KR102151194B1 - Cement resistor fixing structure - Google Patents

Abstract

An object of the present invention is to provide a cement resistor fixing structure capable of fixing a cement resistor to a switch body without using a separate item such as a bolt or a foam pad,
A cement resistor fixing structure formed on a switch body, comprising: a bottom portion formed in a shape corresponding to the shape of the cement resistor and including an elastic support portion for pressing the cement resistor upward when the cement resistor is fixed; And a side wall extending upwardly along the circumference of the bottom portion, and having a snap portion formed thereon to prevent the cement resistor from being separated upward when the cement resistor is fixed. Including, it provides a cement resistor fixing structure in which the cement resistor is formed to be inserted and fixed to the inside of the side wall.

Description

Cement resistor fixing structure

The present invention relates to a structure for fixing a cement resistor installed in an opening/closing device that supplies or cuts off power from a battery.

A cement resistor is a type of resistance that interferes with the flow of electricity in an electronic circuit, and is a high-power resistor with an allowable power of about 5 to 25W. Compared with the allowable power of a general rod resistor of 0.125 to 0.25W, the allowable power of a cement resistor can be said to be considerably larger, and the size is also formed larger than that of other cement resistors. Cement resistors are also called ceramic cement resistors, and are provided in the form of molding a winding resistor in a case made of ceramic for structural insulation and heat dissipation.

Meanwhile, a battery power switch (hereinafter, referred to as a'switch') such as a power relay assembly (PRA) or a battery disconnect unit (BDU) includes a capacitive load for pre-charging. In addition, the switchgear generally includes a high current main relay that performs an emergency shut-off function. However, in the case of a high-voltage system having a capacitive load, an impulse current flows at the initial stage of energization, and the rush current causes power-up stress and damage to a component. Therefore, the switch has a large resistance that can act as a shock damping like a cement resistor to protect the main relay by lowering the peak value of the rush current.

In the case of a general rod resistor, the terminal is electrically connected and structurally fixed by soldering the terminal to the board. However, since the cement resistor is much larger in size and weight than the general rod resistor, it needs to be fixed to the switch body separately from the electrical connection.

1 is a perspective view of a conventional cement resistor fixing structure. Referring to FIG. 1 (a), an electrode 2 is formed on the cement resistor 1, and the cement resistor 1 is fixed by a bracket 3. The bracket (3) includes a fixing part (4) wrapped around the circumference of the cement resistor (1) and fixed, and an installation part (5) formed integrally with the fixing part (4) and having a bolting hole (6). By fastening the bolt 7 to the part 5, the cement resistor 1 can be fixed to the switch.

Alternatively, referring to FIG. 1 (b), after attaching the foam pad 10 to the lower part of the cement resistor 1, the cement resistor 1 is fixed by inserting it into the fixing structure formed on the switch body 8, and have. Furthermore, a snap structure 9 formed to support the upper surface of the cement resistor 1 is formed on one side of the portion where the cement resistor 1 is inserted, thereby preventing the cement resistor 1 from being separated. Here, the foam pad 10 is a structure for compensating for an assembly tolerance in the vertical direction, and is formed of a compressible material to provide an upward reaction force so that the cement resistor 1 does not vibrate vertically.

However, the above-described conventional cement resistor fixing structure uses a separate material (bracket and bolt, or foam pad) for the switch body, and causes an increase in material cost as well as an increase in the number of fastening man-hours, resulting in an increase in cost.

The present invention is to solve the problems of the prior art as described above, and an object of the present invention is to provide an economical fixing structure of a cement resistor. Specifically, an object of the present invention is to provide a cement resistor fixing structure capable of fixing a cement resistor to a switch body without using a bracket, bolt, or foam pad.

Furthermore, it is an object of the present invention to provide a cement resistor fixing structure capable of increasing A/S performance because it is easy to remove because no separate material is used.

