JP2021181933A - Vertical contact probes, probe cards and sockets - Google Patents

Abstract

To provide a vertical contact type probe, a probe card, and a socket that are excellent in durability even in an inspection of a DUT with a small electrode interval that is a semiconductor IC or a packaged semiconductor, and can be used in a high frequency inspection of a DUT with a high operation frequency.SOLUTION: A vertical contact type probe 1 inspects a DUT by bringing a second end 20b of a first needle-shaped conductive member 20 into contact with an electrode of the DUT, in a state in which the first needle-shaped conductive member 20 extends on a first surface 10a side of an elastomer connector 10 in a thickness direction of an elastomer sheet 12; a first end 20a of the first needle-shaped conductive member 20 is in contact with a thin metallic wire 14; a second needle-shaped conductive member 30 extends on a second surface 10b side of the elastomer connector 10 in the thickness direction of the elastomer sheet 12; a first end 30a of the second needle-shaped conductive member 30 is in contact with the thin metallic wire 14; and a second end 30b of the second needle-shaped conductive member 30 is in contact with an electrode terminal of a circuit board.SELECTED DRAWING: Figure 2

Description

The present invention relates to vertical contact probes, probe cards and sockets.

Semiconductor devices such as BGA (Ball Grid Array), LGA (Land Grid Array), QFP (Quad Flat Package), and CSP (Chip Size Package) have IC chips mounted in the package. In the manufacture of such packaged semiconductor devices, each semiconductor IC in a semiconductor wafer on which a large number of semiconductor ICs are formed is electrically inspected (on-wafer inspection) in a wafer state, and then the wafer is cut. Chip into a shape. The chip is called an IC chip. After that, the non-defective IC chips selected in the on-wafer inspection are mounted in a package made of ceramic or plastic and packaged. After that, a process of finally conducting an electrical inspection of the packaged product (called a packaged semiconductor) is performed. In the on-wafer inspection, the probe attached to the probe card is brought into contact with the electrode of the semiconductor IC (DUT) to be measured to make an electrical connection with the measuring instrument. On the other hand, in the inspection of a packaged semiconductor, an individual packaged semiconductor (DUT) to be measured is inserted and mounted in a socket, and the electrode of the package is brought into contact with a probe mounted in the socket to make an electrical connection with the measuring instrument. conduct.
Here, the semiconductor IC and the packaged semiconductor are collectively referred to as a semiconductor element. The present invention relates to a probe that can be applied to both a probe card and a socket for inspecting a semiconductor device.

In Patent Document 1, a conductive needle-shaped member held by a holder and a socket body having a mounting portion are provided on the upper side of an elastomer connector in which a plurality of thin metal wires are diagonally inserted into an elastomer sheet, and the elastomer connector is provided. A socket provided with a circuit board on the lower side is disclosed. In the socket, the electrode terminal of the circuit board is in contact with the lower end of the thin metal wire, and the lower end of the needle-shaped member is in contact with the upper end of the thin metal wire. Further, when the DUT is mounted on the mounting portion of the socket body, the electrode of the DUT contacts the upper end of the needle-shaped member, so that the electrode of the DUT and the electrode terminal of the circuit board are connected via the metal wire and the needle-shaped member. Then, the DUT can be inspected.

Japanese Patent No. 3233193

In a socket as in Patent Document 1, when the DUT is brought into contact during inspection, the elastomer connector is compressed and deformed in the thickness direction. Therefore, the metal thin wire inserted diagonally is further inclined due to the compression deformation of the elastoma connector, and the tip of the metal fine wire slides in the surface direction of the elastoma connector and rubs against the electrode of the circuit board. PCBs (Printed Circuit Boards) such as FR-4, which are generally used as circuit boards, have a thickness of a metal film such as Cu that forms a circuit pattern on the order of several tens of μm, and are inspected even if the tip of a thin metal wire is repeatedly rubbed during inspection. Is unlikely to cause any problems.

On the other hand, both the electrodes of semiconductor ICs and the electrodes of packaged semiconductors are becoming finer pitched, and the electrode terminals with fine pitches are used in both on-wafer inspection of semiconductor ICs by probe cards and in inspection of packaged semiconductors by sockets. A circuit board to have is required. A soft and thin Au thin film is mainly used for fine pitching of the circuit pattern of the circuit board. Therefore, in a probe such as that used for the socket of Patent Document 1, the Au thin film of the circuit board is easily consumed due to repeated rubbing of the thin metal wire, and it is difficult to obtain sufficient durability.

Further, since semiconductor devices are becoming higher in frequency, it is also important that probes used for probe cards and sockets can be applied to high frequency inspection of DUTs having extremely high operating frequencies.

INDUSTRIAL APPLICABILITY The present invention is a vertical contact probe, which has excellent durability in inspection of a semiconductor element (DUT) having a small electrode spacing, that is, a semiconductor IC or a packaged semiconductor, and can also be used for high-frequency inspection of a DUT having a high operating frequency. It is an object of the present invention to provide a probe card and a socket provided with a contact probe.

