[go: up one dir, main page]
More Web Proxy on the site http://driver.im/

CN101825364A - Cascade high-temperature heat pump with gaseous intermediate-temperature heat source and double low-temperature heat sources - Google Patents

Cascade high-temperature heat pump with gaseous intermediate-temperature heat source and double low-temperature heat sources Download PDF

Info

Publication number
CN101825364A
CN101825364A CN201010170316A CN201010170316A CN101825364A CN 101825364 A CN101825364 A CN 101825364A CN 201010170316 A CN201010170316 A CN 201010170316A CN 201010170316 A CN201010170316 A CN 201010170316A CN 101825364 A CN101825364 A CN 101825364A
Authority
CN
China
Prior art keywords
working medium
heat pump
high temperature
temperature
heat
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
CN201010170316A
Other languages
Chinese (zh)
Inventor
周光辉
刘寅
董秀洁
崔四齐
王聪民
陈圣洁
蔡哲
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Zhongyuan University of Technology
Original Assignee
Zhongyuan University of Technology
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Zhongyuan University of Technology filed Critical Zhongyuan University of Technology
Priority to CN201010170316A priority Critical patent/CN101825364A/en
Publication of CN101825364A publication Critical patent/CN101825364A/en
Pending legal-status Critical Current

Links

Images

Landscapes

  • Heat-Pump Type And Storage Water Heaters (AREA)

Abstract

The invention discloses a cascade high-temperature heat pump with a gaseous intermediate-temperature heat source and double low-temperature heat sources. The heat pump is cascaded by high and low-temperature two heat pump circulating systems; the low-temperature heat pump circulating system comprises a low-temperature compressor, a double heat source evaporator, a heat source type condenser/evaporator, a low-temperature throttling valve and a connecting pipeline; the heat pump working medium of the low-temperature heat pump circulating system is a low-temperature heat pump working medium; the high-temperature heat pump circulating system comprises a high-temperature compressor, a heat source type condenser/evaporator, a high-temperature condenser, a high-temperature throttling valve and a connecting pipeline; the heat pump working medium of the high-temperature heat pump circulating system is a high-temperature heat pump working medium; the double heat source evaporator is provided with a low-temperature heat pump working medium passage and two heat source passages; and the heat source type condenser/evaporator is provided with a low-temperature heat pump working medium passage, a high-temperature heat pump working medium passage and a gaseous heat source passage. The system device can efficiently provide hot water of over 75 DEG C, can be widely applied to the heating systems of civil buildings, public buildings and villa buildings, and can meet the high-temperature hot water requirement of industrial production.

