KR20080042732A - Relay connector - Google Patents

Abstract

A relay connector is provided to contact a probe with a tested connector terminal directly and replace only a damage probe if the probe is damaged, thereby reducing measurement test costs. A floating guide(26) is attached to and separated from a pin block(24). The floating guide is elastically compressed in the separation direction. In the floating guide, a guide hole(26b) is formed. The guide hole is for positioning by inserting a tested connector(38) into the pin block. Towards a terminal of the tested connector inserted into the guide hole, a probe(54) is disposed in the pin block as having the attachment/separation direction as an axis direction. In the guide hole, a press operation member(14) is installed. The press operation member is operated in an opening state and a press state. The opening state allows the insertion of the tested connector. The press state is generated when inserted tested-connector is pressed towards the pin block.

Description

Relay connector {RELAY CONNECTOR}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a relay connector used for electrically connecting an inspected side connector disposed on an inspected substrate, such as an electronic component, to a measuring instrument or the like for irradiation.

In a small electronic device such as a mobile phone or a digital camera, a plurality of boards are overlapped and arranged in order to mount many electronic circuits in a small space, and the boards of these boards are electrically connected to each other through the arranged connectors. There is. Therefore, in order to inspect a board | substrate and the connector arrange | positioned at it, it is preferable to connect electrically a measuring instrument etc. to a connector suitably. Here, in order to inspect the board | substrate under test and the whole test | inspection side connector, it is required to connect the jig | tool side pair which is paired to the test | inspection side connector, and to electrically connect to a measuring instrument. Nevertheless, in either of the inspected connector and the jig connector, the endurance number of pulling out the fitting is relatively small, about 50 times. Therefore, the jig-side connector must be replaced each time the number of inspections reaches the endurance number. If the jig-side connector is fixed to the jig-side board by soldering and several wiring cables connected to the jig-side board are connected to the measuring device or the like, only the jig-side connector cannot be easily replaced. Therefore, the jig side connector, the jig side board, and the entire wiring cable must be replaced. Then, a problem arises in that the cost of measurement inspection increases.

Therefore, the applicant of the present invention has already proposed a technique as disclosed in Japanese Patent Laid-Open No. 2004-273192, and by reducing the portion to be replaced, the measurement inspection cost is reduced. Prior to this, the proposed technique arranges the jig side connector corresponding to the inspected side connector on the insulated relay board, and arranges the insulated relay board to be detachably attached to the probe unit made of the insulating material. The probe unit is arranged with a probe. The jig side connector terminal is electrically connected to the terminal provided on the insulated relay board, and the probe of the probe unit is electrically connected to the insulated relay board terminal. In addition, the other end of the probe provided in the probe unit is suitably electrically connected to a plurality of wiring cables connected to a measuring instrument or the like. As a result, the inspection-side connector is electrically connected to the measuring device or the like through the jig-side connector, the insulated relay board, the probe, and the wiring cable. Therefore, when the number of times of inspection use of the jig-side connector reaches the endurance number of times, the jig-side connector and the insulating relay board may be replaced, and the measurement inspection cost can be reduced as there are fewer parts to be replaced.

[Patent Document 1] Japanese Patent Application Laid-Open No. 2004-2731912

In the technique proposed in Japanese Patent Application Laid-Open No. 2004-273192, it is only necessary to replace the jig side connector and the insulated relay board, so that the measurement inspection cost can be reduced, but not necessarily satisfactorily. Therefore, the inventors have a structure in which the probe is directly brought into contact with the terminal to be inspected, and the jig-side connector and the insulated relay board are not replaced. I thought I could.

This invention is made | formed based on this idea, and an object of this invention is to provide the relay connector which contacts a probe to a connector under test | inspection.

The relay connector of the present invention for achieving the above object is a relay connector for electrically connecting the probe to the measuring device by contacting the probe to the terminal to be inspected arranged on the substrate to be inspected, and a floating guide made of an insulating material against a pin block made of an insulating material. Approach-detachable, elastically pressurized in the separation direction, are disposed, and a guide hole for positioning by positioning the connector on the floating side toward the pin block side is formed in the floating guide. An opening state in which the probe is arranged in the pin block toward the connector side under test, with the approach separation direction of the floating guide in the axial direction, and the connector is inserted into the guide hole of the floating guide to allow insertion of the connector under test And sandwiched in the floating guide It is comprised by providing the pressurizing operation member operated in the pressurized state which pressed the said to-be-tested side connector inserted into the pin block side.

Then, the engaging projection is provided on the pressing operation member, the engaging support portion is provided on the floating guide, and the engaging projection engages with the engaging support portion in the open state of the pressing operation member, so that the floating guide is moved toward the pin block side. It may be configured to restrict movement.

Further, the pressing operation member is allowed to swing in the opening state and the pressing state by a swing shaft disposed on a surface parallel to the surface facing the pin block side of the connector to be inspected inserted into the guide hole. It can arrange | position so that a press block may be made to rock | swivel by the 2nd rocking shaft parallel to the rocking shaft, in the front-end | tip side which presses the said test | inspection side connector.

In addition, a floating pin having an extension part at both ends is disposed through the floating guide and the pin block in an approach separation direction of the floating guide, so that the floating guide can be moved in the separation direction from the pin block by the extension parts at both ends. It may be configured by regulating the distance therebetween, inserting the float spring into the floating pin so that the floating spring can flow, and reducing the gap between the floating guide and the pin block.

The floating pin adjusts a distance that can be moved in the separation direction by an adjustment spring that is screwed to one end of the floating pin, and forms an adjustment hole in the pressure manipulation member toward the adjustment spring to adjust the adjustment spring from the outside. It can also be configured to adjust.

