JP7185450B2 - connector, board with connector - Google Patents

Description

The present invention relates to a connector mounted on a wiring board and a board with a connector.

Many electronic endoscopes employ an image pickup module in which a solid-state image pickup device (hereinafter simply referred to as an image pickup device) is electrically connected to the tip of an electric cable via a wiring board (for example, patent Reference 1).
In this type of imaging module, the ends of a plurality of electric cables are electrically connected to the wiring of the wiring board, and each electric cable is electrically connected to the imaging device via the wiring of the wiring board.
In addition, when this type of imaging module is incorporated into a videoscope device of an electronic endoscope system, a step of passing it through a thin resin tube is performed. It was common practice to solder the rear end) to a relay board that was electrically connected to the video processing display, including the monitor.

JP 2006-109097 A

The process of passing the imaging module through the resin tube includes inserting the imaging module into the tube from the imaging device side, and inserting the imaging module at the rear end (proximal side end. Specifically, the rear end of the electric cable). It is also widely practiced to insert it into the tube from the beginning.
For example, when an electrical connection plug is assembled at the rear end of the image pickup module to detachably fit into a receptacle on the side of the video processing display device, the image pickup module cannot be inserted through the tube from the rear end side. was normal. Therefore, in the process of inserting the imaging module from its rear end into the tube, the rear end of the electric cable of the imaging module is inserted into the tube as it is without a plug. As a result, when assembling or repairing the videoscope device, it is necessary to solder the end of the cable and the board (relay board), and this work is troublesome. In addition, when using a very thin cable, the difficulty of soldering is high, and the actual situation is that the soldering takes a lot of time and effort.

The problem to be solved by the aspects of the present invention is to enable easy electrical connection between an electronic module such as an imaging module and other equipment without using a receptacle and a plug that is inserted and fitted into the receptacle. To provide a connector and a substrate with a connector.

In order to solve the above problems, the present invention provides the following aspects.
A first aspect is a connector that is mounted on a wiring board, and has a contact portion that contacts an electrode formed on a connection end substrate of an electronic module and a connection portion that is electrically connected to the wiring of the wiring substrate. a plurality of contacts, a housing for holding the contacts, pressing means for pressing the connection end substrate against the contact portions of the contacts, and the connection end substrate arranged on the housing with respect to the housing. Longitudinal positioning means for positioning the contacts in the arrangement pitch direction and width direction positioning means for positioning in the width direction perpendicular to the arrangement pitch direction are provided.
The pressing means is a shell rotatably attached to the housing, and the housing has a board support surface for supporting the connection end board so as to be able to contact the contact portion of the contact, and a board support surface. and an engaging portion for restricting rotation of the shell in the opening direction by engaging the shell arranged at the closed position covering the substrate support surface, the shell being arranged at the closed position covering the substrate support surface. An engaging portion that can be engaged with the engaging portion of the housing is provided, and the connecting end substrate is pressed against the substrate supporting surface by engaging the engaging portion with the engaging portion of the housing. It may be possible.
The housing has a contact arrangement region in which a plurality of the contacts are arranged, and a first base portion and a second base portion separated from each other through the contact arrangement region in the arrangement pitch direction. The direction positioning means is a positioning pin provided on the first base portion and inserted into a pin locking hole formed in the connecting end board, and the width direction positioning means is the first base plate of the housing. protruding portions formed on at least the second base portion of the base portion and the second base portion so as to be spaced apart from each other in the width direction at a spacing that allows the connection end substrate to be inserted; By arranging the connection end substrates between the protrusions and inserting the positioning pins into the pin locking holes of the connection end substrates, the connection end substrates are arranged in the arrangement pitch direction and the Positioning may be performed in the width direction.
The protruding portion formed on the second base portion passes through a substrate escape groove formed in the second base portion so as to extend from the end of the second base portion opposite to the contact arrangement region toward the contact arrangement region. It may be provided on both sides.
The electronic module includes an electronic element that is one of an image sensor, a laser element, and a sensor element, an electric cable that is electrically connected to the electronic element, and a tip of the electric cable that is electrically connected to the electronic element. and the connecting end board electrically connected to the rear end of the connector. A tube housing groove capable of housing a flexible tube housing the electronic element of the electronic module and the electric cable is formed across the side surface opposite to the contact arrangement region, and the tube housing groove is formed in the second contact arrangement region. It may be formed such that the depth from the upper surface increases toward the side surface of the base.
A board with a connector of a second aspect has the connector described above and a wiring board on which the connector is mounted, and the connection portion of the contact is electrically connected to the wiring of the wiring board.

According to the connector and the board with the connector according to the aspect of the present invention, the electrical connection between the electronic module and the contacts can be easily made simply by pressing the connection end board of the electronic module against the contact portion of the connector contact by the pressing means of the connector. can be realized. As a result, electrical connection between the electrical module and the wiring board can be easily achieved through the contacts of the connector. If there is a device electrically connected to the wiring board, the electrical connection between this device and the electronic module can also be realized.

Further, according to the connector and the board with the connector according to the aspect of the present invention, it is possible to ensure the degree of freedom in the shape and size of the connection end board of the electronic module.
For this reason, for example, the electronic module includes an electronic element that is any one of an image pickup element, a laser element, and a sensor element, an electric cable electrically connected to the electronic element, and a tip of the electric cable electrically connected to the electronic element. In the case of a configuration having a connecting end board electrically connected to the opposite rear end, the connecting end board can be sized to be inserted into a tube that houses the electronic elements and electrical cables. . For example, the connection end substrate may have a size that allows it to be inserted into a tube whose inner diameter is as small as possible within the range in which the electronic elements of the electronic module can be inserted.

1 is a perspective view showing a connector and a substrate with a connector according to a first embodiment of the present invention, showing a state in which a shell is opened with respect to a housing; FIG. FIG. 1 is a perspective view of the connector and the board with the connector shown in FIG. 1, in which the connecting end board (the rear board of the imaging module) is sandwiched between the shell closed to the housing and locked to maintain the closed position and the housing. It is a diagram. FIG. 2 is a cross-sectional view showing the vicinity of a contact housing groove of the connector and the board with the connector of FIG. 1; FIG. 3 is a cross-sectional view showing the vicinity of a contact accommodating groove of the connector of FIG. 2 and a board with the connector; 2 is a perspective view showing contacts of the connector of FIG. 1; FIG. 3 is a perspective view showing the vicinity of an imaging element of the imaging module; FIG. 4 is a cross-sectional view showing the vicinity of the front end portion of the rear substrate of the imaging module; FIG. FIG. 2 is a diagram showing an electronic endoscope system using the connector of FIG. 1 and the board with the connector; FIG. 9 is a cross-sectional view for explaining the configuration of an imaging module of the electronic endoscope system of FIG. 8; FIG. 10 is a view showing the first surface side of the rear substrate of the imaging module of FIG. 9; FIG. 11 is a diagram showing the connection state of the conductors of the coaxial cable of the electric cable of the image pickup module to the conductor connection terminals of the rear substrate of FIG. 10; FIG. 10 is a perspective view showing a connector and a board with a connector according to a second embodiment of the present invention, showing a state in which the shell is opened with respect to the housing; FIG. 12 is a perspective view of the connector and connector-equipped board in which the connecting end board (the rear board of the image pickup module) is sandwiched between the shell closed to the housing and locked to maintain the closed position and the housing. It is a diagram. FIG. 13 is a cross-sectional view showing the vicinity of the connector and the contact housing groove of the substrate with the connector of FIG. 12 ; 13 is an enlarged front cross-sectional view showing the vicinity of the positioning pin and the erroneous insertion prevention projecting wall of the connector of FIG. 12; FIG. FIG. 10 is a diagram showing a configuration using two positioning pins for the longitudinal positioning means;

A connector and a substrate with a connector according to embodiments of the present invention will be described below with reference to the drawings.

(First embodiment)
First, the connector and the board with the connector of the first embodiment will be described.
1 and 2 show a connector 20 and a board with connectors 30 of the embodiment described here.
The substrate with connectors 30 shown in FIGS. 1 and 2 has a connector 20 mounted on one side of a base substrate 31 (wiring substrate).

As shown in FIG. 1, the connector 20 has a plurality of contacts 21, a housing 22 for holding the contacts 21, and a shell 23 (pressing means) rotatably supported by the housing 22. As shown in FIG.
The connector 20 also includes positioning means (longitudinal direction) for positioning the rear substrate 14 (connection end substrate) of the imaging module 10 (see FIGS. 8 and 9; electronic module) electrically connected to the contacts 21 with respect to the housing 22 . It also has directional positioning means 24 and widthwise positioning means 25).
The connector 20 has a connector base member 20A in which a housing 22 is provided with longitudinal positioning means 24 and widthwise positioning means 25 .

As shown in FIG. 8 , the imaging module 10 can be used as part of an electronic endoscope system 50 .
As shown in FIG. 9, the imaging module 10 includes an imaging element 11 (electronic element), a wiring board 12 (hereinafter also referred to as a head-side substrate) on which the imaging element 11 is mounted, and wiring (illustrated) of the head-side substrate 12. ), and a rear substrate 14 electrically connected to the rear end of the electric cable 13 opposite to the front end connected to the wiring of the head side substrate 12 . have.

9 shows a module 16 with a tube in which the imaging element 11, the head-side substrate 12, and the electric cable 13 of the imaging module 10 are housed in a highly flexible resin tube 15. As shown in FIG.
However, the rear substrate 14 of the imaging module 10 is not accommodated in the tube 15 and is exposed to protrude outward from the end (rear end) of the tube 15 .

FIG. 8 shows an example of an electronic endoscope system 50 to which the board 30 with connectors is applied.
The electronic endoscope system 50 shown in FIG. 8 includes a video processing display device 51 and a board 30 with a connector having a base board 31 (relay board) electrically connected to the video processing display device 51 via a connection cable 52. , and a module 16 with tubes.
The module with tube 16 constitutes part or all of the videoscope device of the electronic endoscope system 50 .