Description

A kind of cascade high-temperature heat pump with warm source in the gaseous state and two low-temperature heat sources
Technical field
The present invention relates to the heat pump air conditioner technical field, especially relate to a kind of cascade high-temperature heat pump that hot water more than 75 ℃ is provided with warm source and two low-temperature heat sources in the gaseous state.
Background technology
Along with the continuous propelling of national energy-saving and emission-reduction work, the medium small boiler in the city is eliminated gradually, presses for new high-efficient energy-saving environment friendly device at present and replaces the medium small boiler that is eliminated for heating with the high-temperature-hot-water that provides more than 75 ℃ is provided.Traditional heat pump can only provide water temperature not to be higher than 55 ℃ hot water, can not satisfy heating and production demand, and the single-stage of studying at present circulation and superposition type cyclic high-temperature heat pump all can only adopt single low temperature or single in warm source, can't realize compound utilization to two or more thermals source, and the worst hot case running efficiency is very low, is difficult to apply.
Summary of the invention
Purpose of the present invention provide at existing weak point in the above-mentioned prior art just a kind of can to air, solar energy, regenerative resource such as energy and various waste heat, used heat carry out comprehensive with rationally utilize, can produce the cascade high-temperature heat pump with warm source and two low-temperature heat sources in the gaseous state of hot water more than 75 ℃.
Purpose of the present invention can realize by following technique measures:
Cascade high-temperature heat pump with warm source in the gaseous state and two low-temperature heat sources of the present invention is to be formed by two heat pump circulating system overlappings of high and low temperature:
A, the circulation of described low temperature comprise cryogenic compressor, two thermal source evaporimeter, heat source type condenser/evaporator, cryogenic throttle valve and connecting line; Described pair of thermal source evaporimeter has a hot pump in low temp working medium passage and two thermal source passages, and the heat source type condenser/evaporator has a hot pump in low temp working medium passage, a high temperature heat pump working medium passage and a gaseous state thermal source passage; Wherein the import of cryogenic compressor connects the outlet of the hot pump in low temp working medium passage of two thermal source evaporimeters, and the outlet of cryogenic compressor connects the import of the hot pump in low temp working medium passage of heat source type condenser/evaporator; The outlet of the hot pump in low temp working medium passage of heat source type condenser/evaporator is connected by the import of cryogenic throttle valve with the hot pump in low temp working medium passage of two thermal source evaporimeters, and its heat pump fluid is hot pump in low temp working medium (for the used working medium of conventional heat pump air conditioner); Being connected with the import and export pipeline of gaseous state thermal source respectively of the gaseous state thermal source passage of described heat source type condenser/evaporator, constitute independently loop into and out of interface; Two thermal source passages of described pair of thermal source evaporimeter connecting with the import and export pipeline of two kinds of different low-temperature heat sources respectively separately, constitute two independently loops into and out of interface;
B, described high temperature circulation comprise high temperature compressed machine, heat source type condenser/evaporator, high temperature condenser, high temperature choke valve and connecting line; Wherein the import of high temperature compressed machine connects the outlet of the high temperature heat pump working medium passage of heat source type condenser/evaporator, the outlet of high temperature compressed machine connects the import of the heat pump fluid passage of high temperature condenser, the import of the high temperature heat pump working medium passage of heat source type condenser/evaporator is connected by the outlet of high temperature choke valve with the heat pump fluid passage of high temperature condenser, and its heat pump fluid is high temperature heat pump working medium (for condensation temperature 〉=75 in the higher high temperature heat pump working medium of condensation temperature, its nominal situation scope ℃).
The described pair of employed thermal source of thermal source evaporimeter can be temperature≤30 ℃ air, solar energy, regenerative resource and various waste heat and used heat such as energy.
The employed thermal source of described heat source type condenser/evaporator can be the air of temperature 〉=30 ℃ and various gaseous state waste heat, used heat.
Cascade high-temperature heat pump with warm source in the gaseous state and two low-temperature heat sources of the present invention both can absorb warm source heat in gaseous state low-temperature heat source, liquid low-temperature heat source and the gaseous state separately, can absorb the heat of any two or three thermal source in the warm source in gaseous state low-temperature heat source, liquid low-temperature heat source, the gaseous state again simultaneously.
