JP2004061390A - Method of manufacturing contactor, and contactor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To make easily and inexpensively manufacturable a contactor having an electrically ideal and desired shape. <P>SOLUTION: This manufacturing method of contactor is characterized in that one or more element areas having a shape according to the shape of the manufacturing contactor on one or more first conductive plate base materials and one or more second conductive plate base materials are manufactured in a state of integrally connecting the element areas to the corresponding each of conductive plate base materials in a plurality of places, and a contactor element is manufactured by superposing and adhering the manufactured element areas in the thickness direction by an electric insulating material, and the manufactured contactor element is separated from the first and second conductive plate base materials. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a method of manufacturing a contact and a contact used for a current test of a device under test such as a semiconductor device such as an integrated circuit and a display substrate such as a liquid crystal display panel.
[0002]
[Prior art]
Inspection or testing of the electrical characteristics of a package or molded semiconductor device, particularly an integrated circuit (IC), generally involves testing an electrical connection device such as a test socket or test socket for removably mounting the semiconductor device. It is performed by using it as a device.
[0003]
As one of such electrical connection devices, there is one using a plurality of probes or contacts bent in an arc shape or a J shape (Japanese Patent Laid-Open No. 11-31566).
[0004]
In this conventional technique, each contact has a first contact portion that contacts a lead electrode of a semiconductor device and a second contact portion that connects to a conductive portion (wiring portion) of a substrate.
[0005]
The electrical connection device also includes a plurality of contacts arranged on a plate-shaped cover, that is, a plate-like body, and a common pressing member, that is, an elastic body, arranged at a curved portion of the contact. Is assembled on the substrate.
[0006]
[Problem to be solved]
However, in the above-described conventional technology, since the manufacture of the contacts becomes complicated, it is difficult to easily and mass-produce the contacts having an electrical ideal and desired shape.
[0007]
An object of the present invention is to make it possible to easily and inexpensively manufacture a contact having an electrically ideal and desired shape.
[0008]
[Solutions, actions, and effects]
The method for manufacturing a contact according to the present invention includes the step of forming at least one element region having a shape corresponding to the shape of the contact to be manufactured by using at least one first conductive plate base material and at least one second conductive material. On each of the plate base materials, the element regions are manufactured in a state where they are integrally connected to the corresponding conductive plate base material at a plurality of locations, and the manufactured element regions are overlapped in the thickness direction with an electrically insulating material and adhered. Then, the contact element is manufactured, and the manufactured contact element is separated from the first and second conductive plate base materials.
[0009]
In the contacts manufactured as described above, all the element regions may be used as contact pieces that are in contact with the electrodes of the device under test and the conductive portions of the substrate, or one or more element regions may be tested. The remaining element region may be used as a guard piece connected to the ground or a guard piece for protecting the contact, which is used as a contact piece for contacting the electrode of the body and the conductive portion of the substrate.
[0010]
The operation of manufacturing the element region on each of the first and second conductive plate base materials as described above can be performed using an etching technique. Each of the conductive plate base materials, in particular, the first or second conductive plate base material that is finally brought into contact with the electrode of the test object and the conductive portion of the substrate, such as beryllium, copper and alloys thereof, A conductive metal plate can be used. As a result, by manufacturing a plurality of element regions on each conductive plate base material, it is possible to manufacture a plurality of element regions that are electrically ideal and have a desired shape at low cost.
[0011]
As will be described next, the element regions are located at the same position of the conductive plate base material on the XY coordinates so that the element regions are the same when the first and second conductive plate base materials themselves are overlapped. It is desirable to produce
[0012]
The operation of superposing and bonding the element regions in the thickness direction with an electric insulating material is performed, for example, by applying an electric insulating adhesive to at least the element regions of the first or second conductive plate base material at the time of superposition, and thereafter, This can be performed by overlapping the first and second conductive plate base materials themselves. For this reason, even if a large number of element regions are manufactured on the conductive plate base material, the plurality of element regions of both conductive plate base materials can be accurately and easily overlapped and bonded.
[0013]
The operation of separating the contact element from the conductive plate base material can be performed using an etching technique, a laser processing technique, or the like. Such a separating operation can be performed accurately and easily.
