KR20090060790A - A tensile tester - Google Patents

Abstract

A tensile tester is provided to set various angles between a cable and a connector without the movement of a movable member and to thereby measure the terminal retention easily and accurately. A tensile tester comprises a base plate(10) in which a clamp(11) fixing a connector housing is installed, a vertical plate(30) equipped on one end of the base plate, a moving disk(60) in which a part of the cable hang up so that the connector housing and the cable are inclined, and a rotation part(50) controlling the inclination angle of the cable to the connector housing. On the vertical plate, an angle scale is indicated in order to measure the inclination angle of the cable to the connector housing.

Description

Tensile Tester

The present invention relates to a tensile tester, and more particularly to a tensile tester capable of measuring the terminal holding force of the connector by transmitting a tensile force to the cable connected to the connector at various angles.

The connector is a connecting mechanism for connecting the circuits or devices so as to be electrically connected to each other. A connector is installed inside a mechanical device such as an automobile together with various cables to supply electricity from a battery. At this time, the terminal is inserted and fixed to the housing forming the appearance of the connector. The terminal is connected to the terminal provided in the mating connector or mounted on other circuit boards to serve as a connection area.

The connectors used in these machines must have the required terminal holding capacity depending on the nature of the field of use.

In order to measure the terminal holding force of the connector, a tensile tester is used. The tensile test is a basic test for knowing the mechanical properties of industrial materials. It is an experiment for measuring the resistance of a material to a force pulling in the opposite direction at a constant speed.

It is most widely used to obtain basic design information on material strength. It examines the deformation process and stress changes of industrial materials, and provides mechanical properties such as yield strength and tensile strength of materials, elastic limits, proportional limits, and elasticity. The objective is to find the physical properties of the coefficients.

1 is a front view of a tension tester according to the prior art. As shown in this figure, holders (1, 2) for fixing the cable (W) and the connector (C) is provided, one holder (1) is fixed to the fixing member (3), the other holder (2) ) Is installed on the movable member 4 installed to move horizontally or vertically and moves together. The holders 1 and 2 are divided on both sides to adjust the gap by the control levers 5 and 6 provided on one side.

Both ends of the cable (W) should be fixed for the tensile test. For this purpose, the holder (1) installed on the fixing member (3) and the holder (2) installed on the movable member (4) are spaced apart by the control levers (5, 6). And widen the cable (W) and the connector (C) between them, and then use the control levers (5, 6) to narrow the distance between the holders (1, 2) and the cables (W) located therebetween. ) And connector (C). When the cable (W) and the connector (C) is fixed in this way, the movable member (4) is moved to perform a tensile test to measure the terminal holding force.

When the tensile test is executed, the tensile force is transmitted and the cable (W) starts to be tensioned. If the cable (W) connected to the connector (C) is stretched above the limit of the terminal holding force of the cable (W), breakage occurs inside the connector (C). The terminal is disconnected. At this time, the terminal holding force of the connector (C) can be known based on the tensile force applied.

In general, the cable W connected to the connector C is often connected to be inclined at a predetermined angle as well as in the direction perpendicular to the connector C. Therefore, when the connection direction of the cable W in the connector C is inclined at a certain angle such as 30 degrees, 60 degrees, 90 degrees, a test for the terminal holding force is required.

However, the tension tester according to the prior art as described above has the following problems.

In order to change the inclination angle of the cable (W) connected to the connector (C) in the prior art, the movable member (4) should be moved to form a predetermined angle between the connector (C) and the cable (W). Since it is difficult to secure an accurate moving distance of the member 4, there is a problem that it is difficult to accurately set the inclination angle of the cable W to be tested.

The present invention is to solve the problems of the prior art as described above, an object of the present invention is to enable the various angles of the connector and the cable can be set without moving the movable member so that the tension tester can easily and accurately measure the terminal holding force To provide.

According to a feature of the present invention for achieving the object as described above, the present invention includes a base plate provided with a clamp for fixing the connector housing; A vertical plate provided at one end of the base plate and having an angle displayed on one surface thereof to measure an inclination angle of the cable connected to the connector housing with the connector housing; It is installed on the vertical plate by a fastening member, and one side is provided with a moving disk to which a part of the cable is walked so that the connector housing and the cable is inclined, the other side to adjust the inclination angle of the cable and the connector housing And a rotational hole for selectively rotating the fastening member as a rotating shaft.