Further, a plane larger than the substrate to be inspected is formed on the substrate mounting surface of the floating guide for fitting the connector to be inspected into the guide hole toward the pin block side, and the connector to be inspected is guided. The test plate may be configured so as not to be restricted in any position in the state of being fitted in the fitting.

In addition, a restricting portion for restricting the swing on the open state side may be provided on the swingable pressing operation member, and the engaging projection may be configured to engage the engaging support portion in a state where the pressing operating member is regulated by the restricting portion. .

In addition, the relay connector of the present invention is a relay connector for electrically connecting a probe to a tester-side connector terminal disposed on a test target board and electrically connecting the probe to the base member made of an insulating material. And a guide hole for fitting and positioning the inspected side connector to the floating guide in a state in which the inspected substrate is inserted between the base member and the floating guide. Inserting the floating guide, arranging a pressing operation member so that the floating guide side can be separated by access, and arranges a pin block made of an insulating material toward the floating guide on the pressing operation member, and the pin block on the floating guide In the connected state The probe is placed on the pin block so as to be connected to the inspection-side connector terminal fitted into the guide hole, and the floating guide is interlocked with the operation of the pressing operation member in a direction of separating the pin block from the floating guide. The pin block at an opening state allowing separation of the substrate under test between the base member and the floating guide and fitting into the guide hole of the floating guide, the pin block being separated from the base member. The pressing operation member may be operated in a pressurized state in which pressure is applied.

And the board | substrate positioning recessed part which has the shape of the insertion side front-end | tip part of the said to-be-tested board | substrate was provided in the board | substrate mounting surface provided in the said base member toward the said guide hole of the said floating guide from the edge part, and the said board | substrate position It is also possible to configure the inspection target substrate by regulating the insertion dimension and the lateral shift of the inspection target substrate by the crystal recess.

In addition, the floating guide may be guided to the linear guide provided in the base member, so that the floating guide may be contacted and separated in a vertical direction with respect to the substrate mounting surface of the base member.

The pressing operation member and the pressing operation member may be arranged so as to be able to swing so that the floating guide side is separated from the base member so as to elastically press in a direction approaching the floating guide side of the pressing operation member. The pressure spring may be compression-installed between the base members.

Further, the pressing operation member is arranged to be able to swing so that the floating guide side is separated from the base member, and the lever member with respect to the base member may swing on a swing shaft parallel to the swing axis of the pressing operation member. Arranged so that the one end of the lever member is coupled to the floating guide, and the other end is pressed by the operation of the pressing operation member, so that the floating guide side of the pressing operation member swings in the separation direction from the base member. The floating guide may be configured to swing in the separation direction from the base member so as to be in the open state.

Further, the depth of the guide hole formed in the floating guide may be configured to match the height of the connector under test.

Further, a concave portion is provided on the surface of the pin block side of the floating guide, and a convex portion fitted to the concave portion is formed on the floating guide side surface of the pin block, and the concave portion and the convex portion are joined together. The floating guide and the pin block may be configured to be relatively positioned.

Moreover, it is also possible to form the front end outer side of the floating guide side of the pressing operation member by forming a chamfered inclined surface.

In the relay connector according to claim 1, the connector to be inspected is inserted into the guide hole of the floating guide which is elastically pressed in the opening state of the pressing operation member and is separated from the pin block, and is positioned to be positioned toward the pin block side, In such a state, since the floating guide and the inspected side connector are operated in a pressurized state pressed against the pin block side by the pressurizing operation member, the inspected connector is placed in an improper position when the connector to be inspected is inserted into the guide hole and positioned. No contact with the furnace probe, no relatively transverse force (shear force) in the state in which the probe under test is in contact with the probe, and no damage to the probe or connector under test.

In the relay connector according to claim 2, the engaging projection is provided on the pressing operation member, the engaging support portion is provided on the floating guide, and the floating guide is engaged with the engaging projection and the engaging support portion in the opening state of the pressing operation member. Since the movement to the pin block side is regulated, when the connector to be inspected is inserted into the guide hole of the floating guide, the floating guide does not move even when a force toward the pin block is applied to the floating guide. The untested side connector does not come into contact with the probe and does not damage the probe or the inspected side connector.

Moreover, in the relay connector of Claim 3, since the pressurizing operation member is arrange | positioned so that it can rock to an open state and a pressurized state by a rocking shaft, the structure which arrange | positions a pressurizing operation member is simple. Moreover, since the pressing block can be rocked by the second rocking shaft parallel to the rocking shaft on the front end side to press the connector under test, the floating guide can be accurately pressed in the direction of approaching the pin block side.

Moreover, in the relay connector of Claim 4, the distance which a floating guide can move to a separation direction from a pin block is regulated by the floating pin which has an extension part in both ends. Further, the floating guide can be elastically pressed in the separation direction by the floating spring, and the floating guide can be separated from the pin block in the opening state of the pressing operation member.

And in the relay connector of Claim 5, since the floating pin adjusts the distance which can be moved to a separation direction by the adjustment screw screwed to the one end side, it sets arbitrarily the distance which a floating guide separates from a pin block. Can be. Moreover, since the adjustment hole is formed in the press operation member toward the adjustment screw, even if the adjustment screw loosens during use, it can be easily readjusted externally.

Further, in the relay connector according to claim 6, a plane larger than the substrate to be inspected is formed on the board mounting surface of the floating guide for fitting and inserting the inspected connector into the guide hole toward the pin block side. Since the board under test is not regulated at any position while being fitted in the guide hole, the connector under test is shifted laterally with respect to the board under test even when the connector on the test side is mounted in a different position. Force does not work anywhere, and does not cause any problem in inspection.

