JP7337191B2 - Power connector with cable - Google Patents

Description

The present invention relates to a power supply connector with cable.
This application claims priority based on Japanese Patent Application No. 2019-212195 filed in Japan on November 25, 2019, the content of which is incorporated herein.

Patent Literature 1 listed below discloses a terminal in which a coolant channel is formed in a terminal body portion.

Chinese Patent Application Publication No. 106887733

The terminal has an inflow port and an outflow port of the coolant flow path that are open to the sides of the terminal main body. A cooling tube is connected to the inlet and the outlet. By the way, the cooling tube may be vibrated, twisted, or pulled by inserting/removing the terminal. As a result, a load is applied to the connecting portion between the terminal and the cooling tube, which may cause refrigerant leakage.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a power supply connector with a cable capable of reducing the load applied to the connecting portion between the terminal and the cooling tube.

A power supply connector with cable according to an aspect of the present invention includes a terminal, a flexible cooling tube that is connected to the terminal and supplies a coolant to the terminal, a terminal gripping portion that grips the terminal, and the a holder having a tube gripping portion for gripping the cooling tube.
According to this configuration, the holder grips both the terminal and the cooling tube, causes the cooling tube to follow the movement of the terminal, and keeps the positional relationship between the terminal and the cooling tube constant. can reduce the load on As a result, it is possible to prevent coolant from leaking from the connecting portion between the terminal and the cooling tube.

In the above power supply connector with cable, the holder is a set formed by combining a first split body having a split surface and a second split body facing the first split body via the split surface. A position of the dividing surface may overlap with the terminal gripping portion and the tube gripping portion when viewed from the direction in which the terminal gripping portion and the tube gripping portion are arranged.
This configuration facilitates assembly of the holder with respect to the terminals and the cooling tube.

In the power supply connector with cable, the tube gripping portion may have a straight portion extending parallel to the central axis of the terminal.
According to this configuration, the cooling tube can be arranged so that the orbit of the cooling tube does not widen with respect to the terminals, and it is easy to incorporate in a narrow space such as the inside of the case of the power supply connector.

In the power supply connector with cable, the tube gripping portion may have a curved portion that curves along the cooling tube.
According to this configuration, the cooling tube can be gripped and the load applied to the cooling tube can be reduced without forcibly bending the cooling tube at a position near the connecting portion between the cooling tube and the terminal.

In the above power supply connector with cable, the cooling tube is curved at a position rearward of the tube gripping portion, and the curvature rate of the cooling tube at a position rearward of the tube gripping portion is greater than that of the curved portion. Curvature may be small.
With this configuration, a load is less likely to be applied to the connecting portion between the terminal and the cooling tube, and refrigerant leakage can be prevented.

The power supply connector with cable may further include a non-slip member interposed between the tube gripping portion and the cooling tube.
According to this configuration, the cooling tube can be firmly gripped by the tube gripping portion via the non-slip member. Also, this makes it difficult for the cooling tube to be twisted.

In the power supply connector with cable described above, the terminal may have a constricted portion, and the holder may have a fitting portion that fits into the constricted portion.
According to this configuration, the holder cannot be pulled out in the axial direction with respect to the terminal, and the fitting between the terminal and the holder is strengthened.

According to the aspect of the present invention, it is possible to reduce the load applied to the connecting portion between the terminal and the cooling tube.

1 is a schematic diagram showing a power supply connector comprising a power supply connector with a cable according to one embodiment; FIG. FIG. 4 is a perspective view showing a terminal to which a holder according to one embodiment is attached; 1 is an exploded perspective view showing a holder according to one embodiment; FIG. It is a figure which shows the cross-sectional structure of the holder which concerns on one Embodiment.

An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a schematic diagram showing a power supply connector 100 with cable according to one embodiment.
As shown in FIG. 1 , the power supply connector 100 with cable includes a terminal 1 , a cable 105 and a case 200 . Terminal 1 and cable 105 are connected to each other and introduced into case 200 that can be inserted into a charging port (inlet portion) of an electric vehicle. The cable 105 incorporates a conductor wire 102 for supplying power to a power supply target and a cooling tube 101 for cooling the conductor wire 102 . The cooling tube 101 is a tube connected to the terminal 1, has flexibility, and can be freely bent.

