JP2010145419A - Feed/discharge testing device using clip for current carrying - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a testing device for feed/discharge for simultaneously and automatically testing many electronic components using a clip for current carrying. <P>SOLUTION: This testing device for feed/discharge includes an electronic component tray for projecting and setting an electrode of an electronic component, the clip for current carrying disposed so that it faces the electrode of the electronic component, a cylinder for a wedge object for back-and-forth moving the wedge object between clip objects so as to open or close the gap between a pair of contact terminals of the clip for current carrying, and a cylinder for the clip for current carrying for back-and-forth moving the clip for current carrying and the wedge object integrally to the electrode side of the electronic component. The cylinder for the clip for current carrying includes an upper cylinder for back-and-forth moving the clip for current carrying and the wedge object, and a lower cylinder for temporarily stopping the moving-back operation of the upper cylinder with a slight stroke. The pair of contact terminals of the clip for current carrying slide the electrode of the electronic component by pressure contact. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention is connected to the + and − electrodes of an electronic component (for example, a card-type secondary battery or an electric double layer capacitor) to charge / discharge the electronic component or detect signals from the + and − electrodes. Thus, the present invention relates to a power supply / discharge test apparatus using a current-carrying clip for testing the electronic component.

  In general, as shown in FIGS. 9 and 10, a general electrode 21 of an electronic component 20 such as a card-type secondary battery is formed by a positive electrode 22 and a negative electrode 23 projecting from one end of the electronic component 20. Aluminum is used for the + electrode 22 and nickel is used for the − electrode 23, both of which are rectangular in shape and about 80 μm in thickness.

Conventionally, such supply / discharge and signal detection from the + electrode 22 and the − electrode 23 of the electronic component 20 are performed by a method using a contact pin 24 as shown in FIG. 9 or a crocodile clip 26 as shown in FIG. The method by was used.
Among them, in the method using the contact pins 24 as shown in FIG. 9, the signal detection is performed by pressing a plurality of contact pins 24 implanted on the insulating board 25 against the + electrode 22 and the − electrode 23. The number of contact pins 24 to be used and the size of the pin diameter are selected according to the purpose of use such as the amount of supply / discharge of 20 and the amount of current detected from the electronic component 21.
Further, as shown in FIG. 10, in the method of performing supply / discharge by sandwiching the + electrode 22 and the − electrode 23 of the electronic component 20 with the alligator clip 26 or the method of detecting the signal, the alligator clip 26 is used. The positive electrode 22 and the negative electrode 23 are sandwiched by the clip portion 28 having a sawtooth shape.

JP-A-6-5320 Japanese Patent Laid-Open No. 3-98273

When the plurality of contact pins 24 are pressed and contacted with the electrodes 21 as shown in FIG. 9 to perform supply / discharge and signal detection of the electronic component 20, the tip portion 29 of the contact pin 24 has a protruding shape. In particular, even if a thin plate-like electrode 21 has a flat member on the back surface, scratches, irregularities, and the like are generated on the surface of the electrode 21. For this reason, after the test with the contact pin 24, there has been a problem that processing such as assembling of electronic parts and connection with other parts becomes difficult.
On the other hand, as shown in FIG. 10, when the electrode 21 is sandwiched between the alligator clip 26 and connected, at least two alligator clip clips 26 for supply and discharge and alligator clip clips 26 for signal detection are used. I needed it. Further, since the clip portion 28 of the alligator clip 26 has a sawtooth shape, more scratches and irregularities are generated on the surface of the electrode 21 than when the contact pin 24 is used. For this reason, there is a problem that it becomes difficult to process the electronic component 20 even after the test with the alligator clip 26.

  Further, in the contact pin 24, only the protruding tip portion 29 is in contact with the electrode 21, and in the alligator clip 26, the protruding portion of the clip portion 28 is in contact with the electrode 21. It was only. That is, the electrode 21 and the contact pin 24 or the alligator clip 26 were all in contact by point contact. For this reason, there is a problem that it cannot cope with a large current of the electronic component, and the contact resistance increases, so that correct supply / discharge and signal detection cannot be performed.

