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JP6171164B2 - COOLING DEVICE AND ELECTRIC CAR AND ELECTRONIC DEVICE EQUIPPED WITH THE SAME - Google Patents

COOLING DEVICE AND ELECTRIC CAR AND ELECTRONIC DEVICE EQUIPPED WITH THE SAME Download PDF

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JP6171164B2
JP6171164B2 JP2012194651A JP2012194651A JP6171164B2 JP 6171164 B2 JP6171164 B2 JP 6171164B2 JP 2012194651 A JP2012194651 A JP 2012194651A JP 2012194651 A JP2012194651 A JP 2012194651A JP 6171164 B2 JP6171164 B2 JP 6171164B2
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heat
receiving plate
receiver
heat receiving
cooling device
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JP2014053338A (en
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郁 佐藤
郁 佐藤
若菜 野上
若菜 野上
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Panasonic Intellectual Property Management Co Ltd
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Priority to CN201380039562.0A priority patent/CN104487794B/en
Priority to US14/415,137 priority patent/US20150181756A1/en
Priority to PCT/JP2013/005190 priority patent/WO2014038179A1/en
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L2924/00Indexing scheme for arrangements or methods for connecting or disconnecting semiconductor or solid-state bodies as covered by H01L24/00
    • H01L2924/0001Technical content checked by a classifier
    • H01L2924/0002Not covered by any one of groups H01L24/00, H01L24/00 and H01L2224/00

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  • Inverter Devices (AREA)
  • Cooling Or The Like Of Electrical Apparatus (AREA)
  • Cooling Or The Like Of Semiconductors Or Solid State Devices (AREA)
  • Electric Propulsion And Braking For Vehicles (AREA)

Description

本発明は、例えば、電力半導体を搭載した電気自動車や電子機器の冷却装置に関するものである。   The present invention relates to a cooling device for an electric vehicle or an electronic device on which a power semiconductor is mounted, for example.

従来この種の冷却装置は、電気自動車の電力変換回路に搭載されたものが知られている。   Conventionally, this type of cooling device is known to be mounted on a power conversion circuit of an electric vehicle.

電気自動車では、駆動動力源となる電動機を電力変換回路であるインバータ回路でスイッチング駆動していた。   In an electric vehicle, an electric motor serving as a driving power source is switched by an inverter circuit which is a power conversion circuit.

インバータ回路には、パワートランジスタを代表とする電力半導体が複数個使われており、それぞれの電力半導体に数十アンペアの大電流が流れていた。   A plurality of power semiconductors represented by power transistors are used in the inverter circuit, and a large current of several tens of amperes flows through each power semiconductor.

そのため電力半導体は大きく発熱し、冷却することが必要であった。   For this reason, power semiconductors generate a large amount of heat and need to be cooled.

そこで、例えば特許文献1に示す冷却装置では、下部の受熱器において、冷媒で電力半導体の熱を奪わせて気化させ、上部に配置した放熱器で冷やして液化させ、再び下部に滴下させるサイクルを繰り返させることで、インバータ回路を冷却するようにしている。   Therefore, for example, in the cooling device shown in Patent Document 1, in the lower heat receiver, a cycle in which the heat of the power semiconductor is taken away by the refrigerant to be vaporized, cooled by the radiator disposed at the upper part, liquefied, and dropped again at the lower part. The inverter circuit is cooled by being repeated.

しかしながら、このような冷却装置は、受熱器において冷媒を沸騰することにより気化させる沸騰型冷却タイプといわれるものであり、このタイプのものは、受熱器において冷媒が滞留した状態で受熱するので、冷媒への熱移動効率が悪く、結論として、冷却性能が低いことが知られている。   However, such a cooling device is said to be a boiling type cooling type that evaporates by boiling the refrigerant in the heat receiver, and this type receives heat with the refrigerant remaining in the heat receiver. As a conclusion, it is known that the cooling performance is low.

これに対して、特許文献2に示す冷媒循環型冷却タイプは、受熱器において冷媒を対流させた状態で受熱させるので、冷媒への熱移動効率が高く、結論として、冷却性能が飛躍的に高くなる。   On the other hand, since the refrigerant circulation type cooling type shown in Patent Document 2 receives heat in a state where the refrigerant is convected in the heat receiver, the heat transfer efficiency to the refrigerant is high, and as a conclusion, the cooling performance is remarkably high. Become.

