CN111711015A - Cable connector and connector for vehicle-mounted camera module having the same - Google Patents

Abstract

The invention provides a cable connector which can be miniaturized and can realize good transmission characteristics with a simple structure under the condition of not damaging the assembly performance, and a connector for a vehicle-mounted camera module with the cable connector. The cable connector includes: a contact terminal (20) connected to a cable (63); a locking part (28) which is non-conductive and is arranged on the contact terminal (20); and an insulator (40) to which the contact terminal (20) is fixed, wherein the contact terminal (20) is fixed to the insulator (40) via the locking portion (28).

Description

Cable connector and connector for vehicle-mounted camera module having the same

Technical Field

The present invention relates to a cable connector preferably used for an in-vehicle camera module, and an in-vehicle camera module connector provided with the cable connector.

Background

In the recent vehicle-mounted camera market, with the improvement of ADAS (Advanced driver assistance systems) or image sensing technology for autonomous driving, a high-speed and large-capacitance transmission technology is required, and the necessity of transmission characteristics of a cable connector is increased.

As such a cable connector, for example, there is a cable connector disclosed in patent document 1. The cable connector described in patent document 1 includes a plurality of contact terminals to be crimped onto a cable, and the contact terminals and an insulator are fixed together by pressing the contact terminals into the insulator.

The contact terminal is provided with a flat contact portion, and two claw portions are integrally formed on the contact portion. The claw portions are bent at substantially right angles to the flat contact portions so as to face each other. The contact terminal is inserted and pressed into the insulator by being pushed into the back surface of the claw portion using a jig or the like. Further, the contact terminal and the insulator are fixed together by the claw portion being depressed into the insulator.

Prior art documents

Patent document

Patent document 1: japanese patent laid-open publication No. 2017-73359

Disclosure of Invention

Problems to be solved by the invention

However, in the cable connector described in patent document 1, the claw portion is integrally formed in a part of the metal contact portion, and therefore, there is a possibility that the impedance of the contact terminal is lowered and the transmission characteristic is deteriorated.

Therefore, it is considered that the claw portion is omitted to suppress the decrease in impedance. However, when the claw portion is omitted, the contact terminal cannot be fixed to the insulator.

In view of the above, a case where the height dimension in the upright direction of the claw portion is reduced is considered. However, if the height of the claw portion is reduced, when the back surface of the claw portion is pushed in using a jig or the like, a sufficient space is not secured behind the claw portion, and therefore there is a possibility that the cable or the contact terminal is damaged by the contact of the jig.

As another method for suppressing the decrease in impedance, it is also conceivable to use a claw portion that opens in the left-right direction along the contact portion without bending the claw portion, in addition to reducing the protruding amount of the claw portion. However, when the claw portion is opened in the right-left direction, the contact terminals adjacent to each other in the right-left direction interfere with each other, and therefore, the pitch of the contact terminals is increased. If this is done, it is not preferable because there is a possibility that the size of the cable connector itself is enlarged.

In view of the above, it is conceivable to form the claw portion only on one of the left and right sides. However, in this case, two types of contact portions are required, which are asymmetric in the left-right direction, of the contact terminal having the claw portion formed on the right side and the contact terminal having the claw portion formed on the left side. Therefore, the worker who assembles the cable connector must recognize the left and right of the contact terminal, and there is a possibility that the assembling property is deteriorated.

Therefore, an object of the present invention is to provide a cable connector that can realize a good transmission characteristic with a small and simple structure without impairing the assembling property, and a connector for an in-vehicle camera module including the cable connector.

Means for solving the problems

In order to solve the above problems, the following means are adopted in the cable connector according to the present invention and the connector for a vehicle-mounted camera module including the cable connector.

That is, a cable connector according to an aspect of the present invention includes: a contact terminal connected with a cable; and a locking portion provided on the contact terminal, the locking portion being electrically non-conductive, and a base member to which the contact terminal is fixed, the contact terminal being fixed to the base member via the locking portion.

