claim 1, wherein: the outer wall of the multi-energy complementary cold and heat energy mechanism (1) is fixedly provided with an aluminum alloy protective layer (18), and the inner wall of the aluminum alloy protective layer (18) is fixedly provided with a phenolic aldehyde insulation board (19).

7. A multi-energy complementary cold and heat energy supply system according to claim 1, wherein: and a control valve (20) and a thermometer (21) are fixedly mounted on the outer wall of the first heat exchanger connecting pipe through screws.

Images