JP2012146580A - Insulation bush of power cable - Google Patents

Abstract

PROBLEM TO BE SOLVED: To restrain electricity from being leaked from a power cable when the power cable is broken.SOLUTION: A cylindrical insulation bush 20 is mounted adjacent to a crimping terminal 11 outside a power cable 300, formed by coating a conductor 301, to the tip of the which the crimping terminal 11 is mounted, with an insulation member 302. The insulation bush comprises plate-like valve bodies 22, 23 whose bottom ends 22a, 23a are mounted to a peripheral edge of an end face 24 by an insulative elastic body, and whose tips 22b, 23b are opened/closed in a direction for approaching to and separating from the end face. The respective tips 22b, 23b of the valve bodies 22, 23 are pushed and opened to contact an outer surface of the bottom part 17 when a distance between the end face and the bottom part 17 of the crimping terminal 11 is normal, and closed to cover the end face when the distance is an abnormal distance Dlonger than a normal distance.

Description

  The present invention relates to a structure of an insulating bush attached to an outer surface of a power cable.

  In recent years, electric vehicles such as hybrid vehicles and electric vehicles have been used. In many of such electric vehicles, DC power obtained by boosting the voltage of a battery of about 200 V from 400 to 600 V is converted into three-phase AC by an inverter and supplied to an AC motor to drive the vehicle. In such an electric vehicle, a power cable that can withstand a high voltage of 400 to 600 V is used between the inverter and the motor.

  On the other hand, when the electric vehicle collides, a large tension is applied to the power cable, the power cable is broken, and leakage may occur from the power cable connected to an inverter or the like including a capacitor or the like. In view of this, there has been proposed a method of caulking the connection terminal on the PCU side in a power cable that connects the power terminal of a PCU in which an inverter or the like is stored and the power terminal of a drive unit such as a motor (for example, Patent Documents). 1). In this method, when a large tension is applied to the power cable, the power cable on the PCU side is disconnected from the connection terminal or this portion is broken, and the power cable is not broken when the PCU and the power cable are connected. At the same time, an insulating cover can be attached around the power terminal of the PCU to prevent leakage from the power terminal of the PCU.

JP 2009-51284 A

  However, the arrangement and route of the high-voltage cable inside the electric vehicle is complicated, and the power cable does not always come off the connection terminal on the inverter side or breaks near the terminal on the inverter side in the event of a collision. . In addition, collisions can take various forms such as side collisions and rear collisions as well as front collisions.For example, in the case of a front collision, the power cable may come off from the connection terminal on the inverter side as planned. Even if the power cable breaks in the vicinity of the terminal on the inverter side, in the case of a collision from the side or from the back, this does not happen, and the broken power cable remains connected to the inverter. There may be a case where electric leakage occurs.

  An object of the present invention is to suppress leakage from a power cable when the power cable is broken.

  An insulating bush of a power cable according to the present invention is a cylindrical insulating bush attached close to the terminal on the outside of a power cable in which a conductor to which a terminal is attached is covered with an insulating member. A plate-like valve body, one end of which is attached to the peripheral edge of the terminal surface of the insulating bush and the other end of which opens and closes in a direction contacting and separating from the end surface of the insulating bush. When the distance between the end surface of the insulating bush and the terminal is a normal distance, the end is pushed open so as to contact the outer surface of the terminal, and the distance between the end surface of the insulating bush and the terminal is a predetermined distance from the normal distance. In the case of an abnormal distance longer than the distance, the insulating bush is closed so as to cover the end face.

  In the insulating bush of the power cable according to the present invention, the other end of the valve body is broken when the conductor is broken between the terminal and the end face of the insulating bush. The insulating bush is a thick-walled cylinder, and the length from the one end to the other end of the valve body is the thickness of the insulating bush and the thickness of the insulating member. It is also preferable that the total length of the conductor and the diameter of the conductor is longer than the total length of the conductors. It is also preferable that a plurality of the valve bodies are arranged radially on the end face of the insulating bush.

  The present invention has an effect that leakage from the power cable when the power cable is broken can be suppressed.

