JP6783574B2 - Connector structure - Google Patents

Description

The techniques disclosed herein relate to connector structures that connect electrical (signal or power) transmission paths.

A connector structure is used to connect the electrical transmission paths of the two members. In the connector structure, the transmission paths of the two members are connected by fitting the two connectors corresponding to one-to-one. For example, Patent Document 1 discloses a connector structure in which a card member and a card edge connector are fitted. The card member includes a substrate and a card edge terminal that is electrically connected to the substrate. The card edge terminal is provided on the flat surface of the card member and is arranged at the edge of the card member. The card edge connector includes a contact terminal extending parallel to the card edge terminal and a housing accommodating the contact terminal. A wire is connected to one end of the contact terminal, and a contact portion that contacts the flat surface of the card edge terminal is provided at the other end. The contact portion is arranged in an opening provided on the side surface of the housing. When the edge of the card member is inserted into the opening, the card member and the card edge connector are fitted, and the flat surface of the card edge terminal and the contact portion of the contact terminal come into contact with each other. As a result, the board of the card member and the transmission path of the wire of the card edge connector are connected.

The substrate of the card member and the housing of the card edge connector repeat thermal expansion / contraction due to changes in the environmental temperature using the connector structure. When the substrate expands along the width direction along the edge of the card member, the card edge terminal also moves in the width direction as the substrate expands. On the other hand, when the housing expands along the width direction, the contact terminals also move in the width direction as the housing expands. When the coefficient of linear expansion of the substrate and the coefficient of linear expansion of the housing are different, the distance that the card edge terminal moves and the distance that the contact terminal moves are different. Therefore, the contact portion slides with respect to the card edge terminal. Sliding between terminals is not preferable because it increases contact resistance. In the technique of Patent Document 1, by making both coefficient of linear expansion the same, the distance that the card edge terminal moves and the distance that the contact terminal moves are made the same, and the contact portion with respect to the card edge terminal. Prevents sliding.

JP-A-2015-185210

Patent Document 1 prevents the card edge terminal and the contact terminal from sliding in consideration of thermal expansion / contraction of the card member substrate and the housing of the card edge connector. However, Patent Document 11 does not consider the thermal expansion / contraction of the card edge terminal itself and the contact terminal itself. For example, it is assumed that both the card edge terminal and the contact terminal expand along the insertion direction. For example, when the card edge terminal extends so that the end edge moves toward the card edge connector side and the contact terminal extends so that the contact portion moves toward the card member side, the contact portion and the contact portion are in contact with each other. The contact points on the edge terminal side move in opposite directions. Therefore, in the technique of Patent Document 1, the distance (sliding distance) in which both terminals slide due to thermal expansion / contraction becomes long.

The present specification provides a technique for shortening the sliding distance due to thermal expansion / contraction of a male terminal and a female terminal extending in parallel in a connector structure in which a male connector and a female connector are fitted.

This specification discloses two aspects as a connector structure in which a male connector and a female connector are fitted. In one aspect, the male connector comprises a plate-shaped male terminal whose one end is fixed to the male housing at the first fixing location and the other end is not fixed to the male housing. The female connector is a female terminal that extends parallel to the male terminal when the male connector and the female connector are fitted, and one end is fixed to the female housing at the second fixing point and the other end is fixed to the female housing. It has an unfixed female terminal. Then, one of the female terminal and the male terminal is provided with a convex portion that contacts the other, and when the male connector and the female connector are fitted, the first fixing portion and the second fixing portion are viewed from the convex portion. It is located on the same side.

According to this configuration, the male terminal extends so that the other end not fixed to the male housing moves away from the first fixing portion due to expansion. On the other hand, the female terminal parallel to the male terminal also extends so that the other end to which the female housing is not fixed moves away from the second fixing portion due to expansion. In this case, one convex portion and the other contact portion with which the convex portion contacts also move away from the first fixed portion and the second fixed portion, respectively. Here, since the first fixed portion and the second fixed portion are located on the same side as viewed from the convex portion, the convex portion and the contact portion move in the same direction. Therefore, the distance that the convex portion moves relative to the contact portion can be reduced as compared with the case where the convex portion and the contact portion move in opposite directions. That is, the sliding distance between the male terminal and the female terminal extending in parallel due to thermal expansion / contraction can be shortened.

