CN112097308A - Heat pump heating system - Google Patents

Abstract

The invention discloses a heat pump heating system, which comprises a high-temperature heat source generating part, an air source heat pump and an absorption heat pump, wherein the air source heat pump is arranged on the high-temperature heat source generating part; when the heat pump heat supply system works, the high-quality heat source prepared by the air source heat pump is used as a waste heat source of the absorption heat pump, and the high-grade heat source output by the absorption heat pump is used for supplying heat to the outside, so that the operating efficiency of the air source heat pump can be improved because the temperature of waste heat water is lower than the temperature required by direct heat supply, particularly, when the temperature of the outside environment is lower, the system can also normally operate, the operating time of the system is improved, and the overall economy is better. The absorption heat pump in the invention takes a high-temperature heat source generated by a boiler as a driving source, so that the operation cost of the system is further reduced, and moreover, the control automation degree of each module of the heat pump heating system is higher, so that the unattended operation is favorably realized, and the application flexibility is higher.

Description

Heat pump heating system

Technical Field

The invention relates to the technical field of waste heat recovery equipment, in particular to a heat pump heating system.

Background

The new rural construction brings the rural heating demand, and the energy-saving and environment-friendly policy brings the heating mode change of changing coal into gas and changing coal into electricity. The current commonly adopted technology is that a gas boiler or an air source heat pump directly supplies heat, and the main energy source is natural gas or electric energy. When the heating temperature is relatively high, a lithium bromide heat pump and an air cold source tower are generally adopted for secondary heating.

The current heat supply adopts a gas boiler or an air source heat pump for heat supply, and has the following defects:

firstly, natural gas and electric energy are used as consumed energy, so that the price is high, the operation cost is high, and the burden of common people is heavy;

secondly, a heating system of a lithium bromide heat pump and an air cold source tower with secondary temperature rise is adopted, the system is complex, the automation degree is low, the unattended requirement cannot be met, and the large-scale popularization cannot be realized; the overall efficiency is also lower due to the adoption of the secondary temperature rise of the lithium bromide;

and thirdly, a heating system of a lithium bromide heat pump and an air cold source tower adopting secondary temperature rise is greatly influenced by the ambient temperature, and when the ambient temperature is lower, the problem that the system is low in efficiency and even cannot operate exists.

Therefore, how to overcome one of the above-mentioned drawbacks is a technical problem to be solved urgently by those skilled in the art.

Disclosure of Invention

The invention provides a heat pump heating system with low operation cost and wide application range.

The invention comprises a heat pump heating system, which comprises a high-temperature heat source generating part, an air source heat pump and an absorption heat pump; the air source heat pump at least comprises an evaporation module, a condensation module and a compressor, and a high-level heat medium outlet pipe of the condensation module is communicated with at least one waste heat water inlet pipe of the absorption heat pump; and a high-temperature medium outlet pipe of the high-temperature heat source generating part can be communicated with an inlet of a driving heat source pipeline of the absorption heat pump.

Compared with the prior art that the air source heat pump directly provides external heat supply heat energy, when the heat pump heat supply system works, a higher-quality heat source prepared by the air source heat pump is used as a waste heat source of the absorption heat pump, and a high-grade heat source output by the absorption heat pump is used for supplying heat to the outside, so that the operating efficiency of the air source heat pump can be improved because the temperature of the waste heat water is lower than the temperature required by direct heat supply, particularly, when the external environment temperature is lower, the system can also normally operate, the operating time of the system is improved, and the overall economy is better. The absorption heat pump in the invention takes a high-temperature heat source generated by a boiler as a driving source, thereby further reducing the operation cost of the system.

Moreover, the automation degree of each module control of the heat pump heating system is higher, unattended operation is favorably realized, and the application flexibility is higher.

Optionally, one absorption heat pump includes at least one evaporator, and the waste heat water inlet pipe and the waste heat water outlet pipe inside at least one of the evaporators are respectively communicated with the high-level heat medium outlet pipe and the high-level heat medium inlet pipe of the air source heat pump to form the waste heat water circulation loop.

