KR20220143545A - Pogo Pin For Super High Current - Google Patents

Abstract

According to the present invention, a pogo pin relates to an ultra-high current pogo pin having a spring (30) for elastically supporting a probe and an outer cylinder (40) for guiding the sliding of the probe, wherein the probe (50) comprises: a cylindrical coupling portion wrapped around a portion of the probe and coupled to and fixed to the portion of the probe; and a sleeve having a plurality of brushes extending from the cylindrical coupling portion and sliding while elastically contacting an inner circumferential surface of an outer cylinder (40). Therefore, a manufacturing process is simpler and manufacturing cost can be reduced.

Description

Pogo Pin For Super High Current

The present invention relates to a pogo pin that enables the transmission of ultra-high current.

In a conventional general pogo pin), when the tip of the probe supported by the spring is pressed, the probe slightly collapses depending on the instability, and a part of the probe comes into contact with the outer tube, and by such contact, the probe and the outer tube It forms an electrical path between them. For example, if the probes (upper probe and lower probe) are configured at both upper and lower ends of the pogo pin, the electrical path is composed of the upper probe - outer tube - lower probe path, and depending on the collapse of the probe, it is between the probe and the outer tube. In the conventional pogo pin, the contact impedance is large and the contact impedance is relatively large, so it is difficult to transmit ultra-high current.

To solve this problem, modified pogo pins or connecting pins of various structures are being studied, and they maintain or improve physical properties such as stroke, spring force, density (miniaturization), durability, and stability while maintaining or improving physical properties such as ultra-high current or ultra-low impedance. It is necessary to develop a pogo pin having electrical characteristics.

Although the problems and problems of the prior art have been described above, recognition of these problems and problems is not obvious to those of ordinary skill in the art of the present invention.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a pogo pin capable of having superior electrical properties without sacrificing physical properties of the pogo pin or improving physical properties without sacrificing electrical properties.

Another object of the present invention is to provide a pogo pin that has a simpler manufacturing process and can reduce manufacturing costs.

The pogo pin according to an aspect of the present invention is a pogo pin having a spring 30 for elastically supporting the probe and having an outer cylinder 40 for guiding the sliding of the probe, wherein the probe has a small diameter and the small diameter. From the cylindrical coupling part and the cylindrical coupling part extending from the neck and having an outer diameter larger than the small diameter part and having a large diameter part located inside the outer cylinder 40, which is coupled to and fixed to the large diameter part while surrounding the large diameter part of the probe A sleeve extending and having a plurality of brushes slidable while in elastic contact with the inner circumferential surface of the outer cylinder (40); characterized in that it is configured to include.

The pogo pin according to an aspect of the present invention has a built-in spring 30 for elastically supporting the probe and includes an outer cylinder 40 for guiding the sliding of the probe. A sleeve having a cylindrical coupling part that wraps around the large diameter part and fixed to the part, and a plurality of brushes extending from the cylindrical coupling part and slidable while in elastic contact with the inner circumferential surface of the outer cylinder 40; characterized by

In the above-described pogo pin, the probe 10 and the sleeve 20 are both formed by processing a flat material, and the sleeve 20 is formed by processing a flat material thinner than the probe 10. it could be

In the above-described pogo pin, the sleeve is formed by processing a flat material, but the contact surface of the brush in elastic contact with the inner circumferential surface of the outer cylinder 40 is derived from a plane of one side of the flat material, not the cut surface of the flat material. may be doing

In the above-described pogo pin, the lower end of the cylindrical coupling portion of the sleeve is provided with a locking jaw (21a) that is partially punched and bent inward, and the locking jaw (21a) is the probe (10) when the pogo pin is compressed. It is possible to prevent one end of the large-diameter portion 12 from being separated to the outside of the sleeve 20 .

In the above-described pogo pin, the probe may be formed by cutting a cylindrical material, and the sleeve may be formed by processing a flat material.

In the above-described pogo pin, the probe further includes a head portion extending from the small diameter portion opposite to the large diameter portion and having an outer diameter larger than the small diameter portion and located outside the outer cylinder 40, and the upper surface of the head portion has an external A contact portion 14 ′ in which an arrangement of sharp projections is formed by cutting for contact with may be provided.

