KR20190024070A - Test socket and conductive particle - Google Patents

Abstract

The present invention relates to an inspection socket and a conductive particle thereof, and more particularly, to an inspection socket, which is disposed between a device to be inspected and an inspection device to electrically connect a terminal of the device to be inspected and a pad of the inspection device, comprising: a plurality of conductive units provided at each position corresponding to a terminal of a device to be inspected, and having a plurality of conductive particles vertically disposed in an elastic insulating material; and an insulating support unit provided between the conductive units, and electrically insulating the conductive units from each other while supporting each of the conductive units. At least one of the conductive particles includes: a body unit made of a metal material, and forming an appearance of the conductive particles; and a plurality of silica particles having a part thereof fixed in the body unit, a part of the remainder to protrude from the body unit, and being in contact with the elastic insulating material forming the conductive units to be firmly coupled to the elastic insulating material.

Description

Test sockets and conductive particles [0002]

The present invention relates to a test socket and a conductive particle, and more particularly, to a test socket and a conductive particle which prevent the conductive particles from being detached from the conductive portion during an inspection process.

In general, a socket for inspection is used in an inspection process for judging whether or not a manufactured device to be inspected is defective. That is, the manufactured device to be inspected performs a predetermined electrical inspection in order to judge whether the device is defective. At this time, the device to be inspected requiring inspection and the inspection device for inspection are not directly in contact with each other, . The reason for this is that the inspection apparatus for inspection is relatively expensive, so that it is not easy to replace the apparatus when it is frequently worn or damaged due to contact with the device to be inspected, and the replacement cost is high. Accordingly, the inspecting socket is replaceably mounted on the inspection apparatus, and the inspecting device is electrically connected to the inspecting apparatus by contacting the inspecting socket, not the inspecting apparatus. Therefore, the inspection signal coming from the inspection device is transmitted to the device under test through the inspection socket.

1 and 2, the inspecting socket 140 is disposed between the inspecting device 140 and the inspecting device 130 and is provided between the terminal 141 of the inspecting device 140 and the inspecting device 130 The conductive part 110 is disposed at a position corresponding to a terminal of the device to be inspected and exhibits conductivity in the thickness direction. The conductive part 110 is elastic A conductive part 110 in which a plurality of conductive particles 111 are arranged in a thickness direction in an insulating material; And an insulating supporting portion 120 for supporting and insulating each of the conductive portions 110. At this time, the pad 131 of the inspection apparatus 130 and the conductive section 110 are in contact with each other while the inspection socket 130 is mounted on the inspection apparatus 130, And is configured to be able to contact the conductive portion 110 of the inspection socket 100.

The inspected device 140 moved by the insert is brought into contact with the conductive part 110 of the inspection socket 100 to be seated on the inspection socket 100 and then to be inspected by the inspection device 130 The electric signal is transmitted to the device under test 140 through the socket 100 for inspection so that a predetermined electrical inspection is performed.

On the other hand, the conductive part of the inspection socket is constituted by arranging a plurality of conductive particles in the insulating material, and the terminals of the device to be inspected frequently touch the conductive parts. When the terminals of the device to be inspected frequently touch the conductive parts, the conductive particles distributed in the insulating material can be easily released to the outside. Particularly, the conductive particles are spherical, and thus the spherical conductive particles are easily separated from the insulating material. In the case where the conductive particles are detached as described above, the conductive performance is deteriorated as a whole, and thus the reliability of the whole inspection is affected.

In order to solve such a problem, Korean Patent Registration No. 1339166 (published on December 9, 2013) filed by the applicant of the present invention discloses a method of forming a through hole in conductive particles and filling the through hole with a peripheral elastic insulating material, Discloses a technique for preventing particles from escaping from a conductive portion.

Such conventional technology has the effect of preventing the conductive part from being separated from the conductive part, but it has a problem in that the conductive material is made of a conductive material composed of a metal material having conductivity and a material between the elastic insulating material made of silicone rubber It is not possible to overcome the disadvantage that the adhesion at the interface is weak.

