JP3673153B2 - Spring contact - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a spring contact used for interconnection between a semiconductor package such as a CPU, logic, and memory and a circuit board of a test apparatus for testing the semiconductor package.
[0002]
[Prior art]
As a conventional spring contact, for example, the one shown in FIG. 6 is known (see Japanese Patent Laid-Open No. 10-214665).
The spring contact 100 includes a conductive upper contact 101 that contacts a built-in battery of a mobile phone, a lower contact 102 that slidably accommodates the upper contact 101, and is electrically connected to the substrate, and a lower contact. A compression coil spring 103 is disposed in the cylindrical portion 102b of 102 and presses and biases the upper contact 101 in the protruding direction. A plurality of spring contacts 100 are prepared, and the plurality of spring contacts 100 are attached to the insulating housing 104 by press-fitting the lower contacts 102 into the insulating housing 104 at a predetermined narrow pitch for high density arrangement. It has become.
[0003]
In the spring contact 100, the lower end portion of the compression coil spring 103 abuts on a recess 102 a formed in the bottom portion of the lower contact 102, and the upper end portion of the compression coil spring 103 abuts on the lower end inclined surface 101 a of the upper contact 101. Yes. Therefore, when the upper contact 101 is biased in the protruding direction by the pressing force of the compression coil spring 103, a side pressure acts in the direction of the arrow X perpendicular to the axial direction of the lower contact 102, and the upper contact 101 The cylindrical portion 102b of the lower contact 102 is surely in contact. For this reason, the current flowing from the built-in battery side of the mobile phone to the substrate side bypasses the upper contact 101 as shown mainly by the arrow A and flows through the cylindrical portion 102b of the lower contact 102 through the bottom thereof, and vice versa. The current flowing from the substrate side to the built-in battery side flows mainly in the direction opposite to the direction indicated by the arrow A. In order to cause such a current to flow through a conductive path having a low contact resistance, the outer peripheral surface of the upper contact 101 and the inner peripheral surface of the cylindrical portion 102b of the lower contact 102 are made of nickel under gold plating or the like. A plating layer is formed.
[0004]
[Problems to be solved by the invention]
However, in this conventional spring contact 100, since the lower contact 102 is press-fitted into the insulating housing 104 at a narrow pitch, the cylindrical portion 102b of the lower contact 102 is narrowed, its inner diameter is small, and the cylinder Since the bottom portion 102b is deeper than the inner diameter, and the bottom contact 102 has a bottom, the plating solution does not sufficiently enter when plating the inner peripheral surface of the tubular portion 102b of the bottom contact 102. was there. If the plating solution does not sufficiently enter the lower contact 102, the plating layer is not uniformly formed on the inner peripheral surface of the cylindrical portion 102b of the lower contact 102, and the contact resistance with the upper contact 101 becomes high. Sometimes. As the inner diameter of the cylindrical portion 102b of the lower contact 102 becomes smaller, the problem that the plating solution does not sufficiently enter the lower contact 102 becomes more prominent.
[0005]
Accordingly, the present invention has been made to solve the above-described problems, and the object thereof is to easily form a uniform plating layer on the inner peripheral surface of a separate conductive sleeve that accommodates the upper and lower contacts. An object of the present invention is to provide a spring contact capable of high-density mounting capable of forming a conductive path having a low contact resistance through an upper contact, a conductive sleeve, and a lower contact even when the contacts do not contact each other.
[0006]
[Means for Solving the Problems]
In order to solve the above problems, a spring contact according to claim 1 of the present invention includes a pair of upper and lower contacts and a compression coil spring that urges the pair of contacts in a direction away from each other. The upper and lower ends are open, receive the pair of contacts and the compression coil spring, and are fixed to one contact of the pair of contacts, and are separate from the pair of upper and lower contacts. Sex sleeve and In a spring contact comprising: The pair of upper and lower contacts each have a spring accommodating recess for receiving an end of the compression coil spring, and the opposing end surfaces of the pair of upper and lower contacts are substantially complementary corrugated surfaces or saw teeth extending in the vertical direction. Consists of form It is characterized by that.
[0007]
According to a second aspect of the present invention, the spring contact according to the first aspect is characterized in that a tapered taper surface is formed on both outer surfaces of the conductive sleeve.
[0008]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described with reference to the drawings. FIG. The Pulling contact Reference example FIG.