The rotating slot is formed with a guide slot elongated along the longitudinal direction of the rotating sphere, the movable disk is relative to the fastening member within the range in which the guide slot is formed to adjust the inclination angle of the cable with the connector housing. It is installed to be movable.

The movable disk is fixed to the pivot by a fastening member penetrating through the guide slot at one side of the pivot, and the fixing part is coplanar with the fixing part so as to be rotatable about a central axis. It is installed in the radial direction of the government, and the cable comprises a rotating part surrounding a part of the edge.

A ball bearing is provided between the fixed part and the rotating part to reduce frictional force during rotation of the rotating part.

The movable disk has a cable seating groove formed around the edge of the movable disk to prevent separation of the cable during rotation.

According to the present invention, since the connector housing and the cable can form various inclination angles by rotating the pivoting hole, the terminal holding force of the connector housing can be easily and accurately measured.

In addition, in the present invention, since the moving disk on which the cable is walked can be fixed at various positions while moving the guide slot formed in the pivot, the inclination angle of the connector housing and the cable can be adjusted in detail.

Hereinafter, a preferred embodiment of a tensile tester according to the present invention having the configuration as described above will be described in detail with reference to the accompanying drawings.

2 is a front view showing the configuration of a preferred embodiment of the tensile tester according to the present invention, Figure 3 is an exploded perspective view of the pivoting hole and the moving disk constituting an embodiment of the present invention, Figure 4 is an embodiment of the present invention In the example, the fastening state of the movable disk is shown in cross section.

As shown in these figures, the base plate 10 is formed in a substantially hexahedral shape. The base plate 10 is installed to be substantially parallel to the horizontal plane, the clamp 11 is installed on the base plate 10.

The clamp 11 is provided with a fixture 12. The holder 12 may be formed integrally with the base plate 10 in a substantially hexahedral plate shape, but is preferably fastened to be detachable by a bolt or the like for easy replacement.

The holder 12 is formed to protrude from the holder 12. The moving holder 16 is fastened to the fixed holder 14 to be movable by the fastener 20. That is, the moving holder 16 moves relative to the fixed holder 14 by the rotation of the fixture 20.

The fixing holder 14 and the moving holder 16 are formed with holes (not shown) through which the fastener 20 penetrates, and the fastener 20 is inserted into the hole formed in the moving holder 16 to move the moving holder 16. Threads and screw bones are formed to guide the movement of the holder 16. The connector housing C is selectively fixed between the fixed holder 14 and the moving holder 16 by the movement of the moving holder 16.

In order for the moving holder 16 to move in conjunction with the rotation of the fixture 20, the moving holder 16 should not rotate together with the fixture 20. Therefore, guide members (not shown) may be provided at both sides of the moving holder 16 to guide the movement of the moving holder 16 while preventing the moving holder 16 from rotating. However, the guide member is not necessarily provided because the user can prevent the moving holder 16 from rotating when the fixing tool 20 rotates.

The front end of the fixture 20 is provided with a screw portion 22 inserted into the hole of the moving holder 16 to guide the movement of the moving holder 16. The screw portion 22 is fastened to the moving holder 16 through the fixing holder 14.

In addition, the other end of the fixture 20 is provided with a support 24 and the operation unit 26. The support 24 is formed surrounding the outer circumferential surface of the fixture 20. The diameter of the support 24 is larger than the hole of the fixed holder 14 so that the support 24 does not penetrate the hole of the fixed holder 14 and is supported on the outer surface of the fixed holder 14. do.

The operation unit 26 is formed to protrude from the outer peripheral surface of the fastener 20 to face in opposite directions to each other. The user rotates the fixture 20 by using the manipulation unit 26.

One end of the base plate 10 is provided with a vertical plate 30 formed in a substantially hexahedral plate shape perpendicular to the base plate 10.

The goniometer 40 is installed at the height of the connector housing C in the vertical plate 30. The goniometer 40 is connected to the connector housing (C) to measure the inclination angle (θ) formed by the cable (W) and the connector housing (C), which is connected to the moving disk 60 to be described below, The front end of the connector housing C to which the cable W is connected is installed at the center of the goniometer 40.

The goniometer 40 is installed separately to facilitate the adjustment and replacement of the installation position, but it is not necessarily so, and measures the inclination angle of the cable (W) at a position corresponding to the connector housing (C) according to the design conditions. The angle plate may be displayed on the vertical plate 30 itself.