Two thermal source evaporimeters are Chinese patent 200720091299.1 disclosed fin-sleeve type three mediums composite heat exchangers described in the present invention, also can adopt Chinese patent 200820069364.5 disclosed shell-sleeve type three mediums composite heat-exchangers with three kinds of medium channels.
The condenser/evaporator of heat source type described in the present invention is Chinese patent 200720091299.1 disclosed fin-sleeve type three mediums composite heat exchangers.
Beneficial effect of the present invention is as follows:
Device of the present invention can provide the hot water more than 75 ℃ efficiently, can be widely used in the heating system of civil buildings, public building, villa buildings, and can satisfy industrial high-temperature-hot-water demand.
Description of drawings
Fig. 1 has the structure principle chart of the cascade high-temperature heat pump of warm source in the gaseous state and two low-temperature heat sources for the present invention.
Fig. 2 is gaseous state and liquid structure principle chart with the cascade high-temperature heat pump in warm source and two low-temperature heat sources in the gaseous state for low-temperature heat source.
Fig. 3 is the structure principle chart of the cascade high-temperature heat pump with warm source in the gaseous state and two low-temperature heat sources of two kinds of liquid heat sources for low-temperature heat source.
Sequence number among the figure: 1 cryogenic compressor, 1 ' the high temperature compressed machine, 2 pairs of thermal source evaporimeters, 3 high temperature condensers, 4 cryogenic throttle valves, 4 ' high temperature choke valve, 5 heat source type condenser/evaporators.
The specific embodiment
The present invention is further described below with reference to embodiment (accompanying drawing), but does not limit the present invention.
Embodiment 1
As shown in Figure 1, the cascade high-temperature heat pump with warm source in the gaseous state and two low-temperature heat sources of the present invention is to be formed by two heat pump circulating system overlappings of high and low temperature: described low temperature circulation comprises cryogenic compressor 1, two thermal source evaporimeter 2, heat source type condenser/evaporator 5, cryogenic throttle valve 4 and connecting line; Described pair of thermal source evaporimeter 2 has a hot pump in low temp working medium passage and two thermal source passages, and heat source type condenser/evaporator 5 has a hot pump in low temp working medium passage, a high temperature heat pump working medium passage and a gaseous state thermal source passage; Wherein the import of cryogenic compressor 1 connects the outlet of the hot pump in low temp working medium passage of two thermal source evaporimeters 2, and the outlet of cryogenic compressor 1 connects the import of the hot pump in low temp working medium passage of heat source type condenser/evaporator 5; The outlet of the hot pump in low temp working medium passage of heat source type condenser/evaporator 5 is connected by the import of cryogenic throttle valve 4 with the hot pump in low temp working medium passage of two thermal source evaporimeters 2, and its heat pump fluid is hot pump in low temp working medium (for the used working medium of conventional heat pump air conditioner); Being connected with the import and export pipeline of gaseous state thermal source respectively of the gaseous state thermal source passage of described heat source type condenser/evaporator 5, constitute independently loop into and out of interface; Two thermal source passages of described pair of thermal source evaporimeter 2 connecting with the import and export pipeline of two kinds of different low-temperature heat sources respectively separately, constitute two independently loops into and out of interface; Described high temperature circulation comprises high temperature compressed machine 1 ', heat source type condenser/evaporator 5, high temperature condenser 3, high temperature choke valve 4 ' and connecting line; Wherein the import of high temperature compressed machine 1 ' connects the outlet of the high temperature heat pump working medium passage of heat source type condenser/evaporator 5, the outlet of high temperature compressed machine 1 ' connects the import of the heat pump fluid passage of high temperature condenser 3, the import of the high temperature heat pump working medium passage of heat source type condenser/evaporator 5 is connected by the outlet of high temperature choke valve 4 ' with the heat pump fluid passage of high temperature condenser 3, and its heat pump fluid is high temperature heat pump working medium (for condensation temperature 〉=75 in the higher high temperature heat pump working medium of condensation temperature, its nominal situation scope ℃).
Embodiment 2
As shown in Figure 2, the present embodiment structure is identical with embodiment 1, and the low-temperature heat source described in this embodiment is gaseous state and liquid heat source.
Embodiment 3
As shown in Figure 3, the present embodiment structure is identical with embodiment 1, and the low-temperature heat source described in this embodiment is two kinds of liquid heat sources.
Two thermal source evaporimeters are Chinese patent 200720091299.1 disclosed fin-sleeve type three mediums composite heat exchangers described in the present invention, also can adopt Chinese patent 200820069364.5 disclosed shell-sleeve type three mediums composite heat-exchangers with three kinds of medium channels.
