JP6936710B2 - Connector module and in-vehicle camera using it - Google Patents

Description

The present invention relates to a connector module having a shield case and an in-vehicle camera using the connector module.

Patent Document 1 discloses a plug used for connecting a coaxial cable to a receptacle provided in an electronic circuit unit. Here, the coaxial cable has an inner conductor, an outer conductor that surrounds the inner conductor and shields the inner conductor from electromagnetic noise, and a dielectric (insulator) arranged between the inner conductor and the outer conductor. It is a cable.

The plug comprises an inner contact connected to the inner conductor of the coaxial cable and an outer contact and shell connected to the outer conductor of the coaxial cable. The electronic circuit unit has a shield case for shielding the circuit from electromagnetic noise, and the receptacle provided in the electronic circuit unit has a connection terminal connected to the ground of the circuit. The outer contacts of the plug are electrically connected to the ground of the circuit by being connected to the connection terminals of the receptacle. The shell of the plug conducts with the shield case via a wave washer while being in contact with a predetermined contact pressure. That is, the shield property is improved by connecting the shield case to the ground via a plug. Further, in Patent Document 1, as a form in which a wave washer is not used, a plurality of arms separated by slits are formed at the edge of the opening formed in the center of the bottom of the shield case, and the arms are shelled. The configuration of pressing with the tip of the is disclosed.

Japanese Unexamined Patent Publication No. 2015-210292

However, in the technique disclosed in Patent Document 1, by using a wave washer, the number of parts increases, so that the manufacturing cost may increase. Further, since the wave washer is not completely flat, the contact area between the shield case and the shell of the plug becomes non-uniform, and the shielding effect may be reduced.

On the other hand, in the case where the arm formed in the center of the bottom of the shield case is pressed by the tip of the shell, if the shield case is misaligned, the contact area between the shield case and the shell of the plug becomes uneven, and the shield is shielded. The effect may be reduced.

Therefore, it is desired to provide a connector module having a high shielding property with an inexpensive configuration.

In view of the above, as one embodiment, the connector module transmits a signal and has a central conductor having a linear portion and a through hole through which the linear portion penetrates, and at least a part of the linear portion. A terminal module having a tubular insulator holder that covers and supports the central conductor, and a tubular conductive shell that covers the radial outside of the insulator holder, and a terminal module that is engaged with the terminal module. A bottom tubular conductive case including a shield case that shields electromagnetic waves propagating in the external space of the case, and the shield case is provided in a first direction along the extending direction of the linear portion. It has an orthogonal bottom portion and a side wall portion that bends from the periphery of the bottom portion and extends along the first direction, and the bottom portion has an opening through which the terminal module penetrates and an edge of the opening. It has a plurality of elastically deformable elastic portions that are bent from the portions and protrude along the first direction, and the shield case is engaged with the conductive shell of the terminal module at the elastic portions. An annular recess having a side wall in which the inner ends of the plurality of elastic portions are in contact with each other and electrically connected to the elastic portion is formed in a portion of the conductive shell that is engaged with the elastic portion. ing.

According to this configuration, the annular recess of the conductive shell and the elastic portion of the shield case are electrically in contact with each other without interposing a component such as a wave washer. As a result, even if the position of the shield case is displaced, the side wall of the annular recess and the elastic portion come into contact with each other, and good contact between the conductive shell and the shield case can be maintained. As described above, according to this configuration, it is possible to provide a connector module having a high shielding property with an inexpensive configuration.

Further, it is preferable that each of the plurality of elastic portions has the same shape and is arranged at equal intervals in the circumferential direction.

If a plurality of elastic portions have the same shape and are evenly arranged in the circumferential direction as in this configuration, the path of the current flowing through the elastic portions becomes uniform, so that the shielding effect can be improved.

Further, the terminal module is an annular member, and the outer peripheral portion on the outer side in the radial direction is brought into contact with the inner peripheral surface of the conductive shell by applying pressure, and the inner peripheral portion on the inner side in the radial direction is the center. It is preferable to have an annular internal sealing member that seals the inside of the terminal module in a state where the conductor is brought into contact with the conductor by applying pressure.

By providing the internal sealing member inside the terminal module, it is possible to suppress the infiltration of liquid such as water droplets into the inside of the terminal module such as the center conductor, and it is possible to improve the reliability of the connector module.

Further, a plurality of first annular convex portions are formed on the outer peripheral portion of the internal sealing member by applying pressure to the inner peripheral surface of the conductive shell, and the inner peripheral portion of the internal sealing member is formed. Is formed with a plurality of second annular convex portions that come into contact with the outer peripheral surface of the central conductor by applying pressure, and the first annular convex portion and the second annular convex portion are formed in the radial direction. It is preferable that they are arranged on the same plane.

If the first annular convex portion and the second annular convex portion are arranged on the same plane as in this configuration, the radial inner force received by the first annular convex portion from the conductive shell and the second annular convex portion are generated. Since the radial outer force received from the central conductor is canceled out, the deformation of the internal sealing member can be minimized and the sealing performance can be maintained. Further, by providing a plurality of the first annular convex portion and the second annular convex portion, even if one annular convex portion is deformed and the waterproof performance is deteriorated, the waterproof function is ensured by the other annular convex portion. Can be done.

