• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A tube inside passage height (Tr) is set within a range of 0.35-0.8 mm. Thereby, sum of radiation performance reduction due to pressure loss inside tube and radiation performance reduction due to air flow resistance is reduced, thereby attaining high radiation performance. Especially, when the tube inside passage height (Tr) is set within a range of 0.5-0.7 mm, the radiation performance is further improved.
    公开号:US20010004935A1
    申请号:US09/733,140
    申请日:2000-12-08
    公开日:2001-06-28
    发明作者:Ryouichi Sanada;Michiyasu Yamamoto;Yoshifumi Aki
    申请人:Denso Corp;
    IPC主号:F28D1-05391
    专利说明:
    [0001] This application is based on and incorporates herein by reference Japanese Patent Application No. Hei. 11-350719 filed on Dec. 9, 1999. [0001] BACKGROUND OF THE INVENTION
    [0002] 1. Field of the Invention [0002]
    [0003] The present invention relates to a refrigerant condenser, through which gas-liquid two phase refrigerant flows, suitable for use in a automotive air conditioner. [0003]
    [0004] 2. Description of Related Art [0004]
    [0005] U.S. Pat. No. 4,998,580 discloses a multi-flow type refrigerant condenser including a plurality of tubes and fins laminated between a pair of header tanks. In U.S. Pat. No. 4,998,580, equivalent diameter of a refrigerant passage inside tube is set within a particular range for improving the radiation performance of the multi-flow type refrigerant condenser. U.S. Pat. No. 4,932,469 discloses a rib formed on a plate of a tube. The rib protrudes toward the inside of the tube. U.S. Pat. No. 5,682,944, U.S. Pat. No. 6,003,592 and U.S. Pat. No. 5,730,212 disclose that a condensing length is set within a particular range. [0005]
    [0006] However, in these prior arts, only heat transfer efficiency inside the tube is considered. That is, neither air flow resistance nor pressure loss inside tube are considered for improving the radiation performance of the refrigerant condenser. [0006] SUMMARY OF THE INVENTION
    [0007] An object of the present invention is to improve a radiation performance while considering air-flow resistance and pressure loss inside tube. [0007]
    [0008] In the present invention, a state where an optimum radiation performance is attained is simulated while considering the air-flow resistance and the pressure loss inside tube. [0008]
    [0009] According to a first aspect of the present invention, a tube inside passage height (Tr) is set within a range of 0.35-0.8 mm. Thereby, sum of radiation performance reduction due to the pressure loss inside tube and radiation performance reduction due to the air flow resistance is reduced, thereby attaining high radiation performance. Especially, when the tube inside passage height (Tr) is set within a range of 0.5-0.7 mm, the radiation performance is further improved. [0009]
    [0010] According to a second aspect of the present invention, air flow opening ratio (Pr) is set in accordance with following formula expression, [0010]
    [0011] Here, Td is a dimension between an outer surface of the tube and a top of the refrigerant passage in the tube lamination direction. Pr is a ratio of tube height Th to tube pitch Tp (Th/Tp). Th is a height of the tube in the tube lamination direction. Tp is an interval between each of the adjacent tubes. Thereby, sum of radiation performance reduction due to the pressure loss inside tube and radiation performance reduction due to the air flow resistance is further reduced, thereby attaining much higher radiation performance. [0011] BRIEF DESCRIPTION OF THE DRAWINGS
    [0012] Additional objects and advantages of the present invention will be more readily apparent from the following detailed description of preferred embodiments thereof when taken together with the accompanying drawings in which: [0012]
    [0013] FIG. 1 is a front view showing a condenser of the present invention; [0013]
    [0014] FIG. 2 is a cross-sectional view taken along line II-II in FIG. 1; [0014]
    [0015] FIG. 3 is a graph showing a relation between fin height Fh and radiation performance (Td=0.1 mm); [0015]
    [0016] FIG. 4 is a graph showing a relation between fin height Fh and radiation performance (Td=0.2 mm); [0016]
    [0017] FIG. 5 is a graph showing a relation between fin height Fh and radiation performance (Td=0.3 mm); [0017]
    [0018] FIG. 6 is a graph showing a relation between fin height Fh and radiation performance (Td=0.4 mm); [0018]