The present invention has the following configurations.
[1] A vertical contact probe for inspecting a semiconductor element in a state where an electrode of a semiconductor IC or a packaged semiconductor is in contact with an electrode terminal of a circuit board, and has an elastoma connector and one or more first needles. A conductive member, one or more second needle-shaped conductive members, a first holder, and a second holder are provided, and the elastoma connector is a plurality of elastoma sheets inserted in the thickness direction of the elastoma sheet. The first needle-shaped conductive member includes a thin metal wire, and the first needle-shaped conductive member is in contact with the thin metal wire on the first surface side of the elastoma connector, and the first end of the first needle-shaped conductive member is in contact with the thin metal wire, in the thickness direction of the elastoma sheet. The second needle-shaped conductive member is held by the first holder in a state of extending to the second needle-shaped conductive member, and the first end of the second needle-shaped conductive member is in contact with the metal wire on the second surface side of the elastoma connector. The first needle-shaped conductive member is held by the second holder in a state of extending in the thickness direction of the elastoma sheet, and the second end of the second needle-shaped conductive member is in contact with the electrode terminal. A vertical contact probe that inspects the semiconductor element by bringing the second end of the conductor into contact with the electrode.
[2] The vertical contact probe according to [1], wherein the shape of the second needle-shaped conductive member is a columnar shape in which both the first end and the second end are flat.
[3] The vertical contact type probe according to [1] or [2] and a circuit board provided with an electrode terminal are provided, and in the vertical contact type probe, the first needle-shaped conductive member is under the elastoma connector. The second needle-shaped conductive member is located on the upper side of the elastoma connector, and the circuit board is in vertical contact with the second end of the second needle-shaped conductive member in contact with the electrode terminal. A probe card provided on the upper side of the mold probe.
[4] The vertical contact probe according to [1] or [2], a circuit board provided with electrode terminals, and a socket body provided with a mounting portion for detachably mounting a packaged semiconductor are provided. In the vertical contact type probe, the first needle-shaped conductive member is located above the elastoma connector, the second needle-shaped conductive member is located below the elastoma connector, and the circuit board is the first. The second end of the two-needle-shaped conductive member is provided under the vertical contact probe in a state of being in contact with the electrode terminal, and the socket body has the first packaged semiconductor electrode mounted on the mounting portion. A socket positioned above the vertical contact probe, positioned to contact the second end of the needle-like conductive member.

According to the present invention, the vertical contact probe, which has excellent durability even in the inspection of a semiconductor element having a small electrode spacing, that is, a semiconductor IC or a packaged semiconductor, and can be used for high frequency inspection of a DUT having a high operating frequency, said vertical contact. Probe cards and sockets with type probes can be provided.

It is a top view which showed the vertical contact type probe of this embodiment. FIG. 1 is a cross-sectional view taken along the line II of the vertical contact probe of FIG. It is sectional drawing which showed the probe card of this embodiment. It is sectional drawing which showed the socket of this embodiment. It is a measurement result of the high frequency characteristic (S parameter) of the socket of Example 1.

[Vertical contact probe]
The vertical contact probe of the present invention is a vertical contact probe for inspecting a semiconductor element in a state where the electrode of a semiconductor element, that is, a semiconductor IC or a packaged semiconductor is in contact with an electrode terminal of a circuit board. The "vertical contact type" of the probe means that the probe is of a type in which the electrodes of the semiconductor element and the electrode terminals of the circuit board are brought into contact with each other above and below the probe at the time of inspection.

Hereinafter, an example of an embodiment of the vertical contact probe of the present invention will be described. It should be noted that the dimensions and the like of the figures exemplified in the following description are examples, and the present invention is not necessarily limited to them, and the present invention can be appropriately modified without changing the gist thereof. ..

FIG. 1 is a plan view showing the vertical contact probe 1 of the present embodiment. FIG. 2 is a cross-sectional view taken along the line II of the vertical contact probe 1. The vertical contact probe 1 is a probe having a form suitable for both a probe card and a socket.
The vertical contact probe 1 includes an elastomer connector 10, one or more first needle-shaped conductive members 20, one or more second needle-shaped conductive members 30, a first holder 40, and a second holder 50. It is equipped with.

The elastomer connector 10 includes an elastomer sheet 12 and a plurality of thin metal wires 14 inserted obliquely with respect to the thickness direction of the elastomer sheet 12.
The planar view shape of the elastomer sheet 12 in this example is rectangular. The planar view shape of the elastomer sheet 12 is not limited to a rectangular shape, and can be appropriately set according to the form of the DUT. The size of the elastoma sheet 12 can also be appropriately set according to the form of the DUT.

