• 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 multichannel flat tube for a heat exchanger has a plurality of parallel flow channels aligned in a row, side by side, along a transverse axis of the tube. At least the inner flow channels have oval cross-sections, and major semiaxes of the inner flow channels are inclined relative to the transverse axis of the tube at an acute angle. The flat tube can be designed for high operating pressures with relatively low weight and relatively high heat exchange capability. The construction may be used, for example, in CO2 air conditioners in motor vehicles.
    公开号:US20010004014A1
    申请号:US09/775,817
    申请日:2001-02-05
    公开日:2001-06-21
    发明作者:Bernd Dienhart;Hans-Joachim Kraub;Hagen Mittelstrab;Roland Schirrmacher;Karl-Heinz Staffa;Christoph Walter
    申请人:Behr GmbH and Co KG;
    IPC主号:F28F1-022
    专利说明:
    [0001] This application claims the priority of German application 198 45 336.1, filed Oct. 1, 1998, the disclosure of which is expressly incorporated by reference herein, and is a continuation-in-part of U.S. patent application Serial No. 09/411,158, filed Oct. 1, 1999, the disclosure of which is also expressly incorporated by reference herein. [0001] BACKGROUND AND SUMMARY OF THE INVENTION
    [0002] The present invention relates to a multichannel flat tube for a heat exchanger, having a plurality of parallel flow channels located side by side in the transverse direction of the tube. [0002]
    [0003] A flat tube of this kind for use in a condenser of a cooling or air conditioning system is known from European patent EP 0 219 974 B1, with the parallel flow channels in the flat tube being formed by a corrugated insert that is placed in the interior of the originally hollow tube made with one channel, and brazed fluid-tight at the points where it contacts the inside wall of the tube. In this manner, flow channels located side by side are produced with a triangular cross-section matching the cross-section of the corrugated insert. The flat tube is designed for use with R[0003] 12 coolant and similar coolants, in which maximum operating pressures of approximately 20 bars typically occur. In one typical example, the tube wall thickness is 0.381 mm and the extent of the tube in the vertical direction is 1.91 mm. U.S. Pat. No. 5,372,188 teaches, as an alternative to installing a corrugated insert, the manufacture of flat tubes, with a row of channels with triangular cross-sections, from an extruded profile.
    [0004] In offenlegungsschrift DE 38 43 305 A1 and U.S. Pat. Nos. 3,416,605, and 5,036,909, flat tubes with a plurality of flow channels located side by side with rectangular cross-sections are disclosed, with projections to increase the surface area possibly being provided on the edges of the channels. [0004]
    [0005] An application that has recently gained in significance is heat exchangers for air conditioners, especially in motor vehicles that use coolant R-744, i.e. carbon dioxide. In this case, heat exchanger structures made of rectilinear or serpentine flat tubes are required which reliably withstand operating pressures above 100 bars. Although extruded multichannel flat tubes with flow channels having circular cross-sections and conventional flat non-profiled broad-sided tube outer surfaces have been considered for this application, it turns out that the heat exchange efficiency of these flat tubes requires improvement because of the relatively small heat-transmitting surfaces. The tubes are also relatively heavy for a given heat exchange efficiency. [0005]
    [0006] The technical problem to be solved by the invention is to provide a multichannel flat tube of the type recited at the outset that is suitable for high-pressure applications with operating pressures of more than 100 bars, which is relatively light, and which provides relatively high heat exchange efficiency with a slight pressure drop in the coolant. [0006]
    [0007] One disclosed manner by which this problem is solved is by providing a particularly constructed multichannel flat tube with flow channels with oval cross-sections and/or a corrugated external tube contour that matches the flow channels so that the flat tube is thinner in the vertical direction of the tube between each pair of flow channels than in the area of each flow channel. It turns out that the flat tube can be designed in this way so that, firstly, a relatively high heat exchange surface is available and, secondly, the remaining wall thicknesses are sufficient to provide the bursting strength required of the tube. The multichannel flat tube thus designed exhibits satisfactory heat exchange efficiency in terms of both volume and weight, with a relatively slight pressure drop in the coolant and a low weight. In particular, the multichannel that flat tube can be used for evaporators in condensers or gas coolers as well as internal heat exchangers in CO[0007] 2 vehicle air conditioning systems. The multichannel flat tube can preferably be manufactured as an extruded flat tube, with the desired oval cross-sectional shape of the individual channels being produced by an extrusion process using suitably shaped dies.