Further, the conductive shell has an inward extending portion extending radially inward from the inner peripheral surface, and the terminal module is sandwiched between the internal sealing member and the inward extending portion. It is preferable that the center conductor is further provided with an annular tilt prevention member that prevents the center conductor from tilting.

By providing an anti-tilt member that prevents the central conductor from tilting as in this configuration, the tilt of the central conductor can be prevented even if the length of the cylindrical insulator holder that supports the central conductor along the first direction is short. Can be prevented. Further, by sandwiching the anti-tilt member between the inward extending portion and the internal seal member, the displacement of the anti-tilt member itself can be prevented. Therefore, even when the connector module is compactly configured, it is possible to prevent the center conductor from being displaced.

Further, the insulator holder has an elastically deformable engaging portion protruding outward in the radial direction on the rear end side in the direction of being inserted into the conductive shell, and the conductive shell has the engagement portion. It is preferable to have an engaging recess that engages the joint.

Like this configuration, the insulator holder has an elastically deformable engaging portion protruding outward in the radial direction on the rear end side in the direction of being inserted into the conductive shell. Therefore, as the insulator holder is inserted into the conductive shell, the engaging portion elastically deforms inward in the radial direction, and after reaching the engaging recess in the conductive shell, the engaging portion returns to the outward in the radial direction. , The engaging portion and the engaging recess are engaged. Therefore, it is easy to assemble the insulator holder and the conductive shell, and the insulating portion is prevented from falling off because the protruding portion of the engaging portion in the radial direction abuts on the side wall of the engaging recess. .. As a result, the shielding effect of the conductive shell can be ensured for a long period of time.

Further, it is preferable that a partition wall is formed on the bottom side of the engaging recess.

If the engaging recess formed in the conductive shell is formed of a through hole, external electromagnetic noise may enter the inside of the conductive shell through the through hole and noise may be added to the signal. However, as in this configuration, the bottom side of the engaging recess is provided with a partition wall instead of a through hole to form a bottom, so that the above-mentioned inconvenience when the through hole is formed can be prevented.

Further, it is preferable that the linear portion covered with the insulator holder is formed with an annular protrusion protruding outward in the radial direction, and the annular protrusion is integrated with the insulator holder. be.

If an annular protrusion is formed in the linear portion of the central conductor as in this configuration and the annular protrusion is integrated with the insulator holder, the center conductor can be reliably prevented from falling off. As a result, the shielding effect of the conductive shell can be ensured for a long period of time.

In recent years, cameras are often mounted on vehicles for driving assistance and recording of driving conditions. Cameras are often installed on the exterior of vehicles such as bumpers and doors, and image processing devices and monitoring devices are often installed inside vehicles. Therefore, the image processing device or the monitoring device and the camera are often connected by a cable or the like. The connector module described above is used to connect such a cable and is suitable for configuring an in-vehicle camera.

In one embodiment, such an in-vehicle camera is connected to a connector module having any of the above-described configurations and the connector module to drive and control an image pickup element and the image pickup element, and an image output from the image pickup element. A camera module including an electronic circuit for processing a signal and an optical system including a lens that collects light on the image sensor is provided, and the central conductor is electrically connected to the electronic circuit to form the electronic circuit. At least a part is shielded by the shield case.

It is an exploded perspective view of a connector module. It is a figure which shows typically the structure of the camera unit (vehicle-mounted camera). It is an exploded perspective view of a terminal module. It is a vertical sectional view of a connector module. It is a top view of the shield case. It is a rear perspective view of a shield case. It is an exploded perspective view which shows another example of a terminal module. It is a vertical sectional view which shows another example of a terminal module.

Hereinafter, embodiments of the connector module 10 will be described with reference to the drawings. In the present embodiment, as schematically shown in FIG. 2, the connector module 10 used in the camera unit 100 (vehicle-mounted camera) mounted on the vehicle will be described as an example. The camera unit 100 can be used for applications other than in-vehicle use (for example, it may be mounted on a bicycle, a drone, or the like). The camera unit 100 includes a camera module 110 and a connector module 10. The camera module 110 is an optical system including at least an image sensor 101, an electronic circuit 102 that drives and controls the image sensor 101 and processes a video signal output from the image sensor 101, and a lens 103 that collects light on the image sensor 101. It has 104 and.

The camera unit 100 is connected to an image processing device (not shown) or a monitoring device (not shown) by a coaxial cable 120. The coaxial cable 120 is a cable having a structure in which an inner conductor and an outer conductor are arranged coaxially with a dielectric (insulator) interposed therebetween. The inner conductor transmits a signal, and the outer conductor functions as a shield that suppresses the influence of electromagnetic waves on the inner conductor. In the present embodiment, the internal conductor supplies power to the image sensor 101 and the electronic circuit 102 of the camera unit 100 from the image processing device and the monitor device, and also outputs a video signal output from the image sensor 101 and the electronic circuit 102. Output to an image processor or monitor device. That is, the camera unit 100 is a photographing device using a known power supply superimposition method.