As shown in FIG. 4, the contacts 21 of the substrate with connector 30 are soldered to the contact portions 21a that come into contact with the electrodes 14c formed on the rear substrate 14 of the imaging module 10 and the wiring 31b of the base substrate 31. It has a connecting portion 21b that is electrically connected.
The electrical connection of the connection portion 21b of the contact 21 to the wiring 31b of the base substrate 31 is not limited to soldering. It may be realized by mechanical fixation or the like by pressing the connection portion 21b onto the wiring 31b with a clip.

The connector 20 electrically connects the circuit of the imaging module 10 including the electrode 14c of the rear substrate 14 and the wiring 31b of the base substrate 31 via the contact 21. As shown in FIG.
The substrate with connector 30 serves to electrically connect the circuits of the imaging module 10 including the electrodes 14 c of the rear substrate 14 and the external circuit electrically connected to the wiring 31 b of the base substrate 31 .

In the electronic endoscope system 50 shown in FIG. 8, the external circuit electrically connected to the wiring 31b of the base substrate 31 of the substrate with connector 30 is an electrical circuit on the side of the video processing display device 51 including the connection cable 52 (hereinafter referred to as the display device). It is also called a side circuit). In the electronic endoscope system 50 shown in FIG. 8, the substrate with connector 30 serves to electrically connect the circuits of the imaging module 10 including the electrodes 14c of the rear substrate 14 and the circuits of the display device.

The connector 20 will now be described in more detail.
1 to 4, the connector 20 will be described with the upper side as the upper side and the lower side as the lower side.

A housing 22 of the connector 20 shown in FIG. 1 is a plate-like member made of resin. Housing 22 is electrically insulating.
Moreover, the housing 22 shown in FIG. 1 is formed in the shape of an elongated plate.

As shown in FIG. 1, the housing 22 includes a contact arrangement region 22C in which a plurality of contact accommodation grooves 26 for accommodating the contacts 21 are formed, and pedestals (a first pedestal 22A, a 2 base portion 22B).
22 C of contact arrangement|positioning area|regions are located in the longitudinal direction center part of the housing 22. As shown in FIG.
The first base portion 22A and the second base portion 22B are portions on both sides of the contact arrangement region 22C in the longitudinal direction of the housing 22 .

As shown in FIGS. 3 and 4, the housing 22 has a flat bottom surface 22a that abuts the main surface of the base substrate 31 so as to be superimposed thereon, and an upper surface formed parallel to the bottom surface 22a on the opposite side of the bottom surface 22a. and a substrate support surface 22b.
The rear substrate 14 of the imaging module 10 is placed on the substrate support surface 22b.

Regarding the housing 22, the direction of spacing between the bottom surface 22a and the board support surface 22b (vertical direction in FIGS. 1, 3, and 4) is hereinafter also referred to as the height direction.
As shown in FIGS. 3 and 4, the housing 22 has a front surface 22c, which is one side surface in the direction perpendicular to the height direction, and a rear surface, which is a side surface opposite to the front surface 22c, in a cross section perpendicular to the longitudinal direction. 22d.
As shown in FIG. 1, the end surface 22e on the side of the first base portion 22A among the end surfaces on both sides in the longitudinal direction of the housing 22 will be hereinafter referred to as the first end surface, and the end surface 22f on the side of the second base portion 22B will be referred to as the second end surface. To tell.

As shown in FIGS. 1, 3, and 4, the contact receiving grooves 26 of the contact arrangement area 22C of the housing 22 are recessed from the substrate support surface 22b toward the bottom surface 22a. Further, the contact receiving groove 26 is formed by opening only the front surface 22c of the front surface 22c and the rear surface 22d of the housing 22. As shown in FIG.

The housing 22 has a groove bottom wall 22g positioned below the contact receiving groove 26 and forming part of the bottom surface 22a. The contact receiving groove 26 is formed in a range from the board supporting surface 22b of the housing 22 to the groove bottom wall 22g in the height direction of the housing 22. As shown in FIG.
The housing 22 also has a groove rear wall 22h that closes the contact housing groove 26 on the housing rear surface 22d side.

A plurality of contact receiving grooves 26 of the housing 22 are formed extending perpendicularly to the longitudinal direction of the housing 22 . Further, the contact receiving grooves 26 are formed parallel to each other at a plurality of locations in the housing 22 longitudinal direction in the contact arrangement region 22C of the housing 22 .
The spacing direction (arrangement pitch direction) of the contact housing grooves 26 of the plurality of contact housing grooves 26 of the housing 22 coincides with the longitudinal direction of the housing 22 .
The contacts 21 accommodated one by one in each contact accommodation groove 26 are arranged in the longitudinal direction of the housing 22 . A plurality of contacts 21 provided on the housing 22 are arranged in an arrangement pitch direction that matches the longitudinal direction of the housing 22 .

As shown in FIGS. 3, 4, and 5, the contact 21 is an integrally molded product formed from one metal strip.
The material of the metal band plate forming the contact 21 is, for example, a conductor metal such as copper or aluminum.

A bent portion 21c (hereinafter, also referred to as a central bent portion) is formed by bending the metal band plate in its plate thickness direction at the central portion in the longitudinal direction of the metal band plate.
In the longitudinal direction of the metal band plate, the contact 21 is movable with respect to the main plate portion 21d on one side through the central bent portion 21c, and the movable contact 21 extends obliquely from the central bent portion 21c to the main plate portion 21d while securing an acute opening angle with respect to the main plate portion 21d. and a plate portion 21e.

As shown in FIGS. 3, 4 and 5, the main plate portion 21d of the contact 21 extends straight from the central bent portion 21c.
As shown in FIGS. 3 and 4, the contact 21 has a main plate portion 21d (specifically, one side of the main plate portion 21d) disposed on the groove bottom wall 22g of the housing 22 and near the groove rear wall 22h of the housing 22. A movable plate portion 21e extending from the arranged central bent portion 21c is accommodated in the contact accommodating groove 26 while being positioned on the main plate portion 21d.

As shown in FIG. 5, the tip portion of the main plate portion 21d of the contact 21 on the side opposite to the central bent portion 21c in the direction of extension thereof is provided with tension on both sides in the plate width direction perpendicular to the direction of extension from the main plate portion 21d. A protruding portion 21f is formed. The main plate portion 21d of the contact 21 is also formed with fixing projections 21g that protrude away from each other in the width direction of the main plate portion 21d from projecting portions 21f on both sides in the width direction of the main plate portion 21d.
The fixing protrusion 21g is formed in a mountain shape in which the projecting dimension in the width direction of the main plate portion 21d from the projecting portion 21f increases from both ends toward the center portion of the contact 21 in the extending direction of the main plate portion 21d.

The contact accommodating groove 26 of the housing 22 shown in FIGS. 1, 3, and 4 includes a main groove portion 26a recessed from the board support surface 22b of the housing 22 to the groove bottom wall 22g, and two groove width direction sides of the groove bottom portion of the main groove portion 26a. and a guide groove 26b formed on the inner surface of the .
The guide groove 26b is formed so that the projecting portion 21f of the main plate portion 21d of the contact 21 and the fixing projection 21g can be inserted from the front surface 22c side of the housing 22. As shown in FIG. The guide grooves 26b extend from the front surface 22c of the housing 22 toward the rear wall 22h of the groove on both sides of the main groove portion 26a of the contact receiving groove 26 in the groove width direction (matching the longitudinal direction of the housing 22). . The protrusion 21f and the fixing projection 21g of the main plate portion 21d of the contact 21 are inserted into the guide groove 26b, so that the guide groove 26b prevents the main plate portion 21d from rising from the groove bottom wall 22g of the housing 22 by the inner surface of the guide groove 26b.

The contacts 21 are accommodated in the contact accommodating grooves 26 from the front surface 22c side of the housing 22 by sliding the main plate portion 21d to the upper surface of the groove bottom wall 22g and inserting the central bent portions 21c into the contact accommodating grooves 26 toward the leading end.
When the contact 21 is pushed from the front surface 22c side of the housing 22 and accommodated in the contact accommodation groove 26, the projecting portion 21f and the fixing projection 21g are inserted into the guide groove 26b. The distance between the tips of the fixing protrusions 21g projecting on both sides in the plate width direction of the main plate portion 21d of the contact 21 is greater than the distance between the inner surfaces of the guide grooves 26b on both sides of the contact housing groove 26 on the side opposite to the main groove portion 26a. slightly larger. The main plate portion 21d of the contact 21 inserted into the contact housing groove 26 is pressed against the inner surface of the guide groove 26b of the contact housing groove 26 on the side opposite to the main groove portion 26a. is fixed to the housing 22 with . Also, as a result, the contacts 21 are held at predetermined positions in the housing 22 .

The structure (contact holding structure) for holding the main plate portion 21d of the contact 21 at a predetermined position of the housing 22 is not limited to pressing the fixing projection 21g of the contact 21 against the inner surface of the guide groove 26b.
The contact holding structure is, for example, an engagement between an elastic locking piece (housing lance) projecting from the inner surface of the contact receiving groove 26 of the housing 22 and an engaging protrusion or engaging recess formed in the main plate portion 21d of the contact 21. A configuration in which the main plate portion 21d is held at a predetermined position of the housing 22 can also be adopted depending on the combination.

The contact 21 extends from the end opposite to the central bent portion 21c in the extending direction (longitudinal direction) of the main plate portion 21d toward the opposite side (lower side) to the movable plate portion 21e at an angle of 45 degrees or less with respect to the main plate portion 21d. and a connecting portion 21b extending from the end of the extending piece 21h opposite to the main plate portion 21d.
The extension piece portion 21h and the connection portion 21b are part of the metal band plate that forms the contact 21. As shown in FIG.
The connecting portion 21b extends parallel to the main plate portion 21d from the end of the extending piece portion 21h opposite to the main plate portion 21d.

As shown in FIGS. 1 to 4, the connecting portion 21b of the contact 21 is soldered to the wiring 31b formed on the main surface 31a of the connector 20 of the base substrate 31 on which the housing 22 of the connector 20 is arranged. It is connected.
The contact 21 is entirely electrically connected to the wiring 31b on the main surface 31a of the base substrate 31. As shown in FIG.

