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JP6030861B2 - Residential distribution board - Google Patents

Residential distribution board Download PDF

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JP6030861B2
JP6030861B2 JP2012132116A JP2012132116A JP6030861B2 JP 6030861 B2 JP6030861 B2 JP 6030861B2 JP 2012132116 A JP2012132116 A JP 2012132116A JP 2012132116 A JP2012132116 A JP 2012132116A JP 6030861 B2 JP6030861 B2 JP 6030861B2
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distribution board
conductive
heat dissipating
conductive bar
heat
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JP2013258816A (en
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三輪 修
三輪  修
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河村電器産業株式会社
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Description

本発明は住宅用分電盤に関し、特に分岐ブレーカを接続するために配設された単相3線式電路の3本の導電バーが重ねて配置された住宅用分電盤に関する。   The present invention relates to a residential distribution board, and more particularly, to a residential distribution board in which three conductive bars of a single-phase three-wire circuit arranged to connect a branch breaker are stacked.

住宅用分電盤は、近年の電気設備の増加や過電流警報機能等の高機能化を受けて、決められたスペースにおける分岐ブレーカ等の高密度収納が進んでいる。図4は、このような背景から、単3線式電路Lを構成する3本の導電バー11を高密度収納のために重ねて配設し、この導電バー11に分岐ブレーカ12を接続した一例を示している。
図4に示すように、3本の導電バー11を重ねて配置し、その両脇に分岐ブレーカ12を列設した場合、導電バー11の発熱も顕著になるため放熱対策が必要となってきた。この放熱対策として、特許文献1にあるように導電バーの端部に複数のスリットを設けて表面積を増やす構成や、特許文献2に開示されているように、導電バー11の幅を広くして放熱効率を高める構成があった。
Residential distribution boards are receiving high-density storage of branch breakers and the like in a predetermined space in response to the recent increase in electrical facilities and high functionality such as overcurrent alarm functions. FIG. 4 shows an example in which three conductive bars 11 constituting the AA wire circuit L are arranged in a stacked manner for high-density storage and a branch breaker 12 is connected to the conductive bars 11 from such a background. Is shown.
As shown in FIG. 4, when the three conductive bars 11 are stacked and the branch breakers 12 are arranged on both sides thereof, the heat generation of the conductive bars 11 becomes significant, so that a heat dissipation measure has been required. . As a heat dissipation measure, as disclosed in Patent Document 1, a plurality of slits are provided at the end of the conductive bar to increase the surface area, and as disclosed in Patent Document 2, the width of the conductive bar 11 is increased. There was a configuration that increased heat dissipation efficiency.

特開2002−171619号公報JP 2002-171619 A 特開2001−157324号公報JP 2001-157324 A

しかしながら、上記特許文献1の構成の場合、導電バー端部の発熱を抑制することはできたが、分岐ブレーカが列設された狭い空間での導電バーの温度上昇まで十分に抑制することはできなかった。
また、特許文献2の場合、導電バーの幅を広くすることで、分岐ブレーカが列設された狭い空間の温度上昇を抑制することは可能であるが、導電バーを形成する銅等の金属の使用量が増加する為、コストアップを招いたし、導電バーの広い設置空間が必要であり、分電盤の大きな設計変更を必要とした。
However, in the case of the configuration of Patent Document 1, although heat generation at the end portion of the conductive bar could be suppressed, it was possible to sufficiently suppress the temperature rise of the conductive bar in the narrow space where the branch breakers were arranged. There wasn't.
In the case of Patent Document 2, it is possible to suppress the temperature rise in the narrow space where the branch breakers are arranged by increasing the width of the conductive bar, but the metal such as copper forming the conductive bar As the amount used increased, the cost was increased, a large installation space for the conductive bar was required, and a large design change of the distribution board was required.

そこで、本発明はこのような問題点に鑑み、大きな設計変更をすることなく導電バーの発熱を抑制できる住宅用分電盤を提供することを目的としている。   Then, in view of such a problem, an object of the present invention is to provide a residential distribution board that can suppress heat generation of a conductive bar without making a major design change.