The image sensor 101 of the camera module 110 is a CCD (Charge Coupled Device) sensor or a CIS (CMOS Image Sensor). The number of lenses 103 is not limited to one, and may be a plurality of lenses. The electronic circuit 102 includes a clock driver that drives the image pickup element 101, and an analog signal processing circuit that performs analog signal processing such as sample hold and clamp processing on the analog signal output from the image pickup element 101. The electronic circuit 102 may further include an A / D converter that converts an analog signal into a digital signal. Further, the electronic circuit 102 may have a power supply circuit that performs processing such as rectification on the power source supplied by the power supply superimposition method.

The electronic circuit 102 is configured as a circuit board in which electronic components are mounted on one or a plurality of printed circuit boards. When a plurality of circuit boards are provided, a flexible substrate may be used for electrical connection between the circuit boards. A receptacle (not shown) is mounted on a circuit board on which the electronic circuit 102 is formed. The connector module 10 is connected to the receptacle and also to the coaxial cable 120 to electrically connect the electronic circuit 102 and the coaxial cable 120.

FIG. 1 shows an exploded perspective view of the connector module 10. The connector module 10 includes a connector case 8, a terminal module 30, a shield case 7, a main body case 9, and an external seal member 6. Further, as shown in the exploded perspective view of FIG. 3, the terminal module 30 has a central conductor 1, an insulator holder 2, a conductive shell 3, and an internal sealing member 4. The terminal module 30 has the same function as the coaxial cable 120. The central conductor 1 corresponds to the inner conductor of the coaxial cable 120, the insulator holder 2 corresponds to the dielectric (insulator) of the coaxial cable 120, and the conductive shell 3 corresponds to the outer conductor of the coaxial cable 120. The characteristic impedance of the terminal module 30 is preferably the same as that of the coaxial cable 120. That is, the connector module 10 (terminal module 30) has a predetermined characteristic impedance (for example,) based on the outer diameter of the central conductor 1, the inner diameter of the conductive shell 3, and the relative permittivity of the insulator holder 2. 50 [Ω]) is set.

Returning to FIG. 1, the connector case 8 is a case that houses the terminal module 30, the shield case 7, and the external seal member 6. Since the connector case 8 is located behind the camera module 110 in the camera unit 100, it may be referred to as a rear case. The camera module 110 is housed in the main body case 9. In the camera unit 100, the main body case 9 may be referred to as a front case with respect to the rear case. The connector case 8 and the main body case 9 are in contact with each other, and a storage space for the terminal module 30, the shield case 7, the external seal member 6, and the camera module 110 is formed inside.

As shown in the vertical cross-sectional view of FIG. 4, the shield case 7 shields the internal space E2 of the shield case 7 from the electromagnetic waves propagating in the external space E1 of the shield case 7. The shield case 7 covers at least a part of the electronic circuit 102 of the camera module 110 to shield the electronic circuit 102 from electromagnetic waves such as electromagnetic noise. The shield case 7 is connected to the ground of the electronic circuit 102. The outer conductor of the coaxial cable 120 is electrically connected to the conductive shell 3. Further, as will be described later, the shield case 7 and the conductive shell 3 are electrically connected to each other. Therefore, when the shield case 7 is connected to the ground of the electronic circuit 102, the outer conductors of the conductive shell 3 and the coaxial cable 120 are also electrically connected to the ground of the electronic circuit 102.

As described above, the camera unit 100 (vehicle-mounted camera) collects the image sensor 101, the electronic circuit 102 that drives and controls the image sensor 101 and processes the video signal output from the image sensor 101, and the image sensor 101. It includes a camera module 110 having an optical system 104 having a shining lens 103, and a connector module 10. Then, the central conductor 1 is electrically connected to the electronic circuit 102, and at least a part of the electronic circuit 102 is shielded by the shield case 7. Hereinafter, the connector module 10 will be described in detail.

As described above, the terminal module 30 has a central conductor 1, an insulator holder 2, a conductive shell 3, and an internal sealing member 4. As shown in FIG. 3, the central conductor 1 is a linear conductor that transmits a signal. In the present embodiment, the central conductor 1 is composed of only the linear portion 1a, and the extending direction of the central conductor 1 will be hereinafter referred to as the first direction L. Further, the direction orthogonal to the first direction L is referred to as a radial direction R, the direction toward the central conductor 1 in the radial direction R is referred to as a radial inner R1 and the direction away from the central conductor 1 is referred to as a radial outer R2.

The insulator holder 2 is a thick cylindrical member having a through hole 23 (conductor through hole) through which the center conductor 1 penetrates in the center of the cylindrical insulator. The length of the insulator holder 2 in the first direction L is shorter than that of the central conductor 1. Therefore, the insulator holder 2 covers the central portion 14 (main line portion) in the first direction L (extending direction of the central conductor 1) of the central conductor 1 and supports the central conductor 1 (see FIG. 4). That is, both ends of the central conductor 1 are not covered by the insulator holder 2 and are exposed to become the first terminal portion 11 and the second terminal portion 12. As shown in FIGS. 3 and 4, the first terminal portion 11 is arranged on the side of the coaxial cable 120, and the second terminal portion 12 is arranged on the side of the camera module 110 (for example, the side of the receptacle). Although the exploded perspective view is shown in FIG. 3 for convenience, the central conductor 1 is insert-molded into the insulator holder 2. At both ends of the central portion 14 covered with the insulator holder 2, a first annular protrusion 14a and a second annular protrusion 14b (an example of the annular protrusion) are formed so as to protrude outward R2 in the radial direction. If annular protrusions 14a and 14b are formed at both ends of the central portion 14 of the central conductor 1 and the central portions 14 are insert-molded into the insulator holder 2 to be integrated, the central conductor 1 becomes an insulator. It is surely prevented from falling off from the holder 2. Further, the outer diameters of the first terminal portion 11 and the second terminal portion 12 are set smaller than the outer diameter of the central portion 14. As described above, the linear portion 1a of the central conductor 1 is composed of the first terminal portion 11, the second terminal portion 12, and the central portion 14. The central conductor 1 may be formed with only one of the first annular protrusion 14a and the second annular protrusion 14b.