As shown in FIGS. 3 and 4, the connector base member 20A of the connector 20 has fitting projections 22j projecting from the bottom surface 22a of the housing 22. As shown in FIGS. The connector base member 20A is formed by inserting and fitting the fitting projections 22j of the housing 22 into the fitting holes 31c formed in the base substrate 31, and bringing the bottom surface 22a of the housing 22 into contact with the main surface 31a of the base substrate 31 to form the base. It is attached to the substrate 31 .
The connector base member 20A also secures a fixing force to the base substrate 31 by soldering the connecting portions 21b of the contacts 21 inserted into the respective contact accommodating grooves 26 to the wiring 31b of the base substrate 31. there is

The contact portion 21a of the contact 21 is formed at the end portion (tip portion) of the movable plate portion 21e opposite to the central bent portion 21c.
The tip portion of the movable plate portion 21e of the contact 21 shown in FIGS. 3, 4, and 5 has a bent tip portion 21i that is bent in the plate thickness direction to form an upwardly convex chevron shape.
Specifically, the contact portion 21a of the contact 21 shown in FIGS. 3, 4, and 5 is formed to extend along the extending direction of the movable plate portion 21e on the outer angle side of the tip bent portion 21i of the movable plate portion 21e. It is a rib-like projection.

It should be noted that the contact portion 21a of the contact 21 is not limited to the rib-shaped protrusion formed at the tip of the movable plate portion 21e, and can be changed as appropriate. The contact 21 may omit the contact portion 21a, which is a rib-like projection, and use, for example, the tip bending portion 21i itself of the tip portion of the movable plate portion 21e as the contact portion.

As shown in FIGS. 1 and 2, the shell 23 includes a top plate 23a, a pair of axially supporting projecting pieces 23b projecting from one end of the top plate 23a toward one side of the top plate 23a, and the top plate 23a. It has an engaging plate piece 23c protruding from the end portion toward one side of the top plate 23a.
The pair of shaft support protrusions 23b of the shell 23 are arranged in the longitudinal direction of the housing 22 via a rotating shaft 27 provided at the rear portion of the housing 22 (portion on the side of the rear surface 22d in FIGS. 3 and 4). It is rotatably supported around a parallel axis (rotational axis).
The shell 23 as a whole rotates with respect to the housing 22 around the rotational axis of the pivotal support protrusion 23b with respect to the housing 22. As shown in FIG.

A top plate 23a of the shell 23 shown in FIGS. 1 and 2 is formed in a rectangular plate shape.
One end of the top plate 23a is a portion along one side of the outer circumference of the top plate 23a. The pair of shaft support protrusions 23b extends from one end of the top plate 23a toward one side of the top plate 23a.
The shell 23 is rotatably supported by the housing 22 so that one end of the top plate 23 a extends along the longitudinal direction of the housing 22 .

As the shell 23 rotates with respect to the housing 22, the top plate 23a of the shell 23 opens and closes with respect to the portion of the board support surface 22b of the housing 22 located in the contact arrangement area 22C (the arrangement area upper support surface 22i).
A surface 23d of the top plate 23a of the shell 23, which faces the contact arrangement area 22C when closed with respect to the contact arrangement area 22C, is hereinafter also referred to as a pressing surface.
The shaft support projecting piece 23b and the engaging plate piece 23c protrude from the top plate 23a toward the pressing surface 23d of the top plate 23a.

The engaging plate piece 23c of the shell 23 shown in FIGS. 1 and 2 is a plate piece extending perpendicularly to the top plate 23a along the other end of the top plate 23a. The extending direction of the engaging plate piece 23c is parallel to the extending direction of one end of the top plate 23a. Further, the engagement plate piece 23c extends along the longitudinal direction of the housing 22. As shown in FIG.

The engagement plate piece 23c of the shell 23 shown in FIGS. 1 and 2 is connected to both ends in the extension direction of the other end of the top plate 23a only at the ends in the extension direction. One end of the top plate 23a of the shell 23 shown in FIGS. An elongated engaging window hole 23f extending parallel to the extending direction of the portion is formed.

As shown in FIGS. 2 and 4, on the housing front surface 22c side of the groove partition wall 22k positioned between the contact receiving grooves 26 of the housing 22, an engagement plate of the shell 23 closed with respect to the contact arrangement area 22C of the housing 22 is provided. A locking groove 22m into which the piece 23c is inserted is formed. In the connector 20 shown in FIG. 1, the locking grooves 22m on the housing front surface 22c side of the plurality of groove partition walls 22k of the housing 22 are continuous with each other in the longitudinal direction of the housing 22 via the contact accommodating grooves 26 between the groove partition walls 22k. is formed to

The engagement plate piece 23c of the shell 23 (the engagement portion that engages with the housing 22) accommodates the engagement projection 22n above the engagement groove 22m of the groove partition wall 22k of the housing 22 in the engagement window hole 23f. can be inserted into the locking groove 22m. The locking protrusion 22n of the housing 22 accommodated in the engagement window hole 23f of the shell 23 restricts upward displacement of the engagement plate piece 23c with respect to the housing 22 by engaging with the engagement plate piece 23c of the shell 23. , prevent rotation of the shell 23 in the opening direction. The shell 23 accommodates the locking protrusion 22n (locking portion that locks the shell 23) of the groove partition wall 22k of the housing 22 in the engagement window hole 23f, and the engagement plate piece 23c is inserted into the locking groove 22m. By doing so, it is possible to maintain a closed state with respect to the contact arrangement region 22C.
The engagement plate piece 23 c of the shell 23 serves as an engagement portion that engages with the housing 22 .

In a state (closed state) in which the shell 23 is closed with respect to the contact arrangement region 22C, the top plate 23a of the shell 23 is closed with respect to the contact arrangement region 22C, and the pressing surface 23d of the top plate 23a contacts the arrangement region upper support surface 22i. refers to the state of extending along As shown in FIG. 2, the top plate 23a of the shell 23 in the closed state covers substantially the entire support surface 22i on the arrangement area.
When the shell 23 is opened with respect to the contact arrangement area 22C (open state), the holding surface 23d of the top plate 23a has an opening angle of 45 degrees or more with respect to the arrangement area upper support surface 22i. is separated upward from the housing 22, and the operation of positioning the rear substrate 14 of the imaging module 10 by the longitudinal positioning means 24 and the width direction positioning means 25 on the housing 22 can be performed from the housing front surface 22c side. point to
In the shell 23 of the connector 20 shown in FIGS. 1 to 4, the pressing surface 23d of the top plate 23a can secure an opening angle of 90 degrees or more with respect to the support surface 22i on the arrangement area.

The rear substrate 14 of the imaging module 10 can be arranged (placed, etc.) on the substrate support surface 22b of the housing 22 with the shell 23 of the connector 20 opened with respect to the contact arrangement area 22C.
By closing the shell 23 in the open state with respect to the contact arrangement area 22C, the connector 20 is configured such that the rear substrate 14 of the imaging module 10 arranged on the substrate support surface 22b of the housing 22 is connected to the top plate 23a of the shell 23 and the housing 22. can be sandwiched between The shell 23 inserts the engaging plate piece 23c into the locking groove 22m of the groove partition wall 22k of the housing 22, and engages the engaging plate piece 23c with the locking projection 22n of the groove partition wall 22k, whereby the image pickup module is mounted. The state in which the rear substrate 14 of 10 is sandwiched between the top plate 23a and the housing 22 can be maintained.

Regarding the shell 23, the state in which the engaging plate piece 23c is inserted into the locking groove 22m of the groove partition wall 22k of the housing 22 and is locked to the locking protrusion 22n of the housing 22 is hereinafter referred to as the closed state and locked state. Also say.
The top plate 23a of the shell 23 in the closed maintenance locking state presses the rear substrate 14 of the imaging module 10 against the arrangement area upper support surface 22i by the pressing surface 23d.

The locking groove 22m of the housing 22 shown in FIG. 1 is formed only in the groove partition wall 22k of the housing 22, and is not formed in the first base portion 22A and the second base portion 22B of the housing 22. As shown in FIG.
When the shell 23 is closed with respect to the contact arrangement area 22C, both ends in the extension direction of the engaging plate piece 23c of the shell 23 are positioned in the contact arrangement area 22C of the housing 22 in the contact receiving grooves 26 located at both ends in the longitudinal direction of the housing 22. It is arranged on the front side 22c of the housing.
However, the engaging plate piece 23c of the shell 23 abuts only the groove partition wall 22k of the housing 22 when the shell 23 is closed with respect to the contact arrangement region 22C, and the first base portion 22A and the second base portion of the housing 22 are in contact with each other. 22B is formed in such a size that it does not come into contact with it.
The engagement plate piece 23c of the shell 23 can be smoothly inserted into the locking groove 22m of the groove partition wall 22k of the housing 22 without interfering with the first base portion 22A and the second base portion 22B.

The housing 22 may adopt a configuration in which the locking groove 22m is formed not only on the groove partition wall 22k but also on one or both of the first base portion 22A and the second base portion 22B on the housing front surface 22c side. be.
In the case of a configuration in which the locking groove 22m is formed not only on the groove partition wall 22k but also on the housing front surface 22c side of one or both of the first base portion 22A and the second base portion 22B, the engaging plate piece 23c of the shell 23 is formed. can adopt a configuration in which the ends in the extending direction along the longitudinal direction of the housing 22 can be inserted into the locking grooves 22m of one or both of the first base portion 22A and the second base portion 22B.

The shell 23 includes an operation piece 23g that protrudes from the end of the engaging plate piece 23c opposite to the top plate 23a in the plate thickness direction of the engaging plate piece 23c to the side opposite to the top plate 23a.
Even when the engaging plate piece 23c of the shell 23 is inserted into the locking groove 22m of the groove partition wall 22k of the housing 22, the operating piece 23g can secure a portion projecting from the locking groove 22m toward the housing front surface 22c. .
By rotating the shell 23 with respect to the housing 22 using the operation piece 23g with fingers or the like, the shell 23 can be easily changed from the open state to the closed state with respect to the housing 22 and the closed maintenance locked state. can do

The shell 23 in the closed-maintaining locked state is lifted by a tool inserted between the engaging plate piece 23c and the base substrate 31, so that the locking protrusion of the housing 22 of the engaging piece portion 23c is lifted. 22n can be disengaged.
The shell 23 in which the engaging piece 23c is disengaged from the locking projection 22n of the housing 22 can be opened by rotating the housing 22. As shown in FIG.