    [0019] FIG. 7 is a graph showing a relation between tube inside passage height Tr and radiation performance; [0019]
    [0020] FIG. 8 is a graph showing a relation between air flow opening ration Pr and radiation performance (Td=0.1 mm); [0020]
    [0021] FIG. 9 is a graph showing a relation between air flow opening ration Pr and radiation performance (Td=0.2 mm); [0021]
    [0022] FIG. 10 is a graph showing a relation between air flow opening ration Pr and radiation performance (Td=0.3 mm); [0022]
    [0023] FIG. 11 is a graph showing a relation between air flow opening ration Pr and radiation performance (Td=0.4 mm); [0023]
    [0024] FIG. 12 is a graph showing a relation tube outer periphery thickness Td and air flow opening ratio Pr; and [0024]
    [0025] FIGS. [0025] 13A-13F are cross sectional view showing miscellaneous tubes according to modifications. DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
    [0026] FIG. 1 shows an entire structure of a refrigerant condenser [0026] 10 used for an automotive air conditioner. The condenser 10 cools and condenses high temperature and high pressure refrigerant discharged from a compressor (not illustrated) of a refrigerant cycle for the automotive air conditioner. The condenser 10 is disposed at the front most area, in front of an engine cooling radiator, in a vehicle engine compartment. Cooling air (external air) generated by a cooling fan commonly used for the engine cooling radiator cools the condenser 10.
    [0027] The condenser [0027] 10 includes first and second header tanks 11 and 12 located to have a predetermined distance therebetween. The first and second header tanks 11 and 12 substantially cylindrically extend in a vertical direction. A heat exchanging core portion 13 is disposed between the first and second header tanks 11 and 12.
    [0028] The condenser [0028] 10 in the present embodiment is a multi-flow type condenser. A plurality of aluminum flat tubes 14 are vertically laminated within the core portion 13. The refrigerant flows through the flat tubes 14 between the first and second header tanks 11 and 12. An aluminum corrugate fin 15 is provided between each of the tubes 14 to promote a heat-exchange between the refrigerant and the cooling air.
    [0029] As shown in FIG. 2, the flat tube [0029] 14 includes a plurality of circle refrigerant passages 141, and is made by extrusion. One end of the flat tube 14 connects with the first header tank 11, and the other end of the flat tube 14 connects with the second header tank 12. Therefore, the first tank 11 communicates with the second header tank 12 through the flat tube 14.
    [0030] A separator [0030] 16 is provided inside the first tank 11 to divide the inside of the first tank 11 into an upper chamber 17 and a lower chamber 18. The gas refrigerant discharged from the compressor flows into the upper chamber 17. The gas refrigerant flows through some of the flat tubes 14 communicating with the upper chamber 17, and flows into the second header tank 12. The refrigerant U-turns in the second header tank 12, and flows through the remaining flat tubes 14 and into the lower chamber 18. The gas refrigerant heat-exchanges with air passing through between each of flat tubes 14 to be cooled and condensed. In this way, the refrigerant is condensed to be gas-liquid two-phase refrigerant.
    [0031] Next, a radiation performance simulation result of the condenser [0031] 10 will be explained.
    [0032] The simulation was done under the following state; [0032]
    [0033] Core portion height H=300 mm, Core portion width W=600 mm, Fin pitch Fp=3 mm, Air flow speed at condenser inlet is 2 m/s, Air temperature at condenser inlet is 35° C., Refrigerant pressure at condenser inlet is 1.74 MPa (abs), Super heat at condenser inlet is 20° C., Dryness at condenser outlet is 0 (zero), Sub-cool at condenser outlet is 0° C. [0033]
    [0034] In this simulation, parameters are Tube height Th, Tube outer periphery thickness Td, and Fin height Fh. The tube height Th is a height of the flat tube [0034] 14 in the tube laminating direction. The tube outer periphery thickness Td is a tube laminating direction dimension between the outer surface of the flat tube 14 and the top of the refrigerant passage 141. The fin height Fh is a height of the corrugate fin 15 in the tube laminating direction. The simulation calculates a radiation amount of the condenser 10 while considering air low resistance and pressure loss inside the tube 14.