  An object of the present invention is to provide a power supply / discharge test apparatus that can simultaneously and automatically test a large number of electronic components using a current-carrying clip.

  The present invention relates to an electronic component tray 30 in which an electrode 21 of an electronic component 20 as a test object is protruded and set, and an energization provided facing the electrode 21 of the electronic component 20 set in the electronic component tray 30. A wedge body cylinder that moves a wedge body 34 for moving forward and backward between the clip body 1 and the pair of clip bodies 2 of the energizing clip 1 so that the clip 1 and the pair of contact terminals 18 of the energizing clip 1 are opened and closed. 48, a current-carrying clip cylinder 49 that advances and retreats the current-carrying clip 1 and the wedge body 34 integrally with the electrode 21 side of the electronic component 20. An upper cylinder 51 that advances and retreats the wedge body 34 and a lower cylinder 52 that temporarily stops the retraction of the upper cylinder 51 with a slight stroke. The contact terminal 18 of a pair of lip 1 is characterized in that as allowed to press the sliding electrode 21 of the electronic component 20.

  Since the present invention is configured as described above, the current-carrying clip does not damage the electrode when performing voltage supply / discharge, signal detection, or the like.

In the present invention, an automatic electronic device testing apparatus is formed by using a plurality of the energizing clips.
Accordingly, it is possible to provide a test apparatus that can automatically test an electronic component having a large amount of current that cannot be handled by one energizing clip or a plurality of electronic components.
Further, in the automatic device according to the present invention, two cylinders having different strokes are used to contact the contact terminal and the electrode, and the contact terminal slides on the electrode by a difference in stroke. Therefore, the contact surface between the contact terminal and the electrode can be increased, and a test apparatus that can cope with a larger capacity current can be provided.

In the present invention, by using a normally open type energizing clip, when the electrode is sandwiched between the contact terminals, the contact terminal is closed by only one type of operation of press-fitting a wedge body or the like between the lead wire contact terminals. The electrode can be sandwiched.
Therefore, the operation can be omitted, and labor and time required for the test can be greatly reduced, and the number of tests can be increased.

It is a disassembled perspective view which shows one Example of the clip for electricity supply by this invention. It is a perspective view after the assembly in FIG. It is a longitudinal cross-sectional view of the normally closed type electricity supply clip by this invention. It is a longitudinal cross-sectional view of the normally open type energizing clip according to the present invention. It is a disassembled perspective view which shows one Example of the manual supply / discharge test apparatus using the clip for electricity supply by this invention. It is the front view which carried out the partial cross section for operation | movement description in FIG. It is a disassembled perspective view of the principal part in FIG. It is a disassembled perspective view which shows one Example of the automatic type | mold supply / discharge test apparatus using the clip for electricity supply by this invention. It is a perspective view at the time of using the conventional contact pin. It is a perspective view at the time of using the conventional alligator clip.

  A power supply / discharge test apparatus using a current-carrying clip according to the present invention is set by fixing a fixed case and electrodes of a plurality of electronic components as a test object to protrude downward at a predetermined interval. An electronic component tray for energizing, an energizing grip support case provided in the fixed case so as to be movable up and down, a wedge body mounting frame provided in the energizing grip support case so as to be movable up and down, and the plurality A plurality of energizing clips provided on the energizing grip support case so as to face the electrodes of the electronic components, and provided between the energizing grip support case and the wedge body mounting frame, A wedge body cylinder for moving a wedge body for advancing and retreating between the pair of clip bodies of the energizing clip so that a pair of contact terminals is opened and closed; 3 is provided between the energizing grip support case, and includes an energizing clip cylinder that integrally advances and retracts the energizing clip and the wedge body toward the electrode side of the electronic component, and the energizing clip cylinder includes: It consists of a current-carrying clip and an upper cylinder that advances and retracts the wedge body, and a lower cylinder that temporarily stops the retraction of the upper cylinder with a slight stroke. It is characterized in that the electrodes of the parts are slid in pressure contact.