    [0008] According to one feature, the flow channels are oriented in a specific fashion, depending on the application, so that their major semiaxes lie perpendicularly or parallel to the transverse axis of the tube or are inclined at a specific acute angle relative to this axis. [0008]
    [0009] According to another feature, the multichannel flat tube is designed so that the ratio of the major to the minor semiaxes of its oval flow channels lies between the values of 1 and 2, the ratio of the material cross-sectional area to the cross-sectional area through which flow occurs is between 1.4 and 4.5, in the case of the minor semiaxis of the respective flow channel that lies parallel to the transverse axis of the tube, the ratio of twice the value of the minor semiaxis to the period length of the flow channel row is between 0.4 and 0.9, and/or the ratio of twice the value of the major semiaxis to the flat tube thickness is between 0.4 and 0.8. These value ranges are especially favorable for achieving a high heat exchange efficiency on the one hand and a high bursting strength with the lowest possible weight on the other. [0009]
    [0010] According to yet another feature, the channel edges in the circumferential direction have a path that is smooth and in the shape of an arc or a path that is corrugated or polygonal, the oval cross-section formed by a polygon with at least five, and preferably many more than five, corners. The corrugated or polygonal irregular surface contour, depending on the application, can have advantages from a manufacturing standpoint, especially advantages relating to flow behavior and heat exchange capability in addition to resistance to pressure. [0010]
    [0011] In one preferred embodiment of the invention, a multichannel flat tube for a heat exchanger has a plurality of parallel flow channels aligned in a row, side by side, along a transverse axis of the tube. At least the inner flow channels have oval cross-sections, and major semiaxes of the inner flow channels are inclined relative to the transverse axis of the tube at an acute angle. The acute angle is preferably about 45°, and each outermost flow channel of the plurality of flow channels preferably has a circular cross-section. [0011]
    [0012] Most preferably, in this particularly embodiment, a ratio of the major semiaxes lengths to the minor semiaxes lengths of the flow channels which have oval cross-sections is between 1.2 and 1.4, a ratio of material cross-sectional areas to cross-sectional areas of the flat tube through which flow can occur is between 1.0 and 4.0, a ratio of twice the value of each minor semiaxis length to a periodicity length of the row of flow channels is between 0.5 and 0.7, and a ratio of twice the value of each major semiaxis length to the tube thickness is between 0.6 and 0.8. Oval cross-sectional edges of the flow channels can be corrugated or can be formed of individual linear sections that form a polygon with at least five corners. [0012] BRIEF DESCRIPTION OF THE DRAWINGS
    [0013] Advantageous embodiments of the invention are shown in the drawings and will be described below. [0013]
    [0014] FIG. 1 is a partial cross-sectional view of a multichannel flat tube with oval flow channels having major semiaxes which run perpendicularly to the transverse axis of the tube; [0014]
    [0015] FIG. 2 is a partial cross-sectional view of a multichannel flat tube with oval flow channels having major semiaxes which run at an angle to the transverse axis of the tube; [0015]
    [0016] FIG. 3 is a partial cross-sectional view of a multichannel flat tube with oval flow channels having major semiaxes which run parallel to the transverse axis of the tube; [0016]
    [0017] FIG. 4 is a partial cross-sectional view of a multichannel flat tube with flow channels with a circular cross-section and matching external surfaces of the tube as well as accordingly shaped corrugated ribs; and [0017]
    [0018] FIG. 5 is a partial cross-sectional view of a multichannel flat tube similar to that of FIG. 2 but with each outermost flow channel having a circular cross-section. [0018] DESCRIPTION OF THE PREFERRED EMBODIMENTS
    [0019] A left area of a cross-section of the multichannel flat tube [0019] 1 is shown in FIG. 1. The multichannel flat tube incorporates a number of parallel flow channels 2, which are arranged side by side in the cross-sectional direction y and are separated from one another in a row, and have an oval, essentially elliptical, cross-sectional shape. The flow channels 2 are offset and parallel, and are oriented so that the major semiaxis a of their oval cross-sections runs perpendicularly to the transverse direction y of the tube and hence parallel to the vertical direction z of the tube, while the minor semiaxis b lies parallel to the transverse direction y of the tube in a central lengthwise plane 3 of the flat tube 1.