The average thickness of the elastomer sheet 12 is preferably 0.015 mm or more and 1 mm or less, and more preferably 0.03 mm or more and 0.5 mm or less. When the average thickness of the elastomer sheet 12 is at least the lower limit of the above range, the mechanical strength and rigidity are improved, and the handling becomes easy. When the average thickness of the elastomer sheet 12 is not more than the upper limit of the above range, the high frequency characteristics are excellent.

The elastoma constituting the elastoma sheet 12 is not particularly limited, and for example, an elastoma-like thermosetting resin such as a silicone resin or an epoxy resin, a synthetic rubber or polyethylene resin, a polyurethane resin, an ABS resin, a soft vinyl chloride resin or the like can be used. Examples thereof include thermoplastic resins. Silicone rubber is preferable because it has excellent environmental resistance and heat resistance. The elastomers constituting the elastomer sheet 12 may be one kind or two or more kinds.

The volume resistivity of the elastomer sheet 12 ^{is preferably 10 3} Ω · cm or more, and more preferably 10 ⁸ Ω · cm or more and 10 ¹⁹ Ω · cm or less.
The hardness of the elastomer sheet 12 is preferably 5 or more and 95 or less, and more preferably 10 or more and 90 or less.

Each of the thin metal wires 14 is slanted with respect to the thickness direction of the elastomer sheet 12 and is parallel to each other. Both ends of each metal wire 14 project from both sides of the elastomer sheet 12. The average length of the protruding portions at both ends of each metal wire 14 can be, for example, 5 μm or more and 60 μm or less. In addition, each thin metal wire 14 may be inserted in the thickness direction of the elastomer sheet 12 without being inclined. Further, as long as the contact between the thin metal wire 14 and the first needle-shaped conductive member 20 and the second needle-shaped conductive member 30 can be ensured at the time of inspection, both ends of each of the thin metal wires 14 are both sides and surfaces of the elastomer sheet 12. It may be in one position, or it may be in a position subducted from both sides of the elastomer sheet 12.

The average deviation (offset amount) of the elastomer sheets 12 at both ends of the metal thin wire 14 in the plane direction can be appropriately set according to the form of the DUT, and can be, for example, 0 mm or more and 2 mm or less. The offset amount of the thin metal wire 14 can be controlled by adjusting the thickness of the elastomer sheet 12 and the inclination angle of the thin metal wire 14 with respect to the thickness direction of the elastomer sheet 12.

The average wire diameter of the thin metal wire 14 is preferably 2 μm or more and 100 μm or less, and more preferably 5 μm or more and 50 μm or less. The wire diameter of the fine metal wire is the diameter of the cross section perpendicular to the length direction of the fine metal wire, and when the cross-sectional shape is not a circle, it is the diameter of the circumscribed circle.

The average density of the metal thin wires 14 in the plan view of the elastomer connector 10 and the average spacing between the metal thin wires 14 can be appropriately set according to the form of the DUT. The average density of the thin metal wires 14 can be, for example, 50 lines / mm ² or more and 120,000 lines / mm ² or less. The average distance between the thin metal wires 14 can be, for example, 1 μm or more and 50 μm or less.

As the material of the fine metal wire 14, a material having a volume resistance of 10 ^-1 Ω · cm or less can be used, for example, pure gold wire, gold alloy wire, gold-plated wire, solder wire, solder-plated wire, copper alloy wire, plating. CNT yarn with CNT, CNT yarn and the like can be mentioned. The thin metal wire 14 included in the elastomer connector 10 may be of one type or two or more types.

The elastomer connector 10 is held by being sandwiched between the first holder 40 and the second holder 50. The first holder 40 is arranged on the first surface 10a side of the elastomer connector 10, that is, on the lower side in this example. The second holder 50 is arranged on the second surface 10b side of the elastomer connector 10, that is, on the upper side in this example.

The plan-view shapes of the first holder 40 and the second holder 50 are not particularly limited, and are rectangular in this example.
In this example, a recess 41 having a shape complementary to the shape of the elastomer connector 10 is formed in the central portion of the first holder 40 on the side holding the elastomer connector 10 by counterbore processing. The depth of the recess 41 is preferably set to be about 10 to 20 μm smaller than the thickness of the elastomer connector 10. The size of the recess 41 in a plan view is set to be slightly larger than the size of the elastomer connector 10 in a plan view so that the elastomer connector 10 can be easily inserted.

Further, in the first holder 40 and the second holder 50, positioning pin holes 44 and 54 are formed on both sides of the recess 41 on the diagonal line in a plan view. Coupling screw insertion holes 46 and 56 are formed at the corners on both sides of the other diagonal line of the first holder 40 and the second holder 50 in a plan view. With the elastomer connector 10 fitted in the recess 41 and the positioning pins inserted in the positioning pin holes 44 and 54 for positioning, the coupling screws 60 are inserted into the coupling screw insertion holes 46 and 56 to form the first holder 40 and the first holder 40. The elastomer connector 10 is sandwiched by the two holders 50.
The form in which the elastomer connector 10 is held by the first holder 40 and the second holder 50 is not limited to the above-mentioned form as long as the elastomer connector 10 can be firmly positioned.