An energization clip used in the test apparatus for supply / discharge of the present invention will be described with reference to FIGS.
The energizing clip 1 includes two clip bodies 2 and 2, two electrode members 5 and 5 embedded integrally with the clip body 2 when the clip bodies 2 and 2 are molded, a shaft 7, and a torsion spring 13. There are a normally closed type energizing clip 1a shown in FIG. 3 and a normally open type energizing clip 1b shown in FIG. 4 depending on the direction in which the torsion spring 13 is assembled. Hereinafter, each type will be described.

Normally closed clip 1a for energization
1, 2, and 3, the electrode material 5 is made of a thin rectangular conductor, the long side is substantially the same as the length of the clip material 2, and the short side is narrower than the width of the clip body 2. To do. One end of the longitudinal side is used as a lead wire connection terminal 17, and the other end is bent into a semicircle to form a contact terminal 18. In the illustrated example, the lead wire connecting terminal 17 of the electrode material 5 is formed in a plate shape and a small hole is formed as a solder type. However, the present invention is not limited to this, and the lead wire connecting terminal 17 is not limited thereto. May be a crimp type bent into a U-shaped groove.

The two clip bodies 2 are formed by forming insulating members in the shape of selective scissors having the same shape on the left and right, and the specific shapes are as follows.
At the time of forming the clip body 2, the electrode material 5 is embedded in the center of the clip body 2, and the lead wire contact terminal 17 and the contact terminal 18 at both ends of the electrode material 5 are integrally molded so as to protrude from the electrode material 5. .
More specifically, two protrusions 3 and 3 are formed on the upper portion of the clip member 2 in order to protect the lead wire contact terminal 17 of the electrode material 5 and prevent a short circuit. A recess 4 is formed between 3 and 3.
One end of the electrode material 5 is projected from one end of the clip body 2 at the center of the recess 4 to form a lead wire connection terminal 17. Further, a semicircular end portion is projected from the multi-end portion of the electrode material 5 and is wound around the semicircular portion 11 inside the clip body 2 to form the contact terminal 18.

  Two shaft receiving projections 8 and 8 are formed at an interval 12 in the center of the two clip members 2 so that the shafts 7 are inserted into the respective center portions to serve as bearings. Of these shaft receiving protrusions 8, 8, one shaft receiving protrusion 8 is provided on the same surface as one side edge of the clip material 2, and the other shaft receiving protrusion 8 is between the other side edge of the clip material 2. A notch approximately the same as the width of the shaft receiving protrusion 8 is provided as a shaft engaging portion 9. Further, shaft holes 10 and 10 are formed in the center of the shaft receiving projections 8 and 8 so as to be mutually straight.

  The torsion spring 13 is made of a metallic wire. The shape is V-shaped with a central angle of about 60 degrees, only the central part is wound several times to form a coil part 14, and the other parts are straight lines. The diameter of the coil portion 14 is slightly larger than the diameter of the shaft 7.

  The shaft 7 is made of an insulating rod or a metal rod and has a diameter slightly smaller than that of the shaft hole 10. In addition, the shaft 7 is formed with a retaining head 15 that is slightly larger than the shaft hole 10 at one end, and a retaining protrusion 16 that can be inserted but does not come out. To do.

  The clip material 2, the electrode material 5, the torsion spring 13 and the shaft 7 formed as described above are assembled as follows.

