KR100960882B1 - A carrier for semiconductor package - Google Patents

Abstract

A carrier body having a through portion vertically penetrated and provided with a latch rotatably inside the through portion; A pocket member coupled to a lower portion of the carrier body and having a pocket portion on which the semiconductor package moved through the through portion is seated; And a coupling member coupled from a side of the carrier body to movably support the pocket member with respect to the carrier body.

Semiconductor, Package, Pocket Member, Carrier, Pin, Gap

Description

A carrier for semiconductor package

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a carrier for semiconductor packages, and more particularly to a carrier for semiconductor packages on which a semiconductor package to be tested can be mounted.

In general, a semiconductor package manufactured by a semiconductor package manufacturing process undergoes reliability tests such as electrical property test and function test before shipment. A handler is mainly used to transfer the manufactured semiconductor package to a test apparatus and to transfer the semiconductor package to classify the tested semiconductor package.

The handler carries a plurality of semiconductor packages into a test apparatus, and conducts a test process by electrically contacting each semiconductor package to a test head through a test socket. Each semiconductor package after the test is completed is taken out from the test head and classified according to the test result.

In this case, the handler may test the semiconductor package by transferring the plurality of carriers, each containing the individual semiconductor package, into the test chamber with left and right aligned with the test tray.

The carrier for mounting each semiconductor package may be separately mounted on the test tray.

1 and 2 show a conventional carrier for a semiconductor package, the carrier body having a through portion 11 in the center portion, and the press is provided to be elevated on the carrier body 10 And a pocket member 30 coupled to the lower portion of the member 20 and the carrier body 10 and having a pocket portion 31 for supporting the semiconductor package transferred through the through portion.

According to the above constitution, a pair of latch members 13 are rotatably provided inside the penetrating portion 11 of the carrier body 10. The latch member 13 rotates during the pressing operation of the pressing member 20 so that the semiconductor package can be mounted and detached from the pocket member 30, and the pocket member 30 is released when the pressing member 20 is released. It serves to support the semiconductor package seated in the pocket 31 of the separation.

The pocket member 30 is coupled to the lower portion of the carrier body 10 and is supported to be movable by four pins 40. Here, the pin 40 is coupled to pass through the pinhole 35 formed in each of the four corner portions of the pocket member 30 and the pinhole 15 formed in the carrier body 10. As described above, each of the four pins 40 is coupled to pass through the carrier body 10 from the pocket member 30, and then, as shown in FIG. 2, the upper end 41 is caulked by using the caulking equipment. It is fixedly installed so as not to be separated from the carrier body 10.

On the other hand, in the case of the conventional carrier for a semiconductor package as described above, at least four pins 40 must be provided in order to couple the lower pocket member 30 to the carrier body 10, thus increasing the number of parts and thus the cost. There is an increasing problem.

In addition, since the pin 40 has to be coked to the carrier body 10 by using the caulking equipment, the assembly process takes a long time and is difficult, there is a problem that the cost increases and productivity is lowered.

On the other hand, in the case of the pocket member 30, since the size and shape of the pocket portion 31 can be variously manufactured according to the size of the semiconductor package, the pocket member 30 of various models is prepared, and the carrier body 10 ) Has the advantage that it can be used universally. However, in the case of the carrier for the conventional semiconductor package as described above, since the pocket member 30 is virtually impossible to be separated and dismantled from the carrier body 10 after the pin 40 is caulked, the pocket member 30 and It becomes impossible to recycle the whole part including the carrier body 10. Therefore, every time the size and model of the semiconductor package is changed, the entire carrier must be newly manufactured and produced, and thus there is a problem in that the cost burden increases.

In addition, in order to caulk the pin 40, a hollow pin must be used, and thus, a costly component can be used compared to a general pin, thereby increasing the cost of the product.

SUMMARY OF THE INVENTION The present invention has been made in view of the above, and an object thereof is to provide a carrier for a semiconductor package improved to reduce the number of components.

In addition, another object of the present invention is to provide a carrier for a semiconductor package improved to enable separation and disassembly of a pocket member and a carrier body.

The carrier for a semiconductor package of the present invention for achieving the above object, the carrier body having a through portion formed through the top and bottom, the latch body is installed to be rotatable inside the through portion; A pocket member coupled to a lower portion of the carrier body and having a pocket portion on which a semiconductor package moved through the through portion is seated; And a coupling member coupled to a side of the carrier body to movably support the pocket member with respect to the carrier body.

The pocket member may include a plate-shaped pocket member body formed to penetrate the pocket portion at a central portion thereof and face the lower portion of the carrier body; A seating portion provided around the inner side of the pocket portion to seat the semiconductor package; A guide rib protruding from the upper surface of the pocket member to correspond to the inner surface of the through part to guide the movement of the pocket member; It is preferable to include; a pair of connecting ribs protruding upward from each of the corner portions of the pocket member body corresponding to each other, and having a clearance hole into which the coupling member is fitted.