In the above-described pogo pin, the large diameter portion of the probe is provided with a first circular trench E1 cut inward along the circumference, and the cylindrical coupling portion of the sleeve has a second circular trench bent inward along the circumference ( E2), and the second circular trench E2 is seated in the first circular trench E1, whereby the probe and the sleeve may be fixed to each other.

In the above-described pogo pin, a concave portion 23 is configured above the cylindrical coupling portion 21 of the sleeve 20, and the concave portion 23 is formed of the probe 10 when the pogo pin is extended. It is possible to prevent the other end of the large-diameter portion 12 from being separated to the outside of the sleeve 20 .

The pogo pin according to an aspect of the present invention is a pogo pin having a spring 60 for elastically supporting the probe 50 and having an outer cylinder 70 for guiding the sliding of the probe 50, the probe ( 50), the small diameter portion 51; a large-diameter portion 52 extending from the small-diameter portion 51 and having an outer diameter greater than that of the small-diameter portion 51; a plurality of brushes 53 extending from the large-diameter portion 52 and slidable while in elastic contact with the inner circumferential surface of the outer cylinder 40, wherein the probe 50 is formed by processing a flat material do.

In the above-described pogo pin, the contact surface of the brush 53 in elastic contact with the inner circumferential surface of the outer cylinder 40 may be derived from a plane of one side of the flat material, not the cut surface of the flat material.

In the above-described pogo pin, in the probe 50, the flat material is processed so that the thickness t2 of the brush 53 is thinner than the thickness t1 of the small-diameter portion 51 and the large-diameter portion 52 characterized by being

In the above-described pogo pin, the brush 53 is integrally configured with a cantilever 53a extending long in the longitudinal direction on the circumference of the large-diameter portion 52, and a free end of the cantilever 53a, A sliding contact portion 53b for elastically contacting the inner circumferential surface of the outer cylinder 40 may be provided.

In the above-described pogo pin, the sliding contact portion 53a may have a bent portion in contact with the inner peripheral surface of the outer cylinder (7).

In the above-described pogo pin, the outer cylinder 70 is also formed by processing a flat material, and the outer cylinder 70 is press-fitted inward on the circumference of the outer cylinder 70 to form a circular projection (B) By providing a first step (A1) between the large-diameter portion 52 and the small-diameter portion 51 to be caught, the probe 50 is prevented from being separated to the outside of the outer cylinder (70) can

In the above-mentioned pogo pin, the outer cylinder 70, with the circular protrusion (B) of the outer cylinder 70 as a boundary, guides the large-diameter portion 52 and provides an inner peripheral surface on which the brush 53 slides A first cylindrical portion 71 and a second cylindrical portion 72 coupled to the first cylindrical portion 71 and formed at one or both ends of the outer cylinder 70, the first cylindrical portion ( 71) and the inner diameter of the second cylindrical portion 72 are the same.

In the above-described pogo pin, the probe 50 further has a contact portion 54 that extends after forming the second stepped portion A2 from the small diameter portion 51, but the inner diameter of the contact portion 54 is Since it is smaller than the inner diameter of the small diameter portion 51 , one end of the spring 60 may be supported by the second stepped portion A2 .

According to an aspect of the present invention, it is possible to increase the elastic deformation range of the brush, use a brush having a shorter length, and improve the electrical characteristics of the pogo pin by using the brush without significantly increasing the length of the pogo pin. can have an effect.

According to one aspect of the present invention, there is no need for caulking, which was required in the process of raising the conventional pogo pin, thereby lowering the defect rate and significantly reducing the manufacturing cost.

According to an aspect of the present invention, since the structure allows the passage of the spring into the probe, there is an effect of enabling a longer spring length and a longer spring stroke.

1 to 3 are pogo pins for ultra-high current according to a first embodiment of the present invention, wherein FIG. 1 is a perspective view showing the exterior, FIG. 2 is an exploded perspective view, and FIG. 3 is a vertical cross-sectional view.
4 to 6 are diagrams showing the structure of a pogo pin for ultra-high current according to a second embodiment of the present invention, and FIG. 4 is a perspective view showing the external appearance, FIG.
7 to 8 are modified examples of the ultra-high current pogo pin according to the first embodiment of the present invention, and FIG. 7 is a perspective view showing the exterior, FIG. 8 is an exploded perspective view, and FIG. .
10 is a view showing a separator 80 is applied according to an embodiment of the present invention. FIG. 10 (a) shows that the separator 80 is coupled to the head of the probe, and FIG. 10 (b) is It is a view showing that the separator 80 is separated from the head of the probe.

With reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. However, the present invention may be embodied in several different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar names and reference numerals are used for similar parts throughout the specification.

1 to 3 are pogo pins for ultra-high current according to a first embodiment of the present invention, wherein FIG. 1 is a perspective view showing the exterior, FIG. 2 is an exploded perspective view, and FIG. 3 is a vertical cross-sectional view.

The pogo pin according to the first embodiment of the present invention is configured to include a probe (10), a sleeve (20), a spring (30) and an outer cylinder (40). Except for the spring 30, the probe 10, the sleeve 20, and the outer cylinder 40 are manufactured by processing a flat plate material.

The outer cylinder 40 has a coil-type spring 30 for elastically supporting the probe 10 , and guides the sliding of the probe 10 and guides the spring 30 during compression and extension of the spring 30 . The first embodiment of the present invention illustrates having the probe 10 in one direction, and accordingly, the probe 10 is partially exposed to the outside in one direction (upper side) of the outer cylinder, and the exposed portion is changed according to the situation. . The other direction (downward) of the outer cylinder is closed by the disk portion 41 of the bottom surface, and in the outer cylinder manufactured by processing a flat material, the disk portion 41 to the cylindrical portion 43 from the lower end side of the cylindrical portion 43 of the outer cylinder. is physically connected, and on the opposite side to which the disk part 41 is connected, the hook 42 extending from the disk part 41 is seated in a bent state in the hook groove (H) provided at the lower end of the cylindrical part 43 . By doing so, the disk part 41 is fixed to the cylindrical part 43 .

For example, when the pogo pin is used in the socket, the probe 10 of the pogo pin, specifically, the contact portion 14 of the probe 10 is for contacting the terminal of the semiconductor device, and the outer cylinder including the disk portion 41 The lower end of (40) is for direct contact with the pad of the PCB or in a soldering manner. In addition, if necessary, the outer wall of the outer cylinder 40 may be in contact with another contact portion.

The first embodiment of the present invention illustrates having the probe 10 in one direction, and as another embodiment, the probe 10 may be provided in both directions of the pogo pin, that is, both in the longitudinal direction. At this time, depending on the purpose of use, that is, depending on the counterpart of the contact, the shape of the contact portion 14 in the probe 10 may be applied in various shapes such as a crown shape, a cone shape, and a cylindrical shape.

The probe 10 has a substantially cylindrical shape with a step, and each of the small diameter portion 11 and the large diameter portion 12 has a cylindrical shape. The large-diameter portion 12 of the probe 10 is integrally connected to the small-diameter portion 11 and has a larger outer diameter than the small-diameter portion 11 and is located inside the outer cylinder 40 . When viewed from the small-diameter portion 11 , the contact portion 14 is formed to extend from the small-diameter portion 11 on the opposite side to the direction in which the large-diameter portion 12 extends.

The probe 10 forms a stepped portion A1 between the small diameter portion 11 and the large diameter portion 12, and the outer diameter of the spring 30 is larger than the inner diameter of the small diameter portion 11 and the inner diameter of the large diameter portion 12 smaller than that, the spring 30 passes through the large diameter portion 12 and is supported by the lower end of the small diameter portion 11 . The large diameter portion 12 of the probe 10 is used for the guide function of the probe 10 and at the same time allows the passage of the spring 30, so that the length of the spring 30 and the stroke of the longer spring are longer as a result. makes it possible This enables a longer stroke compared to the length of the pogo pin.

The sleeve 20 is one of the most important features of the present invention, and is coupled to and fixed to the large-diameter portion 12 while surrounding the large-diameter portion 12 of the probe 10, and a cylindrical coupling portion 21 having an approximately cylindrical shape; A plurality of brushes 22 extending from the cylindrical coupling portion 21 and slidable while elastically contacting the inner circumferential surface of the outer cylinder 40 are provided.

A concave portion 23 is configured above the cylindrical coupling portion 21, and the concave portion 23 is bent approximately 90 degrees with respect to the longitudinal direction of the sleeve to surround the stepped portion A1 of the probe 10, and and prevents the large-diameter portion 12 of the probe 10 from being separated to the outside of the sleeve 20 when the pogo pin is extended.