[0014]
As described above, according to the present invention, the element regions are manufactured in a state where a part thereof is connected to the conductive plate base material, and the element regions are overlapped and adhered in that state. A contact having a shape can be easily and inexpensively manufactured.
[0015]
The method of manufacturing a contact may further include a first contact portion, which is in contact with at least an electrode of the device under test, in at least one of the element regions of the first or second conductive plate base material, and a conductivity of the substrate. The method may include performing a polishing process on the second contact portion that is in contact with the portion. By doing so, the polished first and second contact portions become smooth, so that when the first and second contact portions are pressed against the electrodes of the device under test and the conductive portions of the substrate, The first and second contact portions can smoothly slide on the electrodes and the conductive portion.
[0016]
The method for manufacturing a contact may further include: forming one of the first and second conductive plate base materials on the other element region of the first and second conductive plate base materials. Removing the region including the contact portion and the region including the second contact portion from when the element region is manufactured until the element region is separated from the corresponding conductive plate base material. Can be. With this configuration, when the electrical connection device is used, the element region having such a region removed is used as a guard piece, and the remaining element region is brought into contact with the electrode of the device under test and the conductive portion of the substrate. Since the contact piece can be formed as a contact piece, mixing of electrical noise into the contact piece can be suppressed.
[0017]
The method for manufacturing the contact may further include, before the overlapping of the element regions, gold plating on the surface on the non-overlapping side of each element region. In that way, the manufactured contact becomes more electrically ideal.
[0018]
The method of manufacturing a contact further includes the step of manufacturing one of the element regions of the first and second conductive plate base materials from the time of manufacturing the element region, and the method of manufacturing the conductive plate base material corresponding to the element region. Before cutting off from the substrate, at the contact portion that is in contact with the conductive portion of the substrate, it is necessary to divide into a region on the needle tip side and a region on the non-needle tip side that are in contact with the electrode of the DUT. Can be. In this case, the divided element regions are formed into contact pieces that are in contact with the electrodes of the device under test and the conductive portions of the substrate, so that the effective length dimension of the obtained contact (the electrode of the device under test) (A distance between the contact portion of the substrate and the contact portion of the substrate with the conductive portion) is reduced, so that the incorporation of electrical noise into the separated contact piece is significantly reduced.
[0019]
The contact element may be manufactured by overlapping and bonding the element region of the second conductive plate base material to each surface in the thickness direction of the element region of the first conductive plate base material. Good. By doing so, the mechanical strength and electrical characteristics of the obtained contact are further improved.
[0020]
The thickness dimension of one of the first and second conductive plate base materials may be larger than that of the other. By doing so, the element region having a large thickness dimension can be used as a contact piece that is in contact with the electrode of the device under test and the conductive portion of the substrate.
[0021]
The contact according to the present invention is a plate-shaped contact having a first point on the needle tip side to be brought into contact with the electrode of the device under test and a second point on the non-needle tip side pressed by the conductive portion of the substrate. A pair of second element regions each having a first element region and third and fourth positions respectively corresponding to the first and second positions, wherein the first element region is provided via an electrical insulator; It is characterized in that a region is sandwiched between the second element regions and a second element region overlapped with the first element region in the thickness direction.
[0022]
According to the above-mentioned contact, a contact which is electrically ideal and has a desired shape can be manufactured at low cost.
[0023]
One of the first and second element regions may have the first and second portions or the third and fourth portions removed from the other. By doing so, when the electrical connection device is used, the element region from which such a portion has been removed can be used as a guard piece, so that the remaining element region from which such a portion has not been removed can be inspected. By using the contact piece that is in contact with the electrode and the conductive portion of the substrate, it is possible to suppress mixing of electrical noise into the remaining element regions.
[0024]
The first and second element regions each have a J-shape curved at the second and fourth locations, and one of the first and second element regions is At the second location or the fourth location, the area may be divided into the needle tip side area and the non-needle tip side area. By doing so, by making the element region divided into the needle tip side region and the anti-needle tip side region a contact piece that is in contact with the electrode of the device under test and the conductive portion of the substrate, Since the effective length dimension of the contact obtained is reduced, the incorporation of electrical noise into the contact piece area is significantly reduced. Further, the second contact region is divided into the second region on the tip side and the region on the opposite side of the tip, and the second element region is brought into contact with the electrode of the device under test and the conductive portion of the substrate. By using the pieces, the electrical connection between the contact piece and the electrode of the device under test becomes a more stable Kelvin connection.