The rotating plate 50 is provided on the vertical plate 30 to be rotatable with the fastening member B as a rotating shaft. The rotating hole 50 is formed in a substantially long plate shape, the fastening member (B) is provided on one side, the moving disk 60 is installed on the other side is the cable (W).

As the pivoting port 50 rotates about the fastening member B, the relative position of the movable disk 60 with respect to the connector housing C is changed, and the relative position of the movable disk 60 is changed. As the position is changed, the inclination angle θ formed by the cable W with the connector housing C is changed. The fastening member (B) is preferably fastened above the connector housing (C) vertically.

Guide slots 52 are formed in the pivoting hole 50 in the longitudinal direction of the pivoting hole 50. The fastening member B penetrates through one side of the guide slot 52 to fix the pivoting hole 50 to the vertical plate 30.

More precisely, when the rotating tool 50 is loosely tightened, the rotating tool 50 is rotated, and when the rotating tool 50 is rotated by a set angle, the fastening member B is tightened to rotate the rotating tool ( 50) is fixed so as not to rotate.

At the other end of the pivoting port 50, the movable disk 60 is installed to be movable along the guide slot 52. The movable disk 60 is composed of a fixing part 62 and the rotating part (64).

3 and 4, the fixing part 62 is formed in a disk shape, and a fastening hole 62 'through which the fixing member F penetrates is formed in the middle. The fixing part 62 is installed at the other side of the guide slot 52. In more detail, the fixing member F passes through the fastening hole 62 ′ and the guide slot 52 of the fixing portion 62 in order and is fixed by the nut N. The user can adjust the position of the fixing part 62 within the range in which the guide slot 52 is formed at this time.

The rotating part 64 is installed around the fixing part 62 so as to be rotatable about the fixing part 62 as a central axis. That is, the rotating part 64 is installed in the radial direction of the fixing part 62 on the same plane as the fixing part 62. A ball bearing 70 is provided between the rotating part 64 and the fixing part 62 to reduce frictional force when the rotating part 64 rotates.

In the ball bearing 70, a plurality of balls 76 are sandwiched between the inner race 72 and the outer race 74 so as to enable rolling. The inner race 72 and the outer race 74 are fixed to the fixing portion 62 and the rotating portion 64, respectively. The ball 76 is maintained at a constant distance from each other by the retainer 78, a plurality of pockets (not shown) are formed at a constant interval in the retainer 78 so that each ball 76 is cloudable It is. In addition, seals 79 and 79 'are provided at the front and rear of the inner race 72 and the outer race 74 to block the space where the ball 76 is inserted from the outside.

That is, the rotation part 64 is rotatably installed with respect to the fixing part 62. For this relative rotation, the ball bearing is not necessarily used, and in general, the rotation part 64 may be variously applied as long as it can cause relative rotation. .

As shown in FIG. 3, a cable seating groove 64 ′ is formed at the edge of the rotating part 64. A cable W connected to the connector housing C is hooked into the cable seating groove 64 ′. That is, when the tensile force is applied to the cable (W), the cable (W) may be separated in the state that is engaged with the edge of the rotary unit 64 as the rotating unit 64 rotates, the cable seating groove ( 64 ') prevents the cable W from coming off.

The movable disk 60 may be installed at various positions within the range in which the guide slot 52 is formed. As the movable disk 60 moves in the direction in which the connector housing C is fixed, the cable ( The inclination angle θ formed by W) with the connector housing C is reduced.

As described above, the inclination angle [theta] can be adjusted by rotating the rotating tool 50 or moving the moving disk 60. The latter is used when more careful adjustment is required than the former.

In addition, when the moving disk 60 is moved, the inclination angle θ to be set can be adjusted even when the length of the cable C to be tested is relatively short.

Hereinafter, the operation of the tensile tester according to the present invention having the configuration as described above in detail.

5 and 6 are front views showing a state in which the position of the rotational sphere and the movable disk in the preferred embodiment of the present invention is adjusted.

First, a description will be made of the process of installing the moving disk 60 in the rotational hole 50, as shown in Figure 4, the fixing member F penetrating through the fastening hole 62 'of the moving disk 60 ) Is fastened to the nut (N) through the guide slot (52).

At this time, the fixing part 62 of the moving disk 60 is in a state of being in close contact with the rotating hole 50, and the rotating part 64 of the moving disk 60 is free to the fixing part 62. Rotation is possible.

In addition, the rotation hole 50 is installed on the vertical plate 30 by the fastening member B on the opposite side of the movable disk 60.