In addition, the carrier body has a coupling groove which is formed from the lower side of the carrier rib is inserted into each of the connecting ribs movably, the coupling member is coupled to pass through the coupling groove from the side of the carrier body to the coupling groove It is preferable to include a connecting pin fitted in the clearance hole of the connecting rib located in.

In addition, the carrier body may be formed with a pair of pin press-holes from the side to press-fit the connection pin via the coupling groove from the side.

In addition, the clearance hole may be formed to have a width larger than the diameter of the coupling member in the horizontal and horizontal direction, the width in the vertical direction in the vertical direction.

According to the carrier assembly according to an embodiment of the present invention, in the configuration of coupling the pocket member to the carrier body, the overall number of parts can be reduced, and the joining process can be made simple, thereby improving productivity and reducing production costs. It becomes possible.

In addition, since the pocket member and the carrier body can be easily dismantled, and the breakage or damage of the pocket member, the carrier body, and the coupling member can be prevented during dismantling, it is possible to recycle the dismantled parts, thereby reducing costs. It becomes possible.

Hereinafter, a carrier for a semiconductor package according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3A, 3B, and 4, a carrier for a semiconductor package according to an exemplary embodiment of the present invention may include a carrier body 100 having a through portion 101 formed therethrough, and a carrier body 100 of the carrier body 100. Pocket member 200 is provided to be movable in the lower portion, and the coupling member 300 for movably coupling the pocket member 200 to the carrier body 100.

In the embodiment of the present invention, the carrier body 100 will be described with an example having a dual structure in which a pair is connected to the left and right. However, it is a matter of course that the present invention is not limited to the dual carriage. The carrier body 100 has a pair of latch 110 is rotatably installed in the through portion 101 is formed through the top and bottom. Both ends of the pair of latches 110 are rotatably connected to both upper ends of the through part 101. Here, the through part 101 is formed in a substantially quadrangular frame shape.

Both ends of the pair of latches 110 are connected to the toggle member 120 which is installed to be elevated on the upper portion of the carrier body 100. Therefore, when the toggle member 120 is lowered, the pair of latches 110 are pressed by the toggle member 120 to be rotated. An elastic spring 130 (see FIG. 5) is installed below the toggle member 120 to elastically support the toggle member 120. Therefore, when the pressing force is released while the toggle member 120 is pressed, the toggle member 120 is raised by the restoring force of the elastic spring 130, and the pair of latches 110 are also returned to the initial position. The latch 110 is a generally known function to support the semiconductor package to be test mounted on the pocket member 200 to prevent the latch 110 from being separated.

In addition, the pressing member 140 is installed on the upper portion of the carrier body 100 to be elevated. A compression spring 150 is installed between the carrier body 100 and the pressing member 140. When the pressing member 140 is pressed by a predetermined pressing means, the pressing member 140 by pressing the toggle member 120, as described above, the latch 110 can be rotated. When the toggle member 120 returns to its original position, the pressing member 140 also returns to its original position by the restoring force of the compression spring 150.

The pocket member 200 may include a pocket member body 210 having a pocket portion 201 formed therethrough at a central portion thereof, a seating portion 220 provided around the inner side of the pocket portion 201, and a guide rib. 230 and connecting ribs 240.

The pocket member body 210 has a shape corresponding to the lower portion of the carrier body 100 and has a plate shape having a predetermined thickness. The pocket part 201 is formed through the center of the pocket member body 210 in the form of a quadrangular frame, and is formed to correspond to the through part 101 of the carrier body 100.

The seating part 220 is formed to protrude to the inner side (horizontal direction) of the pocket part 201. The semiconductor package moved through the through part 101 is mounted on the seating part 220 for a test.

The guide rib 230 is formed to protrude upward from the upper surface of the pocket member body 210, that is, the edge of the pocket portion 201. The guide rib 230 is positioned to face the inner surface of the through part 101, thereby guiding the movement of the pocket member 210 in the vertical direction.

The pair of connecting ribs 240 are formed to protrude a predetermined height to the upper surface of the pocket member 200, is formed symmetrically in the corner portions facing each other diagonally around the pocket portion 201. The connecting rib 240 has a clearance hole 241 into which the coupling member 300 is inserted in a horizontal direction. The clearance hole 241 is formed to have a width greater than the thickness of the coupling member 300 in the horizontal direction, that is, the diameter, and is formed to have a width larger than the width in the horizontal direction in the vertical direction. Thus, the pocket member 200 is supported by the coupling member 300 fixed to the carrier body 100, so that the clearance hole 241 and the coupling member 300 can move in the vertical direction as well as the left and right directions. do. The clearance hole 241 may be a long hole formed in the vertical direction.