A spring contact 1 shown in FIG. 1 electrically connects a solder ball S of a semiconductor package P such as a CPU, logic, and memory to a circuit board PCB of a test apparatus that tests the semiconductor package P. The spring contact 1 has a pair of upper and lower contacts 2 and 3, a compression coil spring 4 that urges the contacts 2 and 3 away from each other, and openings 5 a and 5 b at both upper and lower ends. A pair of contacts 2 and 3 and a cylindrical conductive sleeve 5 that accommodates the compression coil spring 4 are provided.
[0009]
Here, the upper contact 2 of the pair of upper and lower contacts 2 and 3 has a solder ball contact portion 2a extending upward from the flange portion 2b and a cylindrical portion 2c extending downward from the flange portion 2b, such as brass. It is manufactured by cutting a copper alloy conductive member. Then, a plating layer such as gold plating on a nickel base is formed over the entire upper contact 2. The solder ball contact portion 2a receives and contacts the solder ball S of the semiconductor package P. The cylindrical portion 2c is press-fitted and fixed into the conductive sleeve 5 from the upper end opening 5a of the conductive sleeve 5, and a spring accommodating recess 2d is provided inside. The press-fitting allowance L1 of the cylindrical portion 2c with respect to the conductive sleeve 5 is the same length as the protruding length L11 of the upper contact 2 from the conductive sleeve 5, and the ratio of the press-fit allowance L1 to the total length of the upper contact 2 is compared. Is getting bigger. For this reason, it is difficult for the upper contact 2 to tilt with respect to the conductive sleeve 5, and the positional accuracy of the solder ball contact portion 2a can be made high. Further, since the conductive sleeve 5 is also difficult to tilt with respect to the upper contact 2, the lower contact 3 accommodated in the conductive sleeve 5 is also aligned without shaking with respect to the upper contact 2, and the spring contact 1 as a whole in use. Can be suppressed.
[0010]
The lower contact 3 has a large diameter portion 3b having an outer diameter slightly smaller than the inner diameter of the conductive sleeve 5 and accommodated in the conductive sleeve 5, and is made of a copper alloy conductive member such as brass. It is formed by cutting. Then, a plating layer such as gold plating on a nickel base is formed over the entire lower contact 3. At the lower end of the large diameter portion 3b, a substrate contact portion 3a having an outer diameter smaller than that of the large diameter portion 3b extends downward. The board contact portion 3a is urged downward by the compression coil spring 4 and can protrude from the lower end opening 5b of the conductive sleeve 5, and its conical tip comes into contact with the circuit board PCB. A spring accommodating recess 3c is provided inside the large diameter portion 3b.
[0011]
In the lower contact 102 of the spring contact 100 shown in FIG. 6, the cylindrical portion 102b is formed by performing deep lathe processing in order to form the accommodating portion for accommodating the compression coil spring 103. In order to form the two spring accommodating recesses 2d and the spring accommodating recess 3c of the lower contact 3, only a relatively shallow lathe process is required, so that it is possible to easily manufacture a component accommodating the compression coil spring.
[0012]
The compression coil spring 4 has both upper and lower ends accommodated in the spring accommodating recess 2d of the upper contact 2 and the spring accommodating recess 3c of the lower contact 3, and the upper and lower contacts 2, 3 are separated from each other, that is, the lower contact 3 is positioned downward. Energize in the direction. On the lower end of the conductive sleeve 5, a reduced diameter portion 5 c that is caulked inward is formed. The shoulder formed at the transition part of the large diameter part 3b of the lower contact 3 and the substrate contact part 3a abuts on the reduced diameter part 5c, and the downward movement of the lower contact 3 is restricted.
[0013]
The conductive sleeve 5 is formed from a tube made of a copper alloy such as brass, and a plating layer such as gold plating on a nickel base is formed on the outer peripheral surface and the inner peripheral surface thereof. In forming this plating layer, the conductive sleeve 5 has openings 5a and 5b at the upper and lower ends thereof, so that the plating solution passes through the inside satisfactorily and a uniform plating layer is formed on the inner periphery of the conductive sleeve 5. It can be formed easily. For this reason, even if the outer diameter of the conductive sleeve 5 is reduced and the depth thereof is increased, the problem of uneven formation of the plating layer due to the ingress of the plating solution can be solved, and the high density of the spring contact 1 Implementation is also possible. Tapered tapered surfaces 5d and 5e are formed on the outer surfaces of the upper and lower ends of the conductive sleeve 5. The tapered surfaces 5d and 5e facilitate the formation of the reduced diameter portion 5c, that is, the caulking process, and eliminate the vertical direction of the conductive sleeve 5 during assembly, thereby facilitating the manufacture of the spring contact 1. .