Optionally, the waste heat water circulation system further comprises a first circulation pump for providing medium circulation power in the waste heat water circulation loop.

Optionally, the high-temperature heat source generating component includes a boiler, and a flue gas-water heat exchanger is further disposed on a flue gas exhaust pipeline of the boiler, and is used for exchanging heat between at least part of flue gas in the flue gas exhaust pipeline of the boiler and waste heat water supplied to the absorption heat pump.

Optionally, the absorption heat pump at least comprises a first evaporator and a second evaporator, and a waste heat water pipeline of the first evaporator and a high-level heat medium pipeline of the air source heat pump form a first waste heat circulation loop; and a waste heat water pipeline of the second evaporator and a water heat exchange pipe inside the smoke-water heat exchanger form a second waste heat circulation loop.

Optionally, the absorption heat pump further comprises an expander, the high-temperature medium outlet pipe of the boiler can be communicated with the high-temperature medium inlet of the expander, and the low-pressure steam outlet of the expander is communicated with the driving heat source pipeline inlet of the absorption heat pump.

Optionally, the absorption heat pump further comprises an expander, the high-temperature medium outlet pipe of the high-temperature heat source generating component can be communicated with the high-temperature medium inlet of the expander, and the low-pressure steam outlet of the expander is communicated with the driving heat source pipeline inlet of the absorption heat pump.

Optionally, the absorption heat pump further comprises an auxiliary heat exchanger, and the auxiliary heat exchanger is used for exchanging heat between part of the high-temperature medium of the high-temperature heat source generating component and the high-quality heat source flowing out of the absorption heat pump.

Optionally, the absorption heat pump includes one or more of a single-effect heat pump unit, a double-effect heat pump unit, or a single-double composite heat pump unit.

Optionally, a switching valve is arranged on a communication pipeline between the high-position heat medium outlet pipe of the condensation module and the waste heat water inlet pipe of the absorption heat pump, and when the switching valve is in a first working state, the high-position heat medium outlet pipe of the condensation module is communicated with the waste heat water inlet pipe of the absorption heat pump; when the switching valve is in a second working state, all connecting pipe sections between the air source heat pump and the absorption heat pump are disconnected.

Drawings

Fig. 1 is a schematic structural diagram of a heat pump heating system according to a first embodiment of the present invention;

fig. 2 is a schematic structural diagram of a heat pump heating system according to a second embodiment of the present invention;

fig. 3 is a schematic structural diagram of a heat pump heating system according to a third embodiment of the present invention;

fig. 4 is a schematic structural diagram of a heat pump heating system according to a fourth embodiment of the present invention.

Wherein, in fig. 1 to 4:

1-a boiler; 2-air source heat pump; 31-a first waste heat circulation loop; 32-a second waste heat circulation loop; 3-an absorption heat pump; 4-a first circulation pump; 5-flue gas heat exchanger; 6-a second circulation pump; 7-an expander.

Detailed Description

In order to make the technical solutions of the present invention better understood by those skilled in the art, the present invention will be further described in detail with reference to the accompanying drawings and specific embodiments.

Referring to fig. 1, fig. 1 is a schematic structural diagram of a heat pump heating system according to a first embodiment of the present invention.

The invention provides a heat pump heating system which comprises a high-temperature heat source generating part, an air source heat pump 2 and an absorption heat pump 3.

The high-temperature heat source generating part can be a boiler 1, or other equipment which uses natural gas or electric energy as fuel and can form high-temperature medium by combustion, wherein the high-temperature medium can be steam or hot water or a mixed medium of the steam and the hot water. The technical solution and technical effects will be described by taking the high temperature heat source generating part as the boiler 1, and it should be understood by those skilled in the art that the high temperature heat source generating part is not limited to the boiler 1 described herein.

The air source heat pump 2 in the invention utilizes the inverse Carnot cycle working principle, obtains low-grade heat energy from the surrounding environment, increases the temperature by electric power work and outputs the heat energy to the condensation module, thereby generating higher-grade heat energy. The air source heat pump 2 at least comprises an evaporation module, a condensation module and a compressor, when the air source heat pump works, energy stored in ambient gas is absorbed in the evaporation module, meanwhile, the compressor consumes power, and heat is released in the condensation module through a working medium circulating system, so that a medium flowing through the condensation module is heated to output high-grade heat energy.