As shown in FIG. 1, the longitudinal positioning means 24 and the widthwise positioning means 25 of the connector base member 20A are provided above the substrate support surface 22b of the housing 22 in a projecting state.

The longitudinal positioning means 24 for the connector base member 20A shown in FIG. Specifically, the longitudinal positioning means 24 in FIG. 1 is a positioning pin that is fixed to the first base portion 22A and protrudes from the upper surface of the first base portion 22A.
Hereinafter, when the longitudinal positioning means 24 refer to positioning pins, the longitudinal positioning means 24 are also referred to as positioning pins. Also, reference numeral 24 is added to the positioning pin.

Specifically, the width direction positioning means 25 of the connector base member 20A shown in FIG. part).
Hereinafter, when the width direction positioning means 25 refers to a rib-like protruding wall, the width direction positioning means 25 is also referred to as a rib-like protruding wall. Moreover, the code|symbol 25 is added to a rib-shaped projecting wall.

As shown in FIG. 1, a pair of rib-like projecting walls 25 extending in the longitudinal direction of the housing 22 are formed on the upper surfaces of the first base portion 22A and the second base portion 22B.
The rear substrate 14 of the imaging module 10 provided on the substrate support surface 22b of the housing 22 is inserted into the substrate accommodation groove 25a secured between the pair of rib-shaped projecting walls 25. As shown in FIG. The substrate accommodation groove 25a between the pair of rib-shaped protruding walls 25 on the first platform 22A is located on the extension of the substrate accommodation groove 25a between the pair of rib-shaped protruding walls 25 on the second platform 22B.
The rib-shaped protruding walls 25 on both sides of the board accommodating groove 25a are separated from each other in the width direction of the board supporting surface 22b of the housing 22 perpendicular to the longitudinal direction of the housing 22. As shown in FIG.

In FIG. 1, the groove width of the substrate accommodation groove 25a, that is, the separation distance between the rib-shaped protruding walls 25 on both sides of the substrate accommodation groove 25a is the width direction (longitudinal direction) of the elongated plate-shaped rear substrate 14 of the imaging module 10. (Longitudinal) dimension of vertical cross-section.
The rear substrate 14 of the imaging module 10 is inserted into the substrate accommodation grooves 25a between the rib-shaped protruding walls 25 of the first base portion 22A and the second base portion 22B, so that the ribs on both sides of each substrate accommodation groove 25a are arranged. The projection wall 25 supports the housing 22 in a longitudinal direction and positions it in the width direction of the board support surface 22 b of the housing 22 .

As shown in FIG. 1, the positioning pin 24 of the connector base member 20A is provided with a jig hooking hole 14e, which is a through hole formed at one longitudinal end (rear end) of the rear substrate 14 of the imaging module 10. As shown in FIG. By being inserted into the (first jig hooking hole), the rear substrate 14 inserted into the substrate accommodation groove 25a between the rib-shaped protruding walls 25 of the first base portion 22A and the second base portion 22B is inserted into the housing. 22 (longitudinal direction of substrate supporting surface 22b).

The first jig hooking hole 14e of the rear substrate 14 is used to attach the imaging module 10 to the rear substrate 14 through an insertion jig such as a wire when inserting the imaging module 10 into the tube 15 to assemble the module 16 with the tube. be done.
When assembling the tube-equipped module 16 , the imaging module 10 is inserted through the tube 15 from the rear substrate 14 .

As shown in FIGS. 1 and 10, two jigs are provided at the rear substrate 14 opposite to the front end of the image sensor 11 in the longitudinal direction of the imaging module 10 (the right end in FIG. 10). Hooking holes 14e and 14f (first jig hooking hole, second jig hooking hole) are formed at intervals in the longitudinal direction of the rear substrate 14. As shown in FIG. Each of the jig hooking holes 14e and 14f is a through hole that penetrates through the plate thickness of the rear substrate 14 and opens to both main surfaces (first main surface 14a and second main surface 14b) of the rear substrate 14. .
In this embodiment, for positioning the rear substrate 14 with respect to the housing 22 in the longitudinal direction of the housing 22, the first jig hooking holes 14e (pin locking holes) located on the rear side of the second jig hooking holes 14f are used. Use only

As shown in FIG. 10, on one main surface (first main surface 14a) of the rear substrate 14 of the imaging module 10, a plurality of electrodes 14c are formed in contact with the contact portions 21a of the contacts 21 of the connector base member 20A. It is The electrodes 14c are formed at a plurality of locations in the longitudinal direction of the rear substrate 14 on the first main surface 14a.
The rear substrate 14 shown in FIG. 10 is formed with the same number of electrodes 14c as the contacts 21 of the connector base member 20A (five electrodes 14c are formed in FIG. 10).

The electric cable 13 of the image pickup module 10 shown in FIGS. 9 and 10 has a configuration in which a plurality of conductors are housed inside an exterior covering 13a. However, the electric cable 13 may be, for example, one in which a plurality of wires are housed in a protective tube, a coaxial cable (having a plurality of conductors), a single-core wire (having only one conductor), or the like.
The electric cable 13 of the imaging module 10 shown in FIGS. 9 and 10 is a signal cable that uses one or more of a plurality of conductors as signal lines.

As shown in FIG. 10, conductors of the electric cable 13 are electrically connected to conductor connection terminals 14d formed on the first main surface 14a of the rear substrate 14 of the imaging module 10 by soldering or the like. The conductor connection terminals 14d are formed at a plurality of locations (five locations in FIG. 10) at one longitudinal end (front end) of the rear substrate 14 of the imaging module 10. As shown in FIG.
Conductors of the electric cable 13 are electrically connected to conductor connection terminals 14d formed on the first main surface 14a of the rear substrate 14 of the imaging module 10, one by one.

The electric cable 13 shown in FIG. 10 has two coaxial cables 13b and one sub-conductor (not shown) which is a conductor accommodated inside the outer covering 13a together with the coaxial cables 13b.
As shown in FIG. 11, coaxial cable 13b has central conductor 13c and outer conductor 13d.
The electric cable 13 shown in FIG. 10 has a total of five conductors, a center conductor 13c and an outer conductor 13d of two coaxial cables 13b, and one sub-conductor.

As shown in FIGS. 10 and 11, the five conductor connection terminals 14d formed on the first main surface 14a of the rear substrate 14 of the imaging module 10 are two terminals to which the central conductor 13c of the coaxial cable 13b is electrically connected. A center conductor connection terminal 14d1, two outer conductor connection terminals 14d2 to which the outer conductor 13d of the coaxial cable 13b is electrically connected, and one sub conductor connection terminal 14d3 to which the sub conductor is electrically connected.

On the rear substrate 14, the conductor connection terminals 14d are formed in the same number as the electrodes 14c. Electrodes 14c of the rear substrate 14 are electrically connected to the plurality of conductor connection terminals 14d one by one via wiring (not shown) formed on the rear substrate 14, respectively.
The conductors of the electric cable 13 electrically connected to the conductor connection terminals 14 d are electrically connected to the electrodes 14 c of the rear substrate 14 via the conductor connection terminals 14 d and wiring of the rear substrate 14 .

A plurality of electrodes 14c of the rear substrate 14 shown in FIG. 10 are arranged in a line in the longitudinal direction of the rear substrate 14 and formed. The arrangement intervals of the plurality of electrodes 14c of the rear substrate 14 in the longitudinal direction of the rear substrate 14 are the arrangement intervals of the plurality of contacts 21 (specifically, their contact portions 21a) of the connector base member 20A in the longitudinal direction of the housing 22 ( array pitch).

In FIG. 1, the arrangement pitch of the contact accommodating grooves 26 in the contact arrangement region 22C of the connector base member 20A in the longitudinal direction of the housing 22 and the arrangement pitch of the contacts 21 in the longitudinal direction of the housing 22 are constant. However, the arrangement pitch of the contact receiving grooves 26 and the arrangement pitch of the contacts 21 may not be constant.

As shown in FIGS. 3 and 4, the rear substrate 14 of the imaging module 10 is arranged on the substrate support surface 22b of the housing 22 such that the first main surface 14a faces the substrate support surface 22b (upper surface). .
Each electrode 14c of the rear substrate 14 of the imaging module 10 is positioned with respect to the housing 22 by the positioning pins 24 and rib-shaped projecting walls 25 on the housing 22, so that the electrodes 14c of the connector base member 20A are connected to the contacts 21 of the connector base member 20A. is aligned with the contact portion 21a.

In the connector 20, the rear board 14 is positioned with respect to the housing 22 by the positioning pins 24 and the rib-shaped protruding walls 25, and is pressed against the board support surface 22b of the housing 22 by the top plate 23a of the shell 23, which is in the closed maintenance locked state. Only by (pressing) the contact between the plurality of electrodes 14c of the rear substrate 14 and the contact portions 21a of the contacts 21 can be stably maintained.
As a result, in the electronic endoscope system 50 shown in FIG. It is possible to easily and stably secure the state of electrical connection.

As shown in FIG. 3, when there is no placed object such as the rear substrate 14 of the imaging module 10 on the substrate support surface 22b of the housing 22, the upper end of the contact portion 21a of the contact 21 is slightly above the substrate support surface 22b. Located in
Further, the upper end of the contact portion 21a of the contact 21 is located on the extension of the board accommodating groove 25a between the pair of rib-like projecting walls 25 (width direction positioning means) on the housing 22. As shown in FIG.