Further, in the relay connector according to claim 7, the restricting portion for restricting the swing on the open state side is provided on the swingable pressing operation member so that the engaging projection is coupled to the engaging support portion in a state where the pressing operating member is regulated by the restricting portion. Therefore, when the pressing operation member is regulated in the opening state, it is reliably regulated that the engaging projection engages with the engaging support portion and the floating guide moves to the pin block side.

In the relay connector according to claim 8, in the state where the substrate to be inspected is inserted between the base member and the floating guide, the connector to be inspected is inserted into the guide hole formed in the floating guide to be positioned and positioned thereon. Since the pin block was brought into contact with the probe to be connected to the terminal to be inspected inserted into the guide hole, when the base member was placed at the lower side, the connector to be inspected was placed above the substrate under test. Can be checked

And in the relay connector of Claim 9, since the board | substrate positioning recessed part provided with the shape of the insertion side front-end | tip part of the board | substrate to be tested on the board | substrate mounting surface of a base member toward the guide hole of a floating guide was provided from the edge part. By the board | substrate positioning recessed part, the insertion dimension of a test | inspection board | substrate and the shift | deviation to the side are regulated, and a test target board | substrate is positioned. Thus, the positioning of the inspected side connector disposed on the inspected substrate is made relative to the guide hole formed in the floating guide.

Further, in the relay connector according to claim 10, since the floating guide is guided to the linear shaft provided in the base member and contacted and separated in the vertical direction with respect to the substrate mounting surface of the base member, the guide is formed in the guide hole formed in the floating guide. When the four-side connector is inserted, the force for shifting the inspected side connector sideways does not work, whereby the force for shifting the inspected substrate on which the inspected side connector is arranged sideways does not work.

Further, in the relay connector according to claim 11, the pressing operation member is arranged so that the floating guide side can be moved so as to be separated from the base member, and the pressing member is elastically pressed in the direction in which the floating guide side of the pressing operation member approaches. Since the pressure spring is compressed and provided between the operation member and the base member, the structure thereof is simple. And while the pressurizing operation member is pressurized, it becomes an opening state and insertion of a board | substrate under test is allowed, and when a press release operation | release is canceled, it becomes a pressurized state which presses a pin block to a connector under test, and can measure. It does not require pressurization operation in the middle, and the operation is easy.

In the relay connector according to claim 12, since the floating guide side swings from the base member in the separation direction from the base member, the floating guide swings from the base member in the separation direction and becomes an open state. The floating guide is separated from the base member during the pressing operation, and the insertion of the substrate under test is reliably permitted.

In the relay connector according to claim 13, since the depth of the guide hole formed in the floating guide is equal to the height of the inspected side connector, the inspected connector inserted into the pin block side and the guide hole of the floating guide. The pin block side of the surface is in the same plane, and by arranging the probe on the pin block based on this surface, the probe can be elastically connected to the connector under test with an appropriate force.

Further, in the relay connector according to claim 14, a recess is provided on the surface of the pin block side of the floating guide, and a convex portion fitted to the recess is formed on the surface of the floating guide side of the pin block to form the recess and the convex. Since the negative coupling causes the floating guide and the pin block to be relatively positioned, the probe placed in the pin block can be brought into contact with the connector to be inspected positioned in the guide hole of the floating guide at an appropriate position.

Further, in the relay connector according to claim 15, since the floating guide side front end portion of the pressurizing operation member is formed with a chamfered inclined surface, inspection of a CCD camera element or the like arranged close to the connector under inspection on the substrate under inspection. When performing the above, the pressurizing operation member of the relay connector of the present invention does not interfere with this inspection.

Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. 1 to 14. 1 is a side view of a pressurized state in a first embodiment of a relay connector of the present invention. 2 is a plan view of FIG. 1. 3 is a side view of the open state of FIG. 1. 4 is an exploded perspective view of FIG. 1. 5 is an exploded perspective view of the upper and lower pin blocks and the floating guide. 6 is an exploded perspective view of the pin block. 7 is an exploded perspective view of the lower pin block, the wiring board, and the base member. 8 is an external perspective view of an inspected side connector provided on an inspected substrate inspected by the relay connector of the present invention. 9 is a longitudinal cross-sectional view of the pin block. It is a figure which shows the terminal pattern provided in a wiring board. 11 is an exploded perspective view of the pressing operation member, the hinge member, and the base. 12 is a cross-sectional view taken from arrow A-A of FIG. 2. FIG. 13 shows a structure in which the wiring board is pressed against the base member by ribs provided in the hinge member, FIG. 12A is a side view with a part removed, and FIG. 12B is a rear view. It is a figure explaining the effect | action by which the front end part of the press operation member was removed from the inclined surface of the chamfer type.

1 to 14, the relay connector of the first embodiment of the present invention is configured as follows. First, the hinge member 12 is fixed to the base member 10 by the screw 10a, and the hinge member 12 is rocked by the pivot shaft 16 through which the pressure manipulation member 14 penetrates. Is arranged. And the press spring 18 is compressed and installed between the back side of this press operation member 14, and the hinge member 12. As shown in FIG. In addition, on the distal end side of the pressing operation member 14, the pressing block 22 can swing by the second swinging shaft 20 disposed through the pressing operating member 14 in parallel with the swinging shaft 16. Is placed. And the floating guide 26 which consists of an insulating material with respect to the pin block 24 which consists of an insulating material can approach-separate linearly in the substantially rocking direction of the front end side of the press operation member 14, and the distance of a separation direction is regulated, Is placed. In addition, the wiring board 28 is fixed by the screw 28a on the opposite side to the floating guide 26 of the pin block 24, and this wiring board 28 is made into the base member 10 side, and the pin block 24 is carried out. ) And the wiring board 28 are fixed to the base member 10 by screws 24a. Then, the engaging support portion 26f protrudes from the floating guide 26, and the engaging projection 14a protrudes from the pressing operation member 14 to the engaging support portion 26f in the opening state of the pressing operation member 14. The engaging projection 14a is formed to be coupled. Thus, when the pressing operation member 14 is in the open state, the floating guide 26 is separated from the pin block 24 and the movement to the pin block 24 side is restricted. In addition, when it is in the opening state of the press operation member 14, the rear end side contacts the hinge member 12, fluctuation | variation is regulated, and the to-be-contacted part of the hinge member 12 acts as a control part.