上記課題を解決する為に、請求項1の発明は、3本の導電バーを重ねて配置し、左右或いは上下方向に帯状に延設した単相3線式電路に対し、その両脇に複数の分岐ブレーカを配設して単相3線式電路の分岐電路を形成した住宅用分電盤において、導電バーの放熱を促進させるために重ねられた導電バーの間に放熱部材を配置してなり、放熱部材は、熱放射率が特定の値以上の絶縁性放熱材で少なくとも表面が覆われると共に、重ねて配置された導電バーの長さに合わせた寸法で形成された棒体であり、少なくとも一方の導電バーに密着して配置されたことを特徴とする。
この構成によれば、熱放射率が特定の値以上の放熱部材を導電バーの間に配置することで、導電バーの放熱が促進される。よって、導電バーを重ねて配置しても、導電バーの幅を広くする等の大きな設計変更をすること無く発熱による温度上昇を抑制することが可能となる。
In order to solve the above-mentioned problem, the invention of claim 1 is directed to a single-phase three-wire electric circuit in which three conductive bars are stacked and extended in a strip shape in the left-right or vertical direction. In a residential distribution board in which a branch breaker is provided to form a branch circuit of a single-phase three-wire circuit, a heat dissipating member is disposed between the stacked conductive bars to promote heat dissipation of the conductive bars. becomes, the heat dissipation member, the thermal emissivity of at least the surface is covered with a specific value or more insulating heat dissipating material Rutotomoni, Cascade be a rod made of a size tailored to the length of the arranged conductive bar Further, it is characterized in that it is arranged in close contact with at least one of the conductive bars.
According to this configuration, the heat dissipation of the conductive bar is promoted by disposing the heat dissipation member having a thermal emissivity of a specific value or more between the conductive bars. Therefore, even if the conductive bars are stacked, the temperature rise due to heat generation can be suppressed without making a major design change such as increasing the width of the conductive bars.

請求項2の発明は、請求項1に記載の構成において、前記分岐ブレーカは、分電盤ケース背面上に配置された金属製パネルに取り付けられ、最奥部の前記導電バーと前記パネルの間にも前記放熱部材を配置してなることを特徴とする。
この構成によれば、最奥部の導電バーの放熱も促進されるため、重ねられた導電バーの奥部の発熱による温度上昇も抑制できる。
According to a second aspect of the present invention, in the configuration according to the first aspect, the branch breaker is attached to a metal panel disposed on the rear surface of the distribution board case, and is located between the conductive bar at the innermost portion and the panel. Further, the heat dissipation member is arranged.
According to this configuration, the heat radiation of the innermost conductive bar is also promoted, so that the temperature rise due to the heat generation at the innermost part of the stacked conductive bars can be suppressed.

請求項3の発明は、請求項2に記載の構成において、前記最奥部の導電バーと前記パネルの間に配置される放熱部材の絶縁性放熱材は、所定値以上の熱伝導率を有し、前記放熱部材は配置する隙間に合わせた厚みを有して前記導電バーと前記パネルの双方に密着することを特徴とする。
この構成によれば、放熱部材は熱伝導率が所定値以上であってパネルにも密着する為、最奥部の導電バーは、放熱部材を介してパネルに放熱できる。よって、分電盤奥部に配置された導電バーの発熱を良好に放熱させることが可能となる。
According to a third aspect of the present invention, in the configuration of the second aspect, the insulating heat radiating material of the heat radiating member disposed between the innermost conductive bar and the panel has a thermal conductivity of a predetermined value or more. The heat dissipating member has a thickness corresponding to the gap to be disposed and is in close contact with both the conductive bar and the panel.
According to this structure, since the heat dissipation member has a thermal conductivity equal to or higher than a predetermined value and is in close contact with the panel, the innermost conductive bar can dissipate heat to the panel via the heat dissipation member. Therefore, it is possible to favorably dissipate the heat generated by the conductive bar disposed at the back of the distribution board.

請求項4の発明は、請求項1乃至3の何れかに記載の構成において、前記導電バー間に配置される放熱部材の絶縁性放熱材は、所定値以上の熱伝導率を有し、前記放熱部材は導電バーの間隔に合わせた厚みを有して前後双方の導電バーに密着することを特徴とする。
この構成によれば、放熱部材は熱伝導率が所定値以上であって双方の導電バーに密着するため、導電バー間の熱伝達を良好に実施でき、内部の導電バーの放熱を最前部の導電バーを介して良好に放熱させることが可能となる。
Invention of Claim 4 is the structure in any one of Claims 1 thru | or 3. The insulating heat dissipation material of the heat radiating member arrange | positioned between the said conductive bars has thermal conductivity more than predetermined value, The said The heat dissipating member has a thickness matched to the interval between the conductive bars and is in close contact with both the front and rear conductive bars.
According to this configuration, since the heat dissipation member has a thermal conductivity equal to or higher than a predetermined value and is in close contact with both conductive bars, heat transfer between the conductive bars can be carried out satisfactorily, and the heat dissipation of the internal conductive bars can be performed at the forefront. It becomes possible to radiate heat well through the conductive bar.