As shown in FIG. 4, when the rear substrate 14 of the imaging module 10 is positioned with respect to the housing 22 by the positioning pins 24 and the rib-shaped protruding walls 25 and the shell 23 is kept closed and locked, the contact portions of the contacts 21 are closed. 21a is pushed into the contact receiving groove 26 by the rear substrate 14. As shown in FIG. At this time, the contact portion 21a of the contact 21 is pushed into the contact receiving groove 26 of the housing 22 by the elastic deformation of the contact 21, and the contact with the electrode 14c of the rear substrate 14 is stably maintained by the elastic restoring force of the contact 21.
Therefore, the connector 20 can stably maintain a state in which the display device side circuit and the electric circuit of the imaging module 10 are electrically connected via the wiring 31 b of the base substrate 31 and the contact 21 .

As shown in FIG. 1, at the end of the second base portion 22B of the housing 22 on the side opposite to the contact arrangement region 22C, a module with a tube extends from the upper surface of the second base portion 22B to the second end face 22f of the housing 22. A tube accommodating groove 22o capable of accommodating 16 tubes 16 is formed.
A second end surface 22f of the housing 22 is a side surface opposite to the contact arrangement area 22C of the second base portion 22B.
The tube accommodation groove 22o is formed such that the depth from the upper surface of the second base portion 22B increases toward the second end surface 22f side of the housing 22. As shown in FIG.

As shown in FIG. 1, the tube accommodation groove 22o is formed recessed from the upper surface of the second base portion 22B in a region corresponding to the extension of the substrate accommodation groove 25a on the upper surface of the second base portion 22B.
The front end (front end side end) of the rear substrate 14 positioned in the housing 22 by the positioning pin 24 and the rib-shaped protruding wall 25 is arranged on the tube accommodating groove 22o. Sub-conductor connecting terminals 14d3 (see FIG. 10) of the rear substrate 14 are arranged on the tube accommodating grooves 22o.

A portion of the tube-equipped module 16 in the longitudinal direction where the tube 15 is present is hereinafter also referred to as a tube exterior portion.
In the tube housing groove 22o, a rear end opposite to the front end housing the imaging device 11 of the tube exterior and a rear end of the tube exterior of the electric cable 13 extending from the rear end of the tube 15 are provided. be accommodated.

Since the rear substrate 14 of the module with tube 16 is placed on the substrate support surface 22b of the housing 22 with the first main surface 14a facing downward, the outer tube portion of the module with tube 16 is positioned below it. A portion of the housing 22 where the substrate support surface 22b does not exist hangs downward from the rear substrate 14. As shown in FIG.
If the second end surface 22f of the housing 22 were perpendicular to the board support surface 22b of the housing 22, the portion of the module with tube 16 supported by the housing 22 and the module with tube 16 below the housing 22 would be present. The vicinity of the boundary with the portion not supported by the housing 22 is locally bent, and the tube 15 is likely to be damaged.
If the tube-equipped module 16 is accommodated in the tube-accommodating groove 22o, it is possible to prevent the tube-equipped module 16 from forming a bent portion that may damage the tube 15 . As a result, if the tube-equipped module 16 is housed in the tube housing groove 22o, the life of the tube 15 is extended compared to the case where the second end surface 22f of the housing 22 is perpendicular to the board support surface 22b of the housing 22. is possible.

As shown in FIG. 6, the image pickup device 11 of the image pickup module 10 is a solid-state image pickup device formed in a square shape (block shape) extending with a rectangular cross section.
As shown in FIG. 7, the rear substrate 14 of the imaging module 10 is formed in the shape of an elongated plate extending with a rectangular cross section.

Here, the length of the diagonal line (first diagonal line T1) on the light receiving surface 11a at the front end of the image pickup device 11 shown in FIG. D2.
The length D2 of the diagonal line (second diagonal line T2) in the cross section of the rear substrate 14 in FIG. 7 is set to be equal to or less than the length D1 of the diagonal line (first diagonal line T1) on the light receiving surface 11a at the front end of the imaging element 11 shown in FIG. (Condition D1≧D2).

Over the entire longitudinal length of the rear substrate 14, the length D2 of the diagonal line (second diagonal line T2) in its cross section is the length of the diagonal line (first diagonal line T1) on the light receiving surface 11a at the front end of the image sensor 11 shown in FIG. It is formed to extend with a cross-sectional dimension equal to or smaller than D1.
Also, as shown in FIG. 7, the portion of the electric cable 13 arranged along the rear side substrate 14 of the two coaxial cables 13b is the circumscribed circle of the second substrate main body 21 whose diameter is the second diagonal line T2. Can be placed inside C.

The head-side substrate 12 and the electric cable 13 of the image pickup module 10 are also formed so that the entire cross section perpendicular to the longitudinal direction of the image pickup module 10 is within the circumference of a diameter equal to or less than the length D1 of the first diagonal T1. ing.
The imaging module 10 is formed over its entire length in the longitudinal direction such that the entire cross section perpendicular to the longitudinal direction of the imaging module 10 is within a circumference of a diameter equal to or less than the length D1 of the first diagonal T1.
Therefore, the tube 15 used to assemble the tube-equipped module 16 may have an inner diameter that can accommodate the imaging element 11, and use of a tube with an unnecessarily large inner diameter can be avoided.

As shown in FIG. 8, according to the electronic endoscope system 50 employing the substrate 30 with connectors, after the module 16 with tubes is assembled, the rear substrate 14 of the imaging module 10 is simply pressed into the housing 22 by the shell 23. , the electrical connection between the display device side circuit and the electrical circuit of the imaging module 10 can be easily realized.

(Second embodiment)
12 to 15 show a connector 220 and a substrate with connectors 230 of a second embodiment according to the invention.
12 to 15, the connector 220 and the substrate with connector 230 will be described with the upper side as the upper side and the lower side as the lower side.

As shown in FIG. 12 and the like, a substrate with connectors 230 of the second embodiment is obtained by changing the connectors 20 of the substrate with connectors 30 of the first embodiment to connectors 220 of the second embodiment. The configuration of the substrate with connectors 230 of the second embodiment other than the connector 220 is the same as that of the substrate with connectors 30 of the first embodiment.

As shown in FIG. 12, the connector 220 of the second embodiment has a connector base member 220A in which a longitudinal positioning means 24 and a width positioning means 25 are provided in a square bar-shaped housing 222 . The connector 220 of this embodiment also has a plurality of contacts 221 held in a contact arrangement area 22C in the longitudinal center of the housing 222, and a shell 223 (pressing means) rotatably supported on the housing 222. .

As shown in FIGS. 3 and 4, in the housing 22 of the connector 20 of the first embodiment, the dimension in the front-rear direction, which is the direction of the distance between the front surface 22c and the rear surface 22d, is equal to the distance between the bottom surface 22a and the board support surface 22b. It is formed in the shape of an elongated plate extending with a flat cross section that is much larger than the dimension in the direction (the dimension in the height direction).
On the other hand, as shown in FIGS. 12 and 14, the housing 222 of the connector 220 of the second embodiment has a large dimension in the front-rear direction, which is the direction of the distance between the front surface 22c and the rear surface 22d (see FIG. 14). It is formed in the shape of a square bar that is approximately the same as the lengthwise dimension.

As shown in FIG. 12, the housing 222 of the connector 220 of the second embodiment includes a central contact arrangement area 22C and bases (first bases 22A) on both sides of the contact arrangement area 22C in the longitudinal direction. , and a second platform 22B).
A longitudinal direction positioning means 24 (positioning pin in FIG. 12 and the like) is provided on one of the bases on both sides of the housing 222 via the contact arrangement region 22C on the first base 22A. The longitudinal positioning means 24 is not provided on the second base portion 22B of the housing 222 opposite to the first base portion 22A with respect to the contact arrangement area 22C.

The lengthwise dimension of the housing 222 of the second base portion 22B of the connector 220 of the second embodiment is significantly larger than the lengthwise dimension of the housing 222 of the first base portion 22A.
Regarding the first base portion 22A and the second base portion 22B, the direction along the longitudinal direction of the housing 222 is hereinafter also referred to as the longitudinal direction.

A board escape groove 22p extending in the longitudinal direction of the housing 222 is formed in the second base portion 22B of the housing 222 .
The substrate escape groove 22p is formed to extend over the entire longitudinal length of the housing 222 of the second base portion 22B. The substrate escape groove 22p is formed recessed from the substrate support surface 22b of the housing 22 in the second base portion 22B.
The substrate escape groove 22p is formed only in the second base portion 22B of the housing 222. As shown in FIG. The substrate escape groove 22p is not formed in the first base portion 22A of the housing 222 and the contact arrangement area 22C.

As shown in FIG. 1, the connector base member 20A of the connector 20 of the first embodiment has rib-shaped protruding walls forming substrate receiving grooves 25a on both sides in the longitudinal direction of the housing 22 via the contact arrangement region 22C. It has 25 pairs, one each.
On the other hand, as shown in FIG. 12, in a connector base member 220A of a connector 220 of the second embodiment, a pair of rib-shaped protruding walls 25 (width direction positioning means) forming a substrate receiving groove 25a are connected to a housing 222. One is provided on the first base portion 22A and two are provided on the second base portion 22B.

In the connector base member 220A illustrated in FIG. 12, the width direction of the board support surface 22b of the housing 222, which is perpendicular to the longitudinal direction of the housing 222 and coincides with the longitudinal direction of the housing 222, coincides with the housing 222 front-rear direction.
The pair of rib-shaped protruding walls 25 forming the substrate accommodating groove 25a are provided apart from each other in the width direction of the substrate supporting surface 22b.

The pair of rib-shaped protruding walls 25 of the second base portion 22B are provided at two locations spaced apart from each other in the longitudinal direction of the second base portion 22B. In the connector base member 220A illustrated in FIG. 12 and the like, the pair of rib-like projecting walls 25 of the second base portion 22B are provided at both ends of the second base portion 22B in the longitudinal direction.

Also, the pair of rib-shaped protruding walls 25 of the second base portion 22B are formed so as to protrude from the substrate support surfaces 22b on both sides through the substrate clearance grooves 22p of the second base portion 22B.
The rib-shaped protruding walls 25 on both sides of the substrate escape groove 22p are formed so that the entire board accommodation groove 25a between the rib-shaped protruding walls 25 is located on the substrate escape groove 22p.