  (1) In order to combine two identical clip materials 2 and 2 in which an electrode material 5 is embedded, first, the clip material 2 faces the shaft receiving projections 8 and 8 to each other, and one of the two The shaft receiving protrusions 8 and 8 are made to wait at the interval 12 between the other shaft receiving protrusions 8 and 8 and the shaft receiving portion 9. At this time, the positions of the shaft holes 10 of the two clip bodies 2 and 2 are matched. Here, a part of the interval 12 generated between the shaft receiving projections 8, 8 of the clip members 2, 2 becomes the coil storage portion 19.

  (2) The coil portion 14 of the torsion spring 13 is fitted into the coil housing portion 19. At this time, as shown in FIG. 3, the tip of the torsion spring 13 is directed toward the lead wire connecting terminal 17, so that a normally closed type energizing clip 1 a is obtained.

  (3) The shaft 7 is inserted into the shaft holes 10 and 10 and the torsion spring 13 of the combined clip bodies 2 and 2. The shaft 7 is inserted through the shaft hole 10 and the coil part 14 until the shaft 7 is locked to the retaining head 15. As a result, the retaining projection 16 is exposed to the outside of the shaft receiving projection 8 and is prevented from being detached.

The normally closed type energizing clip 1 a is connected to the electrode 21 of the electronic component 20 by closing the contact terminals 18 of the clip members 2 and 2 with the torsion spring 13.
Further, when the clip bodies 2 and 2 are pinched with the finger 6 and the side opposite to the contact terminal 18, that is, the lead wire connecting terminal 17 side is pressed inward, the lead wire connecting terminals 17 and 17 are incorporated into the torsion spring 13 incorporated therein. The contact terminals 18, 18 on the opposite side are opened against the force.
When performing supply / discharge and signal detection simultaneously, two normally closed type energizing clips 1a, 1a are connected to the same electronic component 20, and one electrode of each normally closed type energizing clip 1a, 1a is connected. The material 5 acts as a power supply / discharge, and the other electrode material 5 acts as a signal detection.

Normally open type energizing clip 1b
The clip material 2, the electrode material 5, the torsion spring 13 and the shaft 7 are similar in material and shape to the normally closed type energizing clip 1a.
However, in the normally open type energizing clip 1b, when the coil portion 14 is assembled into the coil housing portion 19, the tip of the torsion spring 13 is in the opposite direction to that of the normally closed type, that is, the Direct toward the lead wire connection terminal 17 side.

  The normally open type energizing clip 1b created by the above method is normally in an open state without contacting the contact terminals 18 side of the clip bodies 2 and 2. Therefore, the end of the wedge body 34 is inserted between the protruding portions 3 and 3 on the opposite lead wire connecting terminal 17 side. In this state, when the electrode 21 of the electronic component 20 is inserted between the contact terminals 18 and 18 and the wedge body 34 is press-fitted against the torsion spring 13 to open the protrusions 3 and 3, the contact terminal 18 , 18 are closed, and the contact terminal 18 is in contact with the electrode 21 of the electronic component 20. The normally open type energizing clip 1b has the same supply / discharge and signal detection functions as the normally closed type energizing clip 1a.

  Next, an embodiment of a test apparatus that performs a power supply / discharge test by manual operation and a test apparatus that automatically performs a power supply / discharge test using the energization clip 1 according to the present invention will be described with reference to FIGS. . In addition, the above-mentioned normally open type energization clip 1b is used for these test apparatuses.

Example 1 (Testing device by manual operation)
The test apparatus of the first embodiment is for testing electronic components by manual operation. As shown in FIGS. 5 to 7, a current-carrying clip support case 31 is set at the lower part and the test is performed at the upper part thereof. The electronic component tray 30 containing the electronic components 20 for use is set. The energization clip support case 31 is provided in a lower fixed case 32 so as to be freely advanced and retracted.