Disclosure of the Invention The present invention has been made in order to solve the above-described problems, and more particularly, to provide a test socket and a conductive particle capable of maintaining a constant bonding force in a test process by maintaining a bonding force with the surrounding elastic insulating material .

In order to achieve the above object, according to the present invention, there is provided a test socket for electrically connecting a terminal of an inspecting device and a pad of an inspecting device, the insulated socket being disposed between an inspecting device and an inspecting device,

A plurality of conductive parts provided at positions corresponding to the terminals of the device to be inspected and having a plurality of conductive particles arranged in a vertical direction in an elastic insulating material; And

And an insulating support portion provided between the plurality of conductive portions and electrically insulating the conductive portions from each other while supporting the conductive portions,

At least one of the conductive particles may be a conductive particle,

A body portion made of a metal material and constituting an outer shape of the conductive particles,

And a plurality of silica fine particles which are partly fixed within the body part and a part of which protrudes from the body part and are in contact with the elastic insulating material constituting the conductive part and firmly combined with the elastic insulating material.

In the inspection socket,

The fine silica particles may be evenly distributed over the entire surface of the body portion.

In the inspection socket,

The conductive part is prepared by curing a plurality of conductive particles in a liquid-state elastic insulating material in a thickness direction,

The silica fine particles can prevent the conductive particles from being separated from the elastic insulating material by inducing strong bonding with the elastic insulating material in the course of curing the liquid insulating elastic insulating material.

In the inspection socket,

The body portion may be made of a mixture of a high-conductive metal and a magnetic body, or a state in which a high-conductive metal and a magnetic body are physically or chemically contacted to each other.

In the inspection socket,

The body portion is provided with a plurality of concave portions which are recessed and filled with elastic insulating material,

Fine particles of silica may be fixedly protruded on the inner surface of the concave portion so as to be firmly coupled to the elastic insulating material in the concave portion.

In order to achieve the above object, according to the present invention, there is provided a test socket for electrically connecting a terminal of an inspecting device and a pad of an inspecting device, the insulated socket being disposed between an inspecting device and an inspecting device,

A plurality of conductive parts provided at positions corresponding to the terminals of the device to be inspected and having a plurality of conductive particles arranged in a vertical direction in an elastic insulating material; And

And an insulating support portion provided between the plurality of conductive portions and electrically insulating the conductive portions from each other while supporting the conductive portions,

At least one of the conductive particles may be a conductive particle,

A body portion made of a metal material and constituting an outer shape of the conductive particles,

And a plurality of fine synthetic particles which are partly fixed within the body part and a part of which protrudes from the body part and is in contact with the elastic insulating material constituting the conductive part to constitute a solid connection with the elastic insulating material,

The high-definition synthetic microparticles are made of a material having a high adhesive force to be adhered to the elastic insulating material than the metal material constituting the body part.

In the inspection socket,

The high-definition synthetic fine particles may be made of calcium carbonate.

In the inspection socket,

The high-definition synthetic microparticles can be evenly distributed over the entire surface of the body portion.

In order to achieve the above object, the conductive particles of the present invention are provided for each position corresponding to a terminal of a device to be inspected requiring electrical inspection, and a plurality of conductive particles And an insulative support portion provided between the plurality of conductive portions to electrically insulate the conductive portions from each other while supporting the respective conductive portions,

Wherein at least one of the conductive particles provided in the conductive portion is a conductive particle,

A body portion made of a metal material and constituting an outer shape of the conductive particles,

And a plurality of silica fine particles which are partly fixed in the body part and a part of which protrudes from the body part and are in contact with the elastic insulation material and firmly coupled with the elastic insulation material.

In the conductive particles,

The fine silica particles may be evenly distributed over the entire surface of the body portion.

In the conductive particles,

The body portion may be made of a mixture of a high-conductive metal and a magnetic body, or a state in which a high-conductive metal and a magnetic body are physically or chemically contacted to each other.