特開平8−126125号公報JP-A-8-126125 特開2009−88127号公報JP 2009-88127 A

上述のごとく、冷媒循環型冷却タイプでは冷却性能が飛躍的に高くなるが、そのために特許文献2に示す冷却装置では、受熱器と、この受熱器の排出口に放熱経路を介して接続した放熱器と、この放熱器と前記受熱器の流入口を接続した帰還経路と、この帰還経路に介在させた逆止弁を備えた構成としている。   As described above, the cooling performance of the refrigerant circulation cooling type is drastically improved. For this reason, in the cooling device shown in Patent Document 2, the heat receiver and the heat radiation connected to the outlet of the heat receiver via the heat radiation path are provided. And a return path connecting the radiator and the inlet of the heat receiver, and a check valve interposed in the return path.

また、帰還経路の先端は、放熱器内に突入させ、この突入部で冷媒を受熱器内に薄い膜状態で急速に広げる構成としている。   In addition, the tip of the return path is made to rush into the radiator, and the refrigerant is rapidly spread in a thin film state into the heat receiver at this rush portion.

具体的には、帰還経路から戻った冷媒が、逆止弁の開放とともに受熱器内に流入すると、帰還経路の先端(突入部)内で一部の冷媒が急速に蒸発し、その圧力で帰還経路先端内に残存する冷媒が、受熱器内へと薄い膜状態で急速に広がることとなる。   Specifically, when the refrigerant that has returned from the return path flows into the heat receiver as the check valve is opened, a part of the refrigerant rapidly evaporates in the front end (rushing part) of the return path, and the pressure returns to that temperature. The refrigerant remaining in the path tip spreads rapidly into the heat receiver in a thin film state.

その結果、受熱器内壁面(受熱板表面)においては、極めて効果的な受熱が行われることとなり、これによって冷却性能が飛躍的に高くなるのである。   As a result, extremely effective heat reception is performed on the inner wall surface of the heat receiver (the surface of the heat receiving plate), thereby greatly improving the cooling performance.

しかしながら、このように冷却性能が飛躍的に高くなるものでも、各種機器への搭載に対しては、更なる改善が必要となる。   However, even if the cooling performance is remarkably improved as described above, further improvement is required for mounting on various devices.

その一つとしては、帰還経路の先端を放熱器内に突入させる場合、放熱器内における帰還経路の先端位置を目視することが出来ないので、この位置関係を調整するのに手間がかかり、構成の簡素化が求められている。   As one of them, when the tip of the return path is inserted into the radiator, the position of the tip of the return path in the radiator cannot be visually checked, so it takes time and effort to adjust this positional relationship. There is a need for simplification.

そこで、本発明は、構成の簡素化を図ることを目的とするものである。   Accordingly, the object of the present invention is to simplify the configuration.

そして、この目的を達成するために、本発明は、受熱器と、この受熱器の排出口に放熱経路を介して接続した放熱器と、この放熱器と前記受熱器の流入口を接続した帰還経路と、この帰還経路に介在させた逆止弁を備え、前記受熱器は、その裏面側に、発熱体に接触させて熱を吸収する吸熱部を有する受熱板と、この受熱板の表面側を、空間を介して覆った受熱板カバーとを有し、前記受熱板カバーの前記排出口と前記流入口との間部分には、前記逆止弁側から湾曲しながら前記受熱板側に接近する狭開口形成部を設け、前記受熱板の吸熱部は、前記狭開口形成部の前記排出口側と、流入口側に配置し、これにより初期の目的を達成するものである。 In order to achieve this object, the present invention provides a heat receiver, a radiator connected to the discharge port of the heat receiver via a heat dissipation path, and a feedback connecting the heat sink and the inlet of the heat receiver. A heat-reception plate having a heat-absorbing part that contacts the heat-generating body and absorbs heat on the back side thereof, and a surface side of the heat-receiving plate. And a heat receiving plate cover that covers the heat receiving plate cover through a space, and approaches the heat receiving plate side of the heat receiving plate cover between the discharge port and the inflow port while curving from the check valve side. A narrow opening forming portion is provided, and the heat absorbing portion of the heat receiving plate is disposed on the discharge port side and the inflow port side of the narrow opening forming portion, thereby achieving the initial purpose.