[0025]
BEST MODE FOR CARRYING OUT THE INVENTION
Referring to FIG. 1, the contact 10 is formed in the shape of a plate-like probe (blade type needle) having a substantially J-shape. For this reason, the contact 10 includes a needle tip 12 on the side to be brought into contact with an electrode of the object to be inspected, a curved portion 14 following the needle tip 12, and a needle rear portion 16 rising from the rear end of the curved portion 14. have.
[0026]
The contact 10 has an arc-shaped concave portion 18 that opens upward by the curved portion 14 and the needle rear portion 16. Therefore, the contact 10 has an inner surface formed by the bending portion 14 and the needle rear portion 16 as an arc surface, and an outer surface of the contact element 20 forming the outer surface of the bending portion 14 also has an arc surface. Have been.
[0027]
The contact 10 has three conductive thin plate-shaped element regions 20, 22, 22 stacked in a sandwich direction in the thickness direction such that the element region 20 is located between the two element regions 22. . Adjacent element regions 20 and 22 are bonded together by a sheet-like electric insulator 24 in which an electrically insulating adhesive or resin melt is solidified.
[0028]
Each of the element regions 20, 22, 22 is manufactured in a J-shape having substantially the same size as the overall shape of the contact 10. Therefore, each element region also includes a needle tip, a curved portion, and a needle rear. In the illustrated example, the thickness dimension of the element region 20 is larger than that of the element region 22, but may be the same.
[0029]
The element region 20 located at the center is a contact piece that contacts the electrode of the device under test, and the element regions 22 located on both sides are guard pieces. Each element region 22 is cut out of the element region corresponding to the region including the first portion contacting the electrode of the inspection object and the region corresponding to the region including the second portion contacting the electrode portion of the substrate. Cut portions 26 and 28 are provided.
[0030]
The contact 10 has a tip of the needle tip 12 as a first contact portion 30 that is brought into contact with an electrode of the device under test. The second contact portion 32 is brought into contact.
[0031]
At least the first and second contact portions 30 and 32 of the element region 20 are polished. As a result, the polished first and second contact portions 30 and 32 become smooth, so that the first and second contact portions 30 and 32 are pressed against the electrodes of the device under test and the conductive portions of the substrate. At this time, the first and second contact portions 30 and 32 slide smoothly with respect to the corresponding electrodes and conductive portions.
[0032]
In the illustrated example, the contact 10 is an ono-type needle whose tip extends in the longitudinal direction of the contact as viewed in plan, but may have another shape.
[0033]
Next, a method of manufacturing the contact 10 will be described with reference to FIGS. In the illustrated example, it is shown that one element region is manufactured in each of the conductive plate base materials to manufacture one contact. In practice, however, a plurality of element regions are fabricated on each conductive plate preform to produce a plurality of contacts.
[0034]
First, as shown in FIGS. 2A and 3, one conductive plate base material 34 and two conductive plate base materials 36 are prepared. Each conductive plate matrix can be a conductive metal plate such as beryllium, copper and their alloys. In the illustrated example, the thickness dimension of the first conductive plate base material 34 is larger than that of the second conductive plate base material 36.
[0035]
Next, as shown in FIG. 2A, a plurality of element regions 20 having a shape corresponding to the shape of the contact to be manufactured are manufactured on the first conductive plate base material 34, and in parallel with this. A plurality of element regions 22 having a shape corresponding to the shape of the contact to be manufactured are manufactured on each second conductive plate base material 36 as shown in FIG.
[0036]
The element regions 20 and 22 are manufactured so as to be integrally connected to the corresponding conductive plate base materials 34 and 36 at a plurality of anchoring points 38, respectively. The element regions 20 and 22 have the same shape as the element regions 20 and 22 when completed on the contact 10, respectively. For this purpose, each element region 22 has cutouts 26 and 28.