[0014]
The lower end surface of the cylindrical portion 2c of the upper contact 2 and the upper end surface of the large-diameter portion 3b of the lower contact 3 constitute opposing end surfaces 6 and 7, which are opposed to each other. 4 are in contact with each other when compressed. The opposed end surfaces 6 and 7 are flat surfaces. For this reason, the opposing end surfaces 6 and 7 can be easily processed, and the upper contact 2 and the lower contact 3 can be easily manufactured by cutting.
[0015]
To assemble the spring contact 1, first, the cylindrical portion 2 c of the upper contact 2 is press-fitted into the conductive sleeve 5 from the upper end opening 5 a side until the flange portion 2 b comes into contact with the end surface of the conductive sleeve 5. Next, the compression coil spring 4 is inserted into the spring accommodating recess 2 d from the lower end opening 5 b side of the conductive sleeve 5. Then, the lower contact 3 may be inserted into the conductive sleeve 5 so as to cover the compression coil spring 4 from the large diameter portion 3b side, and the lower end of the conductive sleeve 5 may be crimped inward.
[0016]
Next, the operation of the spring contact 1 will be described.
As shown in FIG. 1, in a state where the substrate contact portion 3a of the lower contact 3 is in contact with the circuit board PCB of the test apparatus, the solder ball S of the semiconductor package P is brought into contact with the solder ball contact portion 2a of the upper contact 2. The package P is pressed downward. Then, while the compression coil spring 4 is compressed, the upper contact 2 and the conductive sleeve 5 fixed thereto move downward, and the lower contact 3 moves relatively upward. When the compression coil spring 4 is further compressed, the opposed end surface 6 of the upper contact 2 and the opposed end surface 7 of the lower contact 3 come into contact with each other. When the opposing end surfaces 6 and 7 come into contact with each other, the current from the solder ball S side of the semiconductor package P causes the ball contact portion 2a of the upper contact 2, the cylindrical portion 2c, the large diameter portion 3b of the lower contact 3, and the substrate contact. The current flows from the circuit board PCB side through the reverse path through the part 3a to the circuit board PCB of the test apparatus. For this reason, the current flows directly between the contacts, the conductive path becomes the shortest, and it can be made suitable for high-speed transmission.
[0017]
On the other hand, when the compression of the compression coil spring 4 is advanced by pressing the semiconductor package P downward, a lateral pressure acts on the conductive sleeve 5 or the lower contact 3, and the opposing end face 6 of the upper contact 2 and the lower contact 3 face each other. There is a case where the end surface 7 does not contact properly. In this case, the inner peripheral surface of the conductive sleeve 5 and the outer peripheral surface of the large-diameter portion 3b of the lower contact 3 are in contact with each other, and the current from the solder ball S side of the semiconductor package P is in contact with the ball contact portion 2a of the upper contact 2, The conductive sleeve 5, the large diameter portion 3b of the lower contact 3, and the substrate contact portion 3a flow to the circuit board PCB of the test apparatus, and the current from the circuit board PCB flows through the reverse path. . Thus, even when the conductive path is a detour path passing through the surrounding conductive sleeve 5, the plating layer is uniformly formed on the outer periphery of the lower contact 3, and the plating layer is uniform on the inner peripheral surface of the conductive sleeve 5. Therefore, a conductive path with low contact resistance can be obtained.
[0018]
Next, the second embodiment of the spring contact according to the present invention. 1 The embodiment will be described with reference to FIGS. FIG. 2 shows a second embodiment of the spring contact according to the present invention. 1 FIG. 3 is a longitudinal sectional view of the spring contact shown in FIG. 2. However, the conductive sleeve is omitted in FIG.
The spring contact 21 shown in FIGS. 2 and 3 has substantially the same configuration as that of the spring contact 1 shown in FIG. 1, but the opposed end surfaces 26 and 27 of the pair of upper and lower contacts 22 and 23 extend in the vertical direction. It differs in that it is composed of a typical corrugated surface. That is, the spring contact 21 has a pair of upper and lower contacts 22 and 23, a compression coil spring 24 that urges the contacts 22 and 23 away from each other, and openings 25a and 25b at both upper and lower ends. A pair of contacts 22 and 23 and a cylindrical conductive sleeve 25 that accommodates a compression coil spring 24 are provided.
