CN210569338U - Triple co-generation system - Google Patents

Triple co-generation system Download PDF

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Publication number
CN210569338U
CN210569338U CN201921382324.0U CN201921382324U CN210569338U CN 210569338 U CN210569338 U CN 210569338U CN 201921382324 U CN201921382324 U CN 201921382324U CN 210569338 U CN210569338 U CN 210569338U
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way valve
heat exchanger
interface
hot water
air
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CN201921382324.0U
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刘桂兴
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Jiangsu Jixiang Air Conditioning Equipment Co ltd
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Jiangsu Jixiang Air Conditioning Equipment Co ltd
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P80/00Climate change mitigation technologies for sector-wide applications
    • Y02P80/10Efficient use of energy, e.g. using compressed air or pressurized fluid as energy carrier

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Abstract

The utility model discloses a triple co-generation system, which comprises a compressor, a gas-liquid separator, a throttling mechanism, a liquid storage device, a water side heat exchanger, an air cooling heat exchanger, a belt coil hot water tank and an air conditioner energy storage water tank; is characterized in that a four-way valve is arranged between the water side heat exchanger and the air cooling heat exchanger, and a one-way valve bridge is arranged below the four-way valve; a hot water three-way valve is arranged between the water side heat exchanger and the belt pulley hot water tank, and a circulating water pump is arranged between the water side heat exchanger and the air conditioner energy storage water tank; a fan motor is arranged on the right side of the air-cooled heat exchanger, and a heat return pipe is arranged below the air-cooled heat exchanger; the device has the advantages of compact structure, convenient use, integration of multiple control modes, effective use cost saving, convenient installation, small occupied area, high safety performance, good stability and effective avoidance of environmental pollution caused by medium leakage; the multifunctional combined type house is suitable for various places such as families, villas, hotels, schools, factories and the like.