    [0020] The dimensioning of flat tube [0020] 1, especially of its oval flow channels 2 on the one hand and the tubular bodies 4 surrounding them on the other hand, is chosen so that the flat tube 1 firstly meets the bursting strength requirements imposed on heat exchangers for CO2 air conditioners in motor vehicles and secondly achieves a low weight and a high heat exchange efficiency. For this purpose, the ratio a/b of the major semiaxis a to the minor semiaxis b of the channel cross-section is chosen in the range between 1 and 2, while the ratio of the major diameter 2 a of the channel cross-section to the tube thickness h, in other words to its length in the vertical direction z of the tube, is between 0.4 and 0.8. The ratio of the minor diameter 2 b of the channel cross-section to the periodicity length or division T, in other words the distance between the midpoints of the cross-sections of each pair of adjacent flow channels 2, is chosen to be between 0.4 and 0.9. In absolute numbers, the tube thickness is typically between 1.5 mm and 4.2 mm, the major semiaxis a typically measures between 0.4 mm and 1.2 mm, the minor semiaxis b measures between 0.4 mm and 1 mm, and the division T is between 1 mm and 3.5 mm. The hydraulic diameter of the individual flow channels 2 or, in other words, the ratio of the multiple of the cross-sectional area to the internal circumference, is typically between 0.9 mm and 2.0 mm. For the abovementioned dimensions, the ratio of the material cross-section, in other words the cross-section of the tube body, to the cross-section through which flow can occur freely, in other words the total cross-sectional area of all the flow channels 2, is between 1.4 and 4.5. The wall thickness of the tube 1 is usually approximately between 0.2 mm and 0.6 mm, and even slightly more than 1 mm in individual cases.
    [0021] When so designed the multichannel flat tube [0021] 1 is especially suitable as a straight tube for a parallel flow heat exchanger or as a serpentine tube for heat exchangers of the serpentine type. The multichannel flat tube 1 is particularly suitable for use in evaporators and gas coolers such as the condensers in CO2 air conditioners. It turns out that multichannel flat tubes with such dimensions can reliably withstand the operating pressures of CO2 air conditioners, which can reach values of more than 100 bars, and at the same time are relatively light in weight and offer comparatively high heat exchange efficiency.
    [0022] FIGS. 2 and 3 show variations on the flat tube in FIG. 1 with a different orientation of the individual flow channels. In the multichannel flat tube [0022] 5 shown in FIG. 2, a row of parallel flow channels 2 a are spaced apart in a row and located next to one another in the transverse direction 3 a of the tube. Each channel is provided with an oval cross-section in which the major semiaxis a runs diagonally to the transverse direction of the tube 3 a. In other words a specific angle α is enclosed between the transverse direction and the major semiaxis a that is larger than 0 degrees and smaller than 90 degrees. Comparable dimensioning possibilities are obtained for both this multichannel flat tube 5 as well, and the case flat tube 1 in FIG. 1. The flat tube 5 shown in FIG. 2 also exhibits essentially the same advantages regarding high bursting strength, heat exchange efficiency, and low weight.
    [0023] In the multichannel flat tube [0023] 6 shown in FIG. 3, a plurality of parallel flow channels 2 b is located so that the channels are spaced apart in a row in the transverse direction 3 b of the tube and lies side by side. In this case, however, each channel is oriented with the major semiaxis a parallel to the transverse direction 3 b of the tube. This version of the flat tube is especially suited for applications for which a flat tube with a limited thickness is desirable. In addition, it turns out, as is evident to the individual skilled in the art; that in the case of this flat tube 6, the dimensioning possibilities mentioned above in connection with flat tube 1 in FIG. 1 also apply to this flat tube 6, with the roles of the major semiaxis a and the minor semiaxis b relative to flat tube 1 in FIG. 1 being reversed; in the flat tube 6 in FIG. 3, the major semiaxis a corresponds in position to the minor semiaxis b of the flat tube 1 in FIG. 1 and the position of the minor semiaxis b corresponds to that of the major semiaxis a of flat tube 1 in FIG. 1.