The material of the first holder 40 and the second holder 50 may be a dielectric, for example, an organic dielectric or an inorganic dielectric having a relative permittivity of 2 or more and 10 or less and a dielectric loss tangent of 0.01 or less. It can be exemplified. Examples of the organic dielectric include glass epoxy and the like. Examples of the inorganic dielectric include alumina and the like.

The first holder 40 has a plurality of insertion holes 42 extending from the outer surface 40a on the side opposite to the side in contact with the elastomer connector 10 toward the elastomer connector 10 at a position corresponding to the elastomer connector 10 in the central portion in a plan view. It is formed. By inserting the first needle-shaped conductive member 20 into the insertion hole 42, the first needle-shaped conductive member 20 is held in a state of extending in the thickness direction of the elastomer connector 10. The position and number of the insertion holes 42 are appropriately set according to the form of the DUT.

The plan view shape of the insertion hole 42 may be set according to the shape of the first needle-shaped conductive member 20, and is circular in this example.
The diameter of the insertion hole 42 takes into consideration the processing tolerance of each part so that the first needle-shaped conductive member 20 can be smoothly inserted and can move up and down with low friction, and the characteristic impedance does not become too high. Set. For example, the diameter of the insertion hole 42 can be set to a value about 5 to 15 μm larger than the diameter of the first needle-shaped conductive member 20.

The first needle-shaped conductive member 20 inserted through the insertion hole 42 is located on the first surface 10a side of the elastomer connector 10, extends in the thickness direction of the elastomer sheet 12, and is the first needle-shaped conductive member 20. The first end 20a is in contact with the first end 14a of the thin metal wire 14. As described above, each of the first needle-shaped conductive members 20 is held by the first holder 40 in a state parallel to each other in a direction in which the length direction is the thickness direction of the elastomer sheet 12.
The number of the first needle-shaped conductive members 20 is not particularly limited and can be appropriately set according to the form of the DUT.

The shape of the first needle-shaped conductive member 20 is not particularly limited. The first needle-shaped conductive member 20 of this example has a columnar main body portion 22 extending halfway from the first end 20a toward the second end 20b and a columnar column provided on the second end 20b side of the main body portion 22. The diameter-reduced portion 24 of the above is provided. The diameter of the reduced diameter portion 24 is smaller than the diameter of the main body portion 22. The shape of the insertion hole 42 is complementary to the first needle-shaped conductive member 20. Therefore, the portion around the opening of the insertion hole 42 on the outer surface 40a side (lower side) of the first holder 40 is supported by the lower end of the main body portion 22 of the first needle-shaped conductive member 20, so that the first needle-shaped conductive member 20 has a first needle shape. The conductive member 20 is prevented from falling off downward.

The diameter of the main body 22 can be appropriately set in consideration of high frequency characteristics. For example, the characteristic impedance is 50Ω according to the pitch between the first needle-shaped conductive members 20 and the dielectric constant of the material of the first holder 40. It can be set to be near.

The diameter of the reduced diameter portion 24 is smaller than the diameter of the main body portion 22, and is set within a range in which the first needle-shaped conductive member 20 does not fall out downward. If the difference between the diameter of the reduced diameter portion 24 and the diameter of the main body portion 22 is large, the characteristic impedance of the reduced diameter portion 24 becomes higher than 50Ω and the high frequency characteristics tend to deteriorate. Therefore, the diameter of the reduced diameter portion 24 is the first. It is preferable that the diameter of the main body 22 is as close as possible to the extent that the needle-shaped conductive member 20 can be prevented from falling.

The shorter the length of the main body portion 22 and the reduced diameter portion 24, the better the high frequency characteristics. Therefore, it is preferable to shorten the lengths as much as possible in consideration of the required specifications of the high frequency characteristics, the processing technique, and the ease of handling.

A part of the first needle-shaped conductive member 20 on the second end 20b side, that is, a part of the reduced diameter portion 24 protrudes from the outer surface 40a of the first holder 40. As a result, at the time of inspection, the second end 20b of the first needle-shaped conductive member 20 comes into contact with the electrode of the DUT. The length of the portion of the first needle-shaped conductive member 20 protruding from the first holder 40 is the second end 20b of the first needle-shaped conductive member 20 even when the second end 20b is brought into contact with the DUT electrode during inspection. It is set so that a part of the side protrudes from the first holder 40, but the protrusion length may be 0. The length of the portion of the first needle-shaped conductive member 20 protruding from the first holder 40 is set in consideration of the difference in thickness between the plurality of electrodes of the DUT and the amount of compression deformation of the elastomer connector 10.