Description

Triple co-generation system
Technical Field
The utility model relates to a field of heat pump especially relates to a trigeminy supplies system.
Background
With the development of economy, the improvement of living standard and the more and more high requirements of the countries on environmental protection, safety and energy conservation in recent years, the application of the air source heat pump has gradually replaced the traditional heating device of medium gas and natural gas. More and more households are equipped with separate heat pump apparatuses. However, installing an independent heat pump for each function of equipment is expensive, and is limited by the installation site, which makes the installation of the engineering difficult. In addition, the traditional air source heat pump water heater is a primary system, domestic hot water directly transfers heat with an exchange medium, and once the medium leaks, the pollution is easily caused.
Disclosure of Invention
The utility model aims at providing a trigeminy supplies system, simple structure, reasonable in design collects refrigeration, heating, hot water supply in an organic whole, has solved above technical problem.
In order to realize the technical purpose, reach foretell technical requirement, the utility model discloses the technical scheme who adopts is: a triple co-generation system comprises a compressor, a gas-liquid separator, a throttling mechanism, a liquid storage device, a water side heat exchanger, an air cooling heat exchanger, a hot water tank with a coil pipe and an air conditioner energy storage water tank; the method is characterized in that: a four-way valve is arranged between the water side heat exchanger and the air cooling heat exchanger, and a one-way valve bridge is arranged below the four-way valve; a hot water three-way valve is arranged between the water side heat exchanger and the belt pulley hot water tank, and a circulating water pump is arranged between the water side heat exchanger and the air conditioner energy storage water tank; the right side of the air-cooled heat exchanger is provided with a fan motor, and a heat return pipe is arranged below the air-cooled heat exchanger.
Preferably: the four-way valve comprises four interfaces, a first interface of the four-way valve is connected with an exhaust port of the compressor, a second interface of the four-way valve is connected with a refrigerant inlet of the water side heat exchanger, a third interface of the four-way valve is connected with the upper end of the air-cooled heat exchanger, and a fourth interface of the four-way valve is connected with the upper end of the gas-liquid separator.
Preferably: the check valve bridge comprises four interfaces, a first interface of the check valve bridge is connected with a cold coal outlet of the water side heat exchanger, a second interface of the check valve bridge is connected with the upper end of the heat return pipe, a third interface of the check valve bridge is connected with the lower end of the air cooling heat exchanger, and a fourth interface of the check valve bridge is connected with a throttling mechanism.
Preferably: the throttling mechanism is connected with the liquid storage device.
Preferably: the lower end of the heat return pipe is connected with the liquid storage device.
Preferably: the hot water three-way valve comprises three interfaces, and a first interface of the hot water three-way valve is connected with a water outlet of the water side heat exchanger; the second interface of the hot water three-way valve is connected with the inlet of the hot water tank with the coil pipe; and a third interface of the hot water three-way valve is connected with an inlet of the air conditioner energy storage water tank.
The utility model has the advantages that; a triple co-generation system, compared to a conventional structure: the air conditioner has a compact structure and is convenient to use, and various operation modes of independent air conditioner refrigeration, independent air conditioner heating, independent domestic hot water, air conditioner refrigeration plus domestic hot water, air conditioner heating plus domestic hot water are integrated; the use cost is effectively saved, the installation is convenient, the occupied area is small, the safety performance is high, the stability is good, and the environmental pollution caused by medium leakage is effectively avoided; and the defrosting, antifreezing and anti-blocking operation functions of the water pump are realized, and the device is suitable for various places such as families, villas, hotels, schools, factories and the like.
Drawings
FIG. 1 is a schematic structural view of the present invention;
in the figure: 1. a compressor; 2. a gas-liquid separator; 3. a four-way valve; 4. an air-cooled heat exchanger; 5. a water side heat exchanger; 6. a reservoir; 7. a throttle mechanism; 8. a one-way valve bridge; 9. a second interface of the four-way valve; 10. a first interface of the four-way valve; 11. a third interface of the four-way valve; 12. a fourth interface of the four-way valve; 13. a first interface of the hot water three-way valve; 14. a second interface of the hot water three-way valve; 15. a third interface of the hot water three-way valve; 16. a hot water tank with a coil; 17. an air-conditioning energy storage water tank; 18. a water circulating pump; 19. a heat recovery pipe; 21. a water side heat exchanger coolant inlet; 22. a coolant outlet of the water side heat exchanger; 23-water outlet of the water side heat exchanger; 24-water side heat exchanger water inlet; 25. a one-way valve bridge first interface; 26. the one-way valve bridge second interface; 27. a one-way valve bridge third interface; 28. the one-way valve bridge fourth interface; 29. a hot water three-way valve; 30. a fan motor.
Detailed Description
In order to make the object, technical solution and beneficial technical effects of the present invention clearer, the present invention will be further described in detail with reference to the accompanying drawings and specific embodiments;
in the drawings: a triple co-generation system comprises a compressor 1, a gas-liquid separator 2, a throttling mechanism 7, a liquid storage device 6, a water side heat exchanger 5, an air-cooled heat exchanger 4, a belt coil hot water tank 16 and an air-conditioning energy storage water tank 17; the method is characterized in that: a four-way valve 3 is arranged between the water side heat exchanger 5 and the air cooling heat exchanger 4, and a one-way valve bridge 8 is arranged below the four-way valve 3; a hot water three-way valve 29 is arranged between the water side heat exchanger 5 and the hot water tank 16 with the coil pipe, and a circulating water pump 18 is arranged between the water side heat exchanger 5 and the air-conditioning energy storage water tank 17; the right side of the air-cooled heat exchanger 4 is provided with a fan motor 30, and a heat return pipe 19 is arranged below the air-cooled heat exchanger 4.
The four-way valve 3 comprises four interfaces, a first interface 10 of the four-way valve is connected with an exhaust port of the compressor 1, a second interface 9 of the four-way valve is connected with a refrigerant inlet 21 of the water-side heat exchanger, a third interface 11 of the four-way valve is connected with the upper end of the air-cooled heat exchanger 4, and a fourth interface 12 of the four-way valve is connected with the upper end of the gas-liquid separator 2; the check valve bridge 8 comprises four interfaces, a first interface 25 of the check valve bridge is connected with a cold coal outlet 22 of the water side heat exchanger, a second interface 26 of the check valve bridge is connected with the upper end of a heat return pipe 19, a third interface 27 of the check valve bridge is connected with the lower end of the air-cooled heat exchanger 4, and a fourth interface 28 of the check valve bridge is connected with the throttling mechanism 7; the throttling mechanism 7 is connected with the liquid storage device 6; the lower end of the heat return pipe 19 is connected with the liquid accumulator 6; the hot water three-way valve 29 comprises three interfaces, and a first interface 13 of the hot water three-way valve is connected with the water outlet 23 of the water side heat exchanger; the second interface 14 of the hot water three-way valve is connected with the inlet of a hot water tank 16 with a coil pipe; and a third interface 15 of the hot water three-way valve is connected with an inlet of an air-conditioning energy storage water tank 17.