It is explanatory drawing which shows the inverter and drive unit which are connected by the power cable with which the insulation bush in the embodiment of this invention was attached. It is a perspective view which shows the connector incorporating the power cable with which the insulation bush in the embodiment of this invention was attached. It is sectional drawing which shows the normal state of the connector incorporating the power cable with which the insulation bush in the embodiment of this invention was attached. It is a perspective view which shows the normal state of the power cable with which the insulation bush in the embodiment of this invention was attached. It is sectional drawing which shows the connector and power cable which became the abnormal state which the electric power cable with which the insulation bush in the embodiment of this invention was attached fractured | ruptured. It is a perspective view which shows the abnormal state which the electric power cable with which the insulation bush in the embodiment of this invention was attached fractured | ruptured. It is explanatory drawing which shows the end surface of the power cable with which the insulation bush in other embodiment of this invention was attached. It is explanatory drawing which shows the end surface of the power cable with which the insulation bush in other embodiment of this invention was attached.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Before describing the insulating bush of the power cable of the present embodiment, the electric system of the electric vehicle 500 will be described with reference to FIG. As shown in FIG. 1, an electric vehicle 500 is connected to a battery (not shown). The inverter 100 converts DC power supplied from the battery into three-phase AC power and outputs the three-phase power supplied from the inverter 100. A drive unit 200 driven by AC power is mounted. Both the inverter 100 and the drive unit 200 are fixed to the electric vehicle 500, for example, in front. The inverter 100 and the drive unit 200 are connected by a power cable 300 that can withstand a high voltage of about 400V to 600V.

  As shown in FIG. 1, the inverter 100 includes a casing 101 and an output terminal block 102 fixed to the casing 101 and electrically insulated from the casing 101. Similarly, the drive unit 200 also includes a casing 201 and an input terminal block 202 fixed to the casing 201 and electrically insulated from the casing 201. The output terminal block 102 and the input terminal block 202 are connected by a power cable 300. Connectors 10 and 50 connected to the output terminal block 102 of the inverter 100 and the input terminal block 202 of the drive unit 200 are attached to both ends of the power cable 300, respectively.

  As shown in FIG. 2, the connectors 10 and 50 electrically insulate and support the power cable 300 covered with the insulating member 302 and the crimp terminals 11 and 51 connected to the conductor 301 of the power cable 300. Resin housings 14 and 54 and flanges 12 and 52 are provided. The housings 14 and 54 support the three power cables 300 and the three crimp terminals 11 and 51 so as to correspond to the three-phase AC U, V, and W phases. Moreover, the front-end | tip of each crimp terminal 11 and 51 is the flat connection board 15, and the hole through which a volt | bolt passes is provided.

  As shown in FIG. 1, the housings 14 and 54 are fixed to the casings 101 and 201 by attaching the flanges 12 and 52 to the casings 101 and 201 with bolts 13 and 53, respectively. The crimp terminals 11 and 51 connected to both ends of the conductor 301 of the power cable 300 are fixed to the terminal blocks 102 and 202 by bolts 103 and 203, respectively, and the terminal blocks 102 and 202 are electrically connected by the power cable 300. It is connected.

  As shown in FIG. 3, the power cable 300 is obtained by covering the outer surface of the conductor 301 with an insulating member 302, and the insulating member 302 is peeled off from the distal end side of the power cable 300 to expose the conductor 301. Yes. A crimp terminal 11 is attached to the exposed tip of the conductor 301. The crimp terminal 11 is squeezed by caulking to reduce its outer diameter and crimp the conductor 301, and a substantially cylindrical root portion 17 that retains the original outer diameter without being crushed. And a connecting plate 15 that is flat and extends to the front end side of the power cable 300. The connection plate 15 is attached to the output terminal block 102 of the inverter 100 with bolts 103. The conductor 301 is exposed in a gap 303 between the end portion of the base portion 17 of the crimp terminal 11 on the power cable 300 side and the power cable 300 covered with the insulating member 302. The cross-sectional area of the conductor 301 in the gap 303 is smaller than that of the conductor 301 in the covered power cable 300. For this reason, the connection strength in the longitudinal direction between the crimp terminal 11 and the power cable 300 is determined by the crimp force between the crimping portion 16 and the distal end side of the conductor 301 and the cross-sectional strength of the conductor 301 in the gap 303. . When the crimping force by the crimping portion 16 is smaller than the cross-sectional strength of the conductor 301 in the gap 303, the crimping is performed by the leading end of the conductor 301 coming out of the crimping portion 16 when a large tensile force is applied to the power cable 300. When the connection between the terminal 11 and the power cable 300 is broken and the crimping force by the caulking portion 16 is larger than the cross-sectional strength of the conductor 301 in the gap 303, the gap is generated when a large tensile force is applied to the power cable 300. When the conductor 301 of 303 is broken, the connection between the crimp terminal 11 and the power cable 300 is broken. In the connector 10 of the present embodiment, the crimping force by the caulking portion 16 is designed to be larger than the cross-sectional strength of the conductor 301 in the gap 303, and when a large tensile force is applied to the power cable 300, the gap When the conductor 301 of 303 is broken, the connection between the crimp terminal 11 and the power cable 300 is broken.