An embodiment of the present invention is to solve the above problems, in the cement resistor fixing structure formed on the switch body, formed in a shape corresponding to the shape of the cement resistor, and the elastic support for pressing the cement resistor upward when the cement resistor is fixed. A bottom including a; And a side wall extending upwardly along the circumference of the bottom portion, and having a snap portion formed thereon to prevent the cement resistor from being separated upward when the cement resistor is fixed. Including, it provides a cement resistor fixing structure in which the cement resistor is formed to be inserted and fixed to the inside of the side wall.

In addition, a plurality of slits are formed in parallel in the bottom portion, and the elastic support portion includes a convex portion formed in a strip shape between the plurality of slits, and one portion is formed to be convex than the other surface of the bottom portion. do. When the cement resistor is inserted by the convex portion, a reaction force that pushes the cement resistor upward is generated while the convex portion is pressed downward, so that the cement resistor can be fixed without shaking up and down.

Further, the elastic support portion may include a concave portion formed to be concave than the other surface of the bottom portion, and the concave portion and the convex portion are formed alternately. In this case, the peak point of the convex portion can be flexibly moved up and down by the concave portion.

In addition, at least one rib is formed extending along the insertion direction of the cement resistor on the inner side of the side wall. Further, the rib is formed in a triangular cross-section, and the upper end of the rib is formed to be inclined downward from the sidewall. The rib is formed in a space between the cement resistor and the side wall, and is a structure to prevent the cement resistor from vibrating in the transverse direction. Since the top of the rib has a downward slope, it is easy to insert the cement resistor, and the cross section of the rib is formed in a triangular shape, so when the cement resistor is forcibly fitted inside the side wall, the rib is crushed and the position of the cement resistor can be stably fixed.

In addition, the bottom portion may include at least one drain hole formed through the bottom portion, thereby preventing moisture from accumulating in the switch.

In addition, the snap portion may include an extension portion extending upwardly from the bottom portion to form a part of the side wall, and a locking protrusion formed protruding from an upper end portion of the extension portion in an inward direction of the side wall.

Further, the snap part includes a cut line through which the bottom part is formed from a lower end of the extension part, and the cut line is a boundary line of the bottom part and the extension part, and an arbitrary outer direction of the side wall at both ends of the boundary line. It is characterized in that it is formed along the line of. When there is an incision line, it can be more easily deformed in a direction in which the snap portion is disengaged than when there is no incision line.

According to the above-described problem solving means of the present invention, various effects including the following can be expected. However, the present invention is not established when all of the following effects are exhibited.

According to the present invention, since the cement resistor can be pressed upward and supported by the elastic support portion formed on the bottom, it is possible to reduce the cost due to the increase in material cost and man-hours since a separate structure is not required as in the conventional foam pad. Therefore, it has a very economical advantage.

In addition, according to the present invention, it is possible to prevent the cement resistor from flowing in the transverse direction by the ribs formed on the side walls, and to prevent the cement resistor from moving in the vertical direction by the elastic support and snap portions. Therefore, it is possible to stably fix the cement resistor, thereby improving durability.

In addition, it is possible to improve the durability of the switch by solving the problem that moisture accumulates in the switch with a drain hole and a plurality of slits formed on the bottom.

1 is a perspective view of a fixed structure of a conventional cement resistor,
2 is a perspective view of a cement resistor fixed to the cement resistor fixing structure of the present invention,
Figure 3 is a perspective view of the cement resistor in Figure 2,
Figure 4 is a plan view of Figure 3,
5 is a cross-sectional perspective view showing a cross section XX' in FIG. 4;
6 is a cross-sectional view taken along the YY' in FIG. 4.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 2 is a perspective view of a cement fixed to the cement resistor of the present invention, FIG. 3 is a perspective view of the cement resistor in FIG. 2, FIG. 4 is a plan view of FIG. 3, and FIG. 5 is a cross-sectional perspective view showing a cross section of XX' 6 is a cross-sectional view taken along the YY' in FIG. 4.