For the cable 105, for example, a cable having the same configuration as the power supply cable described in Japanese Patent No. 6078198 can be adopted. Specifically, the cable 105 contains a plurality (even number) of power lines 103 , and the power lines 103 contain the cooling tubes 101 and the conductor lines 102 . Inside the power line 103 , a plurality of conductor lines 102 are twisted around the cooling tube 101 . As a result, heat generation of the conductor wire 102 due to energization can be suppressed by the refrigerant liquid flowing through the cooling tube 101 . A signal line used for communication between the power supply device and the electric vehicle may be built in the cable 105 .

The cooling tube 101 and the conductor wire 102 branch behind the terminal 1 and are connected to the terminal 1 respectively. The branched cooling tube 101 is connected to a terminal extension portion 40 of the terminal 1, which will be described later. Also, the branched conductor wire 102 is inserted into a conductor wire connecting portion 30 described later and is compression-connected. Although not shown, the case 200 is provided with two terminals 1 and two cables 105 for the + terminal and the - terminal.

The power supply connector 100 with cable shown in FIG. 1 charges, for example, a battery of an electric vehicle. The case 200 of the power supply connector 100 with cable includes an insertion portion 201 arranged such that a part of the terminal 1 (terminal contact portion 20) is exposed to the outside of the case, and a grip portion 202 arranged behind the insertion portion 201. and a cable introduction portion 203 arranged below the grip portion 202 (obliquely behind the insertion portion 201). The cable 105 is introduced into the case 200 from the outside of the case 200 through the cable introduction portion 203 and connected to the terminal 1 .

The power supply connector 100 with cable of this embodiment includes a holder 60 .
The power supply connector 100 with cable having the above configuration can charge the battery of the electric vehicle by holding the grip portion 202 and inserting the insertion portion 201 into the charging port of the electric vehicle. After charging is completed, the insertion portion 201 of the case 200 is removed from the charging port. At this time, since the power supply connector 100 with cable is provided with the holder 60, the cooling tube 101 inside the case 200 may be vibrated, twisted, or pulled due to insertion/removal of the power supply connector or bending/stretching of the cable during the charging operation. nothing to do
Next, the holder 60 will be specifically described.

FIG. 2 is a perspective view showing the terminal 1 to which the holder 60 according to one embodiment is assembled, and FIG. 3 is an exploded perspective view showing the holder 60 according to one embodiment. FIG. 4 is a cross-sectional configuration diagram of the holder 60 according to one embodiment.
As shown in FIGS. 2 and 3, the holder 60 can be split into split pieces 60a and 60b (first split body 60a and second split body 60b).

The split piece 60 a has a split surface 61 . The split piece 60b faces the split piece 60a with the split surface 61 interposed therebetween. The holder 60 is configured by combining the split pieces 60a and 60b via the split piece 60a. That is, the holder 60 is a set obtained by combining the split pieces 60a and 60b. The dividing surface 61 overlaps the terminal gripping portion 62 and the tube gripping portion 63 when viewed from the direction in which the terminal gripping portion 62 and the tube gripping portion 63 are arranged.

The split pieces 60a and 60b are bound and fixed with a binding band or tape (not shown) in the assembled state shown in FIG. Note that the split pieces 60a and 60b may be fixed to each other by providing engaging claws such as snap-fits. In this embodiment, the holder 60 can be divided into two pieces 60a and 60b, but it may be divided into a plurality of pieces.

As shown in FIG. 3 , the holder 60 has a terminal gripping portion 62 and a tube gripping portion 63 . Specifically, the split piece 60a (first split body) has a first terminal gripping portion and a first tube gripping portion. The split piece 60b (second split body) has a second terminal gripping portion and a second tube gripping portion. That is, when the two split pieces 60a and 60b are combined, the terminal gripping portion 62 is formed by the first terminal gripping portion and the second terminal gripping portion, and the tube gripping portion is formed by the first tube gripping portion and the second tube gripping portion. A portion 63 is formed.