In the other aspect, the male connector comprises a plate-shaped male terminal having one end fixed to the male housing at a fixed location and the other end not fixed to the male housing. The female connector is a female terminal that extends parallel to the male terminal when the male connector and the female connector are fitted, and one end is fixed to the female housing via an elastic member, and the other end (free end). Has a female terminal that is not fixed to the female housing. Then, one of the female terminal and the male terminal is provided with a convex portion that contacts the other, and when the male connector and the female connector are fitted, the first fixing portion and the elastic member are opposite to each other when viewed from the convex portion. It is located on the side and the free end is in contact with the male housing.

According to this configuration, the male terminal extends so that the other end not fixed to the male housing moves away from the fixed portion due to expansion. On the other hand, since the free end of the female terminal is in contact with the male housing, one end fixed to the female housing extends away from the fixed portion via an elastic member. In this case, both the convex portion and the contact portion move in the same direction so as to move away from the fixed portion. Therefore, the distance that the convex portion moves relative to the contact portion can be reduced as compared with the case where the convex portion and the contact portion move in opposite directions. That is, even with this configuration, the same effect as that of one aspect can be obtained.

Details of the techniques disclosed herein and further improvements will be described in the "Modes for Carrying Out the Invention" below.

It is sectional drawing of the male terminal of the connector structure of 1st Example. It is sectional drawing of the female terminal of the connector structure of 1st Example. It is sectional drawing of the male terminal and the female terminal fitted with 1st Example. It is sectional drawing of the male terminal of the connector structure of 2nd Example. It is sectional drawing of the female terminal of the connector structure of 2nd Example. It is sectional drawing of the male terminal and the female terminal fitted in the 2nd Example. It is sectional drawing of the male terminal of the connector structure of 3rd Example. It is sectional drawing of the female terminal of the connector structure of 3rd Example. It is sectional drawing of the male terminal and the female terminal fitted with 3rd Example.

(First Example)
The connector structure of the first embodiment will be described with reference to the drawings. The connector structure of this embodiment is composed of a male connector 10 and a female connector 50. This connector structure is used for cable connection of in-vehicle devices such as electric vehicles and hybrid vehicles. FIG. 1 is a cross-sectional view of the male connector 10. FIG. 2 is a cross-sectional view of the female connector 50. By fitting the male connector 10 and the female connector 50, the electric transmission path of the male cable connected to the male connector 10 and the female cable connected to the female connector 50 is connected. The XYZ coordinate system is described in the drawings, and in the present specification, the configuration of the embodiment will be described using the coordinate system as appropriate. When the male connector 10 and the female connector 50 are fitted together, the ends of the male connector 10 and the female connector 50 on the opposite sides may be referred to as a "tip". In the male connector 10, the end in the positive direction of the X-axis is the tip, and in the female connector 50, the end in the negative direction of the X-axis is the tip. The cross-sectional view shown in the drawing is a cross-sectional view seen from the Z-axis direction. The figures referred to herein are all cross-sectional views viewed from the Z-axis in the same direction.

The male connector 10 will be described with reference to FIG. The male connector 10 includes a male terminal 11, a male housing 15, and a male case 16. The male terminal 11 is a metal conductor and is a plate-shaped terminal extending in the X-axis direction. One end 11a of the male terminal 11 in the X-axis direction is embedded in the male housing 15. A male cable (not shown) is connected to one end 11a. On the other hand, the other end 11b protrudes from the inner side surface 15b of the male housing 15. One end 11a is fixed to the male housing 15, and the other end 11b is not fixed to the male housing 15. In other words, the male terminal 11 is a cantilever beam fixed to the male housing 15 at a fixing portion 14 located on the inner side surface 15b of the male housing 15.