The insulator holder 2 extends radially outward R2 toward the second terminal portion 12 at the end portion on the side of the second terminal portion 12, and has a plurality of elastically deformable projecting pieces 22 (the present embodiment). 3) (see FIGS. 3 to 4). These projecting pieces 22 are composed of a cantilever-shaped arm having a free end on the side of the second terminal portion 12. Each of the projecting pieces 22 has a stepped base portion 22a whose diameter is expanded outward in the radial direction R2, and an extension portion 22b extending from the base portion 22a to the side of the second terminal portion 12 along the first direction L. A protruding portion 22c (an example of an engaging portion) in which an end portion (the rear end side in the insertion direction of the insulator holder 2 with respect to the conductive shell 3) on the side of the second terminal portion 12 of the protruding portion 22b is projected to the radial outer side R2. ) And. As the insulator holder 2 is inserted into the conductive shell 3, the protruding portion 22c elastically deforms inward R1 in the radial direction and reaches the first engaging recess 31 (an example of the engaging recess) of the conductive shell 3, which will be described later. After that, the protruding portion 22c returns to the outer side R2 in the radial direction, and the protruding portion 22c and the first engaging recess 31 engage with each other. Therefore, the insulator holder 2 and the conductive shell 3 can be easily assembled, and the projecting piece 22 engages with the first engaging recess 31 of the conductive shell 3, so that the insulator holder 2 becomes conductive. It is prevented from falling off from the shell 3. Further, when the base portion 22a of the projecting piece 22 comes into contact with the stepped portion 35 of the conductive shell 3, which will be described later, the insulator holder 2 is positioned when it is inserted into the conductive shell 3, and the insulator holder is positioned in the insertion direction. 2 is prevented from moving.

The conductive shell 3 is a cylindrical member that covers the radial outer side R2 of the insulator holder 2. The conductive shell 3 is made of metal. The inner diameter of the conductive shell 3 is one of the parameters that define the characteristic impedance as described above, and the inner peripheral surface 3a is formed substantially uniformly. However, as will be described later with reference to FIG. 4, the conductive shell 3 has an annular extension portion that extends annularly from the inner peripheral surface 3a to the radial inner side R1 on a part of the side of the first terminal portion 11. 33 (an example of an inward extending portion) is formed. Further, a first engaging recess 31 which is annularly recessed from the inner peripheral surface 3a to the outer diameter R2 in the radial direction is formed in a part on the side of the second terminal portion 12. As described above, the plurality of projecting pieces 22 of the insulator holder 2 are engaged with the first engaging recess 31. As a result, the insulator holder 2 is fixed to the conductive shell 3.

A bottom wall 31a (an example of a partition wall) is integrally formed on the bottom side of the first engaging recess 31, so that electromagnetic noise is prevented from entering the insulator holder 2. The first engaging recess 31 in the present embodiment is formed by cutting the inner peripheral surface 3a of the conductive shell 3. Further, a stepped portion 35 having a step drop on the outer side R2 in the radial direction is formed between the annular extending portion 33 and the first engaging recess 31, and the base portion 22a of the projecting piece 22 described above comes into contact with the annular extending portion 33. The annular extending portion 33 of the conductive shell 3 may project only a part of the inner peripheral surface 3a inward R1 in the radial direction. Further, the bottom wall 31a of the first engaging recess 31 may be formed by fixing another member to the through hole.

The conductive shell 3 is formed with a second engaging recess 32 that is annularly recessed from the outer peripheral surface 3b near the center to the inner diameter R1 in the radial direction. By engaging the second engaging recess 32 with the plurality of engaging claws 81a of the connector case 8 described later, the conductive shell 3 is prevented from falling off from the connector case 8. Further, the tubular end portion 34 of the conductive shell 3 is formed with a third engaging recess 34a (an example of the annular recess) which is annularly recessed from the outer peripheral surface 3b to the inner side R1 in the radial direction.

The shield case 7 is a bottomed rectangular tubular case. The shield case 7 is provided from the electromagnetic waves existing in the external space E1 of the shield case 7, for example, electromagnetic waves transmitted by the central conductor 1 and electromagnetic noise affecting the electronic circuit 102 of the camera module 110. Shields the internal space E2 of. Therefore, the shield case 7 is also made of a conductive material such as metal. The shield case 7 has a bottom portion 71 orthogonal to the first direction L along the stretching direction of the central conductor 1, and a side wall portion 72 that bends from the periphery of the bottom portion 71 and extends along the first direction L. There is. Further, as shown in FIGS. 4 to 6, the bottom portion 71 is bent from the opening 73 through which the terminal module 30 (conductive shell 3) penetrates and the edge portion (opening edge portion 73e) of the opening 73. It has a plurality of (six in this embodiment) elastic portions 75 that are elastically deformable and project in a cylindrical shape along one direction L. The inner ends 75a of the plurality of elastic portions 75 come into contact with the bottom portion 34a1 of the third engaging recess 34a and one side wall 34a2, respectively, so that the shield case 7 and the terminal module 30 (conductive shell 3) are electrically connected. (See FIG. 4). In the present embodiment, each of the plurality of elastic portions 75 is formed in the same shape having a trapezoidal plate shape, and is arranged at equal intervals in the circumferential direction. The plurality of elastic portions 75 may be formed in a triangular flat plate shape or the like, or may have different shapes and intervals, and are not particularly limited.

