JP4974169B2 - Plug-in bus duct - Google Patents

Description

  The present invention relates to an air-insulated plug-in bus duct.

  The air-insulated bus duct is a metal duct in which a plurality of bare bus bars are arranged in parallel via an insulating support. The length of one unit of the bus duct is generally 2.5 m or 3 m, and a plurality of units of the bus duct are connected to be used as a power line in a factory or the like. A plug-in device or a bolt-on device (hereinafter collectively referred to as a plug-in device) is attached to a location where an electrical branch is taken from the bus duct. A plug-in hole is formed in the duct at a portion where the plug-in device is attached. A plurality of plug-in holes are formed at an appropriate interval in one unit of bus duct, and plug-in holes to which plug-in devices are not attached are closed with a hole cover (see Patent Document 1).

  Specific examples of conventional plug-in bus ducts are shown in FIGS. In the figure, reference numeral 1 denotes a metal duct, which includes a front plate 1a, a back plate 1b, an upper plate 1c, and a lower plate 1d. 2A, 2B, and 2C are bare bus bars made of a strip-shaped conductor, and 3A and 3B are insulating supports that support the plurality of bus bars 2A to 2C in the duct 1 in parallel.

  The front plate 1a and the back plate 1b of the duct 1 are alternately formed with plug-in holes 4 at a predetermined interval in the longitudinal direction (the plug-in holes may be formed only on the front plate). The plug-in hole 4 is a part to which a plug-in device (not shown) is attached, but in the product shipment state, all the plug-in holes 4 are closed by the hole cover 5 as shown in FIG. When the plug-in device is attached after the power supply line is constructed at the delivery destination, the hole cover 5 at that portion is removed and the plug-in device is attached.

  The insulating support 3 is divided into an insulating support 3a on the plug-in hole 4 side and an insulating support 3b on the opposite side. Both insulating supports 3a and 3b are provided with bus bar mounting grooves 6 at opposite positions, and the bus bars 2A to 2C are supported by sandwiching both sides of the bus bars 2A to 2C. In this example, both insulating supports 3a and 3b are formed in a rectangular cylindrical shape, and the insulating support 3a on the plug-in hole 4 side has an end face on the plug-in hole 4 side as shown in FIG. A rib 7 is projected from the inner peripheral portion. The insulating support 3a on the plug-in hole 4 side is installed in the duct 1 with the rib 7 fitted in the plug-in hole 4 as shown in FIG. Since the insulating support 3b on the opposite side is also installed at the same position in the longitudinal direction of the duct, the plug-in hole 4 is surrounded by an insulating wall.

  The height of the rib 7 is set slightly higher than the thickness of the metal plate constituting the duct 1. For this reason, when the rib 7 is fitted into the plug-in hole 4, the tip of the rib 7 slightly protrudes from the surface of the duct 1. The hole cover 5 is formed with a rectangular bulge 8 so as to absorb the protrusion of the rib 7. The periphery of the hole cover 5 is flat so as to make surface contact with the surface of the duct 1.

JP 2004-229358 A

  When the bus duct is energized, the bus bar generates heat. In the air-insulated plug-in bus duct, heat generated in the bus bar is transmitted to the duct and the hole cover via the air in the duct, and is radiated from the surface of the duct and the hole cover to the atmosphere. However, heat transfer from the bus bar to the duct and the hole cover is heat transfer through the air confined in the duct, and therefore the heat dissipation efficiency is poor. For this reason, it is difficult for the conventional plug-in bus duct to suppress the temperature rise of the bus bar.

  An object of the present invention is to provide a plug-in bus duct capable of increasing the heat radiation efficiency of heat generated in a bus bar and suppressing the temperature rise of the bus bar lower than before.

To achieve the above object, according to the present invention, a plurality of bare bus bars are arranged in parallel in a metal duct having a plug-in hole via an insulating support, and a hole cover for closing the plug-in hole is attached to the duct. In the plug-in bus duct
The insulating support that supports the bus bar on both sides of the longitudinal direction of the duct of the plug-in hole has a concave groove on the end surface on the plug-in hole side, and the hole cover that closes the plug-in hole is between the duct It has a gap, and an air passage that leads from the inside of the duct to the outside of the duct is formed by the concave groove and the gap.

  In the plug-in bus duct according to the present invention, it is preferable that a plurality of concave grooves on the end surface of the insulating support on the plug-in hole side are provided.