    [0024] FIG. 4 shows a multichannel flat tube [0024] 7 with flow channels 2 c arranged in a row in the transverse direction 3 c of the tube, spaced apart from one another, and located side by side. These channels have circular cross-sections. This channel shape is favorable for high pressure strength. In order to obtain a high heat exchange capability as well, this flat tube has a particular profile of the outer surfaces 8 a, 8 b of the two wide sides of the flat tube that corresponds to the arrangement of flow channels 2 c. This profile of the outer surfaces 8 a, 8 b is in the shape of a sine wave in the cross-section shown, with the periodicity corresponding to the arrangement of the flow channels being chosen such that flat tube 7 has a maximum thickness hmax in the area of each flow channel and a minimum thickness hmin in the middle between each pair of individual flow channels. By this measure, the surface of the tube is increased and, at the same time, the distance thereof from the internal flow channels 2 c as compared with a flat design of the tube outer surface is reduced, improving the heat exchange efficiency. At the same time, a sufficient wall thickness remains between flow channels 2 c and the outer surfaces 8 a, 8 b of the tube to withstand operating pressures up to 150 bars, so that this flat tube 7, in the same way as flat tube A in FIGS. 1 to 3, can be used for heat exchangers in CO2 air conditioners.
    [0025] To construct a tube/fin block like that conventionally used in heat exchangers in air conditioners, using the externally profiled flat tube type [0025] 7 according to FIG. 4, whether they are straight flat tubes or serpentine flat tubes, a suitably contoured corrugated rib type 9 can be provided as shown in FIG. 4. The corrugated rib 9 used is provided over its entire length or at least in the area of its peaks in the transverse direction with a corrugated contour 9 a with a periodicity which corresponds to that of the corrugated tube exteriors 8 a, 8 b. In this manner, as can be seen from FIG. 4, the peaks of the cross-sectional contour 9 a of the corrugated fin peak areas fit into the valleys of the respective adjoining flat tube 7. This prevents the corrugated ribs 9 inserted between the flat tube layers of the tube/fin block from sliding away from tube 7 even before they are permanently connected, for example by hard brazing. This facilitates the assembly of the tube/fin block, especially in those cases in which the entire block with the flat tubes 7 and corrugated fins 9 is
    [0026] initially installed loosely between the tube layers and only later is connected to form a solid block structure in a single brazing process. In addition, the interlocking of the transverse wave structures of the flat tube [0026] 7 on the one hand and the corrugated fins 9 on the other provides favorable heat exchange between the two elements and thus improves the heat exchange efficiency of the tube/fin block.
    [0027] Of course, if necessary, the flat tubes in FIGS. [0027] 1 to 3 can also be provided with a corrugated external transverse contour such as that of the flat tube 7 in FIG. 4 and can be provided with suitably transversely contoured corrugated fins corresponding to the corrugated fin type 9 in FIG. 4 for constructing the tube/fin block together with such transversely contoured flat tubes, with the same advantages as mentioned above in connection with the embodiment shown in FIG. 4. In addition, it is possible, in all cases, to have a corrugated or polygonal circumferential channel edge with at least five corners instead of providing the indicated smoothly arched pattern of the circumferential edges of the channels. In other words the channel cross-section can have a corrugated oval edge or oval polygonal design made of linear segments adjoining one another. These variations then have advantages from the standpoint of manufacturing techniques or advantages regarding heat exchange efficiency and burst strength.
    [0028] FIG. 5 illustrates an embodiment in which the major semiaxes at least of the inner flow channels are inclined relative to the transverse axis or direction [0028] 3 d of the tube at an acute angle α (with 0<α<90°). The two outer flow channels, i.e. the leftmost flow channel 2 e and the corresponding rightmost flow channel (not shown), are formed with circular cross-sections. The other, inner flow channels 2 d are formed with oval cross-sections and inclined major semiaxes in a manner similar to the flow channels 2 a of FIG. 2.