According to the cable connector of the present aspect, the cable connector includes the contact terminal connected to the cable, the locking portion provided on the contact terminal and being nonconductive, and the base member to which the contact terminal is fixed, and the contact terminal is fixed to the base member via the locking portion. In this case, since the non-conductive locking portion does not lower the impedance of the contact terminal, the contact terminal can be fixed to the base member while achieving a good transmission characteristic. At the same time, by appropriately setting the size of the locking portion, a space for bringing the insertion jig into contact with the back surface of the locking portion is secured, and damage to the cable to be connected can be avoided.

Further, for example, when a contact terminal in which the claw portions are integrally formed is used, complication of the shape of the contact terminal is promoted. However, the shape of the contact terminal can be simplified by not providing the claw portion. In addition, since only the contact terminals having the same shape can be prepared, even when a plurality of contact terminals are provided in parallel with a plurality of cores, the shape of the contact terminal does not need to be recognized by the operator.

In the cable connector according to the aspect of the present invention, the contact terminal includes a contact pin having conductivity to which the cable is connected to a pressure-bonding section provided on a proximal end side, and the locking section is fixed to the contact pin, and the contact pin and the locking section are inserted into the base member.

According to the cable connector of the present aspect, the contact terminal includes a conductive contact pin, the cable is connected to a crimping portion provided on the proximal end side of the conductive contact pin, and the locking portion is fixed to the contact pin, and the contact pin and the locking portion are inserted into the base member. Thus, the contact terminal has a contact pin and an engaging portion, and these contact pin and engaging portion are inserted into the base member. At this time, the locking portion is fixed to the base member, whereby the contact terminal is fixed to the base member via the locking portion.

Further, since the contact pin 22 and the locking portion 28 are separate bodies, the shape of the contact pin 22 can be simplified. In addition, since only the contact pins 22 having the same shape can be prepared, even when a plurality of contact pins 22 are provided in parallel with a plurality of cores, the shape of the contact pin 22 does not need to be recognized by the operator.

In the cable connector according to the aspect of the present invention, a press-fitting space is formed in the base member, and the locking portion is fixed to the base member by being press-fitted into the press-fitting space.

According to the cable connector of the present aspect, the locking portion is fixed to the base member by being press-fitted into the press-fitting space. As the step of press-fitting, for example, the engaging portion can be press-fitted into a press-fitting space communicating with an opening formed in the base member from the opening. This allows the contact terminal to be easily fixed to the base member.

The fixing by the press-fitting of the locking portion is achieved by, for example, forming the press-fitting space to be slightly smaller than the size of the locking portion made of resin.

In the cable connector according to one aspect of the present invention, the locking portion is engaged and fixed to the contact pin by insert molding.

According to the cable connector of the present aspect, the engagement portion is engaged and fixed to the contact pin by insert molding. This makes it possible to easily integrate the contact pin and the locking portion.

The method of fixing the locking portion to the contact pin is not limited to insert molding, and may be, for example, fixing by an adhesive or fixing by fitting.

Further, a cable connector according to an aspect of the present invention includes a plurality of contact terminals connected to a plurality of cables bundled as a multicore cable, and the locking portions of the contact terminals are fixed to one base member.

According to the cable connector of the present aspect, the plurality of contact terminals connected to the plurality of cables bundled as the multicore cables are provided, and the locking portions of the contact terminals are fixed to one base member. Thus, the above-described structure of the contact terminal can be applied to a multi-core cable.

Further, a cable connector according to an aspect of the present invention includes a plurality of contact terminals each having a plurality of contact pins connected to a plurality of bundled multi-core cables, the locking portion of each contact terminal being integrally formed as one member, and the locking portion being fixed to the base member.

According to the cable connector of the present aspect, the plurality of contact terminals each having the plurality of contact pins connected to the plurality of cables bundled as the multicore cable are provided, and the locking portions of the respective contact terminals are integrally formed as one member and fixed to one base member. Thus, the above-described structure of the contact terminal can be applied to a multi-core cable, and in addition, the number of components can be reduced.

