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JP5514656B2 - High voltage equipment - Google Patents
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JP5514656B2 - High voltage equipment - Google Patents

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JP5514656B2
JP5514656B2 JP2010156175A JP2010156175A JP5514656B2 JP 5514656 B2 JP5514656 B2 JP 5514656B2 JP 2010156175 A JP2010156175 A JP 2010156175A JP 2010156175 A JP2010156175 A JP 2010156175A JP 5514656 B2 JP5514656 B2 JP 5514656B2
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water
rectifying element
bus bar
mounting surface
cooling fin
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JP2012019109A (en
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学 左右田
勇 冨永
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Toshiba Mitsubishi Electric Industrial Systems Corp
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Description

本発明は、冷却フィンを備えた高電圧装置に関する。 The present invention relates to a high voltage device provided with water cooling fins.

従来における水冷式半導体素子スタックの一例として特許文献1に示すように、複数個の電力用平形半導体素子と、各半導体素子の両側に配した電極板と、電極板の間に介挿してその内部に冷却水を流す板状のヒートシンクと、ヒートシンクと電極板との間に介在させた絶縁物とを積み重ね、かつ半導体素子の相互間を直列に導電接続して構成した水冷式半導体素子スタックにおいて、前記ヒートシンクと、ヒートシンクの両側に高伝熱性の絶縁物を介して重ね合わせた一対の電極板と、ヒートシンクを包囲して電極板の周縁相互間に架け渡した配線部材兼用の連結板とで一体物の合体部品を組立て、該合体部品と平形半導体素子とを交互に積み重ねてスタックを構成したものが記載されている。   As shown in Patent Document 1 as an example of a conventional water-cooled semiconductor element stack, a plurality of power flat semiconductor elements, electrode plates arranged on both sides of each semiconductor element, and interposed between the electrode plates are cooled inside. In a water-cooled semiconductor element stack configured by stacking a plate-shaped heat sink through which water flows and an insulator interposed between the heat sink and the electrode plate and electrically connecting the semiconductor elements in series, the heat sink And a pair of electrode plates stacked on both sides of the heat sink via a highly heat-conductive insulator, and a connecting plate also serving as a wiring member surrounding the heat sink and spanning between the peripheral edges of the electrode plate There is described an assembly in which union parts are assembled and the union parts and flat semiconductor elements are alternately stacked to form a stack.

特許文献1にあっては、半導体素子の間を接続する渡り配線がなく、スタック全体を小型、コンパクトに構成でき、特に小型化が要求される電気鉄道車両に搭載する電源用の電力変換装置として有利であるという効果が得られる。   In Patent Document 1, there is no crossover wiring for connecting between semiconductor elements, the entire stack can be made compact and compact, and as a power conversion device for a power supply mounted on an electric railway vehicle that is particularly required to be miniaturized An advantageous effect is obtained.

特開平9−260559号公報JP-A-9-260559

しかしながら、特許文献1は、半導体素子1個に対して、内部に冷却水を流す構成のヒートシンクを一枚設けた構成が多数組み合わされ、各ヒートシンクには冷却水を供給する配管を各々設けるか、又は各配管をカスケード接続する必要があることから、配管の構成が複雑で、全体が大形化するという問題がある。   However, Patent Document 1 is a combination of a large number of heat sinks configured to flow cooling water inside one semiconductor element, and each heat sink is provided with a pipe for supplying cooling water, Or since it is necessary to cascade-connect each piping, there exists a problem that the structure of piping is complicated and the whole enlarges.

本発明は、全体がコンパクトで、冷却水を通すための配管の構成を単純にすることができる高電圧装置を提供することを目的とする。 The present invention is entirely compact, and to provide a high voltage device that can simplify the configuration of the piping for passing cooling water.