以上のように本発明は、受熱器と、この受熱器の排出口に放熱経路を介して接続した放熱器と、この放熱器と前記受熱器の流入口を接続した帰還経路と、この帰還経路に介在させた逆止弁を備え、前記受熱器は、その裏面側に、発熱体に接触させて熱を吸収する吸熱部を有する受熱板と、この受熱板の表面側を、空間を介して覆った受熱板カバーとを有し、前記受熱板カバーの前記排出口と前記流入口との間部分には、前記受熱板側に接近する狭開口形成部を設け、前記受熱板の吸熱部は、前記狭開口形成部の前記排出口側と、流入口側に配置したので、構成の簡素化が図れ、生産性の高いものとなる。   As described above, the present invention includes a heat receiver, a radiator connected to the discharge port of the heat receiver via a heat dissipation path, a feedback path connecting the radiator and the inlet of the heat receiver, and the feedback path. The heat receiver has a heat receiving plate having a heat absorbing portion that contacts the heating element and absorbs heat on the back surface side, and a surface side of the heat receiving plate via a space. A heat receiving plate cover that is covered, and a narrow opening forming portion that approaches the heat receiving plate side is provided in a portion between the discharge port and the inflow port of the heat receiving plate cover, and the heat absorbing portion of the heat receiving plate is Since the narrow opening forming portion is arranged on the discharge port side and the inflow port side, the configuration can be simplified and the productivity can be increased.

すなわち、本発明の受熱器は、その裏面側に、発熱体に接触させて熱を吸収する吸熱部を有する受熱板と、この受熱板の表面側を、空間を介して覆った受熱板カバーとを有し、前記受熱板カバーの前記排出口と前記流入口との間部分には、前記受熱板側に接近する狭開口形成部を設け、前記受熱板の吸熱部は、前記狭開口形成部の前記排出口側と、流入口側に配置した構成としている。   That is, the heat receiver of the present invention has, on the back side thereof, a heat receiving plate having a heat absorbing portion that contacts the heating element and absorbs heat, and a heat receiving plate cover that covers the surface side of the heat receiving plate via a space. A narrow opening forming portion that approaches the heat receiving plate side is provided in a portion between the discharge port and the inflow port of the heat receiving plate cover, and the heat absorbing portion of the heat receiving plate is the narrow opening forming portion. It is set as the structure arrange | positioned at the said discharge port side and the inflow port side.

このため、帰還経路から逆止弁を介して受熱器内に流入した冷媒は、受熱板の狭開口形成部よりも流入口側にてその一部が気化し、そのときの圧力上昇で、この受熱板の狭開口形成部よりも流入口側に残存する冷媒は、狭開口形成部を通過することにより流速が増大し、受熱板の流出口側へと薄い膜状となって、急速に広がることとなる。   For this reason, a part of the refrigerant flowing into the heat receiver from the return path through the check valve is vaporized on the inlet side of the narrow opening forming portion of the heat receiving plate, and the pressure rises at this time. Refrigerant remaining on the inlet side of the narrow opening forming portion of the heat receiving plate increases in flow rate by passing through the narrow opening forming portion, and forms a thin film toward the outlet side of the heat receiving plate and spreads rapidly. It will be.

つまり、本発明の構成とすれば、帰還経路の先端を、受熱器内に突入させること無く、受熱器内において冷媒を受熱板表面に薄い膜状態で急速に広げることができ、その分、構成が簡素化され、生産性の高いものとなるのである。   That is, with the configuration of the present invention, the refrigerant can be rapidly spread in a thin film state on the surface of the heat receiving plate in the heat receiver without causing the tip of the return path to enter the heat receiver. This simplifies and increases productivity.

本発明の実施の形態1の電気自動車の概略図Schematic of the electric vehicle according to the first embodiment of the present invention. 同冷却装置の受熱器を示す正面図Front view showing the heat receiver of the cooling device 同受熱器を示す平面図Top view showing the heat receiver 同受熱器を示す側面図Side view showing the heat receiver

以下、本発明の実施の形態について図面を参照しながら説明する。   Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(実施の形態1)
図1に示すように、電気自動車1の車軸2を駆動する電動機3は、電気自動車1の車内4に配置した電力変換装置であるインバータ回路(図示せず)に接続されている。
(Embodiment 1)
As shown in FIG. 1, the electric motor 3 that drives the axle 2 of the electric vehicle 1 is connected to an inverter circuit (not shown) that is a power conversion device disposed in the interior 4 of the electric vehicle 1.