In the connector base member 220A illustrated in FIG. 12, the inner side surfaces on both sides in the groove width direction of the substrate escape groove 22p of the second base portion 22B of the housing 222 are formed perpendicular to the housing 222 front-rear direction. The surfaces (opposing surfaces) of the rib-shaped projecting walls 25 on both sides of the board escape groove 22p that face each other through the board accommodating groove 25a are continuous from the inner side surfaces on both sides of the board escape groove 22p in the groove width direction. 222 is formed to extend vertically in the front-rear direction.

12 and 13, the rear substrate 14 of the imaging module 10 is arranged on the substrate support surface 22b of the housing 222 with the first main surface 14a facing the substrate support surface 22b (upper surface) of the housing 222. . The rear substrate 14 of the imaging module 10 is placed on the substrate support surface 22b of the housing 222 of the connector 220 with the shell 223 (pressing means) opened.
The rear substrate 14 is positioned on the substrate support surface 22b relative to the housing 222 by the positioning pins 24 and the rib-shaped protruding walls 25 on the housing 222 in the width direction and the longitudinal direction of the substrate support surface 22b.

The rear substrate 14 is inserted into the substrate accommodation grooves 25a secured by the pairs of rib-shaped protruding walls 25 at three positions in the longitudinal direction of the housing 222 . The substrate support surface 22b is positioned with respect to the housing 222 in the width direction (the front-rear direction of the housing 222).
The rear substrate 14 is positioned in the longitudinal direction of the substrate support surface 22b (the longitudinal direction of the housing 222) with respect to the housing 222 by inserting the positioning pins 24 on the housing 222 into the first jig hooking holes 14e.

As shown in FIG. 12, the configuration having pairs of rib-shaped protruding walls 25 at three locations in the longitudinal direction of the housing 222 is different from the configuration having pairs of rib-shaped protruding walls 25n at only one location or two locations in the longitudinal direction of the housing 222. In comparison, this is advantageous in that the positioning accuracy of the substrate supporting surface 22b in the width direction with respect to the housing 222 of the rear substrate 14 is stably ensured.
The configuration in which pairs of rib-shaped protruding walls 25 are provided at a plurality of locations in the longitudinal direction of the first base portion 22A and the second base portion 22B of the housing 222 prevents the electric cable 13 of the imaging module 10 from bending or swinging. This is advantageous in avoiding affecting the positioning accuracy of the rear substrate 14 with respect to the housing 222 on 22C, and in stably ensuring the positioning accuracy of the rear substrate 14 on the contact arrangement area 22C.

As shown in FIG. 12, on the first base portion 22A of the housing 222 of the connector 220 of this embodiment, the positioning pin 24 and the positioning pin 24 are provided on the first base portion 22A of the housing 22 of the connector 20 of the first embodiment. A pair of rib-shaped projecting walls 25 are provided.
In addition, on the first base portion 22A of the housing 222 of the connector 220 of this embodiment, the positioning pin 24 on the housing 222 is prevented from being erroneously inserted into the second jig hooking hole 14f of the rear board 14. An erroneous insertion prevention projecting wall 22q is also provided.
A connector base member 220A of the connector 220 of this embodiment includes an erroneous insertion prevention projecting wall 22q.

As shown in FIGS. 12 and 15, the erroneous insertion prevention projecting wall 22q is provided at a position separated from the positioning pin 24 toward the first end surface 22e of the housing 222 (the side opposite to the contact arrangement area 22C). there is
The clearance between the erroneous insertion prevention projecting wall 22q and the positioning pin 24 is larger than the dimension from the rear end of the rear board 14 to the first jig hooking hole 14e, and is the distance from the rear end of the rear board 14 to the first jig hooking hole 14e. 2 The range is secured to be smaller than the dimension up to the jig hooking hole 14f.

As shown in FIG. 15, when the positioning pins 24 on the housing 222 are inserted into the first jig hooking holes 14e, the rear board 14 is inserted into the board receiving grooves 25a between the rib-shaped projecting walls 25 of the housing 222. As shown in FIG. can be inserted and placed on the substrate support surface 22b of the housing 222. FIG. The rear substrate 14 having the positioning pins 24 on the housing 222 inserted into the first jig hooking holes 14 e can be placed on the substrate support surface 22 b of the housing 222 .
When the shell 223 of the connector 220 is closed with respect to the housing 222 from the open state, the rear board 14 is placed on the board support surface 22b by inserting the positioning pins 24 on the housing 222 into the first jig hooking holes 14e. Additionally, the shell 223 can be pressed against the housing 222 so that the first major surface 14a is in surface contact with the board support surface 22b of the housing 222 . The shell 223 can be engaged with the locking protrusion 22n of the housing 222 to maintain the closed state with respect to the contact arrangement region 22C of the housing 222. As shown in FIG.

When trying to insert the positioning pins 24 on the housing 222 into the second jig hooking holes 14f of the rear substrate 14, the rear end portion of the first jig hooking holes 14e of the rear substrate 14 protrudes to prevent misinsertion. It comes into contact with the wall 22q and rides on the erroneous insertion prevention projecting wall 22q. Therefore, the positioning pins 24 on the housing 222 cannot be inserted into the second jig hooking holes 14f of the rear board 14. FIG. Also, the first main surface 14a of the rear substrate 14 cannot be brought into surface contact with the substrate support surface 22b of the housing 222 .

In addition, in a state in which a part of the rear substrate 14 rides on the erroneous insertion prevention projecting wall 22q, the shell 223 rotated in the closing direction opposite to the opening direction from the open state with respect to the housing 222 is not engaged with the housing 222. It abuts against the rear substrate 14 before it reaches the position where it can be engaged with the locking projection 22n, and cannot be engaged with the locking projection 22n.
For this reason, an operator who performs the work of electrically connecting the rear board 14 to the connector 220 (specifically, the contacts 221) cannot engage the shell 223 with the locking projection 22n of the housing 222. It can be easily and clearly grasped that the positioning pin 24 on the housing 222 is not inserted into the 14th jig hooking hole 14e.

The connector 220 of this embodiment can prevent erroneous insertion of the positioning pins 24 on the housing 222 into the second jig hooking holes 14f of the rear board 14. FIG.
Also, this connector 220 is advantageous in ensuring that the positioning pins 24 on the housing 222 are inserted into the first jig hooking holes 14e of the rear substrate 14. As shown in FIG.

As shown in FIGS. 12 to 14, in the contact arrangement region 22C of the housing 222 of the connector 220 of this embodiment, there are a plurality (four or more) partitioned by groove partition walls 22k at a plurality (three or more) locations in the longitudinal direction of the housing 222. ) are formed.
Of the groove partition walls 22k arranged at a plurality of locations in the longitudinal direction of the housing 222 in the contact arrangement region 22C, the locking protrusions 22n of the contact arrangement region 22C of the connector 220 of this embodiment are located at both ends of the arrangement. It is formed only on the housing front surface 22c side of the groove partition wall 22k located between 22k.

In FIG. 12, the locking protrusion 22n is formed on the housing front surface 22c side of the two groove partition walls 22k of the contact arrangement area 22C.
The number of groove partition walls 22k on which locking protrusions 22n are formed is not limited to two, and may be one or three or more.
The number of groove partition walls 22k not formed with locking protrusions 22n may be two or more including the groove partition walls 22k located on both sides of the groove partition wall 22k formed with the locking protrusions 22n in the longitudinal direction of the housing 222. , 3 or more.

The locking protrusions 22n of the connector 220 of this embodiment are formed to protrude forward of the housing 222 (opposite to the rear surface 22d) from the groove partition walls 22k at both ends of the housing 222 in the longitudinal direction.
As shown in FIG. 13, the shell 223 accommodates the engaging projection 22n of the housing 222 in the engaging window hole 23f, thereby engaging the engaging plate piece 23c arranged below the engaging projection 22n. It can be engaged with the portion 22n. As a result, the rotation of the shell 223 in the opening direction is restricted by the locking projection 22n, and the closed state with respect to the contact arrangement region 22C is maintained. The locking protrusion 22n locks the shell 223 to restrict the rotation of the shell 223 in the opening direction.

Compared to the shell 23 of the connector 20 of the first embodiment, the shell 223 of the connector 220 of this embodiment requires fewer locking protrusions 22n to be inserted into the engagement window holes 23f. Therefore, in the shell 223 of the connector 220 of this embodiment, the size of the engagement window hole 23f is reduced in the longitudinal direction (extending direction) of the housing 22 compared to the shell 23 of the connector 20 of the first embodiment. A configuration in which the size of the continuous portion 23e is reduced and the size of the continuous portion 23e is expanded is adopted. The configuration of the shell 223 of the connector 220 of this embodiment is the same as that of the shell 23 of the connector 20 of the first embodiment, except for the size of the engagement window 23f and the continuous portion 23e.
Since the shell 223 of the connector 220 of this embodiment can ensure a large size of the continuous portion 23e in the direction (extending direction) along the longitudinal direction of the housing 22, the continuous portion 23e is larger than the shell 23 of the connector 20 of the first embodiment. The durability of 23e can be enhanced.

As shown in FIG. 14, the connector 220 of this embodiment employs a contact 221 slightly modified from the contact 21 of the connector 20 of the first embodiment.
The contact 221 illustrated in FIG. 14 is a rib-like projection formed on the outer corner side of the distal bent portion 21i of the movable plate portion 21e and extending along the extending direction of the movable plate portion 21e in the connector 20 of the first embodiment. The contact portion 21a is omitted, and the bent end portion 21i itself of the movable plate portion 21e is used as the contact portion.

Further, the extension piece 21h of the contact 221 illustrated in FIG. 14 extends from the end of the main plate portion 21d on the side opposite to the central bent portion 21c in the extending direction (longitudinal direction) to the side opposite to the movable plate portion 21e. It is formed so as to extend substantially perpendicularly to the main plate portion 21d. The connection portion 21b of the contact 221 extends parallel to the main plate portion 21d from the end of the extension piece portion 21h opposite to the main plate portion 21d through the plate thickness of the extension piece portion 21h to the opposite side of the main plate portion 21d. is served.