The condenser/evaporator of heat source type described in the present invention is Chinese patent 200720091299.1 disclosed fin-sleeve type three mediums composite heat exchangers.
Workflow of the present invention is as follows:
(1) independent low-temperature heat source pattern
A, single gaseous state low-temperature heat source pattern.
Hot pump in low temp working medium through to heat source type condenser/evaporator 5 release heat, enters two thermal source evaporimeters 2 through cryogenic throttle valve 4 by cryogenic compressor 1 compression, enters cryogenic compressor behind the absorption gaseous state thermal source heat and enters next circulation; High temperature heat pump working medium is by the 1 ' compression of high temperature compressed machine, through to high temperature condenser 3 release heat, and through high temperature choke valve 4 ', heat source type condenser/evaporator 5, absorption hot pump in low temp working medium heat is laggard goes into high temperature compressed machine and enters next circulation.
B, single liquid low-temperature heat source pattern.
Hot pump in low temp working medium through to heat source type condenser/evaporator 5 release heat, enters two thermal source evaporimeters 2 through cryogenic throttle valve 4 by cryogenic compressor 1 compression, enters cryogenic compressor behind the absorption liquid heat source heat and enters next circulation; High temperature heat pump working medium is by the 1 ' compression of high temperature compressed machine, through to high temperature condenser 3 release heat, and through high temperature choke valve 4 ', heat source type condenser/evaporator 5, absorption hot pump in low temp working medium heat is laggard goes into high temperature compressed machine and enters next circulation.
C, the two low-temperature heat source composite modes of gaseous state-liquid state.
Hot pump in low temp working medium through to heat source type condenser/evaporator 5 release heat, enters pair thermal source evaporimeters 2 through cryogenic throttle valve 4 by cryogenic compressor 1 compression, absorbs simultaneously to enter cryogenic compressor behind gaseous state thermal source and the liquid heat source heat and enter next circulation; High temperature heat pump working medium is by the 1 ' compression of high temperature compressed machine, through to high temperature condenser 3 release heat, and through high temperature choke valve 4 ', heat source type condenser/evaporator 5, absorption hot pump in low temp working medium heat is laggard goes into high temperature compressed machine and enters next circulation.
D, biliquid attitude low-temperature heat source composite mode.
Hot pump in low temp working medium through to heat source type condenser/evaporator 5 release heat, enters pair thermal source evaporimeters 2 through cryogenic throttle valve 4 by cryogenic compressor 1 compression, absorbs simultaneously to enter cryogenic compressor behind the heat of two kinds of liquid heat sources and enter next circulation; High temperature heat pump working medium is by the 1 ' compression of high temperature compressed machine, through to high temperature condenser 3 release heat, and through high temperature choke valve 4 ', heat source type condenser/evaporator 5, absorption hot pump in low temp working medium heat is laggard goes into high temperature compressed machine and enters next circulation.
(2) warm source module in the independent gaseous state
Close cryogenic compressor 1, high temperature heat pump working medium is by high temperature compressed machine 1 ' compression, and through to high temperature condenser 3 release heat, through high temperature choke valve 4 ', heat source type condenser/evaporator 5 enters high temperature compressed machine behind the heat of warm source in the absorption gaseous state and enters next circulation.
(3) warm source and single low-temperature heat source composite mode in the gaseous state
Hot pump in low temp working medium through to heat source type condenser/evaporator 5 release heat, enters two thermal source evaporimeters 2 through cryogenic throttle valve 4 by cryogenic compressor 1 compression, enters cryogenic compressor behind absorption gaseous state or the liquid heat source heat and enters next circulation; High temperature heat pump working medium is by high temperature compressed machine 1 ' compression, and through to high temperature condenser 3 release heat, through high temperature choke valve 4 ', heat source type condenser/evaporator 5 enters high temperature compressed machine behind the heat of warm source in absorption hot pump in low temp working medium and the gaseous state and enters next circulation.
(4) warm source and two low-temperature heat source composite modes in the gaseous state
Hot pump in low temp working medium through to heat source type condenser/evaporator 5 release heat, enters pair thermal source evaporimeters 2 through cryogenic throttle valve 4 by cryogenic compressor 1 compression, absorbs simultaneously to enter cryogenic compressor behind gaseous state and the liquid heat source heat and enter next circulation; High temperature heat pump working medium is by high temperature compressed machine 1 ' compression, and through to high temperature condenser 3 release heat, through high temperature choke valve 4 ', heat source type condenser/evaporator 5 enters high temperature compressed machine behind the heat of warm source in absorption hot pump in low temp working medium and the gaseous state and enters next circulation.