The utility model discloses a concrete implementation: according to the logic control requirement, when the four-way valve second interface 9 of the four-way valve 3 is communicated with the four-way valve first interface 10, the one-way valve bridge first interface 25 of the one-way valve bridge 8 is communicated with the one-way valve bridge second interface 26, the one-way valve bridge third interface 27 of the one-way valve bridge 8 is communicated with the one-way valve bridge fourth interface 28, and the four-way valve third interface 11 of the four-way valve 3 is communicated with the four-way valve fourth interface 12, a refrigerant heating circulation loop of a heat pump system is formed.
The second interface 14 of the hot water three-way valve 29 is connected with the coil inlet of the coil pipe hot water tank 16 through control logic, and the coil penetration outlet of the coil pipe hot water tank 16 is connected with the water inlet of the circulating water pump 18, so that a single hot water supply cycle is formed.
The second interface 14 of the hot water three-way valve 29 is communicated with the circulating water inlet of the air-conditioning energy storage water tank 17 through control logic, and the circulating water outlet of the air-conditioning energy storage water tank 17 is communicated with the water inlet of the circulating water pump 18, so that an independent air-conditioning heating cycle is formed.
The hot water three-way valve 29 is automatically switched according to the needs of users by controlling the logical relationship, and an air conditioner heating and domestic hot water circulation mode is formed.
According to the logic relation requirement, when the first four-way valve interface 10 is communicated with the third four-way valve interface 11, the second one-way valve bridge interface 26 is communicated with the third one-way valve bridge interface 27, the fourth one-way valve bridge interface 28 is communicated with the first one-way valve bridge interface 25, the second four-way valve interface 9 is communicated with the fourth four-way valve interface 12, and the fourth four-way valve interface 12 is communicated with the gas-liquid separator 2, a refrigerant refrigeration cycle loop of a heat pump system is formed.
The second interface 14 of the hot water three-way valve is communicated with the circulating water inlet of the air-conditioning energy storage water tank 17 through control logic, and the circulating water outlet of the air-conditioning energy storage water tank 17 is communicated with the water inlet of the circulating water pump 18, so that an independent air-conditioning refrigeration cycle is formed.
The hot water three-way valve 29 is automatically switched according to the operation mode requirement by controlling the logic relationship, and the formed refrigerant heating circulation and refrigeration circulation are controlled by controlling the logic relationship to form the air-conditioning refrigeration and domestic hot water circulation mode.
And controlling the action relationship of the fan motor 30, the throttling mechanism 7 and the circulating water pump 18 according to the control logic relationship to form a defrosting cycle of the heat pump system.
When the domestic hot water circulation mode is realized, a first interface of the four-way valve is communicated with a second interface of the four-way valve, and a fourth interface of the four-way valve is communicated with a third interface of the four-way valve; the refrigerant loop flow is that a compressor 1, a four-way valve first interface 10, a four-way valve second interface 9, a water side heat exchanger refrigerant inlet 21, a water side heat exchanger refrigerant outlet 22, a one-way valve bridge first interface 25, a one-way valve bridge second interface 26, a heat return pipe 19, a liquid reservoir 6, a throttling mechanism 7, a one-way valve bridge third interface 27, an air-cooled heat exchanger 4, a four-way valve third interface 11, a four-way valve fourth interface 12, a gas-liquid separator 2 and the compressor 1 are arranged; the water circulation flow is a circulating water pump 18, a water side heat exchanger water inlet 24, a water side heat exchanger water outlet 23, a hot water three-way valve first interface 13, a hot water three-way valve second interface 14, a belt coil hot water tank 16 and a circulating water pump 18.
When the air-conditioning heating mode is realized, the flow of a refrigerant loop is the same as that of a refrigerant loop in a domestic hot water circulation mode, and the water circulation flow comprises a circulating water pump 18, a water inlet 24 of a water side heat exchanger, a water outlet 23 of the water side heat exchanger, a first interface 13 of a hot water three-way valve, a third interface 15 of the hot water three-way valve, an air-conditioning energy storage water tank 17 and the circulating water pump 18.
When the air-conditioning refrigeration mode is realized, the refrigerant loop flow is that a compressor 1, a four-way valve first interface 10, a four-way valve third interface 11, an air-cooled heat exchanger 4, a one-way valve bridge third interface 27, a one-way valve bridge second interface 26, a heat return pipe 19, a liquid accumulator 6, a throttling mechanism 7, a one-way valve bridge fourth interface 28, a one-way valve bridge first interface 25, a water side heat exchanger cold coal outlet 22, a water side heat exchanger refrigerant inlet 21, a four-way valve second interface 9, a four-way valve fourth interface 12, a gas-liquid separator 2 and the compressor 1 are arranged; the water circulation flow is the same as that of the air-conditioning heating mode.
The utility model discloses a control the operating condition of each part, make the compressor, air-cooled heat exchanger, hot water heat exchanger forms different connected modes between the coil pipe heat exchanger to reach the circulation circuit of different refrigerant systems and water systems. Through the logical relation of the input and the output of each part controlled by the core controller, the heat pump system can realize five control modes, namely independent air-conditioning refrigeration, independent air-conditioning heating, independent domestic hot water, air-conditioning refrigeration + domestic hot water, and air-conditioning heating + domestic hot water; meanwhile, the defrosting, antifreezing and anti-blocking operation functions of the water pump are realized, and different requirements of various places such as families, villas, hotels, schools, factories and the like are fully met.
The foregoing examples are given for the purpose of illustrating the present invention in a clear and non-restrictive manner, and it will be apparent to those skilled in the art that variations and modifications of the present invention may be made in other variations and modifications based on the foregoing description, and it is not necessary or necessary to exhaustively enumerate all embodiments, and all such variations and modifications as are obvious and desirable in the art are within the scope of the present invention.