A connector for an in-vehicle camera module according to an aspect of the present invention includes the above-described cable connector.

Effects of the invention

According to the present invention, a small and simple structure can be provided, and good transmission characteristics can be achieved without impairing the assembling property.

Drawings

Fig. 1 is a perspective view of a state in which a contact terminal and an insulator are fixed in one embodiment of the present invention.

Fig. 2 is a perspective view of the contact terminal and the insulator before being fixed in one embodiment of the present invention.

Fig. 3 is a perspective view of a contact terminal and an insulator when they are fixed in one embodiment of the present invention.

Fig. 4 is a perspective view of the contact terminal shown in fig. 1 to 3.

Fig. 5 is a graph showing a comparison of transmission characteristics of the cable connector according to the embodiment of the present invention and the cable connector according to the comparative example.

Fig. 6 is a perspective view showing a contact terminal according to a comparative example.

Detailed Description

Hereinafter, a cable connector according to an embodiment of the present invention and a connector for a vehicle-mounted camera module including the cable connector will be described with reference to the drawings.

First, the structure of the cable connector will be explained.

As shown in fig. 1, the cable connector according to the present embodiment includes a contact terminal 20 and an insulator (base member) 40 into which the contact terminal 20 is inserted and fixed.

As shown in fig. 2, the contact terminal 20 includes a contact pin 22 and a locking portion 28 fixed to the contact pin 22.

As shown in fig. 1, the cable connector of the present embodiment is connected to a multi-core cable 60 formed by bundling a plurality of cables 63.

The multi-core cable 60 is configured such that a plurality of cables 63 are bundled by braided wires 62, and the outer side of the braided wires 62 is covered with an outer sheath 61. In this drawing, the cables 63 are set to four.

Each of the four cables 63 has a contact terminal 20 connected thereto, and each contact terminal 20 is fixed to one of the insulators 40.

The contact pin 22 is a flat and long member made of a material having conductivity (e.g., metal). The contact pin 22 has a crimp portion 24 on a base end side (right end side in the drawing) to which a cable 63 (not shown in the drawing) is connected by crimping.

The crimp portion 24 includes a first crimp claw 24A located on the base end side and a second crimp claw 24B located on the tip end side of the first crimp claw 24A.

The "tip" referred to herein is an end portion located on the opposite side of the base end of the contact pin 22, and is an insertion end 26 shown at the left end in the drawing.

As shown in fig. 1, the first crimp claws 24A are claws for crimping the cable 63 from the outside of the sheath 64. The second crimp claws 24B are claws that crimp the core wires of the cable 63 extending from the inside of the sheath 64.

The cable 63 is electrically connected by being crimped to the contact pin 22 by the first crimp claws 24A and the second crimp claws 24B. In the embodiment, the cable 63 is fixed by the first crimp claws 24A and the second crimp claws 24B, but may be connected by other methods or may be arbitrarily changed according to specifications.

As shown in fig. 2, the locking portion 28 is fixed to the contact pin 22 on the insertion end 26 side of the crimp portion 24.

The locking portion 28 is a conductive member to be formed into a rectangular pillar shape by a resin (for example, PBT (polybutylene terephthalate), LCP (liquid crystal polymer), or the like). The locking portion 28 is engaged and fixed to the surface of the contact pin 22 by insert molding.

In this case, it is preferable that a fitting hole for preventing the contact pin 22 from coming off is formed in a part of the joint area with the locking portion 28. This can prevent the locking portion 28 from coming off or being positionally displaced with respect to the contact pin 22.

The method of fixing the contact pin 22 and the locking portion 28 is not limited to insert molding, and may be fixing by an adhesive or fixing by fitting, and may be arbitrarily changed depending on the specification. The shape of the locking portion 28 is not limited to the corner post shape, and can be arbitrarily changed according to the shape of the press-fitting space S1 described later.

The procedure for engaging the locking portion 28 and crimping the cable 63 is as follows.