Next, in order to measure the terminal holding force of the connector housing (C), the connector housing (C) to which the cable (W) is connected is positioned between the fixing holder (14) and the moving holder (16). At this time, the cable (W) connected to the connector housing (C) is connected to a tension jig (J) installed separately to transmit a tensile force to the connector housing (C), the cable (W) is a tension jig (J) In order to face), the connector housing C is fixed to face in the opposite direction in which the tension jig J is installed.

Rotating the operation part 26 in this state reduces the distance between the fixed holder 14 and the moving holder 16. Since the support part 24 is supported by the fixed holder 14, the moving holder 16 ) Moves to the fixing holder 14 to fix the connector housing (C).

At this time, the start of the cable (W) inclined in the connector housing (C) is preferably adjusted to be located at the starting point (reference point) of the goniometer (40).

The cable (W) is connected to the tension jig (J) surrounding the cable seating groove (64) of the movable disk (60). In this state, the inclination angle θ may be adjusted by rotating the rotational tool 50. When the rotational tool 50 rotates in the clockwise direction, the inclination angle θ becomes large, and the rotational hole 50 is rotated. As shown in FIG. 5, when rotated counterclockwise, the inclination angle θ becomes small.

In addition, as shown in FIG. 6, the inclination angle θ may be finely adjusted by moving the moving disk 60 toward or away from the connector housing C. FIG. At this time, the movable disk 60 is movable within the formation range of the guide slot 52 formed in the rotating hole (50).

When the inclination angle θ formed by the cable W with respect to the connector housing C is set by the above-described process, the tension jig J moves in a direction away from the connector housing C. .

Then, the cable W is tensioned, and a tensile force is transmitted to the terminal inserted into the connector housing C. Tensile force is increased due to the continuous movement of the tension jig J, and when the tension force acts above the limit of the terminal holding force, breakage occurs in the connector housing C and the terminal is separated.

As such, when the terminal is separated from the connector housing (C), the tensile strength at the moment of separation from the computer connected to the tensile tester is measured.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

1 is a front view showing the configuration of a tensile tester according to the prior art.

Figure 2 is a front view showing the configuration of a preferred embodiment of a tensile tester according to the present invention.

Figure 3 is an exploded perspective view showing a rotating sphere and a moving disk constituting an embodiment of the present invention.

Figure 4 is a cross-sectional view showing a fastening state of the movable disk in the embodiment of the present invention.

5 and 6 is a front view showing a state in which the position of the rotational sphere and the moving disk in the preferred embodiment of the present invention is adjusted.

Explanation of symbols on the main parts of the drawings

10: Baseplate 11: Clamp

12: holder 14: holder

16: moving holder 20: fixture

22: screw portion 24: support portion

26: operation unit 30: vertical plate

40: goniometer 50: turning hole

52: guide slot 60: movable disk

62: fixing part 64: rotating part

70: ball bearing C: connector housing

W: Cable J: Tension Jig

Claims (5)

A base plate provided with a clamp for fixing the connector housing; A vertical plate provided at one end of the base plate and having an angle displayed on one surface thereof to measure an inclination angle of the cable connected to the connector housing with the connector housing; It is installed on the vertical plate by a fastening member, and one side is provided with a moving disk to which a part of the cable is walked so that the connector housing and the cable is inclined, the other side to adjust the inclination angle of the cable and the connector housing Tensile tester characterized in that it comprises a rotating hole for selectively rotating the fastening member as a rotating shaft. According to claim 1, wherein the rotating slot is formed in the guide slot lengthwise along the longitudinal direction of the rotating sphere, the movable disk within the range in which the guide slot is formed to adjust the inclination angle of the cable and the connector housing Tensile tester characterized in that the relatively movable toward the fastening member is installed. The method of claim 2, wherein the movable disk A fixed part fixed to the pivot by a fastening member penetrating the guide slot at one side of the pivot; Tensile tester is installed in the radial direction of the fixing part on the same plane as the fixing part so as to be rotatable about the fixing part as a central axis, characterized in that the cable comprises a rotating part surrounding a portion of the edge. The tensile tester of claim 3, wherein a ball bearing is provided between the fixing part and the rotating part to reduce frictional force when the rotating part is rotated. The tensile tester according to any one of claims 1 to 4, wherein the moving disk has a cable seating groove formed around the edge of the moving disk to prevent separation of the cable during rotation.

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