[0019]
Here, of the pair of upper and lower contacts 22, 23, the upper contact 22 has a solder ball contact portion 22a extending upward from the flange portion 22b and a cylindrical portion 22c extending downward from the flange portion 22b. Similarly to the upper contact 2 shown in FIG. 1, the upper contact 22 is manufactured by cutting a conductive member of a copper alloy such as brass. Then, a plating layer such as gold plating on a nickel base is formed over the entire upper contact 22. The solder ball contact portion 22a receives and contacts the solder ball S of the semiconductor package P shown in FIG. The cylindrical portion 22c is press-fitted and fixed into the sleeve 25 from the upper end opening 25a of the conductive sleeve 25, and has a spring accommodating recess 22d therein. The press-fit allowance L2 of the cylindrical portion 22c with respect to the conductive sleeve 25 is significantly longer than the protruding length L22 of the upper contact 22 from the conductive sleeve 25, and the ratio of the press-fit allowance L2 to the total length of the upper contact 22 is It is getting bigger. For this reason, the upper contact 22 hardly tilts with respect to the conductive sleeve 25, and the positional accuracy of the solder ball contact portion 22a can be increased. Further, since the conductive sleeve 25 is also difficult to tilt with respect to the upper contact 22, the lower contact 23 accommodated inside the conductive sleeve 25 is also aligned without being shaken with respect to the upper contact 22, and the spring contact 21 as a whole in use. Can be suppressed.
[0020]
The lower contact 23 has an outer diameter slightly smaller than the inner diameter of the conductive sleeve 25 and is accommodated in the conductive sleeve 25, and extends downward from the lower end of the large diameter portion 23b. And a substrate contact portion 23a having an outer diameter smaller than that of the diameter portion 23b. Similarly to the lower contact 3 shown in FIG. 1, the lower contact 23 is also manufactured by cutting a conductive member of a copper alloy such as brass. Then, a plating layer such as gold plating on a nickel base is formed over the entire lower contact 23. The board contact portion 23a is urged downward by the compression coil spring 24 and can protrude from the lower end opening 25b of the conductive sleeve 25, and its conical tip contacts the circuit board PCB of the test apparatus shown in FIG. It is like that. A spring accommodating recess 23c is provided inside the large diameter portion 23b.
[0021]
As in the case of the spring contact 1 shown in FIG. 1, since the spring accommodating recess 22d of the upper contact 22 and the spring accommodating recess 23c of the lower contact 23 are formed by relatively shallow lathe processing, the compression coil spring is accommodated. This makes it easy to manufacture parts to be manufactured.
The compression coil spring 24 has both upper and lower ends accommodated in the spring accommodating recess 22d of the upper contact 22 and the spring accommodating recess 23c of the lower contact 23, and the upper and lower contacts 22, 23 are separated from each other, that is, the lower contact 23 is positioned downward. Energize in the direction. At the lower end of the conductive sleeve 25, a reduced diameter portion 25c caulked inside is formed. The large diameter portion 23b of the lower contact 23 and the shoulder portion formed at the transition portion of the substrate contact portion 23a abut against the reduced diameter portion 25c, and the downward movement of the lower contact 23 is restricted.
[0022]
As with the conductive sleeve 5 shown in FIG. 1, the conductive sleeve 25 is formed from a tube made of a copper alloy such as brass, and a plating layer such as gold plating on a nickel base is formed on the outer peripheral surface and inner peripheral surface thereof. The When forming the plating layer, the conductive sleeve 25 has openings 25a and 25b at both upper and lower ends thereof, so that the plating solution passes through the inside satisfactorily and a uniform plating layer is formed on the inner periphery of the conductive sleeve 25. It can be formed easily. For this reason, even if the outer diameter of the conductive sleeve 25 is reduced and the depth thereof is increased, the problem of uneven formation of the plating layer due to the ingress of the plating solution can be solved, and the high density mounting of the spring contact 21 is achieved. Is also possible. Further, taper tapered surfaces 25d and 25e are formed on the outer surfaces of the upper and lower ends of the conductive sleeve 25 as in the case of the conductive sleeve 5 of FIG.