On the other hand, as shown in Figure 4 and 5, the coupling groove 103 is formed in the lower portion of the carrier body 100 to accommodate the connecting rib 240 as described above. The coupling groove 103 is formed deeper than the height of the connecting rib 240, so that the connecting rib 240 in the coupling groove 103 can be guided in the vertical direction without collision.

Here, the coupling member 300 may include a connection pin having a predetermined length. The connecting pin is formed of a metal material.

In addition, a pair of pin indentation holes 105 through which the coupling member 300, that is, the connection pin is press-fitted, is formed to penetrate to both sides of the carrier body 100 so as to be connected to the coupling groove 103. The pin indentation hole 105 is formed to penetrate from one side of the carrier body 100 to the other side via the coupling groove 103. Therefore, when the pocket member 200 is positioned so that the connecting rib 240 is inserted into the coupling groove 103, the coupling member 300 is press-fitted into the pin pressing hole 105 and the pocket member 200 is inserted therein. ) Can be movably connected to the lower portion of the carrier body (100).

Here, since the pair of connecting ribs 240 are provided in the diagonal direction on the upper portion of the pocket member 200, by coupling to support the connecting ribs 240 using a pair of coupling members 200, pocket member ( 200 and the carrier body 100 can be combined.

Therefore, the number of parts thereof can be reduced as compared with the related art, and since the operation of coupling the coupling member 300 can be performed by hand or the like, the assembling process is very easy and the working time can be shortened. That is, the caulking equipment for caulking coupling, alignment equipment, etc. are unnecessary as in the prior art, and the coupling member 300 may be provided with a simple pin structure, and an expensive pin for caulking processing is used as in the prior art. This eliminates the cost of individual components.

In addition, since the coupling member 300 coupled as described above is press-fitted into the pin press-in hole 105, it is possible to dismantle the press-coupled coupling member 300 from the pin press-in hole 105 by manual work or the like. . At this time, since the carrier body 100, the coupling member 300 and the pocket member 200 are not damaged or damaged when the coupling member 300 is separated, the carrier body 100 and the pocket member 200 which have been dismantled are removed. And the coupling member 300 and the like can all be reused. Therefore, there is an advantage that can reduce the cost in terms of the user.

1 and 2 are schematic views showing a carrier for a conventional semiconductor package.

Figure 3a is an exploded perspective view showing a carrier for a semiconductor package according to an embodiment of the present invention.

FIG. 3B is a perspective view illustrating a coupled state of the carrier for the semiconductor package illustrated in FIG. 3A.

4 is a cross-sectional view taken along line II of FIG. 3B.

5 is a cross-sectional view taken along line II-II of FIG. 3B.

6 is a cross-sectional view taken along line III-III of FIG. 3B.

Description of the Related Art

100. Carrier body 101.

110. Latch 120. Toggle member

130. Elastic spring 140. Pushing member

150. Compression spring 200. Pocket member

201.Pocket section 210.Pocket member body

220. Seating 230. Guy dribble

240. Connecting rib 300. Joining member

Claims (5)

A carrier body (100) having a through portion (101) formed through the top and bottom, the latch (110) being rotatably installed inside the through portion (101); A pocket member 200 coupled to a lower portion of the carrier body 100 and having a pocket portion 201 on which the semiconductor package moved through the through portion is seated; And And a coupling member 300 coupled from the side of the carrier body 100 to movably support the pocket member 200 with respect to the carrier body 100. The pocket member 200, The pocket portion 201 is formed through the center portion, the plate-shaped pocket member body 210 which is located facing the lower portion of the carrier body (100); A seating part 220 provided around the inner side of the pocket part 201 to seat the semiconductor package; A guide rib 230 protruding from the upper surface of the pocket member body 210 to correspond to the inner surface of the through part 101 to guide the movement of the pocket member 200; A pair of connecting ribs 240 protruding upward from both corner portions corresponding to diagonal directions of the pocket member body 210 and having a clearance hole 241 into which the coupling member 300 is fitted; Including; The carrier body 100 is formed deeper than the height of the connecting rib 240 from the lower side of the coupling groove 103, each of the connecting ribs 240 is movably inserted, and the coupling from the side It has a pair of pin press-holes 105 formed from each of both sides such that the coupling member is press-fitted via the groove 103, The coupling member 300 is coupled to pass through the coupling groove 103 from the side of the carrier body 100 is fitted in the clearance hole 241 of the connecting rib 240 located in the coupling groove 103 And a connection pin press-fitted to the pin press-fit hole 105, The clearance hole 241 has a width larger than the diameter of the coupling member 300 in the horizontal and horizontal direction, and the carrier for a semiconductor package, characterized in that formed in the vertical direction has a width larger than the width in the horizontal and horizontal directions. delete delete delete delete

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