The detailed configuration of each part will be described below.
For example, as shown in FIG. 9 or 10, the test electronic component 20 is a thin rectangle, and a pair of extremely thin plate-like electrodes 21 (+ electrode 22 and −electrode 23) project on one side. Yes.
The electronic component tray 30 has a shallow concave portion 27 inside the rectangular parallelepiped. A plurality of electronic component insertion openings 36 are formed in a plurality of rows at equal intervals in the recess 27 of the electronic component tray 30. The electronic component insertion port 36 has a shape that can be accommodated with the electrode 21 of the electronic component 20 facing downward, and the electrode insertion port 37 below the electronic component insertion port 36 can insert the electrode 21. The front end of the electronic component 30 protrudes from the bottom of the electronic component tray 30 by at least about 10 mm.

  A shallow wedge mounting frame 33 is loosely fitted in the energizing clip support case 31. The wedge body mounting frame 33 is a rectangular box, has an upper surface open, and has a wedge guide hole 41 for supporting the wedge body support guide rod 38 formed in the bottom plate at equal intervals.

  As shown in FIG. 7, the energization clip support case 31 is a rectangular box, and has an energization support case main body 42 having an open top surface and a bottom hole 44 having a slightly narrower width than the bottom plate on the bottom surface. , And two push-down eaves 43 and 43 formed outwardly from the upper end thereof.

The fixed case 32 includes a fixed case main body 45 and a connector connecting portion 46 for connecting a power source and a detector.
The fixed case main body 45 is a rectangular box and has an upper surface opened. In order to loosely fit the energizing clip support case main body 31 therein, the energization clip support case main body 31 is made slightly larger than the energizing clip support case main body 31. Further, a wedge guide hole 41 and a connector mounting hole 61 of the wedge body guide rod 38 are provided on the bottom surface, and the wedge body guide rod 38 is planted at both ends of the bottom surface. Then, a coil-like pusher is provided between the bottom surface of the fixed case main body 45 and the lower side of the bottom surface of the push-down collar portion 43 of the energizing clip support case 31 so that the wedge body mounting guide bar 38 is loosely fitted. A lifting spring 35 is interposed.
On the upper surface of the connector connection portion 46, several rows of connector connection ports 47 for attaching a plurality of connectors 62 are formed at equal intervals.

In the energization clip support case main body 42 of the energization clip support case 31, a normally open type energization clip 1b is accommodated in which two shafts are paired and one shaft 7 is shared. Seven portions are mounted on shaft holes 63 on both side plates of the energizing clip support case main body 42, and a large number of sets are attached at regular intervals. The contact terminal 18 of the normally open type energizing clip 1b is arranged so that a part of the contact terminal 18 protrudes from the upper surface opening of the energizing clip support case 31 and the lead wire connecting terminal 17 side faces downward.
The wedge body 34 is made of an insulating material and has a trapezoidal shape having an inclination that gradually widens on both sides from the distal end portion to the proximal end portion. Further, one wedge body 34 can be press-fitted between the projecting portions 3 and 3 of the energizing clip 1b, which is a pair of two. Further, a wedge body guide bar 38 is integrally formed at the center of the bottom surface of the wedge body 34. The wedge body support guide bar 38 is cylindrical and penetrates the round hole 64 of the wedge body mounting frame 33 and the long hole 44 of the energizing clip support case main body portion 42, and further the wedge guide hole 41 of the fixed case main body portion 45. And is locked by a retaining protrusion 39 at the lower end. A coil spring 40 is interposed between the upper surface of the bottom plate of the fixed case main body 45 and the lower surface of the pressing collar 43.

  In the above-described embodiment, the width of the wedge body 34 is formed wide, and one wedge body 34 can be press-fitted into the current-carrying clip 1b, and the present invention is not limited to this. A single wedge body 34 may be press fit into one energizing clip 1b.

Next, a test method using the manual test apparatus assembled as described above will be described.
Prior to the test, the electronic component tray 30 is placed on the energizing support clip 31, the electronic components 20 are placed one by one in the electronic component insertion slot 36 of the electronic component tray 30, and the tip of the electrode 21 is placed on the electronic component tray 30. It is exposed from the lower end of the electrode insertion opening 37.
Then, the electrode 21 is inserted between the contact terminals 18 and 18 of the retaining protrusion 16 as shown in the left half of FIG.