[0023]
The lower end surface of the cylindrical portion 22c of the upper contact 22 and the upper end surface of the large-diameter portion 23b of the lower contact 23 constitute opposing end surfaces 26 and 27 that are opposed to each other, and these opposing end surfaces 26 and 27 are compression coil springs. 24 are in contact with each other when compressed. The opposing end surfaces 26 and 27 are formed of substantially complementary corrugated surfaces extending in the vertical direction. In the opposed end faces 26 and 27, the number of projecting portions entering the counterpart contact is two in this embodiment. In addition, a groove 28 extending in the upward direction is provided at the apex portion of the concave surface into which the protruding portion of the lower contact 23 enters among the facing end surface 26 configured by the corrugated surface of the upper contact 22.
[0024]
The operation of the spring contact 21 will be described. The solder ball S of the semiconductor package P is brought into contact with the solder ball contact portion 22a of the upper contact 22 while the substrate contact portion 23a of the lower contact 23 is in contact with the circuit board PCB of the test apparatus. Then, the semiconductor package P is pressed downward. Then, while the compression coil spring 24 is compressed, the upper contact 22 and the conductive sleeve 25 move downward, and the lower contact 23 moves relatively upward. During the movement of the upper contact 22, the upper contact 22 moves downward while slightly rotating due to the torsion of the compression coil spring 24 during compression, and the opposed end surfaces 26 and 27 are complementary corrugated surfaces extending in the vertical direction. The upper contact 22 moves downward while the opposing end faces 26 and 27 are in contact with each other. The wiping effect between the opposing end faces 26 and 27 improves the reliability of electrical connection between the upper and lower contacts 22 and 23. Then, when the compression of the compression coil spring 24 further proceeds, the compression is stopped in a state where the opposed end surface 26 of the upper contact 22 and the opposed end surface 27 of the lower contact 23 are in contact with each other. At this time, since the opposed end surfaces 26 and 27 are formed of substantially complementary corrugated surfaces extending in the vertical direction, the upper and lower contacts 22 and 23 contact at more points than the upper and lower contacts shown in FIGS. Further, the reliability of electrical connection is further improved. Moreover, since the groove | channel 28 containing a circular arc part is provided in the opposing end surface 26 of the upper contact 22, generation | occurrence | production of the crack by stress concentration can be prevented. The opposing end surface 26 of the upper contact 22 is an inclined surface region that gradually inclines at an acute angle with respect to the outer surface 22e of the upper contact 22 from the intersection with the groove 28 at the apex to the lower end 26a. Further, the opposed end surface 27 of the lower contact 23 is gradually inclined at an acute angle with respect to the outer surface 23e of the lower contact 23 from the apex portion to the lower end 27a so as to correspond to the inclined surface region of the opposed end surface 26 of the upper contact 22. It is an inclined surface area. For this reason, since the opposing end surface 26 of the upper contact 22 and the opposing end surface 27 of the lower contact 23 are in contact with each other, the contact area between the opposing end surfaces 26 and 27 is increased, and the reliability of electrical connection is further increased. improves. When the opposing end surfaces 26 and 27 come into contact with each other, the current from the solder ball S side of the semiconductor package P causes the ball contact portion 22a of the upper contact 22, the cylindrical portion 22c, the large diameter portion 23b of the lower contact 23, and It flows to the circuit board PCB through the board contact portion 23a, and the current from the circuit board PCB side flows through the reverse path. For this reason, the current flows directly between the contacts, the conductive path becomes the shortest, and it can be made suitable for high-speed transmission.
[0025]
On the other hand, when the compression of the compression coil spring 24 proceeds by pressing the semiconductor package P downward, a lateral pressure acts on the conductive sleeve 25 or the lower contact 23, and the opposing end face 26 of the upper contact 22 and the lower contact 23 face each other. There is a case where the end surface 27 does not contact properly. In this case, the inner peripheral surface of the conductive sleeve 25 and the outer peripheral surface of the large-diameter portion 23b of the lower contact 23 are in contact with each other, and the current from the solder ball S side of the semiconductor package P is the ball contact portion 22a of the upper contact 22, It flows to the circuit board PCB of the test apparatus through the conductive sleeve 25, the large diameter part 23b of the lower contact 23, and the board contact part 23a, and the current from the circuit board PCB side flows through the reverse path. . Thus, even when the conductive path is a detour path passing through the surrounding conductive sleeve 25, the plating layer is uniformly formed on the outer periphery of the lower contact 23, and the plating layer is uniform on the inner peripheral surface of the conductive sleeve 25. Therefore, a conductive path with low contact resistance can be obtained.