The high-level heat medium outlet pipe of the condensation module of the air source heat pump 2 is communicated with at least one residual heat water inlet pipe of the absorption heat pump 3. Namely, the heat source with higher quality prepared by the air source heat pump 2 is used as the residual heat water of the absorption heat pump 3. The hot water inlet 3a and the hot water outlet 3b of the absorption heat pump 3 are respectively connected with an external heat supply network, and the hot water flowing out of the hot water outlet 3b provides a heat source for the external heat supply network.

Meanwhile, the high-temperature medium outlet pipe of the high-temperature heat source generating component can be communicated with the driving heat source pipeline inlet of the absorption heat pump 3, so that part of heat of the high-temperature medium generated by the high-temperature heat source generating component can be directly or indirectly used as a driving source of the absorption heat pump 3.

Compared with the prior art that the air source heat pump 2 directly provides external heat supply heat energy, when the heat pump heat supply system works, a higher-quality heat source prepared by the air source heat pump 2 is used as a waste heat source of the absorption heat pump 3, and a high-grade heat source output by the absorption heat pump 3 is used for supplying heat to the outside, so that the operation efficiency of the air source heat pump 2 can be improved because the temperature of the waste heat water is lower than the temperature required by direct heat supply, particularly, when the temperature of the external environment is lower, the system can also normally operate, the operation time of the system is improved, and the overall economy is better. The absorption heat pump 3 in the invention takes a high-temperature heat source generated by the boiler 1 as a driving source, thereby further reducing the operation cost of the system.

In addition, each module of the heat pump heating system is high in degree of independence, high in degree of automation of control, beneficial to achieving unattended operation and high in application flexibility.

And because the absorption heat pump 3 in this heat pump heating system, air source heat pump 2 are the independent module, through installing parts such as diverter valve on the pipeline, can realize each part and work alone, when the user has the refrigeration demand in summer, through closing the ooff valve that sets up on the pipeline between absorption heat pump 3 and air source heat pump 2, can realize the independent work of absorption heat pump 3, air source heat pump 2, namely with external cooling tower cooperation work in order to provide cold volume to the external world. This greatly increases the flexibility of application of the system provided herein.

The absorption heat pump 3 comprises at least one absorber, at least one generator, at least one condenser and at least one evaporator, and a waste heat water inlet pipe and a waste heat water outlet pipe inside at least one of the evaporators are respectively communicated with a high-level heat medium outlet pipe and a high-level heat medium inlet pipe of the air source heat pump 2 to form a waste heat water circulation loop.

That is, the air source heat exchanger may provide the waste heat water for one of the absorption heat pumps 3, or may provide the waste heat water for several evaporators at the same time. Of course, in order to make the residual heat water in the residual heat water circulation loop flow smoothly, the heat pump heating system may further include a first circulation pump 4 for providing a circulation power of the medium in the residual heat water circulation loop.

The absorption heat pump 3 can be any one or more of a single-effect heat pump unit, a double-effect heat pump unit or a single-double composite heat pump unit. The specific structure of the absorption heat pump 3 can be referred to the prior art, and is not described in detail herein.

For the boiler 1, the high-temperature flue gas also contains a large amount of heat energy, and the heat energy is greatly wasted when the high-temperature flue gas is directly discharged into the air, so that the following improvement is further carried out on the heat pump heating system.

Referring to fig. 2 and 4, fig. 2 is a schematic structural diagram of a heat pump heating system according to a second embodiment of the present invention; fig. 4 is a schematic structural diagram of a heat pump heating system according to a fourth embodiment of the present invention.

In a specific embodiment, a smoke and water heat exchanger 5 is further disposed on the smoke exhaust pipeline of the boiler 1, and is used for exchanging heat between at least part of smoke in the smoke exhaust pipeline of the boiler 1 and waste heat water supplied to the absorption heat pump 3. That is, part of the heat energy of the waste heat water of the absorption heat pump 3 comes from the high-temperature flue gas in the flue gas exhaust pipeline.