As shown in FIGS. 1 and 4, the connector case 8 is a case for accommodating a part of the terminal module 30 and the shield case 7. The connector case 8 has a cylindrical space E3 containing the terminal module 30 and a rectangular tubular space accommodating a part of the shield case 7 on the inner surface side. Since the outer surface of the terminal module 30 is a conductive shell 3 and the shield case 7 is also conductive, the connector case 8 is made of resin or the like in order to insulate the conductive shell 3 and the shield case 7 from the outside of the connector module 10. It is made of an insulating (non-conductive) material.

A plurality of (four in this embodiment) engaging grooves 81 are formed on the inner peripheral surface 8a of the connector case 8. A plurality of these engaging grooves 81 extend from the base end portion (side wall portion) to the side of the shield case 7 along the first direction L, and the tips thereof project outward in the radial direction R1 (four in the present embodiment). The engaging claw 81a is provided. As described above, these engaging claws 81a are engaged with the second engaging recess 32 of the conductive shell 3.

In the present embodiment, the tubular end portion 34 of the conductive shell 3 is press-fitted into the elastic portion 75 (see FIG. 4), and the third engaging recess 34a of the conductive shell 3 and the inner end of the elastic portion 75. It is pressure-welded to 75a and electrically connected. As a result, the intrusion of electromagnetic waves from the external space E1 to the internal space E2 of the shield case 7 and the leakage of electromagnetic waves from the internal space E2 to the external space E1 are appropriately suppressed. The electrical connection between the conductive shell 3 and the shield case 7 is not limited to the press fitting as described above. After inserting the tubular end 34 of the conductive shell 3 into the elastic portion 75, the inner end 75a of the elastic portion 75 is welded, adhered, or soldered to the third engaging recess 34a. The conductive shell 3 and the shield case 7 may be joined.

As shown in FIGS. 3 and 4, the internal sealing member 4 seals the terminal module 30 that functions as a coaxial cable so that liquid or the like does not enter the terminal module 30. The internal seal member 4 is an annular member (elastic member) having an elastic force. A plurality of (two in this embodiment) first annular convex portions 41 are formed on the outer peripheral portion 4b of the radial outer side R2 of the inner seal member 4 so as to press contact with the inner peripheral surface 3a of the conductive shell 3. Further, a plurality of (two in this embodiment) second annular convex portions 42 that are in pressure contact with the central conductor 1 are formed on the inner peripheral portion 4a of the radial inner side R1 of the internal sealing member 4. The first annular convex portion 41 and the second annular convex portion 42 are arranged on the same plane in the radial direction R. If the first annular convex portion 41 and the second annular convex portion 42 are arranged on the same plane in the radial direction R, the force of the radial inner R1 received by the first annular convex portion 41 from the conductive shell 3 and the third. Since the force of the radial outer R2 received from the central conductor 1 by the bicyclic convex portion 42 is canceled out, the deformation of the internal sealing member 4 can be minimized and the sealing performance can be maintained. Further, by providing a plurality of the first annular convex portion 41 and the second annular convex portion 42, even if one annular convex portion 41, 42 is deformed and the waterproof function is deteriorated, the other annular convex portion 41, The waterproof function can be ensured by 42.

As described above, the conductive shell 3 has an annular extending portion 33 extending in an annular shape from the inner peripheral surface 3a. The inner seal member 4 has a terminal module in which one surface in the first direction L is locked by the annular extension 33 and the other surface is locked by the end surface 21 in the first direction L of the insulator holder 2. It is installed at 30.

In this way, the terminal module 30 abuts one side of the internal seal member 4 on the annular extension portion 33, and abuts the insulator holder 2 supporting the central conductor 1 on the other side of the internal seal member 4. The projecting piece 22 of the insulator holder 2 is engaged with the first engaging recess 31 of the conductive shell 3. In other words, in the terminal module 30, the internal seal member 4 and the insulator holder 2 are sandwiched between the annular extension portion 33 and the projecting piece 22 of the insulator holder 2 in a direction along the first direction L. It is placed in the specified position.

The terminal module 30 thus formed is electrically connected to the shield case 7. An intermediate assembly in which the terminal module 30 and the shield case 7 are joined is appropriately referred to as a terminal module assembly. The terminal module assembly is attached to the connector case 8.