[0026]
Finally, the spring contact according to the present invention 2 The embodiment will be described with reference to FIGS. 4 and 5. FIG. 4 shows a second embodiment of the spring contact according to the present invention. 2 FIG. 5 is a longitudinal sectional view of the spring contact shown in FIG. 4. In FIG. 4, the sleeve is shown with its front side omitted.
The spring contact 31 shown in FIGS. 4 and 5 has substantially the same configuration as the spring contact 21 shown in FIGS. 2 and 3, but the opposed end faces 36 and 37 of the pair of upper and lower contacts 32 and 33 are in the vertical direction. The difference is that it is constituted by extending substantially complementary sawtooth-shaped surfaces. That is, the spring contact 31 has a pair of upper and lower contacts 32 and 33, a compression coil spring 34 that urges the contacts 32 and 33 away from each other, and openings 35a and 35b at both upper and lower ends. A pair of contacts 32 and 33 and a cylindrical conductive sleeve 35 that accommodates a compression coil spring 34 are provided.
[0027]
Here, of the pair of upper and lower contacts 32 and 33, the upper contact 32 has a solder ball contact portion 32a extending upward from the flange portion 32b and a cylindrical portion 32c extending downward from the flange portion 32b. Similarly to the upper contact 22 shown in FIG. 2, the upper contact 32 is manufactured by cutting a conductive member of a copper alloy such as brass. Then, a plating layer such as gold plating on a nickel base is formed over the entire upper contact 32. The solder ball contact portion 32a receives and contacts the solder ball S of the semiconductor package P shown in FIG. The cylindrical portion 32c is press-fitted and fixed into the sleeve from the upper end opening 35a of the conductive sleeve 35, and has a spring accommodating recess 32d therein. The press-fit allowance L3 with respect to the conductive sleeve 35 of the cylindrical portion 32c is longer than the protruding length L33 of the upper contact 32 from the conductive sleeve 35, and the ratio of the press-fit allowance L3 to the total length of the upper contact 32 is increased. ing. For this reason, the upper contact 32 is not easily inclined with respect to the conductive sleeve 35, and the positional accuracy of the solder ball contact portion 32a can be increased. Further, since the conductive sleeve 35 is also difficult to tilt with respect to the upper contact 32, the lower contact 33 accommodated inside the conductive sleeve 35 is also aligned without shaking with respect to the upper contact 32, and the spring contact 31 as a whole in use. Can be suppressed.
[0028]
The lower contact 33 has an outer diameter slightly smaller than the inner diameter of the conductive sleeve 35 and is accommodated in the conductive sleeve 35, and extends downward from the lower end of the large diameter portion 33b. And a substrate contact portion 33a having an outer diameter smaller than that of the diameter portion 33b. Similarly to the lower contact 23 shown in FIG. 3, the lower contact 33 is also manufactured by cutting a conductive member of a copper alloy such as brass. Then, a plating layer such as gold plating on a nickel base is formed over the entire lower contact 33. The board contact portion 33a is urged downward by the compression coil spring 34 and can protrude from the lower end opening 35b of the conductive sleeve 35, and its conical tip contacts the circuit board PCB of the test apparatus shown in FIG. It is like that. A spring accommodating recess 33c is provided inside the large diameter portion 33b.
[0029]
As in the case of the spring contact 21 shown in FIG. 2, since the spring accommodating recess 32d of the upper contact 32 and the spring accommodating recess 33c of the lower contact 33 are formed by a relatively shallow lathe, the compression coil spring is accommodated. This makes it easy to manufacture parts to be manufactured.
The compression coil spring 34 has both upper and lower ends accommodated in the spring accommodating recess 32d of the upper contact 32 and the spring accommodating recess 33c of the lower contact 33, and the upper and lower contacts 32, 33 are separated from each other, that is, the lower contact 33 is lowered. Energize in the direction. At the lower end of the conductive sleeve 35, a reduced diameter portion 35c caulked inside is formed. The large diameter portion 33b of the lower contact 33 and the shoulder portion formed at the transition portion of the substrate contact portion 33a abut against the reduced diameter portion 35c, and the downward movement of the lower contact 33 is restricted.