As shown in FIG. 4 , the terminal gripping portion 62 grips the terminal 1 . Also, as shown in FIG. 3 , the tube gripping portion 63 grips the cooling tube 101 . A pair of tube gripping portions 63 are provided on both sides of the terminal gripping portion 62 .

First, the configuration of the terminal 1 held by the holder 60 and the cooling tube 101 will be described. As shown in FIG. This terminal 1 is suitable for rapid charging of the battery of an electric vehicle, and can cool Joule heat generated by flowing a large current by the refrigerant flowing through the refrigerant flow path 2 .

The terminal 1 is a metal terminal, and is made of, for example, copper or copper alloy. The surface of the terminal 1 is covered with silver plating or the like to prevent corrosion. The terminal 1 includes a terminal body portion 10 , a terminal contact portion 20 and a conductor wire connection portion 30 . The terminal body portion 10, the terminal contact portion 20, and the conductor wire connection portion 30 are integrally molded. Such a terminal 1 can be formed by casting or cutting from an ingot.

The coolant that flows through the coolant channel 2 is preferably an insulating coolant. By using an insulating coolant, it is possible to prevent electric leakage from the terminal 1 through the coolant channel 2 to a cooler (not shown). Examples of insulating coolants include insulating oils such as silicone oil and mineral oil, fluorine-based coolants, alcohol-based coolants, and the like. However, if an insulating layer or an insulating film is formed on the inner wall surface of the coolant channel 2, a non-insulating coolant can also flow.

The terminal main body portion 10, the terminal contact portion 20, and the conductor wire connection portion 30 are coaxially arranged with the central axis O of the terminal 1 as a common axis. Hereinafter, the direction along the central axis O will be referred to as the axial direction, the direction crossing the central axis O as seen from the axial direction will be referred to as the radial direction, and the direction that rotates around the central axis O will be referred to as the circumferential direction. Further, in the axial direction, the position of the terminal contact portion 20 with respect to the terminal main body portion 10 or the direction from the terminal main body portion 10 toward the terminal contact portion 20 is referred to as "forward". On the other hand, the position of the conductor wire connection portion 30 with respect to the terminal main body portion 10 or the direction from the terminal main body portion 10 toward the conductor wire connection portion 30 is referred to as "rear".

A coolant channel 2 is formed inside the terminal main body 10 . The coolant flow path 2 includes a radially extending hole portion 11 , a first inclined hole portion 41 connected to one end side (first end side) of the hole portion 11 , and the other end side (second end side) of the hole portion 11 . and a second inclined hole portion 42 connected to the side). One end of the hole portion 11 penetrates the terminal body portion 10 and is open, and the other end of the hole portion 11 does not penetrate the terminal body portion 10 but is closed. An opening 11 a at one end of the hole 11 is closed by a plug 50 .

The first inclined hole portion 41 and the second inclined hole portion 42 are opened through a pair of terminal extension portions 40 projecting laterally from the terminal body portion 10 . One terminal extension portion 40</b>A (first terminal extension portion) of the terminal extension portion 40 is formed with an inlet 2 a of the coolant flow path 2 in which the first inclined hole portion 41 opens to the outside. The other terminal extension portion 40B (second terminal extension portion) of the terminal extension portion 40 is formed with an outflow port 2b of the refrigerant flow path 2 through which the second inclined hole portion 42 opens to the outside.

On the outer surface of the terminal extension portion 40, a first slanted portion 44, which extends away from the central axis O as it goes rearward from a plane portion 43 parallel to the central axis O of the terminal 1, A second inclined portion 45 adjacent to the axis O is formed. The angle (elevation angle) of the first inclined portion 44 with respect to the plane portion 43 is an acute angle of 45 degrees or less, for example, 30 degrees. Also, the angle (inclination) of the second inclined portion 45 with respect to the first inclined portion 44 is, for example, a right angle of 90 degrees. That is, the terminal extension portion 40 has a substantially right-angled triangular shape when viewed from the side.