The terminal module assembly is housed in the connector case 8 by inserting the terminal module 30 side of the terminal module assembly from the rectangular tubular space toward the cylindrical space E3 of the connector case 8 along the first direction L. be able to. At this time, a plurality of hole portions 77 (see FIGS. 4 to 6) formed in the bottom portion 71 of the shield case 7 are positioned by being inserted into the convex portions 82 of the connector case 8, and the engaging claws of the connector case 8 are positioned. 81a engages with the second engaging recess 32 of the conductive shell 3. As a result, the movement of the terminal module 30 along the first direction L is restricted with respect to the connector case 8. Further, an external seal member 6 is attached to the cylindrical space E3 in order to prevent the liquid from entering the cylindrical space E3 of the connector case 8. In the present embodiment, the external seal member 6 is arranged so as to abut the bottom portion 71 of the shield case 7 in the first direction L. The outer seal member 6 is also an annular member (elastic member) having an elastic force, like the inner seal member 4. The outer peripheral portion 6b of the radial outer side R2 of the outer sealing member 6 is in pressure contact with the inner peripheral surface 8a of the connector case 8 forming the cylindrical space E3. Further, the inner peripheral portion 6a of the radial inner side R1 of the outer sealing member 6 is in pressure contact with the outer peripheral surface 3b of the conductive shell 3.

When the connector module 10 is used in the camera unit 100 as an in-vehicle camera as in the present embodiment, sealing using the internal seal member 4 and the external seal member 6 is effective. The camera unit 100 as an in-vehicle camera is often used, for example, for driving support and recording of a traveling state. At this time, the camera unit 100 is often installed on the exterior of the vehicle such as a bumper or a door. The exterior of the vehicle is easily exposed to rain, snow, and water droplets from puddles on the road. Therefore, it is preferable to impart waterproofness to the connector module 10 by applying the sealing as described above.

The assembly in which the terminal module 30 and the shield case 7 are housed and fixed in the connector case 8 is the connector module 10 in a narrow sense. The connector module 10 in the narrow sense may be further referred to as a connector module 10 including the main body case 9. However, when the main body case 9 is included, the camera module 110 may be housed in the main body case 9. In this case, the connector module 10 has almost the same meaning as the camera unit 100. Therefore, the terminal module 30 and the shield case 7 are housed in the connector case 8 and fixed, the intermediate assembly including the main body case 9, and the camera unit 100 containing the camera module 110 are all connectors. It can be made to correspond to the module 10. In the present embodiment, unless otherwise specified, an assembly in which the terminal module 30 and the shield case 7 are housed and fixed in the connector case 8 will be referred to as a connector module 10.

Here, a form in which the terminal module assembly is attached to the connector case 8 and the connector module 10 is assembled is illustrated, but the form is not limited to that form. For example, only the terminal module 30 can be attached to the connector case 8 to form a connector case assembly. Then, the connector module 10 may be assembled by joining the conductive shell 3 of the connector case assembly and the shield case 7. Further, after attaching only the conductive shell 3 to the connector case 8, the inner seal member 4 and the insulator holder 2 holding the central conductor 1 are attached to the conductive shell 3 in this order, and then the shield case 7 is attached. The connector module 10 may be assembled by joining. Here, the case where the center conductor 1 is held in the insulator holder 2 is illustrated first, but after the insulator holder 2 is inserted into the conductive shell 3, the center conductor 1 is inserted into the through hole 23 of the insulator holder 2. You may insert it.

As described above, the connector module 10 can be assembled with a small number of parts and a small number of steps without using a washer or the like. That is, according to the present embodiment, it is possible to realize the connector module 10 which has a high shielding property with a small number of parts and can connect the coaxial cable 120 and the circuit unit (camera unit 100).
Further, in the present embodiment, the third engaging recess 34a of the conductive shell 3 and the elastic portion 75 of the shield case 7 are engaged with each other in an electrically contacted state. As a result, even if the shield case 7 is misaligned, the side wall 34a2 of the third engaging recess 34a and the inner end 75a of the elastic portion 75 come into contact with each other to bring the conductive shell 3 into contact with the shield case 7. Can be maintained well. Further, since the plurality of elastic portions 75 have the same shape and are evenly arranged in the circumferential direction, the path of the current flowing through the elastic portions 75 becomes uniform, and the shielding effect can be improved.

[Other Embodiments]
Hereinafter, other embodiments will be described. The configuration of each embodiment is not limited to the one applied independently, and can be applied in combination with the configuration of other embodiments as long as there is no contradiction. Further, the members having the same functions as those in the above-described embodiment will be described using the same member names, and detailed description thereof will be omitted.

(1) FIGS. 7 to 8 show another embodiment of the terminal module 30A. The insulator holder 2A in the present embodiment is configured to have a smaller dimension along the first direction L than the insulator holder 2 of the terminal module 30 in the above-described embodiment. As a result, the dimensions of the central conductor 1A in this embodiment are also smaller than the dimensions of the central conductor 1 in the above-described embodiment. Therefore, the region where the central conductor 1A is supported by the insulator holder 2A along the first direction L is small, and the central conductor 1A may tilt. Therefore, the terminal module 30A of the present embodiment has an anti-tilt member 5 for preventing the central conductor 1A from tilting between the internal seal member 4A and the annular extending portion 33A of the conductive shell 3A.

That is, the terminal module 30A in the present embodiment has a central conductor 1A, an insulator holder 2A, a conductive shell 3A, an internal seal member 4A, and an anti-tilt member 5.