In order to achieve the above-mentioned object,

A plurality of conductive parts which are provided for respective positions corresponding to terminals of the device to be inspected and in which a large number of conductive particles are arranged in the elastic insulating material in the vertical direction, and a plurality of conductive parts which are provided between the plurality of conductive parts, 1. A conductive particle provided in a test socket comprising an insulating support for electrically insulating a conductive particle,

At least one of the conductive particles may be a conductive particle,

A body portion made of a metal material and constituting an outer shape of the conductive particles,

And a plurality of fine particles adhered to the main body and a portion of the fine particles adhered to the main body, the plurality of fine particles being in contact with the elastic insulating material constituting the conductive part and being firmly bonded to the elastic insulating material,

The high-definition synthetic microparticles are made of a material having a higher adhesive force to the elastic insulation material than the metal material constituting the body part.

The conductive particles may be,

The high-definition synthetic microparticles can be evenly distributed over the entire surface of the body portion.

The present invention provides fine particles of silica on the surface of conductive particles to induce strong bonding with the elastic insulating material, thereby preventing the conductive particles from being detached in the process of pressing the conductive part during the inspection process, There is an advantage to maintain.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 shows a prior art socket for inspection. Fig.
Figure 2 is an operational view of Figure 1;
3 is a view showing a test socket according to an embodiment of the present invention;
Fig. 4 is a view showing conductive particles used in the inspection socket of Fig. 3; Fig.
5 and 6 are views showing a method of manufacturing a test socket of the present invention.
7 is a view showing conductive particles according to another embodiment of the present invention.

Hereinafter, a test socket according to the present invention will be described in detail with reference to the accompanying drawings.

The inspection socket 10 according to the present invention is disposed between the device under test 60 and the inspection device 70 and is provided with the terminals 61 of the device under test 60 and the pads 71 of the inspection device 70, And includes an electrically conductive portion 20 and an insulative support portion 30. The electrically conductive portion 20 and the insulative support portion 30 are electrically connected to each other.

A plurality of the conductive parts 20 are disposed at positions corresponding to the terminals 61 of the device under test 60. Each of the conductive parts 20 is arranged to be spaced apart from each other in the plane direction and exhibits conductivity in the thickness direction and does not show conductivity in the plane direction perpendicular to the thickness direction. In the conductive part 20, a plurality of conductive particles 21 are arranged in the thickness direction in the elastic insulating material. When the upper surface of the conductive part 20 is pressed, the conductive part 20 is compressed in the thickness direction and expanded in the surface direction.

The elastic insulating material constituting the conductive part 20 is preferably a polymer material having a crosslinked structure. As the curable polymeric substance-forming material usable for obtaining such an elastic insulating material, various materials can be used. Specific examples thereof include polybutadiene rubber, natural rubber, polyisoprene rubber, styrene-butadiene copolymer rubber, acrylonitrile- Butadiene-diene block copolymer, and styrene-isoprene block copolymer, and hydrogenated products thereof, chloroprene rubber, urethane rubber, poly Ester rubber, epichlorohydrin rubber, silicone rubber, ethylene-propylene copolymer rubber, and ethylene-propylene-diene copolymer rubber.

In the above, when weatherability is required for the conductive parts 20 to be obtained, it is preferable to use a material other than the conjugated diene rubber, and in particular, from the viewpoints of moldability and electrical characteristics, it is preferable to use silicone rubber.

As the silicone rubber, it is preferable that the liquid silicone rubber is crosslinked or condensed. The liquid silicone rubber preferably has a viscosity of 10 ⁵ poise or less at a strain rate of 10 ^-1 s, and may be any of condensation type, addition type, vinyl type, and hydroxyl type. Specific examples thereof include dimethyl silicone raw material, methyl vinyl silicone raw material and methylphenyl vinyl silicone raw material.

The conductive particles 21 have conductivity as a whole and perform a function of allowing electricity to flow in the conductive parts 20. [ A plurality of the conductive particles 21 are contained in the insulating elastic material.

These conductive particles 21 include a body portion 21a and silica fine particles 21b.

The body portion 21a is made of a metal material and forms a general outer shape of the conductive particles 21, and may have a usual sphere shape. However, the present invention is not limited thereto and may have various shapes such as a columnar shape, a star shape, and an irregular shape.