    [0035] 1. Tube inside passage height Tr Examination: [0035]
    [0036] FIGS. [0036] 3-6 are graphs showing relations between Fin height Fh and radiation performance at Td=0.1 mm, 0.2 mm, 0.3 mm, and 0.4 mm, respectively. The simulations were done by setting the Tube height Th every 0.2 mm within a range of 0.8-1.8 mm, and by setting Fin height Fh every 2 mm within a range of 4-12 mm. Here, according to the condenser 10 used for the simulation, Core portion height H=300 mm, Core portion width W=600 mm, Fin pitch Fp=3.2 mm, Tube height Th=1.7 mm, and Tube outer periphery thickness Fd=0.35 mm. As is understood from FIGS. 3-6, the radiation performance is the maximum when Fh is set around 4 mm regardless of Td and Th.
    [0037] FIG. 7 is a graph showing a relation between tube inside passage height Tr and radiation performance including the results of FIGS. [0037] 3-6 while paying attention to tube inside passage height Tr influencing on the air flow resistance and tube inside pressure loss. Here, the tube inside passage height Tr=Th−2×Td. That is, the tube inside passage height Tr is a height of the refrigerant passage 141 in the laminating direction of the flat tube 14.
    [0038] As is understood from FIG. 7, the radiation performance is high when Tr is set within a range of 0.35 mm-0.8 mm regardless of Td and Fh. Especially, radiation performance becomes the maximum when Tr is set within a range 0.5 mm-0.7 mm. [0038]
    [0039] Here, when Tr is set under 0.35 mm, radiation performance is abruptly reduced, because the cross sectional area of the refrigerant passage is reduced and the pressure loss inside passage increases. Likewise, when Tr is set over 0.8 mm, the radiation performance is reduced, because an air flow area is reduced due to an increasing of Tr and the air flow resistance is increased. Therefore, it is desired to set Tr within a range of 0.35 mm-0.8 mm to minimize sum of radiation performance reduction due to the pressure loss inside passage and radiation performance reduction due to the air flow resistance, for attaining high radiation performance. [0039]
    [0040] 2. Air flow opening ratio Examination: [0040]
    [0041] FIGS. [0041] 8-11 are graphs showing relations between Air flow opening ratio Pr and radiation performance at Td=0.1 mm, Td=0.2 mm, Td=0.3 mm, and Td=0.4 mm, respectively, which include the results of FIGS. 3-6 while paying attention to the Air flow opening ratio Pr influencing on the air flow resistance and the pressure loss inside passage. Here, the air flow opening ratio Pr=Th/Tp. The tube pitch Tp is an interval between each of the adjacent flat tubes 14 in the tube laminating direction.
    [0042] FIG. 12 is a graph showing a relation between Air flow opening ratio Pr and radiation performance, and showing an optimum Pr range. The optimum Pr range was obtained by attaining Pr range where radiation performance is high, at every tube outer periphery thickness Td (0.1 mm, 0.2 mm, 0.3 mm, 0.4 mm), based on FIGS. [0042] 8-11. The optimum Pr range is expressed by following formula expression. Here, the unit of tube outer periphery thickness Td is “mm”.
    [0043] Therefore, when the tube inside passage height Tr is set within a range 0.35 mm≦Tr≦0.8 mm (especially 0.5 mm-≦Tr≦0.7 mm) and the air flow opening ratio Pr is set in accordance with the formula expression, high radiation performance can be attained. [0043]
    [0044] (Modifications) [0044]
    [0045] According to the above-described embodiment, the flat tube [0045] 14 including circle refrigerant passages 141 is formed by extrusion. Alternatively, the present invention may be applied to miscellaneous tubes shown in FIGS. 13A-13F.
    [0046] A flat tube [0046] 14 shown in FIG. 13A includes a plurality of rectangular refrigerant passages 141, and is made by extrusion.
    [0047] A flat tube shown in FIG. 13B includes a plurality of projections [0047] 142 protruding toward the inside of the refrigerant passage 141, and is made by extrusion.
    [0048] A flat tube [0048] 14 shown in FIG. 13C is an electro-rasistance-welded tube made by cylindrically bending a metal rectangular plate and welding both facing ends of the bent metal plate each other, and includes a single refrigerant passage 141. An inner fin 143 is provided in the refrigerant passage 141.
    [0049] A flat tube [0049] 14 shown in FIG. 13D is made by bending a metal plate and brazing both ends to each other, and includes a single refrigerant passage 141. An inner fin 143 is provided in the refrigerant passage 141. Here, straight inner fin or offset inner fin may be used for the inner fins 143 shown in FIGS. 13C and 13D.
