KR20090098475A - The structure of fork pin - Google Patents

Abstract

A structure of a fork pin is provided to compensate volume reduction of a fork pin by expanding a connection part for connecting support pieces into an insertion space part side. A body(10) comprises a pair of support pieces(12,13), an insertion space part(14), a connection part(16), and a fixing protrusion(11). The insertion space part is formed between a pair of support pieces. A bottom part of a pair of support pieces is integrally formed by the connection part. A pair of gripping protrusions(12A,13A) is formed in a top end part of a pair of support pieces. The fixing protrusion is formed in a bottom end of the connection part. An expansion dimension part(15) is formed by expanding the connection part into the insertion space part side.

Description

Structure of the fork pin

The present invention relates to a fork pin, and more particularly, even if the width and thickness of the fork pin are reduced, the fork pin can satisfy the basic conditions for insertion force and bearing force of the standardized counterpart of the fork pin without changing the volume. It's about structure.

Typically, the fork pin 100 has an end thereof connected to and fixed to the printed circuit board 200 as shown in FIG. 1, and the fork pin 100 is inserted into and contacted with a counterpart 300 such as a fuse to the fork pin 100. It is a component that performs a receptive function (recept) to enable the electrical current between the counterpart 300 and the printed circuit board 200.

As shown in FIG. 2, a general fork pin 100 has a support piece 111 and 112 formed in a pair of cantilever shapes connected to each other by a connecting portion 116, and the support piece 111 is shown in FIG. 2. Insertion space portion 113 is formed between the (112) is inserted into the counterpart, the support piece 111, 112 is fixed to the insert 300 on both sides of the inlet side of the insertion space 113. It comprises a pair of gripping protrusions 111A, 112A, the lower side of the connecting portion 116 is composed of a body 110 formed integrally with a fixing protrusion 114 is inserted into the printed circuit board 200 is fixed. .

In the conventional fork pin 100 configured as described above, the fixing protrusion 114 integrally formed at the lower end of the body 110 is inserted or welded to the printed circuit board 200 to fix the body 110 vertically. In this state, the insertion of the counterpart 300 such as a fuse to the fork pin 100 is made, and the insertion of the support piece 111 formed in the form of a pair of cantilever beams on the upper side of the body 110. Inserted into the insertion space 113 between the 112, by the insertion force the support piece 111, 112 of the body 110 is opened to both sides, the upper end of the support piece 111, 112 By holding the insert 300 by the holding protrusions 111A and 112A formed therein, it is possible to conduct electricity between the insert 300 and the printed circuit board 200.

On the other hand, the fork pin 100 is usually 6mm wide and 0.8mm thick, the total volume and the length of the support piece 111, 112 is standardized in order to maintain the optimized performance of the fork pin.

In more detail, when the counterpart 300 is inserted into the fork pin 100, the insertion is easy and the support force for the inserted counterpart, that is, the holding force may be maintained to a certain degree, so that the fork pin 100 may be maintained. Do not allow the opponent to fall off easily.

However, one of the key to securing the competitiveness of these standardized fork pins is cost reduction, which means that materials can only be reduced in order to reduce costs. There is a problem that the performance of the fork pin is sharply lowered by the heat generated in proportion to the area volume.

Therefore, it is necessary to meet the standard condition of the fork pin, that is, to make it easy to insert and maintain the support for the inserted counterpart while reducing the cost by reducing the material without changing the volume. It will be secured.

Therefore, the present invention was devised to solve the conventional problems as described above, the purpose of which is to reduce the width and thickness of the fork pin even if the volume of the standard for the insertion force and the supporting force of the standardized counterpart of the fork pin without changing the volume The condition is to be satisfied as it is.

In order to achieve the object of the present invention between the pair of support pieces is formed an insertion space open to the upper side, the lower portion of the support piece is integrally formed by the connecting portion, the support piece is a pair of gripping stones inside the upper end In the fork pin comprising a body formed of a body formed integrally with a fixing protrusion at the lower end of the connecting portion, the body, the area of the connecting portion is extended to the insertion space so that the volume compensation can be made by reducing the width and thickness of the body It provides a structure of a fork pin characterized in that it further comprises an enlarged area formed by.

In addition, the support piece is characterized in that the inclined surface is formed on the inner surface between the end side of the insertion space portion and the support protrusion, the cross-sectional area of the support piece to increase toward the holding protrusion side.

In addition, the support piece is characterized in that the inclined surface is formed on the inner surface between the end side of the insertion space portion and the gripping protrusions, the cross-sectional area of the support piece is reduced toward the gripping protrusion side.

In addition, the support piece is characterized in that it further comprises a pair of deformation grooves on both inner side surfaces of the insertion space portion.

In addition, the end portion of the insertion space portion is formed in a semi-circular shape, the deformation groove is characterized in that formed along an imaginary circle larger than the imaginary circular diameter forming the end of the insertion space portion.