[0037]
The element regions 20 and 22 are formed such that the element regions 20 and 22 are located at the same position on the XY coordinates when the first and second conductive plate base materials 34 and 36 are overlapped, respectively. It is manufactured in the same place of the base materials 34 and 36.
[0038]
The operation of forming the element regions 20 and 22 on the first and second conductive plate base materials 30 and 32 as described above can be performed using an etching technique. As a result, using a conductive metal plate as each conductive plate base material, particularly as the first or second conductive plate base material that is finally brought into contact with the electrode of the device under test and the conductive portion of the substrate In addition to manufacturing a plurality of element regions on each conductive plate base material, a plurality of element regions having an ideal shape and a desired shape can be manufactured at low cost.
[0039]
Next, as shown in FIG. 2B, of the element region 20 of the first conductive plate base material 34, at least the first contact portion 30 that is in contact with the electrode of the device under test and the conductive portion of the substrate. Is polished. Thereby, the polished first and second contact portions 30 and 32 are smoothed.
[0040]
Next, at least the surfaces of the element regions 20 and 22 are plated with gold. This makes the element regions 20 and 22 more electrically ideal. However, gold plating may be performed only on the element region used as the contact piece.
[0041]
Next, as shown in FIGS. 4A and 4B, the element regions 20 and 22 are sandwiched so that the element region 20 is located between the two element regions 22, and the adjacent element regions are adjacent to each other. 20 and 22 are glued. Thereby, the contact element 40 is manufactured.
[0042]
When the element regions 20 and 22 are overlapped and bonded, an electrically insulating material 42 such as a resin having an adhesive property or an adhesive is used. The electrically insulating material 42 functions as the sheet-shaped electrical insulator 24 in the completed contact 10.
[0043]
The operation of overlapping and bonding the element regions 20 and 22 is performed by applying an adhesive 38 to at least one element region 20 or 22 of the first or second conductive plate base material 34 or 36 at the time of overlapping, This can be performed by overlapping the first and second conductive plate base materials 34 and 36. Therefore, even if a large number of element regions are manufactured on the conductive plate base material, the plurality of element regions of both conductive plate base materials can be accurately and easily overlapped and bonded.
[0044]
Next, the contact element 40 is separated from the remaining portions of the conductive plate base materials 34 and 36 and the electrically insulating material 42 by using an etching technique, a laser processing technique, or the like. This separating operation can be performed accurately and easily.
[0045]
Referring to FIG. 5, a contact 50 is a needle that is in contact with an electrode of a device under test in a region including an element region 20 used as a contact piece and a second contact portion 32 that contacts a conductive portion of a substrate. It has the same shape as the contact 10 except that it has a cut that divides into two into a front area and a non-needle front area, and the cut is filled with the same electrical insulator 52 as the electrical insulator 24. And a structure.
[0046]
For this reason, as shown in FIG. 6, when manufacturing the element region 20 in the first conductive plate base material 34, the contact 50 has the notch 54 formed therein, and as shown in FIG. Manufactured in the same manner as the contact 10 except that the cuts 54 are filled with an electrically insulating material 56 of the same material as the electrically insulating material 42 when the element regions 20 and 22 are glued together in a sandwich. can do.
[0047]
Each part of the divided element region 20 is integrally connected to the corresponding conductive plate base material 34 at one or more places. The electrically insulating material 56 filled in the cuts 54 acts as a part of the electrical insulator 24 in the completed contact 50.
[0048]
According to the contact 50 and the method of manufacturing the same, not only the same operation and effect as those of the contact 10 can be obtained, but also the two divided element regions are contacted with the contact piece contacting the electrode of the device under test and the conductive portion of the substrate. By doing so, the effective length dimension of the obtained contact (the distance between the contact portion of the test object to the electrode and the contact portion to the conductive portion of the substrate) is reduced, so that the separated contact piece Electrical noise contamination is significantly reduced.
[0049]
Referring to FIG. 8, the contact element 60 includes two element regions 20 which are divided in a region including the second contact portion 32 and are used as contact pieces, and one other element region 22. It has the same shape and structure as the contact 50, except that the element regions 20, 22, 20 are superimposed and adhered so that 22 is located between the two element regions 20.