The floating guide 26 with respect to the pin block 24 is linear in the up-down direction of the figure in FIG. 1 and FIG. 3 as the front end side of the press operation member 14 swings between an open state and the pressurization state which closed it. You can move to. Therefore, the linear shaft 30a is provided in the pin block 24 in the up-and-down direction, and the linear cylinder member 30b into which the linear shaft 30a is slidably moved in the axial direction is installed in the floating guide 26. This linear movement is realized by the linear guide 30 which is arrange | positioned in the direction and consists of these linear shafts 30a and the linear cylinder member 30b. Moreover, the floating pin 32 which has the expansion part in the both ends in the up-down direction with respect to the pin block 24 and the floating guide 26 is arrange | positioned through. The distance between the expansion parts of both ends can be adjusted by the screwing of the adjustment screw 32a provided in the one end side. In addition, a floating spring 34 fitted to flow to the floating pin 32 is compressed between the pin block 24 and the floating guide 26 to separate the floating guide 26 from the pin block 24. Elastic pressing in the direction. Thereby, by the adjustment of the floating pin 32, the distance which the floating guide 26 can separate from the pin block 24 is arbitrarily regulated, and also by the elasticity in which the floating spring 34 was compressed and installed, The floating guide 26 is in a state where the floating guide 26 is separated from the pin block 24 in the opening state of the pressure operating member 14.

The floating guide 26 is provided with a board mounting surface 26a on which the test substrate 36 is mounted, and a guide hole for fitting and inserting the test side connector 38 disposed on the test target 36. A 26b penetrates through the substrate mounting surface 26a. The inner circumferential wall of the guide hole 26b is brought into contact with the outer circumferential wall of the inspected connector 38 so as to position the inserted inspected side connector 38. In addition, nothing is provided in the board | substrate mounting surface 26a around this guide hole 26b, and the structure which regulates the position so that the mounted board | substrate to test | inspected 36 may be positioned is provided, and it has a plane big enough. Moreover, the recessed part 26c is provided in the surface of the pin block 24 side of the back surface of the board | substrate mounting surface 26a centering around the guide hole 26b formed through. The substrate mounting surface 26a is adjusted by cutting or the like so that the bottom surface of the recess 26c and the thickness of the substrate mounting surface 26a, that is, the depth of the guide hole 26b coincide with the height of the connector 38 under inspection. Is formed. Further, reinforcing ribs 26d are provided inside both ends of the substrate mounting surface 26a to increase the mechanical strength.

The pin block 24 is made by integrating the lower pin block 40 and the upper pin block 42 by a spring 42b, the upper pin block 42 is provided with a convex portion 42a facing upwards, The pin block 24 fitted to the recess 26c of the floating guide 26 and the floating guide 26 are configured to be relatively positioned. In addition, a plurality of probe holes 46 penetrating in the vertical direction are formed in the lower pin block 40 and the upper pin block 42. Then, an insertion hole 50 is formed through the lower block 40 and the upper block 42 in the vertical direction and into which the positioning block 48 made of an insulating material is inserted. The positioning block 48 is also composed of the lower positioning block 48a and the upper positioning block 48b so as to be properly integrated, and a plurality of probe holes 52 penetrating in the vertical direction are formed in a row. The positioning block 48 is adjusted so that the position of the probe hole 52 in the insertion hole 50 is appropriate between the lower pin block 40 and the probe hole 46 formed in the upper pin block 42. By means of a cylindrical positioning pin 56. In addition, the positioning block 48 in the insertion hole 50 can be moved only in the direction for adjusting the distance between the probe holes 46 and 52, and is set so as not to move in the direction orthogonal to this. In addition, the probe holes 46 and 52 are provided with a constriction part at the upper end part, and can insert the probe 54 appropriately from the lower side, and are formed so that it may not protrude upwards. The pitch at which the probe holes 46 and 52 are formed is, of course, formed in accordance with the pitch P of the terminal 38a of the connector 38 under inspection. Further, the distance d between the probe hole 52 of the positioning block 48 and the probe hole 46 of the lower pin block 42 is the distance d between the two rows of the terminal 38a of the connector 38 to be inspected. It is also appropriately adjusted to correspond to. In addition, the probe 54 is inserted into the probe holes 46 and 52 at an appropriate number from the lower side with the appropriate number of probes 54 in accordance with the terminal 38a of the connector under inspection 38.

Moreover, the wiring board 28 is arrange | positioned from the lower side with respect to the pin block 24 in which the probe 54 was inserted in the probe hole 46 and 52, and is fixed and integrated by the screw 28a from the lower side. By fixing the wiring board 28, the probe 54 does not escape from the probe holes 46 and 52. And the pin block 24 to which this wiring board 28 was fixed is fixed to the base member 10 by the screw 24a from the upper side. In addition, the base member 10 may be suitably fixed with the fixing screw 10b beforehand by the inspection jig | tool etc. which are not shown in figure. Therefore, the flange 38 of the probe 54 inserted into the probe holes 46 and 52 can be brought into contact with the terminal 38a of the connector 38 to be tested shown in FIG. 8. . In addition, as shown in FIG. 10, the terminal pattern 28b provided on the wiring board 28 is formed long in the moving direction so that the flanger of the probe 54 can be contacted even when the positioning block 48 moves. have.

