KR20100008992U - Load cell - Google Patents

Abstract

The present invention relates to a load cell, and aims at enabling an accurate load measurement by attenuating the flow generated at the same time as limiting the excessive flow of the weight of the weight of the weigher plate (Weigher Plate) generated when measuring the load of the object.

In order to achieve the above object, the present invention includes a metal elastic body, a weight plate supporting the object and a load support for transferring the load applied to the weight plate to the metal elastic body, the load support is fixed to the weight plate A load cell consisting of an upper ball cup, a lower ball cup fixed to a metal elastic body, and a ball disposed between the upper ball cup and the lower ball cup, to limit and attenuate excessive flow of the wafer plate generated at the time of measuring an object. The elastic support member may be further provided to elastically support the wafer plate to the metal elastic body.

Description

Load cell {LOAD CELL}

The present invention relates to a load cell for measuring a load, and more particularly, to limit the excessive flow of the weight of the side plate (Weigher Plate) generated in the measurement of the load of the object and at the same time attenuates the generated flow The present invention relates to a load cell that enables accurate load measurement.

A load cell is a device which converts the magnitude of the applied load into an electric quantity and measures it. As shown in FIG. 1, the load cell has a base plate 10, and a metal elastic body 20 is installed in a cantilever shape on an upper surface of the base plate 10.

The metal elastic body 20 is a rectangular columnar shape, and has the fixing | fixed part 22 and the extended part 24 extended along the base plate 10 from the fixed part 22. As shown in FIG.

The fixing part 22 is fixed on the base plate 10 and serves as a fixing end. The extension part 24 is comprised so that it may be deflected by the load applied from the upper part. Thus, it serves as a free end.

On the other hand, a pair of strain gauges 30 are attached to both sides of the extension part 24.

The strain gauge 30 detects the bending deformation of the extension part 24 and converts it into electrical resistance. The two strain gauges 30 are attached to both sides of the extension part in parallel with each other. In FIG. 1, only one of the two strain gauges 30 is shown. The strain gauge 30 is connected to a data processor (not shown) through a cable 32.

In addition, the load supporter 40 and the weight plate (Weigher Plate) 50 are sequentially disposed on the upper part of the extension part 24.

The wafer plate 50 is configured to support the measurement object, and the load support 40 serves to transfer the load applied to the wafer plate 50 to the metal elastic body 20.

In particular, the load support 40 is to transfer the load applied from the top to the metal elastic body 20 to enable the strain gauge 30 to accurately measure the load, as shown in FIG. The upper ball cup 42 fixed to the bottom of the plate 50, the lower ball cup 44 fixed to the upper surface of the extension portion 24 and disposed between the upper ball cup 42 and the lower ball cup 44 Consisting of a ball 46.

Here, the bottom surface of the upper ball cup 42 and the upper surface of the lower ball cup 44 are formed with concave surfaces 42a and 44a on which the upper and lower surfaces of the ball 46 can be seated, respectively. 44a always return the position of the ball 46 to the center of the concave surfaces 42a and 44a. Therefore, the load applied to the wafer plate 50 is always transmitted perpendicular to the metal elastic body 20.

On the other hand, the weir plate 50 is in spherical contact by the metal elastic body 20 and the ball 46, when the lateral force is applied, it can flow in the vertical direction and the left and right directions with respect to the metal elastic body 20 When the up and down and left and right flows are excessive, the metal elastic body 20 may be separated from the upper portion.

Therefore, the load cell is provided with up and down flow preventing means and left and right flow preventing means for preventing excessive vertical flow and left and right flow of the wafer plate 50.

The vertical flow preventing means includes a flow preventing bolt 60 as shown in FIG. 1. The anti-flow bolt 60 is inserted through the anti-flow hole 52 formed in the wafer plate 50 and the end thereof is screwed to the base plate 10.

This vertical flow preventing means restricts excessive vertical flow of the flow preventing bolt 60. Therefore, the detachment of the wafer plate 50 is prevented.

The horizontal flow preventing means has a pair of flow preventing plates 70 as shown in FIG. The anti-flow plate 70 is disposed at predetermined intervals on both sides of the wafer plate 50.

This left and right flow preventing means restricts excessive left and right flow of the wafer plate 50. Therefore, the detachment of the wafer plate 50 is prevented. Typically, the anti-flow plate 70 is configured to be installed in advance in the installation portion of the load cell.