As shown in these drawings, the present invention relates to a cement resistor fixing structure 100 formed on the switch body 8, and a bottom portion 120 forming a structure into which the cement resistor 1 can be inserted and It includes a side wall (110). The cement resistor 1 may be inserted and fixed inside the sidewall 110. Each configuration described below is preferably integrally plastic injection-molded as a part of the switch body 8, but it is also irrelevant that it is made of another material having elasticity or is formed in a separate configuration and bonded to each other.

The bottom part 120 forms a bottom surface having a shape corresponding to the cross-sectional shape of the cement resistor 1 and supports the lower surface of the cement resistor 1, and is an elastic support part that presses the cement resistor 1 upward. (123) and a drain hole 121 formed through the bottom surface.

As shown in FIGS. 3 and 4, a plurality of slits 122 penetrating the bottom surface are formed in parallel on the bottom portion 120. In the drawing, a portion formed in a strip shape between the two slits 122 is referred to as an elastic support part 123, and the slit 122 and the elastic support part 123 are formed in the longitudinal direction (longitudinal direction) of the bottom part 120. desirable.

The elastic support portion 123 is formed with a concave portion 125 that is concave than other portions of the bottom portion 120 and a convex portion 124 that is convexly formed, and is formed in a shape that is meandering in the vertical direction as a whole. The concave portion 125 and the convex portion 124 are formed alternately, and preferably, the concave portion 125, the convex portion 124, and the concave portion 125 may be sequentially formed as shown in the figure.

When the cement resistor 1 is inserted and mounted, the convex portion 124 is elastically deformed by pressing the convex portion 124 downward, and at the same time, it provides a reaction force to press the cement resistor 1 upward, and thus the cement resistor 1 ) Can be fixed in the vertical direction. Further, the concave portion 125 is a structure for more flexible elastic deformation when the convex portion 124 is pressed downward by the cement resistor 1, and the cement resistor 1 is formed by the concave portion 125. Can be easily inserted and mounted.

In addition, a drain hole 121 may be formed in the bottom 120 by penetrating the bottom surface. The drain hole 121 is configured to discharge moisture without accumulating in the switch body 8. Moisture may also be discharged through the aforementioned slit 122, and it is possible to prevent the quality of the resistor and the switch from deteriorating due to moisture.

The sidewall 110 is formed to extend upward from the bottom portion 120 along the periphery of the bottom portion 120 to form a structure in which the cement resistor 1 can be inserted inside the sidewall 110.

A plurality of ribs 111 are protruded on the inner side of the side wall 110. The rib 111 is preferably formed extending along the insertion direction of the cement resistor 1, that is, the vertical direction. Furthermore, the rib 111 may have a narrower width of the protruding end than the protruding start point. More preferably, as shown in FIG. 4, a cross section perpendicular to the longitudinal direction in which the rib 111 extends may be formed in a triangular shape. In addition, as shown in FIG. 5, the upper end of the rib 111 has a downwardly inclined surface 112 inclined downward from the sidewall 110.

The reason that the cross section of the rib 111 is formed in a triangular shape is to facilitate the protruding end of the rib 111 to be crushed when the cement resistor 1 is forcibly fitted to the inside of the side wall 110. In addition, the downwardly inclined surface 112 at the top of the rib 111 is to guide the insertion position when inserting the cement resistor 1 and at the same time allow the rib 111 to start crushing with little force. As the rib 111 is crushed, since the cement resistor 1 is forcibly fitted, the cement resistor 1 can be stably fixed without flowing in the transverse direction, and separation from the switch body can be prevented.

One side of the sidewall 110 may be provided with a snap portion 130 that supports the upper surface of the cement resistor 1 and prevents the cement resistor 1 from being separated from the top. The snap part 130 includes a lance 132 that elastically deforms to be coupled to or released from the upper surface of the cement resistor 1 and a cut line 131 formed through the bottom part 120 along the lower end of the lance 132 do. The snap portion 130 is formed on one of the side surfaces and is formed to be separated from the side surface.