本発明によれば、放熱部材を導電バーの間に配置することで、導電バーの放熱が促進される。よって、導電バーを重ねて配置しても導電バーの幅を広くする等の大きな設計変更をすること無く発熱による温度上昇を抑制することができる。   According to the present invention, the heat dissipation of the conductive bar is promoted by disposing the heat dissipation member between the conductive bars. Therefore, even if the conductive bars are stacked, the temperature rise due to heat generation can be suppressed without making a major design change such as increasing the width of the conductive bars.

本発明に係る住宅用分電盤の一例を示す部分斜視図である。It is a fragmentary perspective view which shows an example of the distribution board for houses concerning this invention. 図1の分岐ブレーカを右側から見た側面図である。It is the side view which looked at the branch breaker of FIG. 1 from the right side. 放熱部材を示し、(a)は平面図、(b)は側面図である。A heat radiating member is shown, (a) is a top view, (b) is a side view. 従来の住宅用分電盤の説明図である。It is explanatory drawing of the conventional distribution board for houses.

以下、本発明を具体化した実施の形態を、図面を参照して詳細に説明する。図1は本発明に係る住宅用分電盤の一例を示す部分斜視図であり、単相3線式電路と分岐ブレーカの関係を示している。図1において、1は商用電力系統からの引き込み線が接続される主幹ブレーカ、2は分岐ブレーカ、3は2本の電圧線及び中性線から成る単相3線式電路Lを構成する導電バー、4は放熱部材であり、主幹ブレーカ1及び分岐ブレーカ2は分電盤底部に配置された金属製パネル5に組み付けられている。   DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments embodying the present invention will be described below in detail with reference to the drawings. FIG. 1 is a partial perspective view showing an example of a residential distribution board according to the present invention, and shows a relationship between a single-phase three-wire circuit and a branch breaker. In FIG. 1, 1 is a main breaker to which a lead-in line from a commercial power system is connected, 2 is a branch breaker, 3 is a conductive bar constituting a single-phase three-wire circuit L composed of two voltage lines and a neutral line. Reference numeral 4 denotes a heat radiating member, and the main breaker 1 and the branch breaker 2 are assembled to a metal panel 5 arranged at the bottom of the distribution board.

尚、図1では分岐ブレーカ2は多数設置されたうちの主幹ブレーカ1寄りの一対のみ示し、導電バー3及び放熱部材4は途中で切断した状態を示している。また、6は露出した導電バー3を保護する電路カバーであるし、図示しない分電盤ケースや分岐ブレーカ2の負荷側端子21に接続された二次配線等は省略してある。また、図1において、図面上方が分電盤前方であり、パネル5が配設された底部が分電盤が取り付けられる壁面側となる。   In FIG. 1, only a pair of branch breakers 2 near the main breaker 1 is shown, and the conductive bar 3 and the heat radiating member 4 are cut in the middle. Reference numeral 6 denotes an electric circuit cover for protecting the exposed conductive bar 3, and a distribution board case (not shown), secondary wiring connected to the load side terminal 21 of the branch breaker 2, and the like are omitted. Further, in FIG. 1, the upper side of the drawing is the front of the distribution board, and the bottom portion on which the panel 5 is disposed is the wall surface side to which the distribution board is attached.

単相3線式電路Lは、3枚の導電バー3を重ねて配設して構成され、左右方向に延設されている。この電路Lに沿うように上部及び下部に分岐ブレーカ2が列設され、その電源側端子22が個々に導電バー3に接続される。分岐ブレーカ2は、パネル5に組み付けられて分電盤ケース背面上に配設される。但し、電路Lが縦に配設された分電盤の場合は、分岐ブレーカ2も縦に列設される。
導電バー3は、銅板を打ち抜いて形成したものが通常使用され、主幹ブレーカ1の二次側端子からこの導電バー3で形成される単相3線式電路Lは配設されている。そして、分岐ブレーカ2が配設される部位の導電バー3は直線状に配設されている。
The single-phase three-wire electric circuit L is configured by arranging three conductive bars 3 so as to extend in the left-right direction. The branch breakers 2 are arranged in the upper and lower portions along the electric path L, and the power source side terminals 22 are individually connected to the conductive bars 3. The branch breaker 2 is assembled to the panel 5 and disposed on the rear surface of the distribution board case. However, in the case of a distribution board in which the electric circuit L is arranged vertically, the branch breakers 2 are also arranged vertically.
The conductive bar 3 is usually formed by punching a copper plate, and a single-phase three-wire circuit L formed by the conductive bar 3 from the secondary side terminal of the main breaker 1 is disposed. And the conductive bar 3 of the site | part by which the branch breaker 2 is arrange | positioned is arrange | positioned linearly.