  In the plug-in bus duct according to the present invention, it is preferable that the edges of the ducts on both sides in the longitudinal direction of the plug-in hole are located in the middle in the longitudinal direction of the concave groove.

  In the plug-in bus duct according to the present invention, it is preferable that the dimension of the gap provided between the hole cover and the duct in the longitudinal direction of the duct is larger than the longitudinal dimension of the concave groove.

  In the plug-in bus duct according to the present invention, the insulating support has a rectangular cylindrical shape, and is composed of an insulating support on the plug-in hole side and an insulating support on the opposite side, and the insulating support on the plug-in hole side. Preferably, a rib that fits into the plug-in hole is provided on the inner peripheral portion of the end surface on the plug-in hole side, and the concave groove is formed in a portion other than the rib on the end surface. .

  Moreover, in the plug-in bus duct according to the present invention, it is more preferable that a through hole communicating with the concave groove is formed in a wall on the base side of the rib of the insulating support.

  According to the present invention, since the air passage that leads from the inside of the duct to the outside of the duct is formed using the plug-in hole, the air in the duct heated by the heat generated by the bus bar passes through the air passage at the top of the duct to the outside of the duct. The discharged air is discharged into the duct through the air passage below the duct. For this reason, the air in the duct is replaced with the low-temperature air outside the duct, and the heat generated in the bus bar can be efficiently radiated to the outside of the duct, and the temperature rise of the bus bar can be suppressed lower than before. As a result, the current capacity can be increased or the bus bar sectional area can be reduced.

  Further, when the edges of the ducts on both sides in the longitudinal direction of the plug-in hole are positioned in the middle of the longitudinal direction of the concave groove, the air passage is U-turned at the edge of the plug-in hole from the inner surface side of the duct and the duct Therefore, it is less likely that dust or the like enters the duct from the outside.

  Moreover, if the dimension of the gap provided in the hole cover in the longitudinal direction of the duct is made larger than the longitudinal dimension of the groove, it is possible to reduce the possibility of dust and the like entering the duct from the outside.

  In addition, a rib that fits into the plug-in hole protrudes from an inner peripheral portion of the end surface of the insulating support on the plug-in hole side, and the concave groove is formed in a portion other than the rib on the end surface. Therefore, there is less risk of dust and the like entering the duct.

<Embodiment 1> FIG.1 and FIG.2 shows one Embodiment of this invention. 1 and 2, the same parts as those in FIGS. 4 to 5 described above are denoted by the same reference numerals, and redundant description is omitted.

  This plug-in bus duct is different from the conventional plug-in bus duct in that (a) the plug-in of the insulating support 3a on the plug-in hole 4 side is located on both sides of the plug-in hole 4 (both sides in the longitudinal direction of the duct). A plurality of concave grooves 9 are formed in the longitudinal direction of the duct excluding the ribs 7 on the end surface on the hole 4 side (the end surface on which the ribs 7 project), and (b) the duct of the plug-in hole 4 The edge E is positioned in the middle in the longitudinal direction of the concave groove 9, and (c) the portion overlapping the duct 1 on the concave groove 9 on both sides of the hole cover 5 is bulged outward, and the concave groove 9 The gap S is provided between the upper duct 1 and the upper duct 1.

  In addition, in order to position the edge E of the duct on both sides in the longitudinal direction of the plug-in hole 4 in the middle of the longitudinal direction of the concave groove 9, the walls on both sides in the longitudinal direction of the insulating support 3a are formed thicker than before. The distance between the edges of the ducts on both sides of the plug-in hole 4 in the longitudinal direction of the duct is wider than in the prior art.

  The number of the recessed grooves 9 is larger than the number of bus bars 2A to 2C (three in this embodiment). The dimension in the longitudinal direction of the duct of the gap S provided between the hole cover 5 and the duct 1 is set to be larger than the longitudinal dimension of the concave groove.

  If comprised as mentioned above, it will pass through the concave groove 9 from the inside of the duct 1, and will make a U-turn at the edge E of the plug-in hole 4, and will go around to the outer surface side of the duct 1, and the air path which leads outside the duct 1 will be formed. . For this reason, the air in the duct 1 heated by the heat generated by the bus bars 2A to 2C rises in the duct 1 and is discharged out of the duct 1 through the air passage at the top of the duct. It enters the duct 1 from the outside through the lower air passage. That is, an air flow as shown by arrows in FIGS. 1C and 1D is generated. For this reason, the air in the duct 1 is replaced with the low-temperature air outside the duct 1, and the heat generated in the bus bars 2 </ b> A to 2 </ b> C can be efficiently radiated to the outside of the duct 1. Can be kept lower.