In addition, in the pressing operation member 14 which is arrange | positioned so that the hinge member 12 can rock, the movement of a swing direction is restrict | limited by the hinge member 12 in an opening state. The engaging projection 14a and the engaging support portion 26f described above are formed in such a state that the movement in the swinging direction in the opening state is restricted. And the rib member 12a is provided in the hinge member 12, as shown in FIG. 13, and it acts to press the wiring board 28 to the base member 10 side from the top, and the wiring board 28 acts as a base member ( 10) It is regulated to emerge from.

The pressing operation member 14 is provided with a hole 14c and an adjusting hole 14d toward the linear guide 30 and the floating pin 32, respectively. In addition, the hole 26e is formed in the floating guide 26 toward the screw 24a for fixing the pin block 24 to which the wiring board 28 is fixed to the base member 10. Moreover, the tip upper part of the press operation member 14 is formed in the chamfering inclined surface 14b. The external dimensions of the first embodiment of the relay connector of the present invention are 27 mm in height, 26 mm in width, 60 mm in length, and can be inspected by hand.

In such a configuration, the pressing operation member 14 is swinged to open the hole against the elasticity of the pressing spring 18, and the test subject 36 is disposed on the substrate mounting surface 26a of the floating guide 26. The connector 38 to be inspected is fitted into the guide hole 26b. The insertion of the inspection-side connector 38 is performed by fitting into the guide hole 26b. Here, the force for determining any position does not act on the inspected substrate 36 itself, and the force for shifting the position of the inspected side connector 38 laterally with respect to the inspected substrate 36 does not act. . While the pressing operation member 14 is held in the open state, the engaging projection 14a of the pressing operation member 14 is engaged with the engaging support portion 26f of the floating guide 26, and the floating guide 26 is Since it is separated from the pin block 24, it does not inadvertently move to the pin block 24 side. Therefore, when the work to which the side to be inspected connector 38 is inserted and inserted into the guide hole 26b is in full swing, the floating guide 26 is moved downwards, and with respect to the side to be inspected 38 with an improper posture. There is no fear that the probe 54 may come in contact and damage either of the connector 38 to be inspected or the probe 54. And when the pressurizing operation member 14 is closed by the front end side by the elasticity of the pressurizing spring 18, and it will be in a pressurized state, the floating guide 26 will move linearly to the pin block 24 side by the linear guide 30. The flanger of the probe 54 is in contact with the terminal 38a of the connector 38 under test. At this time, the concave portion 26c of the floating guide 26 and the convex portion 42a of the pin block 24 are fitted so that the relative positioning of the floating guide 26 and the pin block 24 is surely established. Is done. As a result, the positioning of the inspected connector 38 is performed with respect to the pin block 24, and the positioning of the terminal 38a is performed by the probe 54. Moreover, the elasticity which makes the pressing operation member 14 of the pressing spring 18 pressurized is set larger than the elasticity which isolate | separates the floating guide 26 of the floating spring 34 from the pin block 24, of course. In addition, since the depth of the guide hole 26b of the floating guide 26 is set to match the height of the inspected connector 38, the pin of the inspected connector 38 fitted into the guide hole 26b is inserted. The surface on the side of the block 24 is in the same plane as the bottom of the recess 26c, and the probe 54 is disposed so that the protruding height of the flanger is appropriate based on the bottom of the recess 26c. The flanger of the probe 54 can be contacted with the terminal 38a of the connector under inspection 38 with appropriate elasticity.

The pressing operation member 14 is configured to be able to swing in an open state and a pressurized state by the swing shaft 16, and its structure is relatively simple. Moreover, since the pressurizing block 22 is provided in the front end side of the press operation member 14 by the 2nd oscillation shaft 20, this press block 22 makes the floating guide 26 pin pin 24 Can be pressed precisely toward the approach direction.

However, in order to correspond the relay connector of the present invention to the inspection side connector 38 having various other dimensions, first, the size and depth of the guide hole 26b of the floating guide 26 are determined according to the inspection side connector 38. Adjust the setting accordingly. The depth of the guide hole 26b can be adjusted by appropriately cutting the substrate mounting surface 26a. In addition, also on the pin block 24 side, by setting the fixed position of the positioning block 48 appropriately in the insertion hole 50, the distance between the two rows of probe holes 46 and 52 can be set as the connector 38 to be tested. The distance d between the two-column terminals 38a is matched. This can be done by appropriately forming the position of the hole into which the positioning pin 56 is inserted. It goes without saying that the probe 54 is inserted so as to face the terminal 38a of the connector under inspection 38 with respect to the probe holes 46 and 52. As described above, the operation for the correspondence of the relay connector of the present invention to the connector 38 to be inspected in various different dimensions is relatively simple if each member just before final processing is prepared in advance. You can respond quickly.

The distance from which the floating guide 26 deviates from the pin block 24 in the separation direction can be arbitrarily adjusted by the floating pin 30, but the floating guide 26 deviates from the pin block 24 in the separation direction by use. When the distance is changed, the tool may be appropriately inserted from the adjustment hole 14d formed in the pressing operation member 14 to adjust the screw engagement insertion state of the adjustment screw 32a of the floating pin 32. Moreover, when the probe 54 is damaged and replaced, the hole 26e which removed the hinge member 12 from the base member 10 in the state which the press operation member 14 adhered, and formed in the floating guide 26 was carried out. The tool 24 is removed from the base member 10. In addition, the removed pin block 24 faces the wiring board 28 up to remove the screw 28a, and the wiring board 28 is removed from the pin block 24. Then, only the probe 54 that is damaged and needs to be replaced can be removed from the probe holes 46 and 52 and replaced.