Claims (6)

1. A triple co-generation system comprises a compressor (1), a gas-liquid separator (2), a throttling mechanism (7), a liquid storage device (6), a water side heat exchanger (5), an air cooling heat exchanger (4), a hot water tank (16) with a coil pipe and an air conditioning energy storage water tank (17); the method is characterized in that: a four-way valve (3) is arranged between the water side heat exchanger (5) and the air cooling heat exchanger (4), and a one-way valve bridge (8) is arranged below the four-way valve (3); a hot water three-way valve (29) is arranged between the water side heat exchanger (5) and the hot water tank (16) with the coil pipe, and a circulating water pump (18) is arranged between the water side heat exchanger (5) and the air conditioner energy storage water tank (17); the right side of the air-cooled heat exchanger (4) is provided with a fan motor (30), and a heat return pipe (19) is arranged below the air-cooled heat exchanger (4).
2. The cogeneration system of claim 1, wherein: the four-way valve (3) comprises four interfaces, a first interface (10) of the four-way valve is connected with an exhaust port of the compressor (1), a second interface (9) of the four-way valve is connected with a refrigerant inlet (21) of the water side heat exchanger, a third interface (11) of the four-way valve is connected with the upper end of the air cooling heat exchanger (4), and a fourth interface (12) of the four-way valve is connected with the upper end of the gas-liquid separator (2).
3. The cogeneration system of claim 1, wherein: check valve bridge (8) include four interfaces, first interface of check valve bridge (25) are connected with water side heat exchanger cold coal export (22), check valve bridge second interface (26) are connected with backheat pipe (19) upper end, check valve bridge third interface (27) are connected with air-cooled heat exchanger (4) lower extreme, check valve bridge fourth interface (28) are connected with throttle mechanism (7).
4. The co-generation system of claim 3, wherein: the throttling mechanism (7) is connected with the liquid storage device (6).
5. The co-generation system of claim 3, wherein: the lower end of the heat return pipe (19) is connected with the liquid reservoir (6).
6. The cogeneration system of claim 1, wherein: the hot water three-way valve (29) comprises three interfaces, and a first interface (13) of the hot water three-way valve is connected with a water outlet (23) of the water side heat exchanger; the second interface (14) of the hot water three-way valve is connected with the inlet of a hot water tank (16) with a coil pipe; and a third interface (15) of the hot water three-way valve is connected with an inlet of an air-conditioning energy storage water tank (17).
CN201921382324.0U 2019-08-24 2019-08-24 Triple co-generation system Active CN210569338U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN201921382324.0U CN210569338U (en) 2019-08-24 2019-08-24 Triple co-generation system

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN201921382324.0U CN210569338U (en) 2019-08-24 2019-08-24 Triple co-generation system

Publications (1)

Publication Number Publication Date
CN210569338U true CN210569338U (en) 2020-05-19

Family

ID=70645573

Family Applications (1)

Application Number Title Priority Date Filing Date
CN201921382324.0U Active CN210569338U (en) 2019-08-24 2019-08-24 Triple co-generation system

Country Status (1)

Country Link
CN (1) CN210569338U (en)

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Address after: 214500 68-10 North Third Ring Road, Chengbei Park, Jingjiang Economic Development Zone, Taizhou, Jiangsu

Patentee after: JIANGSU JIXIANG AIR CONDITIONING EQUIPMENT Co.,Ltd.

Address before: No. 68-10, North Third Ring Road, Chengbei Park, Jingjiang Economic Development Zone, Nantong City, Jiangsu Province

Patentee before: JIANGSU JIXIANG AIR CONDITIONING EQUIPMENT Co.,Ltd.