前記目的を達成するため、請求項に対応する発明は、 その内部に冷却水を通す通水路部と、対向する表面及び裏面に有し、その接合面が接合されかつそれ自身の発熱を伝熱可能な複数のモジュール型整流素子を取り付ける整流素子取付面部を備え、前記通水路部における前記冷却水が接触する部分又はこの部分を含む全体が、前記冷却水と反応せず、かつ絶縁性及び熱伝導性の材質からなる板状の水冷却フィンと、
前記水冷却フィンの表面側及び裏面側の整流素子取付面部にそれぞれ接合され、各々の電位が異なり必要な沿面絶縁距離を確保し、且つ前記各々が接合している接合面を介してそれ自身の発熱を伝熱可能な複数個のモジュール型整流素子と、
前記水冷却フィンの同一面側の整流素子取付面部にそれぞれ設けた複数の整流素子のうち隣接の整流素子同士を直列接続する第1のブスバーと、
前記表面側の整流素子取付面部及び前記裏面側の整流素子取付面部であって同一位置における整流素子同士を直列接続する第2のブスバーと、
前記表面側の整流素子取付面部及び前記裏面側の整流素子取付面部であって異なる位置における整流素子同士を直列接続する第3のブスバーと、
前記水冷却フィンの通水路部に冷却水を供給する冷却水供給装置と、
を具備した高電圧装置である。
In order to achieve the above-mentioned object, the invention corresponding to claim 1 has a water passage portion through which cooling water passes and an opposed front surface and back surface, and the joint surfaces are joined and transmit their own heat generation. A rectifying element mounting surface part for mounting a plurality of heatable module type rectifying elements is provided, and the part in contact with the cooling water in the water passage part or the whole including this part does not react with the cooling water, and has insulation and A plate-like water cooling fin made of a thermally conductive material;
The water cooling fins are respectively joined to the rectifying element mounting surface portions on the front surface side and the back surface side, each of the electric potentials is different, a necessary creeping insulation distance is secured, and each of the water cooling fins is joined via the joining surfaces to which the water cooling fins are joined. A plurality of modular rectifiers capable of transferring heat,
A first bus bar that connects adjacent rectifier elements in series among a plurality of rectifier elements provided on the rectifier element mounting surface portion on the same surface side of the water cooling fin,
A second bus bar connecting the rectifying elements at the same position in series on the rectifying element mounting surface part on the front surface side and the rectifying element mounting surface part on the back surface side;
A third bus bar for connecting the rectifying elements at different positions in series on the front surface side rectifying element mounting surface part and the back surface side rectifying element mounting surface part;
A cooling water supply device for supplying cooling water to the water passage section of the water cooling fin;
Is a high voltage device.

本発明の高電圧装置の第1の実施形態である高電圧整流装置の主回路を示す図。The figure which shows the main circuit of the high voltage rectifier which is 1st Embodiment of the high voltage apparatus of this invention. 本発明の水冷却フィンの第1実施形態を説明するための図。The figure for demonstrating 1st Embodiment of the water cooling fin of this invention. 図1の整流装置を説明するための斜視図。FIG. 2 is a perspective view for explaining the rectifier of FIG. 図1の整流装置を説明するための斜視図。FIG. 2 is a perspective view for explaining the rectifier of FIG. 図3及び図4のモジュール型整流素子を説明するための図。The figure for demonstrating the module type rectifier of FIG.3 and FIG.4. 図1の整流装置の継手を説明するための斜視図。The perspective view for demonstrating the coupling of the rectifier of FIG. 図1の整流装置の継手にOリングを装着した状態を示す斜視図。The perspective view which shows the state which mounted | wore the coupling of the rectifier of FIG. 1 with the O-ring. 図3の整流装置に使用している第1のブスバーを説明するための図。The figure for demonstrating the 1st bus bar currently used for the rectifier of FIG. 図3の整流装置に使用している第2のブスバーを説明するための図。The figure for demonstrating the 2nd bus bar currently used for the rectifier of FIG. 図3の整流装置に使用している第3のブスバーを説明するための図。The figure for demonstrating the 3rd bus bar currently used for the rectifier of FIG. 本発明の高電圧装置の第2の実施形態を説明するための図。The figure for demonstrating 2nd Embodiment of the high-voltage apparatus of this invention. 本発明の高電圧装置の第2の実施形態を説明するための図。The figure for demonstrating 2nd Embodiment of the high-voltage apparatus of this invention.

図1は本発明の高電圧装置の第1の実施形態である高電圧整流装置の主回路を示すもので、第1の整流素子群20と、第2の整流素子群30とが直列に接続され、また第3の整流素子群40と、第4の整流素子群50とが直列に接続され、それぞれ直列接続された第1、第2と第3、第4の整流素子群が並列に接続され、各整流素子群20〜50にはそれぞれ10個のモジュール型整流素子2が直列に接続され、各整流素子2には、各素子の過渡及び直流電圧の分担を均等化する電圧分担回路10が並列に接続されている。各電圧分担回路10は、抵抗8とコンデンサ9が並列接続された並列回路である。   FIG. 1 shows a main circuit of a high voltage rectifier which is a first embodiment of a high voltage device of the present invention. A first rectifier element group 20 and a second rectifier element group 30 are connected in series. The third rectifying element group 40 and the fourth rectifying element group 50 are connected in series, and the first, second, third, and fourth rectifying element groups connected in series are connected in parallel. Ten rectifier elements 2 are connected in series to each of the rectifier element groups 20 to 50, and each rectifier element 2 has a voltage sharing circuit 10 that equalizes the distribution of transients and DC voltage of each element. Are connected in parallel. Each voltage sharing circuit 10 is a parallel circuit in which a resistor 8 and a capacitor 9 are connected in parallel.