    [0029] Calculations have led to the conclusion that, starting with the embodiment shown in FIG. 1, in which each of the major semiaxes is inclined relative to the transverse axis of the tube by an angle α of 90°, decreasing this inclination α increases the free cross-sectional area of the flow channels up to 15% with a simultaneous reduction in weight of the multichannel flat tube. It turns out that, in this respect, an optimal angle of about α=45° exists. One condition which always has to be satisfied is that a tube wall thickness must be sufficient to withstand the pressure of the medium directed through the flow channels. This pressure can be quite high, for example, in a cooling or air-conditioning system using CO[0029] 2 as a coolant. Inclining the oval cross-sections of the flow channels results in a maximum inner flow cross-section and minimal tube weight while retaining the ability of the tube to withstand a given maximum pressure.
    [0030] Providing the two outer channels with a circular cross-section, while keeping the inclined oval cross-sections for the other channels, increases rupture and bursting strength. This is of particular importance in embodiments in which the tube is bent, e.g. by 180° (as used, e.g., for heat exchanger arrangements in which both ends of each of a plurality of multichannel flat tubes arranged in a tube block are positioned at one block side) . Such bending of the tubes often weakens the wall thickness between the respective outer channel and the outside. This makes it preferable to use circular rather than oval outer channels, while for the other, inner, channels, the advantages of having oval, inclined channels are maintained. [0030]
    [0031] Referring again to FIG. 5, preferably, the acute angle is about 45°, a ratio of the length “a” of the major semiaxes to the length “b” of the minor semiaxes of the flow channels [0031] 2 d which have oval cross-sections is between 1.2 and 1.4, a ratio of material cross-sectional areas to cross-sectional areas of the flat tube through which flow can occur (i.e., the areas of the channels 2 d and 2 e) is between 1.0 and 4.0, a ratio of twice the length “b” of the minor semiaxes to a periodicity length T of the row of flow channels is between 0.5 and 0.7, and a ratio of twice the length “a” of the major semiaxes to the tube thickness “h” is between 0.6 and 0.8. Oval cross-sectional edges of the flow channels can be either corrugated or formed of individual linear sections that form a polygon with at least five corners.
    [0032] The foregoing disclosure has been set forth merely to illustrate the invention and is not intended to be limiting. Since modifications of the disclosed embodiments incorporating the spirit and substance of the invention may occur to persons skilled in the art, the invention should be construed to include everything within the scope of the appended claims and equivalents thereof. [0032]
    权利要求:
    Claims (6)
    [1" id="US-20010004014-A1-CLM-00001] 1. Multichannel flat tube for a heat exchanger, with a plurality of parallel flow channels aligned in a row side by side along a transverse axis of the tube, wherein at least inner flow channels have oval cross-sections, major semiaxes of the inner flow channels being inclined relative to the transverse axis of the tube at an acute angle.
    [2" id="US-20010004014-A1-CLM-00002] 2. Multichannel flat tube according to
    claim 1 , wherein the acute angle is about 45°.
    [3" id="US-20010004014-A1-CLM-00003] 3. Multichannel flat tube according to
    claim 1 , wherein each outermost flow channel of said plurality of flow channels has a circular cross-section.
    [4" id="US-20010004014-A1-CLM-00004] 4. Multichannel flat tube according to
    claim 1 , wherein a ratio of the major semiaxes to minor semiaxes of the flow channels which have oval cross-sections is between 1.2 and 1.4, a ratio of material cross-sectional areas to cross-sectional areas of the flat tube through which flow can occur is between 1.0 and 4.0, a ratio of twice the value of the minor semiaxes to a periodicity length of the row of flow channels is between 0.5 and 0.7, and a ratio of twice the value of the major semiaxes to the tube thickness is between 0.6 and 0.8.
    [5" id="US-20010004014-A1-CLM-00005] 5. Multichannel flat tube according to
    claim 1 , wherein oval cross-sectional edges of the flow channels are made corrugated.
    [6" id="US-20010004014-A1-CLM-00006] 6. Multichannel flat tube according to
    claim 1 , wherein oval cross-sectional edges of the flow channels are formed of individual linear sections that form a polygon with at least five corners.