As shown in FIGS. 12 to 14, on the front side of the contact arrangement area 22C of the housing 222, an extension piece arrangement recess 22r is formed by recessing the lower side of each groove partition wall 22k from the front surface 22c of the housing 222. It is
The extension piece portion 21 h of the contact 221 is arranged in the extension piece portion arrangement recess 22 r of the housing 222 .

As shown in FIG. 12, the front end of the groove partition wall 22k (the end opposite to the rear surface 22d of the housing 222) where the locking projection 22n is not formed constitutes part of the front surface 22c of the housing 222. As shown in FIG.
The shell 223 in the open state is rotatable in the closing direction to a position where the engaging plate piece 23c contacts the front end of the groove partition wall 22k where the locking projection 22n is not formed. Further rotation of the shell 223 in the closing direction is restricted when the engagement plate piece 23c abuts against the front end of the groove partition wall 22k on which the locking protrusion 22n is not formed. Therefore, even when the shell 223 is in the closed state with respect to the contact arrangement region 22C of the connector 220, it does not come into contact with the extension piece 21h of the contact 221, and there is concern that the extension piece 21h may be damaged by contact with the extension piece 21h. There is no

As shown in FIGS. 12 and 13, the rear substrate 14 of the imaging module 10 is positioned with respect to the housing 222 by the positioning pins 24 and the rib-shaped protruding walls 25 on the housing 222, so that the first main surface 14a faces the housing. It is arranged on the board support surface 22b of the housing 222 in an orientation facing the board support surface 22b (upper surface) of the housing 222. As shown in FIG. The rear board 14 is then kept closed with respect to the housing 222 by engaging (locking) the shell 223 rotated in the closing direction with respect to the housing 222 from the open state with the locking protrusion 22n of the housing 222. Then, the top plate 23a of the shell 223 presses against the arrangement area support surface 22i of the contact arrangement area 22C and is fixed to the housing 222. As shown in FIG.

As shown in FIG. 14, the bent distal end portion 21i of the contact 221 projects slightly upward from the support surface 22i of the contact arrangement region 22C before the rear substrate 14 is placed thereon. there is
The rear substrate 14 arranged on the housing 222 moves the movable plate portion 21e of the contact 221 to the contact of the housing 22 until it is pressed against the substrate support surface 22b of the housing 222 by the rotation of the shell 223 in the open state in the closing direction. Push it into the accommodation groove 26 .
As a result, when the rear substrate 14 is press-fixed against the substrate support surface 22b of the housing 222 by the shell 223, the bent tip portions 21i of the contacts 221 are brought into contact with the electrodes 14c of the rear substrate 14 by the elastic restoring force of the contacts 221. maintain stable contact.

The rear substrate 14, which is pressed and fixed to the substrate support surface 22b of the housing 222 by the shell 223, is supported by the substrate support surface 22b in parallel with the substrate support surface 22b.
However, the portion of the rear board 14 located on the second base portion 22B of the housing 222 is arranged on the board escape groove 22p formed in the second base portion 22B.
One end in the extending direction of the board escape groove 22p opens to the second end surface 22f of the housing 222 . The substrate escape groove 22p is formed extending from the second end surface 22f of the housing 222 to the vicinity of the contact arrangement region 22C, substantially over the entire length of the second base portion 22B in the longitudinal direction.

The rear board 14 is supported on the board support surface 22b by being pressed by the shell 223 against the portion of the board support surface 22b located at the first base portion 22A and the contact arrangement area 22C of the housing 222 . The portion of the rear substrate 14 that is pressed and fixed to the substrate support surface 22b of the housing 222 by the shell 223 and is located on the second platform 22B side from the placement area upper support surface 22i is located from the placement area upper support surface 22i to the second platform. As the separation distance to the 22B side increases, it bends so as to be positioned downward, and at least a part of it is accommodated in the substrate escape groove 22p, or it extends from the arrangement area support surface 22i onto the substrate escape groove 22p. It will be in an extended state.

In the connector 220 of this embodiment, the conductor of the electric cable 13 is electrically connected to the conductor connection terminal 14d at the front end of the first main surface 14a of the rear substrate 14 by soldering or the like, and the connection portion is connected to the substrate of the second base portion 22B. It can be accommodated in the escape groove 22p. In addition, the substrate clearance groove 22p accommodates the portion arranged along the front end portion of the first main surface 14a of the rear substrate 14 of the electric cable 13 and the end portion of the flexible tube 16 accommodating the electric cable 13. It is possible.
As a result, a connecting portion where the conductor of the electric cable 13 is electrically connected to the conductor connecting terminal 14d at the front end portion of the first main surface 14a of the rear substrate 14 by soldering or the like, and the first terminal of the rear substrate 14 of the electric cable 13 are not connected. It is possible to prevent the portion arranged along the front end of the main surface 14a and the tube from affecting the state of contact of the rear substrate 14 with the substrate support surface 22b of the housing 222.

In the connector 220 of this embodiment, even if there is a connection point where the conductor of the electric cable 13 is electrically connected to the front end portion of the first main surface 14a of the rear substrate 14, the support surface 22i on the arrangement area of the contact arrangement area 22C does not. It is possible to prevent the rear substrate 14 from being lifted from the upper support surface 22i, and to stably and reliably maintain the state of contact of the rear substrate 14 with the upper support surface 22i of the arrangement area.
Further, even if the electric cable 13 or the end portion of the tube containing the electric cable 13 is arranged along the front end portion of the first main surface 14a of the rear substrate 14, the connector 220 does not dispose the contact arrangement region 22C. It is possible to prevent the rear substrate 14 from floating with respect to the upper region support surface 22i, and to stably and reliably maintain the state of contact of the rear substrate 14 with the arrangement region upper support surface 22i.
As a result, the connector 220 can stably maintain the contact state of the contact portion of the contact 221 (the tip bent portion 21i in FIG. 12) with the electrode 14c of the rear substrate 14, and the connection between the circuit of the imaging module 10 and the contact 221 can be maintained. A stable electrical connection can be maintained.

Although the present invention has been described above based on the best mode, the present invention is not limited to the above-described best mode, and various modifications are possible without departing from the gist of the present invention.
As exemplified in the second embodiment, a pair of rib-shaped protruding walls 25 (width direction positioning means) forming board accommodation grooves 25a are provided at a plurality of positions in the longitudinal direction of the second base portion 22B, and the second base of the housing is provided. Forming a substrate escape groove 22p in the portion 22B, and forming a pair of rib-shaped protruding walls 25 which are provided in the second base portion 22B and form a substrate accommodating groove 25a are arranged on both sides in the groove width direction through the substrate accommodating groove 25a. , providing the erroneous insertion prevention projecting wall 22q near the positioning pin 24 of the first base portion 22A, and using the tip bending portion 21i itself of the contact as the contact portion are the same as those of the connector, etc. of the first embodiment. , is widely applicable to connectors of various embodiments according to the present invention.
In addition, as illustrated in the second embodiment, the locking protrusions 22n are provided only on a portion of the plurality of groove partition walls 22k of the contact arrangement region 22C, and the engagement plate piece 23c of the shell extends in the longitudinal direction of the housing. Both sides can abut against the front end of the groove partition wall 22k which is not provided with the locking protrusion 22n through the engagement window hole 23f in the connector of the first embodiment. It is widely applicable to the connector of the embodiment.

As exemplified in the first embodiment, the contact portion of the contact is a rib-like protrusion formed on the outer angle side of the tip bent portion 21i of the movable plate portion 21e and extending along the extending direction of the movable plate portion 21e. That is, a pair of rib-shaped protruding walls 25 forming a substrate receiving groove 25a is provided on each of the first base portion 22A and the second base portion 22B of the housing, and a plurality of groove partition walls 22k in the contact arrangement area 22C. and a shell formed with engaging window holes 23f capable of accommodating the locking projections 22n provided on all of the plurality of groove partition walls 22k of the contact arrangement region 22C. and can be widely applied to connectors of various embodiments according to the present invention, such as the connector of the second embodiment.
Further, as illustrated in the first embodiment, adopting a housing in which the board escape groove 22p is not formed, or adopting a housing in which the erroneous insertion prevention projecting wall 22q is not provided, is also possible in the second embodiment. It can be widely applied to connectors of various embodiments according to the present invention, such as connectors.

The tube housing groove 22o (see FIG. 1) exemplified in the first embodiment can also be applied to the second base portion 22B in which a substrate escape groove is formed, such as the housing of the connector of the second embodiment.
However, the tube accommodating groove applied to the second base portion 22B having the substrate relief groove is located on the side opposite to the contact arrangement region 22C of the second base portion 22B from the substrate relief groove (specifically, its groove bottom). It is formed over the second end surface 22f. This tube accommodation groove is formed such that the depth from the upper surface of the second base portion 22B increases toward the second end surface 22f side.

The cross-sectional shape of the housing can be changed as appropriate.
In this regard, for example, the housing of the connector of the first embodiment may be changed to a rectangular bar shape whose dimension in the front-rear direction, which is the direction of the distance between the front surface 22c and the rear surface 22d, is substantially the same as the dimension in the height direction, or the housing of the connector of the second embodiment. It is also possible to change the housing of the connector in the form of an elongated plate extending with a flattened cross section in which the dimension in the front-rear direction, which is the direction of the distance between the front face 22c and the rear face 22d, is much larger than the dimension in the height direction. is.

In the above-described embodiments, as an example of an electronic module, an imaging module using an imaging element as an electronic element was illustrated, but the electronic module is not limited to an imaging module.
For the electronic module, for example, a configuration using a laser element or a sensor element in place of the electronic element of the imaging module of the above-described embodiment can be adopted.

The electronic module has an electronic element, an electric cable electrically connected to the electronic element, and a connecting end board electrically connected to the rear end of the electric cable opposite to the front end electrically connected to the electronic element. Not limited to configuration.
An electronic module includes a connection end substrate constituting an end portion thereof, and an electronic component (for example, an electronic element) electrically connected to an electrode of the connection end substrate via wiring formed on the connection end substrate. For example, a configuration without an electric cable can also be adopted.