<Embodiment 2> In Embodiment 1, since the air in the plug-in hole 4 is surrounded by the rectangular cylindrical insulating support 3, it is difficult to replace it with outside air (the tip of the rib 7 and the hole cover 5). If there is a gap between the bulging portion 8 and the bulging portion 8, it will be replaced a little through the gap). In order to easily replace the air in the plug-in hole 4 with the air outside the duct 1, the insulating support 3a on the plug-in hole 4 side may be configured as shown in FIG. The insulating support 3 a is formed by forming a through hole 10 communicating with the groove 9 on the base side wall of the rib 7. If it does in this way, the air in plug-in hole 4 will also become easy to change, and the effect which controls the temperature rise of bus bars 2A-2C will become higher than Embodiment 1. Since the configuration other than the above is the same as that of the first embodiment, the description thereof is omitted.

The principal part of one Embodiment of the plug-in bus duct which concerns on this invention is shown, (A) is a partially cutaway front view, (B) is a top view, (C) is CC sectional view taken on the line of (A), (D) is the DD sectional view taken on the line of (A). 1 shows an insulating support on the plug-in hole side used in the plug-in bus duct of FIG. 1, (A) is a front view, (B) is a view taken along line BB of (A), and (C) is a view of (A). CC arrow directional view. The other embodiment of the insulation support body by the side of the plug-in hole used for the plug-in bus duct which concerns on this invention is shown, (A) is a front view, (B) is a BB line arrow directional view of (A), (C ) Is a view taken along the line CC of (A). An example of the conventional plug-in bus duct is shown, (A) is a front view, (B) is a bottom view. FIG. 4A is a partially cutaway front view, FIG. 4B is a plan view, FIG. 4C is a cross-sectional view along line CC of FIG. 4A, and FIG. D-D sectional view taken on the line of FIG. The plug-in-hole side insulating support used for the plug-in bus duct of FIG. 4 is shown, (A) is a front view, (B) is a partially cut side view, and (C) is a partially cut bottom view.

Explanation of symbols

1: Duct, 2A-2C: Bus bar, 3: Insulating support,
3a: insulating support on the plug-in hole side, 3b: insulating support on the opposite side,
4: plug-in hole, 5: hole cover, 6: bus bar mounting groove, 7: rib,
8: bulging part, 9: concave groove, 10: through hole

Claims (6)

In a plug-in bus duct in which a plurality of bare bus bars are arranged in parallel through an insulating support in a metal duct having a plug-in hole, and a hole cover for closing the plug-in hole is attached to the duct.
The insulating support that supports the bus bar on both sides of the longitudinal direction of the duct of the plug-in hole has a concave groove on the end surface on the plug-in hole side, and the hole cover that closes the plug-in hole is between the duct A plug-in bus duct having a gap, wherein an air passage leading from the inside of the duct to the outside of the duct is formed by the concave groove and the gap.   The plug-in bus duct according to claim 1, wherein a plurality of concave grooves on an end surface of the insulating support on the plug-in hole side are provided.   2. The plug-in bus duct according to claim 1, wherein edges of the ducts on both sides in the longitudinal direction of the plug-in hole are located in the middle in the longitudinal direction of the concave groove.   The plug-in according to any one of claims 1 to 3, wherein a dimension of a gap provided between the hole cover and the duct in a longitudinal direction of the duct is larger than a dimension of the concave groove in a longitudinal direction. Bus duct.   The insulating support is a quadrangular cylinder, and is composed of an insulating support on the plug-in hole side and an insulating support on the opposite side. The insulating support on the plug-in hole side has an end surface on the plug-in hole side. 2. The plug according to claim 1, wherein a rib that fits into the plug-in hole protrudes from an inner peripheral portion, and the concave groove is formed in a portion other than the rib of the end face. Inbass duct.   6. The plug-in bus duct according to claim 5, wherein a through hole communicating with the concave groove is formed in a wall on a base side of the rib of the insulating support.

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