放熱部材4は導電バー3の間及び導電バー3とパネル5の間に配置されている。図2は図1の分岐ブレーカ2を右側から見た側面図であり、図2に示すように放熱部材4は上下の導電バー3に密着するように、また導電バー3とパネル5に密着するように配置されている。   The heat dissipation member 4 is disposed between the conductive bars 3 and between the conductive bars 3 and the panel 5. 2 is a side view of the branch breaker 2 of FIG. 1 as viewed from the right side. As shown in FIG. 2, the heat radiating member 4 is in close contact with the upper and lower conductive bars 3 and in close contact with the conductive bars 3 and the panel 5. Are arranged as follows.

図3は放熱部材4単体を示し、(a)は平面図、(b)は側面図である。図3に示すように、放熱部材4は断面略四角形の棒状体であり、重ねて配置された導電バー3の長さ及び隙間に合わせた寸法で形成され、合成樹脂製の角材4aをシート状の絶縁性放熱材4bで被覆して形成されている。
具体的に、3本の導電バー2で形成される2箇所の空間の間隔(奥行き)は図2に示すように同一の幅W1(第1の幅)で形成され、最下部の導電バー3とパネル5の間の間隔W2(第2の幅)は第1の幅W1とは異なっているが、放熱部材4の断面を長方形状として高さを第1の幅W1、幅を第2の幅W2とすることで、1種類の形状で対応させている。
FIG. 3 shows the heat radiating member 4 alone, (a) is a plan view, and (b) is a side view. As shown in FIG. 3, the heat radiating member 4 is a rod-shaped body having a substantially square cross section, and is formed with a dimension matching the length and gap of the conductive bar 3 arranged in an overlapping manner, and a square member 4a made of synthetic resin is formed into a sheet shape. Insulating heat dissipation material 4b is formed.
Specifically, the space (depth) between the two spaces formed by the three conductive bars 2 is formed with the same width W1 (first width) as shown in FIG. The space W2 (second width) between the panel 5 and the panel 5 is different from the first width W1, but the heat radiating member 4 has a rectangular cross section and the height is the first width W1 and the width is the second width. By using the width W2, one type of shape is used.

尚、図3に示す溝41は、導電バー3にネジ(図示せず)が螺入された場合の突起を避けるために設けられたもので、一辺のみ長さ方向に形成されている。また、角材4aは、僅かに弾性を有する合成樹脂で作成すると良く、導電バー3に良好に密着させることができ好ましい。   Note that the groove 41 shown in FIG. 3 is provided in order to avoid a protrusion when a screw (not shown) is screwed into the conductive bar 3, and is formed in the length direction only on one side. Also, the square member 4a is preferably made of a slightly elastic synthetic resin, which is preferable because it can be satisfactorily adhered to the conductive bar 3.

角材4aを被覆する絶縁性放熱材4bは、樹脂製シート上に放熱部材を混入した粘着材を塗布したもので、一例としてTGM社製のTera−5シートが使用できる。このシートは、具体的に熱伝導率λ=170W/mk、熱放射率ε=0.97、の特性を有し、例えば厚み6μmの樹脂シートに25μmの厚さでTera−5フィラーを混入した粘着材を添付して形成されている。
尚、銅の熱伝導率λ=398W/mk、空気の熱伝導率は約0.6W/mkである。また、銅(研磨面)の熱放射率ε=0.02〜0.04、銅(酸化面)の熱放射率ε=0.5であり、熱放射率は1.0に近いほど熱放射率が高く、熱を発散し易い。
The insulating heat radiating material 4b covering the square 4a is obtained by applying an adhesive material mixed with a heat radiating member on a resin sheet. As an example, a Tera-5 sheet manufactured by TGM can be used. Specifically, this sheet has characteristics of thermal conductivity λ = 170 W / mk and thermal emissivity ε = 0.97. For example, a Tera-5 filler is mixed in a thickness of 25 μm in a resin sheet having a thickness of 6 μm. It is formed with an adhesive.
Note that the thermal conductivity of copper is λ = 398 W / mk, and the thermal conductivity of air is about 0.6 W / mk. Further, the thermal emissivity ε = 0.02 to 0.04 of copper (polished surface), the thermal emissivity ε = 0.5 of copper (oxidized surface), and the closer to 1.0, the thermal radiation High rate and easy to dissipate heat.