An inlet 2 a and an outlet 2 b of the coolant channel 2 are formed in the second inclined portion 45 . That is, the inflow port 2a and the outflow port 2b of the coolant channel 2 are opened obliquely rearward. A cooling tube 101 is connected to the inlet 2a and the outlet 2b via a tube connector 101a. The cooling tube 101 is made of, for example, a resin tube such as nylon, and has flexibility. In addition, the cooling tube 101 has a certain degree of elasticity against bending, so-called repulsive force and restoring force.

The terminal contact portion 20 protrudes forward from the terminal body portion 10 . The terminal contact portion 20 of the present embodiment is in the shape of a solid pin (male terminal contact portion) extending in the axial direction. Since the coolant channel 2 is not formed in the terminal contact portion 20, a large cross-sectional area of the conductor can be secured, which is suitable for passing a large current. A flange 21 is formed at the base of the terminal contact portion 20 . Flange 21 engages case 200 (see FIG. 1) to limit the protrusion of terminal contact portion 20 from case 200 . Although the terminal contact portion 20 of this embodiment has a pin-like shape, a socket-like (female) terminal contact portion such as the terminal contact portion 22 may be attached to a mating member or device into which the terminal contact portion 20 is inserted. ) shape.

The conductor wire connection portion 30 protrudes rearward from the terminal body portion 10 . The conductor wire connecting portion 30 is a cylindrical portion extending in the axial direction. The conductor wire connection portion 30 includes a first hole portion 31 that extends in the axial direction and opens to the rear, and a second hole portion 31 that extends radially outward from the inner wall surface of the first hole portion 31 and opens to the outer peripheral surface of the conductor wire connection portion 30 . 2 holes 32 are provided. The first hole portion 31 is an insertion hole for the conductor wire 102 described above. The second hole 32 is an air vent hole for filling the inside of the first hole 31 with a plating solution when the terminal 1 is plated.

A tapered portion 33 is formed in the conductor wire connecting portion 30 . The tapered portion 33 is positioned in front of the terminal main body 10 , that is, closer to the terminal main body 10 than the rear side of the conductor wire connecting portion 30 . The tapered portion 33 is a conical portion whose radial dimension gradually increases toward the rear from the terminal body portion 10 . A columnar constricted portion 12 is formed between the terminal body portion 10 and the tapered portion 33 . The radial dimension of the constricted portion 12 is the same as the minimum diameter of the tapered portion 33 and smaller than the radial external dimensions of the terminal body portion 10 and the conductor wire connection portion 30 .

The terminal gripping portion 62 of the holder 60 grips the conductor wire connection portion 30 and the constricted portion 12 described above. The terminal gripping portion 62 has a first accommodating portion 62a that accommodates the conductor wire connecting portion 30, a second accommodating portion 62b that accommodates the tapered portion 33, and a third accommodating portion 62c that accommodates the constricted portion 12. ing. The first accommodation portion 62a, the second accommodation portion 62b, and the third accommodation portion 62c communicate with each other in the axial direction with the central axis O as a common axis.

The first accommodating portion 62 a is a cylindrical hole formed with the same size as or slightly larger than the cylindrical portion of the conductor wire connecting portion 30 . The second accommodation portion 62b is a conical hole portion arranged in front of the first accommodation portion 62a and having the same size as or slightly larger than the tapered portion 33 . The third accommodation portion 62c is a cylindrical hole that is arranged in front of the second accommodation portion 62b and has the same size as or slightly larger than that of the constricted portion 12 .

The tube gripping portion 63 of the holder 60 grips the tube connector 101a and the cooling tube 101 described above. The tube gripping portion 63 has a connector accommodating portion 63 a that accommodates the tube connector 101 a and a tube accommodating portion 63 b that accommodates the cooling tube 101 . The connector accommodating portion 63a is a cylindrical hole formed with the same or slightly larger dimensions than the tube connector 101a. The connector accommodating portion 63a extends obliquely rearward at the same angle as the inlet 2a and the outlet 2b of the coolant channel 2 described above.