    [0050] A flat tube [0050] 14 shown in FIG. 13E includes a first plate 145 and a second plate 146 brazed to the first plate 145. The first plate 145 includes a plurality of roller-formed or press-formed ribs 144.
    [0051] A flat tube [0051] 14 shown in FIG. 13F is formed by bending a metal plate including a plurality of roller-formed or press-formed rib 144, and brazing both ends to each other. Here, straight rib extending in a refrigerant flow direction or cross rib extending diagonally with respect to the refrigerant flow direction may be used for the rib 114 shown in FIGS. 13E and 13F.
    权利要求:
    Claims (4)
    [1" id="US-20010004935-A1-CLM-00001] 1. A refrigerant condenser comprising:
    a plurality of tubes including refrigerant passages therein, said tubes being laminated;
    a fin disposed between each of the adjacent tubes; and
    header tanks disposed at both longitudinal ends of said tubes and communicating with said refrigerant passage, wherein
    said refrigerant passage defines a height thereof in a tube lamination direction as a tube inside passage height (Tr), and
    the tube inside passage height (Tr) is set within a range of 0.35-0.8 mm.
    [2" id="US-20010004935-A1-CLM-00002] 2. A refrigerant condenser according to
    claim 1 , wherein the tube inside passage height (Tr) is set within a range of 0.5-0.7 mm.
    [3" id="US-20010004935-A1-CLM-00003] 3. A refrigerant condenser according to
    claim 1 , wherein
    a dimension between an outer surface of said tube and a top of said refrigerant passage in the tube lamination direction is defined as tube outer periphery thickness Td,
    a height of said tube in the tube lamination direction is defined as tube height Th,
    an interval between each of the adjacent tubes is defined as tube pitch Tp,
    a ratio of the tube height Th to the tube pitch Tp (Th/Tp) is defined as air flow opening ratio (Pr), and
    the air flow opening ratio (Pr) is set in accordance with following formula expression,
    0.1429×Td 2+0.1343×Td+0.139≧Pr≧0.1429×Td 2+0.1343×Td+0.113.
    [4" id="US-20010004935-A1-CLM-00004] 4. A refrigerant condenser according to
    claim 1 , wherein
    a dimension between an outer surface of said tube and a top of said refrigerant passage in the tube lamination direction is defined as tube outer periphery thickness Td, and
    the tube outer periphery thickness Td is set less than 0.4 mm.
    类似技术:
    公开号 | 公开日 | 专利标题
    US6880627B2|2005-04-19|Refrigerant condenser used for automotive air conditioner
    US5289874A|1994-03-01|Heat exchanger with laterally displaced louvered fin sections
    JP3030036B2|2000-04-10|Double heat exchanger
    JP4078766B2|2008-04-23|Heat exchanger
    US20060237178A1|2006-10-26|Heat exchanger
    US20050061489A1|2005-03-24|Integrated multi-function return tube for combo heat exchangers
    US6339937B1|2002-01-22|Refrigerant evaporator
    US7992401B2|2011-08-09|Evaporator
    US7174953B2|2007-02-13|Stacking-type, multi-flow, heat exchanger
    US6209628B1|2001-04-03|Heat exchanger having several heat exchanging portions
    US5099913A|1992-03-31|Tubular plate pass for heat exchanger with high volume gas expansion side
    US6431264B2|2002-08-13|Heat exchanger with fluid-phase change
    EP1347259B1|2009-05-20|Heat exchanger
    WO2007099868A1|2007-09-07|Heat exchanger and integrated-type heat exchanger
    EP1195568B1|2014-02-12|Heat exchanger having several heat exchanging portions