The lower end of the cylindrical coupling part 21 of the sleeve 20 is provided with a locking jaw 21a that is partially punched and bent inward, and is punched in an approximately 'C' shape, in the longitudinal direction of the sleeve 20 . The brush 22 has an unpunched side on the configured side. Therefore, the free end of the locking jaw 21a faces upward of the sleeve 20 but is bent inwardly. When the probe 10 and the sleeve 20 are assembled, the locking jaw 21a is the large diameter part of the probe 10 . While facilitating (12) entry into the cylindrical coupling portion 21 of the sleeve 20, the locking jaw 21a in the step of using the pogo pin after assembly is the large diameter portion of the probe 10 when the pogo pin is compressed. 12) to prevent the one end (lower end) from being separated to the outside of the sleeve 20 .

After assembling, the probe 10 and the sleeve 20 are integrated, and in a state supported by the spring 30, the probe 10 and the sleeve 20 can perform a reciprocating motion in the vertical direction integrally.

The brush 22 extends from the cylindrical engaging portion 21, and a plurality, for example, 10, are erected at equal intervals on the lower circumference of the cylindrical engaging portion 21. There is a space between the adjacent brushes, and the fixed end of the brush is coupled to the cylindrical coupling portion 21 , and the free end of the brush or a portion including the vicinity of the free end is in elastic contact with the inner circumferential surface of the outer cylinder 40 .

The probe 10 and the sleeve 20 and the like are formed by processing a flat material. The contact surface of the brush 22 in elastic contact with the inner circumferential surface of the outer cylinder 40 is derived from a plane of one side of the flat material, not the cut surface of the flat material. Accordingly, it is easy to make the thickness of the cantilever small when the brush acts as a cantilever.

The sleeve 20 is formed by processing a flat material thinner than the probe 10 , and the thickness of the sleeve 20 is selected to be thinner than the thickness of the probe 10 . Due to the thickness of the sleeve thinner than the probe, the bent portion of the concave portion 23 of the sleeve may have a smaller radius of curvature, and thus the cylindrical portion 43 of the outer cylinder 40 and the inlet portion 44 are configured between the By allowing the probe and the sleeve integrated more securely to be caught on the step portion A2, the escape to the outside is more reliably prevented.

And the thinner sleeve 20 increases the elastic deformation range of the brush 22 and thus enables the use of a brush having a shorter length, thus without increasing the length of the pogo pin or significantly increasing the length of the pogo pin. It is possible to improve the electrical characteristics of the pogo pin by using a brush.

Before inserting the sleeve 20 into the outer cylinder 40, the brush 22 of the sleeve 20 must be bent outward. Only then is the brush 22 after assembly the required elastic contact with respect to the outer cylinder (40) is possible. However, if the elastic deformation range is less than the required level, there is a problem that may cause plastic deformation and defects of the sleeve 20 after assembly.

For example, when the thickness of the sleeve 20 is reduced to 1/2, the elastic deformation range of the brush is increased by 8 times. Assume that if you want to achieve the same elastic deformation range without thinning the sleeve 20, the length of the brush must be significantly increased, and considering the free space that guarantees free up-and-down reciprocating movement of the probe, the length of the pogo pin becomes too long. There is a problem with throwing away. According to the first embodiment of the present invention, by adopting a sleeve that is assembled with the probe separately from the probe, it is easier to use a sleeve thinner than the probe, and furthermore, the pogo pin can be used without increasing or significantly increasing the length of the pogo pin. It has the effect of improving the electrical properties of

4 to 6 are diagrams showing the structure of a pogo pin for ultra-high current according to a second embodiment of the present invention, and FIG. 4 is a perspective view showing the external appearance, FIG.

4 to 6, for convenience, the probe is described in the form at both ends of the pogo pin, but it is obvious that the form in which the probe is located only at one end of the pogo pin while having the same characteristics is also included in the scope of the present invention. In the description of the second embodiment, parts similar to those of the first embodiment may be omitted, and the structure in the first embodiment may be borrowed.

The pogo pin according to the second embodiment of the present invention is configured to include two probes 50, a spring 60 and an outer cylinder 70 positioned at both ends, respectively, except for the spring 60, two probes ( 50) and the outer cylinder are manufactured by processing a flat plate material.

