JP5753694B2 - Capacitor - Google Patents
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- JP5753694B2 JP5753694B2 JP2011016737A JP2011016737A JP5753694B2 JP 5753694 B2 JP5753694 B2 JP 5753694B2 JP 2011016737 A JP2011016737 A JP 2011016737A JP 2011016737 A JP2011016737 A JP 2011016737A JP 5753694 B2 JP5753694 B2 JP 5753694B2
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Description
この発明は、たとえば自動車に搭載される冷凍サイクルであるカーエアコンに好適に用いられるコンデンサに関する。 The present invention relates to a capacitor suitably used for, for example, a car air conditioner that is a refrigeration cycle mounted on an automobile.
この明細書および特許請求の範囲において、上下、左右は図1の上下、左右をいうものとする。 In this specification and claims, the top, bottom, left, and right refer to the top, bottom, left, and right in FIG.
たとえばカーエアコンのコンデンサとして、凝縮部および過冷却部が、前者が上側に位置するように設けられており、長さ方向を左右方向に向けるとともに上下方向に間隔をおいて並列状に配置された複数の熱交換管と、隣り合う熱交換管どうしの間に配置されたフィンと、熱交換管の左右両端部が接続された上下方向にのびるヘッダタンクとを備え、すべての熱交換管の長さが等しくなっており、上下に連続して並んだ複数の熱交換管からなる熱交換パスが、凝縮部および過冷却部において1つずつ設けられ、凝縮部に設けられた熱交換パスが、冷媒を凝縮させる冷媒凝縮パスであり、過冷却部に設けられた熱交換パスが冷媒を過冷却する冷媒過冷却パスであり、左右両端部側に、それぞれすべての熱交換管が接続されるヘッダタンクが設けられ、両ヘッダタンク内が、それぞれ冷媒凝縮パスと冷媒過冷却パスとの間の高さ位置に設けられた仕切板により上側ヘッダ部と下側ヘッダ部とに区画され、冷媒凝縮パスの熱交換管の左右両端部が両ヘッダタンクの上側ヘッダ部に接続され、冷媒過冷却パスの熱交換管の左右両端部が両ヘッダタンクの下側ヘッダ部に接続され、一方のヘッダタンクの上側ヘッダ部に冷媒入口が設けられるとともに、同下側ヘッダ部に冷媒出口が設けられ、他方のヘッダタンクに気液を分離しかつ液を溜める受液器が接合されるとともに、前記他方のヘッダタンクの上下両ヘッダ部内と受液器内とが相互に通じさせられ、冷媒が、前記他方のヘッダタンクの上側ヘッダ部から受液器内に流入し、受液器内において気液が分離された後、液相主体混相冷媒が前記他方のヘッダタンクの下側ヘッダタンクに流入するようになされているコンデンサが知られている(特許文献1参照)。 For example, as a condenser of a car air conditioner, a condensing unit and a supercooling unit are provided so that the former is located on the upper side, and the length direction is directed in the left-right direction, and they are arranged in parallel at intervals in the up-down direction. It is equipped with a plurality of heat exchange tubes, fins arranged between adjacent heat exchange tubes, and a header tank extending in the vertical direction to which both left and right ends of the heat exchange tubes are connected. Are equal, and a heat exchange path consisting of a plurality of heat exchange tubes arranged continuously in the vertical direction is provided one by one in the condensing unit and the subcooling unit, and the heat exchanging path provided in the condensing unit is It is a refrigerant condensing path for condensing refrigerant, a heat exchange path provided in the supercooling section is a refrigerant subcooling path for supercooling the refrigerant, and headers to which all the heat exchange pipes are connected to the left and right end portions, respectively. Tank installed Both header tanks are partitioned into an upper header portion and a lower header portion by a partition plate provided at a height position between the refrigerant condensing path and the refrigerant subcooling path, and heat exchange of the refrigerant condensing path is performed. The left and right ends of the pipes are connected to the upper headers of both header tanks, and the left and right ends of the heat exchange pipes of the refrigerant subcooling path are connected to the lower headers of both header tanks. Is provided with a refrigerant inlet, a refrigerant outlet is provided in the lower header portion, a liquid receiver for separating gas and liquid and collecting liquid is joined to the other header tank, and After both header portions and the receiver are connected to each other, the refrigerant flows into the receiver from the upper header portion of the other header tank, and after the gas and liquid are separated in the receiver, Liquid phase mainly mixed phase refrigerant Capacitor that is adapted to flow into the lower header tank of the serial other header tank is known (see Patent Document 1).
しかしながら、特許文献1記載のコンデンサにおいては、すべての熱交換管の長さが等しくなっており、両ヘッダタンク内が、それぞれ冷媒凝縮パスと冷媒過冷却パスとの間の高さ位置に設けられた仕切板により上側ヘッダ部と下側ヘッダ部とに区画され、冷媒凝縮パスの熱交換管の左右両端部が両ヘッダタンクの上側ヘッダ部に接続されているので、凝縮部および過冷却部の左右方向の長さが等しくなっており、受液器を含めたコンデンサの上下方向および左右方向の寸法を一定にした場合に、凝縮部および過冷却部の熱交換部の面積が不足して、冷媒凝縮効率および冷媒過冷却効率のさらなる向上を図ることができない。
However, in the capacitor described in
そこで、冷媒凝縮効率および冷媒過冷却効率のさらなる向上を図りうるカーエアコン用コンデンサとして、本出願人は、先に、凝縮部および過冷却部が、前者が上側に位置するように設けられており、長さ方向を左右方向に向けるとともに上下方向に間隔をおいて並列状に配置された複数の熱交換管と、熱交換管の左右両端部が接続された上下方向にのびるヘッダタンクとを備え、上下に連続して並んだ複数の熱交換管からなる熱交換パスが上下に並んで3以上設けられ、凝縮部に設けられた熱交換パスが冷媒を凝縮させる冷媒凝縮パスであり、過冷却部に設けられた熱交換パスが冷媒を過冷却する冷媒過冷却パスであり、左右いずれか一端部側に、冷媒過冷却パスの熱交換管および下端の冷媒凝縮パスの熱交換管が接続される第1ヘッダタンクと、下端の冷媒凝縮パスを除いた冷媒凝縮パスの熱交換管が接続される第2ヘッダタンクとが設けられ、第1ヘッダタンクが、第2ヘッダタンクよりも左右方向外側に配置されるとともに、第1ヘッダタンクの上端が第2ヘッダタンクの下端よりも上方に位置しており、第1ヘッダタンクが気液を分離しかつ液を溜める機能を有し、第1ヘッダタンク内に乾燥剤を収納した乾燥剤収納部材が配置されているコンデンサを提案した(特許文献2参照)。 Therefore, as a car air conditioner capacitor that can further improve the refrigerant condensation efficiency and the refrigerant subcooling efficiency, the present applicant has previously provided the condensing unit and the supercooling unit so that the former is located on the upper side. A plurality of heat exchange pipes arranged in parallel in the vertical direction with the length direction turned to the left and right directions, and a header tank extending in the vertical direction to which the left and right ends of the heat exchange pipes are connected 3 or more heat exchange paths are arranged in the vertical direction, and the heat exchange path provided in the condensing part is a refrigerant condensing path for condensing the refrigerant, and is supercooled. The heat exchange path provided in the section is a refrigerant subcooling path that supercools the refrigerant, and the heat exchange pipe of the refrigerant subcooling path and the heat exchange pipe of the refrigerant condensation path at the lower end are connected to either one of the left and right ends. First header And a second header tank to which the heat exchange pipe of the refrigerant condensing path excluding the refrigerant condensing path at the lower end is connected, and the first header tank is disposed on the outer side in the left-right direction than the second header tank. In addition, the upper end of the first header tank is located above the lower end of the second header tank, and the first header tank has a function of separating gas and liquid and storing the liquid, and is dried in the first header tank. The capacitor | condenser by which the desiccant storage member which accommodated the agent was arrange | positioned was proposed (refer patent document 2).
特許文献2記載のコンデンサによれば、コンデンサの上下方向および左右方向の寸法を、特許文献1記載のコンデンサの受液器を含めた上下方向および左右方向の寸法と等しくした場合に、下端の冷媒凝縮パスの熱交換管の長さを、特許文献1記載のコンデンサの冷媒凝縮パスの熱交換管の長さよりも長くすることができるので、凝縮部の熱交換部の面積が増大し、しかも冷媒過冷却パスの熱交換管の長さを、特許文献1記載のコンデンサの冷媒過冷却パスの熱交換管の長さよりも長くすることができるので、過冷却部の熱交換部の面積が増大する。その結果、冷媒凝縮効率および冷媒過冷却効率のさらなる向上を図ることができる。
According to the capacitor described in Patent Document 2, when the vertical and horizontal dimensions of the capacitor are equal to the vertical and horizontal dimensions including the condenser receiver described in
ところで、特許文献2記載のコンデンサにおいては、冷媒封入の際に、冷凍サイクルにおける冷媒封入量を、早い段階で過冷度が一定となる適正封入量とするとともに、過冷度が一定となる安定化域の幅を広くして、負荷変動や冷媒洩れに対してより安定した過冷特性が得られることが要求される。また、すべての冷媒を乾燥剤に接触させて冷媒中の水分を効率良く除去することが要求される。 By the way, in the capacitor | condenser of patent document 2, while enclosing a refrigerant | coolant, while making the refrigerant | coolant enclosure amount in a refrigerating cycle into the proper enclosure amount that a supercooling degree becomes constant at an early stage, it is stable that a supercooling degree becomes constant. It is required to widen the width of the control region to obtain more stable supercooling characteristics against load fluctuations and refrigerant leakage. Further, it is required that all the refrigerant is brought into contact with the desiccant to efficiently remove moisture in the refrigerant.
