Absorption refrigerating machine
IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0556724
(2004-05-14)
|
등록번호 |
US-7316126
(2008-01-08)
|
우선권정보 |
JP-2003-135359(2003-05-14) |
국제출원번호 |
PCT/JP04/006851
(2004-05-14)
|
§371/§102 date |
20051114
(20051114)
|
국제공개번호 |
WO04/102085
(2004-11-25)
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발명자
/ 주소 |
- Aoyama,Jun
- Murata,Jun
- Arai,Norio
- Matsubara,Toshio
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출원인 / 주소 |
- Ebara Refrigeration Equipment & Systems Co., Ltd.
|
대리인 / 주소 |
Westerman, Hattori, Daniels & Adrian, LLP.
|
인용정보 |
피인용 횟수 :
1 인용 특허 :
3 |
초록
▼
The present invention provides a high-efficiency absorption refrigerating machine which can recover heat from a heat source and can efficiently recover heat from an internal cycle. The absorption refrigerating machine includes an evaporator, an absorber (A), a condenser (C), a high-temperature regen
The present invention provides a high-efficiency absorption refrigerating machine which can recover heat from a heat source and can efficiently recover heat from an internal cycle. The absorption refrigerating machine includes an evaporator, an absorber (A), a condenser (C), a high-temperature regenerator (GH), a low-temperature regenerator (GL), a low-temperature solution heat exchanger (LX), and solution paths and refrigerant paths by which these units are connected. The absorption refrigerating machine further comprises two branch solution paths branched from a solution supply path through which a dilute solution is introduced from the absorption (A) to the high-temperature regenerator (GH). On one of the branch solution paths, there is disposed a drain heat exchanger (DX) operable to perform heat exchange between the dilute solution in the branch solution path and an exhaust heat source which has heated the high-temperature regenerator (GH). On the other of the branch solution paths, there are disposed a first high-temperature solution heat exchanger (HX1) and a second high-temperature solution heat exchanger (HX2) operable to perform heat exchange between the dilute solution in the branch solution path and a concentrated solution heated and concentrated in the high-temperature regenerator (GH). The absorption refrigerating machine is configured such that the dilute solution flows through the first high-temperature solution heat exchanger (HX1) and the second high-temperature solution heat exchanger (HX2) in this order, and the concentrated solution discharged from the high-temperature regenerator flows through the second high-temperature solution heat exchanger (HX2) and the first high-temperature solution heat exchanger (HX1) in this order.
대표청구항
▼
The invention claimed is: 1. An absorption refrigerating machine comprising: an evaporator; an absorber; a condenser; a high-temperature regenerator; a low-temperature regenerator; a low-temperature solution heat exchanger; a solution path through which an absorption solution flows; a refrigerant p
The invention claimed is: 1. An absorption refrigerating machine comprising: an evaporator; an absorber; a condenser; a high-temperature regenerator; a low-temperature regenerator; a low-temperature solution heat exchanger; a solution path through which an absorption solution flows; a refrigerant path through which a refrigerant flows; a first branch solution path and a second branch solution path configured to divide a dilute solution to be introduced from said absorber to said high-temperature regenerator; a first high-temperature solution heat exchanger and a second high-temperature solution heat exchanger operable to perform heat exchange between the dilute solution in said first branch solution path and a concentrated solution heated and concentrated in said high-temperature regenerator; and a drain heat exchanger operable to perform heat exchange between the dilute solution in said second branch solution path and an exhaust heat source which has heated the dilute solution in said high-temperature regenerator, wherein the dilute solution in said first branch solution path flows through said first high-temperature solution heat exchanger and said second high-temperature solution heat exchanger in this order, and the concentrated solution discharged from said high-temperature regenerator flows through said second high-temperature solution heat exchanger and said first high-temperature solution heat exchanger in this order. 2. The absorption refrigerating machine according to claim 1, wherein the dilute solution to be supplied to said high-temperature regenerator flows along an outer portion of a heat-transfer member of said second high-temperature solution heat exchanger. 3. The absorption refrigerating machine according to claim 1, wherein said second high-temperature solution heat exchanger is constructed integrally with said high-temperature regenerator. 4. An absorption refrigerating machine comprising: an evaporator; an absorber; a condenser; a high-temperature regenerator; a low-temperature regenerator; a low-temperature solution heat exchanger; a solution path through which an absorption solution flows; a refrigerant path through which a refrigerant flows; a first branch solution path and a second branch solution path configured to divide a dilute solution to be introduced from said absorber to said high-temperature regenerator; a high-temperature solution heat exchanger operable to perform heat exchange between the dilute solution in said first branch solution path and a concentrated solution heated and concentrated in said high-temperature regenerator; and a first drain heat exchanger and a second drain heat exchanger operable to perform heat exchange between the dilute solution in said second branch solution path and an exhaust heat source which has heated the dilute solution in said high-temperature regenerator, wherein the dilute solution in said second branch solution path flows through said first drain heat exchanger and said second drain heat exchanger in this order, and the exhaust heat source discharged from said high-temperature regenerator flows through said second drain heat exchanger and said first drain heat exchanger in this order. 