  As shown in FIG. 3, a cylindrical insulating bush 20 is fitted on the outside of the insulating member 302 on the crimp terminal 11 side of the power cable 300 in the vicinity of the root portion 17 of the crimp terminal 11. The insulating bush 20 is an elastic insulator such as rubber or resin, and its outer surface is attached so as to contact the inner surface of the cylindrical hole 18 of the housing 14 of the connector 10. As described above, the insulating bush 20 fixes the power cable 300 to the housing 14 of the connector 10 while filling a gap between the inner surface of the hole 18 of the housing 14 and the outer surface of the insulating member 302 of the power cable 300. . As shown in FIG. 3, the gap between the insulation member 302 and the portion of the crimp terminal 11 other than the connection plate 15 housed inside the housing 14 of the connector 10 and the base portion 17 of the crimp terminal 11 and the insulation member 302. The conductor 301 of 303 is comprised so that it cannot touch from the outside, and it is comprised so that an electric leakage may not arise outside from this part.

As shown in FIGS. 3 and 4, rectangular plate-like insulating elastic pairs of valve elements 22 and 23 are attached to the end surface 24 of the cylindrical and thick insulating bush 20 on the crimping terminal 11 side in two places, upper and lower. It has been. The valve bodies 22, 23 are attached to the periphery of the end surface 24 of the insulating bush 20 at the base end 22 a, 23 a side of the insulating bush 20, and the tips 22 b, 23 b are moved in the direction of contacting and separating from the end surface 24 of the insulating bush 20. The length from each root end 22a, 23a to each tip 22b, 23b is the sum of the thickness of the cylindrical insulating bush 20 and the thickness of the insulating member 302 of the power cable 300 and the diameter of the conductor 301. It is comprised so that it may become longer than length. Then, as shown in FIGS. 3 and 4, when the distance is normal normal distance D ₁ of the between the end face 24 of the base portion 17 and the insulating bushing 20 of the crimp terminal 11, the valve provided in the vertical The tips 22b and 23b of the bodies 22 and 23 are pushed open so as to contact the outer surface of the cylindrical root portion 17 of the crimp terminal 11.

As shown in FIGS. 5 and 6, when a large tensile force is applied to the power cable 300 due to a collision or the like, and the conductor 301 in the gap 303 between the power cable 300 and the crimp terminal 11 is broken, the power cable 300 is insulated. Together with the bush 20, the connector 10 comes out of the housing 14. Then, the distance between the root portion 17 of the crimp terminal 11 and the end surface 24 of the insulating bush 20 becomes an abnormal distance D _{2 that} is larger than the normal distance D ₁ by a predetermined distance. Here, the predetermined distance is a distance at which the tips 22 b and 23 b of the valve bodies 22 and 23 are not hooked on the root portion 17 of the crimp terminal 11. Then, as shown in FIGS. 5 and 6, the tips 22 b and 23 b of the valve bodies 22 and 23 attached to the top and bottom of the end surface 24 of the insulating bush 20 come off from the outer surface of the root portion 17 of the crimp terminal 11. It moves toward the end surface 24 of the insulating bush 20 by the elastic force. The length from each root end 22a, 23a of each valve body 22, 23 to each tip 22b, 23b is the sum of the thickness of the insulating bush 20, the thickness of the insulating member 302 of the power cable 300, and the diameter of the conductor 301, respectively. Since it is longer than the length, each of the valve bodies 22 and 23 moved toward the end face 24 side of the insulating bush 20 has a fracture surface 304 of the conductor 301 in the gap 303 broken with the end face 24 of the insulating bush 20. The cover is closed so that the conductor 301 is not exposed. As shown in FIGS. 5 and 6, in this embodiment, the lower valve body 23 covers the fracture surface 304 of the conductor 301, and the upper valve body 22 is overlaid thereon. However, the overlapping order of the valve bodies 22 and 23 may be reversed. As a result, even when the power cable 300 is broken at the gap 303, the conductor 301 of the power cable 300 is not exposed, and leakage from the power cable 300 can be prevented.