インバータ回路には、電力半導体の一例として、電動機3に電力を供給する複数の半導体スイッチング素子5を備えている。   The inverter circuit includes a plurality of semiconductor switching elements 5 that supply power to the motor 3 as an example of a power semiconductor.

また、インバータ回路(図示せず)、特に、その半導体スイッチング素子5を冷却する冷却装置6が設けられている。   Further, an inverter circuit (not shown), in particular, a cooling device 6 for cooling the semiconductor switching element 5 is provided.

前記冷却装置6は、半導体スイッチング素子5の上面に熱移動可能状態で接続された受熱器7と、この受熱器7の排出口8に放熱経路9を介して接続した放熱器10と、この放熱器10と前記受熱器7の流入口11を接続した帰還経路12と、この帰還経路12に介在させた逆止弁(図2〜図4の13)とを、備えた構成となっている。   The cooling device 6 includes a heat receiver 7 connected to the upper surface of the semiconductor switching element 5 in a heat transferable state, a heat radiator 10 connected to the discharge port 8 of the heat receiver 7 via a heat dissipation path 9, and the heat dissipation. It has the structure provided with the return path | route 12 which connected the inlet 10 of the heat | fever 10 and the said heat receiver 7, and the non-return valve (13 of FIGS. 2-4) interposed in this return path | route 12. FIG.

また、受熱器7、放熱経路9、放熱器10、帰還経路12で形成する循環経路は密閉状態となっており、しかもその内部雰囲気は大気圧より負圧状態としている。   The circulation path formed by the heat receiver 7, the heat radiation path 9, the heat radiator 10, and the return path 12 is in a sealed state, and the internal atmosphere is in a negative pressure state from atmospheric pressure.

そして、この負圧経路内には、例えば数百cc程度(循環経路の容積よりも十分に少ない量)の水(冷媒の一例)が注入されている。   Then, for example, about several hundred cc (an amount sufficiently smaller than the volume of the circulation path) of water (an example of a refrigerant) is injected into the negative pressure path.

つまり、本実施形態の冷却装置6は、上記特許文献2で示されたものと同じように、先ず、受熱器7内の水が、半導体スイッチング素子5の熱で沸騰すると、その時の圧力上昇で、気液混合状態ではあるが放熱経路9を介して放熱器10に到達し、次に、放熱器10の外表面にファン(図示せず)で送風することで冷却すると、再び液相状態となり、その後、帰還経路12の逆止弁13上流側へと戻る。   That is, in the cooling device 6 of the present embodiment, the water in the heat receiver 7 is first boiled by the heat of the semiconductor switching element 5 in the same manner as that shown in Patent Document 2 above. Although it is in a gas-liquid mixed state, it reaches the radiator 10 through the heat dissipation path 9 and then cools by blowing with a fan (not shown) to the outer surface of the radiator 10 to become a liquid phase state again. Thereafter, the return path 12 returns to the upstream side of the check valve 13.

この状態となると、受熱器7内の圧力は徐々に低下しており、次の瞬間に、この受熱器7内の圧力よりも、この逆止弁13上流側の水の量により主に決まる圧力の方が高くなると、逆止弁13を開放させることになる。   In this state, the pressure in the heat receiver 7 gradually decreases, and at the next moment, the pressure mainly determined by the amount of water upstream of the check valve 13 rather than the pressure in the heat receiver 7. If becomes higher, the check valve 13 is opened.

その結果、逆止弁13上流側の水が受熱器7内へと流入し、次の瞬間、受熱器7内では水の爆発的な気化が行われ、この気化熱により上記半導体スイッチング素子5は効果的に冷却されることになる。   As a result, the water upstream of the check valve 13 flows into the heat receiver 7, and at the next moment, the water is explosively vaporized in the heat receiver 7, and the semiconductor switching element 5 is caused by this heat of vaporization. It will be cooled effectively.

本実施形態の特徴は、受熱器7を図2〜図4に示す構成としたものである。   The feature of this embodiment is that the heat receiver 7 is configured as shown in FIGS.

