KR101182361B1 - Semiconductor device carrier unit - Google Patents

Abstract

The present invention relates to a semiconductor device carrier unit, the semiconductor device carrier unit comprising a body portion 400 for detachably accommodating the semiconductor device to transfer to the socket board 100 for performing the test of the semiconductor device, Printed on the bottom of the body portion 400 of the semiconductor device carrier unit is fixed to the upper and lower flow by the fixing means, and having a contact terminal for electrically connecting the lead terminal of the semiconductor device and the contact pad of the socket board It is characterized in that it further comprises a buffer member which is embedded in the circuit board 500, the bottom surface of the body portion, and positioned between the upper surface of the printed circuit board and the bottom surface of the body portion for a buffering action.

Description

Semiconductor Device Carrier Unit {SEMICONDUCTOR DEVICE CARRIER UNIT}

The present invention relates to a semiconductor device carrier unit, and more particularly, it is possible to conveniently transfer a high-density integrated semiconductor device to the test position necessary for the function test and to allow the distance between the contact pad and the pad to be elastically changed during the test. The present invention relates to a semiconductor device carrier unit having an improved structure to prevent damage to a contact pad.

After the semiconductor device manufacturing process is completed, test the electrical performance of the device using a test jig. Most of the semiconductor device tests are made by inserting the lead terminals of the semiconductor elements into contact with the contact terminals of the socket contactors, and analyzing the signals input and output to the contact terminals as the test circuits.

As an example of a conventional general semiconductor device, a cross section of a main portion of a semiconductor device in a ball grid array (BGA) type and a semiconductor device carrier unit is shown in FIG. As shown in Fig. 1, the conventional semiconductor element 5 uses a semiconductor element carrier unit 1 mounted on a robot arm or the like as a transfer means to test equipment for testing the semiconductor element 5. The semiconductor device 5 moved to the desired position by the semiconductor carrier unit 5 is pushed by the pusher 200 and leads to the contact pads 102 of the socket board 100 positioned below the semiconductor device 5. The test is carried out with the terminal 2 in contact.

However, in the semiconductor device 5 of the related art, an empty area 3 in which the lead terminal 2 exposed to the outside is not formed because the degree of integration is relatively low. The semiconductor device 5 was transferred to the required test position by supporting the empty region 3 in the semiconductor device carrier unit 1 which transports the semiconductor device 5 to the test equipment. That is, the semiconductor device carrier unit 1 supports the lower portion, which is the empty area 3 of the semiconductor device 5, and is separated from the semiconductor device carrier unit 1 while the semiconductor device 5 is transferred to the required position. It was not.

However, as the degree of integration of the semiconductor device 5 increases, the circuit components inside the semiconductor device 5 increase. As a result, the number of lead terminals 2 exposed to the outside of the semiconductor device 5 increases, and the empty area 3 that can be supported by the semiconductor device carrier unit 1 cannot be provided. Therefore, in the structure of the conventional semiconductor device carrier unit 1, the semiconductor device 5 is separated from the semiconductor device carrier unit 1 when it is to be transferred to a position necessary for testing a semiconductor device having a high degree of integration. Problems have arisen.

FIG. 2 is a semiconductor device carrier unit whose structure is improved so that the integrated semiconductor device can be conveniently moved to a required position in order to solve such a problem (Registration No. 20-0414883, registered on April 19, 2006). .

Referring to FIG. 2, the semiconductor device carrier unit 20 includes a body portion 30, a first socket contactor 40, an auxiliary printed circuit board 50, and a second socket contactor 40a.

The body portion 30 is a member which is mounted on a robot arm or the like and detachably accommodates the semiconductor device 300 and transfers it to the socket board 100 for performing the test of the semiconductor device 300. The body part 30 is provided with a plurality of side wall parts 32 to accommodate the semiconductor device 300. The side wall part 32 is provided to serve as a guide while the outer edge of the semiconductor device 300 is in contact with each other. The lower side of the body portion 30 is open so that the lead terminal 302 of the semiconductor device 300 may protrude below the body portion 30.

The first socket contactor 40 is fixed to the body portion 30 so as to be able to flow up and down by fixing means such as a bolt under the body portion 30. The first socket contactor 40 is provided so as not to be separated from the body portion 30 while the semiconductor device 300 is being transferred. In addition, the first socket contactor 40 may also electrically connect the lead terminal 302 of the semiconductor device 300 to the test socket board 100. The first socket contactor 40 includes a contact terminal portion 42 and an insulating portion 44. The contact terminal part 42 is configured to electrically connect the lead terminal 302 of the semiconductor device 300 and the contact pad 102 of the socket board 100.