各整流素子群20、30の中間点を交流入力端子として交流電源100が接続され、各整流素子群20、30の両端部の接続点である直流出力端子に直流負荷200が接続されている。このように各整流素子群20、30毎に、整流素子2を例えば20個直列接続し、さらに整流素子群20、30を並列接続することで、例えば13KVと高電圧化を図っている。また、各整流素子2に、それぞれ電圧変動を抑制するための抵抗8とコンデンサ9を並列してなる電圧分担回路10を並列に接続している。   An AC power supply 100 is connected with an intermediate point of each rectifying element group 20, 30 as an AC input terminal, and a DC load 200 is connected to a DC output terminal that is a connection point between both ends of each rectifying element group 20, 30. Thus, for example, 20 rectifying elements 2 are connected in series for each rectifying element group 20 and 30, and the rectifying element groups 20 and 30 are connected in parallel to achieve a high voltage of, for example, 13 KV. In addition, a voltage sharing circuit 10 in which a resistor 8 and a capacitor 9 for suppressing voltage fluctuation are connected in parallel is connected to each rectifying element 2 in parallel.

以上述べた整流装置は、以下に述べる水冷却フィン1と、モジュール型整流素子2と、
第1のブスバー3と、第2のブスバー4と、第3のブスバー5と、冷却水供給装置6とを備えている。
The rectifier described above includes a water cooling fin 1 described below, a modular rectifier 2 and
The first bus bar 3, the second bus bar 4, the third bus bar 5, and the cooling water supply device 6 are provided.

水冷却フィン1は、図2(a)の平面図、図2(b)の側面図、図2(c)の正面図に示すように、その内部に冷却水を通す例えば断面円形の通水路部11と、対向する表面及び裏面に有し、後述するモジュール型整流素子2を取り付ける整流素子取付面部12を備えている。水冷却フィン1は、通水路部11及び整流素子取付面部12を含む全体が、冷却水と反応せず、かつ絶縁性及び熱伝導性の材質からなり、表面及び裏面が対向する板状部材で形成されている。冷却水は高電圧回路に使用されるため、イオン交換樹脂等により不要なイオンを取り除き、電気伝導率を極力小さくしている。   As shown in the plan view of FIG. 2 (a), the side view of FIG. 2 (b), and the front view of FIG. 2 (c), the water cooling fin 1 is, for example, a water passage having a circular cross section through which cooling water passes. It has a rectifying element mounting surface section 12 that is provided on the front surface and the back surface of the portion 11 and to which a module type rectifying element 2 described later is mounted. The water cooling fin 1 is a plate-like member whose entire surface including the water passage portion 11 and the rectifying element mounting surface portion 12 is made of an insulating and heat conductive material that does not react with the cooling water, and whose front and back surfaces face each other. Is formed. Since the cooling water is used in a high voltage circuit, unnecessary ions are removed by an ion exchange resin or the like, and the electric conductivity is minimized.

ここで、前記冷却水と反応せず、かつ絶縁性及び熱伝導性の材質としては、酸化アルミニューム(Al2O3:通称アルミナと言う)を使用し、酸化アルミニュームの粉末を鋳型に入れて焼く鋳造方法によって製造したものである。 Here, aluminum oxide (Al 2 O 3 : commonly called alumina) is used as an insulating and heat conductive material that does not react with the cooling water, and aluminum oxide powder is put in a mold. It is manufactured by a baked casting method.

モジュール型整流素子2は、図2及び図5に示すようにベース21と、素子本体22と、電極23、24を備え、以下のように構成されている。ベース21は、平板状であって両端部近くに水冷却フィン1にねじ等により取り付ける取付孔211及び取付溝212を有している。   As shown in FIGS. 2 and 5, the module type rectifying element 2 includes a base 21, an element body 22, and electrodes 23 and 24, and is configured as follows. The base 21 has a flat plate shape, and has mounting holes 211 and mounting grooves 212 that are attached to the water cooling fins 1 with screws or the like near both ends.

ベース21の上面には、ほぼ平板状の2個の素子本体22が独立して固着され、各素子本体22の上面にはそれぞれ陽極23及び陰極24が固着され、各素子本体22の上面にはひだを形成することで必要な沿面絶縁距離を確保している。各ベース21の下面は水冷却フィン1の整流素子取付面部12と接合されるようになっており、これによって素子本体22自身の発熱を伝熱可能になっている。   Two substantially flat element main bodies 22 are independently fixed to the upper surface of the base 21, and an anode 23 and a cathode 24 are fixed to the upper surface of each element main body 22. Necessary creepage insulation distance is secured by forming pleats. The lower surface of each base 21 is joined to the rectifying element mounting surface portion 12 of the water cooling fin 1 so that heat generated by the element body 22 itself can be transferred.