When the electronic component tray 30 is pushed down in this state, the energizing clip support case 31 moves downward together with the normally open type energizing clip 1b, but the spring 35 has a sufficiently large drag, so the wedge body mounting frame 33 And the wedge body 34 does not move. For this reason, the wedge body 34 is press-fitted between the projecting parts 3 and 3 and the projecting parts 3 and 3 side opens against the torsion spring 13, so that the contact terminals 18 and 18 on the opposite side are closed, and FIG. As in the right half, the electrode 21 is sandwiched and electrically connected by the contact terminals 18 and 18.
In the normally open type energizing clip 1b, when the wedge body 34 bites between the protrusions 3 and 3 and the contact terminals 18 and 18 are brought into close contact with each other, the wedge body 34 also moves down together with the wedge body mounting frame 33. The amount of the wedge body 34 that is caught between the protrusions 3 and 3 is absorbed by the spring 35.

The external power source, detector, etc. connected to the connector 62 of the test apparatus are connected to the lead wire 54, the connector 53, the lead wire connecting terminal 17 of the normally open type energizing clip 1b, and the contact terminal 18, and then the electrode of the electronic component 20. 21 for connecting and discharging electronic components and detecting signals.
Here, when the downward pressing by the electronic component tray 30 is removed, the original state as in the left half of FIG. 6 is restored.

Second embodiment (automatic test equipment)
In the test apparatus of the second embodiment, the electronic component tray 30 is fixed, and the opening and closing of the normally open type energizing clip 1b and the contact terminals 18, 18 of the normally open type energizing clip 1b are automatically opened and closed. The main structure is substantially the same as that of the first embodiment except for a mechanism that automatically moves. That is, as shown in FIG. 8, the electronic component tray 30 is set on the fixed case 32. Further, an energizing clip support case 31 is provided in the fixed case 32 so as to be movable up and down, and a wedge body mounting frame 33 is further provided in the energizing clip support case 31 so as to be movable up and down.
Similarly to the first embodiment, a plurality of electronic components 20 are accommodated inside the electronic component tray 30.
In particular, in the second embodiment, as means for moving the wedge body 34 and the normally open type energization clip 1b, two upper and lower cylinders 51 are provided between the energization clip support case 31 and the fixed case 32. , 52, and a vertically moving clip cylinder 49 is provided. Also, a wedge body cylinder 48 is installed to open and close the normally open type energizing clip 1b.

The detailed configuration of each part will be described below.
The shapes of the electronic component tray 30, the wedge body 34, the wedge body mounting frame 33, the normally open type energization clip 1b, the energization clip support case 31 and the fixing case 32 that store the electronic components 20 are substantially the same as in the first embodiment. It is the same.

A piston 55 and a rod 56 are accommodated in the wedge body cylinder 48, and the cylinder 48 moves up and down by hydraulic pressure or air pressure. The upper end portion of the rod 56 of the wedge body cylinder 48 is connected to the upper end portion of the energizing clip support case 31, and the wedge body cylinder 48 is fixed to the wedge body mounting frame 33. For this reason, when the wedge body cylinder 48 moves up and down, the wedge body 34 also moves up and down, and the normally open type energization clip 1b is opened and closed.
The energizing clip cylinder 49 is formed by directly connecting two cylinders (an upper cylinder 51 and a lower cylinder 52) in the vertical direction.
That is, the upper plate of the lower cylinder 52 and the bottom plate of the upper cylinder 51 are communicated with each other through a through hole, and the rod 56 connected to the piston 55 of the lower cylinder 52 is inserted into the through hole. It faces the lower surface of 55. The stroke S1 of the upper cylinder 51 is set slightly longer (for example, 1 mm) than the stroke S2 of the lower cylinder 52.
The rod 56 connected to the piston 55 of the upper cylinder 51 extends upward through the upper plate, and the upper end penetrates the mounting member 57 fixed to the energizing clip support case 31, and the head 58 of the rod 56. Is locked.
A spring 60 having the same purpose as that of the spring 35 is interposed between the mounting member 57 and the spring support 59 in the middle of the rod 56.