That is, after the locking portion 28 is fixed to the contact pin 22, the crimping portion 24 of the contact pin 22 is crimped to the cable 63. If the locking portion 28 is engaged before the contact pin 22 is crimped to the cable 63, the cable 63 or the crimp portion 24 may be damaged when the locking portion 28 is engaged, which is not preferable.

As shown in fig. 3, the insulator 40 has a cylindrical main body portion 46, and a terminal guide portion 48 and a plug portion 42 formed integrally with the main body portion 46, and these portions are integrally molded by an insulating material.

In the body portion 46, four press-fitting spaces S1 arranged in a lattice shape are formed in the central portion of one end surface (surface corresponding to the back surface) with the terminal guide portion 48 having a + shape in cross-sectional shape as a partition wall. Each of the press-fitting spaces S1 has an opening communicating with the outside formed on one end surface side of the body 46. The press-fitting space S1 is formed to have a predetermined depth from each opening.

The press-fitting space S1 is a space into which the locking portion 28 engaged with the contact terminal 20 is press-fitted, and the locking portion 28 can be pushed in from the opening toward the inside of the press-fitting space S1.

The depth dimension is set to be smaller than the dimension of the cylindrical body 46 in the axial direction (the height dimension in the cylindrical shape). That is, the depth dimension in the axial direction of the body 46 is set to a dimension to the extent that the press-fitting space S1 does not penetrate the body 46. The depth direction of the press-fitting space S1 coincides with the insertion direction of the contact terminal 20 described later.

Each press-fitting space S1 is formed in a corner post shape and is set to be slightly smaller than the corner post shape of the locking portion 28. This allows the locking portion 28 to be press-fitted into the press-fitting space S1. The shape of the press-fitting space S1 is not limited to the corner post shape, and may be changed to any shape.

The body portion 46 is formed with a through hole communicating with the press-fitting space S1 from the other end surface side (the end surface side opposite to the one end surface). The through-holes are sized to the extent of the cross-sectional shape of the contact pins 22, and are formed in a one-to-one manner with respect to the respective press-fitting spaces S1. Through the through-hole, the contact pin 22 can be inserted from the inside of the press-fitting space S1 toward the terminal guide groove 44 (described later) of the plug portion 42 integrally formed on the other end surface side.

The terminal guide portion 48 is formed so as to partition the four openings and the press-fitting space S1 as described above, and so as to protrude from one end surface of the body portion 46 in a + shape in cross-sectional shape.

The terminal guide 48 is configured such that a vertical guide 48A extending in the vertical direction in the figure and a horizontal guide 48B extending in the left-right direction and perpendicular to the vertical guide 48A are integrally formed.

The longitudinal guide 48A is along the projecting direction of the terminal guide 48, and its thickness dimension is set to be substantially constant.

On the other hand, the lateral guide portions 48B have a thickness dimension that varies along the protruding direction of the terminal guide portions 48. Specifically, the thickness thereof is tapered in a direction from the body portion 46 side toward the end of the terminal guide portion 48.

The number of press-fitting spaces S1 defined by the terminal guide 48 corresponds to the number of cables 63 (i.e., the number of contact terminals 20), and when applied to a 6-core cable, six press-fitting spaces S1 are defined by terminal guides of other shapes (for example, one lateral guide 48B and two longitudinal guides 48A). That is, the cross-sectional shape of the terminal guide 48 and the number of the press-fitting spaces S1 can be arbitrarily changed depending on the number of cables 63 included in the multicore cable 60.

In the case of application to a coaxial cable, the terminal guide portion 48 is omitted, and the number of the press-fitting spaces S1 is set to one.

The plug portion 42 is formed as a portion protruding from the other end surface of the body portion 46, and is formed in a corner post shape.

The plug portion 42 is formed with a number of terminal guide grooves 44 corresponding to the number of contact terminals 20 along the projecting direction of the plug portion 42. In the case of this drawing, two terminal guide grooves 44 are formed on the upper surface side of the plug portion 42, and two terminal guide grooves 44 are formed on the lower surface side of the plug portion 42, which is not shown.