第1のブスバー3は、図3及び図8に示すように水冷却フィン1の同一面側(表面側又は裏面側)の整流素子取付面部12にそれぞれ設けた複数の整流素子2のうち隣接の整流素子2同士を直列接続するものである。第1のブスバー3は、帯状導体の両端部をそれぞれL字形に折曲した折曲部31を備え、その両方の折曲部31はそれぞれ折曲方向が逆となるようになっており、両折曲部31の両端部にそれぞれ各折曲部31と直交する方向に整流素子2の電極とねじ33により接続する電極接続部32を備えている。   As shown in FIGS. 3 and 8, the first bus bar 3 is adjacent to a plurality of rectifying elements 2 provided on the rectifying element mounting surface 12 on the same surface side (front surface side or back surface side) of the water cooling fin 1. The rectifying elements 2 are connected in series. The first bus bar 3 includes bent portions 31 in which both end portions of the belt-like conductor are bent into L-shapes, and both the bent portions 31 have their bending directions opposite to each other. At both ends of the bent portion 31, there are provided electrode connecting portions 32 that are connected to the electrodes of the rectifying element 2 by screws 33 in directions orthogonal to the respective bent portions 31.

第2のブスバー4は、図3及び図9(a)の平面図、図9(b)の正面図に示すように水冷却フィン1における表面側の整流素子取付面部12及び水冷却フィン1における裏面側の整流素子取付面部12であって同一位置における整流素子同士を直列接続するものである。第2のブスバー4は、帯状導体をほぼU字形に折曲し、その折曲部41とは離れた対向片の端部に、整流素子2の電極とねじ33により接続する電極接続部42を備えたものである。   The second bus bar 4 is formed on the rectifying element mounting surface 12 on the surface side of the water cooling fin 1 and the water cooling fin 1 as shown in the plan views of FIGS. 3 and 9A and the front view of FIG. 9B. It is the rectifying element mounting surface portion 12 on the back surface side, and rectifying elements at the same position are connected in series. The second bus bar 4 bends the belt-like conductor in a substantially U shape, and an electrode connection portion 42 connected to the electrode of the rectifying element 2 by the screw 33 at the end portion of the opposing piece away from the bent portion 41. It is provided.

第3のブスバー5は、図3及び図10(a)の平面図、図10(b)の正面図に示すように水冷却フィン1における表面側の整流素子取付面部12及び水冷却フィン1における裏面側の整流素子取付面部12であって異なる位置における整流素子2同士を直列接続するものである。第3のブスバー5は、帯状導体の両端部をほぼU字形に折曲すると共に、この両折曲部51の両端部にそれぞれ整流素子2の電極とねじ33により接続する電極接続部52を備え、且つこの両電極接続部52と52を連結している連結部は傾斜部53となっている。具体的には、第3のブスバー5の両端部は、図10(a)のように、電極接続部52をそれぞれ含む端部が互いに平行状態のとき前記連結部は所定の傾斜が形成された状態となっている。   As shown in the plan view of FIGS. 3 and 10 (a) and the front view of FIG. 10 (b), the third bus bar 5 is provided in the rectifying element mounting surface portion 12 and the water cooling fin 1 on the surface side of the water cooling fin 1. It is the rectifying element mounting surface portion 12 on the back side, and the rectifying elements 2 at different positions are connected in series. The third bus bar 5 bends both ends of the belt-like conductor in a substantially U shape, and includes electrode connecting portions 52 that are connected to the electrodes of the rectifying element 2 by screws 33 at both ends of the both bent portions 51, respectively. In addition, a connecting portion that connects the electrode connecting portions 52 and 52 is an inclined portion 53. Specifically, as shown in FIG. 10 (a), both end portions of the third bus bar 5 are formed with a predetermined inclination when the end portions including the electrode connecting portions 52 are parallel to each other. It is in a state.

前記冷却水供給装置6は、図2に示すように水冷却フィン1の通水路部11に冷却水を供給するものである。   The cooling water supply device 6 supplies cooling water to the water passage portions 11 of the water cooling fins 1 as shown in FIG.

水冷却フィン1に有する通水路部11を形成している端部壁面に、図2に示すように雌ねじ部13を形成し、この雌ねじ部13に図6及び図7に示すような構成の継手7に形成されている雄ねじ部71を螺合することにより、図2の前述した冷却水供給装置6と接続し、水冷却フィン1の通水路部11に冷却水を供給するようになっている。   As shown in FIG. 2, a female thread portion 13 is formed on the end wall surface of the water cooling fin 1 where the water passage portion 11 is formed, and the female thread portion 13 is configured as shown in FIGS. 7 is connected to the above-described cooling water supply device 6 in FIG. 2 to supply cooling water to the water passage 11 of the water cooling fin 1. .