[0030]
As with the conductive sleeve 25 shown in FIG. 2, the conductive sleeve 35 is formed from a tube made of a copper alloy such as brass, and a plating layer such as gold plating on a nickel base is formed on the outer peripheral surface and the inner peripheral surface thereof. The When forming the plating layer, the conductive sleeve 35 has openings 35a and 35b at both upper and lower ends thereof, so that the plating solution passes through the inside satisfactorily and a uniform plating layer is formed on the inner periphery of the conductive sleeve 35. It can be formed easily. For this reason, even if the outer diameter of the conductive sleeve 35 is reduced and the depth thereof is increased, the problem of uneven formation of the plating layer due to the ingress of the plating solution can be solved, and the high density mounting of the spring contact 31 is achieved. Is also possible. Further, tapered surfaces 35d and 35e are formed on the outer surfaces of the upper and lower ends of the conductive sleeve 35 in the same manner as the conductive sleeves 5 and 25 of FIGS.
[0031]
The lower end surface of the cylindrical portion 32c of the upper contact 32 and the upper end surface of the large-diameter portion 33b of the lower contact 23 constitute opposing end surfaces 36 and 37 that oppose each other, and these opposing end surfaces 36 and 37 are compression coil springs. 34 are in contact with each other when compressed. The opposed end surfaces 36 and 37 are substantially complementary sawtooth surfaces extending in the vertical direction. In the opposed end faces 36 and 37, the number of projecting portions entering the counterpart contact is three in this embodiment. For this reason, since the number of projecting portions entering the counterpart contact is larger than the opposing end faces 26 and 27 of the upper and lower contacts 22 and 23 shown in FIG. 2, the upper and lower contacts 32 and 33 are larger than the upper and lower contacts 22 and 23 shown in FIG. Contact at points further improves the reliability of the electrical connection.
[0032]
The action of the spring contact 31 will be described. The solder ball S of the semiconductor package P is brought into contact with the solder ball contact portion 32a of the upper contact 32 in a state where the substrate contact portion 33a of the lower contact 33 is in contact with the circuit board PCB of the test apparatus. Then, the semiconductor package P is pressed downward. Then, while the compression coil spring 34 is compressed, the upper contact 32 and the conductive sleeve 35 move downward, and the lower contact 33 moves relatively upward. When the upper contact 32 moves, the upper contact 32 moves downward while slightly rotating due to the influence of the torsion of the compression coil spring 34 during compression, and the opposed end faces 36 and 37 extend in the vertical direction. The upper contact 32 moves downward while the opposed end surfaces 36 and 37 are in contact with each other because of the configuration of the surfaces. Due to the wiping effect between the opposing end faces 36 and 37, the reliability of the electrical connection of the upper and lower contacts 32 and 33 is improved in the same manner as the spring contact 21 shown in FIG. Then, when the compression of the compression coil spring 34 further proceeds, the compression is stopped while the opposed end surface 36 of the upper contact 32 and the opposed end surface 37 of the lower contact 33 are in contact with each other. At this time, since the opposing end surfaces 36 and 37 are formed of substantially complementary sawtooth surfaces extending in the vertical direction, the upper and lower contacts 32 and 33 are in contact with each other at more points than the upper and lower contacts shown in FIG. The reliability of the connection is further improved. Further, the opposing end surface 36 of the upper contact 32 is an inclined surface region that gradually inclines at an acute angle with respect to the outer surface 32e of the upper contact 32 from the apex portion to the lower end 36a. Further, the opposed end surface 37 of the lower contact 33 is gradually inclined at an acute angle with respect to the outer surface 33e of the lower contact 33 from the apex portion to the lower end 37a so as to correspond to the inclined surface region of the opposed end surface 36 of the upper contact 32. It is an inclined surface area. For this reason, since the opposing end surface 36 of the upper contact 32 and the opposing end surface 37 of the lower contact 33 are in contact with each other, the contact area between the opposing end surfaces 36 and 37 is increased, and the reliability of electrical connection is further increased. improves. When the opposing end surfaces 36 and 37 come into contact with each other, the current from the solder ball S side of the semiconductor package P causes the ball contact portion 32a of the upper contact 32, the cylindrical portion 32c, the large diameter portion 33b of the lower contact 33, and It flows to the circuit board PCB through the board contact portion 33a, and the current from the circuit board PCB side flows through the reverse path. For this reason, the current flows directly between the contacts, the conductive path becomes the shortest, and it can be suitable for high-speed transmission.