5. The absorption refrigerating machine according to claim 4, wherein the dilute solution to be supplied to said high-temperature regenerator flows along an outer portion of a heat-transfer member of said second drain heat exchanger. 6. The absorption refrigerating machine according to claim 4, wherein said second drain heat exchanger is constructed integrally with said high-temperature regenerator. 7. An absorption refrigerating machine comprising: an evaporator; an absorber; a condenser; a high-temperature regenerator; a low-temperature regenerator; a low-temperature solution heat exchanger; a solution path through which an absorption solution flows; a refrigerant path through which a refrigerant flows; a first branch solution path and a second branch solution path configured to divide a dilute solution to be introduced from said absorber to said high-temperature regenerator; a first high-temperature solution heat exchanger and a second high-temperature solution heat exchanger operable to perform heat exchange between the dilute solution in said first branch solution path and a concentrated solution heated and concentrated in said high-temperature regenerator; and a first drain heat exchanger and a second drain heat exchanger operable to perform heat exchange between the dilute solution in said second branch solution path and an exhaust heat source which has heated the dilute solution in said high-temperature regenerator, wherein the dilute solution in said first branch solution path flows through said first high-temperature solution heat exchanger and said second high-temperature solution heat exchanger in this order, the concentrated solution discharged from said high-temperature regenerator flows through said second high-temperature solution heat exchanger and said first high-temperature solution heat exchanger in this order, the dilute solution in said second branch solution path flows through said first drain heat exchanger and said second drain heat exchanger in this order, and the exhaust heat source discharged from said high-temperature regenerator flows through said second drain heat exchanger and said first drain heat exchanger in this order. 8. The absorption refrigerating machine according to claim 7, wherein the dilute solution to be supplied to said high-temperature regenerator flows along at least one of an outer portion of a heat-transfer member of said second high-temperature solution heat exchanger and an outer portion of a heat-transfer member of said second drain heat exchanger. 9. The absorption refrigerating machine according to claim 7, wherein at least one of said second high-temperature solution heat exchanger and said second drain heat exchanger is constructed integrally with said high-temperature regenerator. 10. An absorption refrigerating machine comprising: an evaporator; an absorber; a condenser; a high-temperature regenerator; a low-temperature regenerator; a low-temperature solution heat exchanger; a solution path through which an absorption solution flows; a refrigerant path through which a refrigerant flows; a first branch solution path and a second branch solution path configured to divide a dilute solution to be introduced from said absorber to said high-temperature regenerator; a recovery heat exchanger disposed on a solution path through which the dilute solution is introduced from said absorber to said low-temperature regenerator, said recovery heat exchanger being operable to perform heat exchange between the dilute solution in said solution path and a concentrated solution heated and concentrated in said high-temperature regenerator; a high-temperature solution heat exchanger operable to perform heat exchange between the dilute solution in said first branch solution path and the concentrated solution heated and concentrated in said high-temperature regenerator; and a drain heat exchanger operable to perform heat exchange between the dilute solution in said second branch solution path and an exhaust heat source which has heated the dilute solution in said high-temperature regenerator. 11. The absorption refrigerating machine according to claim 10, wherein said recovery heat exchanger is disposed adjacent to a group of heat-transfer pipes of said low-temperature regenerator, and is disposed in a casing of said low-temperature regenerator. 12. The absorption refrigerating machine according to claim 1, wherein a solution path, through which the dilute solution is discharged from said absorber, extends through a heat-receiving side of said low-temperature solution heat exchanger to a branch point of said first branch solution path and said second branch solution path. 13. The absorption refrigerating machine according to claim 1, wherein a solution path, which extends to said high-temperature regenerator, branches into said first branch solution path and said second branch solution path at a midpoint of a heat-receiving side of said low-temperature solution heat exchanger. 14. The absorption refrigerating machine according to claim 1, wherein each of said evaporator and said absorber has a multistage structure which operates at different pressure stages.
이 특허에 인용된 특허 (3)
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Yoda Hiroaki (Tsuchiura JPX) Machizawa Kenzi (Ibaraki JPX) Yamamoto Koji (Ibaraki JPX), Absorption heat pump and cogeneration system utilizing exhaust heat.
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Dodo, Satoshi; Tsubouchi, Kuniyoshi; Yasugahira, Norio; Arita, Hiroshi; Akatsu, Yasuaki; Hatamiya, Shigeo, Heat and electric power supply system and operation method thereof.
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Satoshi Dodo JP; Kuniyoshi Tsubouchi JP; Norio Yasugahira JP; Hiroshi Arita JP; Yasuaki Akatsu JP; Shigeo Hatamiya JP, Heat and electric power supply system and operation method thereof.
이 특허를 인용한 특허 (1)
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Mazumder, Indrajit; Saha, Rajarshi, Reduction of diluent nitrogen compressor power using vapor absorption chiller.
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