[0050]
Therefore, as shown in FIG. 9, the contact 60 manufactures two element regions 20, but manufactures one element region 22, so that the element region 22 is located between the element regions 20. It can be manufactured in the same manner as the contact 50, except that the regions 20, 22, 20 are superimposed and glued.
[0051]
According to the contact 60 and the method of manufacturing the same, not only the same operation and effect as the contact 50 can be obtained, but also the two element regions 20 are used as the contact pieces to be brought into contact with the electrode of the device under test and the conductive portion of the substrate. Thus, the electrical connection between the contact piece and the electrode of the device under test is a more stable Kelvin connection.
[0052]
Next, an embodiment of the electrical connection device using the plurality of contacts 10, 50 or 60 as described above will be described.
[0053]
Referring to FIGS. 10 to 12, the electrical connection device 100 is used as a socket in testing or testing a semiconductor device 102 such as an integrated circuit using a plurality of contacts 10 (or 50).
[0054]
The semiconductor device 102 has a main body 104 packaged or molded in a rectangular planar shape, and a plurality of lead electrodes 106 protruding outward from portions corresponding to respective sides of the rectangle. The lead electrodes 106 are divided into a plurality of lead electrode groups corresponding to the respective sides of the rectangle, and are arranged in parallel for each lead electrode group.
[0055]
The connection device 100 includes a substrate 120, a plurality of contacts 10 individually corresponding to the lead electrodes 106, a flat cover or plate-like body 124 for assembling the contact 10 to the substrate 120, and a contact A plurality of rod-shaped elastic bodies 126 to be assembled to the body 124.
[0056]
The substrate 120 is a wiring substrate in which a wiring pattern is formed on one surface of an electrically insulating material by a printed wiring technology, and has a plurality of strip-shaped printed wirings 128 corresponding to the contacts 10 on one surface.
[0057]
Each wiring 128 functions as a conductive part. Each wiring 128 is a part of a wiring pattern. The wirings 128 are divided into a plurality of wiring groups corresponding to the respective sides of the rectangle of the main body 104 of the semiconductor device 102, and are arranged in parallel for each wiring group.
[0058]
Each wiring 128 corresponds to the lead electrode 106 of the semiconductor device 102 and thus the contact 10. Part of each wiring 128 is used as a conductive part.
[0059]
The plate-like body 124 is assembled to the substrate 120 by the plurality of screw members 130 and the plurality of positioning pins 132 so as to be overlapped with each other. The plate-like body 124 has an opening that opens to the substrate 120 side, that is, a first recess 134, a plurality of slits 136 communicating with the first recess 134, and an elastic body 126 having a circular cross-sectional shape. And a second recess 138 for each lead electrode group.
[0060]
The slit 136 extends in the longitudinal direction of the wiring 128, penetrates the plate-like body 124 in the thickness direction, and communicates with the first and second recesses 134 and 138. The second recess 138 continuously extends in the direction in which the plurality of contacts 10 are arranged, and is open to the substrate 120 side. Adjacent slits 136 are defined by partition walls 140.
[0061]
The contact 10 has a needle tip portion penetrating the corresponding slit 136 and an upper end protruding from the plate-like body 124, a rear end portion is received by the second recess 138, and a rear end of the contact 10 is formed by the second recess 138. It is arranged on the plate-like body 124 in a state of being in contact with the back surface 138a.
[0062]
The elastic body 126 is formed in a rod shape from an elastic material such as silicone rubber in the illustrated example, and extends in the second recess 138 in the longitudinal direction thereof. The elastic body 126 is located between the contact 10 and the plate-like body 124 in a state where the elastic body 126 is assembled to the connection device 100, so that the second contact portion 32 of the contact 10 contacts the wiring portion 128. In order to make it possible, the contact 10 is locked to the surface of the curved portion 14 and the needle rear portion 16 on the side of the concave tail 18.
[0063]
In a state where the elastic body 126 is disposed in the second recess 138, the connecting device 100 is configured such that the distal end side of the contact 10 is inserted into the slit 136 so that the distal end thereof protrudes upward from the plate-like body 124. Then, the rear end side is inserted into the second recess 138, and the plate-like body is assembled to the substrate 120 in this state, whereby assembly can be performed. Therefore, the contacts 10 can be easily and correctly arranged on the plate-like body 124 in parallel.