As the body portion 21a, a material exhibiting magnetism is used. Specific examples of the material exhibiting such magnetism include particles of a magnetic metal such as iron (Fe), cobalt (Co), nickel (Ni), alnico, ferrite, neodymium (NdFeB), and samarium (SmCo) Alloy particles or particles containing these metals or those particles as core particles and plating the surface of the core particles with a metal having a good conductivity such as gold, silver, palladium, or rhodium, or a non- Or inorganic particles such as glass beads or polymer particles as core particles and plating the surfaces of the core particles with a conductive magnetic metal such as nickel or cobalt. Among them, it is preferable to use the nickel particles as the core particles and the surface of which is plated with gold having good conductivity.

In addition, the body 21a is made of a magnetic material such as iron, cobalt, nickel, or the like, which represents magnetic properties, and an alloy of a high-conductivity metal such as gold, silver and copper, It is also possible to include a state in which the "

The silica fine particles (21b) are, as has having a granule size smaller than the body portion (21a), and the formula as SiO _2. These fine silica particles 21b are excellent in bonding strength with the silicone rubber constituting the elastic insulating material as compared with the metal material. That is, the adhesive strength to the silicone rubber at the interface is excellent, so that it is not easily peeled off when bonded.

The silica fine particles 21b are partially embedded in the surface of the body portion 21a and are firmly fixed to the body portion 21a while the remaining portion of the silica fine particles 21b protrudes from the body portion 21a. The silica fine particles 21b protruding from the body 21a are in contact with the elastic insulating material and are firmly coupled to the elastic insulating material. These fine silica particles 21b are evenly distributed over the entire surface of the body portion 21a. The fine silica particles 21b do not completely cover the surface of the body 21a so that the conductive particles 21 can be brought into electrical contact with the adjacent conductive particles 21, They are spaced apart from each other.

In addition, when the component ratio of the fine silica particles 21b is increased, the conductivity can be reduced, but the adhesive strength with the elastic insulating material can be further improved by controlling the composition ratio effectively, thereby increasing the service life of the test socket 10.

The insulating supporting portion 30 is formed of the same material as the elastic insulating material so as to insulate the conductive portions 20 from each other while preventing the electric conduction between the conductive portions 20 while supporting the conductive portions 20. [ Specifically, a silicone rubber can be used. However, the present invention is not limited thereto, and it is also possible to use a material different from the elastic insulating material constituting the conductive part 20.

A method of manufacturing the inspection socket 10 of the present invention will be described with reference to Figs. 5 and 6. Fig.

First, as shown in Fig. 5, a molding material of a fluidity is prepared by dispersing magnetic particles 21 in a liquid insulating elastic material, and the molding material is filled in the cavity of the mold, Is embedded in the mold in a state in which it is positioned between the ferromagnetic layer 52 of the upper mold 50 and the ferromagnetic layer 57 of the lower mold 55 corresponding thereto. Next, a pair of electromagnets (not shown), for example, are disposed on the lower surface of the ferromagnetic substrate 56 on the upper surface and the lower surface 55 of the ferromagnetic substrate 51 in the upper mold 50, A parallel magnetic field having a large intensity between the parallel magnetic field having the intensity distribution, that is, the ferromagnetic material portion 52 of the upper mold 50 and the corresponding ferromagnetic material portion 57 of the lower mold 55, .

As a result, in the molding material 20A, the conductive particles 21 dispersed in the molding material layer 20A as shown in Fig. 6 are separated from the ferromagnetic material portion 52 of the upper mold 50 and the lower mold 55 and the ferromagnetic material portions 57 of the forming material 20A at the same time and aligned so as to be aligned in the thickness direction of the molding material 20A.

In this state, the molding material 20A is cured to form an insulating elastic material (not shown) disposed between the ferromagnetic material portion 52 of the upper die 50 and the corresponding ferromagnetic material portion 57 of the lower die 55, A conductive part 20 densely packed in a state in which the conductive particles 21 are arranged so as to be arranged in the thickness direction and an insulating support part 21 having no or almost no conductive particles 21 around the conductive part 20 30 are manufactured.