この場合の継手7は、図6に示すように平行な雄ねじを形成すると共に、継手7の先端部であって水冷却フィン1の通水路部11と当接する端部に、Oリング装着溝72を形成し、Oリング装着溝71にOリング73を装着した状態で、継手7を通水路部11の雌ねじ部13に螺合させる。   In this case, the joint 7 forms parallel male threads as shown in FIG. 6, and at the end of the joint 7 that is in contact with the water passage portion 11 of the water cooling fin 1, the O-ring mounting groove 72. In the state where the O-ring 73 is mounted in the O-ring mounting groove 71, the joint 7 is screwed into the female screw portion 13 of the water passage portion 11.

以上述べた本発明の実施形態の水冷却フィン1によれば、内部に冷却水を供給する通水路部11及び少なくとも一面に複数の電子部品例えば整流素子を取り付ける電子部品取付面部12を備えているので、簡単な構成でコンパクトにでき、水冷却フィン1を使用する高電圧装置全体のコンパクト化が可能となる。   According to the water cooling fin 1 of the embodiment of the present invention described above, the water passage portion 11 for supplying cooling water to the inside and the electronic component mounting surface portion 12 for mounting a plurality of electronic components, for example, rectifying elements, are provided on at least one surface. Therefore, it can be made compact with a simple configuration, and the entire high-voltage device using the water cooling fin 1 can be made compact.

また、以上述べた本発明の実施形態の高電圧装置によれば、全体がコンパクトで、冷却水供給装置6からの冷却水を水冷却フィン1の通水路部11に供給するための配管の構成を単純にすることができる。これに対して前述した特許文献1の発明では、半導体素子1素子に1枚の金属性のヒートシンクを設け、その間を空間及び沿面絶縁距離を確保し、かつ冷却配管を絶縁パイプでカスケードに接続することで、高電圧に適用していたため、半導体素子と同数のヒートシンクを必要とし、ヒートシンクの個数だけの冷却水配管が必要になり、構成が複雑となるという、問題点を改善できる。   Moreover, according to the high voltage apparatus of embodiment of this invention described above, the structure of the piping for supplying the cooling water from the cooling water supply apparatus 6 to the water flow path part 11 of the water cooling fin 1 is compact as a whole. Can be simplified. On the other hand, in the invention of Patent Document 1 described above, a single metal heat sink is provided in one semiconductor element, a space and a creeping insulation distance are secured between them, and cooling pipes are connected in cascade with insulating pipes. Thus, since it is applied to a high voltage, the same number of heat sinks as the semiconductor elements are required, and cooling water pipes corresponding to the number of the heat sinks are required, so that the problem that the configuration becomes complicated can be improved.

また、本発明の開発の段階で考えられた高電圧装置あっては、モジュール型整流素子1素子に1枚の金属製水冷フィンを設け、その整流素子間を空間および沿面絶縁距離を確保し、かつ冷却配管を絶縁パイプでカスケードに接続する案では、非常に多数の金属製フィンと、冷却配管並びに配管同士を接続する継手が必要になり、全体が大型化し、これに伴いコストがかかるという問題点があった。本発明は、このような問題点を改善できる。   Further, in the high voltage device considered at the development stage of the present invention, one module type rectifier element is provided with one metal water-cooled fin, ensuring a space and creepage insulation distance between the rectifier elements, In addition, the proposal for connecting the cooling pipes in cascade with insulating pipes requires a large number of metal fins, cooling pipes, and joints that connect the pipes together, which increases the overall size and costs associated with this. There was a point. The present invention can improve such problems.

本発明の実施形態の高電圧装置は、整流素子群を冷却水にて間接的に冷却する必要がある用途、例えば絶縁油に浸漬できない用途には最適である。   The high-voltage device according to the embodiment of the present invention is optimal for applications that require the rectifying element group to be indirectly cooled with cooling water, for example, applications that cannot be immersed in insulating oil.

さらに、水冷却フィン1の材質として酸化アルミニュームを用いたので、これに冷却水が反応することがなく、通水路部11の内面に冷却水が常時接触しても安定した状態で長期間使用できる。また、酸化アルミニュームを鋳造により水冷却フィン1全体を製造したので、通水路部11の端部内面に形成され、継手7の雄ねじ部71と螺合する雌ねじ部13の加工が容易である。   Furthermore, since aluminum oxide is used as the material of the water cooling fin 1, the cooling water does not react with this, and it is used for a long time in a stable state even if the cooling water always contacts the inner surface of the water passage portion 11. it can. Further, since the entire water cooling fin 1 is manufactured by casting aluminum oxide, it is easy to process the female screw portion 13 formed on the inner surface of the end portion of the water passage portion 11 and screwed with the male screw portion 71 of the joint 7.