[0064]
In the assembled state, the contact 10 is maintained in a stable state by the slit 136 and the elastic body 126, and the adjacent contact 10 is prevented from being short-circuited by electrical contact by the partition 140.
[0065]
At the time of inspection, when the lead electrode 106 of the semiconductor device 102 is pressed against the tip of the contact 10, the element region 20 of each contact 10 is pressed by the lead electrode 106 and the wiring 128.
[0066]
Referring to FIG. 13, in the case of an electrical connection device capable of performing Kelvin connection using the contact 60, the wiring 128 is divided into two wiring portions 128 a and 128 b individually corresponding to the element regions 20. At the time of inspection, both element regions 20 are individually pressed against the wiring portion 128a which is pressed against the same lead electrode.
[0067]
The present invention can be applied not only to the above-mentioned J-shaped contact but also to a contact having another shape.
[0068]
Referring to FIGS. 14 and 15, the electrical connection device uses a Z (or S) -shaped contact 70. Each contact 70 uses two Z (or S) -shaped thin plate-like element regions 80 and one element region 822 having the same shape as this element region. The element regions 80, 82, 80 are overlapped and adhered in the thickness direction with an electric insulator 84 interposed therebetween. The element regions 80, 82, and 80 have conductivity.
[0069]
The element regions 80 and 88 correspond to the wiring portions 128a and 128a of the wiring 128, respectively. The upper ends of the element regions 80 and 80 function as first contact portions that are in common contact with the corresponding lead electrodes 106, and the lower end portions function as second contact portions that individually contact the wiring portions 128a and 128a. . Each contact 70 can be manufactured in the same manner as contacts 10, 50, 60, except that they differ in shape and size.
[0070]
The plate-shaped body 86 used in the electrical connection device shown in FIGS. 14 and 15 has a plurality of slits 88 for receiving the contacts 70. Each slit 88 penetrates in the thickness direction of the plate 86 and extends in the longitudinal direction of the wiring 128. Adjacent slits 88 are defined by partition walls 90.
[0071]
This electrical connection device uses two elastic members 126 for each contact group. Each elastic body 126 extends through the partition wall 90 and is locked inside the upper or lower curved portion of the contact 88.
[0072]
The electrical connection device is assembled by attaching the elastic body 126 to the plate-like body 86 and assembling the plate-like body 86 to the substrate 120 while the contact 70 is locked to both elastic bodies 126. Can be.
[0073]
In the assembled state, each contact 70 has a lower end portion abutting on the wiring 128 obliquely penetrating the slit 88 and an upper end portion protruding from the plate body 86.
[0074]
In this state, when the lead electrode 106 is pressed by the contact 70, the contact 70 is pressed by the lead electrode 106 and the wiring 128, and slightly rotates clockwise in FIG. Thereby, a rubbing action is applied to the lead electrode 106 and the wiring 128.
[0075]
The present invention is not limited to the above embodiment. For example, the contact may have a simple shape such as an arc, a U-shape, a U-shape, an L-shape, a V-shape, and a W-shape. Further, the upper and lower sides may be used in a state where the upper and lower sides are reversed. Therefore, the present invention can be variously modified without departing from the gist thereof.
[Brief description of the drawings]
FIG. 1 is a view showing a first embodiment of a contact according to the present invention, wherein (A) is a perspective view, (B) is a front view, and (C) is a side view.
FIGS. 2A and 2B are views for explaining the method of manufacturing the contact shown in FIG. 1, wherein FIG. 2A is a view showing steps of a method of manufacturing one element region, and FIG. 2B is a step following FIG. FIG.
FIG. 3 is a view showing a method of manufacturing another element region used in the contact shown in FIG. 1;
FIGS. 4A and 4B are diagrams for explaining a step of obtaining a contact element by combining element areas obtained by the steps of FIGS. 2 and 3, wherein FIG. 4A is a front view and FIG. FIG. 4B is a sectional view taken along 4B-4B.