The outer cylinder 70 includes a coil-type spring 60 that elastically supports the probe 10, guides the sliding of the probe 10, and guides the spring 60 during compression and extension of the spring 60. After assembly, the outer cylinder 70 guides the probe and the spring during compression and extension of the pogo pin while preventing the probe 50 from departing from the outer cylinder 70 over a predetermined range despite the elastic force of the spring 60 .

The outer cylinder 70 guides the large-diameter portion 52 of the probe 50 with the circular protrusion B as a boundary and provides an inner circumferential surface on which the brush 53 of the probe 50 slides. And , and a second cylindrical portion 72 coupled to the first cylindrical portion 71 and formed on one or both ends of the outer cylinder 70 (in the illustrated embodiment).

The outer cylinder 70 is also formed by processing a flat material, and the outer cylinder 70 has a circular protrusion (B) that is press-fitted inwardly on one or both sides of the outer cylinder 70 on a circumference to constitute a circular protrusion, the probe By making the first step portion A1 between the large diameter portion 52 and the small diameter portion 51 of (50) engage, the probe 50 is prevented from being separated to the outside of the outer cylinder (70).

However, in the second exemplary embodiment of the present invention, the inner diameters of the first cylindrical portion 71 and the second cylindrical portion 72 are the same. Accordingly, compared to the interval between the large diameter portion 52 and the first cylindrical portion 71 of the probe 50, the spacing between the small diameter portion 51 and the second cylindrical portion 72 of the probe 50 is quite large. Although it looks strange, the above feature has the advantage of facilitating the assembly process of the pogo pin.

In the manufacturing process of the conventional pogo pin, this bar caulking is needed to prevent the probe from escaping out of the outer tube by positioning the probe inside the outer tube while resisting the elastic force of the spring and then closing the end of the outer tube. Caulking can be performed only in the assembly process independently of the manufacture of each part, and can be performed while controlling the spring's resilient force.

However, according to the present invention, since the inner diameter of the second outer cylinder portion 72 is the same as the inner diameter of the first cylindrical portion 71, the large diameter portion 52 of the probe 50 is the second outer cylinder portion at the beginning of the outer cylinder when assembling the probe and the outer cylinder. It is easy to enter (72) (the brush enters the second outer cylinder in a closed or not closed state), and when it meets the circular protrusion (B), it is possible to ride over the outer cylinder made of flat material by slightly spreading it, so the inside of the outer cylinder Since it is easy to enter the pogo pin, caulking, which was required in the manufacturing process of the conventional pogo pin, is not required, thereby reducing the defect rate and significantly reducing the manufacturing cost.

A stop protrusion (D) is formed at one point of the outer cylinder with a part punched out and the free end protruding and curved to the outside while extending from the outer cylinder, and the stop protrusion (D) is used to mount the pogo pin on the socket body (housing), etc. When seated in the hole of the socket body, the pogo pin is prevented from being separated from the socket body during the manufacturing process. The conventional socket body (housing) requires two of the upper housing and the lower housing, and it is necessary to combine the two housings after accommodating the pogo pins on one side. There are advantages to being able to do it.

The probe 50 includes a small-diameter portion 51 having an outer diameter smaller than the large-diameter portion 52, a large-diameter portion 52 integrally connected to the small-diameter portion 51 and having a larger outer diameter than the small-diameter portion 51, and It is configured to include a contact portion 53 for electrical contact, and a plurality of brushes 53 extending from the large diameter portion 52 and slidable while elastically contacting the inner circumferential surface of the outer cylinder 40 . The large diameter portion 52 plays a major role in guiding the probe by the outer cylinder in an upright state.

The probe 50 is also formed by processing a flat material, and the probe 50 is a first step portion (A1) between the small-diameter portion 51 entering and exiting the outer cylinder and the large-diameter portion 52 reciprocating up and down inside the outer cylinder. to form As described above, the first step portion (A1) is caught on the circular protrusion (B) of the outer cylinder to prevent separation of the probe (50). And having a contact portion 54 extending after forming the second step portion A2 from the small diameter portion 51, as shown in FIG. 6, the inner diameter of the contact portion 54 is smaller than the inner diameter of the small diameter portion 51 , one end of the spring 60 is supported by the second step portion A2. And according to the purpose of use, that is, according to the counterpart of the contact, the shape of the contact part 54 in the probe 50 may be applied in various shapes such as a crown shape, a cone shape, and a cylindrical shape.