The structure of the end surface of the second end 20b of the first needle-shaped conductive member 20 that comes into contact with the electrode of the DUT is set in consideration of contactability, ease of alignment, and the like according to the type of DUT. Examples of the structure of the end surface of the second end 20b of the first needle-shaped conductive member 20 include a flat structure, a needle structure, and a crown structure.

As the material of the first needle-shaped conductive member 20, a metal generally used for a member that comes into contact with a DUT electrode or an electrode terminal of a circuit board in a probe card or a socket can be used, and for example, Pd, W, BeCu, etc. can be used. Those that are hard to rust and are hard and hard to wear are preferable.

The second holder 50 is formed with a plurality of insertion holes 52 extending from the outer surface opposite to the side in contact with the elastomer connector 10 toward the elastomer connector 10 at a position corresponding to the elastomer connector 10 in the central portion in a plan view. Has been done. By inserting the second needle-shaped conductive member 30 into the insertion hole 52, the second needle-shaped conductive member 30 is held in a state of extending in the thickness direction of the elastomer connector 10.

The number of insertion holes 52 in the second holder 50 is the same as the number of insertion holes 42 in the first holder 40. That is, the number of the second needle-shaped conductive members 30 is the same as the number of the first needle-shaped conductive members 20.
The position of the insertion hole 52 in the plan view of the second holder 50 is offset from the position of the insertion hole 42 of the first holder 40 by the offset amount of the thin metal wire 14. That is, the position of the second needle-shaped conductive member 30 in the plan view is offset from the position of the first needle-shaped conductive member 20 by the offset amount of the thin metal wire 14. As described above, the position of the insertion hole 52 and the position of the second needle-shaped conductive member 30 can be appropriately set according to the form of the DUT and the offset amount of the thin metal wire 14.

The diameter of the insertion hole 52 is such that the second needle-shaped conductive member 30 can be smoothly inserted and can move up and down with low friction, and the position between the second needle-shaped conductive member 30 and the electrode terminal of the circuit board at the time of assembly. Set in consideration of the machining tolerance of each part so that the deviation does not become large. For example, the diameter of the insertion hole 52 can be set to a value about 5 to 15 μm larger than the diameter of the second needle-shaped conductive member 30.

The shape of the second needle-shaped conductive member 30 is not particularly limited, and examples thereof include a columnar shape in which both the first end 30a and the second end 30b are flat. When the second needle-shaped conductive member 30 has such a simple columnar shape, machining is easy, and the length of the needle-shaped conductive member, which is important for improving high-frequency performance, can be shortened. It is advantageous in that excellent high frequency characteristics can be easily obtained even if the number of members of the vertical contact type probe 1 is increased. From the viewpoint of facilitating the alignment with the electrode terminal of the circuit board, the shape of the second needle-shaped conductive member 30 is a shape in which the edge portion of the end surface of the second end on the side in contact with the electrode terminal of the circuit board is chamfered. May be good.

The diameter of the second needle-shaped conductive member 30 can be appropriately set in consideration of high-frequency characteristics, for example, depending on the distance between the second needle-shaped conductive members 30 and the dielectric constant of the material of the second holder 50. The characteristic impedance can be set to be around 50Ω. Further, the diameter of the second needle-shaped conductive member 30 is set in consideration of the size of the electrode terminals of the circuit board in order to facilitate the alignment with the electrode terminals of the circuit board.

The shorter the length of the second needle-shaped conductive member 30, the better the high-frequency characteristics. Therefore, it is preferable to shorten the length as much as possible in consideration of the required specifications of the high-frequency characteristics, the processing technique, and the ease of handling.

A part of the second needle-shaped conductive member 30 on the second end 30b side protrudes from the outer surface 50a of the second holder 50. As a result, at the time of inspection, the first end 30a side of the second needle-shaped conductive member 30 bites into the elastomer connector 10, and the elasticity of the elastomer sheet 12 applies pressure to the second needle-shaped conductive member 30 toward the second end 30b. Therefore, the second end 30b of the second needle-shaped conductive member 30 can be firmly brought into contact with the electrode terminal of the circuit board.

The length of the portion of the second needle-shaped conductive member 30 protruding from the second holder 50 is such that, for example, the end face of the second end 30b is the second holder 50 in a state where the second end 30b is in contact with the electrode terminal of the circuit board. It is set so as to be flush with the outer surface 50a of. The length of the portion of the second needle-shaped conductive member 30 protruding from the second holder 50 is set in consideration of the amount of biting of the second needle-shaped conductive member 30 into the elastomer connector 10.

As the material of the second needle-shaped conductive member 30, the same material as that exemplified as the material of the first needle-shaped conductive member 20 can be exemplified. The material of the second needle-shaped conductive member 30 and the material of the first needle-shaped conductive member 20 may be the same or different.