As described above, the present invention includes an enlarged area portion formed by extending the area of the connecting portion connecting the support pieces to the insertion space portion, and on both inner sides of the support pieces, inclined surfaces and deformation grooves for increasing displacement and volume compensation are formed. Therefore, even if the thickness and width of the fork pin are reduced, the basic conditions for the insertion force and the supporting force of the standardized counterpart of the fork pin are satisfied without changing the volume, thereby having the effect of securing price competitiveness by reducing the cost. do.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration of the present invention according to the embodiment.

The fork pin structure has an insertion space portion 14 which is open to the upper side between the pair of support pieces 12 and 13 as usual, and the lower portion of the support pieces 12 and 13 is It is formed integrally by the connecting portion 16, the support piece 12, 13 includes a pair of gripping protrusions 12A, 13A inside the upper end, the fixing protrusion 11 at the lower end of the connecting portion 16 It consists of a body 10 formed integrally.

In the fork pin structure, the present invention compensates for the reduced volume when reducing the width and thickness of the body 10 to the same volume as the conventional standardized fork pin so that there is no difference in heat generation due to the change in volume. It has its features.

To this end, the present invention extends the area of the connecting portion 16, which is represented by an imaginary line (double dashed line), to the insertion space portion 14 by a reduced volume, so that the enlarged area 15 is formed as shown in FIG. As a result of the volume compensation, the length of the support pieces 12 and 13 and the insertion space 14 is shortened by the enlarged area.

In this way, when the length of the support pieces 12 and 13 is shortened, the insertion force, that is, the extent to which the support pieces 12 and 13 open well when the insert is inserted between the support pieces 12 and 13, decreases. do.

Therefore, it is necessary to have the support piece 12, 13 of the present invention to have the same insertion force as the conventional standardized fork pin, and to compensate for such insertion force, the present invention is similar to the embodiment shown in FIG. Likewise, the inner surfaces of the support pieces 12 and 13 are formed to be inclined upwardly or inclined downwardly.

Figure 3 is a front view of the fork pin showing an embodiment of the present invention, as shown in the present invention, the support piece 12 between the end side of the insertion space portion 14 and the gripping protrusions 12A, 13A A pair of inclined surfaces 18 (18A) are formed on the inner surface of the c) inclined upward.

That is, the inclined surfaces 18 and 18A are to gradually reduce the cross-sectional area of the support pieces 12 and 13 toward the gripping protrusions 12A and 13A, so that the support pieces 12 having the form of cantilever beams ( If the cross-sectional area of 13) is made smaller toward the free end side, a larger amount of displacement can be obtained with the same force as compared to the displacement caused by applying a force to a supporting piece of the same length having the same cross-sectional area without the inclined surface.

4A and 4B, the cantilever beam is normally applied to the free end of the structure 20, as shown in FIG. 4A. As the displacement occurs while forming the difference curve, stress concentration is generated on the upper and lower sides of the structure 20 of the fixed end.

However, in the case of the structure 20A having the same length as that of the structure of FIG. 4A and having a smaller cross-sectional area toward the free end side as shown in FIG. 4B, the stress is reduced due to the reduction of the cross-sectional area. It is possible to obtain a larger displacement with respect to the vertical displacement, so that even if the length is somewhat shorter, the same displacement as in FIG. 4A can be obtained with respect to the vertical load.

In this way, the present invention, even if the length of the support pieces 12 and 13 is shortened as the enlarged area 15 is formed in the body 10 for volume compensation, the cross-sectional area of the support pieces 12 and 13 is a gripping protrusion ( 12A) is gradually reduced toward the side of 13A so that the stress can be reduced so that the insertion force can be compensated for, and the volume reduced by the inclined surfaces 18 and 18A is used to adjust the area of the enlarged area 15 to be somewhat larger. Can be compensated for.

In addition, another embodiment of the present invention shown in Figure 6, the support piece 12, 13 between the end side of the insertion space portion 14 and the gripping protrusions 12A, 13A as opposed to the embodiment of the present invention A pair of inclined surfaces 19 (19A) are formed on the inner surface to be inclined downward, and the inclined surfaces 19 (19A) hold the cross-sectional areas of the support pieces 12, 13, and 12A (13A). Towards the) side is gradually formed larger.

Thus, when the cross-sectional area of the support pieces 12 and 13 is gradually increased toward the gripping protrusions 12A and 13A, the cross-sectional areas of the supporting pieces 12 and 13 gradually increase toward the gripping protrusions 12A and 13A. The displacement amount is smaller for the same length and force than for the support pieces 12 and 13 formed smaller, and the insertion force is lowered.

However, the amount of displacement of the support pieces 12 and 13 can be changed by making the length of the support pieces 12 and 13 larger, and enlarged to make the length of the support pieces 12 and 13 larger. Even if the area of the area portion 15 is reduced, the volume compensation can be achieved by the area enlarged to both inner sides of the support pieces 12 and 13 by the inclined surfaces 19 and 19A.