The tube accommodating portion 63b is a hole formed with the same or slightly larger dimensions than the cooling tube 101, but has a smaller diameter and a gentle curve than the connector accommodating portion 63a. Specifically, the tube accommodating portion 63b has a first straight portion 63b1, a curved portion 63b2, and a second straight portion 63b3. The first linear portion 63b1 is arranged coaxially with the connector accommodating portion 63a and extends obliquely rearward in the same manner as the connector accommodating portion 63a.

The first straight portion 63b1 extends in a direction intersecting the central axis O. As shown in FIG. On the other hand, the second linear portion 63b3 extends parallel to the central axis O. As shown in FIG. The curved portion 63b2 is a portion that smoothly connects the first straight portion 63b1 and the second straight portion 63b3 and curves along the cooling tube 101 . The curved portion 63b2 may be curved with a curvature that does not cause the cooling tube 101 to buckle.

The cooling tube 101 is curved at a position behind the tube gripping portion 63 . The curvature of the curved portion 63 b 2 is smaller than the curvature of the cooling tube 101 at the position behind the tube gripping portion 63 .

Specifically, as shown in FIG. 1, at a position behind the holder 60, the cooling tube 101 protrudes from the holder 60 and extends toward the inside of the power line 103 so as to be greatly curved.
In other words, at the rear position of the holder 60, the cooling tube 101 extends in a direction inclined with respect to the central axis O shown in FIG. Also, the cooling tube 101 built in the power line 103 extends in a direction parallel to the grip portion 202 .

In the cable-attached power supply connector 100 having such a structure, the cooling tube 101 is curved behind the holder 60 in order to insert the cooling tube 101 exposed from the power line 103 into the holder 60 .

On the other hand, the curvature rate of the curved portion 63b2 is set smaller than the curvature rate of the cooling tube 101 at the rear position of the holder 60. ) becomes smaller.
Therefore, at the connecting portion between the terminal 1 and the cooling tube 101, it is difficult for the cooling tube 101 to be subjected to a load due to bending, and the occurrence of refrigerant leakage can be prevented.

A non-slip member 70 is arranged near the exit of the second straight portion 63b3. The non-slip member 70 is made of rubber, sponge, or the like, and is interposed between the tube gripping portion 63 and the cooling tube 101 to prevent the cooling tube 101 from slipping. The non-slip member 70 may be provided on the inner wall surface of the tube gripping portion 63 or may be wound around the outer circumference of the cooling tube 101 .

The holder 60 has a fitting portion 64 that fits into the constricted portion 12 of the terminal 1 . The fitting portion 64 is formed by a partition wall portion separating the terminal gripping portion 62 and the tube gripping portion 63 described above. In the present embodiment, the fitting portions 64 are the partition wall portion between the tube accommodating portion 63b and the second accommodating portion 62b and the partition wall portion between the second accommodating portion 62b and the third accommodating portion 62c. ing.

The power supply connector 100 with a cable having the above configuration includes a terminal 1, a cooling tube 101 that supplies a coolant to the terminal 1, a terminal gripping portion 62 that grips the terminal 1, and a tube gripping portion 63 that grips the cooling tube 101. and a holder 60 having. For this reason, the holder 60 holds both the terminal 1 and the cooling tube 101 and makes the cooling tube 101 follow the inserting/removing operation of the terminal 1 to keep the positional relationship between the terminal 1 and the cooling tube 101 constant. Therefore, the load applied to the connecting portion between the terminal 1 and the cooling tube 101 can be reduced.
As a result, it is possible to prevent refrigerant leakage from the connecting portion between the terminal 1 and the cooling tube 101 (for example, the connecting portion between the terminal 1 and the tube connector 101a or the connecting (joint) portion between the tube connector 101a and the cooling tube 101). can.

As described above, the cooling tube 101 has a certain degree of elasticity against bending, that is, so-called repulsive force and restoring force, and is curved as shown in FIG. Therefore, a load (bending reaction force of the cooling tube 101) is always applied to the connecting portion between the terminal 1 and the cooling tube 101, but the holding of the cooling tube 101 by the holder 60 prevents the bending of the cooling tube 101. The degree should not be greater (bend tighter). Therefore, it is possible to prevent an increase in the load applied to the connection portion. Furthermore, buckling of the cooling tube 101 can also be prevented.