Next, a test method using an automatic test apparatus will be described.
The electronic component 20 is disposed inside the electronic component tray 30.
In the second embodiment, the distance from the lower surface of the bottom plate of the electronic component tray 30 to the upper end of the contact terminal 18 of the normally open type energizing clip 1b is the stroke of the upper cylinder in the energizing clip cylinder 49. It is arranged with a slightly larger space (for example, 1 mm) than S1.

Here, first, a normally open type energizing clip incorporated in the energizing clip support case 31 by simultaneously applying hydraulic pressure, air pressure or the like to the upper cylinder 51 and the lower cylinder 52 in the direction of the solid line and raising them simultaneously. The clip 1b and the wedge body 34 are raised together by S1 (20 mm). Then, the contact terminals 18 and 18 of the normally open type energization clip 1b are raised to a position where the electrode 21 of the electronic component 20 is sandwiched by a gap between them.
At this time, a gap of S1-S2 = 1 mm is generated between the lower surface of the piston 55 of the upper cylinder 51 and the upper end of the rod 56 of the lower cylinder 52.

In this state, when pressure is applied to the wedge cylinder 48 in the direction of the solid line, the piston 55 is fixed and the cylinder 48 is raised. Along with this, the wedge body 34 also rises.
As a result of this rise, the upper portion of the wedge body 34 is press-fitted between the projecting portions 3 and 3 of the normally open type energizing clip 1b, and the line contact terminals 18 and 18 on the opposite side are closed and clamped with the electrode 21 positioned therebetween. And make electrical connections.

With the pressure contacted as described above, pressure is applied to the upper cylinder 51 only in the dotted line direction while the lower cylinder 52 is applied with pressure in the solid line direction and then moved downward.
Then, the upper cylinder 51 is lowered by a stroke difference from the lower cylinder 52, that is, 1 mm, and the contact terminals 18 and 18 and the wedge body 34 of the normally open type energizing clip 1b are also maintained in a clamped state. Move down 1 mm. For this reason, the contact terminals 18, 18 slide on the surface of the electrode 21 by 1 mm.

  As a result, the contact terminals 18 and 18 of the normally open type energizing clip 1b can be more reliably connected to both surfaces of the electrode 21. Therefore, tests such as power supply / discharge and signal detection are performed in a reliable electrical connection state by pressure contact sliding as described above.

After completion of the test, first, pressure in the dotted line direction is applied to the wedge cylinder 48 and lowered. Accordingly, the normally open type energizing clip 1b is separated from the electrode 21 because the wedge body 34 press-fitted between the projecting portions 3 and 3 is lowered and the contact terminals 18 and 18 are opened.
Thereafter, pressure is applied to the upper cylinder 51 and the lower cylinder 52 of the energizing clip cylinder 49 in the direction of the dotted line to lower the energizing clip support case 31.