The insulating portion 44 is formed between the contact terminal portions 42 to electrically insulate the contact terminal portions 42. More specifically, the contact terminal portion 42 is formed by mixing and solidifying liquid metal powder such as gold or copper with liquid silicon, and the insulating portion 44 has electrical conductivity. It is formed by filling non-conductive silicon in between to electrically insulate the contact terminal portions 42. Since the contact terminal part 42 is elastic in silicon, the contact terminal part 42 may have good contact even when the contact terminal part 42 is not horizontally aligned with the socket board 102 or the semiconductor device 300.

The insulating part 44 is charged between the contact terminal parts 42 to stabilize the position of the first socket contactor 40, and the lead terminal 302 of the semiconductor device 300 is pressed. When contacted, the contact terminal 42 can be erected vertically in its original form.

The auxiliary printed circuit board 50 is fixed to the body portion 30. The auxiliary printed circuit board 50 is disposed below the first socket contactor 40. The auxiliary printed circuit board 50 is configured to electrically connect the contact terminal 42 and the second socket contactor 40a disposed below the auxiliary printed circuit board 50. The main structure of the second socket contactor 40a, that is, the contact terminal portion 42a has the same structure as that of the first socket contactor 40. The contact terminal portion 42a of the second socket contactor 40a is electrically connected to the contact pad 100 of the socket board 100 disposed below the second socket contactor 40a. The auxiliary printed circuit board 50 has a plurality of through holes 52. The inner wall of each of the through holes 52 is plated with a conductive material 54 such as copper, for example. The conductive material 54 is a contact terminal portion 42 of the first socket contactor 40 and the second socket. The contact terminal part 42a of the contactor 40a is electrically connected. As a result, the lead terminal 302 of the semiconductor device 300 is electrically connected to the contact pad 102.

The second socket contactor 40a is coupled to the socket guide 60 and disposed below the auxiliary printed circuit board 50. The socket guide 60 may be moved relative to the auxiliary printed circuit board 50 to some extent. The socket guide 60 is disposed even when the semiconductor device 300 is tilted by placing the first and second socket contactors 40 and 40a on the upper and lower surfaces thereof with the auxiliary printed circuit board 50 interposed therebetween. It is provided as an additional safety device so as not to damage the socket board 100.

However, according to the prior art as described above, there is a problem in that the first socket contactor is damaged or deformed during repeated use, resulting in poor contact.

In addition, there was a problem in that the configuration of the auxiliary printed circuit board is complicated and the production time and costs are high, and the test speed is lowered.

An object of the present invention has been proposed to solve the problems in the prior art as described above, it is possible to conveniently transfer a high-density integrated semiconductor device to the test position necessary to test the function and to contact with the contact pad during the test. The present invention provides a semiconductor device carrier unit having an improved structure so that the gap may be elastically changed to prevent damage to the contact pad.

According to a preferred embodiment of the present invention for achieving the object as described above, in the semiconductor device carrier unit comprising a body portion for receiving the semiconductor device detachably and transported to the socket board for performing the test of the semiconductor device, A printed circuit board fixed to the bottom surface of the body part of the semiconductor device carrier unit by a fixing means and having a contact terminal part electrically connecting the lead terminal of the semiconductor device to the contact pad of the socket board; A buffer member embedded in a bottom surface of the body portion, positioned between an upper surface of the printed circuit board and a bottom surface of the body portion, and configured to buffer the same;
The fixing means is a bolt for fixing the printed circuit board on the bottom surface of the body portion, and wrapped around the bolt at the same time installed through the printed circuit board to limit the downward movement of the printed circuit board, at the same time the printed circuit board There is provided a semiconductor device carrier unit comprising a bush for moving upwardly with a gap while interacting with the buffer member when moving upward.

Preferably, the buffer member is characterized in that the compression spring.

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As described above, according to the semiconductor device carrier unit according to the present invention, the semiconductor device with high density can be conveniently transported to the test position necessary for the function test, and the distance between the contact pad and the elastic contact pad during the test is printed. It is possible to prevent the damage of the contact pad of the circuit board and to prevent the test failure.