The male housing 15 and the male case 16 are resin insulators. The male housing 15 includes a tubular housing portion 15a into which the female housing 55, which will be described later, is inserted. The accommodating portion 15a is open to the tip end side (that is, the X-axis positive direction side) and is closed by the inner side surface 15b in the X-axis negative direction.

The male case 16 houses the male housing 15 and fixes the male housing 15. A through hole 17 penetrating the side wall of the male case 16 in the positive direction of the Y-axis is provided. The through hole 17 also penetrates the male housing 15. The through hole 17 communicates with the space in the accommodating portion 15a.

The female connector 50 will be described with reference to FIG. The female connector 50 includes a female terminal 51, a female housing 55, and a female case 56. The female terminal 51 is a metal conductor made of the same material as the male terminal 11, and is a terminal extending in the X-axis direction. As shown later in FIG. 3, when the male connector 10 and the female connector 50 are fitted, the female terminal 51 extends in parallel with the male terminal 11. One end 51a of the female terminal 51 in the X-axis direction is located on the tip end side (that is, the X-axis negative direction side) of the female connector 50. One end 51a is bent to a position where a fixing member 54 (for example, a metal screw or the like) is arranged. One end 51a is fastened together with one end of the female side cable 52 to the female housing 55 by the fixing member 54.

On the other hand, the other end 51b is formed in a tubular shape. Hereinafter, the other end 51b is referred to as a tubular portion 51b. A convex portion 53 is provided on the inner side surface 51c of the tubular portion 51b on the positive direction side of the Y axis. The convex portion 53 is formed by bending a part of the side wall including the inner side surface 51c of the tubular portion 51b inward of the tubular portion 51b at an end edge. The other end 11b of the male terminal 11 is inserted between the other inner side surface of the tubular portion 51b facing the inner side surface 51c and the convex portion 53. Although the tubular portion 51b is fitted to the female housing 55, it is not fixed to the female housing 55 because there is room for expansion and contraction in the X direction during thermal expansion / contraction.

As shown in FIG. 2, the fixing member 54 for fixing one end 51a to the female housing 55 is located on the tip end side of the female connector 50 when viewed from the other end 51b.

The female housing 55 and the female case 56 are resin insulators. The female housing 55 includes an insertion portion 55a that is inserted into the accommodating portion 15a of the male housing 15. A female terminal 51 is housed inside the insertion portion 55a. A through hole 55b into which the other end 11b of the male terminal 11 is inserted is provided on the side surface of the tip of the insertion portion 55a. The other end 11b passes through the through hole 55b and is inserted into the tubular portion 51b of the female terminal 51.

The female case 56 houses the female housing 55 and fixes the female housing 55. A through hole 57a penetrating the side wall of the female case 56 in the positive direction of the Y-axis is provided. Further, a through hole 57b coaxial with the through hole 57a is provided in the female housing 55.

A state in which the male connector 10 and the female connector 50 are fitted will be described with reference to FIG. As shown in FIG. 3, the other end 11b of the male terminal 11 passes through the through hole 55b of the insertion portion 55a of the female housing 55 and is inserted into the tubular portion 51b of the female terminal 51. Then, the side surface of the male terminal 11 in the Y-axis direction and the top of the convex portion 53 come into contact with each other. In FIG. 3, the reference numeral P1 is attached to the contact point between the male terminal 11 and the convex portion 53.

When the male connector 10 and the female connector 50 are fitted, the fixing portion 14 of the male connector 10 and the fixing member 54 of the female connector 50 are on the same side (that is, the side in the negative direction of the X axis) when viewed from the convex portion 53. To position. Then, the distance L1 in the X-axis direction from the fixed portion 14 to the contact portion P1 is the same as the distance L2 in the X-axis direction from the position of the fixing member 54 in the X-axis direction to the contact portion P1.

