KR102678521B1 - Test socket for a semiconductor chip - Google Patents

Abstract

A test socket for a semiconductor chip includes a chip holder body on which the semiconductor chip to be tested is placed; a substrate member disposed on the bottom of the chip holding body member and on which a circuit for testing the semiconductor chip is mounted; an insulating member disposed on the bottom of the substrate member to insulate the substrate member; a support panel member disposed on the bottom of the insulating member and supporting the chip mounting body member, the substrate member, and the insulating member; and a holder member disposed on the bottom of the support panel member and including an opening for distributing pressure at a central portion.

Description

Test socket for semiconductor chip {TEST SOCKET FOR A SEMICONDUCTOR CHIP}

The present invention relates to a test socket for a semiconductor chip, and more specifically, to a socket used to test the electrical characteristics of a semiconductor chip.

A test socket for a semiconductor chip can test whether the semiconductor chip being tested is normal.

A stability test may be performed by applying voltage to the semiconductor chip while it is mounted in a test socket.

The test socket for a semiconductor chip may include a chip holder body for mounting the semiconductor chip and a board on which a circuit for testing the semiconductor chip placed on the chip holder body is mounted.

However, in a conventional test socket, the chip holder body and the substrate are coupled with bolts. For this reason, when the test socket for the semiconductor chip is exposed to test conditions in a high temperature environment (for example, burn-in test, etc.), heat from the high temperature environment is transmitted to the inside of the chip holder body through the bolt, which is made of metal. The heat transferred in this way can cause testing errors in semiconductor chips.

In addition, since the structure is connected using the bolt, if repeated loading and unloading of the semiconductor chip is repeated, there may be a problem that its durability is reduced.

Registration Patent No. 10-2025765, registration date: 2019.09.20, title of invention: semiconductor module test socket

The present invention provides a test socket for a semiconductor chip that can easily couple and separate a chip holder body and a substrate.

A test socket for a semiconductor chip according to one aspect of the present invention includes a chip holder body member on which a semiconductor chip to be tested is placed; a substrate member disposed on the bottom of the chip holding body member and on which a circuit for testing the semiconductor chip is mounted; an insulating member disposed on the bottom of the substrate member to insulate the substrate member; a support panel member disposed on the bottom of the insulating member and supporting the chip mounting body member, the substrate member, and the insulating member; And it may include a holder member disposed on the bottom of the support panel member and including an opening for pressure distribution in the center.

The holder member includes a body portion supporting a bottom surface of the support panel member; a pair of support parts extending upward from both sides of the body portion and supporting both sides of the support panel member, both sides of the insulating member, both sides of the substrate member, and both sides of the chip holding body member; and hook portions formed on upper ends of the support portions and hooked to both sides of the chip holder body member.

According to the present invention, a single holder member is disposed on the bottom of the support panel member and can support both sides of the support panel member, the insulating member, the substrate member, and the chip holding body member. In particular, the support panel member, insulating member, substrate member, and chip mounting body member can be fixed by simply inserting a pair of clip portions of the holder member made of elastic material into the clip connection groove on the chip mounting side of the chip mounting body member. there is. In addition, the holder member can be separated from the chip mounting body member by a simple operation of disengaging one of the pair of clip parts from the clip connection groove on the chip mounting side.

1 is an exploded cross-sectional view showing a test socket for a semiconductor chip according to an embodiment of the present invention.
FIG. 2 is a perspective view showing a holder member of the test socket for a semiconductor chip shown in FIG. 1.
FIG. 3 is a cross-sectional view showing a state in which the test socket for a semiconductor chip shown in FIG. 1 is coupled by the holder member shown in FIG. 2.

The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and will be implemented in various different forms. These embodiments only serve to ensure that the disclosure of the present invention is complete, and those skilled in the art It is provided to fully inform the person of the scope of the invention, and the present invention is only defined by the scope of the claims. The sizes and relative sizes of layers and regions in the drawings may be exaggerated for clarity of explanation. Like reference numerals refer to like elements throughout the specification.

FIG. 1 is an exploded cross-sectional view showing a test socket for a semiconductor chip according to an embodiment of the present invention, FIG. 2 is a perspective view showing a holder member of the test socket for a semiconductor chip shown in FIG. 1, and FIG. 3 is a holder member for a test socket for a semiconductor chip shown in FIG. 1. This is a cross-sectional view showing a state in which the test socket is coupled by the holder member shown in FIG. 2.