Each of the terminal guide grooves 44 communicates with each of the press-fitting spaces S1 through the through-hole formed in the body 46, and guides the contact pin 22 inserted through the through-hole from the inside of the press-fitting space S1 along the groove direction.

Next, a method of fixing the contact terminal 20 and the insulator 40 will be described.

As shown in fig. 4, first, the insertion end 26 of the contact pin 22 is inserted into the opening of the press-fitting space S1, and the back surface 28A (see fig. 2) of the locking portion 28 is pressed by a jig or the like, so that the contact terminal 20 is pushed toward the insulator 40. The jig or device for pressing the rear surface 28A of the locking portion 28 may be arbitrarily selected according to specifications, and may be automatic or manual.

At this time, the contact pin 22 and the locking portion 28 are guided in the insertion direction by the terminal guide portion 48. Further, the insertion end 26 side of the contact pin 22 is guided in the insertion direction by the terminal guide groove 44. This allows the contact terminal 20 to smoothly move toward the insulator 40.

The "back surface" referred to herein is a surface located on the pressure-bonding section 24 side among the surfaces of the locking section 28, and is represented by, for example, reference numeral 28A shown in fig. 2.

When the locking portion 28 reaches the opening surface of the press-fitting space S1, the back surface 28A of the locking portion 28 is further pressed with a jig or the like, whereby the locking portion 28 is press-fitted and fixed in the press-fitting space S1.

As a result, as shown in fig. 1, the contact terminal 20 is fixed to the insulator 40.

As a method of fixing the locking portion 28 in the press-fitting space S1, there is no limitation to a method of press-fitting the pressing-fitting space S1 to be slightly smaller than the locking portion 28, and for example, a method of forming a claw on an inner wall surface of the insulator 40 defining the press-fitting space S1 and sinking the claw into the locking portion 28, or a method of forming a rib on the locking portion 28 and bringing the rib into contact with the inner wall surface of the insulator 40 defining the press-fitting space S1 may be employed. That is, any method of fixing the locking portion 28 in the press-fitting space S1 can be adopted.

The contact terminal 20 and the insulator 40, which are integrated, are provided with a mold cover, an outer mold, and the like, which are not shown. The plug portion 42 of the insulator 40 in the cable connector in which these respective components are integrated is connected on the camera module side. Such a device is particularly preferably used as a connector for an in-vehicle camera module.

According to the present embodiment, since the clamping part 28 made of resin is integrally fixed to the contact pin 22, impedance is not lowered, and thus the contact terminal 20 can be fixed to the insulator 40 while achieving good transmission characteristics.

Fig. 5 is a graph showing transmission characteristics (solid line) of the cable connector according to the present embodiment and transmission characteristics (broken line) of the cable connector according to the comparative example using the contact pin 122 (see fig. 6). Here, the horizontal axis of the graph represents frequency, and the vertical axis represents transmission characteristics (VSWR: voltage standing wave ratio).

As shown in fig. 6, two metal claw portions 130 are integrally formed with the contact pin 122 according to the comparative example. The claw portion 130 is locked to the insulator 40, whereby the contact terminal 120 is fixed to the insulator 40.

As shown in fig. 5, at a predetermined frequency f1 Hz, the transmission characteristics are good because the value of the transmission characteristics indicated by the solid line is smaller than the value of the transmission characteristics indicated by the broken line, and the cable connector according to the present embodiment has good transmission characteristics.

Further, by appropriately setting the size of the locking portion 28, a space for bringing a jig (jig for pressing the back surface of the locking portion 28) into contact with the back surface of the locking portion 28 is secured, and damage to the cable 63 connected to the pressure-bonding section 24 can be avoided.

The contact pin 22 and the locking portion 28 may be formed separately. This can simplify the shape of the contact pin 22. In addition, since only the contact pins 22 having the same shape can be prepared, even when a plurality of contact pins 22 are provided in parallel with a plurality of cores, the shape of the contact pins 22 does not need to be recognized by the operator.