The insertion of the spring is allowed through the inner space of the small-diameter portion 51, the large-diameter portion 52, and the brush 53 formed by processing from a flat plate material, and accordingly, a spring of sufficient length can be easily configured, and a sufficient stroke is provided. can do.

The brush 53 may extend after having a step (third step A3) as shown on the circumference of the large-diameter portion 52 or may extend without a step. A plurality of brushes 53 are installed along the circumference of the large-diameter portion 52, and the cantilever 53a extending long in the longitudinal direction on the circumference of the large-diameter portion 52 is integrally formed with the free end of the cantilever 53a. and a sliding contact portion 53b that is slidable in a state of elastic contact with the inner circumferential surface of the outer cylinder 40 .

The sliding contact portion 53a is bent toward the inner circumferential surface of the outer cylinder 7 in a clamp shape or a semicircle shape and has a bent portion contacting the inner circumferential surface, and the end of the sliding contact portion 53a is more easily inserted into the outer cylinder during assembly. It is angled toward the center so that it can be

And the contact surface (contact surface of the contact part) of the brush 53 which is in elastic contact with the inner circumferential surface of the outer cylinder 40 is derived from the plane of one side of the flat material, not the cut surface of the flat material. Accordingly, it is easy to reduce the thickness of the cantilever.

According to the present invention, in the probe 50, the thickness t2 of the brush 53 is characterized in that the metal plate material is processed to be thinner than the thickness t1 of the small diameter portion 51 and the large diameter portion 52. The point at which the thickness varies may be selected from the tip of the large-diameter portion 52 or the beginning of the brush 53 or exactly between the two, but in any case, it is included in the above-described range. Preferably, the thickness t1 including the third step portion A3 is thicker.

The small diameter part 51, the large diameter part 52, and the brush 53 are all integrated and are not combined after manufacturing the flat material, but have different thicknesses as described above. It can be processed so that the corresponding part to be formed of the brush becomes thinner by a process or the like.

In the first embodiment, a sleeve separate from the probe was used to achieve a thinner thickness, but in the second embodiment, the brush is integrally formed with the probe and has a thinner thickness.

A thinner brush increases its elastic deformation range and thus enables the use of a brush having a shorter length. There is an effect that can improve the , and the detailed description thereof refers to the related description of the first embodiment. For example, reducing the thickness by 25% increases the elastic deformation range by approximately 2.37 times.

Hereinafter, a brief look at the manufacturing method of the pogo pin, but looking at the process of manufacturing the probe of the second embodiment, other parts, that is, the parts of the first embodiment or the outer cylinder of the second embodiment, are easily inferred through this description. may be implemented.

First, by punching a sheet-shaped metal flat material using a mold based on the development view of the probe, a flat plate-shaped intermediate member is made according to a predetermined development view shape.

And, as described above, by pressing the part to be formed with the brush by the pressing process to make the thickness thinner, and by punching again using the same mold, the shape of the intermediate material with the extended outline can be trimmed by the pressing process. The second press process may be omitted. In addition, the sliding contact portion and the stepped portion (which may be formed by a subsequent rolling process) bent by the coining process can be formed, and then rolled into a cylindrical shape by the rolling process, as shown in FIGS. 5 and 6 . Shaped probes can be manufactured. These processes can be performed by progress stamping.

7 to 8 are modified examples of the ultra-high current pogo pin according to the first embodiment of the present invention, and FIG. 7 is a perspective view showing the exterior, FIG. 8 is an exploded perspective view, and FIG. .

Since the modified example of the present invention is similar to the pogo pin according to the first embodiment, detailed descriptions of the same or similar parts will be largely omitted. The pogo pin according to the modified example is configured to include a probe (10'), a sleeve (20'), a spring (30) and an outer cylinder (40). The sleeve 20' and the outer cylinder 40 except for the spring 30 and the probe 10' are manufactured by processing a flat plate material.

When the pogo pin is used in the socket, the probe 10' of the pogo pin, specifically, the contact portion 14' of the probe 10' is for contacting the terminal of the semiconductor device.