    JP3922288B2|2007-05-30|Refrigerant condenser
    US20070056718A1|2007-03-15|Heat exchanger and duplex type heat exchanger
    US6276445B1|2001-08-21|Heat exchanger with heat insulating member disposed between condenser and radiator tanks
    US20050006072A1|2005-01-13|Heat exchanger
    JP2005055013A|2005-03-03|Heat exchanger
    JP2001324290A|2001-11-22|Refrigerant evaporator
    JP3446260B2|2003-09-16|Refrigerant condenser
    JP4106718B2|2008-06-25|Heat exchanger
    JP2903745B2|1999-06-14|Stacked refrigerant evaporator
    KR20170112659A|2017-10-12|Cooling module for hybrid vehicle
    同族专利:
    公开号 | 公开日
    US6880627B2|2005-04-19|
    US7140424B2|2006-11-28|
    JP2001165532A|2001-06-22|
    DE10060104A1|2001-06-13|
    US20050155747A1|2005-07-21|
    DE10060104B4|2007-12-06|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US4998580A|1985-10-02|1991-03-12|Modine Manufacturing Company|Condenser with small hydraulic diameter flow path|
    US4932469A|1989-10-04|1990-06-12|Blackstone Corporation|Automotive condenser|
    US5567493A|1992-11-05|1996-10-22|Nippondenso Co., Ltd.|Die for extrusion of multi-hole tube and multi-hole tube made with the die|
    US5682944A|1992-11-25|1997-11-04|Nippondenso Co., Ltd.|Refrigerant condenser|
    US5730212A|1992-11-25|1998-03-24|Nippondenso Co., Ltd.|Refrigerant condenser|
    US6003592A|1992-11-25|1999-12-21|Denso Corporation|Refrigerant condenser|
    US5553377A|1993-03-26|1996-09-10|Showa Aluminum Corporation|Method of making refrigerant tubes for heat exchangers|
    US5564497A|1994-11-04|1996-10-15|Nippondenso Co., Ltd.|Corrugated fin type head exchanger|
    US6339937B1|1999-06-04|2002-01-22|Denso Corporation|Refrigerant evaporator|US20040251013A1|2003-05-23|2004-12-16|Masaaki Kawakubo|Heat exchange tube having multiple fluid paths|
    US20050016716A1|2003-04-30|2005-01-27|Valeo, Inc.|Heat exchanger|
    WO2005003669A3|2003-06-25|2005-03-03|Valeo Inc|Heat exchanger|
    US20050194124A1|2004-02-13|2005-09-08|Behr Gmbh & Co. Kg|Heat exchanger, in particular oil cooler for a motor vehicle|
    WO2005091968A2|2004-02-26|2005-10-06|Modine Manufacturing Company|Compact radiator for an electronic device|
    WO2006128684A1|2005-06-01|2006-12-07|Hydrogen Research Aktiengesellschaft|Heating body|
    WO2006083449A3|2005-02-02|2007-03-22|Carrier Corp|Heat exchanger with fluid expansion in header|
    US20070131393A1|2005-12-14|2007-06-14|Showa Denko K.K.|Heat exchanger|
    US20080041092A1|2005-02-02|2008-02-21|Gorbounov Mikhail B|Multi-Channel Flat-Tube Heat Exchanger|
    US20080093062A1|2005-02-02|2008-04-24|Carrier Corporation|Mini-Channel Heat Exchanger Header|
    US20080110606A1|2005-02-02|2008-05-15|Carrier Corporation|Heat Exchanger With Fluid Expansion In Header|
    US20080110608A1|2005-02-02|2008-05-15|Carrier Corporation|Mini-Channel Heat Exchanger With Reduced Dimension Header|
    US20080202733A1|2007-02-23|2008-08-28|Samuelson David E|Bend relief spacer|
    US20080251245A1|2005-02-02|2008-10-16|Carrier Corporation|Mini-Channel Heat Exchanger With Multi-Stage Expansion Device|
    US20080289806A1|2005-02-02|2008-11-27|Carrier Corporation|Heat Exchanger with Perforated Plate in Header|
    US20090065183A1|2007-09-06|2009-03-12|Showa Denko K.K.|Flat heat transfer tube|
    WO2009035440A1|2007-09-14|2009-03-19|Carrier Corporation|Methods and systems for utilizing a mini-channel heat-exchanger device in a refrigeration circuit|