この発明の目的は、上記要求に応え、冷凍サイクルにおける冷媒封入量を早い段階で適正封入量とすることができるとともに、冷媒中の水分を効率良く除去することができるコンデンサを提供することにある。 SUMMARY OF THE INVENTION An object of the present invention is to provide a capacitor that can satisfy the above requirements and can make the amount of refrigerant enclosed in the refrigeration cycle an appropriate amount at an early stage and efficiently remove moisture in the refrigerant. .
本発明は、上記目的を達成するために以下の態様からなる。 In order to achieve the above object, the present invention comprises the following aspects.
1)凝縮部および過冷却部が、前者が上側に位置するように設けられており、長さ方向を左右方向に向けるとともに上下方向に間隔をおいて並列状に配置された複数の熱交換管と、熱交換管の左右両端部が接続された上下方向にのびるヘッダタンクとを備え、上下に連続して並んだ複数の熱交換管からなる熱交換パスが上下に並んで3以上設けられ、凝縮部に設けられた熱交換パスが冷媒を凝縮させる冷媒凝縮パスであり、過冷却部に設けられた熱交換パスが冷媒を過冷却する冷媒過冷却パスであり、左右いずれか一端部側に、冷媒過冷却パスの熱交換管および下端の冷媒凝縮パスの熱交換管が接続される第1ヘッダタンクと、下端の冷媒凝縮パスを除いた冷媒凝縮パスの熱交換管が接続される第2ヘッダタンクとが設けられ、第1ヘッダタンクが、第2ヘッダタンクよりも左右方向外側に配置されるとともに、第1ヘッダタンクの上端が第2ヘッダタンクの下端よりも上方に位置しており、第1ヘッダタンクが気液を分離しかつ液を溜める機能を有し、第1ヘッダタンク内に乾燥剤を収納した乾燥剤収納部材が配置されているコンデンサであって、
第1ヘッダタンク内における左右方向内側の部分に、第1ヘッダタンク内から冷媒凝縮パスに隣接する冷媒過冷却パスの熱交換管内への液相冷媒の流れを促進する分流制御部材が設けられており、乾燥剤収納部材が、分流制御部材よりも左右方向外側の部分において第1ヘッダタンク内に配置され、第1ヘッダタンクの周壁および分流制御部材と、乾燥剤収納部材の周壁との間に、第1ヘッダタンク内を上下に区画するシール部が設けられ、下端の冷媒凝縮パスの熱交換管から第1ヘッダタンク内に流入した冷媒が、シール部よりも上方で乾燥剤収納部材内に流入するとともに、シール部よりも下方で乾燥剤収納部材内から流出し、さらに分流制御部材を経て冷媒凝縮パスに隣接する冷媒過冷却パスの熱交換管に流入するようになされ、シール部の直上部分に、第1ヘッダタンクの周壁と乾燥剤収納部材の周壁との間の間隔が、これよりも上方の部分の前記間隔よりも大きくなっている冷媒流入部が設けられ、第1ヘッダタンクの周壁と乾燥剤収納部材の周壁との間の隙間における冷媒流入部よりも上方の部分の冷媒が、冷媒流入部に流入するとともに冷媒流入部を経て乾燥剤収納部材内に流入するようになされており、分流制御部材の下端が、冷媒凝縮パスに隣接する冷媒過冷却パスの下端の熱交換管よりも下方に位置するとともに、上端が、冷媒凝縮パスに隣接する冷媒過冷却パスの上端の熱交換管よりも上方に位置し、乾燥剤収納部材の少なくとも一部が分流制御部材の上下方向の範囲内に位置し、シール部が分流制御部材の上下方向の範囲内に設けられているコンデンサ。
1) A plurality of heat exchange tubes in which the condensing unit and the supercooling unit are provided so that the former is located on the upper side, and the length direction is directed in the left-right direction and the vertical direction is spaced apart in parallel And a header tank extending in the vertical direction to which both right and left ends of the heat exchange pipe are connected, and three or more heat exchange paths are provided in the vertical direction, each of which includes a plurality of heat exchange pipes arranged vertically. The heat exchange path provided in the condensing part is a refrigerant condensing path for condensing the refrigerant, and the heat exchanging path provided in the supercooling part is a refrigerant supercooling path for supercooling the refrigerant, and is arranged at one of the left and right ends. The first header tank to which the heat exchange pipe of the refrigerant supercooling path and the heat exchange pipe of the refrigerant condensation path at the lower end are connected, and the heat exchanger pipe of the refrigerant condensation path excluding the refrigerant condensation path at the lower end are connected. A header tank and a first header tank However, the upper end of the first header tank is located above the lower end of the second header tank, and the first header tank separates gas and liquid. A capacitor having a function of storing liquid and having a desiccant storage member in which a desiccant is stored in the first header tank;
A shunt control member that promotes the flow of the liquid-phase refrigerant from the first header tank to the heat exchange pipe of the refrigerant subcooling path adjacent to the refrigerant condensing path is provided at the inner portion in the left-right direction in the first header tank. And the desiccant storage member is disposed in the first header tank at a portion on the outer side in the left-right direction with respect to the flow dividing control member, and between the peripheral wall of the first header tank and the flow control member and the peripheral wall of the desiccant storage member. The first header tank is provided with a seal section that vertically divides the refrigerant into the first header tank from the heat exchange pipe of the refrigerant condensation path at the lower end, and enters the desiccant storage member above the seal section. In addition to flowing in, it flows out of the desiccant storage member below the seal portion, and further flows into the heat exchange pipe of the refrigerant supercooling path adjacent to the refrigerant condensing path through the flow dividing control member. A refrigerant inflow portion in which a distance between the peripheral wall of the first header tank and the peripheral wall of the desiccant storage member is larger than the above-mentioned distance in the portion above the first header tank is provided immediately above the portion. The refrigerant above the refrigerant inflow portion in the gap between the peripheral wall of the header tank and the desiccant storage member flows into the refrigerant inflow portion and flows into the desiccant storage member through the refrigerant inflow portion. The lower end of the flow dividing control member is positioned below the heat exchange pipe at the lower end of the refrigerant supercooling path adjacent to the refrigerant condensing path, and the upper end of the refrigerant subcooling path adjacent to the refrigerant condensing path. Located above the heat exchange pipe at the upper end, at least a part of the desiccant storage member is located in the vertical range of the flow dividing control member, and the seal portion is provided in the vertical range of the flow dividing control member. It is capacitors.
2)過冷却部に1つの冷媒過冷却パスが設けられとともに、分流制御部材が冷媒過冷却パスと対応する高さ位置に設けられ、分流制御部材が、冷媒過冷却パスの熱交換管に通じるとともに冷媒過冷却パスの熱交換管内に冷媒を流入させる密閉状の冷媒流入空間を形成するように第1ヘッダタンク内に設けられ、分流制御部材の下端部に、第1ヘッダタンク内におけるシール部よりも下方の部分と冷媒流入空間とを通じさせる連通穴が設けられている上記1)記載のコンデンサ。 2) One refrigerant subcooling path is provided in the subcooling section, and the flow dividing control member is provided at a height corresponding to the refrigerant subcooling path, and the flow dividing control member communicates with the heat exchange pipe of the refrigerant subcooling path. And a seal portion in the first header tank provided in the first header tank so as to form a sealed refrigerant inflow space for allowing the refrigerant to flow into the heat exchange pipe of the refrigerant supercooling path. The capacitor as described in 1) above, wherein a communication hole is provided through the lower part and the refrigerant inflow space.
3)分流制御部材が、長さ方向を上下方向に向けるとともに、第1ヘッダタンク内を左右方向内側部分と同外側部分とに区画する仕切壁と、仕切壁の上下両端に設けられ、かつ仕切壁よりも左右方向内側部分の空間の上下両端開口を閉鎖する上下両閉鎖壁とを有し、仕切壁および上下両閉鎖壁によって冷媒流入空間が形成され、連通穴が仕切壁または下閉鎖壁に形成されている上記2)記載のコンデンサ。 3) A flow dividing control member is provided with a partition wall that divides the first header tank into an inner part and an outer part in the left-right direction, and is provided at both upper and lower ends of the partition wall, with the length direction directed vertically. Both upper and lower closing walls that close both the upper and lower opening of the space in the left and right direction inside the wall, and a refrigerant inflow space is formed by the partition wall and the upper and lower closing walls, and the communication hole is formed in the partition wall or the lower closing wall. The capacitor as described in 2) above, which is formed.
4)冷媒流入部が、乾燥剤収納部材の周壁外面に凹所を形成することにより設けられており、乾燥剤収納部材の周壁における凹所よりも上方の部分に、下端の冷媒凝縮パスの熱交換管から第1ヘッダタンク内に流入した冷媒が乾燥剤収納部材内に流入する第1の流入口が設けられるとともに、乾燥剤収納部材の周壁における凹所内に臨む部分に凹所内に導かれた冷媒が乾燥剤収納部材内に流入する第2の流入口が設けられ、乾燥剤収納部材の周壁におけるシール部よりも下方の部分に、乾燥剤収納部材内の冷媒が第1ヘッダタンク内に流出する流出口が設けられている上記2)または3)記載のコンデンサ。 4) The refrigerant inflow portion is provided by forming a recess in the outer surface of the peripheral wall of the desiccant storage member, and the heat of the refrigerant condensing path at the lower end is formed in a portion above the recess in the peripheral wall of the desiccant storage member. A first inflow port through which the refrigerant that has flowed into the first header tank from the exchange pipe flows into the desiccant storage member is provided, and is guided into the recess at a portion facing the recess in the peripheral wall of the desiccant storage member. A second inflow port through which the refrigerant flows into the desiccant storage member is provided, and the refrigerant in the desiccant storage member flows into the first header tank at a portion below the seal portion on the peripheral wall of the desiccant storage member. The capacitor as described in 2) or 3) above, wherein an outlet is provided.