[Probe card]
The probe card of the present invention is a probe card including the vertical contact type probe of the present invention and a circuit board provided with electrode terminals. The probe card of the present invention may adopt known embodiments except that the probe card of the present invention includes the vertical contact type probe of the present invention. Hereinafter, as an example of the probe card of the present invention, the probe card 100 including the vertical contact type probe 1 will be described with reference to FIG.

The probe card 100 includes a vertical contact type probe 1 and a circuit board 110 provided with electrode terminals.
In the vertical contact type probe 1 of the probe card 100, the first needle-shaped conductive member 20 is located below the elastomer connector 10, and the second needle-shaped conductive member 30 is located above the elastomer connector 10.

In the probe card 100, the circuit board 110 is provided on the upper side of the vertical contact type probe 1. Further, the second end 30b of the second needle-shaped conductive member 30 in the vertical contact probe 1 is in contact with the electrode terminal of the circuit board 110. The mode in which the circuit board 110 is provided on the upper side of the vertical contact probe 1 is not particularly limited, and known modes such as connection with bolts and adhesion with an adhesive can be adopted.

The minimum line width (L) and the minimum gap (S) between the patterns in the circuit pattern of the circuit board 110 can be appropriately set. It is particularly effective that L and S of the circuit board 110 are 100 μm or less that can be used for inspection of a fine pitch semiconductor element (DUT). In order to manufacture such a circuit pattern, it is necessary to apply a thin film circuit manufacturing technique, and in many cases, as a thin film circuit, an Au thin film having a thickness of 0.5 μm or more and 10 μm or less or a multilayer metal such as Ti / Pd / Au is used. A thin film composed of is adopted.

In the on-wafer inspection of the DUT, that is, the semiconductor IC by the probe card 100, the second end 30b of the second needle-shaped conductive member 30 is in contact with the electrode terminal of the circuit board 110, and the second needle-shaped conductive member 20 is in contact with the electrode terminal. The end 20b is brought into contact with the electrode of the DUT. At this time, since the first end 14a of the thin metal wire 14 does not come into contact with the electrode of the DUT, even if the first end 14a of the thin metal wire 14 slides in the plane direction due to the compression deformation of the elastoma connector 10, the thin metal wire 14 It is possible to prevent the first end 14a from rubbing against the DUT electrode and damaging the electrode. Further, the second end 14b of the thin metal wire 14 is in contact with the electrode terminal of the circuit board 110 via the second needle-shaped conductive member 30, and the second end 14b of the thin metal wire 14 is directly connected to the electrode terminal of the circuit board 110. Not in contact. Therefore, it is possible to prevent the electrode terminal of the circuit board 110 from being damaged by the second end 14b of the thin metal wire 14. Thereby, in the inspection of the fine pitch DUT, excellent durability can be ensured even when the circuit board 110 having the fine pitch thin film circuit is used. Further, since the first needle-shaped conductive member 20 and the second needle-shaped conductive member 30 are a simple cylinder having a convex shape and a simple cylinder, respectively, they are easy to machine and are important for improving high frequency performance. The lengths of the first needle-shaped conductive member and the second needle-shaped conductive member can be shortened, the high frequency characteristics are excellent, and the DUT having a high operating frequency can also be applied to high frequency inspection.

[socket]
The socket of the present invention is a socket including the vertical contact probe of the present invention, a circuit board provided with electrode terminals, and a socket body provided with a mounting portion for detachably mounting a semiconductor element. The socket of the present invention may adopt known embodiments except that it comprises the vertical contact probe of the present invention. Hereinafter, as an example of the socket of the present invention, the socket 200 including the vertical contact probe 1 will be described with reference to FIG.

The socket 200 includes a vertical contact probe 1, a circuit board 110 having electrode terminals, and a socket body 220.
The vertical contact type probe 1 in the socket 200 has the same aspect as the vertical contact type probe 1 in the probe card, and is different from the case of the probe card only in that the vertical contact type probe 1 is used upside down.

In the vertical contact probe 1, the first holder 40 is arranged on the upper side (first surface 10a side) of the elastomer connector 10, and the second holder 50 is arranged on the lower side (second surface 10b side) of the elastomer connector 10. There is. In this example, the elastomer connector 10 is fitted into a recess 41 formed by counterbore processing in the central portion of the first holder 40 on the side holding the elastomer connector 10, and the positioning pins are inserted into the positioning pin holes 44 and 54 for positioning. By inserting the coupling screw 60 into the coupling screw insertion holes 46 and 56 in this state, the elastomer connector 10 is sandwiched between the first holder 40 and the second holder 50.

The second needle-shaped conductive member 30 in this example is a columnar shape having no reduced diameter portion, but since the circuit board 110 is underneath, it does not fall out downward. The shapes of the first needle-shaped conductive member 20 and the second needle-shaped conductive member 30 are not limited to the columnar shape described above.