Referring to FIGS. 1 to 3 together, the test socket 100 for a semiconductor chip according to this embodiment includes a chip holding body member 110, a substrate member 140, an insulating member 150, a support panel member 160, and It may include a holder member 170.

The holder member 170 may be disposed on the bottom of the support panel member 160 to support the bottom of the support panel member 160. In addition, the holder member 170 may fix both sides of the support panel member 160, both sides of the insulating member 150, both sides of the substrate member 140, and both sides of the chip holder body member 110. . In particular, the holder member 170 may be one single part. That is, the support panel member 160, the insulating member 150, the substrate member 140, and the chip mounting body member 110 can be firmly fixed using the holder member 170, which is one component.

The holder member 170 may include a body portion 180, a pair of support portions 190, and hook portions 195. In particular, the body portion 180, the support portions 190, and the hook portion 195 may be formed integrally. Additionally, the body portion 180, the support portions 190, and the hook portion 195 may include an elastic material. That is, the entire holder member 170, which is a single component, may be made of an elastic material. Elastic materials may include metals with elasticity, but may not be limited to specific materials.

The body portion 180 may support the bottom of the support panel member 160. The body portion 180 includes a center plate 182 abutted to the bottom of the support panel member 160, and a pair of connection plates 184 connecting both sides of the center plate 182 and the support portion 190. can do. The connection plates 184 may be spaced apart from the bottom of the support panel member 160. By separating the connection plates 184 from the bottom of the support panel member 160, the holder member 170 can be easily attached and detached. The attachment and detachment operation of the holder member 170 will be described later. As an example, the opening 186 inside the center plate 182 can disperse the pressure applied during subsequent cementation.

The connection plates 184 may have a length shorter than that of the center plate 182. For example, the length of each of the connection plates 184 may gradually decrease from the center plate 182 to the support portions 190. As another example, the length of the connecting plates 184 may be the same as the length of the center plate 182 or may be longer than the length of the center plate 182.

A pair of support parts 190 may extend upward from both sides of the body part 180. That is, the support portions 190 may be substantially perpendicular to the upper surface of the body portion 180. However, the present invention is not limited thereto, and the support portions 190 may form an acute or obtuse angle with the upper surface of the body portion 180. The support portions 190 abut both sides of the support panel member 160, both sides of the insulating member 150, both sides of the substrate member 140, and both sides of the chip holding body member 110, so that the support panel member ( 160), both sides of the insulating member 150, the substrate member 140, and the chip holding body member 110 may be supported.

Hook portions 195 may be formed at the upper ends of the support portions 190. The hook portions 195 are configured to be caught on both sides of the chip holding body member 110, and the holder member 170 is sequentially stacked with a support panel member 160, an insulating member 150, a substrate member 140, and The chip holding body member 110 can be firmly fixed.

In this embodiment, each of the hook parts 195 may include an insertion part 197 extending downward from an end of each of the hook parts 195. The insertion portion 197 may be supported by being caught by the chip holder body member 110. Additionally, each of the hook portions 195 may be formed of a pair disposed on both sides of the upper ends of the support portions 190. It is not limited to this and may consist of one or three or more.

The chip mounting body member 110 may mount a semiconductor chip (not shown) to be tested on its upper surface. The chip holding body member 110 may include a chip holding body 111 and a clip portion 115.

A connection electrode 113 electrically connected to the chip lifting portion 114 may protrude from the bottom of the chip holding body 111. As the connection electrode 113 is electrically connected to the substrate electrode 142, which will be described later, an electrical signal can be applied to the semiconductor chip mounted on the chip raising portion 114 through the connection electrode 113. .

Drawing number 112 indicates a coupling guide protrusion protruding from the bottom of the chip holding body 111. The coupling guide protrusion 112 may be inserted into a guide groove (not shown) formed in the substrate body 141, which will be described later. The chip holder body 111 can be coupled to a predetermined position of the substrate body 141 by this coupling guide protrusion 112.