In the inspection socket 10 manufactured as described above, since the silica fine particles 21b induce strong bonding with the conductive particles 21 in the curing process of the insulating elastic material, The sliding of the conductive particles 21 can be prevented.

In addition, due to the strong coupling between the conductive particles 21 and the elastic insulating material, the conductive part 20 can be held firmly in the process of compressing the conductive part 20, and the conductivity can be maintained constant.

Since the silica fine particles 21b have a strong adhesive force with the elastic insulating material such as silicone rubber, there is little fear that the conductive particles 21 will be separated from the conductive part 20 and the whole life of the test socket 10 is improved .

The test socket 10 according to an embodiment of the present invention has the following actions and effects.

First, after inserting the inspecting socket 10 into the inspecting device 70, the inspecting device 10 is placed on the inspecting socket 10. At this time, the conductive portion 20 of the inspection socket 10 is placed in a state in which it can be electrically conducted by the terminal 61 of the device under test. At this time, the electric signal is transmitted to the terminal 61 of the device under test 60 through the conductive part 20 by applying a predetermined electrical signal from the testing device 70, Can be performed.

The test socket of the present invention is advantageous in that the conductive fine particles provided in the conductive particles induce a strong bonding between the conductive particles and the silicone rubber, which is an elastic insulating material, so that the conductivity can be maintained constant.

In the conventional conductive particles, when the elastic insulating material is expanded in a high-temperature environment, the contact surface between the conductive particles is always deteriorated. In the conductive particles having silica particles adhered thereto according to this embodiment, The contact between the conductive particles can be maintained even if the elastic insulating material expands, so that more stable electrical contact can be maintained in a high temperature environment.

In addition, in the conductive particles according to the present invention, even if a plating layer is formed on the surface of the body portion for high conductivity, the fine particles of silica can not be plated, so that the exposure of the fine particles of silica can be maintained.

The test socket according to the present invention can be modified as follows.

Although the conductive particles of the present invention are formed on the body portion of the conductive fine particles, the present invention is not limited thereto, and the fine synthetic particles of other materials may be used as long as the conductive particles adhere to the elastic material more than the metal material constituting the body portion It is possible. Examples of such highly consolidated synthetic fine particles include calcium carbonate, calcium phosphate, alumina, titanium oxide, and the like. It is also possible to use silica fine particles and calcium carbonate fine particles alone, or to mix different kinds of dissimilar materials to form a body part.

As described above, the fine particles adhering to the surface of the body have intrinsic properties so that the adhesive force with the elastic insulating material can be maintained.

In the above-described embodiment, silica fine particles are formed on the surface of the spherical body portion. However, as shown in FIG. 7, the concave portions of the conductive particles 21 ' It is also possible that a plurality of silica particles 22 'are formed and silica fine particles 21b' are formed up to the inner surface of the concave portion 22 '. That is, the elastic insulating material is filled up to the concave portion 22 ', which is recessed, so that the solid particles between the conductive particles 21' and the elastic insulating material can be firmly bonded to the inner surface of the concave portion 22 ' (21b ') are formed, which makes it possible to more securely engage with each other.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the present invention is not limited to the disclosed exemplary embodiments, but various changes and modifications may be made without departing from the spirit and scope of the invention.

10 ... test socket 20 ... conductive part
21 ... conductive particles 21a ... body portion
21b ... silica fine particles 30 ... insulating support
40 ... frame plate 50 ... upper die
51 ... ferromagnetic substrate 52 ... ferromagnetic portion
55 ... lower mold 56 ... ferromagnetic substrate
57 ... ferromagnetic part 60 ... inspected device
61 ... terminal 70 ... test apparatus
71 ... pad

Claims (13)