The circuit board 110 is provided under the vertical contact type probe 1 in a state where the second end 30b of the second needle-shaped conductive member 30 is in contact with the electrode terminal. The socket body 220 is provided above the vertical contact probe 1 so that the electrode of the semiconductor element (DUT) mounted on the mounting portion 222 is positioned so as to contact the second end 20b of the first needle-shaped conductive member 20. There is. The mode in which the circuit board 110 and the socket main body 220 are provided is not particularly limited, and known modes such as connection with bolts and adhesion with an adhesive can be adopted.

The socket body 220 has a mounting portion 222 formed of a through hole formed so as to penetrate the central portion in a plan view in the thickness direction. The shape and size of the mounting portion 222 can be appropriately set according to the shape of the DUT. The socket body 220 may include a lid member that closes the opening of the mounting portion 222.

The material forming the socket body 220 is not particularly limited, and examples thereof include an epoxy resin, an acrylic resin, a polyester resin, a polyphenylene sulfide resin, a polyether sulfone resin, and a polyetherimide resin. The material forming the socket body 220 may be one type or two or more types.

When inspecting the DUT by the socket 200, the DUT is mounted on the mounting portion 222 of the socket main body 220 so that the electrode is on the bottom side of the mounting portion 222. As a result, the second end 20b of the first needle-shaped conductive member 20 is in contact with the electrode of the DUT while the second end 30b of the second needle-shaped conductive member 30 is in contact with the electrode terminal of the circuit board 110. At this time, similarly to the probe card 100, the first end 14a and the second end 14b of the thin metal wire 14 are not in contact with the electrode of the DUT or the electrode terminal of the circuit board 110. This prevents the electrodes of the DUT and the electrode terminals of the circuit board 110 from being damaged by the first end 14a and the second end 14b of the thin metal wire 14. Therefore, in the inspection of the fine pitch DUT, excellent durability can be ensured even when the circuit board 110 having the fine pitch thin film circuit is used. Further, since the first needle-shaped conductive member 20 and the second needle-shaped conductive member 30 are a simple cylinder having a convex shape and a simple cylinder, respectively, machining is easy and the length can be shortened, resulting in high frequency characteristics. It is excellent and can be applied to high frequency inspection of DUT with high operating frequency.

As described above, in the present invention, in the case of both the probe card and the socket, one or more first needle-shaped conductive members are provided on the first surface side of the elastoma connector in the vertical contact type probe, and the elastoma connector is the first. One or more second needle-shaped conductive members are provided on the two-sided side. The first end of the first needle-shaped conductive member and the first end of the second needle-shaped conductive member are in contact with both ends of the thin metal wire, respectively. When inspecting a semiconductor, the second end of the first needle-shaped conductive member is brought into contact with the electrode of the DUT while the second end of the second needle-shaped conductive member is in contact with the electrode terminal of the circuit board.

As described above, in the present invention, in the case of both the probe card and the socket, the second end of the first needle-shaped conductive member is a DUT, that is, the semiconductor IC in the case of the probe card, and the electrode of the packaged semiconductor in the case of the socket. It touches and the tip of the thin metal wire does not touch the electrode of the DUT. Therefore, during inspection, the elastoma connector is compressed and deformed in the thickness direction, and the thin metal wire is further tilted. Is prevented.

Further, in the present invention, in both the probe card and the socket, the second end of the second needle-shaped conductive member is in contact with the electrode terminal of the circuit board, and the tip of the thin metal wire is in contact with the electrode terminal of the circuit board. Not done. A circuit board having a thin film circuit is used as a fine pitch circuit pattern for inspection of a fine pitch semiconductor element having a small electrode spacing, that is, a semiconductor IC or a packaged semiconductor. In the present invention, the electrode terminals of the circuit board are used even in this case. Can be prevented from being damaged by the tip of the fine metal wire. Therefore, excellent durability can be ensured even in the inspection of fine pitch semiconductor elements.

Further, in the present invention, in the case of both the probe card and the socket, the first needle-shaped conductive member and the second needle-shaped conductive member are provided on both the first surface side and the second surface side of the elastoma connector, and further. Since the first needle-shaped conductive member and the second needle-shaped conductive member are a simple convex cylinder or a simpler cylinder, they are easy to machine and are important for improving high frequency performance. Although the length of the conductor can be shortened and the number of members is large, it has excellent high frequency characteristics and can be applied to high frequency inspection of a DUT having a high operating frequency.

The present invention is not limited to the above-described aspect. As long as it does not deviate from the gist of the present invention, it is appropriately possible to replace the constituent elements in the above-described embodiment with well-known constituent elements, and the above-mentioned modifications may be appropriately combined.