In addition, it is possible to increase the displacement amount of the support pieces 12 and 13 without increasing the length of the support pieces 12 and 13, and the end side support pieces 12 and 13 of the insertion space portion 14 can be increased. It can be achieved by forming the deformation grooves (17) (17A) on both inner sides of the), even in the case of the fork pin presented in an embodiment of the present invention by the deformation grooves (17) (17A) You can get it.

That is, when the groove 20B is formed in the fixed end structure 20A as shown in FIG. 4C, the stress of the structure 20A due to the vertical load applied to the structure at the free end side is not concentrated at the fixed end side. By dispersing into the grooves 20B to produce an equivalent stress, it is possible to obtain a larger displacement than when the grooves are not formed.

In addition, the deformation grooves 17 and 17A are formed at the end of the insertion space 14 formed in a semicircular shape, and should be formed along a circle larger than the imaginary circular diameter forming the end of the insertion space 14. At first, at the fixed end of the support pieces 12 and 13, deformation is caused by primary stress and deformation is caused by secondary stress distributed again.

On the contrary, if the deformation grooves 17 and 17A are formed along a circle smaller than the imaginary circle diameter forming the end of the insertion space 14, the stress is not distributed to the load and the support piece 12 ( As the stress is concentrated only at the fixed end of 13), the function for increasing the amount of displacement cannot be performed.

Here, the present invention is described as being to be formed along the circular groove, but is not limited to the shape as long as it can fulfill the function according to the size of the groove may be performed.

5 and 7, the insert 300 is inserted into the insert space portion 14 entrance side of the body 10, the support piece 12, 13 to the insert 300 as shown in FIGS. While the upper side gripping protrusions 12A and 13A of the side contact with each other, the insertion force acts on the gripping protrusions 12A and 13A and the support pieces 12 and 13.

Accordingly, the stress due to the insertion force is concentrated on the lower end side of the support pieces 12 and 13, wherein the stress is supported by the connecting parts 16 and the end pieces are integrally formed with the support pieces 12 and 13. Primary stress is generated at the fixed end side of the support, and the support piece is expanded by the enlarged area 15 by being dispersed with an equivalent stress such that secondary stress is generated in the deformation grooves 17 and 17A of the support pieces 12 and 13. 12) 13 and even if the length of the insertion space portion 14 is to be able to maintain the existing displacement amount as it is.

1 is a cross-sectional view showing a state of use of a general fork pin.

Figure 2 is a front view showing a conventional fork pin structure.

Figure 3 is a front view showing an embodiment of the present invention.

Figures 4a to 4c is an exemplary view for explaining the action of the fork pin of the present invention.

5 is a front view showing the operating state of FIG.

6 is a front view showing another embodiment of the present invention.

7 is a front view illustrating an operating state of FIG. 6.

* Explanation of symbols for main parts of the drawings

10: body 11: fixed protrusions

12, 13: support piece 12A, 13A: gripping protrusions

14: insertion space 15: enlarged area

16: Connection 17, 17A: Bending groove

18,18A, 19,19A: Slope

Claims (5)

Between the pair of support pieces 12, 13 is formed an insertion space 14 which is open to the upper side, the lower portion of the support pieces 12, 13 is integrally formed by the connecting portion 16 The support pieces 12 and 13 include a pair of gripping protrusions 12A and 13A inside the upper end portion, and a body 10 having the fixing protrusion 11 integrally formed at the lower end of the connecting portion 16. For fork pins, The body 10 has an enlarged area 15 formed by extending the area of the connecting portion 16 toward the insertion space 14 so that volume compensation can be achieved by reducing the width and thickness of the body 10. The structure of the fork pin further comprising. The method of claim 1, The support pieces 12 and 13 are formed on the inner side between the end side of the insertion space 14 and the gripping protrusions 12A and 13A, and toward the gripping protrusions 12A and 13A. 13) The inclined surface 18 (18A) which enlarges the cross-sectional area of the fork pin is characterized in that formed. The method of claim 1, The support pieces 12 and 13 are formed on the inner side between the end side of the insertion space 14 and the gripping protrusions 12A and 13A, and toward the gripping protrusions 12A and 13A. 13, the inclined surface (19) (19A) is formed to reduce the cross-sectional area of the fork pin. The method according to claim 2 or 3, The support piece (12) (13) structure of the fork pin, characterized in that it further comprises a pair of deformation grooves (17) (17A) on both inner sides of the end of the insertion space (14). The method of claim 4, wherein The end of the insertion space 14 is formed in a semi-circular shape, the deformation grooves (17) (17A) is formed along an imaginary circle larger than the imaginary circular diameter forming the end of the insertion space (14). Structure of fork pin.

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