When the male connector 10 and the female connector 50 are fitted, the through holes 17 of the male case 16 and the male housing 15, the through holes 57a of the female case 56, and the through holes 57b of the female housing 55 are coaxially arranged. Then, fixing members (not shown) such as screws are inserted into the through holes 17, 57a and 57b. As a result, the female housing 55 is fixed to the male housing 15.

The effect of this embodiment will be described. Since the connector structure of this embodiment is used for cable connection of an in-vehicle device, the ambient temperature thereof changes. Therefore, the male terminal 11 and the female terminal 51 repeat thermal expansion / contraction. Due to the expansion of the male terminal 11, the other end 11b, which is the unfixed end of the cantilever, extends in the positive direction of the X-axis so as to move away from the fixed portion 14. On the other hand, the female terminal 51 extends in the positive direction of the X-axis so that the other end (that is, the tubular portion 51b) that is not fixed to the female housing 55 is moved away from the fixing member 54 due to expansion. Since the male terminal 11 and the female terminal 51 extend in the same direction (that is, in the positive direction of the X-axis), the contact points of the male terminal 11 in contact with the convex portion 53 and the convex portion 53 also move in the same direction. Therefore, the distance that the convex portion 53 moves relative to the male terminal 11 can be reduced as compared with the case where the convex portion 53 and the contact portion move in opposite directions. That is, the sliding distance between the male terminal 11 and the female terminal 51 due to thermal expansion / contraction can be shortened.

The extension amount of the portion between the fixed portion 14 of the male terminal 11 and the contact portion P1 is the product of the distance L1, the coefficient of linear expansion of the male terminal 11, and the temperature rise of the male terminal 11. Therefore, the amount of movement of the male terminal 11 with respect to the fixed portion 14 of the contact portion is an amount proportional to the extension amount. On the other hand, the amount of extension of the portion between the position of the fixing member 54 of the female terminal 51 and the contact portion P1 is the product of the distance L2, the coefficient of linear expansion of the female terminal 51, and the temperature rise of the female terminal 51. .. Therefore, the amount of movement of the convex portion 53 with respect to the fixing member 54 is an amount proportional to the amount of extension. Here, since the male terminal 11 and the female terminal 51 are made of the same metal material, the coefficient of linear expansion of the male terminal 11 and the coefficient of linear expansion of the female terminal 51 are the same. Further, since the male terminal 11 and the female terminal 51 are in contact with each other, the temperature rise of the male terminal 11 and the temperature rise of the female terminal 51 are the same. Since the distance L1 and the distance L2 are the same, the extension amount of the male terminal 11 and the extension amount of the female terminal 51 are also the same. Therefore, the amount of movement proportional to the amount of extension is the same, or the difference is small. Therefore, the distance that the convex portion 53 moves relative to the male terminal 11 can be further reduced.

Further, when the male connector 10 and the female connector 50 are fitted, the female housing 55 is fixed to the male housing 15. The fixing portion 14 of the male housing 15 is restricted from moving relative to the fixing member 54 of the female housing 55. Thereby, the extending directions of the male terminal 11 and the female terminal 51 can be appropriately regulated in the same direction.

(Second Example)
The connector structure of the second embodiment will be described with reference to the drawings. The connector structure of this embodiment is composed of a male connector 110 and a female connector 150.

The male connector 110 will be described with reference to FIG. The male connector 110 includes a male terminal 111, a male housing 115, and a male case 116. Hereinafter, a configuration different from that of the first embodiment will be mainly described.

The male terminal 111 extends in the X-axis direction like the male terminal 11 of the first embodiment. One end 111a of the male terminal 111 in the X-axis direction is bent along the inner side surface 115b of the male housing 115. Then, one end 111a is fastened together with one end of the male side cable 112 to the male housing 115 by the fixing member 114. On the other hand, the other end 111b is not fixed to the male housing 115 as in the first embodiment.