Furthermore, the locking portion 28 is engaged and fixed to the contact pin 22 by insert molding. This enables the contact pin 22 and the locking portion 28 to be easily integrated.

[ modified examples ]

Although the locking portions 28 are provided independently for each contact pin 22 in the above-described embodiment, a plurality of contact pins 22 may be grouped and fixed by one locking portion 28.

In addition, when one locking portion 28 is insert-molded with respect to the plurality of contact pins 22, the respective contact pins 22 are fixed to the locking portion 28 in a state of being close to each other. In this case, a working space near the pressure-bonding section 24 required for pressure-bonding the contact pins 22 to the cable 63 cannot be secured. Further, it is not practical to perform insert molding after crimping the cable 63. Therefore, when the plurality of contact pins 22 are grouped together by one locking portion 28, the following method is adopted regardless of insert molding.

First, the contact pin 22 is crimped to the cable 63. In addition, four insertion holes into which the contact pins 22 are inserted in advance are formed in the locking portion 28.

Then, the contact pins 22 in a state of being crimped on the cable 63 are inserted into the insertion through holes formed in the locking portions 28, respectively.

At this time, by forming a projection on the contact pin 22 on the insertion end 26 side of the second crimp claws 24B, it is possible to restrict the movement of the locking portion 28 to the base end side of the projection.

As a fixing method of the contact terminal 20 and the insulator 40, the following is described.

That is, the insertion end 26 of the contact pin 22 of each contact terminal 20 is inserted into the press-fitting space S1.

Thereafter, the contact terminal 20 is moved to the insulator 40 side by pulling the protruding contact pin 22 from the plug portion 42 side.

When the locking portion 28 reaches the opening surface of the press-fitting space S1, the contact pin 22 is further pulled, whereby the locking portion 28 is press-fitted and fixed in the press-fitting space S1.

Thereby, the contact terminal 20 is fixed to the insulator 40.

In the modification, since it is not necessary to prepare the number of the locking portions 28 corresponding to the number of the contact terminals 20, the number of components can be reduced. Further, since it is not necessary to divide the plurality of press-fitting spaces S1 in the insulator 40, the terminal guide portion 48 can be omitted.

Description of the symbols

20. A contact terminal;

22. a contact pin;

24. a crimping part;

24A, a first crimp claw;

24B, a second crimp claw;

26. an insertion end (tip);

28. a locking part;

40. an insulator (base member);

42. a plug portion;

44. a terminal guide groove;

46. a main body portion;

48. a terminal guide portion;

48A, a longitudinal guide part;

48B, a transverse guide part;

60. a multi-core cable;

61. an outer sheath;

62. weaving wires;

63. a cable;

64. a sheath;

120. a contact terminal;

122. a contact pin;

130. a claw portion;

and S1, pressing into the space.

Claims (7)

1. A cable connector includes:

a contact terminal connected with a cable;

a locking portion provided on the contact terminal and provided to be non-conductive,

a base member on which the contact terminals are fixed,

the contact terminal is fixed to the base member via the locking portion.

2. The cable connector of claim 1,

the contact terminal has a conductive contact pin to which the cable is connected at a crimping part provided at a base end side,

the detent is fixed relative to the contact pin,

the contact pin and the locking portion are inserted into the base member.

3. The cable connector of claim 2,

in the base member, a press-in space is formed,

the locking portion is fixed to the base member by being press-fitted into the press-fitting space.

4. The cable connector of claim 2 or 3,

the locking part is engaged and fixed to the contact pin by insert molding.

5. The cable connector according to any one of claims 1 to 3,

a plurality of contact terminals connected to the plurality of cables bundled as a multi-core cable,

each of the locking portions of each of the contact terminals is fixed to one of the base members.

6. The cable connector of claim 1 or 3,

a plurality of contact terminals connected to the plurality of cables bundled as a multi-core cable,

the engaging portion of each of the contact terminals is integrally formed as a single member,

the locking portion is fixed to the base member.

7. A connector for a vehicle-mounted camera module, comprising the cable connector according to any one of claims 1 to 6.

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