Moreover, in this embodiment, as shown in FIGS. 2 and 3, the holder 60 is a set obtained by combining the split pieces 60a and 60b, so that the holder 60 can be easily assembled to the terminal 1 and the cooling tube 101. become.

Further, in this embodiment, the tube gripping portion 63 has a second linear portion 63b3 extending parallel to the central axis O of the terminal 1, as shown in FIG. Therefore, the cooling tube 101 can be arranged so that the track of the cooling tube 101 does not widen with respect to the terminal 1, and it can be easily incorporated into the narrow space inside the case 200 as shown in FIG.

In addition, in this embodiment, as shown in FIG. 4, the tube gripping portion 63 has a curved portion 63b2 that curves along the cooling tube 101. Therefore, the cooling tube 101 can be The cooling tube 101 can be gripped. That is, the load applied to the cooling tube 101 can be reduced.

In addition, in this embodiment, since the non-slip member 70 is interposed between the tube gripping portion 63 and the cooling tube 101 , the cooling tube 101 is firmly gripped by the tube gripping portion 63 via the non-slip member 70 . can do. Also, this makes it difficult for the cooling tube 101 to be twisted.

In this embodiment, the terminal 1 has the constricted portion 12, and the holder 60 has the fitting portion 64 that fits into the constricted portion. The terminal 1 and the holder 60 cannot be pulled out, and the fitting between the terminal 1 and the holder 60 is strengthened.

While the preferred embodiments of the invention have been described and described, it is to be understood that they are illustrative of the invention and should not be considered limiting. Additions, omissions, substitutions, and other modifications may be made without departing from the scope of the invention. Accordingly, the invention should not be viewed as limited by the foregoing description, but rather by the claims appended hereto.

For example, in the above-described embodiment, the cooling tube 101 is connected to the terminal 1 having the coolant channel 2 inside. A configuration in which the cooling tube 101 is connected to the . Also with this configuration, the terminal 1 can be cooled by supplying the coolant to the terminal 1 through the cooling tube 101 .

Although the cooling tube 101 connected to the terminal 1 has been described in the above embodiment, the present invention is not limited to this structure. A structure in which a connection member is arranged between the terminal 1 and the cooling tube 101 and the terminal 1 and the cooling tube 101 are connected via the connection member may be employed. In this case, the connecting member may or may not have flexibility. If the cooling tube 101 has flexibility, the above effects can be obtained.

DESCRIPTION OF SYMBOLS 1... Terminal 12... Constriction part 60... Holder 61... Division surface 62... Terminal gripping part 63... Tube gripping part 63b2... Curved part 63b3... Second straight part (straight part) 64... Fitting Parts 70... Non-slip member 100... Power supply connector with cable 101... Cooling tube O... Central axis

Claims (6)

a terminal;
a cooling tube that is connected to the terminal, supplies a coolant to the terminal, and has flexibility;
a holder having a terminal gripping portion that grips the terminal and a tube gripping portion that grips the cooling tube ;
The tube gripping portion has a curved portion that curves along the cooling tube,
Powered connector with cable. The holder is a set formed by combining a first divided body having a dividing surface and a second divided body facing the first divided body through the dividing surface,
When viewed from the direction in which the terminal gripping portion and the tube gripping portion are arranged, the position of the dividing surface overlaps with the terminal gripping portion and the tube gripping portion.
The power supply connector with cable according to claim 1. The tube gripping portion has a straight portion extending parallel to the central axis of the terminal,
The power supply connector with cable according to claim 1 or 2. The cooling tube is curved at a position behind the tube gripping portion,
The curvature of the bending portion is smaller than the curvature of the cooling tube at a position behind the tube gripping portion,
The power supply connector with cable according to any one of claims 1 to 3 . An anti-slip member interposed between the tube grip and the cooling tube,
The power supply connector with cable according to any one of claims 1 to 4 . The terminal has a constricted portion,
The holder has a fitting portion that fits into the constricted portion,
The power supply connector with cable according to any one of claims 1 to 5 .

Images