A pair of snap fits 118a and 118b are provided in the accommodating portion 115a of the male housing 115. The pair of snap fits 118a and 118b are respectively arranged on the pair of inner surfaces of the accommodating portion 115a in the Y-axis direction.

A fixing hole 117 is provided on the side wall of the male case 116 in the positive direction of the Y-axis. Unlike the first embodiment, the fixing hole 117 does not penetrate the male housing 115.

The female connector 150 will be described with reference to FIG. The female connector 150 includes a female terminal 151, a female housing 155, and a female case 156.

The female terminal 151 extends in the X-axis direction, like the male terminal 11 of the first embodiment. One end 151a of the female terminal 151 in the X-axis direction is located on the side opposite to the tip of the female connector 150 (that is, in the positive direction of the X-axis). One end 151a is bent into a Z shape. The end of the Z-shape in the positive direction of the X-axis is fastened together with one end of the female side cable 152 by the fixing member 154 to the female housing 155. The Z-shaped portion at one end 151a is hereinafter referred to as a Z-shaped portion 159. The Z-shaped portion 159 functions as a so-called leaf spring.

On the other hand, the other end 151b (cylinder portion 151b) is formed in a tubular shape as in the first embodiment. Although the tubular portion 151b is fitted to the female housing 155, there is room for expansion and contraction in the X direction during thermal expansion / contraction, and the female housing 155 is not fixed. For example, when the tubular portion 151b is pushed in the positive direction of the X-axis, the Z-shaped portion 159 is elastically deformed. Then, the tubular portion 151b moves in the positive direction of the X-axis. That is, the tubular portion 151b can freely move along the X-axis direction.

An opening 155b is provided on the side surface of the tip of the insertion portion 155a of the female housing 155. A female terminal 151 is arranged inside the opening 155b, and the tubular portion 151b is exposed from the opening 155b. Further, the insertion portion 155a is provided with a pair of receiving grooves 158a and 158b. The pair of receiving grooves 158a and 158b are respectively arranged on the pair of side surfaces of the insertion portion 155a in the Y-axis direction. When the insertion portion 155a is inserted into the accommodating portion 115a of the male housing 115, the pair of snap fits 118a and 118b are caught in the pair of receiving grooves 158a and 158b, and the insertion portion 155a is prevented from coming out of the accommodating portion 115a. .. Further, a fixing hole 157 corresponding to one-to-one with the fixing hole 117 of the male case 116 is provided on the side wall of the female case 156 in the positive direction of the Y-axis.

A state in which the male connector 110 and the female connector 150 are fitted will be described with reference to FIG. As shown in FIG. 6, the other end 111b of the male terminal 111 is inserted into the tubular portion 151b of the female terminal 151 exposed from the opening 155b. When the other end 111b is inserted all the way into the tubular portion 151b, the tip of the tubular portion 151b comes into contact with the inner side surface 115b of the male housing 115 via the bent portion 111c of the male terminal 111. Further, when the male connector 110 moves toward the female connector 150, the Z-shaped portion 159 is elastically deformed, and the pair of snap fits 118a and 118b are caught in the pair of receiving grooves 158a and 158b. Then, when a fixing member such as a screw is inserted into the two fixing holes 117 and 157, the female housing 55 is fixed to the male housing 15.

In FIG. 6, reference numeral P2 is attached to a contact portion between the male terminal 111 and the convex portion 153 of the female terminal 151. The fixing member 114 of the male terminal 111 is located on the side in the negative direction of the X-axis when viewed from the convex portion 153. On the other hand, the Z-shaped portion 159 and the fixing member 154 are located on the side in the positive direction of the X-axis when viewed from the convex portion 153. That is, the fixing member 114 and the Z-shaped portion 159 are located in opposite directions with respect to the convex portion 153.