Claims (1)

1. cascade high-temperature heat pump with warm source in the gaseous state and two low-temperature heat sources, it is characterized in that: this device is formed by two heat pump circulating system overlappings of high and low temperature:
A, the circulation of described low temperature comprise cryogenic compressor (1), two thermal source evaporimeter (2), heat source type condenser/evaporator (5), cryogenic throttle valve (4) and connecting line; Described pair of thermal source evaporimeter (2) has a hot pump in low temp working medium passage and two thermal source passages, and heat source type condenser/evaporator (5) has a hot pump in low temp working medium passage, a high temperature heat pump working medium passage and a gaseous state thermal source passage; Wherein the import of cryogenic compressor (1) connects the outlet of the hot pump in low temp working medium passage of two thermal source evaporimeters (2), and the outlet of cryogenic compressor (1) connects the import of the hot pump in low temp working medium passage of heat source type condenser/evaporator (5); The outlet of the hot pump in low temp working medium passage of heat source type condenser/evaporator (5) is connected by the import of cryogenic throttle valve (4) with the hot pump in low temp working medium passage of two thermal source evaporimeters (2), and its heat pump fluid is a hot pump in low temp working medium; Being connected with the import and export pipeline of gaseous state thermal source respectively of the gaseous state thermal source passage of described heat source type condenser/evaporator (5), constitute independently loop into and out of interface; Two thermal source passages of described pair of thermal source evaporimeter (2) connecting with the import and export pipeline of two kinds of different low-temperature heat sources respectively separately, constitute two independently loops into and out of interface;
B, described high temperature circulation comprise high temperature compressed machine (1 '), heat source type condenser/evaporator (5), high temperature condenser (3), high temperature choke valve (4 ') and connecting line; The import of wherein high temperature compressed machine (1 ') connects the outlet of the high temperature heat pump working medium passage of heat source type condenser/evaporator (5), the outlet of high temperature compressed machine (1 ') connects the import of the heat pump fluid passage of high temperature condenser (3), the import of the high temperature heat pump working medium passage of heat source type condenser/evaporator (5) is connected by the outlet of high temperature choke valve (4 ') with the heat pump fluid passage of high temperature condenser (3), and its heat pump fluid is a high temperature heat pump working medium.
CN201010170316A 2010-05-13 2010-05-13 Cascade high-temperature heat pump with gaseous intermediate-temperature heat source and double low-temperature heat sources Pending CN101825364A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN201010170316A CN101825364A (en) 2010-05-13 2010-05-13 Cascade high-temperature heat pump with gaseous intermediate-temperature heat source and double low-temperature heat sources

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN201010170316A CN101825364A (en) 2010-05-13 2010-05-13 Cascade high-temperature heat pump with gaseous intermediate-temperature heat source and double low-temperature heat sources

Publications (1)

Publication Number Publication Date
CN101825364A true CN101825364A (en) 2010-09-08

Family

ID=42689428

Family Applications (1)

Application Number Title Priority Date Filing Date
CN201010170316A Pending CN101825364A (en) 2010-05-13 2010-05-13 Cascade high-temperature heat pump with gaseous intermediate-temperature heat source and double low-temperature heat sources

Country Status (1)

Country Link
CN (1) CN101825364A (en)