Specifically, a liquid heat exchange pipeline in the smoke-water heat exchanger 5 and a residual heat water pipeline in one evaporator of the absorption heat pump 3 form a circulation loop.

Specifically, the absorption heat pump 3 at least comprises a first evaporator and a second evaporator, and a residual heat water pipeline of the first evaporator and a high-level heat medium pipeline of the air source heat pump form a first residual heat circulation loop 31; and a second waste heat circulation loop 32 is formed by a waste heat water pipeline of the second evaporator and a water heat exchange pipe inside the smoke-water heat exchanger 5. A second circulation pump 6 can be arranged on the second waste heat circulation loop 32 and used for providing circulation power for the medium in the pipeline.

In the embodiment, the waste heat water pipeline formed by the air source heat pump 2 and the absorption heat pump 3 and the waste heat water pipeline formed by the smoke-water heat exchanger 5 and the absorption heat pump 3 are independent from each other, so that the mutual influence is avoided, and the stability of the system operation is facilitated. In addition, the heat pump heating system recovers the heat of the flue gas, and can eliminate the white smoke phenomenon of the boiler 1.

The smoke-water heat exchanger 5 may be one or more of a shell-and-tube heat exchanger, a double-tube heat exchanger, a serpentine heat exchanger, a fin-tube heat exchanger, a jacket heat exchanger, a plate heat exchanger, a heat-pipe heat exchanger, a graphite heat exchanger, and the like, as long as the heat exchanger capable of exchanging heat between gas and water is realized.

Similarly, the smoke-water heat exchanger 5 in the present disclosure only needs to be capable of exchanging heat between air and water.

Referring to fig. 3 and 4, fig. 3 is a schematic structural diagram of a heat pump heating system according to a third embodiment of the present invention.

In order to realize the step utilization of energy, the heat pump heating system can further comprise an expander 7, a high-temperature medium outlet pipe of the boiler 1 can be communicated with a high-temperature medium inlet of the expander 7, and a low-pressure steam outlet of the expander 7 is communicated with a driving heat source pipeline inlet of the absorption heat pump 3.

Therefore, high-temperature steam from the boiler 1 can be firstly used for power generation through the expansion machine 7, and low-pressure steam generated in the expansion machine 7 is then introduced into the absorption heat pump 3 to be used as a driving heat source of the expansion machine, so that the high-temperature steam is further recycled, and the energy is recycled as much as possible.

When the heat supply temperature required by the external environment is higher, an auxiliary heat exchanger can be additionally arranged in the heat pump heat supply system and is used for exchanging heat between part of high-temperature media of the high-temperature heat source generating component and the high-quality heat source flowing out of the absorption heat pump 3, so that the temperature of the high-quality heat source generated by the absorption heat pump 3 can be further increased.

Although the figures do not show the specific components inside the absorption heat pump 3 and the air-source heat pump 2, the technical solutions described herein can be fully understood and implemented by those skilled in the art according to the basic knowledge and description herein that those skilled in the art are aware of.

In addition, a switching valve is arranged on a communication pipeline between the high-position heat medium outlet pipe of the condensation module and the waste heat water inlet pipe of the absorption heat pump 3, and when the switching valve is in a first working state, the high-position heat medium outlet pipe of the condensation module is communicated with the waste heat water inlet pipe of the absorption heat pump 3; when the switching valve is in the second working state, the high-position heat medium outlet pipe of the condensation module is disconnected with the waste heat water inlet pipe of the absorption heat pump 3, and all connecting pipe sections between the condensation module and the absorption heat pump 3 are disconnected.

Therefore, when the switching valve is in the second working state, the connecting pipeline between the absorption heat pump 3 and the air source heat pump 2 is completely disconnected, the two are independent, and then when refrigerating in summer, the absorption heat pump and the air source heat pump can be respectively configured with components such as a cooling tower and the like to form a refrigerating unit so as to provide cold for the outside and meet the refrigerating requirement of the outside environment.