Although the wiring board 28 is fixed to the pin block 24 by the screw 28a, it may be bent by the heat of soldering etc., and thereafter, there exists a possibility that the rear end side may become a floating state from the base member 10 after that. have. Therefore, the rib 12a provided in the hinge member 12 is formed so that the wiring board 28 may be pressed firmly toward the base member 10 side. In addition, when the board | substrate under test 36 is a camera module, the CCD camera element 58 is arrange | positioned at the other end side of the board | substrate 36 to test | inspection, ie, the opposite side to which the connector under test | inspection side 38 was provided. In addition, the positions where the inspection-side connector 38 and the CCD camera element 58 are arranged may be relatively close to each other as shown in FIG. Thus, by forming the tip outer side of the floating guide 26 side of the pressing operation member 14 into the chamfered inclined surface 14b, the upper field of view of the CCD camera element 58 is large and wide open, and any obstacles in the field of view are prevented. Without this, the lens 62 provided in the inspection apparatus 60 for inspecting this CCD camera element 58 can be opposed.

Next, a second embodiment of the present invention will be described with reference to Figs. Fig. 15 is a side view of the pressurized state of the second embodiment of the relay connector of the present invention. 16 is a longitudinal cross-sectional view of FIG. 15. 17 is a side view of the open state of FIG. 15. 18 is a longitudinal cross-sectional view of FIG. 17. 19 is an exploded perspective view of FIG. 15. FIG. 20 is an enlarged vertical sectional view of a main portion in which a substrate to be inspected is inserted into an open state in the second embodiment; FIG. Fig. 21 is an enlarged vertical sectional view of a main portion of the second embodiment in which the substrate to be inspected is inserted and pressed; In FIGS. 15-21, the same code | symbol is attached | subjected to the thing same as or equivalent to the member shown in FIGS. 1-14, and the overlapping description is abbreviate | omitted.

15 to 21, the relay connector of the second embodiment of the present invention is configured as follows. Substrate mounting surface on which the floating guide 74 made of an insulating material is provided on the front end side of the base member 70 by the linear guides 72 and 72 provided on the base member 70 with respect to the base member 70 made of an insulating material. It is arrange | positioned so that contact separation in the perpendicular direction with respect to 70a is possible. Moreover, the pin block 24 is arrange | positioned and fixed to the front end side of the press operation member 76 which consists of an insulation material by the wiring base 28, and the hinge block 78 which consists of an insulation material is provided on the rear end side. The arrangement is fixed by vis etc. And the 1st oscillation shaft 80 provided in the base member 70 is penetrated through the hinge block 78, and the press operation member 76 is arrange | positioned so that it can oscillate. Here, the pin block 24 is set to the position toward the floating guide 74 disposed on the base member 70. In addition, the pressing springs 82 and 82 are compressed and provided between the hinge block 78 and the base member 70, and the pin block 24 is elastically pressed in the direction which contacts the floating guide 74. As shown in FIG. Moreover, the lever member 86 is arrange | positioned in the base member 70 so that the lever member 86 can rock by the 2nd rocking shaft 84 arrange | positioned in parallel with the 1st rocking shaft 80. FIG. One end of the lever member 86 is coupled to the engaging recess 74c of the floating guide 74, and the other end of the lever operating member 76 swings the pin block 24 in the separation direction from the floating guide 74. ), The lever member 86 is rocked by being pressed by the hinge block 78. Moreover, the lever press spring 88 is compressed and installed between the lever member 86 and the base member 70, and the floating guide 74 is elastically pressed in the direction which contacts the base member 70. As shown in FIG. Moreover, the chamfering inclined surface 76a is provided in the front-end | tip outer side of the side where the pin block 24 of the press operation member 76 is arrange | positioned.

On the board | substrate mounting surface 70a of the base member 70, the board | substrate positioning recessed part 70b which has the shape of the insertion side front-end | tip part of the board | substrate 36 to test is provided from the edge part. The width | variety of the edge part side of this board | substrate positioning recessed part 70b is extended to taper shape, and insertion of the board | substrate 36 to be tested is made easy. The substrate positioning concave portion 70b is regulated to be laterally shifted from the insertion dimension so that the inspected side connector 38 disposed upward on the inspected substrate 36 positioned relative to the base member 70. And a guide hole 74a in which the inspection-side connector 38 can be fitted into the floating guide 74. And the recessed part 74b is provided in the surface by the pin block 24 side of the floating guide 74 centering around this guide hole 74a. Here, the depth of the guide hole 74a is formed so that it may correspond with the height of the to-be-tested connector 38. The structure of the pin block 24 is the same as that of the first embodiment, but in that the probes 54, 54... Are arranged on the pressing operation member 76 so as to protrude toward the floating guide 74 side, the first embodiment. It is different from the example. In addition, the convex part 42a fitted to the recessed part 76b provided in the floating guide 76 is provided in the pin block 24 similarly to 1st Example.

In the second embodiment having such a configuration, when the rear end side hinge block 78 of the pressing operation member 76 is pressed against the elasticity of the pressing springs 82 and 82, the pressing operating member 76 swings. The pin block 24 on the tip side is moved in the separation direction from the base member 70. Accordingly, the other end of the lever member 86 is pressed against the hinge block 78 to oscillate against the elasticity of the lever pressing spring 88, and the floating guide 74 having one end of the lever member 86 engaged thereto is engaged. It is moved from the base member 70 in the separation direction, thereby becoming an open state. Thus, as shown in FIG. 20, the inspection target substrate 36 is inserted between the base member 70 and the floating guide 74, and the positioning thereof is performed by the substrate positioning recess 70b. Here, the test | inspection side connector 38 is a state arrange | positioned toward the floating guide 74. FIG. When the pressurizing operation member 76 is released in such a state, the pressurizing operation member 76 is swung by the elasticity of the pressurizing springs 82 and 82, and the pin block 24 at the front end side causes the floating guide 74 to float. At the same time, the lever member 86 also swings due to the elasticity of the lever pressing spring 88 so that the floating guide 74 is moved to contact the base member 70. Thus, the inspected side connector 38 disposed on the inspected substrate 36 is inserted into the guide hole 74a of the floating guide 74 and inserted into the terminals 38a, 38a of the inspected connector 38. The probes 54, 54... Of the pin block 24 are in contact with each other to make electrical connections.