水冷却フィン1の表面側の電子部品取付面部12及び裏面側の電子部品取付面部12にそれぞれ複数個のモジュール型整流素子2を接合し、各整流素子2を第1、第2、第3のブスバー3、4、5により直列接続したので、さらに全体がコンパクトで、構成も前述の従来例等に比べて単純となる。   A plurality of module-type rectifying elements 2 are joined to the electronic component mounting surface portion 12 on the front surface side and the electronic component mounting surface portion 12 on the back surface side of the water cooling fin 1, and the rectifying elements 2 are connected to the first, second, and third rectifier elements 2. Since the bus bars 3, 4, and 5 are connected in series, the whole is further compact and the configuration is simpler than the above-described conventional example.

図11は本発明の第2の実施形態の冷却フィン及びこれを含む高圧整流装置を説明するための図であり、冷却フィン1は2分割形式の水冷却フィン本体15、16と、水冷却フィン本体15、16に形成されている通水路部材挿通溝17、18に挿通させる通水路を構成する通水パイプ19を備えたものである。   FIG. 11 is a view for explaining a cooling fin and a high-pressure rectifier including the cooling fin according to the second embodiment of the present invention. The cooling fin 1 includes two-part water cooling fin bodies 15 and 16 and water cooling fins. A water passage pipe 19 is provided that constitutes a water passage that is inserted into the water passage member insertion grooves 17 and 18 formed in the main bodies 15 and 16.

水冷却フィン本体15、16は、絶縁性及び熱伝導性の材質例えば窒化アルミニュームから構成されている。通水パイプ19は、冷却水と反応せず、熱伝導性の材質例えば銅パイプ又はアルミニュームパイプで構成されている。   The water cooling fin bodies 15 and 16 are made of an insulating and heat conductive material such as aluminum nitride. The water flow pipe 19 does not react with the cooling water and is made of a heat conductive material such as a copper pipe or an aluminum pipe.

図12は、水冷却フィン本体15、16と、通水パイプ19と、複数のモジュール型整流素子2をねじ14により整流装置を組み立てた状態を示す。具体的には、水冷却フィン本体15の通水路部材挿通溝17と、水冷却フィン本体16の通水路部材挿通溝18を向かい合わせて、通水路部材挿通溝17、18内に通水パイプ19を挿通させ、水冷却フィン本体15に整流素子2を接合させた状態で、予め形成されている整流素子2のねじ挿通孔26と、水冷却フィン本体15のねじ孔151と、水冷却フィン本体16のねじ孔161にねじ14を順次挿入し、ねじ孔151、161に螺合させることで、整流装置を組み立てたものである。   FIG. 12 shows a state where the water cooling fin bodies 15 and 16, the water flow pipe 19, and the plurality of module type rectifying elements 2 are assembled with the screws 14 by the screws 14. Specifically, the water passage member insertion groove 17 of the water cooling fin body 15 and the water passage member insertion groove 18 of the water cooling fin body 16 face each other, and the water pipe 19 is inserted into the water passage member insertion grooves 17 and 18. In a state where the rectifying element 2 is joined to the water cooling fin main body 15, the screw insertion hole 26 of the rectifying element 2 formed in advance, the screw hole 151 of the water cooling fin main body 15, and the water cooling fin main body The rectifier is assembled by sequentially inserting the screws 14 into the 16 screw holes 161 and screwing them into the screw holes 151 and 161.

このように構成された整流装置においても、各素子2の相互間を接続するブスバー並びに各素子2に並列に接続する電圧分担回路も前述の実施形態と同様であるので、その説明を省略する。   Also in the rectifier configured as described above, the bus bar connecting the elements 2 and the voltage sharing circuit connected in parallel to the elements 2 are the same as those in the above-described embodiment, and thus the description thereof is omitted.

なお、熱伝導性とは、物質内に温度差があるとき、熱は温度の高い方から低い方へ移動する際に、この熱の移動の起こりやすさを表す。この場合、熱電導性が大きいほど熱が伝わりやすいということで、同じ材料であれば、厚みが小さいほど放熱効果は高まるということを意味している。   Note that the thermal conductivity indicates the ease of the movement of heat when there is a temperature difference in the substance and the heat moves from a higher temperature to a lower temperature. In this case, it means that heat is more easily transmitted as the thermal conductivity is greater, which means that if the same material is used, the heat dissipation effect increases as the thickness decreases.

本発明は、前述の実施形態では13Kvの整流装置を例に挙げて説明したが、電子部品としては整流素子以外に抵抗、コンデンサ等であって水冷却フィンに面接合されかつ素子自身の発熱が伝熱可能なモジュール型電子部品なら何でもよく、電圧も5Kvを越える高電圧装置なら何でも良い。   In the above-described embodiment, the present invention has been described by taking a 13 Kv rectifier as an example. However, as an electronic component, in addition to the rectifier element, a resistor, a capacitor, etc. are surface-bonded to the water cooling fin and the element itself generates heat. Any module type electronic component capable of transferring heat may be used, and any high voltage apparatus having a voltage exceeding 5 Kv may be used.