The effect of this embodiment will be described. The male terminal 111 extends in the positive direction of the X-axis so that the other end 111b moves away from the fixing member 114 due to expansion. On the other hand, in the female terminal 151, since the tubular portion 151b is in contact with the male housing 115, the movement of the tubular portion 151b in the negative X-axis direction is restricted. Therefore, the female terminal 151 extends so that one end 151a on which the Z-shaped portion 159 is formed moves in the positive direction of the X-axis due to expansion. In this case, the contact points of the convex portion 153 and the male terminal 111 in contact with the convex portion 153 also move in the same direction (that is, in the positive direction of the X-axis). Therefore, in this embodiment as well, as in the first embodiment, the sliding distance between the male terminal 111 and the female terminal 151 due to thermal expansion / contraction can be shortened.

Further, the convex portion 153 of the female terminal 151 moves with respect to the tip of the tubular portion 151b that is in contact with the bent portion 111c due to expansion. The amount of movement is proportional to the amount of extension calculated by the product of the distance L3, the coefficient of linear expansion of the female terminal 151, and the temperature rise of the female terminal 151. On the other hand, the contact point of the male terminal 111 with the convex portion 153 also moves with the bent portion 111c as the base point. The amount of movement is proportional to the amount of extension calculated by the product of the distance L3, the coefficient of linear expansion of the male terminal 111, and the temperature rise of the male terminal 111. Therefore, the amount of movement of the convex portion 153 and the amount of movement of the contact portion are the same, or the difference is small. Therefore, in this embodiment as well, as in the first embodiment, the distance that the convex portion 153 moves relative to the male terminal 111 can be further reduced.

Further, the female terminal 151 may slide with respect to the male terminal 111 due to a factor other than thermal expansion / contraction, for example, vibration in the X-axis direction. In this embodiment, the tubular portion 151b is in contact with the male housing 115 due to the elastic force of the Z-shaped portion 159. Therefore, the movement of the female terminal 151 with respect to the male terminal 111 in the negative X-axis direction is restricted. Therefore, the distance that the female terminal 151 slides with respect to the male terminal 111 can be reduced due to the vibration in the X-axis direction.

(Third Example)
The connector structure of the third embodiment will be described with reference to the drawings. The connector structure of this embodiment is composed of a male connector 210 and a female connector 250.

The male connector 210 will be described with reference to FIG. The male connector 210 includes a male terminal 211, a male housing 215, and a male case 216. Hereinafter, a configuration different from that of the first embodiment will be mainly described.

The male terminal 211 extends in the Y-axis direction. One end 211a of the male terminal 211 in the Y-axis direction is bent in the negative direction of the X-axis. Then, one end 211a is fastened to the male housing 215 together with one end of the male side cave 212 by the fixing member 214. On the other hand, the other end 211b is in contact with the male housing 215, but there is room for expansion and contraction in the Y direction during thermal expansion / contraction, and the other end 211b is not fixed to the male housing 215.

The accommodating portion 215a of the male housing 115 is provided with a pair of snap fits 218a and 218b as in the second embodiment. A fixing hole 217 is provided on the side wall of the male case 216 in the positive direction of the Y-axis, as in the second embodiment.

The female connector 250 will be described with reference to FIG. The female connector 150 includes a female terminal 151, a female housing 155, and a female case 156.

The female terminal 251 extends in the Y-axis direction. As shown later in FIG. 9, when the male connector 210 and the female connector 250 are fitted, the female terminal 251 extends in parallel with the male terminal 211. One end 251a of the male terminal 211 in the Y-axis direction is bent in the positive direction of the X-axis. Then, one end 251a is fastened together with one end of the female side cave 252 by the fixing member 254 to the female housing 255.

On the other hand, the other end 251b is in contact with the female housing 255, but there is room for expansion and contraction in the Y direction during thermal expansion / contraction, and the other end 251b is not fixed to the female housing 255. Further, the other end 251b is provided with a convex portion 253. The convex portion 253 is formed by bending a part of the other end 251b toward the tip end side in a V shape. That is, the top of the convex portion 253 is located on the tip end side.