つまり、受熱器7を図2〜図4に示すように、その裏面側に、半導体スイッチング素子5(発熱体の一例)に接触させて熱を吸収する吸熱部(半導体スイッチング素子5領域部分)を有する受熱板14と、この受熱板14の表面側を、空間を介して覆った受熱板カバー15とを有し、受熱板カバー15の排出口8と流入口11との間部分には、受熱板14側に接近する狭開口形成部16を設けている。   That is, as shown in FIGS. 2 to 4, the heat receiver 7 is brought into contact with the semiconductor switching element 5 (an example of a heating element) on the back surface side to absorb heat (semiconductor switching element 5 region). A heat receiving plate 14 and a heat receiving plate cover 15 that covers the surface side of the heat receiving plate 14 through a space, and a portion between the outlet 8 and the inlet 11 of the heat receiving plate cover 15 has a heat receiving plate. A narrow opening forming portion 16 approaching the plate 14 side is provided.

また、排出口8と流入口11は、受熱器7の側方壁面に設けている。   Further, the discharge port 8 and the inflow port 11 are provided on the side wall surface of the heat receiver 7.

そして、受熱板カバー15に狭開口形成部16を設けることにより、受熱器7内に流入口11側の空間17と、排出口8側の空間18を設け、この両空間17、18を、狭開口形成部16を介して連結した状態としている。   Then, by providing the narrow opening forming portion 16 in the heat receiving plate cover 15, a space 17 on the inlet 11 side and a space 18 on the outlet 8 side are provided in the heat receiver 7, and both the spaces 17 and 18 are narrowed. It is in a state of being connected via the opening forming portion 16.

なお、流入口11側の空間17は、排出口8側の空間18よりも小さくしている。   The space 17 on the inlet 11 side is smaller than the space 18 on the outlet 8 side.

また、受熱板14の吸熱部(半導体スイッチング素子5領域部分)は、狭開口形成部16の排出口8側と、流入口11側につながった状態で配置しているが、この吸熱部(半導体スイッチング素子5領域部分)も、狭開口形成部16の排出口8側の方が、流入口11側よりも、その面積を大きくしている。   Moreover, the heat absorption part (semiconductor switching element 5 area | region part) of the heat receiving plate 14 is arrange | positioned in the state connected to the discharge port 8 side and the inflow port 11 side of the narrow opening formation part 16, but this heat absorption part (semiconductor). The area of the switching element 5 region) is larger on the outlet 8 side of the narrow opening forming portion 16 than on the inlet 11 side.

以上の構成において、本実施形態では、図2〜図4に示すように、逆止弁13は受熱器7外に設けられ、この受熱器7内の流入口11には、帰還経路12を受熱器7内に突出させず単に接続しただけの状態としている。   In the above configuration, in the present embodiment, as shown in FIGS. 2 to 4, the check valve 13 is provided outside the heat receiver 7, and the return path 12 is received by the inflow port 11 in the heat receiver 7. It is in a state where it is simply connected without protruding into the vessel 7.

また、帰還経路12が接続された受熱器7内の流入口11側の空間17は、排出口8側の空間18よりも小さな状態としている。   The space 17 on the inlet 11 side in the heat receiver 7 to which the return path 12 is connected is smaller than the space 18 on the outlet 8 side.

したがって、上述のごとく、受熱器7内の圧力が徐々に低下し、次の瞬間に、この受熱器7内の圧力よりも、この逆止弁13上流側の水の量により主に決まる圧力の方が高くなることで、逆止弁13が開放され、逆止弁13上流側の水が、空間17内に流入すると、この空間17で水の一部が沸騰し、その結果として、空間17内の圧力を急上昇させる。   Therefore, as described above, the pressure in the heat receiver 7 gradually decreases, and at the next moment, the pressure mainly determined by the amount of water upstream of the check valve 13 rather than the pressure in the heat receiver 7. When the check valve 13 becomes higher, the check valve 13 is opened, and when water on the upstream side of the check valve 13 flows into the space 17, a part of the water boils in the space 17. As a result, the space 17 Increase the pressure inside.