Hereinafter, the present invention will be specifically described with reference to Examples, but the present invention is not limited to the following description.
[Example 1]
A socket having the configuration illustrated in FIG. 4 was manufactured.
An elastomer connector was used in which a gold-plated beryllium copper wire (Φ17 μm) was inserted into a silicone rubber sheet at an inclination angle of 63 ° as a fine metal wire. The length of protrusion from both sides of the silicone rubber sheet at both ends of the thin metal wire was 15 μm, and the vertical and horizontal pitches of the thin metal wire when the surface of the silicone rubber sheet was viewed from the thickness direction were 32 μm and 50 μm, respectively. .. As the silicone rubber, one having a shore hardness of 70 ° was used.
Pd columnar pin as the first needle-shaped conductive member (second end end face: flat structure), Pd columnar pin as the second needle-shaped conductive member (second end end face: flat structure and edge) The shape of the chamfered part) was used.
As the circuit board, a quartz substrate on which an Au thin film having a thickness of 2 μm was formed as a thin film circuit was used.

[Comparative Example 1]
A socket having the same shape as that of the first embodiment was produced except that the second needle-shaped conductive member was not provided and the tip of the thin metal wire of the elastomer connector was in direct contact with the electrode terminal of the circuit board.

[High frequency characteristics]
Using a network analyzer, the amplitude (Magnitude) value when a high frequency inspection signal of 0 to 110 GHz was supplied to the manufactured socket was measured, and the high frequency characteristic (S parameter) was measured. The pin-to-pin pitch of the G (ground) S (signal) G (ground) configuration was 160 μm. The results are shown in FIG.

[Durability test]
After fixing the manufactured socket, pressing the tip of the first needle-shaped conductive member and compressing the elastomer connector 410,000 times, the DC characteristics and high-frequency characteristics of the DUT were measured to evaluate the durability. ..

As shown in FIG. 5, which is actual measurement data, the socket of the first embodiment including the first needle-shaped conductive member and the second needle-shaped conductive member on both sides of the elastoma connector is the S parameter S21 of the transmission line from the high frequency connector to the DUT. The 3 dB reduction band was 96 GHz and the ripple up to 80 GHz was less than D ± 0.3 dB, and the high frequency characteristics were excellent. Further, the socket of Example 1 has sufficient durability for practical use because no specific fluctuation of DUT and other deterioration phenomena due to repeated compression of 410,000 times are observed as compared with Comparative Example 1. confirmed.

1 ... Vertical contact type probe, 10 ... Elastoma connector, 12 ... Elastoma sheet, 14 ... Metal wire, 20 ... First needle-shaped conductive member, 30 ... Second needle-shaped conductive member, 40 ... First holder, 42 ... Insertion hole , 50 ... 2nd holder, 52 ... Insertion hole, 100 ... Probe card, 110 ... Circuit board, 200 ... Socket.

Claims (4)

A vertical contact probe for inspecting a semiconductor element in contact with an electrode of a semiconductor IC or a packaged semiconductor and an electrode terminal of a circuit board.
It comprises an elastomer connector, one or more first needle-shaped conductive members, one or more second needle-shaped conductive members, a first holder, and a second holder.
The elastomer connector comprises an elastomer sheet and a plurality of thin metal wires inserted in the thickness direction of the elastomer sheet.
The first needle-shaped conductive member is in a state where the first end of the first needle-shaped conductive member is in contact with the thin metal wire on the first surface side of the elastomer connector and extends in the thickness direction of the elastomer sheet. Held by the first holder
In the second needle-shaped conductive member, the first end of the second needle-shaped conductive member is in contact with the thin metal wire on the second surface side of the elastomer connector, and the second needle-shaped conductive member extends in the thickness direction of the elastomer sheet. Held by the second holder
A vertical contact type in which the semiconductor element is inspected by contacting the second end of the first needle-shaped conductive member with the electrode while the second end of the second needle-shaped conductive member is in contact with the electrode terminal. probe. The vertical contact probe according to claim 1, wherein the shape of the second needle-shaped conductive member is a columnar shape in which both the first end and the second end are flat. A vertical contact probe according to claim 1 or 2, and a circuit board provided with electrode terminals.
In the vertical contact type probe, the first needle-shaped conductive member is located below the elastomer connector, and the second needle-shaped conductive member is located above the elastomer connector.
The circuit board is a probe card provided on the upper side of the vertical contact type probe in a state where the second end of the second needle-shaped conductive member is in contact with the electrode terminal. A vertical contact probe according to claim 1 or 2, a circuit board provided with electrode terminals, and a socket body provided with a mounting portion for detachably mounting a packaged semiconductor.
In the vertical contact probe, the first needle-shaped conductive member is located above the elastomer connector, and the second needle-shaped conductive member is located below the elastomer connector.
The circuit board is provided under the vertical contact type probe in a state where the second end of the second needle-shaped conductive member is in contact with the electrode terminal.
The socket body is a socket provided on the upper side of the vertical contact type probe so that the electrode of the packaged semiconductor mounted on the mounting portion is positioned so as to contact the second end of the first needle-shaped conductive member. ..

Images