前述の実施形態において、水冷却フィン1における整流素子取付面部の表面側及び裏面側に配設するモジュール型整流素子を導電性ねじによりそれぞれ取付け、導電性ねじにより前記表面の整流素子及び裏面の整流素子を接続するブスバーを兼ねるようにしてもよい。   In the above-described embodiment, the module type rectifier elements disposed on the front surface side and the back surface side of the rectifier element mounting surface portion in the water cooling fin 1 are respectively attached with conductive screws, and the front surface rectifier elements and the back surface rectifier are connected with the conductive screws. You may make it also serve as a bus bar which connects an element.

前述の実施形態において、水冷却フィン1を全体を、冷却水と反応せず、かつ絶縁性及び熱伝導性の材質例えば酸化アルミニュームで構成したが、水冷却フィン1の通水路部における冷却水が接触する部分だけを酸化アルミニューム等で形成してもよい。   In the above-described embodiment, the entire water cooling fin 1 is made of an insulating and heat conductive material such as aluminum oxide that does not react with the cooling water, but the cooling water in the water passage portion of the water cooling fin 1 is used. Only the portion in contact with each other may be formed of aluminum oxide or the like.

1…冷却フィン、2…モジュール型整流素子、3…第1のブスバー、4…第2のブスバー、5…第3のブスバー、6…冷却水供給装置、7…継手、8…抵抗、9…コンデンサ、10…電圧分担回路、11…通水路部、12…整流素子取付面部、13…雌ねじ部、15…水冷却フィン本体、16…水冷却フィン本体、17…通水路部材挿通溝、18…通水路部材挿通溝、19…通水パイプ、20…第1の整流素子群、21…ベース、22…素子本体、23…陽極、24…陰極、26…挿通孔、30…第2の整流素子群、31…折曲部、32…電極接続部、41…折曲部、42…電極接続部、51…折曲部、52…電極接続部、53…傾斜部、71…雄ねじ部、72…Oリング装着溝、73…Oリング、100…交流電源、200…直流負荷、211…取付孔、212…取付溝。   DESCRIPTION OF SYMBOLS 1 ... Cooling fin, 2 ... Module type rectifier, 3 ... 1st bus bar, 4 ... 2nd bus bar, 5 ... 3rd bus bar, 6 ... Cooling water supply apparatus, 7 ... Joint, 8 ... Resistance, 9 ... Capacitor, 10 ... Voltage sharing circuit, 11 ... Water passage part, 12 ... Rectifier element mounting surface part, 13 ... Female thread part, 15 ... Water cooling fin body, 16 ... Water cooling fin body, 17 ... Water passage member insertion groove, 18 ... Water passage member insertion groove, 19 ... water passage pipe, 20 ... first rectifier element group, 21 ... base, 22 ... element body, 23 ... anode, 24 ... cathode, 26 ... insertion hole, 30 ... second rectifier element Group, 31 ... bent portion, 32 ... electrode connecting portion, 41 ... bent portion, 42 ... electrode connecting portion, 51 ... bent portion, 52 ... electrode connecting portion, 53 ... inclined portion, 71 ... male screw portion, 72 ... O-ring mounting groove, 73 ... O-ring, 100 ... AC power supply, 200 ... DC load, 2 1 ... mounting hole, 212 ... mounting groove.

Claims (6)