このとき、空間17は空間18より小さくしているので、同等の大きさとした場合に比べ、空間17内の圧力の増加はより大きくなり、この空間17の残存する水は、狭開口形成部16を介して、薄い膜状態で、勢い良く空間18に進入する。   At this time, since the space 17 is smaller than the space 18, the increase in pressure in the space 17 is larger than that in the case of the same size, and the water remaining in the space 17 is reduced by the narrow opening forming portion 16. Through the space 18 in a thin film state vigorously.

さらに、空間18は空間17よりも大きなもので、しかも大きな吸熱部分(半導体スイッチング素子5領域部分)となっているので、この空間18に進入した薄い膜状の水は急激に気化し、その結果として、上述したごとく、その時の圧力上昇で、気液混合状態ではあるが放熱経路9を介して放熱器10に到達し、次に、放熱器10の外表面にファン(図示せず)で送風することで冷却すると、再び液相状態となり、その後、帰還経路12の逆止弁13上流側へと戻る。   Furthermore, since the space 18 is larger than the space 17 and has a large heat absorption part (semiconductor switching element 5 region part), the thin film-like water that has entered the space 18 is rapidly vaporized, and as a result. As described above, the pressure rise at that time reaches the radiator 10 through the heat dissipation path 9 although it is in a gas-liquid mixed state, and then blows to the outer surface of the radiator 10 by a fan (not shown). If it cools by doing so, it will be in a liquid phase state again, and will return to the non-return valve 13 upstream of the return path 12 after that.

なお、受熱板14の表面で、空間17、狭開口形成部16、空間18にわたって、複数の溝19を設ければ、空間17から、空間18へと薄い膜状の水を、空間18部分の受熱板14の表面に広げやすく、その点でも熱交換効率を高めることが出来る。   If a plurality of grooves 19 are provided on the surface of the heat receiving plate 14 over the space 17, the narrow opening forming portion 16, and the space 18, thin film-like water is supplied from the space 17 to the space 18. It is easy to spread on the surface of the heat receiving plate 14, and the heat exchange efficiency can be increased in that respect.

そして、このような循環が繰り返されることで、半導体スイッチング素子5は十分に冷却され、所期の特性を維持できるものとなる。   By repeating such circulation, the semiconductor switching element 5 is sufficiently cooled and can maintain the desired characteristics.

また、本実施形態では、受熱器7を、図2〜図4に示すように、その裏面側に、半導体スイッチング素子5(発熱体の一例)に接触させて熱を吸収する吸熱部(半導体スイッチング素子5領域部分)を有する受熱板14と、この受熱板14の表面側を、空間を介して覆った受熱板カバー15とを有し、前記受熱板カバー15の前記排出口8と前記流入口11との間部分には、前記受熱板14側に接近する狭開口形成部16を設けたものとしている。   In the present embodiment, as shown in FIGS. 2 to 4, the heat receiver 7 is brought into contact with the semiconductor switching element 5 (an example of a heating element) on the back surface side to absorb heat (semiconductor switching). A heat receiving plate 14 having an element 5 region portion) and a heat receiving plate cover 15 covering the surface side of the heat receiving plate 14 with a space therebetween, and the outlet 8 and the inflow port of the heat receiving plate cover 15. 11 is provided with a narrow opening forming portion 16 that approaches the heat receiving plate 14 side.

そして、受熱板カバー15に狭開口形成部16を設けることにより、受熱器7内に流入口11側の空間17と、排出口8側の空間18を設け、この両空間17、18を、狭開口形成部16を介して連結した状態としている。   Then, by providing the narrow opening forming portion 16 in the heat receiving plate cover 15, a space 17 on the inlet 11 side and a space 18 on the outlet 8 side are provided in the heat receiver 7, and both the spaces 17 and 18 are narrowed. It is in a state of being connected via the opening forming portion 16.

また、前記受熱板14の吸熱部(半導体スイッチング素子5領域部分)は、前記狭開口形成部16の前記排出口8側と、流入口11側につながった状態で配置している。   Moreover, the heat absorption part (semiconductor switching element 5 area | region part) of the said heat receiving plate 14 is arrange | positioned in the state connected to the said discharge port 8 side of the said narrow opening formation part 16, and the inflow port 11 side.