The switching valve may be a valve or a valve assembly, as long as the above-mentioned purpose is achieved, and those skilled in the art can refer to the prior art and will not be described in detail herein. Not shown in the drawings, but not meant to impede understanding and implementation of the teachings herein by those skilled in the art.

The heat pump heating system provided by the invention is described in detail above. The principles and embodiments of the present invention are explained herein using specific examples, which are presented only to assist in understanding the method and its core concepts. It should be noted that, for those skilled in the art, it is possible to make various improvements and modifications to the present invention without departing from the principle of the present invention, and those improvements and modifications also fall within the scope of the claims of the present invention.

Claims (10)

1. A heat pump heating system is characterized by comprising a high-temperature heat source generating component, an air source heat pump (2) and an absorption heat pump (3); the air source heat pump (2) at least comprises an evaporation module, a condensation module and a compressor, and a high-level heat medium outlet pipe of the condensation module is communicated with at least one waste heat water inlet pipe of the absorption heat pump (3); and a high-temperature medium outlet pipe of the high-temperature heat source generating component can be communicated with a driving heat source pipeline inlet of the absorption heat pump (3).

2. The heat pump heating system according to claim 1, wherein each absorption heat pump (3) comprises at least one evaporator, and a residual heat water inlet pipe and a residual heat water outlet pipe inside at least one evaporator are respectively communicated with a high-level heat medium outlet pipe and a high-level heat medium inlet pipe of the air source heat pump (2) to form the residual heat water circulation loop.

3. A heat pump heating system according to claim 2, further comprising a first circulation pump (4) for providing medium circulation power in the residual heat water circulation circuit.

4. A heat pump heating system according to any one of claims 2 or 3, wherein the high-temperature heat source generating part comprises a boiler (1), and a smoke exhaust pipeline of the boiler (1) is further provided with a smoke-water heat exchanger (5) for exchanging heat between at least part of smoke in the smoke exhaust pipeline of the boiler (1) and waste heat water supplied to the absorption heat pump (3).

5. A heat pump heating system according to claim 3, wherein the absorption heat pump (3) comprises at least a first evaporator and a second evaporator, and the residual heat water pipeline of the first evaporator and the high-level heat medium pipeline of the air source heat pump form a first residual heat circulation loop (31); and a waste heat water pipeline of the second evaporator and a water heat exchange pipe inside the smoke-water heat exchanger (5) form a second waste heat circulation loop (32).

6. A heat pump heating system according to claim 5, further comprising an expander (7), wherein the high temperature medium outlet pipe of the boiler (1) is capable of communicating with the high temperature medium inlet of the expander (7), and the low pressure steam outlet of the expander (7) is communicated with the driving heat source pipeline inlet of the absorption heat pump (3).

7. A heat pump heating system according to claim 1 or 2, further comprising an expander (7), wherein the high temperature medium outlet pipe of the high temperature heat source generating part is capable of communicating with the high temperature medium inlet of the expander (7), and the low pressure steam outlet of the expander (7) is communicated with the driving heat source pipeline inlet of the absorption heat pump (3).

8. A heat pump heating system according to claim 1 or 2, further comprising an auxiliary heat exchanger for exchanging heat of part of the high temperature medium of the high temperature heat source generating part with the high quality heat source flowing out of the absorption heat pump (3).

9. The heat pump heating system according to claim 1 or 2, wherein the absorption heat pump (3) comprises one or more of a single-effect heat pump unit, a double-effect heat pump unit, or a single-double composite heat pump unit.

10. The heat pump heating system according to claim 1, wherein a switching valve is provided on a communication pipe between the high-level heat medium outlet pipe of the condensation module and the waste heat water inlet pipe of the absorption heat pump (3), and when the switching valve is in a first operating state, the high-level heat medium outlet pipe of the condensation module is communicated with the waste heat water inlet pipe of the absorption heat pump (3); when the switching valve is in a second working state, all connecting pipe sections between the air source heat pump (2) and the absorption heat pump (3) are disconnected.

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