上記1)〜4)のコンデンサによれば、第1ヘッダタンク内における左右方向内側の部分に、第1ヘッダタンク内から冷媒凝縮パスに隣接する冷媒過冷却パスの熱交換管内への液相冷媒の流れを促進する分流制御部材が設けられているので、冷媒封入の際に、液相冷媒が、第1ヘッダタンク内から冷媒過冷却パスを構成する熱交換管内に速やかに流入する。したがって、冷媒過冷却パスの熱交換管内を早い段階で液相冷媒で満たすことが可能になって、冷凍サイクルにおける冷媒封入量を、早い段階で、過冷度が一定となる適正封入量とすることが可能になる。しかも、過冷度が一定となる安定化域の幅、すなわち過冷度が一定となる冷媒封入量の幅が広くなるので、負荷変動や冷媒洩れに対してより安定した過冷特性が得られる。 According to the capacitors 1) to 4) above, the liquid phase refrigerant from the inside of the first header tank to the heat exchange pipe of the refrigerant supercooling path adjacent to the refrigerant condensing path is formed on the inner side in the left and right direction within the first header tank. Therefore, when the refrigerant is sealed, the liquid-phase refrigerant quickly flows from the first header tank into the heat exchange pipe constituting the refrigerant subcooling path. Therefore, it becomes possible to fill the heat exchange pipe of the refrigerant supercooling path with the liquid phase refrigerant at an early stage, and the refrigerant filling amount in the refrigeration cycle is set to an appropriate filling amount at which the degree of supercooling becomes constant at an early stage. It becomes possible. In addition, since the width of the stabilization region where the degree of supercooling is constant, that is, the range of the refrigerant filling amount where the degree of supercooling is constant is widened, more stable supercooling characteristics against load fluctuations and refrigerant leakage can be obtained. .
また、乾燥剤収納部材が、分流制御部材よりも左右方向外側の部分において第1ヘッダタンク内に配置され、第1ヘッダタンクの周壁および分流制御部材と、乾燥剤収納部材の周壁との間に、第1ヘッダタンク内を上下に区画するシール部が設けられ、下端の冷媒凝縮パスの熱交換管から第1ヘッダタンク内に流入した冷媒が、シール部よりも上方で乾燥剤収納部材内に流入するとともに、シール部よりも下方で乾燥剤収納部材内から流出し、さらに分流制御部材を経て冷媒凝縮パスに隣接する冷媒過冷却パスの熱交換管に流入するようになされているので、すべての冷媒を乾燥剤に接触させることができ、冷媒中の水分を効率良く除去することが可能になる。 In addition, the desiccant storage member is disposed in the first header tank at a portion on the outer side in the left-right direction with respect to the flow control member, and between the peripheral wall of the first header tank and the flow control member and the peripheral wall of the desiccant storage member. The first header tank is provided with a seal section that vertically divides the refrigerant into the first header tank from the heat exchange pipe of the refrigerant condensation path at the lower end, and enters the desiccant storage member above the seal section. As it flows in, it flows out from the desiccant storage member below the seal part, and further flows into the heat exchange pipe of the refrigerant supercooling path adjacent to the refrigerant condensing path via the flow dividing control member. The refrigerant can be brought into contact with the desiccant, and the moisture in the refrigerant can be efficiently removed.
さらに、第1ヘッダタンク内を上下に区画するシール部の直上部分に、第1ヘッダタンクの周壁と乾燥剤収納部材の周壁との間の間隔が、これよりも上方の部分の前記間隔よりも大きくなっている冷媒流入部が設けられ、第1ヘッダタンクの周壁と乾燥剤収納部材の周壁との間の隙間における冷媒流入部よりも上方の部分に存在する冷媒が、冷媒流入部に流入するとともに冷媒流入部を経て乾燥剤収納部材内に流入するようになされているので、次の効果を奏する。すなわち、乾燥剤収納部材が、分流制御部材よりも左右方向外側の部分において第1ヘッダタンク内に配置されている場合、第1ヘッダタンクの周壁と乾燥剤収納部材の周壁との隙間を小さくなることは避け得ない。したがって、下端の冷媒凝縮パスの熱交換管から第1ヘッダタンク内に流入した冷媒および冷媒中に混入している圧縮機潤滑油が、前記隙間に停滞するおそれがある。その結果、圧縮機潤滑油を速やかに圧縮機に戻すことができず、圧縮機内の潤滑が不足して圧縮機の耐久性に悪影響を及ぼし、圧縮機の寿命が短くなるおそれがある。しかしながら、シール部の直上部分に、第1ヘッダタンクの周壁と乾燥剤収納部材の周壁との間の冷媒を流入させる冷媒流入部が設けられ、冷媒流入部に流入した冷媒が乾燥剤収納部材内に流入するようになされていると、前記隙間に停滞しかつ圧縮機潤滑油が混入した冷媒が、導かれるように冷媒流入部に流入するとともに冷媒流入部を経て乾燥剤収納部材内に流入するので、乾燥剤収納部材内に流入した他の冷媒とともにシール部よりも下方で乾燥剤収納部材内から流出し、さらに分流制御部材を経て冷媒凝縮パスに隣接する冷媒過冷却パスの熱交換管に流入する。したがって、圧縮機潤滑油を速やかに圧縮機に戻すことが可能になり、上述した問題を解決しうる。 Furthermore, the space between the peripheral wall of the first header tank and the peripheral wall of the desiccant storage member in the portion directly above the seal portion that divides the inside of the first header tank up and down is greater than the above-described space in the portion above this. A refrigerant inflow portion that is larger is provided, and refrigerant that exists in a portion above the refrigerant inflow portion in the gap between the peripheral wall of the first header tank and the peripheral wall of the desiccant storage member flows into the refrigerant inflow portion. And since it is made to flow in a desiccant storage member through a refrigerant | coolant inflow part, there exists the following effect. That is, when the desiccant storage member is disposed in the first header tank at a portion on the outer side in the left-right direction with respect to the flow control member, the gap between the peripheral wall of the first header tank and the peripheral wall of the desiccant storage member is reduced. That is inevitable. Therefore, the refrigerant that has flowed into the first header tank from the heat exchange pipe of the refrigerant condensation path at the lower end and the compressor lubricating oil mixed in the refrigerant may stagnate in the gap. As a result, the compressor lubricating oil cannot be quickly returned to the compressor, the lubrication in the compressor is insufficient and the durability of the compressor is adversely affected, and the life of the compressor may be shortened. However, a refrigerant inflow portion for allowing a refrigerant to flow between the peripheral wall of the first header tank and the peripheral wall of the desiccant storage member is provided immediately above the seal portion, and the refrigerant flowing into the refrigerant inflow portion is contained in the desiccant storage member. When the refrigerant flows into the refrigerant, the refrigerant stagnated in the gap and mixed with the compressor lubricating oil flows into the refrigerant inflow portion so as to be guided and flows into the desiccant storage member through the refrigerant inflow portion. Therefore, together with other refrigerant that has flowed into the desiccant storage member, it flows out of the desiccant storage member below the seal portion, and further passes through the flow dividing control member to the heat exchange pipe of the refrigerant supercooling path adjacent to the refrigerant condensing path. Inflow. Therefore, the compressor lubricating oil can be quickly returned to the compressor, and the above-described problems can be solved.
上記1)のコンデンサによれば、分流制御部材の下端が、冷媒凝縮パスに隣接する冷媒過冷却パスの下端の熱交換管よりも下方に位置するとともに、上端が、冷媒凝縮パスに隣接する冷媒過冷却パスの上端の熱交換管よりも上方に位置し、乾燥剤収納部材の少なくとも一部が分流制御部材の上下方向の範囲内に位置し、シール部が分流制御部材の上下方向の範囲内に設けられているので、下端の冷媒凝縮パスの熱交換管から第1ヘッダタンク内に流入した冷媒が、シール部よりも上方で乾燥剤収納部材内に流入するとともに、シール部よりも下方で乾燥剤収納部材内から流出し、さらに分流制御部材を経て冷媒凝縮パスに隣接する冷媒過冷却パスの熱交換管に流入しやすくなる。 According to the condenser of 1) above, the lower end of the flow dividing control member is located below the heat exchange pipe at the lower end of the refrigerant subcooling path adjacent to the refrigerant condensing path, and the upper end is the refrigerant adjacent to the refrigerant condensing path. Located above the heat exchange pipe at the upper end of the supercooling path, at least a part of the desiccant storage member is located in the vertical range of the flow control member, and the seal portion is in the vertical range of the flow control member Therefore, the refrigerant that has flowed into the first header tank from the heat exchange pipe of the refrigerant condensation path at the lower end flows into the desiccant storage member above the seal portion and below the seal portion. The refrigerant flows out of the desiccant storage member and further flows into the heat exchange pipe of the refrigerant subcooling path adjacent to the refrigerant condensing path via the flow dividing control member.
上記2)および3)のコンデンサによれば、分流制御部材の構成を比較的簡単にすることができる。 According to the capacitors 2) and 3) above, the configuration of the shunt control member can be made relatively simple.