その内部に冷却水を通す通水路部と、対向する表面及び裏面に有し、その接合面が接合されかつそれ自身の発熱を伝熱可能な複数のモジュール型整流素子を取り付ける整流素子取付面部を備え、前記通水路部における前記冷却水が接触する部分又はこの部分を含む全体が、前記冷却水と反応せず、かつ絶縁性及び熱伝導性の材質からなる板状の水冷却フィンと、
前記水冷却フィンの表面側及び裏面側の整流素子取付面部にそれぞれ接合され、各々の電位が異なり必要な沿面絶縁距離を確保し、且つ前記各々が接合している接合面を介してそれ自身の発熱を伝熱可能な複数個のモジュール型整流素子と、
前記水冷却フィンの同一面側の整流素子取付面部にそれぞれ設けた複数の整流素子のうち隣接の整流素子同士を直列接続する第1のブスバーと、
前記表面側の整流素子取付面部及び前記裏面側の整流素子取付面部であって同一位置における整流素子同士を直列接続する第2のブスバーと、
前記表面側の整流素子取付面部及び前記裏面側の整流素子取付面部であって異なる位置における整流素子同士を直列接続する第3のブスバーと、
前記水冷却フィンの通水路部に冷却水を供給する冷却水供給装置と、
を具備した高電圧装置。
A water passage portion for passing cooling water therein, and a rectifying element mounting surface portion for attaching a plurality of module type rectifying elements which are provided on opposite front and back surfaces, the joint surfaces of which are joined and capable of transferring their own heat generation. A plate-like water-cooling fin made of an insulating and thermally conductive material that does not react with the cooling water, or a part including the portion in contact with the cooling water in the water passage section
The water cooling fins are respectively joined to the rectifying element mounting surface portions on the front surface side and the back surface side, each of the electric potentials is different, a necessary creeping insulation distance is secured, and each of the water cooling fins is joined via the joining surfaces to which the water cooling fins are joined. A plurality of modular rectifiers capable of transferring heat,
A first bus bar that connects adjacent rectifier elements in series among a plurality of rectifier elements provided on the rectifier element mounting surface portion on the same surface side of the water cooling fin,
A second bus bar connecting the rectifying elements at the same position in series on the rectifying element mounting surface part on the front surface side and the rectifying element mounting surface part on the back surface side;
A third bus bar for connecting the rectifying elements at different positions in series on the front surface side rectifying element mounting surface part and the back surface side rectifying element mounting surface part;
A cooling water supply device for supplying cooling water to the water passage section of the water cooling fin;
A high voltage device comprising:
前記第1のブスバーは、帯状導体の両端部をそれぞれL字形に折曲すると共に、その両方の折曲方向が逆となるようにし、前記両折曲部の両端部にこの折曲部と直交方向に前記整流素子の電極と接続する端子接続部を備え、
前記第2のブスバーは、帯状導体をU字形に折曲すると共に、前記整流素子の電極と接続する端子接続部を備え、
前記第3のブスバーは、帯状導体の両端部をそれぞれU字形に折曲すると共に、この両端部に前記整流素子の電極と接続する端子接続部を備え、且つこの端子接続部との連結部は傾斜部となっている請求項に記載の高電圧装置。
The first bus bar bends both ends of the belt-like conductor into L-shapes, and the bending directions of both are reversed, and both the bent portions are orthogonal to the bent portions. Comprising a terminal connection for connecting to the electrode of the rectifying element in the direction;
The second bus bar includes a terminal connection portion that bends the strip-shaped conductor into a U shape and connects to the electrode of the rectifying element,
The third bus bar is provided with a terminal connection portion connected to the electrode of the rectifying element at both ends of the belt-like conductor, and a connecting portion with the terminal connection portion. The high voltage device according to claim 1 , wherein the high voltage device is an inclined portion.
前記各整流素子に、それぞれの過渡及び直流電圧の分担を均等化するための抵抗とコンデンサを並列接続してなる電圧分担回路を並列に接続した請求項1又は2に記載の高電圧装置。 The high voltage apparatus according to claim 1 or 2 , wherein a voltage sharing circuit formed by connecting a resistor and a capacitor for equalizing the sharing of each transient and DC voltage in parallel is connected in parallel to each of the rectifying elements. 前記水冷却フィンにおける整流素子取付面部の表面側及び裏面側に配設するモジュール型整流素子を導電性ねじによりそれぞれ取付け、前記導電性ねじにより前記表面の整流素子及び裏面の整流素子を接続するブスバーを兼ねるようにした請求項1〜3のいずれか一項記載の高電圧装置。 The module type rectifying element disposed on the front side and the back side of the rectifying element mounting surface portion of the water cooling fin is attached by a conductive screw, and the bus bar connects the front side rectifying element and the back side rectifying element by the conductive screw. The high-voltage device according to any one of claims 1 to 3 , wherein the high-voltage device is also used. 前記水冷却フィンに有する通水路部を形成している端部壁面に、雌ねじを形成し、前記雌ねじに螺合される雄ねじを有する継手により、前記冷却水供給装置と接続し、前記通水路部に冷却水を供給するように構成した請求項1〜4のいずれか一項記載の高電圧装置。 The end wall surface forming the water passage portion of the water cooling fin is formed with a female screw and connected to the cooling water supply device by a joint having a male screw screwed to the female screw, and the water passage portion high voltage apparatus according to any one claim of construction claims 1-4 so as to supply cooling water to. 前記継手は平行な雄ねじを形成すると共に、前記継手の先端部であって前記水冷却フィンの通水路部と当接する端部に、Oリング装着溝を形成し、前記Oリング装着溝にOリングを装着した状態で、前記継手を前記通水路部の雌ねじに螺合させた請求項に記載の高電圧装置。 The joint forms parallel male threads, and an O-ring mounting groove is formed at an end of the joint that is in contact with the water passage portion of the water cooling fin, and an O-ring is formed in the O-ring mounting groove. The high-voltage apparatus according to claim 5 , wherein the joint is screwed into the female screw of the water passage section in a state where is attached.
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