A testing socket for electrical connection between a terminal of a device to be inspected and a pad of an inspecting device disposed between the device to be inspected and the inspecting device,
A plurality of conductive parts provided at positions corresponding to the terminals of the device to be inspected and having a plurality of conductive particles arranged in a vertical direction in an elastic insulating material; And
And an insulating support portion provided between the plurality of conductive portions and electrically insulating the conductive portions from each other while supporting the conductive portions,
At least one of the conductive particles may be a conductive particle,
A body portion made of a metal material and constituting an outer shape of the conductive particles,
And a plurality of silica fine particles which are partly fixed in the body part and a part of which protrudes from the body part and which are in contact with the elastic insulating material constituting the conductive part and firmly combined with the elastic insulating material. socket. The method according to claim 1,
Wherein the fine silica particles are evenly distributed over the entire surface of the body part. The method according to claim 1,
The conductive part is prepared by curing a plurality of conductive particles in a liquid-state elastic insulating material in a thickness direction,
Wherein the silica fine particles induce strong bonding with the elastic insulating material in the process of curing the liquid elastic insulating material, thereby preventing the conductive particles from being separated from the elastic insulating material. The method according to claim 1,
Wherein the body is made of a mixture of a high-conductive metal and a magnetic material, or a high-conductive metal and a magnetic material are physically or chemically bonded to each other. The method according to claim 1,
The body portion is provided with a plurality of concave portions which are recessed and filled with elastic insulating material,
And fine particles of silica are fixedly protruded on the inner surface of the concave portion to be firmly coupled to the elastic insulating material in the concave portion. A testing socket for electrical connection between a terminal of a device to be inspected and a pad of an inspecting device disposed between the device to be inspected and the inspecting device,
A plurality of conductive parts provided at positions corresponding to the terminals of the device to be inspected and having a plurality of conductive particles arranged in a vertical direction in an elastic insulating material; And
And an insulating support portion provided between the plurality of conductive portions and electrically insulating the conductive portions from each other while supporting the conductive portions,
At least one of the conductive particles may be a conductive particle,
A body portion made of a metal material and constituting an outer shape of the conductive particles,
And a plurality of fine particles adhered to the body portion and partially protruding from the body portion and contacting the elastic insulating material constituting the conductive portion to form a firm connection with the elastic insulating material,
Wherein the high-hardness synthetic microparticles are made of a material having a high adhesive strength to be adhered to the elastic insulating material than a metal material constituting the body portion. The method according to claim 6,
Characterized in that said highly-synthesized fine particles are made of calcium carbonate. The method according to claim 1,
Wherein the high-definition synthetic microparticles are evenly distributed over the entire surface of the body portion. A plurality of conductive parts provided for respective positions corresponding to terminals of the device to be inspected requiring electrical inspection and in which a plurality of conductive particles are arranged in the elastic insulating material in the vertical direction; And an insulating supporting portion for supporting the conductive portions while electrically insulating the conductive portions from each other while supporting the conductive portions,
Wherein at least one of the conductive particles provided in the conductive portion is a conductive particle,
A body portion made of a metal material and constituting an outer shape of the conductive particles,
And a plurality of silica fine particles which are partly fixed within the body part and a part of which protrudes from the body part and which are in contact with the elastic insulating material and firmly combined with the elastic insulating material. 10. The method of claim 9,
Wherein the fine particles of silica are evenly distributed over the entire surface of the body part. 10. The method of claim 9,
Wherein the body portion is in a state in which a high-conductive metal and a magnetic body are mixed or a high-conductive metal and a magnetic body are physically or chemically contacted to each other. A plurality of conductive parts which are provided for respective positions corresponding to terminals of the device to be inspected and in which a large number of conductive particles are arranged in the elastic insulating material in the vertical direction, and a plurality of conductive parts which are provided between the plurality of conductive parts, 1. A conductive particle provided in a test socket comprising an insulating support for electrically insulating a conductive particle,
At least one of the conductive particles may be a conductive particle,
A body portion made of a metal material and constituting an outer shape of the conductive particles,
And a plurality of fine particles adhered to the main body and a portion of the fine particles adhered to the main body, the plurality of fine particles being in contact with the elastic insulating material constituting the conductive part and being firmly bonded to the elastic insulating material,
Wherein the high-hardness composite fine particles are made of a material having a high adhesive force to an elastic insulating material than a metal material constituting the body portion. 13. The method of claim 12,
Characterized in that the high-definition synthetic microparticles are evenly distributed over the entire surface of the body part.

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