上記4)のコンデンサによれば、下端の冷媒凝縮パスの熱交換管から第1ヘッダタンク内に流入した冷媒が、シール部よりも上方で乾燥剤収納部材内に流入するとともに、シール部よりも下方で乾燥剤収納部材内から流出し、さらに分流制御部材を経て冷媒凝縮パスに隣接する冷媒過冷却パスの熱交換管に流入するための構成、冷媒流入部の構成、および冷媒流入部に誘導された冷媒が乾燥剤収納部材内に流入するための構成を比較的簡単にすることができる。 According to the condenser of 4) , the refrigerant that has flowed into the first header tank from the heat exchange pipe of the refrigerant condensation path at the lower end flows into the desiccant storage member above the seal portion, and more than the seal portion. A structure for flowing out from the desiccant storage member at the lower side, and further flowing into the heat exchange pipe of the refrigerant subcooling path adjacent to the refrigerant condensing path through the flow dividing control member, the structure of the refrigerant inflow part, and the induction to the refrigerant inflow part It is possible to make the configuration for allowing the refrigerant to flow into the desiccant storage member relatively simple.
以下、この発明の実施形態を、図面を参照して説明する。 Embodiments of the present invention will be described below with reference to the drawings.
以下の説明において、図1の紙面裏側(図3および図4の上側)を前、これと反対側を後というものとする。 In the following description, the rear side of the paper in FIG.
また、以下の説明において、「アルミニウム」という用語には、純アルミニウムの他にアルミニウム合金を含むものとする。 In the following description, the term “aluminum” includes aluminum alloys in addition to pure aluminum.
図1はこの発明によるコンデンサの全体構成を具体的に示し、図2〜図5は図1のコンデンサの要部の構成を示す。 FIG. 1 specifically shows the overall configuration of the capacitor according to the present invention, and FIGS.
図1において、コンデンサ(1)は、幅方向を前後方向に向けるとともに長さ方向を左右方向に向けた状態で上下方向に間隔をおいて配置された複数のアルミニウム製扁平状熱交換管(2A)(2B)と、熱交換管(2A)(2B)の左右両端部がろう付により接続された上下方向にのびる3つのアルミニウム製ヘッダタンク(3)(4)(5)と、隣り合う熱交換管(2A)(2B)どうしの間および上下両端の熱交換管(2A)(2B)の外側に配置されて熱交換管(2A)(2B)にろう付されたアルミニウム製コルゲートフィン(6A)(6B)と、上下両端のコルゲートフィン(6A)(6B)の外側に配置されてコルゲートフィン(6A)(6B)にろう付されたアルミニウム製サイドプレート(7)とを備えており、凝縮部(1A)および過冷却部(1B)が、前者が上側に位置するように設けられている。 In FIG. 1, a capacitor (1) has a plurality of flat aluminum heat exchange tubes (2A) spaced apart in the vertical direction with the width direction directed in the front-rear direction and the length direction directed in the left-right direction. ) (2B) and three aluminum header tanks (3), (4) and (5) extending in the vertical direction where the left and right ends of the heat exchange tubes (2A) and (2B) are connected by brazing. Aluminum corrugated fins (6A) placed between the exchange pipes (2A) (2B) and outside the heat exchange pipes (2A) (2B) at both upper and lower ends and brazed to the heat exchange pipes (2A) (2B) ) (6B) and an aluminum side plate (7) brazed to the corrugated fins (6A) (6B) arranged outside the corrugated fins (6A) (6B) at both the upper and lower ends, and condensed The part (1A) and the supercooling part (1B) are provided so that the former is located on the upper side.
コンデンサ(1)には、上下に連続して並んだ複数の熱交換管(2A)(2B)からなる熱交換パス(P1)(P2)(P3)が上下に並んで3以上、ここでは3つ設けられている。3つの熱交換パスを、上から順に第1〜第3熱交換パス(P1)(P2)(P3)というものとする。各熱交換パス(P1)(P2)(P3)を構成する全ての熱交換管(2A)(2B)の冷媒流れ方向が同一となっているとともに、隣り合う2つの熱交換パスの熱交換管(2A)(2B)の冷媒流れ方向が異なっている。そして、第1および第2熱交換パス(P1)(P2)が凝縮部(1A)に設けられて冷媒凝縮パスとなっており、第3熱交換パス(P3)が過冷却部(1B)に設けられて冷媒過冷却パスとなっている。 The condenser (1) has three or more heat exchange paths (P1), (P2), and (P3), each of which is composed of a plurality of heat exchange tubes (2A) and (2B) arranged in a row in the vertical direction. One is provided. The three heat exchange paths are referred to as first to third heat exchange paths (P1) (P2) (P3) in order from the top. The refrigerant flow directions of all the heat exchange pipes (2A) (2B) constituting each heat exchange path (P1) (P2) (P3) are the same, and the heat exchange pipes of two adjacent heat exchange paths The refrigerant flow directions of (2A) and (2B) are different. The first and second heat exchange paths (P1) and (P2) are provided in the condensing part (1A) as a refrigerant condensing path, and the third heat exchange path (P3) is provided in the supercooling part (1B). A refrigerant supercooling path is provided.
コンデンサ(1)の左端側には、冷媒過冷却パス、すなわち第3熱交換パス(P3)および下端の冷媒凝縮パス、すなわち第2熱交換パス(P2)を構成する熱交換管(2A)がろう付により接続された上下方向にのびる第1ヘッダタンク(3)と、下端の冷媒凝縮パスを除いた冷媒凝縮パス、すなわち第1熱交換パス(P1)の熱交換管(2B)がろう付により接続された第2ヘッダタンク(4)とが別個に設けられている。ここで、第1ヘッダタンク(3)に接続された熱交換管(2A)を第1熱交換管といい、第2ヘッダタンク(4)に接続された熱交換管(2B)を第2熱交換管というものとする。また、隣り合う第1熱交換管(2A)どうしの間および下端の第1熱交換管(2A)と下側サイドプレート(7)との間に配置されたコルゲートフィン(6A)を第1コルゲートフィンといい、隣り合う第2熱交換管(2B)どうしの間、上端の第2熱交換管(2B)と上側サイドプレート(7)との間、および上端の第2熱交換管(2B)と上端の第1熱交換管(2A)との間に配置されたコルゲートフィン(6B)を第2コルゲートフィンというものとする。 On the left end side of the condenser (1), there is a heat exchange pipe (2A) constituting a refrigerant subcooling path, that is, a third heat exchange path (P3) and a refrigerant condensation path at the lower end, that is, a second heat exchange path (P2). The first header tank (3) extending in the vertical direction connected by brazing and the refrigerant condensing path excluding the refrigerant condensing path at the lower end, that is, the heat exchanging pipe (2B) of the first heat exchanging path (P1) are brazed. The second header tank (4) connected by the above is provided separately. Here, the heat exchange pipe (2A) connected to the first header tank (3) is called the first heat exchange pipe, and the heat exchange pipe (2B) connected to the second header tank (4) is the second heat. This is called an exchange tube. Further, corrugated fins (6A) disposed between adjacent first heat exchange tubes (2A) and between the first heat exchange tubes (2A) at the lower end and the lower side plate (7) are provided as first corrugates. It is called a fin, between adjacent second heat exchange pipes (2B), between the second heat exchange pipe (2B) at the upper end and the upper side plate (7), and at the upper end second heat exchange pipe (2B). The corrugated fin (6B) disposed between the upper end and the first heat exchange pipe (2A) at the upper end is referred to as a second corrugated fin.
第1ヘッダタンク(3)は、両端が開口した筒状の周壁(8a)および周壁(8a)の上端部にろう付されて周壁(8a)の上端開口を閉鎖する頂壁(8b)からなり、かつ上端が閉鎖されるとともに下端が開口したアルミニウム製筒状本体(8)と、筒状本体(8)の下端部に着脱自在に取り付けられて筒状本体(8)の下端開口を閉鎖する下閉鎖部材(9)とにより構成されている。第1ヘッダタンク(3)は、第2ヘッダタンク(4)よりも左右方向外側、ここでは左側に配置されており、上端は第2ヘッダタンク(4)の下端よりも上方でかつ上端よりも下方に位置し、下端は下側サイドプレート(7)よりも下方に位置している。 The first header tank (3) is composed of a cylindrical peripheral wall (8a) that is open at both ends and a top wall (8b) that is brazed to the upper end of the peripheral wall (8a) to close the upper end opening of the peripheral wall (8a). And an aluminum cylindrical main body (8) whose upper end is closed and whose lower end is opened, and a lower end opening of the cylindrical main body (8) which is detachably attached to the lower end of the cylindrical main body (8). And a lower closing member (9). The first header tank (3) is disposed laterally outside the second header tank (4), here on the left side, and the upper end is above the lower end of the second header tank (4) and above the upper end. The lower end is located below the lower side plate (7).
第1ヘッダタンク(3)は、重力を利用して気液を分離しかつ液を溜める受液部としての機能を有している。すなわち、第1ヘッダタンク(3)の内容積は、第1ヘッダタンク(3)内に流入した気液混相冷媒のうち液相主体混相冷媒が重力により第1ヘッダタンク(3)内の下部に溜まるとともに、気液混相冷媒のうちの気相成分が重力により第1ヘッダタンク(3)内の上部に溜まり、これにより第3熱交換パス(P3)の第1熱交換管(2A)内には液相主体混相冷媒が流入するような内容積となっている。 The first header tank (3) functions as a liquid receiver that separates gas and liquid using gravity and stores the liquid. That is, the internal volume of the first header tank (3) is such that the liquid-phase mixed refrigerant flows into the lower part of the first header tank (3) due to gravity. At the same time, the gas phase component of the gas-liquid mixed-phase refrigerant is accumulated in the upper part of the first header tank (3) due to gravity, and thereby enters the first heat exchange pipe (2A) of the third heat exchange path (P3). The internal volume is such that the liquid-phase main mixed refrigerant flows in.