    类似技术:
    公开号 | 公开日 | 专利标题
    US6357522B2|2002-03-19|Multi-channel flat tube
    US6964296B2|2005-11-15|Heat exchanger
    US6732789B2|2004-05-11|Heat exchanger for CO2 refrigerant
    US6523603B2|2003-02-25|Double heat exchanger with condenser and radiator
    US7059394B2|2006-06-13|Heat exchanger
    US5722485A|1998-03-03|Louvered fin heat exchanger
    US20070144721A1|2007-06-28|Heat exchanger
    KR20150029728A|2015-03-18|Serpentine heat exchanger for an air conditioner
    US9593889B2|2017-03-14|Heat exchanger construction
    AU2003272090A1|2004-04-23|Heat exchanging tube and heat exchanger
    US5404942A|1995-04-11|Heat exchanger and method of making the same
    US20070204983A1|2007-09-06|Heat Exchanger
    KR101415738B1|2014-07-09|Liquid supercooling system
    US20170211892A1|2017-07-27|Tube for heat exchanger
    US5915467A|1999-06-29|Heat transfer tube with grooves in inner surface of tube
    JP2006078163A|2006-03-23|Flat tube, plate body for manufacturing flat tube, and heat exchanger
    AU1373000A|2000-04-26|Regulating device for a coolant circuit of an air conditioning system
    JP2000018867A|2000-01-18|Tube material for heat exchanger and heat exchanger
    US6739387B1|2004-05-25|Heat exchanger tubing and heat exchanger assembly using said tubing
    US6854511B2|2005-02-15|Heat exchanger
    US20030102112A1|2003-06-05|Flattened tube heat exchanger made from micro-channel tubing
    US20020011332A1|2002-01-31|Refrigerant tube for heat exchangers
    JPH07260393A|1995-10-13|Header for heat exchanger and tank structure
    EP1608928B1|2010-09-29|Method for providing flat tube designs for an automotive heat exchanger
    EP2941610B1|2018-03-28|Tubing element for a heat exchanger means
    同族专利:
    公开号 | 公开日
    JP4347961B2|2009-10-21|
    JP2000111290A|2000-04-18|
    EP0990828A2|2000-04-05|
    CA2312149A1|2000-04-13|
    US6357522B2|2002-03-19|
    EP0990828B1|2003-05-14|
    WO2000020807A2|2000-04-13|
    DE59905540D1|2003-06-18|
    DE19845336A1|2000-04-06|
    EP0990828A3|2000-07-19|
    ES2199510T3|2004-02-16|
    AU1502800A|2000-04-26|
    WO2000020807A3|2000-09-21|
    AT240474T|2003-05-15|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US20040035562A1|2002-07-12|2004-02-26|Haruyuki Nishijima|Heat exchanger for cooling air|
    FR2856781A1|2003-06-23|2004-12-31|Denso Corp|HEAT EXCHANGER|
    US20060151160A1|2002-10-02|2006-07-13|Showa Denko K.K.|Heat exchanging tube and heat exchanger|
    CN101975526A|2010-11-18|2011-02-16|三花丹佛斯(杭州)微通道换热器有限公司|Heat exchange tube and heat exchanger having the same|
    CN102278906A|2011-08-17|2011-12-14|三花丹佛斯(杭州)微通道换热器有限公司|Heat exchanger and flat pipe thereof|
    CN102510992A|2009-09-30|2012-06-20|大金工业株式会社|Heat-exchanging flat tube|US3416600A|1967-01-23|1968-12-17|Whirlpool Co|Heat exchanger having twisted multiple passage tubes|
    DE1968384U|1967-06-23|1967-09-14|Hermann Saathoff|FLEXIBLE HOSE MADE OF PLASTIC.|
    DE2217252A1|1972-04-11|1973-10-31|Daimler Benz Ag|CONNECTION BETWEEN A FUEL INJECTION ENGINE AND A FUEL TANK|
    FR2269017B1|1974-04-26|1976-12-17|Lugari Frank||
    NL183053C|1975-10-03|1988-07-01|Wavin Bv|COMPOSITE PLASTIC TUBE CONTAINING TWO CONCENTRIC TUBES AND METHOD FOR MANUFACTURING SUCH PLASTIC TUBE.|