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102721226A (en) * 2012-06-12 2012-10-10 宁波天海制冷设备有限公司 Cascade refrigeration circulating high temperature water-source heat pump unit and control method thereof
CN106989540A (en) * 2017-05-11 2017-07-28 南京工程学院 Two-shipper heat source tower heat pump and solution regeneration method with solution regeneration function
CN107120916A (en) * 2017-05-08 2017-09-01 上海理工大学 Superposition type dual temperature drying system

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102721226A (en) * 2012-06-12 2012-10-10 宁波天海制冷设备有限公司 Cascade refrigeration circulating high temperature water-source heat pump unit and control method thereof
CN102721226B (en) * 2012-06-12 2015-01-28 宁波天海制冷设备有限公司 Cascade refrigeration circulating high temperature water-source heat pump unit and control method thereof
CN107120916A (en) * 2017-05-08 2017-09-01 上海理工大学 Superposition type dual temperature drying system
CN106989540A (en) * 2017-05-11 2017-07-28 南京工程学院 Two-shipper heat source tower heat pump and solution regeneration method with solution regeneration function
CN106989540B (en) * 2017-05-11 2023-06-30 南京工程学院 Dual-machine heat source tower heat pump system with solution regeneration function and solution regeneration method

Similar Documents

Publication Publication Date Title
CN100547319C (en) List/single/double stage mixed composite stacking heat pump air-conditioning unit
CN101825374B (en) Cascade high-temperature heat pump with liquid intermediate-temperature heat source and double low-temperature heat sources
CN201811498U (en) Double heat source type multi-compression high temperature heat pump
CN201740299U (en) Combined heat pump heat exchange type high-temperature heat pump
CN201652663U (en) Heat recovery heat pump air conditioning system
CN201672743U (en) Compound heat source type cascade high-temperature heat pump
CN102494442A (en) Direct expansion type mine return air source heat pump system and operation method thereof
CN102226601B (en) Multifunctional injection heat pump unit
CN104676937B (en) Low-temperature air source and ground source dual-source heat pump unit and control method thereof
CN102927718B (en) Novel double-effect dual-temperature high temperature heat pump device
CN101825365A (en) Liquid-liquid middle-low temperature double heat source type cascade high-temperature heat pump
CN203518314U (en) Energy environment unit special for passive house capable of providing domestic hot water and fresh air
CN101825364A (en) Cascade high-temperature heat pump with gaseous intermediate-temperature heat source and double low-temperature heat sources
CN101900458B (en) Gas-liquid intermediate-low temperature double-heat source cascade high-temperature heat pump
CN201779922U (en) Indoor triple-generation ground source heat pump (GSHP) unit based on air-conditioning cooling, air-conditioning heating and sanitary hot water
CN102230690B (en) Solar-powered heat pump unit capable of freely recovering excess heat
CN101799223B (en) Entire-year three-use air source heat pump unit and method for operating same
CN203837330U (en) CO2 heat pump heat exchange enthalpy increase device
CN204593929U (en) A kind of source, Cryogenic air seedbed double-source heat pump unit
CN201672739U (en) Cascade high-temperature heat pump with gaseous medium-temperature heat source and double low-temperature heat sources
CN201672738U (en) Cascade high-temperature heat pump with liquid medium-temperature heat source and double low-temperature heat sources
CN215001823U (en) Geothermal energy step heating system based on double-stage absorption heat pump
CN201373568Y (en) Ultra-low temperature water heater capable of being used under 25 DEG C below zero
CN211233431U (en) Direct-current variable-frequency air-supplementing enthalpy-increasing carbon dioxide heat pump unit
CN201672740U (en) Liquid-liquid middle-and-low temperature double-heat-source cascading high-temperature heat pump

Legal Events

Date Code Title Description
C06 Publication
PB01 Publication
C10 Entry into substantive examination
SE01 Entry into force of request for substantive examination
C02 Deemed withdrawal of patent application after publication (patent law 2001)
WD01 Invention patent application deemed withdrawn after publication

Open date: 20100908