コンデンサ(1)の右端部側には、第1〜第3熱交換パス(P1)〜(P3)を構成するすべての熱交換管(2A)(2B)が接続される第3ヘッダタンク(5)が配置されている。第3ヘッダタンク(5)内は、第2熱交換パス(P2)と第3熱交換パス(P3)との間の高さ位置に設けられたアルミニウム製仕切板(11)により、上側ヘッダ部(12)と下側ヘッダ部(13)とに区画されている。第1熱交換パス(P1)の第2熱交換管(2B)の左端部は第2ヘッダタンク(4)に、同右端部は第3ヘッダタンク(5)の上側ヘッダ部(12)にそれぞれ接続され、第2熱交換パス(P2)の第1熱交換管(2A)の左端部は第1ヘッダタンク(3)に、同右端部は第3ヘッダタンク(5)の上側ヘッダ部(12)にそれぞれ接続され、第3熱交換パス(P3)の第1熱交換管(2A)の左端部は第1ヘッダタンク(3)に、同右端部は第3ヘッダタンク(5)の下側ヘッダ部(13)にそれぞれ接続されている。 A third header tank (5) to which all the heat exchange pipes (2A) (2B) constituting the first to third heat exchange paths (P1) to (P3) are connected to the right end side of the condenser (1). ) Is arranged. In the third header tank (5), the upper header section is formed by an aluminum partition plate (11) provided at a height between the second heat exchange path (P2) and the third heat exchange path (P3). (12) and a lower header (13). The left end of the second heat exchange pipe (2B) of the first heat exchange path (P1) is the second header tank (4), and the right end is the upper header (12) of the third header tank (5). The left end of the first heat exchange pipe (2A) of the second heat exchange path (P2) is connected to the first header tank (3), and the right end is the upper header (12) of the third header tank (5). ), The left end of the first heat exchange pipe (2A) of the third heat exchange path (P3) is the first header tank (3), and the right end is the lower side of the third header tank (5). Each is connected to the header section (13).
第2ヘッダタンク(4)、第1ヘッダタンク(3)における第2熱交換パス(P2)の第1熱交換管(2A)が接続された部分、第3ヘッダタンク(5)の上側ヘッダ部(12)、および第1〜第2熱交換パス(P1)(P2)により冷媒を凝縮させる凝縮部(1A)が形成され、第1ヘッダタンク(3)における第3熱交換パス(P3)の第1熱交換管(2A)が接続された部分、第3ヘッダタンク(5)の下側ヘッダ部(13)および第3熱交換パス(P3)により冷媒を過冷却する過冷却部(1B)が形成され、第1〜第2熱交換パス(P1)(P2)が冷媒を凝縮させる冷媒凝縮パスとなっているとともに、第3熱交換パス(P4)が冷媒を過冷却する冷媒過冷却パスとなっている。 The second header tank (4), the portion of the first header tank (3) where the first heat exchange pipe (2A) of the second heat exchange path (P2) is connected, the upper header portion of the third header tank (5) (12) and the first and second heat exchange paths (P1) and (P2) form a condensing part (1A) for condensing the refrigerant, and the third heat exchange path (P3) in the first header tank (3) Supercooling section (1B) for supercooling the refrigerant by the portion to which the first heat exchange pipe (2A) is connected, the lower header section (13) of the third header tank (5), and the third heat exchange path (P3) Is formed, and the first to second heat exchange paths (P1) and (P2) are refrigerant condensation paths for condensing the refrigerant, and the third heat exchange path (P4) is a refrigerant subcooling path for supercooling the refrigerant. It has become.
凝縮部(1A)を構成する第2ヘッダタンク(4)における第1ヘッダタンク(3)の上端よりも上方に突出した部分に冷媒入口(図示略)が形成され、過冷却部(1B)を構成する第3ヘッダタンク(5)の下側ヘッダ部(13)に冷媒出口(図示略)が形成されている。そして、第2ヘッダタンク(4)に冷媒入口に通じる冷媒入口部材(14)が接合され、第3ヘッダタンク(5)に冷媒出口に通じる冷媒出口部材(15)が接合されている。 A refrigerant inlet (not shown) is formed in a portion of the second header tank (4) constituting the condensing unit (1A) protruding above the upper end of the first header tank (3), and the supercooling unit (1B) A refrigerant outlet (not shown) is formed in the lower header portion (13) of the third header tank (5) to be configured. A refrigerant inlet member (14) leading to the refrigerant inlet is joined to the second header tank (4), and a refrigerant outlet member (15) leading to the refrigerant outlet is joined to the third header tank (5).
図2〜図5に示すように、第1ヘッダタンク(3)の下側サイドプレート(7)よりも下方に突出した部分において、筒状本体(8)の周壁(8a)の下端部内周面にはめねじ(16)が形成されている。また、下閉鎖部材(9)は筒状本体(8)内に挿入される挿入部(9a)を有しており、挿入部(9a)の外周面におねじ(17)が形成されている。そして、挿入部(9a)のおねじ(17)が周壁(8a)のめねじ(16)にねじ合わされることにより、下閉鎖部材(9)が筒状本体(8)の下端部に着脱自在に取り付けられている。また、下閉鎖部材(9)の挿入部(9a)の外周面におけるおねじ(17)の上下両側部分と、周壁(8a)の内周面におけるめねじ(16)の上下両側部分との間は、それぞれ挿入部(9a)に装着されたシールリング(18)(19)によりシールされている。 As shown in FIGS. 2 to 5, the inner peripheral surface of the lower end portion of the peripheral wall (8 a) of the cylindrical body (8) at the portion protruding downward from the lower side plate (7) of the first header tank (3). An internal thread (16) is formed. The lower closing member (9) has an insertion portion (9a) to be inserted into the cylindrical main body (8), and a screw (17) is formed on the outer peripheral surface of the insertion portion (9a). . Then, the lower closing member (9) is detachably attached to the lower end of the cylindrical body (8) by screwing the male screw (17) of the insertion portion (9a) with the female screw (16) of the peripheral wall (8a). Is attached. Also, between the upper and lower side portions of the external thread (17) on the outer peripheral surface of the insertion portion (9a) of the lower closing member (9) and the upper and lower side portions of the female screw (16) on the inner peripheral surface of the peripheral wall (8a). Are sealed by seal rings (18) and (19) respectively attached to the insertion portion (9a).
第1ヘッダタンク(3)内における左右方向内側部分、ここでは右側部分に、第1ヘッダタンク(3)内から第3熱交換パス(P3)の第1熱交換管(2A)内への液相冷媒の流れを促進する分流制御部材(21)が設けられ、分流制御部材(21)よりも左右方向外側部分、ここでは左側部分において第1ヘッダタンク(3)内に、乾燥剤(D)を収納した乾燥剤収納部材(22)が配置され、第1ヘッダタンク(3)の筒状本体(8)の周壁(8a)内面および分流制御部材(21)と、乾燥剤収納部材(22)の周壁外面との間に、第1ヘッダタンク(3)内を上下に区画するシール部(23)が設けられ、下端の冷媒凝縮パスである第2熱交換パス(P2)の第1熱交換管(2A)から第1ヘッダタンク(3)内に流入した冷媒が、シール部(23)よりも上方で乾燥剤収納部材(22)内に流入するとともに、シール部(23)よりも下方で乾燥剤収納部材(22)内から流出し、さらに分流制御部材(21)を経て冷媒凝縮パスに隣接する冷媒過冷却パスの熱交換管に流入するようになされている。 The liquid from the inside of the first header tank (3) to the first heat exchange pipe (2A) of the third heat exchange path (P3) is formed in the left-right inner part, here the right part in the first header tank (3). A diversion control member (21) that promotes the flow of the phase refrigerant is provided, and the desiccant (D) is provided in the first header tank (3) at the outer side in the left-right direction, here the left side portion, from the diversion control member (21). A desiccant storage member (22) that stores the inner wall of the cylindrical main body (8) of the first header tank (3), the inner surface of the peripheral wall (8a), the flow control member (21), and the desiccant storage member (22). The first header tank (3) is provided with a seal portion (23) that divides the first header tank (3) in the vertical direction, and the first heat exchange of the second heat exchange path (P2) that is the refrigerant condensation path at the lower end. The refrigerant flowing into the first header tank (3) from the pipe (2A) flows into the desiccant storage member (22) above the seal portion (23) and below the seal portion (23). desiccant It flows out paid member (22) are adapted to further via diverting control member (21) enters the heat exchange tubes of refrigerant subcooling path adjacent to the refrigerant condensing path.
分流制御部材(21)は、下端が第3熱交換パス(P3)の下端の第1熱交換管(2A)よりも下方に位置するとともに、上端が第3熱交換パス(P3)の上端の第1熱交換管(2A)と第2熱交換パス(P2)の下端の第1熱交換管(2A)との間に位置するように、冷媒過冷却パスである第3熱交換パス(P3)と対応する高さ位置に設けられており、第3熱交換パス(P3)の第1熱交換管(2A)に通じるとともに第3熱交換パス(P3)の第1熱交換管(2A)内に冷媒を流入させる密閉状の冷媒流入空間(24)を形成している。なお、第1ヘッダタンク(3)内におけるシール部(23)よりも上方でかつ冷媒流入空間(24)を除いた部分を第1空間(25)といい、同じくシール部(23)よりも下方でかつ冷媒流入空間(24)を除いた部分を第2空間(26)というものとする。 The diversion control member (21) has a lower end positioned below the first heat exchange pipe (2A) at the lower end of the third heat exchange path (P3) and an upper end at the upper end of the third heat exchange path (P3). A third heat exchange path (P3), which is a refrigerant subcooling path, is positioned between the first heat exchange pipe (2A) and the first heat exchange pipe (2A) at the lower end of the second heat exchange path (P2). ) And the first heat exchange pipe (2A) of the third heat exchange path (P3) as well as the first heat exchange pipe (2A) of the third heat exchange path (P3). A sealed refrigerant inflow space (24) for allowing the refrigerant to flow therein is formed. A portion in the first header tank (3) above the seal portion (23) and excluding the refrigerant inflow space (24) is referred to as a first space (25), which is also below the seal portion (23). The portion excluding the refrigerant inflow space (24) is referred to as a second space (26).