5A and 5B are views showing a second embodiment of the contact according to the present invention, wherein FIG. 5A is a perspective view, FIG. 5B is a front view, and FIG. 5C is a side view.
FIG. 6 is a diagram showing some of the steps for explaining the method of manufacturing the contact shown in FIG. 5;
FIG. 7 is a diagram showing a part of a step that follows the step shown in FIG. 6;
FIG. 8 is a view showing a third embodiment of the contact according to the present invention, wherein (A) is a perspective view, (B) is a front view, and (C) is a side view.
FIG. 9 is a diagram showing some of the steps for explaining the method of manufacturing the contact shown in FIG. 8;
FIG. 10 is a plan view showing a first embodiment of an electrical connection device using a contact according to the present invention.
FIG. 11 is a sectional view taken along line 11-11 of FIG. 10;
FIG. 12 is a bottom view of a part of the electrical connection device shown in FIG. 10 in a state where a substrate is removed.
FIG. 13 is a perspective view showing a part of an electrical connection device using the contact shown in FIG. 8;
FIG. 14 is a cross-sectional view showing a part of another electrical connection device for a contact according to the present invention.
FIG. 15 is a sectional view taken along the line 15-15 in FIG. 14;
[Explanation of symbols]
10, 50, 60, 70 contacts
12 Needle tip
14 Curved section
16 needle rear
18 recess
20, 22, 80, 82 element area
24, 82, 84 Electrical insulator
26,28 resection
30, 32 first and second contact portions
34, 36 First and second conductive plate base materials
38 Mooring point
40 contact element
42,56 Electrical insulation material
54 Cut

Claims (10)

The at least one element region having a shape corresponding to the shape of the contact to be manufactured is provided on each of at least one first conductive plate preform and at least one second conductive plate preform. It is manufactured in a state where it is integrally connected to the corresponding conductive plate base material at a plurality of locations, and the manufactured element regions are laminated and adhered in the thickness direction with an electrically insulating material to manufacture a contact element. A method for manufacturing a contact, comprising separating the contact element from the first and second conductive plate base materials. Further, in at least one of the element regions of the first or second conductive plate base material, at least a first contact portion that is in contact with the electrode of the device under test and a second contact portion that is in contact with the conductive portion of the substrate. The manufacturing method according to claim 1, further comprising performing a polishing process on the contact portion. Further, with respect to one of the element regions of the first and second conductive plate preforms, a region including the other of the first contact portions of the first and second conductive plate preforms and a second region. 2. The method according to claim 1, further comprising: removing a region including the second contact portion from a time when the element region is manufactured until the element region is separated from a corresponding conductive plate base material. Production method. 4. The method according to claim 1, further comprising performing gold plating on a surface on the side opposite to the overlapping side of each element region before overlapping the element regions. 5. Further, any one of the element regions of the first and second conductive plate base materials may be formed between the time of manufacturing the element region and the time before separating the element region from the corresponding conductive plate base material. 5. The method according to claim 1, further comprising: dividing a contact portion in contact with the conductive portion of the substrate into a region on the needle tip side and a region on the non-needle tip side in contact with the electrode of the device under test. Or the production method according to item 1. The contact element is manufactured by overlapping and bonding the element regions of the second conductive plate base material to the respective surfaces in the thickness direction of the element regions of the first conductive plate base material, The method according to claim 1. The manufacturing method according to any one of claims 1 to 6, wherein one of the first and second conductive plate base materials has a thickness dimension larger than that of the other. A plate-like first element region having a first point on the needle tip side to be brought into contact with the electrode of the test object and a second point on the non-needle tip side pressed against the conductive portion of the substrate; A pair of second element regions having third and fourth portions respectively corresponding to the first and second portions, wherein the first element region is connected to the second element region via an electrical insulator; And a second element region sandwiched between the first element region and the second element region in a thickness direction. 9. The contact according to claim 8, wherein one of the first and second element regions has the first and second portions or the third and fourth portions removed from the other. The first and second element regions each have a J-shape curved at the second and fourth locations, and one of the first and second element regions is The contact according to claim 8, wherein the contact is divided into the needle tip side area and the non-needle tip side area at the second location or the fourth location.

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