The clip portion 115 may be formed on the chip holding body 111 and may be a portion where the hook portions 195 of the holder member 170 are caught. The clip portion 115 may be formed on both sides of the chip holder body 111. A clip connection groove 116 on the chip mounting side may be formed in the clip portion 115. The insertion portions 197 of the hook portion 195 may be inserted into the clip connection groove 116 on the chip mounting side.

The clip connection groove 116 on the chip mounting side is formed on the upper surface of the clip portion 115 and is recessed downward to a certain depth, so that the insertion portions 197 are caught and connected.

The chip holding body member 110 may include a chip holding upper body 120, a connection spring 125, a chip pressing lever 130, and a connection lever 135.

The chip holder upper body 120 is located at the upper part of the chip holder body 111 and is configured to be raised and lowered with respect to the chip holder body 111. The chip holder upper body 120 may have, for example, a rectangular parallelepiped structure with an empty interior, and a semiconductor chip may be placed on the chip raising unit 114 or taken out from the chip raising unit 114 through its upper part.

The connection spring 125 is applied to each corner of the chip holder body 111 and the chip holder upper body 120, and a compression spring may be presented as an example.

When the chip holding upper body 120 is lowered toward the chip holding body 111 due to an external force such as an operator, the connecting spring 125 is elastically deformed and compressed, and when the external force is removed, the restoring force of the connecting spring 125 As a result, the chip mounting upper body 120 can be raised and returned to its original position.

The tip of the chip push lever 130 is rotatably connected to the chip holder upper body 120 by the push lever connecting shaft 131, and can press the semiconductor chip placed on the chip lifter 114.

The connection lever 135 is formed in the shape of a bar of a certain length, the front end of which is rotatably connected to the central part of the chip pressing lever 130 by the front connection shaft 132, and the rear end of the connection lever 135 is connected to the rear connection shaft 116. It can be rotatably connected to the clip portion 115.

When the chip holding upper body 120 is lowered toward the chip holding body 111 by an external force such as an operator, the distal end of the chip pressing lever 130 connected to the chip holding upper body 120 by the pressing lever connecting shaft 131 is lowered. do. At this time, the central part of the chip pressing lever 130 is connected to the connection lever 135 and does not descend, and the front part of the chip pressing lever 130 is lifted and the chip pressing lever 130 is tilted to form the chip raising portion 114. ) is opened.

As described above, when the chip holding upper body 120 is lowered toward the chip holding body 111 and the chip lifting portion 114 is opened, the connecting spring 125 is elastically deformed and compressed.

With the chip raising unit 114 open, a semiconductor chip is placed on the chip raising unit 114 or the semiconductor chip is carried out from the chip raising unit 114, and then the external force applied to the chip holding upper body 120 is When removed, the chip holding upper body 120 rises due to the restoring force of the connection spring 125, and accordingly, the distal end of the chip pressing lever 130 also rises, and the front part of the chip pressing lever 130 lowers to chip. The chip raising unit 114 is closed while pressing the semiconductor chip placed on the raising unit 114 or the chip raising unit 114 .

The chip pressing lever 130 and the connecting lever 135 are composed of a pair and are respectively connected to both sides of the chip holding upper body 120 so as to face each other, so that the pair of chip pressing lever 130 and the connecting lever 135 ) can open and close the chip raising portion 114 together.

The substrate member 140 is disposed on the bottom of the chip holding body member 110, and a circuit for testing the semiconductor chip is mounted.

The substrate member 140 may include a substrate body 141, a substrate through hole 143, and a substrate recessed hole 144.

The board body 141, on which the circuit is mounted, is formed in the shape of a plate with a certain area and can be in contact with the bottom of the chip holder body 111.

A plurality of substrate electrodes 142 protrude downward from the bottom of the substrate body 141, and the substrate electrodes 142 are connected to an external power source (not shown), thereby raising circuits and chips through the substrate electrodes 142. Electricity for testing may be applied to the semiconductor chip placed on the unit 114 and the chip raising unit 114.

The substrate through-hole 143 is formed to penetrate one side of the substrate body 141 and passes through one of the support portions 190 of the holder member 170.

The substrate recessed hole 144 is formed on the other side of the substrate body 141 to be spaced apart from the substrate through hole 143, and is recessed to a certain depth from the outer edge of the other side of the substrate body 141. It is formed so that another one of the support portions 190 of the holder member 170 passes through.