分流制御部材(21)は、長さ方向を上下方向に向けるとともに幅方向を前後方向に向け、かつ第1ヘッダタンク(3)内を左右方向内側部分と同外側部分とに区画する帯板状の仕切壁(27)と、仕切壁(27)の上下両端に設けられ、かつ仕切壁(27)よりも左右方向内側部分の空間の上下両端開口を閉鎖する平面から見て半円形の上下両閉鎖壁(28)(29)とを有している。仕切壁(27)の前後両側縁部は、周壁(8a)に形成されかつ第1熱交換管(2A)の左端部が挿入される前後方向に長い管挿入穴(31)よりも前後方向外側部分において第1ヘッダタンク(3)の筒状本体(8)の周壁(8a)にろう付されている。上下両閉鎖壁(28)(29)の先端部には第1ヘッダタンク(3)の筒状本体(8)の周壁(8a)に形成された貫通穴(32)に嵌め入れられる凸片(28a)(29a)が形成されており、凸片(28a)(29a)が貫通穴(32)に嵌め入れられた状態で、上下両閉鎖壁(28)(29)の円弧状周縁部および凸片(28a)(29a)が周壁(8a)にろう付されている。分流制御部材(21)の仕切壁(27)および上下両閉鎖壁(28)(29)によって冷媒流入空間(24)が形成されており、分流制御部材(21)の下閉鎖壁(29)に、第1ヘッダタンク(3)の第2空間(26)と冷媒流入空間(24)とを通じさせる連通穴(33)が形成されている。 The diversion control member (21) has a strip shape in which the length direction is directed in the vertical direction, the width direction is directed in the front-rear direction, and the inside of the first header tank (3) is divided into an inner side portion and an outer side portion in the left-right direction. Partition walls (27), and both upper and lower sides of the semicircular shape as viewed from the plane that closes the upper and lower end openings of the space in the left and right inner direction than the partition walls (27). And closed walls (28) and (29). The front and rear side edges of the partition wall (27) are outside in the front-rear direction than the pipe insertion hole (31) that is formed in the peripheral wall (8a) and is long in the front-rear direction where the left end of the first heat exchange pipe (2A) is inserted. The part is brazed to the peripheral wall (8a) of the cylindrical main body (8) of the first header tank (3). At the tip of the upper and lower closed walls (28) (29), a convex piece (fitted in a through hole (32) formed in the peripheral wall (8a) of the cylindrical body (8) of the first header tank (3) ( 28a) and (29a) are formed, and with the convex pieces (28a) and (29a) being fitted into the through holes (32), the arc-shaped peripheral edges and convex portions of the upper and lower closed walls (28) and (29) are formed. The pieces (28a) (29a) are brazed to the peripheral wall (8a). A refrigerant inflow space (24) is formed by the partition wall (27) and the upper and lower closed walls (28), (29) of the flow dividing control member (21), and is formed on the lower closed wall (29) of the flow dividing control member (21). A communication hole (33) is formed through the second space (26) of the first header tank (3) and the refrigerant inflow space (24).
乾燥剤収納部材(22)はプラスチック製であって、上端が開口するとともに、下端が閉鎖された有底筒状本体(34)と、有底筒状本体(34)の上端部に着脱自在に取り付けられて有底筒状本体(34)の上端開口を閉鎖する上閉鎖部材(35)とよりなる。乾燥剤収納部材(22)の上端は第1ヘッダタンク(3)の上端近傍に位置し、下端は分流制御部材(21)の下端よりも若干下方に位置しており、下側の所定長さ部分が分流制御部材(21)の上下方向の範囲内に位置している。乾燥剤収納部材(22)の有底筒状本体(34)の周壁(36)は横断面半円形であって、前後方向と平行な平らな帯状部(37)と、前後両側縁が帯状部(37)の前後両側縁に連なるように設けられた半円筒状部(38)とよりなる。乾燥剤収納部材(22)の有底筒状本体(34)の帯状部(37)における分流制御部材(21)の高さ方向の中間部よりも下方の部分は、これよりも上方の部分に比べて幅狭となっている。この幅狭部を(37a)で示し、これよりも上方の幅広部を(37b)で示す。なお、幅狭部(37a)におけるシール部(23)よりも下方の部分の右側面は若干凹んでいる。乾燥剤収納部材(22)の有底筒状本体(34)の半円筒状部(38)における分流制御部材(21)の高さ方向の中間部よりも下方の部分は、これよりも上方の部分に比べて小径となっている。この小径部を(38a)で示し、これよりも上方の大径部を(38b)で示す。 The desiccant storage member (22) is made of plastic, and the upper end is open and the bottomed cylindrical main body (34) closed at the lower end and the upper end of the bottomed cylindrical main body (34) are detachable. The upper closing member (35) is attached to close the upper end opening of the bottomed cylindrical main body (34). The upper end of the desiccant storage member (22) is located in the vicinity of the upper end of the first header tank (3), and the lower end is located slightly below the lower end of the flow dividing control member (21). The portion is located within the vertical range of the flow dividing control member (21). The peripheral wall (36) of the bottomed cylindrical body (34) of the desiccant storage member (22) is semicircular in cross section, and is a flat strip (37) parallel to the front-rear direction, and the front and rear side edges are strips. It comprises a semi-cylindrical portion (38) provided so as to be continuous with both front and rear side edges of (37). The portion below the middle portion in the height direction of the flow dividing control member (21) in the strip portion (37) of the bottomed cylindrical body (34) of the desiccant storage member (22) is the portion above this. It is narrower than that. This narrow part is indicated by (37a), and the wide part above this is indicated by (37b). Note that the right side surface of the narrow portion (37a) below the seal portion (23) is slightly recessed. The portion below the intermediate portion in the height direction of the flow dividing control member (21) in the semi-cylindrical portion (38) of the bottomed cylindrical body (34) of the desiccant storage member (22) is higher than this. The diameter is smaller than the part. This small diameter portion is indicated by (38a), and the large diameter portion above this is indicated by (38b).
シール部(23)は、乾燥剤収納部材(22)の有底筒状本体(34)の半円筒状部(38)における小径部(38a)の高さ方向の中間部において、外方に突出するとともに、先端が第1ヘッダタンク(3)の筒状本体(8)の周壁(8a)内周面における分流制御部材(21)よりも左側の部分に接触するように一体に設けられている。そして、小径部(38a)の外面におけるシール部(23)よりも上方の部分によって、乾燥剤収納部材(22)の有底筒状本体(34)の周壁(36)における左側部分に凹所(39)が形成され、この凹所(39)によって、シール部(23)の直上部分に、第1ヘッダタンク(3)の筒状本体(8)の周壁(8a)と乾燥剤収納部材(22)の有底筒状本体(34)の周壁(36)との間の間隔が、これよりも上方の部分の前記間隔よりも大きくなっている冷媒流入部(41)が設けられている。そして、第1ヘッダタンク(3)の筒状本体(8)の周壁(8a)と、乾燥剤収納部材(22)の有底筒状本体(34)の周壁(36)における半円筒状部(38)の大径部(38b)との間の隙間の冷媒が冷媒流入部(41)に流入するようになされている。 The seal portion (23) protrudes outward at the intermediate portion in the height direction of the small diameter portion (38a) in the semi-cylindrical portion (38) of the bottomed cylindrical body (34) of the desiccant storage member (22). In addition, the tip of the first header tank (3) is integrally provided so as to be in contact with a portion on the left side of the flow dividing control member (21) on the inner peripheral surface of the peripheral wall (8a) of the cylindrical body (8) of the first header tank (3). . Then, by a portion above the seal portion (23) on the outer surface of the small diameter portion (38a), a recess is formed in the left side portion of the peripheral wall (36) of the bottomed cylindrical body (34) of the desiccant storage member (22) ( 39) is formed, and by this recess (39), the peripheral wall (8a) of the cylindrical body (8) of the first header tank (3) and the desiccant storage member (22) are formed immediately above the seal portion (23). ) Of the bottomed cylindrical main body (34) is provided with a refrigerant inflow portion (41) in which the interval is larger than the interval in the upper portion. And the semi-cylindrical part (in the peripheral wall (8a) of the cylindrical main body (8) of the first header tank (3) and the peripheral wall (36) of the bottomed cylindrical main body (34) of the desiccant storage member (22) ( The refrigerant in the gap between the large-diameter portion (38b) of 38) flows into the refrigerant inflow portion (41).