In this second embodiment, when the base member 70 is disposed below, the inspected side connector 38 can be inspected in a state in which the inspected side connector 38 is disposed above the inspected substrate 36. Then, it is regulated that the substrate positioning concave portion 70b provided on the substrate mounting surface 70a of the base member 70 laterally shifts the insertion dimension of the substrate under test 36 to the base member 70. Positioning of the inspection target substrate 36 is performed with respect to the above. And since the floating guide 74 is arrange | positioned so that the linear guide 72, 72 can contact and isolate in the vertical direction with respect to the board | substrate mounting surface 70a, the test | inspection side connector arrange | positioned at the board | substrate 36 to be tested. The guide hole 74a of the floating guide 74 is relatively positioned with respect to (38), and the inspection-side connector 38 is precisely inserted into the guide hole 74a by the approach and contact of the floating guide 74. Fit is inserted. Here, since the floating guide 74 is approach-separated in the vertical direction with respect to the board | substrate mounting surface 70a, when the to-be-tested connector 38 fits and is inserted in the guide hole 74a, the to-be-tested connector 38 is laterally connected. Does not work, and the force which shifts the side to-be-inspected connector 38 to the side with respect to the board | substrate 36 to side does not act | work. Moreover, the press operation member 76 is comprised so that it can rock with respect to the base member 70, and its structure is simple. Moreover, when the board | substrate 36 to be tested is inserted and the pressurization operation member 76 is released, the pressurized state which pressed the pin block 24 to the test | inspection side connector 38 by the elasticity of the press spring 82, 82 is carried out. It does not require press operation during measurement, and the operation is easy. In addition, when the pressing operation member 76 is pressurized and rocked, the floating guide 74 moves in interlocking direction in a direction to be separated from the base member 70 in accordance with the rocking, so that the insertion of the substrate under test 36 is performed. It is easy. In addition, while the pressing operation member 76 is being pressurized, by the action of the lever member 86, the floating guide 74 can be reliably regulated to move to the base member 70 side.

In addition, in the 2nd Example, although the floating guide 74 is restrict | limited not moving to the base member 70 side by the lever member 86 in the opening state which has pressed the press operation member 76, It is not limited, The spring which elastically presses the floating guide 74 in the separation direction from the base member 70 is compression-installed between the floating guide 74 and the base member 70, and the press operating member 76 is an opening state. In this case, the elasticity of the spring causes the floating guide 74 to move in the separation direction from the base member 70 so as to allow the insertion of the inspected substrate 36 between the floating guide 74 and the base member 70. You may also do it.

BRIEF DESCRIPTION OF THE DRAWINGS The side view of the pressurized state in the 1st Example of the relay connector of this invention.

2 is a plan view of FIG.

3 is a side view of the open state of FIG.

4 is an exploded perspective view of FIG. 1;

5 is an exploded perspective view of the upper and lower pin blocks and the floating guide.

6 is an exploded perspective view of the pin block;

7 is an exploded perspective view of the lower pin block, the wiring board, and the base member.

Fig. 8 is an external perspective view of an inspected side connector provided on an inspected substrate inspected by the relay connector of the present invention.

9 is a longitudinal cross-sectional view of the pin block.

10 is a diagram showing a terminal pattern provided on a wiring board.

11 is an exploded perspective view of the pressing operation member, the hinge member, and the base member.

12 is a sectional view seen from arrow A-A of FIG. 2;

FIG. 13 shows a structure in which a wiring board is pressed against a base member by ribs provided on the hinge member, FIG. 13A is a side view with a part removed, and FIG. 13B is a rear view.

It is a figure explaining the effect | action by which the front end part of a press operation member was removed in the chamfer-shaped inclined surface.

Fig. 15 is a side view of the pressurized state of the second embodiment of the relay connector of the present invention.

16 is a longitudinal sectional view of FIG. 15;

17 is a side view of the open state of FIG. 15;

18 is a longitudinal cross-sectional view of FIG. 17;

19 is an exploded perspective view of FIG. 15.

Fig. 20 is an enlarged longitudinal sectional view of a main portion of a second embodiment in which a substrate to be inspected is inserted into an open state;

Fig. 21 is an enlarged vertical sectional view of a main part of the second embodiment, in which the substrate to be inspected is inserted and pressed;

<Explanation of symbols for the main parts of the drawings>

10, 70: base member 12: hinge member

12a: rib 14, 76: pressing operation member

14a: engaging projection 14b: inclined surface

14d: adjusting hole 16: swing shaft

18, 82: pressure spring 20: second swing shaft

22: pressure block 24: pin block

26, 74: floating guides 26a, 70a: substrate mounting surface

26b, 74a: guide hole 26c, 74b: recessed part

26f: coupling support 28: wiring board

28a: screw 28b: terminal pattern

30, 72: linear guide 30a: linear shaft

30b: linear cylinder member 32: floating pin

32a: adjusting screw 34: floating spring

36: inspection board 38: inspection side connector

38a: Terminal 40: Lower Pin Block

42: upper pin block 42a: convex portion

46, 52: probe hole 48a: lower positioning block

48b: upper position adjusting block 50: insertion hole

54 probe 56 positioning pin

58: CCD camera element 60: inspection device

62 lens 70b substrate positioning recess

74c: engaging recess 78: hinge block

80: first swing shaft 84: second swing shaft

86 lever member 88 lever pressure spring

Claims (15)