The linear portion 1Aa of the central conductor 1A is composed of a first terminal portion 11A, a second terminal portion 12A, a diameter-expanded portion 13A, and a central portion 14A. The central conductor 1A is supported by the insulator holder 2A by bringing the enlarged diameter portion 13A into close contact with the inner peripheral surface of the insulator holder 2A. Although the exploded perspective view is shown in FIG. 7 for convenience, the center conductor 1A is insert-molded into the insulator holder 2A. Similar to the above-described embodiment, the first annular protrusion 14Aa and the second annular protrusion 14Ab (an example of the annular protrusion) protruding outward R2 in the radial direction are formed at both ends of the central portion 14A of the central conductor 1A. This prevents the center conductor 1A from falling off from the insulator holder 2A.

The insulator holder 2A has a plurality of elastically deformable projecting pieces 22A (three in the present embodiment) at the end on the side of the first terminal portion 11A. These projecting pieces 22A are cantilevered having a free end extending in the circumferential direction from a plurality of projecting portions 24 (three in the present embodiment) protruding at equal intervals from the outer peripheral surface of the insulator holder 2A to the outer side R2 in the radial direction. It is structured like a beam. Each of the projecting pieces 22 extends from the projecting portion 24 along the circumferential direction with the contact surface 22Aa that abuts on the side surface 31Ab on the first terminal portion 11A side of the first engaging recess 31A of the conductive shell 3A, which will be described later. The extending portion 22Ab and the protruding portion 22Ac (an example of the engaging portion) in which the rear end side of the extending portion 22Ab in the insertion direction with respect to the conductive shell 3A is projected to the radial outer side R2. And have.

The conductive shell 3A is formed with a first engaging recess 31A (an example of an engaging recess) which is annularly recessed from the inner peripheral surface 3Aa to the outer side R2 in the radial direction in a part on the side of the second terminal portion 12A. .. Similar to the above-described embodiment, when the insulator holder 2A is inserted into the conductive shell 3A, the plurality of projecting portions 22Ac of the insulator holder 2A engage with the first engaging recess 31A, whereby the insulator holder It is prevented that 2A falls off from the conductive shell 3A. Further, the contact surface 22Aa of the insulator holder 2A and the side surface 31Ab of the first engaging recess 31A of the conductive shell 3A come into contact with each other, so that the insulator holder 2A is positioned when it is inserted into the conductive shell 3A. At the same time, the insulator holder 2A is prevented from moving in the insertion direction. Further, a bottom wall 31Aa (an example of a partition wall) is integrally formed on the bottom side of the first engaging recess 31A to prevent electromagnetic noise from entering the insulator holder 2A side. The conductive shell 3A is formed with a third engaging recess 34Aa (an example of the annular recess) which is recessed in an annular shape with which the elastic portion 75 engages. The description is omitted.

Similar to the above-described embodiment, the internal sealing member 4A is formed with a plurality of (two in this embodiment) first annular convex portions 41A that are in pressure contact with the inner peripheral surface 3Aa of the conductive shell 3, and is formed on the central conductor 1. A plurality of (two in this embodiment) second annular convex portions 42A to be pressure-welded are formed. The first annular convex portion 41A and the second annular convex portion 42A in the present embodiment are formed in a donut shape that is continuously inclined from the end face. As a result, the shaft length of the internal seal member 4A can be made compact.

The tilt prevention member 5 is an annular member (elastic member) having an elastic force. A plurality of (three in the present embodiment) first protrusions 51 arranged at equal intervals in the circumferential direction are formed on the outer peripheral portion 5b of the tilt prevention member 5. Further, a plurality of (three in the present embodiment) second protrusions 52 arranged at positions that are in the same linear shape with respect to the radial direction R from the center are formed on the inner peripheral portion 5a of the tilt prevention member 5. There is. As shown in FIG. 8, the first protrusion 51 of the radial outer side R2 of the tilt prevention member 5 is in pressure contact with the inner peripheral surface 3Aa of the conductive shell 3A. Further, the second protrusion 52 of the radial outer side R2 of the tilt prevention member 5 is in pressure contact with the central conductor 1A. Since the anti-tilt member 5 is an elastic member, it is flexibly deformed according to the inner diameter of the conductive shell 3A and the outer diameter of the central conductor 1A and is pressed against the central conductor 1A.

By providing the tilt prevention member 5 for preventing the center conductor 1A from tilting as in the present embodiment, even when the length of the cylindrical insulator holder 2A supporting the center conductor 1A along the first direction L is short. , The inclination of the central conductor 1A can be prevented. Further, by sandwiching the tilt prevention member 5 between the annular extension portion 33A and the internal seal member 4A, the displacement of the tilt prevention member 5 itself is prevented. Therefore, even when the terminal module 30A is compactly configured, it is possible to prevent the center conductor 1A from being displaced.

(2) In the above-described embodiment, the central conductors 1 and 1A are composed of only the linear portions 1a and 1Aa, but for example, the first terminal portions 11 and 11A may be bent and connected to the coaxial cable 120, and the center may be connected. The shape of the conductors 1 and 1A is not particularly limited as long as it has the linear portions 1a and 1Aa.