    DE3601741A1|1985-04-18|1986-10-23|Festo KG, 7300 Esslingen|Hose arrangement which consists of flexible plastic material|
    CA1317772C|1985-10-02|1993-05-18|Leon A. Guntly|Condenser with small hydraulic diameter flow path|
    US5372188A|1985-10-02|1994-12-13|Modine Manufacturing Co.|Heat exchanger for a refrigerant system|
    CH667816A5|1985-10-09|1988-11-15|Sulzer Ag|CRYSTALIZATION DEVICE AND THEIR USE.|
    DE3843305A1|1988-12-22|1990-06-28|Thermal Waerme Kaelte Klima|CONDENSER FOR A VEHICLE AIR CONDITIONING REFRIGERANT|
    US5036909A|1989-06-22|1991-08-06|General Motors Corporation|Multiple serpentine tube heat exchanger|
    US5307870A|1991-12-09|1994-05-03|Nippondenso Co., Ltd.|Heat exchanger|
    JPH06201284A|1992-12-30|1994-07-19|Kawaju Reinetsu Kogyo Kk|Streamlined heating tube with fin having constant curvature surface|
    US5546656A|1994-11-30|1996-08-20|United Technologies Corporation|Fabrication of rocket thrust chambers|
    DE29502262U1|1995-02-13|1995-06-29|Tecalemit Gmbh Deutsche|Multi-layer - multi-channel plastic pipe|
    JP3438087B2|1995-02-16|2003-08-18|アクトロニクス株式会社|Ribbon plate heat pipe|
    JPH1144498A|1997-05-30|1999-02-16|Showa Alum Corp|Flat porous tube for heat exchanger and heat exchanger using the tube|
    FR2766898B1|1997-07-29|1999-09-03|Elf Antar France|PIPELINE COMPRISING SEVERAL LONGITUDINAL CONDUITS|WO2001061263A1|2000-02-15|2001-08-23|Zexel Valeo Climate Control Corporation|Heat exchanger|
    DE10054158A1|2000-11-02|2002-05-08|Behr Gmbh|Multi-chamber pipe with circular flow channels|
    WO2002042706A1|2000-11-24|2002-05-30|Showa Denko K. K.|Heat exchanger tube and heat exchanger|
    US6536255B2|2000-12-07|2003-03-25|Brazeway, Inc.|Multivoid heat exchanger tubing with ultra small voids and method for making the tubing|
    DE10115513A1|2001-03-28|2002-10-10|Behr Gmbh & Co|Heat exchanger|
    US20020195240A1|2001-06-14|2002-12-26|Kraay Michael L.|Condenser for air cooled chillers|
    JP2008224213A|2001-06-18|2008-09-25|Showa Denko Kk|Evaporator|
    DE60118722T3|2001-07-23|2014-09-25|Zexel Valeo Climate Control Corp.|The use of a refrigerant piping for a vehicle air conditioning system|
    US20070130769A1|2002-09-03|2007-06-14|Moon Seok H|Micro heat pipe with pligonal cross-section manufactured via extrusion or drawing|
    KR100906769B1|2002-01-31|2009-07-10|한라공조주식회사|Heat exchanger tube with tumbling toy-shaped passages and heat exchanger using the same|
    US6742579B1|2002-12-30|2004-06-01|Mikhail Levitin|Freezing plate|
    US6739387B1|2003-02-25|2004-05-25|Alcoa Inc.|Heat exchanger tubing and heat exchanger assembly using said tubing|
    GB2399623A|2003-03-19|2004-09-22|Calsonic Kansei Uk Ltd|Flat tube heat exchanger for a vehicle air conditioning system|
    JP3821113B2|2003-05-23|2006-09-13|株式会社デンソー|Heat exchange tube|
    WO2004113817A1|2003-06-20|2004-12-29|Halla Climate Control Corporation|A tube for heat exchanger|
    US7575046B2|2003-09-18|2009-08-18|Rochester Institute Of Technology|Methods for stabilizing flow in channels and systems thereof|
    US7080683B2|2004-06-14|2006-07-25|Delphi Technologies, Inc.|Flat tube evaporator with enhanced refrigerant flow passages|
    JP4536459B2|2004-08-25|2010-09-01|株式会社ティラド|Heat exchanger tubes and heat exchangers|
    EP1793885B1|2004-09-03|2016-09-28|Löwenstein Medical Technology GmbH + Co. KG|Plastics for medical technical devices|