乾燥剤収納部材(22)の有底筒状本体(34)の周壁(36)における帯状部(37)の幅広部(37b)および半円筒状部(38)の大径部(38b)に、それぞれ第2熱交換パス(P2)の第1熱交換管(2A)から第1ヘッダタンク(3)の第1空間(25)内に流入した冷媒が乾燥剤収納部材(22)内に流入する第1流入口(42)が複数設けられるとともに、乾燥剤収納部材(22)の有底筒状本体(34)の周壁(36)における半円筒状部(38)の小径部(38a)に冷媒流入部(41)内に導かれた冷媒が乾燥剤収納部材(22)内に流入する第2流入口(43)が複数設けられている。また、乾燥剤収納部材(22)の有底筒状本体(34)の周壁(36)における帯状部(37)の幅狭部(37a)および半円筒状部(38)の小径部(38a)に、それぞれ乾燥剤収納部材(22)内の冷媒が第1ヘッダタンク(3)の第2空間(26)内に流出する流出口(44)が設けられている。両流入口(42)(43)および流出口(44)はメッシュ状のフィルタ(46)により塞がれている。 The wide portion (37b) of the strip-shaped portion (37) and the large diameter portion (38b) of the semi-cylindrical portion (38) in the peripheral wall (36) of the bottomed cylindrical main body (34) of the desiccant storage member (22), Refrigerant flowing into the first space (25) of the first header tank (3) from the first heat exchange pipe (2A) of the second heat exchange path (P2) flows into the desiccant storage member (22). A plurality of first inlets (42) are provided, and a refrigerant is provided in the small diameter portion (38a) of the semi-cylindrical portion (38) of the peripheral wall (36) of the bottomed cylindrical main body (34) of the desiccant storage member (22). A plurality of second inflow ports (43) through which the refrigerant guided into the inflow portion (41) flows into the desiccant storage member (22) are provided. Further, the narrow portion (37a) of the strip portion (37) and the small diameter portion (38a) of the semicylindrical portion (38) in the peripheral wall (36) of the bottomed cylindrical main body (34) of the desiccant storage member (22). In addition, there is provided an outlet (44) through which the refrigerant in the desiccant storage member (22) flows out into the second space (26) of the first header tank (3). Both the inlets (42) and (43) and the outlet (44) are closed by a mesh filter (46).
乾燥剤収納部材(22)の有底筒状本体(34)における周壁の帯状部(37)の下端部に、右方に突出して先端部が分流制御部材(21)の下閉鎖壁(29)の下面に接触した上側がたつき防止片(47)と、右斜め下方に突出して先端部が下閉鎖部材(9)の挿入部(9a)上面に接触した下側がたつき防止片(48)とが一体に設けられている。そして、上下両がたつき防止片(47)(48)のうちの少なくともいずれか一方が弾性変形し、その弾発力により上下両がたつき防止片(47)(48)が、分流制御部材(21)の下閉鎖壁(29)と下閉鎖部材(9)の挿入部(9a)との間で突っ張ることにより、コンデンサ(1)に加わる振動が吸収され、乾燥剤収納部材(22)のがたつきが防止されている。また、乾燥剤収納部材(22)の有底筒状本体(34)の底壁下面に、乾燥剤収納部材(22)を第1ヘッダタンク(3)内に出し入れする際に用いる摘み(49)が設けられている。 At the lower end of the belt-shaped portion (37) of the peripheral wall of the bottomed cylindrical main body (34) of the desiccant storage member (22), the tip protrudes rightward and the tip is a lower closing wall (29) of the flow dividing control member (21) The upper anti-rattle piece (47) that contacts the lower surface of the lower anti-rattle piece (48), and the lower anti-rattle piece (48) that protrudes obliquely downward to the right and the tip of the lower contact member (9a) contacts the upper surface of the lower closing member (9). And are provided integrally. Then, at least one of the upper and lower anti-rattle pieces (47) and (48) is elastically deformed, and the upper and lower anti-rattle pieces (47) and (48) are shunted by the elastic force. (21) By stretching between the lower closing wall (29) and the insertion portion (9a) of the lower closing member (9), the vibration applied to the capacitor (1) is absorbed, and the desiccant storage member (22) Shaking is prevented. Further, a knob (49) used when the desiccant storage member (22) is put in and out of the first header tank (3) on the bottom wall lower surface of the bottomed cylindrical main body (34) of the desiccant storage member (22). Is provided.
コンデンサ(1)は、圧縮機、膨張弁(減圧器)およびエバポレータとともに冷凍サイクルを構成し、カーエアコンとして車両に搭載される。 The condenser (1) constitutes a refrigeration cycle together with a compressor, an expansion valve (decompressor) and an evaporator, and is mounted on a vehicle as a car air conditioner.
上述した構成のコンデンサ(1)において、圧縮機により圧縮された高温高圧の気相冷媒が、冷媒入口部材(14)および冷媒入口を通って第2ヘッダタンク(4)内に流入し、第1熱交換パス(P1)の第2熱交換管(2B)内を右方に流れる間に凝縮させられて第3ヘッダタンク(5)の上側ヘッダ部(12)内に流入する。第3ヘッダタンク(5)の上側ヘッダ部(12)内に流入した冷媒は、第2熱交換パス(P2)の第1熱交換管(2A)内を左方に流れる間に凝縮させられて第1ヘッダタンク(3)の第1空間(25)内に流入する。 In the condenser (1) having the above-described configuration, the high-temperature and high-pressure gas-phase refrigerant compressed by the compressor flows into the second header tank (4) through the refrigerant inlet member (14) and the refrigerant inlet, and the first While flowing rightward in the second heat exchange pipe (2B) of the heat exchange path (P1), it is condensed and flows into the upper header portion (12) of the third header tank (5). The refrigerant flowing into the upper header section (12) of the third header tank (5) is condensed while flowing leftward in the first heat exchange pipe (2A) of the second heat exchange path (P2). It flows into the first space (25) of the first header tank (3).
第1ヘッダタンク(3)の第1空間(25)内に流入した冷媒は気液混相冷媒であり、当該気液混相冷媒のうち液相主体混相冷媒は重力により下方に流れ、第1空間(25)内に流入した気液混相冷媒のうちの気相成分は、第1ヘッダタンク(3)の第1空間(25)内の上部に溜まる。ここで、第1空間(25)内に流入した気液混相冷媒は、乾燥剤収納部材(22)の第1流入口(42)を通って乾燥剤収納部材(22)内に入った後に気液に分離され、あるいは乾燥剤収納部材(22)内に入る前に気液に分離された後に第1流入口(42)を通って乾燥剤収納部材(22)内に入り、乾燥剤(D)に触れることにより冷媒中の水分が除去される。 The refrigerant that has flowed into the first space (25) of the first header tank (3) is a gas-liquid mixed phase refrigerant. Among the gas-liquid mixed phase refrigerant, the liquid phase main mixed phase refrigerant flows downward due to gravity, and the first space ( 25) The gas phase component of the gas-liquid mixed-phase refrigerant that has flowed into the reservoir accumulates in the upper portion of the first space (25) of the first header tank (3). Here, the gas-liquid mixed phase refrigerant that has flowed into the first space (25) passes through the first inlet (42) of the desiccant storage member (22) and enters the desiccant storage member (22). It is separated into liquid or separated into gas and liquid before entering the desiccant storage member (22), and then enters the desiccant storage member (22) through the first inlet (42), and the desiccant (D ), Moisture in the refrigerant is removed.
また、第1ヘッダタンク(3)の筒状本体(8)の周壁(8a)と、乾燥剤収納部材(22)の有底筒状本体(34)における周壁(36)の半円筒状部(38)との間に存在する液相主体混相冷媒は、導かれるようにして冷媒流入部(41)に流入し、第2流入口(43)を通って乾燥剤収納部材(22)内に入り、乾燥剤(D)に触れることにより冷媒中の水分が除去される。 Further, the peripheral wall (8a) of the cylindrical main body (8) of the first header tank (3) and the semi-cylindrical part (36) of the peripheral wall (36) of the bottomed cylindrical main body (34) of the desiccant storage member (22) ( 38), the liquid-phase main mixed refrigerant flows into the refrigerant inflow portion (41) so as to be guided, and enters the desiccant storage member (22) through the second inlet (43). The moisture in the refrigerant is removed by touching the desiccant (D).
乾燥剤収納部材(22)内に入った液相主体冷媒は乾燥剤収納部材(22)内を下方に流れ、流出口(44)から第2空間(26)内に流出し、分流制御部材(21)の連通穴(33)を通って冷媒流入空間(24)内に入る。冷媒流入空間(24)内に入った液相主体混相冷媒は、第3熱交換パス(P3)の第1熱交換管(2A)内に入り、第3熱交換パス(P3)の第1熱交換管(2A)内を右方に流れる間に過冷却された後、第3ヘッダタンク(5)の下側ヘッダ部(13)内に入り、冷媒出口(15)および冷媒出口部材(17)を通って流出し、膨張弁を経てエバポレータに送られる。 The liquid phase main refrigerant that has entered the desiccant storage member (22) flows downward in the desiccant storage member (22), flows out from the outlet (44) into the second space (26), and flows into the second flow control member ( 21) enters the refrigerant inflow space (24) through the communication hole (33). The liquid phase main mixed refrigerant entering the refrigerant inflow space (24) enters the first heat exchange pipe (2A) of the third heat exchange path (P3), and the first heat of the third heat exchange path (P3). After being supercooled while flowing in the exchange pipe (2A) to the right, it enters the lower header portion (13) of the third header tank (5) and enters the refrigerant outlet (15) and the refrigerant outlet member (17). And flows out through an expansion valve to the evaporator.