1 is a cross-sectional view of a conventional semiconductor device carrier unit.
2 is a cross-sectional view of a semiconductor device carrier unit according to still another embodiment of the related art.
3 is an enlarged view of the portion “A” shown in FIG. 2.
4 is an exploded perspective view of a semiconductor device carrier unit according to the present invention.
5 is a plan view and a cross-sectional view taken along line CC of the semiconductor device carrier unit according to the present invention.
6 is a partial side cross-sectional view of a semiconductor device carrier unit according to the present invention, before the socket board is operated.
Figure 7 is a side cross-sectional view after completion of the test of the semiconductor device carrier unit according to the present invention, after the socket board is operated.
8 is an enlarged view of a portion of FIG. 6.
9 is an enlarged view of a portion of FIG. 7.

Hereinafter, a semiconductor device carrier unit according to the present invention will be described in detail with reference to the accompanying drawings. The same reference numerals are used for the same parts as in the prior art, and the same description will be omitted.

Referring to FIG. 4, the semiconductor device carrier unit according to the present invention includes a semiconductor device 600, a body 400, and a printed circuit board 500.

The semiconductor device carrier unit according to the present invention includes a body portion 400 which detachably receives the semiconductor device and transfers it to the socket board 100 for performing the test of the semiconductor device.

The semiconductor device carrier unit is fixed to the bottom surface of the body 400 of the semiconductor device carrier unit by a fixing means so as to be movable up and down, and electrically connects the lead terminal of the semiconductor device and the contact pad of the socket board. A printed circuit board 500 having a contact terminal and a lower surface of the body 400 are disposed between the upper surface of the printed circuit board 500 and the bottom of the body 400 to provide a buffering effect. It characterized in that it further comprises a buffer member 522.

The buffer member 522 is characterized in that the compression spring.

The fixing means is installed through the printed circuit board 500 while wrapping the bolt 542 and the bolt 542 for fixing the printed circuit board 500 on the bottom surface of the body 400. It includes a bush 532 to limit the downward movement of the printed circuit board 500, and at the same time to move upwards with a gap while interacting with the buffer member 522 when the printed circuit board 500 moves upward. Characterized in that made.

5, the semiconductor device carrier unit according to the present invention is characterized in that the printed circuit board 500 is flexible. As it is not fixed as in the prior art, it prevents a test defect and maintains the contact function of the contact pad during the test, and at the same time, the contact pad is moved downward as the lead presses, thereby alleviating the impact. To prevent damage.

6 and 8, in the semiconductor device carrier unit according to the present invention, the interval of D1 (0.3 mm, but not limited thereto) is lower than that of the body part 400 and the printed circuit board 500 before the initial test operation. It is maintained between the upper surfaces of the). The printed circuit board 500 can be moved up and down by this interval. That is, in FIG. 8, the printed circuit board 500 is pushed downward by the force of the compression spring, which is the buffer member 522, and no longer moves downward by the bush 532.

7 and 9, the semiconductor device carrier unit according to the present invention has an interval of D2 (0.1 mm, but not limited thereto) as shown in the drawing during and after the initial test operation. It is maintained between the bottom of the substrate and the top surface of the printed circuit board 500. That is, it can be seen that the test operation is surely performed by a reduced interval compared to D1 (0.3 mm) in FIG. 6. That is, during the test operation, the printed circuit board 500 is pushed by the socket board 100 and moved upward by 0.2 mm. At this time, as can be seen in Figure 9, the printed circuit board 500 is pushed upward and spaced apart from the buffer member 522 by a predetermined interval (D3).

400: body
500: printed circuit board
600: semiconductor device

Claims (3)

In the semiconductor device carrier unit comprising a body portion 400 for receiving the semiconductor device detachably and transported to the socket board 100 for performing the test of the semiconductor device,
Printed on the bottom of the body portion 400 of the semiconductor device carrier unit is fixed to the upper and lower flow by the fixing means, and having a contact terminal for electrically connecting the lead terminal of the semiconductor device and the contact pad of the socket board A circuit board 500,
It is embedded in the bottom surface of the body portion, further comprising a buffer member positioned between the upper surface of the printed circuit board 500 and the bottom surface of the body portion for a buffering action,
The fixing means is a bolt for fixing the printed circuit board 500 on the bottom surface of the body portion, and wrapped around the bolt at the same time is installed through the printed circuit board 500 to move downward of the printed circuit board 500 Limiting, and at the same time a semiconductor device carrier unit comprising a bush to move upwardly with a gap while interacting with the buffer member when moving upward of the printed circuit board (500). The semiconductor device carrier unit according to claim 1, wherein the buffer member is a compression spring. delete

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