DESCRIPTION OF SYMBOLS 1 ... Current supply clip, 1a ... Normally closed type current supply clip, 1b ... Normally open type current supply clip, 2 ... Clip body, 3 ... Projection part, 4 ... Recessed part, 5 ... Electrode material, 6 ... Finger, 7 DESCRIPTION OF SYMBOLS ... Shaft, 8 ... Shaft receiving protrusion, 9 ... Shaft receiving engagement part, 10 ... Shaft hole, 11 ... Semicircle part, 12 ... Space | interval, 13 ... Torsion spring, 14 ... Coil part, 15 ... Retaining head, 16 DESCRIPTION OF SYMBOLS ... Locking protrusion, 17 ... Lead wire connection terminal, 18 ... Contact terminal, 19 ... Coil accommodating part, 20 ... Electronic component, 21 ... Electrode, 22 ... + pole, 23 ...- pole, 24 ... Contact pin, 25 ... Insulation Board, 26 ... Alligator clip, 27 ... Recess, 28 ... Clip part, 29 ... Tip part (contact pin), 30 ... Electronic component tray, 31 ... Clip support case for energization, 32 ... Fixed case, 33 ... Wedge body Mounting frame, 34 ... wedge, 35 ... 36 ... Electronic component insertion port, 37 ... Electrode insertion port, 38 ... Wedge body guide rod, 39 ... Retaining protrusion, 40 ... Spring, 41 ... Wedge guide hole, 42 ... Electric clip support case main body, 43 ... Push-down collar, 44 ... elongated hole, 45 ... fixed case body, 46 ... connector connection, 47 ... connector connection port, 48 ... wedge cylinder, 49 ... energizing clip cylinder, 51 ... upper cylinder, 52 ... Lower cylinder, 53 ... Connector, 54 ... Lead wire, 55 ... Piston, 56 ... Rod, 57 ... Mounting member, 58 ... Head, 59 ... Spring support, 60 ... Spring, 61 ... Connector mounting hole, 62 ... Connector 63 ... shaft hole, 64 ... round hole.

Claims (3)

  An electronic component tray that protrudes and sets an electrode of an electronic component as a test object, an energizing clip provided facing the electrode of the electronic component set on the electronic component tray, and a pair of the energizing clip The wedge body cylinder for moving the wedge body for moving forward and backward between the pair of clip bodies of the energizing clip so that the contact terminals of the energizing clip are opened and closed, and the energizing clip 1 and the wedge body are integrated into an electronic component. An energizing clip cylinder that advances and retreats toward and from the electrode side. The energizing clip cylinder temporarily moves the energizing clip and the wedge body forward and backward, and temporarily moves the upper cylinder slightly. It consists of a lower cylinder for stopping with a stroke, and the electrode of the electronic component is slid in pressure contact with a pair of contact terminals of the energizing clip. Sheet discharge test apparatus using a clip.   A fixed case, an electronic component tray that is set on the upper portion of the fixed case, and projects a plurality of electronic component electrodes as a test object to protrude downward at a predetermined interval, and an upper and lower portions inside the fixed case. An energizing grip support case provided movably, a wedge body mounting frame provided on the energizing grip support case so as to move up and down, and the energizing grip support facing the electrodes of the plurality of electronic components. A plurality of energizing clips provided on the case, and the energizing clips provided between the energizing grip support case and the wedge body mounting frame so as to open and close between a pair of contact terminals of the energizing clip. Between the pair of clip bodies and a wedge body cylinder that moves the wedge body to move forward and backward, and the stationary case 3 energizing grip support case, And an energizing clip cylinder for moving the clip and wedge body integrally to the electrode side of the electronic component. The energizing clip cylinder includes an upper cylinder for moving the energizing clip and the wedge body forward and backward, It consists of a lower cylinder that temporarily stops the retreating operation of the cylinder with a slight stroke, and is characterized in that the electrodes of the electronic component are slid in pressure contact with a pair of contact terminals of the energizing clip. Supply / discharge test device using a conducting clip.   In the clip for energization, an electrode material is integrally formed in each clip body made of two insulating members, and one end portion of the electrode material is exposed from one end of the clip body to form a lead wire connection terminal. The other end faces the other end of the clip body and is exposed to form a contact terminal, and the shaft receiving projections at substantially the center of the two clip bodies are engaged with each other, and the shaft is inserted. The torsion spring is interposed in the shaft, and the torsion spring is provided by energizing the contact terminals facing each other in a direction in which the torsion spring is always opened. The supply / discharge test apparatus using a current-carrying clip according to claim 1 or 2, characterized in that it is a normally open type.

Images