    US20100270010A1|2009-04-28|2010-10-28|Abb Research Ltd|Twisted tube thermosyphon|
    US20100277870A1|2009-04-29|2010-11-04|Abb Research Ltd|Multi-row thermosyphon heat exchanger|
    CN102345995A|2010-08-03|2012-02-08|株式会社电装|Condenser|
    EP2613116A1|2010-09-01|2013-07-10|Mitsubishi Heavy Industries, Ltd.|Heat exchanger and vehicle air conditioner with same|
    US20150153116A1|2012-07-27|2015-06-04|Kyocera Corporation|Flow path member, and heat exchanger and semiconductor manufacturing device using same|
    ES2678468A1|2017-02-10|2018-08-13|Radiadores Ordoñez, S.A.|RADIATOR FOR VEHICLE |
    US20180313610A1|2015-10-29|2018-11-01|Uacj Corporation|Extruded aluminum flat multi-hole tube and heat exchanger|
    EP3492853A1|2017-11-29|2019-06-05|Lennox Industries Inc.|Microchannel heat exchanger|
    US10473401B2|2015-07-28|2019-11-12|Sanden Holdings Corporation|Heat exchanger|
    CN110869690A|2017-08-21|2020-03-06|株式会社Uacj|Condenser|GB2058324B|1979-09-14|1983-11-02|Hisaka Works Ltd|Surface condenser|
    US5372188A|1985-10-02|1994-12-13|Modine Manufacturing Co.|Heat exchanger for a refrigerant system|
    DE3673780D1|1985-12-16|1990-10-04|Akzo Nv|CONNECTING HOLLOW PROFILE BODIES TO A PLASTIC PLATE, ESPECIALLY FOR THE PRODUCTION OF HEAT EXCHANGERS.|
    US4825941B1|1986-07-29|1997-07-01|Showa Aluminum Corp|Condenser for use in a car cooling system|
    JPH0345302B2|1986-11-04|1991-07-10|Showa Aluminium Co Ltd||
    JPH03102193A|1989-09-13|1991-04-26|Showa Alum Corp|Condenser|
    JPH03204595A|1989-12-28|1991-09-06|Showa Alum Corp|Condenser|
    DE4201791A1|1991-06-20|1993-07-29|Thermal Waerme Kaelte Klima|FLAT TUBES FOR INSTALLATION IN A FLAT TUBE HEAT EXCHANGER AND METHOD FOR SEPARATING THE FLAT TUBES|
    US5307870A|1991-12-09|1994-05-03|Nippondenso Co., Ltd.|Heat exchanger|
    US5256692A|1992-01-07|1993-10-26|E. R. Squibb & Sons, Inc.|Sulfur-containing HMG-COA reductase inhibitors|
    JP3459271B2|1992-01-17|2003-10-20|株式会社デンソー|Heater core of automotive air conditioner|
    US5329988A|1993-05-28|1994-07-19|The Allen Group, Inc.|Heat exchanger|
    US5771964A|1996-04-19|1998-06-30|Heatcraft Inc.|Heat exchanger with relatively flat fluid conduits|
    JP3699202B2|1996-05-16|2005-09-28|昭和電工株式会社|Aluminum heat exchanger with excellent corrosion resistance and method for producing the same|
    JPH1144498A|1997-05-30|1999-02-16|Showa Alum Corp|Flat porous tube for heat exchanger and heat exchanger using the tube|
    JPH11230686A|1998-02-16|1999-08-27|Denso Corp|Heat exchanger|
    JP2001165532A|1999-12-09|2001-06-22|Denso Corp|Refrigerant condenser|JP2001165532A|1999-12-09|2001-06-22|Denso Corp|Refrigerant condenser|
    US7093474B2|2001-10-23|2006-08-22|Showa Denko K.K.|Extrusion die for manufacturing tube with small hollow portions, mandrel used for said extrusion die, and multi-hollowed tube manu-factured by using said extrusion die|
    CN1228591C|2002-07-12|2005-11-23|株式会社电装|Heat exchanger for cooling air|
    KR20050067168A|2002-10-02|2005-06-30|쇼와 덴코 가부시키가이샤|Heat exchanging tube and heat exchanger|
    JP2005188849A|2003-12-26|2005-07-14|Zexel Valeo Climate Control Corp|Heat exchanger|
    WO2005073655A1|2004-01-29|2005-08-11|Calsonic Kansei Corporation|Heat exchanger and air-conditioning system employing same|
    US7281387B2|2004-04-29|2007-10-16|Carrier Commercial Refrigeration Inc.|Foul-resistant condenser using microchannel tubing|