    DE102004056557A1|2004-11-23|2006-05-24|Behr Gmbh & Co. Kg|Dimensionally optimized heat exchange device and method for optimizing the dimensions of heat exchange devices|
    DE102005016540A1|2005-04-08|2006-10-12|Behr Gmbh & Co. Kg|Multichannel flat tube|
    DE102005058153B4|2005-04-22|2007-12-06|Visteon Global Technologies Inc., Van Buren|Heat exchanger with multi-channel flat tubes|
    US20070113911A1|2005-11-22|2007-05-24|Temp-Flex Cable, Inc.|Multi-lumen miniature ribbon tubing|
    US20070131298A1|2005-12-08|2007-06-14|Jieh-Ming Ueng|Kink proof flat type water hose|
    DE102006008033A1|2006-02-21|2007-09-06|Siemens Ag Österreich|Heat sink with coolant flowing through the pipe|
    US20080115919A1|2006-11-16|2008-05-22|Grant Allan Anderson|Radiator Tube with Angled Flow Passage|
    US8047235B2|2006-11-30|2011-11-01|Alcatel Lucent|Fluid-permeable body having a superhydrophobic surface|
    EP2097708A4|2006-12-26|2013-11-06|Carrier Corp|Multi-channel heat exchanger with improved condensate drainage|
    US20080185130A1|2007-02-07|2008-08-07|Behr America|Heat exchanger with extruded cooling tubes|
    JP4659779B2|2007-03-23|2011-03-30|三菱電機株式会社|Heat exchanger and air conditioner equipped with the heat exchanger|
    KR101468912B1|2007-05-22|2014-12-04|인스티튜트 퓌어 루프트- 운트 캘테테크닉 게마인뉘트치게게엠베하|Rear wall condenser for domestic refrigerators and freezers|
    US7905642B2|2008-05-12|2011-03-15|Richard Sindelar|Exhaust stack and road tractor exhaust pipe|
    JP5378729B2|2008-08-29|2013-12-25|アァルピィ東プラ株式会社|Resin molded body and method for producing the same|
    JP5324169B2|2008-09-13|2013-10-23|カルソニックカンセイ株式会社|Heat exchanger tubes and heat exchangers|
    HUE029949T2|2008-11-03|2017-04-28|Guangwei Hetong Energy TechCo Ltd|Heat pipe with micro tubes array and making method thereof and heat exchanging system|
    CN102269536A|2011-08-17|2011-12-07|三花丹佛斯(杭州)微通道换热器有限公司|Flat tube used for heat exchanger and heat exchanger with same|
    DE102012224353A1|2012-12-21|2014-06-26|Behr Gmbh & Co. Kg|Heat exchanger|
    CN105318753A|2014-06-17|2016-02-10|珠海兴业新能源科技有限公司|Independent phase change heat transfer type antifreezing corrosion-preventing heat pipe|
    法律状态:
    2001-02-05| AS| Assignment|Owner name: BEHR GMBH & CO., GERMANY Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:DIENHART, BERND;KRAUSS, HANS-JOACHIM;MITTELSTRASS, HAGEN;AND OTHERS;REEL/FRAME:011548/0186;SIGNING DATES FROM 20001224 TO 20010129 |
    2005-09-05| FPAY| Fee payment|Year of fee payment: 4 |
    2009-10-26| REMI| Maintenance fee reminder mailed|
    2010-03-19| LAPS| Lapse for failure to pay maintenance fees|
    2010-04-19| STCH| Information on status: patent discontinuation|Free format text: PATENT EXPIRED DUE TO NONPAYMENT OF MAINTENANCE FEES UNDER 37 CFR 1.362 |
    2010-05-11| FP| Lapsed due to failure to pay maintenance fee|Effective date: 20100319 |
    优先权:
    申请号 | 申请日 | 专利标题
    DE19845336||1998-10-01||
    DE19845336A|DE19845336A1|1998-10-01|1998-10-01|Multi-channel flat tube|
    DE19845336.1||1998-10-01||
    US41115899A| true| 1999-10-01|1999-10-01||
    US09/775,817|US6357522B2|1998-10-01|2001-02-05|Multi-channel flat tube|US09/775,817| US6357522B2|1998-10-01|2001-02-05|Multi-channel flat tube|
    [返回顶部]