A relay connector which connects a probe to an inspection-side connector terminal arranged on a substrate to be electrically connected to a measuring device. A floating guide made of an insulating material can be separated from a pin block made of an insulating material and elastically pressed in a separation direction. And a guide hole for fitting and positioning the inspected connector onto the floating block toward the pin block side in the floating guide, and in the pin block toward the inspected connector terminal fitted into the guide hole. The probe is arranged with the approach separation direction of the floating guide in the axial direction, and the opening state allows the inserting of the connector to be inspected into the guide hole of the floating guide and the test piece to be inserted into the floating guide. 4 pin connector A relay connector comprising a pressurizing operation member that is operated in a pressurized state pressed on the block side. 2. The floating guide according to claim 1, wherein the engaging projection is provided on the pressing operation member, the engaging support is provided on the floating guide, and the engaging projection is engaged with the engaging support in the opening state of the pressing operation member. And a relay connector configured to restrict movement to the pin block side. The said opening state and the said pressurization state of Claim 1 by the oscillation axis arrange | positioned at the surface parallel to the surface which faces the said pin block side of the said to-be-tested connector inserted into the said guide hole. A relay connector, which is installed so as to be able to swing and arranged so as to be able to swing the pressing block by a second swing shaft parallel to the swing shaft on the front end side that presses the inspected connector. 2. The floating guide of claim 1, wherein a floating pin having extension portions at both ends is disposed through the floating guide and the pin block in an approach separation direction of the floating guide so that the floating guide is separated from the pin block by the extension portions at both ends. Regulating the distance to move in the direction, the relay connector characterized in that the floating spring is inserted into the floating pin so as to flow and installed compression between the floating guide and the pin block. The said floating pin adjusts the distance which can be moved to the said separation direction by the adjustment spring screwed to the one end side, The adjustment pin forms the adjustment hole in the said press operation member toward the said adjustment spring, and is connected from the outside. Relay connector, characterized in that configured to adjust the adjustment spring. The board | substrate mounting surface of the said floating guide which fits and inserts the said connector under test | inspection into the said guide hole toward the said pin block side, The plane larger than the said test | inspection board | substrate is formed, The said test | inspection side connector And the test plate is not regulated in any position in a state where the fitting is inserted into the guide hole. The said engaging projection is couple | bonded with the said engagement support part in a state in which the restricting part which regulates the rocking | fluctuation in the said opening state side is provided in the said pressure operation member which can be rocked, and the said press operation member is regulated by the said control part. Relay connector, characterized in that configured to. A relay connector for electrically connecting a probe to a tester-side connector terminal arranged on a test target board and electrically connecting the probe to the tester, The floating guide made of the insulating material is arranged to be separated from the base member made of the insulating material, and the connector to be inspected is fitted to the floating guide while the substrate to be inspected is inserted between the base member and the floating guide. A guide hole for inserting and positioning, inserting the floating guide into the base member, arranging a pressing operation member so that the floating guide side can be separated therefrom, and an insulating material toward the floating guide toward the pressing operation member. A pin block comprising: a probe disposed on the pin block such that the pin block is connected to the inspected connector terminal inserted into the guide hole in a state where the pin block is connected to the floating guide, and the pin block From floating guide The floating guide is separated from the base member in association with the operation of the pressing operation member in a retracting direction, and the opening state of the floating guide allowing the insertion of the substrate under test between the base member and the floating guide. And the press manipulation member is operated in a pressurized state in which the pin block is pressed against the inspection-side connector side fitted into the guide hole. 9. A substrate positioning recess according to claim 8, wherein the substrate positioning concave having the shape of the insertion side front end portion of the substrate under test is provided on the substrate mounting surface provided in the base member toward the guide hole of the floating guide. And the insertion position of the test target board and the lateral shift by the board positioning recess, so as to position the test target board. 9. The relay connector according to claim 8, wherein the floating guide is guided to a linear guide provided in the base member, and configured to be in contact with and separated in a vertical direction with respect to the substrate mounting surface of the base member. The pressurizing member according to claim 8, wherein the pressurizing operation member is arranged to be swingable so that the floating guide side is approached and separated from the base member, and the pressurizing means is elastically pressed in a direction approaching the floating guide side of the pressurizing operation member. And a pressurizing spring is provided between the operation member and the base member. 9. The relay connector according to claim 8, wherein in the relay connector, the pressing operation member is arranged to swing so that the floating guide side is separated from the base member, and a lever member is disposed with respect to the base member. It is arrange | positioned so that it can rock to the oscillation shaft parallel to a coaxial, the one end part of the said lever member is couple | bonded with the said floating guide, and the other end member is pressed by operation of the said press operation member, The said floating guide side of the said press operation member And the floating guide swings away from the base member in the separating direction so as to be in the opening state as the swinging guide moves from the base member in the separating direction. The relay connector according to claim 1 or 8, wherein the depth of the guide hole formed in the floating guide is made to match the height of the connector under test. The said recessed part of Claim 1 or 8 provided with the recessed part in the surface of the said pin block side of the said floating guide, and forming the convex part which fits into the said recessed part in the said floating guide side surface of the said pin block. And the convex portion, so that the floating guide and the pin block are relatively positioned. The relay connector according to claim 1 or 8, wherein the tip outer side portion of the pressing operation member on the floating guide side is formed as a chamfered inclined surface.

Images