The insulating member 150 is disposed on the bottom of the substrate member 140 to insulate the substrate member 140, and may have an area equal to that of the support panel member 160.

The support panel member 160 is disposed on the bottom of the insulating member 150 and supports the chip holding body member 110, the substrate member 140, and the insulating member 150, and may be made of a metal material.

Hereinafter, the attachment and detachment operations of the holder member 170 will be described in detail.

First, in a state in which the support panel member 160, the insulating member 150, the substrate member 140, and the chip mounting body member 110 are sequentially stacked, the holder member 170 is placed on the bottom of the support panel member 160. It can be entered upward toward .

The support portions 190 of the rising holder member 170 may be abutted against both sides of the support panel member 160, the insulating member 150, the substrate member 140, and the chip holding body member 110. Since the support portions 190 of the holder member 170 have elastic force, the support portions 190 may be slightly opened on both sides.

The holder member 170 is raised until the body portion 180 of the holder member 170 abuts the bottom surface of the support panel member 160. Then, the hook portions 195 of the holder member 170 may enter the chip mounting side clip connection grooves 116 formed on both sides of the chip mounting body member 110. Subsequently, the hook portions 195 are retracted inward by elastic restoring force, so that the insertion portions 197 can be inserted into the clip connection groove 116 on the chip mounting side. At this time, the connection plates 184 of the body portion 180 may not be in contact with the bottom of the support panel member 160 but may be spaced apart from the bottom of the support panel member 160.

To separate the holder member 170, an external force stronger than the elastic force of the hook portion 195 may be applied to any one of the hook portions 195 to spread the hook portion 195. Accordingly, the insertion portion 197 may be separated from the clip connection groove 116 on the chip mounting side. This opening motion of the hook portion 195 causes the connection plates 184 of the body portion 180 to be spaced apart from the bottom of the support panel member 160, thereby creating a space between the connection plates 184 and the support panel member 160. It can be easily accomplished by existing. In this way, if one of the hook portions 195 is separated from the chip mounting side clip connection groove 116, the remaining hook portion 195 can be naturally removed from the chip mounting side clip connection groove 116 without applying external force. .

Although the present invention has been shown and described in relation to specific embodiments in the above, those skilled in the art can make various modifications to the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. You will see that it can be changed. However, we would like to make it clear that all such modifications and modified structures are included within the scope of the present invention.

According to the present embodiments, a holder member, which is a single component, is disposed on the bottom of the support panel member and can support both sides of the support panel member, the insulating member, the substrate member, and the chip holding body member. In particular, the support panel member, insulating member, substrate member, and chip mounting body member can be fixed by simply inserting a pair of clip portions of the holder member made of elastic material into the clip connection groove on the chip mounting side of the chip mounting body member. there is. In addition, the holder member can be separated from the chip mounting body member by a simple operation of disengaging one of the pair of clip parts from the clip connection groove on the chip mounting side.

As such, a person skilled in the art to which the present invention pertains will understand that the present invention can be implemented in other specific forms without changing its technical idea or essential features. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive. The scope of the present invention is indicated by the claims described below rather than the detailed description above, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention. do.

100 ; Test socket for semiconductor chip 110; Chip holding body member
140 ; Substrate member 150; insulation member
160 ; Support panel member 170 ; Holder member
180 ; body 182; center plate
184 ; connection plate 190; support
195 ; hook part 197; insertion part

Claims (2)

A chip holder body member on which the semiconductor chip to be tested is placed;
a substrate member disposed on the bottom of the chip holding body member and on which a circuit for testing the semiconductor chip is mounted;
an insulating member disposed on the bottom of the substrate member to insulate the substrate member;
a support panel member disposed on the bottom of the insulating member and supporting the chip mounting body member, the substrate member, and the insulating member; and
It includes a holder member disposed on the bottom of the support panel member and including an opening for pressure distribution in the center,
The holder member is
a body portion supporting the bottom of the support panel member;
a pair of support parts extending upward from both sides of the body portion and supporting both sides of the support panel member, both sides of the insulating member, both sides of the substrate member, and both sides of the chip holder body member; and
A test socket for a semiconductor chip including hook portions formed on upper ends of the support portions and hooked to both sides of the chip holder body member.
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