An opening 255b is provided on the side surface of the tip of the insertion portion 255a of the female housing 255. A female terminal 251 is arranged inside the opening 255b, and the convex portion 253 is exposed from the opening 255b. Further, the insertion portion 255a is provided with a pair of receiving grooves 258a and 258b as in the second embodiment. A fixing hole 257 is provided on the side wall of the female case 256 in the positive direction of the Y-axis, as in the second embodiment.

A state in which the male connector 210 and the female connector 250 are fitted will be described with reference to FIG. As shown in FIG. 9, when the male connector 210 and the female connector 250 are fitted, the side surface of the male terminal 211 in the positive direction of the X axis comes into contact with the convex portion 253 of the female terminal 251 exposed from the opening 255b.

In FIG. 9, reference numeral P3 is attached to the contact point between the male terminal 211 and the convex portion 253. When the male connector 210 and the female connector 250 are fitted, the fixing member 214 of the male connector 210 and the fixing member 254 of the female connector 250 are on the same side (that is, the side in the positive direction of the Y axis) when viewed from the convex portion 253. Is located in. The distance L5 in the Y-axis direction from the fixing member 214 to the contact point P3 is the same as the distance L6 in the Y-axis direction from the position of the fixing member 254 in the Y-axis direction to the contact point P3.

The effect of this embodiment will be described. Also in this embodiment, since the male terminal 211 and the female terminal 251 extend in the same direction (that is, in the negative direction of the Y axis), the same effect as that of the first embodiment can be obtained. Further, since the distance L5 and the distance L6 are the same, the effect of further reducing the sliding distance can be obtained as in the first embodiment.

The points to be noted regarding the techniques shown in the examples will be described below. The convex portion 53 may be provided on the male terminal 11. That is, it suffices that one of the female terminal and the male terminal is provided with a convex portion that contacts the other.

The place where the fixing member 54 is arranged is an example of the "second fixing place". For example, one end 51a of the female terminal 51 may be fixed to the female housing 55 by being embedded in the female housing 55.

The Z-shaped portion 159 of the second embodiment is an example of the “elastic member”. For example, one end 151a of the female terminal 151 may be fixed to the female housing 155 via a coil spring.

Although specific examples of the present invention have been described in detail above, these are merely examples and do not limit the scope of claims. The techniques described in the claims include various modifications and modifications of the specific examples illustrated above. The technical elements described herein or in the drawings exhibit their technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the techniques illustrated in the present specification or drawings can achieve a plurality of purposes at the same time, and achieving one of the purposes itself has technical usefulness.

10, 110, 210: Male connector 11, 111, 211: Male terminal 112, 212: Male side cable 14: Fixing location 114, 214: Fixing member 15, 115, 215: Male housing 16, 116, 216: Male case 50 , 150, 250: Female connector 51, 151, 251: Female terminal 52, 152, 252: Female side cable 53, 153, 253: Convex 54, 154, 254: Fixing member 55, 155, 255: Female housing 56, 156: 256: Female case 159: Z-shaped part

Claims (2)

It has a connector structure in which a male connector and a female connector fit together.
The male connector has a plate-shaped male terminal whose one end is fixed to the male housing at the first fixing point and the other end is not fixed to the male housing.
The female connector is a female terminal that extends in parallel with the male terminal when fitted with the male connector, one end of which is fixed to the female housing at a second fixing point, and the other end of which is the female housing. It has the female terminal that is not fixed to
One of the female terminal and the male terminal is provided with a convex portion that contacts the other.
Wherein when the male connector and the female connector is fitted, the second fixing portion and the first fixing portion is located on the same side when viewed from the convex portion,
A connector structure in which the distance from the convex portion to the first fixed portion is the same as the distance from the convex portion to the second fixed portion . The one end of the male terminal and the one end of the female terminal extend in a direction in which the male connector fits into the male connector.
The connector structure according to claim 1, wherein the other end of the male terminal and the other end of the female terminal extend in a direction orthogonal to the direction in which the male connector is fitted to the male connector.

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