上述したカーエアコンに冷媒を封入する際には、第1ヘッダタンク(3)の第1および第2空間(25)(26)内の圧力が冷媒流入空間(24)内の圧力よりも高くなるとともに、分流制御部材(21)の下端部に連通穴(33)が設けられているので、第1および第2空間(25)(26)内に溜まった液相主体混相冷媒の液面が、第3熱交換パス(P3)の上端の第1熱交換管(2A)よりも上方に達する以前に、冷媒流入空間(24)内を液相冷媒で満たすことができるとともに、第3熱交換パス(P3)の第1熱交換管(2A)内を液相冷媒で満たすことができる。したがって、冷媒過冷却パスの第1熱交換管(2A)内を速やかに液相冷媒で満たすことが可能になって、冷凍サイクルにおける冷媒封入量を、早い段階で、過冷度が一定となる適正封入量とすることが可能になる。しかも、冷凍サイクルにおける冷媒封入量を、早い段階で、過冷度が一定となる適正封入量とすることが可能になるので、過冷度が一定となる安定化域の幅、すなわち過冷度が一定となる冷媒封入量の幅が広くなり、負荷変動や冷媒洩れに対してより安定した過冷特性が得られる。 When the refrigerant is sealed in the above-described car air conditioner, the pressure in the first and second spaces (25) and (26) of the first header tank (3) is higher than the pressure in the refrigerant inflow space (24). At the same time, since the communication hole (33) is provided at the lower end of the flow dividing control member (21), the liquid surface of the liquid phase main mixed refrigerant accumulated in the first and second spaces (25), (26) The refrigerant inflow space (24) can be filled with the liquid phase refrigerant before reaching the upper side of the first heat exchange pipe (2A) at the upper end of the third heat exchange path (P3), and the third heat exchange path The inside of the first heat exchange tube (2A) of (P3) can be filled with the liquid phase refrigerant. Accordingly, the first heat exchange pipe (2A) in the refrigerant supercooling path can be quickly filled with the liquid refrigerant, and the amount of refrigerant charged in the refrigeration cycle can be constant at an early stage. It becomes possible to make it an appropriate amount. In addition, since it becomes possible to set the amount of refrigerant charged in the refrigeration cycle at an early stage to an appropriate amount of charging that makes the degree of supercooling constant, the width of the stabilization region where the degree of supercooling becomes constant, that is, the degree of supercooling. As a result, the range of the amount of refrigerant filled becomes constant, and a more stable supercooling characteristic against load fluctuations and refrigerant leakage can be obtained.
この発明によるコンデンサは、自動車に搭載されるカーエアコンに好適に用いられる。 The capacitor | condenser by this invention is used suitably for the car air conditioner mounted in a motor vehicle.
(1):コンデンサ
(1A):凝縮部
(1B):過冷却部
(2A):第1熱交換管
(2B):第2熱交換管
(3):第1ヘッダタンク(3)
(4):第2ヘッダタンク
(5):第3ヘッダタンク
(8):筒状本体
(8a):周壁
(21):分流制御部材
(22):乾燥剤収納部材
(23):シール部
(24):冷媒流入空間
(27):仕切壁
(28)(29):上下両閉鎖壁
(33):連通穴
(36):周壁
(39):凹所
(41):冷媒流入部
(42):第1流入口
(43):第2流入口
(44):流出口
(P1):第1熱交換パス
(P2):第2熱交換パス
(P3):第3熱交換パス
(1): Capacitor
(1A): Condensing part
(1B): Supercooling section
(2A): 1st heat exchange tube
(2B): Second heat exchange tube
(3): First header tank (3)
(4): Second header tank
(5): Third header tank
(8): Tubular body
(8a): Perimeter wall
(21): Shunt control member
(22): Desiccant container
(23): Seal part
(24): Refrigerant inflow space
(27): Partition wall
(28) (29): Both upper and lower closed walls
(33): Communication hole
(36): Perimeter wall
(39): Recess
(41): Refrigerant inlet
(42): 1st inlet
(43): Second inlet
(44): Outlet
(P1): First heat exchange path
(P2): Second heat exchange path
(P3): Third heat exchange path
Claims (4)
第1ヘッダタンク内における左右方向内側の部分に、第1ヘッダタンク内から冷媒凝縮パスに隣接する冷媒過冷却パスの熱交換管内への液相冷媒の流れを促進する分流制御部材が設けられており、乾燥剤収納部材が、分流制御部材よりも左右方向外側の部分において第1ヘッダタンク内に配置され、第1ヘッダタンクの周壁および分流制御部材と、乾燥剤収納部材の周壁との間に、第1ヘッダタンク内を上下に区画するシール部が設けられ、下端の冷媒凝縮パスの熱交換管から第1ヘッダタンク内に流入した冷媒が、シール部よりも上方で乾燥剤収納部材内に流入するとともに、シール部よりも下方で乾燥剤収納部材内から流出し、さらに分流制御部材を経て冷媒凝縮パスに隣接する冷媒過冷却パスの熱交換管に流入するようになされ、シール部の直上部分に、第1ヘッダタンクの周壁と乾燥剤収納部材の周壁との間の間隔が、これよりも上方の部分の前記間隔よりも大きくなっている冷媒流入部が設けられ、第1ヘッダタンクの周壁と乾燥剤収納部材の周壁との間の隙間における冷媒流入部よりも上方の部分の冷媒が、冷媒流入部に流入するとともに冷媒流入部を経て乾燥剤収納部材内に流入するようになされており、分流制御部材の下端が、冷媒凝縮パスに隣接する冷媒過冷却パスの下端の熱交換管よりも下方に位置するとともに、上端が、冷媒凝縮パスに隣接する冷媒過冷却パスの上端の熱交換管よりも上方に位置し、乾燥剤収納部材の少なくとも一部が分流制御部材の上下方向の範囲内に位置し、シール部が分流制御部材の上下方向の範囲内に設けられているコンデンサ。 A plurality of heat exchange tubes arranged in parallel with an interval in the vertical direction, with the condensing unit and the supercooling unit provided so that the former is located on the upper side, with the length direction facing the left and right direction; A header tank that extends in the vertical direction to which both left and right ends of the heat exchange pipe are connected, and is provided with three or more heat exchange paths that are arranged in a row in the vertical direction. The heat exchange path provided in the refrigerant is a refrigerant condensation path for condensing the refrigerant, and the heat exchange path provided in the supercooling part is a refrigerant supercooling path for supercooling the refrigerant. The first header tank to which the heat exchange pipe of the supercooling path and the heat exchange pipe of the refrigerant condensation path at the lower end are connected, and the second header tank to which the heat exchange pipe of the refrigerant condensation path excluding the refrigerant condensation path at the lower end is connected. And the first header tank The first header tank is disposed above the second header tank in the left-right direction, the upper end of the first header tank is located above the lower end of the second header tank, and the first header tank separates gas and liquid. A capacitor in which a desiccant storage member storing a desiccant in the first header tank is disposed,
A shunt control member that promotes the flow of the liquid-phase refrigerant from the first header tank to the heat exchange pipe of the refrigerant subcooling path adjacent to the refrigerant condensing path is provided at the inner portion in the left-right direction in the first header tank. And the desiccant storage member is disposed in the first header tank at a portion on the outer side in the left-right direction with respect to the flow dividing control member, and between the peripheral wall of the first header tank and the flow control member and the peripheral wall of the desiccant storage member. The first header tank is provided with a seal section that vertically divides the refrigerant into the first header tank from the heat exchange pipe of the refrigerant condensation path at the lower end, and enters the desiccant storage member above the seal section. In addition to flowing in, it flows out of the desiccant storage member below the seal portion, and further flows into the heat exchange pipe of the refrigerant supercooling path adjacent to the refrigerant condensing path through the flow dividing control member. A refrigerant inflow portion in which a distance between the peripheral wall of the first header tank and the peripheral wall of the desiccant storage member is larger than the above-mentioned distance in the portion above the first header tank is provided immediately above the portion. The refrigerant above the refrigerant inflow portion in the gap between the peripheral wall of the header tank and the desiccant storage member flows into the refrigerant inflow portion and flows into the desiccant storage member through the refrigerant inflow portion. The lower end of the flow dividing control member is positioned below the heat exchange pipe at the lower end of the refrigerant supercooling path adjacent to the refrigerant condensing path, and the upper end of the refrigerant subcooling path adjacent to the refrigerant condensing path. Located above the heat exchange pipe at the upper end, at least a part of the desiccant storage member is located in the vertical range of the flow dividing control member, and the seal portion is provided in the vertical range of the flow dividing control member. Capacitor.
Priority Applications (3)
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JP2011016737A JP5753694B2 (en) | 2011-01-28 | 2011-01-28 | Capacitor |
CN2011204566354U CN202403462U (en) | 2011-01-28 | 2011-11-11 | Condenser |
DE201210201199 DE102012201199A1 (en) | 2011-01-28 | 2012-01-27 | Capacitor for use in vehicle air conditioner for vehicle provided cooling circuit, comprises condensation area and sub-cooling area, such that condensation area is positioned above sub-cooling area |
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JP2011016737A JP5753694B2 (en) | 2011-01-28 | 2011-01-28 | Capacitor |
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JP2012154606A JP2012154606A (en) | 2012-08-16 |
JP5753694B2 true JP5753694B2 (en) | 2015-07-22 |
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JP2011016737A Expired - Fee Related JP5753694B2 (en) | 2011-01-28 | 2011-01-28 | Capacitor |
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CN (1) | CN202403462U (en) |
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JP6457678B1 (en) * | 2018-03-19 | 2019-01-23 | 株式会社ケーヒン | Power converter |
DE102020215372A1 (en) | 2020-12-04 | 2022-06-09 | Mahle International Gmbh | Closing plug for a collector of a refrigerant circuit |
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Publication number | Priority date | Publication date | Assignee | Title |
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AU2003229566A1 (en) * | 2002-03-23 | 2003-10-08 | Behr Gmbh And Co. | Condenser |
JP2009014274A (en) * | 2007-07-05 | 2009-01-22 | Showa Denko Kk | Heat exchanger |
DE112009001070T5 (en) * | 2008-10-20 | 2011-05-19 | Showa Denko K.K. | capacitor |
-
2011
- 2011-01-28 JP JP2011016737A patent/JP5753694B2/en not_active Expired - Fee Related
- 2011-11-11 CN CN2011204566354U patent/CN202403462U/en not_active Expired - Fee Related
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JP2012154606A (en) | 2012-08-16 |
CN202403462U (en) | 2012-08-29 |
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