The probe 10' is formed by cutting a cylindrical material, and has a substantially cylindrical shape with a step difference. Each of the small diameter part 11', the head part 13', and the large diameter part 12' in the probe 10' also has a substantially cylindrical shape, and the large diameter part 12' of the probe 10' has a small diameter. It is integrally connected to the neck portion 11' and has a larger outer diameter than the small diameter portion 11' and is located inside the outer cylinder 40. When viewed from the small-diameter portion 11', the head portion 13' is formed to extend from the small-diameter portion 11' on the opposite side to the direction in which the large-diameter portion 12' extends. The upper surface of the head portion 13' is provided with a contact portion 14' in which an arrangement of sharp projections is formed by cutting for contact with the outside. The sharp protrusions are arranged two-dimensionally, and the arrangement of protrusions can be formed by forming V-shaped grooves in a lattice shape by cutting.

The lower end of the large-diameter portion 12' in the probe 10' has a conical shape, so that the upper end of the spring 30 can be stably supported. By making the outer diameter decrease from the middle part of the spring 30 toward the top, the interference between the probe and the spring is reduced when assembling the probe and the spring, and it is also possible to enable smoother assembly.

The large-diameter portion 12' of the probe 10' is provided with a first circular trench E1 cut inward along the circumference, and the cylindrical engaging portion 21' of the sleeve 20' is inwardly along the circumference. It has a bent second circular trench E2. As the second circular trench E2 is seated in the first circular trench E1, the probe 10' and the sleeve 20' are fixed to each other. That is, after assembly, the probe 10 ′ and the sleeve 20 ′ are integrated, and in a state supported by the spring 30 , can perform a reciprocating motion in the vertical direction integrally.

10 is a view showing a separator 80 is applied according to an embodiment of the present invention. FIG. 10 (a) shows that the separator 80 is coupled to the head of the probe, and FIG. 10 (b) is It is a view showing that the separator 80 is separated from the head of the probe.

The separator 80 is fitted and coupled to the upper portion of the probe, specifically coupled to the side of the head portion 13'. A circular and serrated protrusion 13a is formed along the circumference of the cylindrical head, and a gentle slope faces outward and a steep slope faces inward in the teeth of each protrusion 13a.

The separator 80 is first in contact with the outside by exposing the contact portion 14 ′ for contact with the outside from the head portion upward, and is configured as a cylinder having electrical insulation. Due to the configuration of the separator 80, the electrical contact with the outside is not disturbed while ensuring the insulation between the neighboring probes.

10, 10': probe 20, 20': sleeve
30: spring 40: outer cylinder
50: probe 60: spring
70: outer cylinder 80: separator

Claims (6)

In the ultra-high current pogo pin having a spring 30 for elastically supporting the probe and having an outer cylinder 40 for guiding the sliding of the probe,
A sleeve having a cylindrical coupling part wrapped around a part of the probe and fixed by being coupled to the part, and a plurality of brushes extending from the cylindrical coupling part and slidable while in elastic contact with the inner circumferential surface of the outer cylinder (40). characterized by being
Pogo pins for ultra-high current. The method according to claim 1,
In the probe, the part is located inside the outer cylinder 40,
The part has a cylindrical shape,
Pogo pins for ultra-high current. The method according to claim 1,
In the probe, the portion is provided with a first circular trench E1 cut inward along the circumference,
The cylindrical coupling portion of the sleeve is provided with a second circular trench (E2) bent inward along the circumference,
By seating the second circular trench (E2) in the first circular trench (E1), the probe and the sleeve are fixed to each other,
Pogo pins for ultra-high current. The method according to claim 1,
The sleeve is formed by processing a flat material,
The contact surface of the brush, which is in elastic contact with the inner circumferential surface of the outer cylinder 40, is derived from a plane of one side of the flat material, not the cut surface of the flat material,
Pogo pins for ultra-high current. The method according to claim 1,
On the other side of the portion of the probe, it includes a head portion located outside the outer cylinder (40),
The upper surface of the head portion is provided with a contact portion 14' in which an arrangement of sharp projections is formed by cutting for contact with the outside,
Pogo pins for ultra-high current. The method according to claim 1,
On the other side of the part of the probe, it includes a cylindrical head portion located outside the outer cylinder (40),
Doedoe coupled to the side of the head portion, the head portion for exposing the contact portion for contact with the outside upward, characterized in that it further comprises a separator (80) consisting of an electrically insulating cylinder,
Pogo pins for ultra-high current.

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