(3) In the above-described embodiment, the inner end 75a of the elastic portion 75 is brought into contact with the bottom portion 34a1 of the third engaging recess 34a of the conductive shell 3 and one side wall 34a2, but the central portion of the elastic portion 75 is also the first. (3) The bottom portion 34a1 of the engaging recess 34a may be brought into contact with the elastic portion 75, and the contact portion between the elastic portion 75 and the third engaging recess 34a is not particularly limited. Further, the elastic portion 75 may be bent from the opening edge portion 73e and protrude in the direction opposite to the side wall portion 72 (the direction opposite to the internal space E2 of the shield case 7).

(4) The arrangement positions of the internal seal members 4 and 4A in the terminal module 30 in the first direction L are not limited to the modes illustrated in FIGS. 4 and 8. For example, the internal seal members 4, 4A may be arranged on the side of the second terminal portions 12, 12A with respect to the insulator holder 2. Similarly, the anti-tilt member 5 may also be arranged on the side of the second terminal portions 12 and 12A with respect to the insulator holder 2.

(5) The internal sealing members 4, 4A or the external sealing member 6 in the above-described embodiment may be omitted as appropriate, and one or three first annular convex portions 41, 41A and second annular convex portions 42, 42A may be omitted. One or more may be provided.

The present invention can be used for connector modules such as in-vehicle cameras.

1,1A Center conductor 1a, 1Aa Linear part 2,2A Insulator holder 3,3A Conductive shell 3a, 3Aa Inner peripheral surface of conductive shell 4,4A Inner sealing member 4a Inner peripheral part 4b of inner sealing member Outer circumference of member 7 Shield case 10 Connector module 14a, 14Aa First annular protrusion (annular protrusion)
14b, 14Ab Second annular protrusion (annular protrusion)
22c, 22Ac protruding part (engaging part)
30,30A Terminal module 31,31A First engaging recess (engaging recess)
31a, 31Aa Bottom wall (bulkhead)
33,33A Ring extension (inward extension)
34a, 34Aa Third engaging recess (annular recess)
41, 41A First annular convex portion 42, 42A Second annular convex portion 71 Bottom 72 Side wall 73 Opening 73e Opening edge 75 Elastic portion 100 Camera unit (vehicle-mounted camera)
101 Imaging element 102 Electronic circuit 103 Lens 104 Optical system 110 Camera module 120 Coaxial cable L 1st direction R radial direction R1 radial inside R2 radial outside

Claims (9)

A central conductor that transmits signals and has a linear part,
A cylindrical insulator holder having a through hole through which the linear portion penetrates and covering at least a part of the linear portion to support the central conductor.
A terminal module having a cylindrical conductive shell that covers the radial outside of the insulator holder, and
It is a bottomed cylindrical conductive case engaged with the terminal module, and includes a shield case that shields electromagnetic waves propagating in the external space of the case.
The shield case has a bottom portion orthogonal to the first direction along the extending direction of the linear portion, and a side wall portion that bends from the periphery of the bottom portion and extends along the first direction.
The bottom portion has an opening through which the terminal module penetrates, and a plurality of elastically deformable elastic portions that are bent from the edge portion of the opening and protrude along the first direction.
The shield case is engaged with the conductive shell of the terminal module at the elastic portion.
An annular recess having a side wall in which the inner ends of the plurality of elastic portions are in contact with each other and electrically connected to the elastic portion is formed in a portion of the conductive shell that is engaged with the elastic portion. Connector module. The connector module according to claim 1, wherein each of the plurality of elastic portions has the same shape and is arranged at equal intervals in the circumferential direction. The terminal module is an annular member, and the outer peripheral portion on the outer side in the radial direction is brought into contact with the inner peripheral surface of the conductive shell by applying pressure, and the inner peripheral portion on the inner side in the radial direction is in contact with the central conductor. The connector module according to claim 1 or 2, further comprising an annular internal sealing member that seals the inside of the terminal module in a state of being brought into contact with pressure. A plurality of first annular convex portions are formed on the outer peripheral portion of the internal sealing member so as to apply pressure to the inner peripheral surface of the conductive shell to make contact with the inner peripheral surface.
A plurality of second annular convex portions that are in contact with the outer peripheral surface of the central conductor by applying pressure are formed on the inner peripheral portion of the internal sealing member.
The connector module according to claim 3, wherein the first annular convex portion and the second annular convex portion are arranged on the same plane in the radial direction. The conductive shell has an inward extending portion extending radially inward from the inner peripheral surface.
3. The connector module described in. The insulator holder has an elastically deformable engaging portion protruding outward in the radial direction on the rear end side in the direction of being inserted into the conductive shell.
The connector module according to any one of claims 1 to 5, wherein the conductive shell has an engaging recess that engages with the engaging portion. The connector module according to claim 6, wherein a partition wall is formed on the bottom side of the engaging recess. An annular protrusion that protrudes outward in the radial direction is formed in the linear portion that is covered by the insulator holder.
The connector module according to claim 6 or 7, wherein the annular protrusion is integrated with the insulator holder. The connector module according to any one of claims 1 to 8.
An optical system connected to the connector module, including an image pickup element, an electronic circuit that drives and controls the image pickup element and processes a video signal output from the image pickup element, and a lens that collects light on the image pickup element. With a camera module,
An in-vehicle camera in which the central conductor is electrically connected to the electronic circuit, and at least a part of the electronic circuit is shielded by the shield case.

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