このように、熱放射率が0.97と銅の熱放射率より高い放熱部材4を導電バー3の間に配置することで、導電バー3の放熱が促進される。よって、導電バー3を重ねて配置しても、導電バー3の幅を広くする等の大きな設計変更をすること無く発熱による温度上昇を抑制することが可能となる。
また、最奥部の導電バー3とパネル5の間にも放熱部材4を配置することで、最奥部の導電バー3の放熱も促進され、重ねられた導電バー3の奥部の発熱による温度上昇も抑制できる。
更に、放熱部材4の熱伝導率が170W/mkであるため、前後の導電バー3に密着することで、導電バー3間の熱伝達を良好に実施でき、内部の導電バー3の放熱を最前部の導電バー3を介して良好に放熱できるし、パネル5と導電バー3の双方に密着する為、パネル5を介しても放熱が促進される。よって、分電盤奥部の発熱を良好に放熱でき、内部に熱がこもるのを防止できる。
In this manner, by disposing the heat radiation member 4 having a thermal emissivity of 0.97, which is higher than the thermal emissivity of copper, between the conductive bars 3, the heat dissipation of the conductive bar 3 is promoted. Therefore, even if the conductive bars 3 are stacked, the temperature rise due to heat generation can be suppressed without making a major design change such as increasing the width of the conductive bars 3.
Further, by disposing the heat dissipating member 4 between the innermost conductive bar 3 and the panel 5, heat radiation of the innermost conductive bar 3 is also promoted, and heat is generated by the innermost part of the stacked conductive bar 3. Temperature rise can also be suppressed.
Furthermore, since the heat conductivity of the heat dissipating member 4 is 170 W / mk, the heat transfer between the conductive bars 3 can be carried out well by closely contacting the front and rear conductive bars 3, and the heat dissipation of the internal conductive bars 3 is most advanced. The heat can be radiated well through the conductive bar 3 of the portion, and the heat is radiated even through the panel 5 because it is in close contact with both the panel 5 and the conductive bar 3. Therefore, the heat generation at the back of the distribution board can be radiated well, and the heat can be prevented from being accumulated inside.

尚、上記実施形態は、導電バー3間に配置した放熱部材4は前後の導電バー3に密着させているが、一方の導電バー3のみに密着させるだけでも、導電バー3の放熱には有効である。放熱部材4の放熱機能により、密着させた導電バー3の放熱を加速させるのは勿論、隣接する導電バー3の熱も空気層を介して熱を奪うため、放熱が加速される。
これは、導電バー3とパネル5の間に設けた放熱部材4に対しても同様であり、導電バー3或いはパネル5の一方に密着させるだけでも放熱に有効となる。
そして、このように一方のみに密着させる構成の場合、放熱部材4は熱放射率が高ければ良く、熱伝導率は低くても良い。具体的に、熱放射率は、1.0に近い値であれば勿論好ましいが、導電バー3を構成する部材より大きな値であれば良く、上記実施形態では銅を使用しているため、銅を超える熱放射率特性を有する物質であれば有効である。そのため、酸化銅の熱放射率より大きな値である0.5以上であれば導電バー3の発熱の抑制に有効である。
In the above embodiment, the heat dissipating member 4 disposed between the conductive bars 3 is in close contact with the front and rear conductive bars 3. It is. The heat radiation function of the heat radiating member 4 not only accelerates the heat radiation of the conductive bars 3 that are in close contact with each other, but also the heat of the adjacent conductive bars 3 takes the heat through the air layer, so the heat radiation is accelerated.
The same applies to the heat radiating member 4 provided between the conductive bar 3 and the panel 5, and it is effective for heat dissipation only by contacting the conductive bar 3 or the panel 5.
In the case where the heat-dissipating member 4 is in close contact with only one side as described above, the heat dissipation member 4 may have a high thermal emissivity and may have a low thermal conductivity. Specifically, the thermal emissivity is preferably a value close to 1.0, but may be a value larger than that of the members constituting the conductive bar 3, and copper is used in the above embodiment. Any substance having a thermal emissivity characteristic exceeding 1 is effective. Therefore, if it is 0.5 or more, which is a value larger than the thermal emissivity of copper oxide, it is effective for suppressing heat generation of the conductive bar 3.