    EP1762804A1|2005-09-12|2007-03-14|Frape Behr S.A.|Refrigerant condenser|
    EP1979698A2|2006-01-19|2008-10-15|Modine Manufacturing Company|Flat tube, flat tube heat exchanger, and method of manufacturing same|
    US20070169922A1|2006-01-24|2007-07-26|Pautler Donald R|Microchannel, flat tube heat exchanger with bent tube configuration|
    WO2007104580A2|2006-03-16|2007-09-20|Behr Gmbh & Co. Kg|Heat exchanger for a motor vehicle|
    JP4898300B2|2006-05-30|2012-03-14|昭和電工株式会社|Evaporator|
    US20090038562A1|2006-12-18|2009-02-12|Halla Climate Control Corp.|Cooling system for a vehicle|
    US20080142190A1|2006-12-18|2008-06-19|Halla Climate Control Corp.|Heat exchanger for a vehicle|
    US20080277095A1|2007-05-07|2008-11-13|Kelvin Zhai|Heat exchanger assembly|
    DE102007033177A1|2007-07-17|2009-01-22|Modine Manufacturing Co., Racine|Coolant radiator|
    CN101158525A|2007-09-11|2008-04-09|东莞高宝铝材制品厂有限公司|Condensator and heat radiation net of integrated molding fin type aluminium alloy compound material seamless micropore heat radiating fin|
    US20090087604A1|2007-09-27|2009-04-02|Graeme Stewart|Extruded tube for use in heat exchanger|
    DE102008062704A1|2008-01-10|2009-08-27|Behr Gmbh & Co. Kg|Extruded tube for a heat exchanger|
    FR2943775B1|2009-03-24|2012-07-13|Valeo Systemes Thermiques|STORAGE EXCHANGER HAVING STORER MATERIAL AND AIR CONDITIONING LOOP OR COOLING CIRCUIT COMPRISING SUCH EXCHANGER.|
    FR2963418B1|2010-07-28|2014-12-26|Muller & Cie Soc|HEAT PUMP EXCHANGER|
    WO2012035668A1|2010-09-14|2012-03-22|グリーンアース株式会社|Heat pump cop improving device|
    JP5858478B2|2012-09-04|2016-02-10|シャープ株式会社|Parallel flow type heat exchanger and air conditioner equipped with the same|
    US20140299303A1|2013-04-04|2014-10-09|Hamilton Sundstrand Corporation|Cooling tube included in aircraft heat exchanger|
    US20150192371A1|2014-01-07|2015-07-09|Trane International Inc.|Charge Tolerant Microchannel Heat Exchanger|
    EP3009779B1|2014-10-15|2019-05-15|VALEO AUTOSYSTEMY Sp. Z. o.o.|A tube of the gas cooler for the condenser|
    EP3239640A4|2014-12-26|2018-09-26|Mitsubishi Electric Corporation|Refrigeration cycle apparatus|
    DE102017201081A1|2016-01-25|2017-07-27|Hanon Systems|Pipe for a heat exchanger|
    CN106196747A|2016-06-30|2016-12-07|浙江龙泉凯利达汽车空调有限公司|A kind of heat absorption plate core structure condenser and processing technology thereof|
    FR3058210A1|2016-10-27|2018-05-04|Valeo Systemes Thermiques|HEAT EXCHANGER|
    FR3060723B1|2016-12-19|2019-05-17|Valeo Systemes Thermiques|GAS COOLER|
    FR3062467B1|2017-01-31|2019-08-16|Valeo Systemes Thermiques|EVAPORATOR FOR AIR CONDITIONING INSTALLATION|
    法律状态:
    2000-12-08| AS| Assignment|Owner name: DENSO CORPORATION, JAPAN Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:SANADA, RYOUICHI;YAMAMOTO, MICHIYASU;AKI, YOSHIFUMI;REEL/FRAME:011351/0527;SIGNING DATES FROM 20001130 TO 20001207 |
    2005-03-30| STCF| Information on status: patent grant|Free format text: PATENTED CASE |
    2008-09-24| FPAY| Fee payment|Year of fee payment: 4 |
    2012-09-19| FPAY| Fee payment|Year of fee payment: 8 |
    2016-10-10| FPAY| Fee payment|Year of fee payment: 12 |
    优先权:
    申请号 | 申请日 | 专利标题
    JP35071999A|JP2001165532A|1999-12-09|1999-12-09|Refrigerant condenser|
    JP11-350719||1999-12-09||US11/079,259| US7140424B2|1999-12-09|2005-03-14|Refrigerant condenser used for automotive air conditioner|
    [返回顶部]