The pressing means for pressing the connecting end board of the electronic module against the contact portions of the contacts provided on the housing is not limited to the shell pivotally supported by the housing.
As the pressing means, for example, a clip-shaped elastic member or the like can be adopted that sandwiches the connection end substrate together with the housing and presses the connection end substrate against the contact portion of the contact.

The width-direction positioning means positions the connecting end board with respect to the housing in a direction perpendicular to the positioning direction by the longitudinal-direction positioning means on the board support surface of the housing.
When the connection end board is a long and narrow plate-like board with one side facing the board support surface of the housing, the width direction positioning means is arranged in the longitudinal direction of the connection end board on the board support surface. are aligned in the arrangement direction (arrangement pitch direction) of the plurality of contacts in the housing, and the connecting end board is positioned at a predetermined position in the width direction perpendicular to the contact arrangement direction (arrangement pitch direction) on the board supporting surface. In this case, the longitudinal positioning means positions the connecting end substrate positioned by the width direction positioning means at a predetermined position in the contact arrangement direction (arrangement pitch direction) with respect to the housing.

The longitudinal direction positioning means and the width direction positioning means are, for example, positioning protrusions formed on the housing so as to surround the arrangement position of the connecting end board set on the board support surface of the housing, It is also possible to adopt a configuration in which the positioning groove is recessed from the housing and the bottom surface of the positioning groove serves as a substrate supporting surface.

The protruding portion that protrudes from the board supporting surface of the housing and constitutes the width direction positioning means is not limited to the rib-like protruding wall described in the above embodiment. The shape of the projecting portion that constitutes the width direction positioning means can be changed as appropriate.

In the above-described embodiment, the connector is provided with only one positioning pin, which is the longitudinal positioning means and is inserted into the pin locking hole formed in the connecting end board, in the housing.
For example, as shown in FIG. 16, the connector longitudinal positioning means is provided on the substrate supporting surface 22b of the housing 22 of the above-described embodiment by first jig hooking holes 14e at the rear end of the rear substrate 14 of the imaging module. In addition to the positioning pin 24 (first positioning pin) inserted into the (first pin locking hole), it is inserted into the second jig hooking hole 14f (second pin locking hole) at the rear end of the rear substrate 14. It is also possible to employ a configuration in which the positioning pin 24a (second positioning pin) also protrudes.
In the configuration illustrated in FIG. 16, the connecting end substrate positioned in the width direction by the width direction positioning means has a first pin locking hole (second Positioning in the longitudinal direction is achieved by inserting the first positioning pin 24 into the jig hooking hole 14e). In other words, the connecting end board is not longitudinally aligned when the positioning pins are inserted into the two pin locking holes (the first jig hooking hole 14e and the second jig hooking hole 14f) at the tip. Positioning is achieved.

In the configuration of FIG. 16, even if the first positioning pin 24 is to be inserted into the second pin locking hole (second jig hooking hole 14f) of the connecting end board, the connecting end board will not be on the positioning pin 24a. As a result, the first positioning pin 24 cannot be inserted into the second pin locking hole (second jig hooking hole 14f).
For this reason, in the configuration illustrated in FIG. 16, the first positioning pin 24 may be misaligned with the two pin locking holes (the first jig hooking hole 14e and the second jig hooking hole 14f) at the tip of the connecting end board. Insertion can be prevented and the longitudinal positioning of the connecting end board with respect to the housing can be ensured.

DESCRIPTION OF SYMBOLS 10... Electronic module (image pick-up module), 11... Image pick-up element, 11a... Light-receiving surface, 12... Head side board, 13... Electric cable, 13a... Exterior coating, 13b... Coaxial cable, 13c... Center conductor, 13d... Outer conductor, 14... Connection end board (rear side board), 14a... First main surface, 14b... Second main surface, 14c... Electrode, 14d... Conductor connection terminal, 14d1... Center conductor connection terminal, 14d2... External conductor connection terminal , 14d3... sub-conductor connection terminal, 14e... pin locking hole (first jig hooking hole), 14f... pin locking hole (second jig hooking hole), 15... tube, 16... module with tube, 20... Connector 20A Connector base member 21 Contact 21a Contact portion 21b Connection portion 21c Central bending portion 21d Main plate portion 21e Movable plate portion 21f Overhang 21g Fixing protrusion 21h... Extending piece part 21i... Bent tip part 22... Housing 22A... First base part 22B... Second base part 22C... Contact arrangement area 22a... Bottom surface 22b... Board support surface 22c... Front surface , 22d... rear surface 22e... first end face 22f... second end face 22g... groove bottom wall 22h... groove rear wall 22i... arrangement area upper support surface 22j... fitting projection 22k... groove partition wall 22m Locking groove 22n Locking portion (locking projection) 22o Tube accommodating groove 22p Substrate clearance groove 22q Mis-insertion prevention protruding wall 22r Extension piece arrangement concave portion 23 Pressing means, shell 23a top plate 23b shaft support projection piece 23c engaging plate piece 23d holding surface 23e continuous portion 23f engaging window hole 23g operating piece 24 longitudinal positioning Positioning pin 24a Positioning pin (second positioning pin) 25 Width direction positioning means Protruding portion (rib-shaped protruding wall) 25a Substrate housing groove 26 Contact housing groove 26a Main groove 26b Guide groove 27 Rotary shaft 30 Board with connector 31 Wiring board (base board) 31a Main surface 31b Wiring 50 Electronic endoscope system 51 Video processing display device 52 Connection cable 220 Connector 221 Contact 220A Connector base member 222 Housing 223 Shell (pressing means) 230 Board with connector.

Claims (5)

A connector mounted on a wiring board,
a plurality of contacts having contact portions that contact electrodes formed on the connection end substrate of the electronic module and connection portions that are electrically connected to the wiring of the wiring substrate;
a housing that holds the contacts;
pressing means for pressing the connection end substrate against the contact portion of the contact;
longitudinal direction positioning means for positioning the connecting end board with respect to the housing in the arrangement pitch direction of the contacts arranged in the housing; and width direction positioning means for positioning in the width direction perpendicular to the arrangement pitch direction; with
The housing has a contact arrangement region in which a plurality of the contacts are arranged, and a first base portion and a second base portion which are separated from each other via the contact arrangement region in the arrangement pitch direction,
the longitudinal positioning means is a positioning pin provided on the first base portion and inserted into a pin locking hole formed in the connecting end substrate;
The width direction positioning means is spaced apart from each other in the width direction by at least the second base portion of the first base portion and the second base portion of the housing at a distance that allows the connection end substrate to be inserted thereinto. a formed protrusion,
By disposing the connecting end board of the electronic module between the protrusions and inserting the positioning pins into the pin locking holes of the connecting end board, the connecting end board Positioning in the arrangement pitch direction and the width direction,
The protruding portion formed on the second base portion passes through a substrate escape groove formed in the second base portion so as to extend from the end of the second base portion opposite to the contact arrangement region toward the contact arrangement region. Connectors on both sides . The housing has a substrate support surface that supports the connection end substrate so as to be in contact with the contact portion of the contact,
The electronic module includes an electronic element that is one of an image sensor, a laser element, and a sensor element, an electric cable that is electrically connected to the electronic element, and a tip of the electric cable that is electrically connected to the electronic element. and the connecting end substrate electrically connected to the rear end of the
The electronic element and the electric cable of the electronic module are provided on the second base portion of the housing over the upper surface which is a part of the substrate supporting surface or the side surface opposite to the contact arrangement area from the substrate escape groove. is formed so as to accommodate a flexible tube accommodating a tube, and the tube accommodation groove is formed such that the depth from the upper surface increases toward the side surface of the second base portion. 2. The connector of claim 1 . A connector mounted on a wiring board,
a plurality of contacts having contact portions that contact electrodes formed on the connection end substrate of the electronic module and connection portions that are electrically connected to the wiring of the wiring substrate;
a housing that holds the contacts;
pressing means for pressing the connection end substrate against the contact portion of the contact;
longitudinal direction positioning means for positioning the connecting end board with respect to the housing in the arrangement pitch direction of the contacts arranged in the housing; and width direction positioning means for positioning in the width direction perpendicular to the arrangement pitch direction; with
The housing includes a contact arrangement area in which a plurality of the contacts are arranged, a first base part and a second base part which are separated from each other through the contact arrangement area in the arrangement pitch direction, and the connecting end part. a substrate support surface that supports a substrate so as to be in contact with the contact portion of the contact;
the longitudinal positioning means is a positioning pin provided on the first base portion and inserted into a pin locking hole formed in the connecting end substrate;
The width direction positioning means is spaced apart from each other in the width direction by at least the second base portion of the first base portion and the second base portion of the housing at a distance that allows the connection end substrate to be inserted thereinto. a formed protrusion,
By disposing the connecting end board of the electronic module between the protrusions and inserting the positioning pins into the pin locking holes of the connecting end board, the connecting end board Positioning in the arrangement pitch direction and the width direction,
The electronic module includes an electronic element that is one of an image sensor, a laser element, and a sensor element, an electric cable that is electrically connected to the electronic element, and a tip of the electric cable that is electrically connected to the electronic element. and the connecting end substrate electrically connected to the rear end of the
The second base portion of the housing has a flexible flexible structure that accommodates the electronic element and the electric cable of the electronic module from the upper surface, which is a part of the substrate support surface, to the side surface opposite to the contact arrangement area. a tube accommodating groove capable of accommodating an electric tube is formed, and the tube accommodating groove is formed so that the depth from the upper surface increases toward the side surface of the second base. said pressing means is a shell rotatably mounted on said housing;
The housing has an engaging portion that restricts rotation of the shell in the opening direction by engaging the shell arranged at the closed position covering the board support surface,
The shell has an engaging portion that can be engaged with the engaging portion of the housing when placed in a closed position covering the board support surface, and the engaging portion engages the engaging portion of the housing. 4. The connector according to claim 2 or 3, wherein the connecting end board can be pressed against the board supporting surface by mating. A board with a connector, comprising: the connector according to any one of claims 1 to 4 ; and a wiring board on which the connector is mounted, wherein the connecting portions of the contacts are electrically connected to the wiring of the wiring board. .

Images