このため、本実施形態では、図2〜図4に示すように、逆止弁13は受熱器7外に設けられ、この受熱器7の流入口11に、帰還経路12を単に接続しただけの状態とできるので、受熱器7の生産時に、帰還経路12の先端をどの部分まで挿入するかと言う作業は必要なく、つまり、構成の簡素化が図れ、生産性の高いものとなる。   For this reason, in this embodiment, as shown in FIGS. 2 to 4, the check valve 13 is provided outside the heat receiver 7, and the return path 12 is simply connected to the inlet 11 of the heat receiver 7. Therefore, when the heat receiver 7 is produced, there is no need to work up to which part the tip of the return path 12 is inserted, that is, the configuration can be simplified and the productivity can be increased.

また、このような構成においても、受熱板カバー15に狭開口形成部16を設けることにより、空間17から空間18に薄い膜状の水を急激に広げることが出来るので、空間18部分における受熱板14の吸熱部(半導体スイッチング素子5領域部分)では、極めて高い熱伝達効率が得られ、その結果として冷却効率も高いものとなるのである。   Also in such a configuration, by providing the narrow opening forming portion 16 in the heat receiving plate cover 15, it is possible to rapidly spread thin film-like water from the space 17 to the space 18, so that the heat receiving plate in the space 18 portion. In the 14 heat absorption part (semiconductor switching element 5 region part), extremely high heat transfer efficiency is obtained, and as a result, the cooling efficiency is also high.

さらに、排出口8と流入口11は、受熱器7の側方壁面に設けているので、受熱器7の低背化が図られ、設置高さに制限がある場合に有効となる。   Furthermore, since the discharge port 8 and the inflow port 11 are provided on the side wall surface of the heat receiver 7, the heat receiver 7 can be reduced in height and is effective when the installation height is limited.

以上のように本発明の受熱器は、その裏面側に、発熱体に接触させて熱を吸収する吸熱部を有する受熱板と、この受熱板の表面側を、空間を介して覆った受熱板カバーとを有し、前記受熱板カバーの前記排出口と前記流入口との間部分には、前記受熱板側に接近する狭開口形成部を設け、前記受熱板の吸熱部は、前記狭開口形成部の前記排出口側と、流入口側に配置した構成としている。   As described above, the heat receiver of the present invention has a heat receiving plate having a heat absorbing portion that contacts the heating element and absorbs heat on the back surface side, and a heat receiving plate that covers the surface side of the heat receiving plate with a space interposed therebetween. A narrow opening forming portion that approaches the heat receiving plate side is provided in a portion between the discharge port and the inflow port of the heat receiving plate cover, and the heat absorbing portion of the heat receiving plate is provided with the narrow opening. It is set as the structure arrange | positioned at the said discharge port side and inflow port side of a formation part.

このため、帰還経路から逆止弁を介して受熱器内に流入した冷媒は、受熱板の狭開口形成部よりも流入口側にてその一部が気化し、そのときの圧力上昇で、この受熱板の狭開口形成部よりも流入口側に残存する冷媒は、狭開口形成部を介して、受熱板の流出口側へと薄い膜状となって、急速に広がることとなる。   For this reason, a part of the refrigerant flowing into the heat receiver from the return path through the check valve is vaporized on the inlet side of the narrow opening forming portion of the heat receiving plate, and the pressure rises at this time. The refrigerant remaining on the inlet side from the narrow opening forming portion of the heat receiving plate becomes a thin film and spreads rapidly through the narrow opening forming portion toward the outlet side of the heat receiving plate.

つまり、本発明の構成とすれば、帰還経路の先端を、受熱器内に突入させること無く、受熱器内において冷媒を受熱板表面に薄い膜状態で急速に広げることができ、その分、構成が簡素化され、生産性の高いものとなるのである。   That is, with the configuration of the present invention, the refrigerant can be rapidly spread in a thin film state on the surface of the heat receiving plate in the heat receiver without causing the tip of the return path to enter the heat receiver. This simplifies and increases productivity.

したがって、電気自動車の駆動装置としての電力変換装置の冷却装置や、電子機器の高速演算処理装置部分などの冷却装置として有用なものとなる。   Therefore, it is useful as a cooling device for a power conversion device as a drive device for an electric vehicle or a high-speed arithmetic processing device portion of an electronic device.