[0033]
On the other hand, when the compression of the compression coil spring 34 is progressed by pressing the semiconductor package P downward, a lateral pressure acts on the conductive sleeve 35 or the lower contact 33, and the opposing end face 36 of the upper contact 32 and the lower contact 33 face each other. There is a case where the end surface 37 does not contact properly. In this case, the inner peripheral surface of the conductive sleeve 35 and the outer peripheral surface of the large-diameter portion 33b of the lower contact 33 are in contact with each other, and the current from the solder ball S side of the semiconductor package P is caused by the ball contact portion 32a of the upper contact 32, It flows to the circuit board PCB of the test apparatus through the conductive sleeve 35, the large diameter part 33b of the lower contact 33, and the board contact part 33a, and the current from the circuit board PCB side flows through the reverse path. . Thus, even when the conductive path is a detour path passing through the surrounding conductive sleeve 35, the plating layer is uniformly formed on the outer periphery of the lower contact 33, and the plating layer is even on the inner peripheral surface of the conductive sleeve 35. Therefore, a conductive path with low contact resistance can be obtained.
[0034]
【The invention's effect】
As described above, according to the spring contact according to the first aspect of the present invention, the upper and lower ends are opened, and the upper and lower pair of contacts and the compression coil spring are accommodated, and one of the upper and lower pair of contacts. Since the conductive sleeve is provided separately from the pair of upper and lower contacts fixed to the contact, the plating layer is formed on the inner peripheral surface of the conductive sleeve because the upper and lower ends of the conductive sleeve are open. Even if the outer diameter of the conductive sleeve is reduced and the depth thereof is increased, the problem of uneven formation of the plating layer due to the ingress of the plating solution can be eliminated and the spring can be formed easily. It is possible to enable high-density mounting of contacts. Even when the pair of upper and lower contacts do not contact each other, the plating layer is uniformly formed on the inner peripheral surface of the separate conductive sleeve, so that the contact through the upper contact, the conductive sleeve, and the lower contact A conductive path with low resistance can be formed.
[0035]
Further, according to the spring contact according to claim 2 of the present invention, in the invention according to claim 1, since the tapered sleeve surfaces are formed on both outer surfaces of the conductive sleeve, the caulking at one end is formed. In addition to facilitating processing, since the up-down direction of the conductive sleeve is eliminated when the spring contact is assembled, the manufacture of the spring contact can be facilitated.
[Brief description of the drawings]
[Figure 1] The Pulling contact Reference example FIG.
FIG. 2 shows a first contact of a spring contact according to the present invention. 1 It is a perspective view of an embodiment. However, the conductive sleeve is omitted in FIG.
3 is a longitudinal sectional view of the spring contact shown in FIG. 2. FIG.
FIG. 4 shows a first contact of a spring contact according to the present invention. 2 It is a perspective view of an embodiment.
5 is a longitudinal sectional view of the spring contact shown in FIG. 4. FIG.
FIG. 6 is a longitudinal sectional view of a conventional spring contact.
[Explanation of symbols]
1, 21, 31 Spring contact
2,22,32 Top contact
3,23,33 Lower contact
4, 24, 34 Compression coil spring
5, 25, 35 Conductive sleeve
5a, 5b, 25a, 25b, 35a, 35b Opening
5d, 5e, 25d, 25e, 35d, 35e Tapered surface

Claims (2)

A pair of upper and lower contacts, a compression coil spring that urges the pair of contacts in a direction away from each other , and upper and lower ends open to accommodate the pair of contacts and the compression coil spring, and the pair of contacts A spring contact that is fixed to one of the contacts and includes a conductive sleeve separate from the pair of upper and lower contacts;
The pair of upper and lower contacts each have a spring accommodating recess that receives an end of the compression coil spring,
A spring contact characterized in that opposing end surfaces of the pair of upper and lower contacts are formed by substantially complementary corrugated surfaces or sawtooth surfaces extending in the vertical direction .   The spring contact according to claim 1, wherein tapered surfaces are formed on outer surfaces of both ends of the conductive sleeve.

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