The lance 132 has an extension part 133 extending from the bottom part 120 to form the same plane as the side wall 110, and protruding from the upper end of the extension part 133 in the inward direction of the side wall 110. It includes a locking protrusion 134. The lance 132 may be elastically deformed in the outer direction of the sidewall 110 as shown in FIG. 6 because only the lower end of the lance 132 is connected to the instrument body. When no external force is applied to the lance 132, it may be coupled to the cement resistor 1, and when a force is applied to the lance 132 in the outward direction of the side wall 110, the lance 132 is elastically deformed and the coupling can be released. have.

The locking protrusion 134 of the lance 132 has an inclined surface 136 formed downward from the upper end of the extension part 133, and the lower part is a chin to form a contact surface 135 in contact with the upper surface of the cement resistor 1 Is formed.

When inserting the cement resistor 1 into the switch body 8, the lance 132 can be easily elastically deformed in the outward direction of the side wall 110 by the inclined surface 136, and the cement resistor 1 is inserted. Afterwards, the position of the lance 132 is restored so that the contact surface 135 is in contact with the upper surface of the cement resistor 1 to prevent the cement resistor 1 from being separated upward. In other words, the cement resistor 1 may be fixed so as not to move in the vertical direction by the locking protrusion 134 and the elastic support 123.

The cut line 131 is formed at the lower end of the extension part 133. The cut line 131 is formed to pass through the opening/closing body along an arbitrary line formed in the outer direction of the sidewall 110 at both ends of the boundary line and the boundary line between the extension part 133 and the bottom part 120. That is, it may be formed in a'c' shape as shown in the drawing.

As a result, the length of the lance 132 is increased by the cut line 131. Therefore, when the lance 132 is elastically deformed in the direction in which the coupling is released, it can be elastically deformed to a larger radius with a small force.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains are capable of various modifications and variations without departing from the essential characteristics of the present invention. The scope of protection should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

1: cement resistor 8: switch body
100: cement resistor fixing structure 110: side wall
111: rib 112: downward slope
120: bottom part 121: drain hole
122: slit 123: elastic support
124: convex portion 125: concave portion
130: snap portion 131: incision line
132: lance 133: extension
134: locking projection 135: contact surface
136: slope

Claims (8)

In the cement resistor fixing structure formed in the switch body,
A bottom portion formed in a shape corresponding to the shape of the cement resistor and including an elastic support portion for pressing the cement resistor upward when the cement resistor is fixed; And
A side wall extending upwardly along the circumference of the bottom portion and having a snap portion formed thereon to prevent the cement resistor from being separated upward when the cement resistor is fixed;
Including,
A plurality of slits are formed through the bottom in parallel,
The elastic support portion is formed in a strip shape between the plurality of slits, and includes a convex portion in which one portion is convexly formed than the other surface of the bottom portion,
The elastic support portion and the snap portion are integrally formed in the switch body, the cement resistor fixing structure in which the cement resistor is formed to be fixed to the inside of the side wall.
delete The method of claim 1,
The elastic support portion includes a concave portion formed to be concave than the other surface of the bottom portion, and the concave portion and the convex portion are formed alternately.
The method of claim 1,
At least one rib is formed extending along the insertion direction of the cement resistor on the inner side of the side wall.
The method of claim 4,
The rib is formed in a triangular cross-section,
Cement resistor fixing structure, characterized in that the upper end of the rib is formed to be inclined downward from the side wall.
The method of claim 1,
The cement resistor fixing structure, wherein the bottom portion includes at least one drain hole formed through the bottom portion.
The method of claim 1,
The snap portion includes an extension portion extending upward from the bottom portion to form a part of the side wall, and a locking protrusion formed protruding from an upper end portion of the extension portion in the inner direction of the side wall. rescue.
The method of claim 7,
The snap portion includes a cut line through which the bottom portion is formed at a lower end of the extension portion,
The cut-out line is formed along a boundary line of the bottom part and the extension part, and an arbitrary line formed in an outer direction of the sidewall at both ends of the boundary line.

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