また、双方の導電バー3に密着させる構成、或いは導電バー3とパネル5に密着させる構成の場合、熱伝導率が空気の熱伝導率(λ=0.6W/mk)より大きければ有効であるが、100W/mk以上であれば確実に放熱が促進され好ましい。   Further, in the case of a configuration in which the conductive bars 3 are in close contact with each other, or a configuration in which the conductive bars 3 and the panel 5 are in close contact, it is effective if the thermal conductivity is larger than the thermal conductivity of air (λ = 0.6 W / mk). However, if it is 100 W / mk or more, heat dissipation is surely promoted, which is preferable.

2・・分岐ブレーカ、3・・導電バー、4・・放熱部材、5・・パネル、5b・・絶縁性放熱材。   2 .... Branch breaker, 3 .... Conductive bar, 4 .... Heat dissipating member, 5 .... Panel, 5b .... Insulating heat dissipating material.

Claims (4)

3本の導電バーを重ねて配置し、左右或いは上下方向に帯状に延設した単相3線式電路に対し、その両脇に複数の分岐ブレーカを配設して前記単相3線式電路の分岐電路を形成した住宅用分電盤において、
前記導電バーの放熱を促進させるために重ねられた導電バーの間に放熱部材を配置してなり、
前記放熱部材は、熱放射率が特定の値以上の絶縁性放熱材で少なくとも表面が覆われると共に、重ねて配置された前記導電バーの長さに合わせた寸法で形成された棒体であり、少なくとも一方の導電バーに密着して配置されたことを特徴とする住宅用分電盤。
A single-phase three-wire electric circuit in which a plurality of branch breakers are arranged on both sides of a single-phase three-wire electric circuit that is formed by overlapping three conductive bars and extending in a strip shape in the left-right or vertical direction. In a residential distribution board that forms a branch circuit of
A heat dissipating member is disposed between the conductive bars stacked to promote heat dissipation of the conductive bar,
The heat dissipation member, the thermal emissivity is at least surface covered by a specific value or more insulating heat dissipating material Rutotomoni, Cascade be a rod made of a size tailored to the length of the arranged the conductive bar A residential distribution board characterized by being disposed in close contact with at least one conductive bar.
前記分岐ブレーカは、分電盤ケース背面上に配置された金属製パネルに取り付けられ、最奥部の前記導電バーと前記パネルの間にも前記放熱部材を配置してなることを特徴とする請求項1記載の住宅用分電盤。 The said branch breaker is attached to the metal panel arrange | positioned on the distribution board case back surface, The said heat radiating member is arrange | positioned also between the said electrically conductive bar of the innermost part, and the said panel, It is characterized by the above-mentioned. Item 1. A distribution board for residential use according to Item 1. 前記最奥部の導電バーと前記パネルの間に配置される前記放熱部材の絶縁性放熱材は、所定値以上の熱伝導率を有し、前記放熱部材は配置する隙間に合わせた厚みを有して前記導電バーと前記パネルの双方に密着することを特徴とする請求項2記載の住宅用分電盤。 The insulating heat dissipating material of the heat dissipating member disposed between the innermost conductive bar and the panel has a thermal conductivity equal to or higher than a predetermined value, and the heat dissipating member has a thickness according to the gap to be disposed. The residential distribution board according to claim 2, wherein the residential distribution board is in close contact with both the conductive bar and the panel. 前記導電バー間に配置される前記放熱部材の絶縁性放熱材は、所定値以上の熱伝導率を有し、前記放熱部材は導電バーの間隔に合わせた厚みを有して前後双方の導電バーに密着することを特徴とする請求項1乃至3の何れかに記載の住宅用分電盤。 The insulating heat dissipating material of the heat dissipating member disposed between the conductive bars has a thermal conductivity equal to or greater than a predetermined value, and the heat dissipating member has a thickness corresponding to the interval between the conductive bars, and both the front and rear conductive bars. The residential distribution board according to any one of claims 1 to 3, wherein the residential distribution board is closely attached to the housing.
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