1 電気自動車
2 車軸
3 電動機
4 車内
5 半導体スイッチング素子
6 冷却装置
7 受熱器
8 排出口
9 放熱経路
10 放熱器
11 流入口
12 帰還経路
13 逆止弁
14 受熱板
15 受熱板カバー
16 狭開口形成部
17 空間
18 空間
19 溝
DESCRIPTION OF SYMBOLS 1 Electric vehicle 2 Axle 3 Electric motor 4 Car interior 5 Semiconductor switching element 6 Cooling device 7 Heat receiver 8 Outlet 9 Heat radiation path 10 Heat radiator 11 Inlet 12 Return path 13 Check valve 14 Heat receiving plate 15 Heat receiving plate cover 16 Narrow opening formation part 17 space 18 space 19 groove

Claims (6)

受熱器と、この受熱器の排出口に放熱経路を介して接続した放熱器と、この放熱器と前記受熱器の流入口を接続した帰還経路と、この帰還経路に介在させた逆止弁を備え、前記受熱器は、その裏面側に、発熱体に接触させて熱を吸収する吸熱部を有する受熱板と、この受熱板の表面側を、空間を介して覆った受熱板カバーとを有し、前記受熱板カバーの前記排出口と前記流入口との間部分には、前記逆止弁側から湾曲しながら前記受熱板側に接近する狭開口形成部を設け、前記受熱板の吸熱部は、前記狭開口形成部の前記排出口側と、流入口側に配置した冷却装置。 A heat receiver, a radiator connected to the outlet of the heat receiver via a heat dissipation path, a feedback path connecting the heat sink and the inlet of the heat receiver, and a check valve interposed in the feedback path. The heat receiver has a heat receiving plate having a heat absorbing portion that contacts the heating element and absorbs heat on the back side thereof, and a heat receiving plate cover that covers the surface side of the heat receiving plate with a space interposed therebetween. A narrow opening forming portion that approaches the heat receiving plate side while being curved from the check valve side is provided at a portion between the discharge port and the inflow port of the heat receiving plate cover, and the heat absorbing portion of the heat receiving plate Is a cooling device disposed on the outlet side and the inlet side of the narrow opening forming portion. 狭開口形成部の流入口側の空間は、前記狭開口形成部の排出口側の空間より小さい請求項1に記載の冷却装置。 The cooling device according to claim 1, wherein a space on the inlet side of the narrow opening forming portion is smaller than a space on the discharge port side of the narrow opening forming portion. 受熱器の排出口と流入口との少なくとも一方は、この受熱器の側方に配置した請求項1または2に記載の冷却装置。 The cooling device according to claim 1 or 2, wherein at least one of the discharge port and the inflow port of the heat receiver is disposed on a side of the heat receiver. 受熱板の表面には、前記狭開口形成部の前記流入口側から排出口側に向けて溝を形成した請求項1から3のいずれか一つに記載の冷却装置。 The cooling device according to any one of claims 1 to 3, wherein a groove is formed on a surface of the heat receiving plate from the inlet side to the outlet side of the narrow opening forming portion. 請求項1から4のいずれか一つに記載の冷却装置を搭載し、車軸を駆動する電動機を駆動する電力変化装置の冷却を行なう電気自動車。 An electric vehicle that mounts the cooling device according to any one of claims 1 to 4 and that cools a power changing device that drives an electric motor that drives an axle. 請求項1から4のいずれか一つに記載の冷却装置を搭載し、発熱体の冷却を行なう電子機器。
An electronic device that mounts the cooling device according to claim 1 and cools a heating element.
JP2012194651A 2012-09-05 2012-09-05 COOLING DEVICE AND ELECTRIC CAR AND ELECTRONIC DEVICE EQUIPPED WITH THE SAME Active JP6171164B2 (en)

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JP2012194651A JP6171164B2 (en) 2012-09-05 2012-09-05 COOLING DEVICE AND ELECTRIC CAR AND ELECTRONIC DEVICE EQUIPPED WITH THE SAME
CN201380039562.0A CN104487794B (en) 2012-09-05 2013-09-03 Cooling device, electric vehicle and electronic apparatus equipped with the cooling device
US14/415,137 US20150181756A1 (en) 2012-09-05 2013-09-03 Cooling device, electric automobile and electronic device equipped with said cooling device
PCT/JP2013/005190 WO2014038179A1 (en) 2012-09-05 2013-09-03 Cooling device, electric automobile equipped with said cooling device, and electronic device

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