  Further, as shown in FIG. 5, when the power cable 300 is broken at the gap 303, the crimped portion 16 and the root portion 17 of the crimp terminal 11 and the remaining portion of the conductor 301 of the broken gap 303 are included in the connector 10. However, since all the portions remain in the insulator housing 14 of the connector 10, it is possible to suppress the leakage of electric charges accumulated in the capacitor of the inverter 100 from this portion. it can.

  As described above, the insulating bush 20 of the power cable 300 according to the present embodiment has an effect that the leakage from the power cable 300 when the power cable 300 is broken can be suppressed.

  Another embodiment of the present invention will be described with reference to FIGS. Parts similar to those of the embodiment described above with reference to FIGS. 1 to 6 are denoted by the same reference numerals, and description thereof is omitted. In the embodiment shown in FIG. 7, four rectangular plate-shaped valve bodies 31 to 34 are arranged radially by shifting 90 degrees on the end face 24 of the insulating bush 20. Similarly to the embodiment described above, in this embodiment, the root ends 31a to 34a of the valve bodies 31 to 34 are fixed to the periphery of the end surface 24, and the root ends 31a to 34a and the tips 31b to 34b are connected to each other. Since the length between them is longer than the total length of the thickness of the insulating bush 20, the thickness of the insulating member 302 of the power cable 300 and the diameter of the conductor 301, when each valve body 31 to 34 is closed. Are closed so as to cover the end surface 24 of the insulating bush 20 and the fractured surface 304 of the conductor 301 in the fractured gap 303 to cover the conductor 301 so that it is not exposed. In the embodiment shown in FIG. 8, the valve bodies 41 and 42 are not rectangular plates, the tips 41 b and 42 b are arcuate, and the root ends 41 a and 42 a are fixed to the periphery of the end surface 24. Each of the embodiments shown in FIGS. 7 and 8 has the same effect as the embodiment described above with reference to FIGS.

  10, 50 Connector, 11, 51 Crimp terminal, 12, 52 Flange, 13, 53 Bolt, 14, 54 Housing, 15 Connection plate, 16 Caulking part, 17 Root part, 18 holes, 20 Insulating bush, 22, 23, 31 34, 41, 42 Valve body, 22a, 23a, 31a-34a, 41a, 42a Root end, 22b, 23b, 31b-34b, 41b, 42b Tip, 24 end face, 100 inverter, 101, 201 casing, 102 output terminal Table, 103, 203 volts, 200 drive unit, 202 input terminal block, 300 power cable, 301 conductor, 302 insulating member, 303 gap, 304 fracture surface, 500 electric vehicle.

Claims (4)

A cylindrical insulating bush attached to the outside of a power cable in which a conductor to which a terminal is attached at the tip is covered with an insulating member, and is attached close to the terminal,
Insulating elastic body, one end is attached to the peripheral edge of the end surface on the terminal side of the insulating bush, and the other end is provided with a plate-like valve body that opens and closes in a direction contacting and leaving the end surface of the insulating bush
The other end of the valve body is pushed open so that it contacts the outer surface of the terminal when the distance between the end surface of the insulating bush and the terminal is a normal distance, and the distance between the end surface of the insulating bush and the terminal is In the case of an abnormal distance longer than the normal distance by a predetermined distance or more, close so as to cover the end face of the insulating bush;
Insulation bushing for power cable. An insulating bush for a power cable according to claim 1,
The other end of the valve body is closed so as to cover a fractured surface of the broken conductor when the conductor is broken between the terminal and the end face of the insulating bush.
Insulation bushing for power cable. An insulating bush for a power cable according to claim 1 or 2,
The insulating bush is a thick-walled cylinder,
The length from the one end to the other end of the valve body is longer than the total length of the thickness of the insulating bush, the thickness of the insulating member, and the diameter of the conductor,
Insulation bushing for power cable. An insulating bush for a power cable according to any one of claims 1 to 3,
A plurality of the valve bodies are arranged radially on the end face of the insulating bush;
Insulation bushing for power cable.

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