According to such a structure, a measurement object is mounted on the wafer plate 50. Then, the load of the measuring object is applied to the wafer plate 50, and the load applied to the wafer plate 50 passes through the upper ball cup 42 and the ball 46 and the lower ball cup 44, It acts perpendicular to the extension 24 of 20.

At this time, the bending portion of the extension part 24 of the metal elastic body 20 is generated, and the bending deformation is immediately detected by the pair of strain gauges 30 and is input to the data processing part through the cable 32.

However, such a conventional load cell has a disadvantage in that a separate flow preventing bolt 60 and a flow preventing plate 70 must be provided in order to prevent the left and right flows and the vertical flow of the waer plate 50. Due to these disadvantages, a large manufacturing cost is required, thereby increasing the manufacturing cost.

In addition, the conventional load cell, there is a disadvantage that the assembly labor is increased, because the manufactured flow preventing bolt 60 and the flow preventing plate 70 must be assembled and installed one by one, due to this disadvantage, assembly and manufacturing time is delayed Thereby, there exists a problem that productivity falls remarkably.

In particular, in the case of the anti-flow plate 70, it is necessary to install in advance in the mounting portion of the load cell, it is very difficult and cumbersome to install, such as to accurately adjust the position and spacing of the load cell at the time of installation It is pointed out.

The present invention is devised to solve the conventional problems as described above, the object is to provide a load cell that can prevent the flow of the up, down, left, right of the Weier plate without the flow prevention bolt and the flow prevention plate. There is.

Another object of the present invention is to prevent the flow of the up, down, left and right of the Weier plate without the flow prevention bolt and the flow prevention plate, there is no need to provide a flow preventing bolt and the flow prevention plate, do not need to install them individually To provide a load cell.

Another object of the present invention, there is no need to include a flow preventing bolt and a flow preventing plate, there is no need to install them, it is possible to reduce the manufacturing cost, shorten the assembly time, improve the productivity To provide a load cell.

The present invention for achieving the above object includes a metal elastic body, a weight plate supporting the object and a load support for transmitting the load applied to the body plate to the metal elastic body, the load support is the way In the load cell consisting of an upper ball cup fixed to the air plate 50, a lower ball cup fixed to the metal elastic body, and a ball disposed between the upper ball cup and the lower ball cup, a waer plate generated when the load of an object is measured It characterized in that it further comprises an elastic support member for elastically movably supporting the wafer plate to the metal elastic body so as to limit the excessive flow and at the same time attenuate.

Preferably, the elastic support member comprises a tubular body, the tubular body, the metal around the lower ball cup, one side of which is fitted around the upper ball cup and fixed, and the other side corresponds to the circumference of the upper ball cup. It is characterized in that it is fixed to the elastic portion.

Since the load cell according to the present invention has a structure for supporting the wafer plate on the metal elastic body, there is an effect that can be prevented from being separated from the metal elastic body.

In particular, when the load is measured, the lateral force acts on the waer plate, so that even if the waer plate flows excessively up, down, left, and right, there is an effect of preventing the departure of the waer plate at its source.

In addition, since the structure for supporting the wafer plate on the metal elastic body, it is possible to prevent the flow of the wafer plate without the flow preventing bolt and the flow preventing plate. Therefore, it is not necessary to provide the flow prevention bolt and the flow prevention plate, and do not need to install them. As a result, manufacturing cost can be reduced, assembly time can be shortened, and productivity can be improved.

In addition, the present invention, since the structure is to elastically support the wafer plate to the metal elastic body, it is possible to efficiently attenuate the up, down, left, right flow of the Weier plate generated during the load measurement. Therefore, the flow of the wafer plate can be reduced as much as possible when measuring the load. Thereby, there is an effect that accurate load measurement is possible.

Hereinafter, a preferred embodiment of a load cell according to the present invention will be described in detail with reference to the accompanying drawings (the same configuration as conventionally described with the same reference numerals).

First, the configuration of the load cell will be briefly described with reference to FIG. 3 before looking at the features of the load cell according to the present invention.

The load cell has a base plate 10, and a metal elastic body 20 is provided in a cantilever shape on the upper surface of the base plate 10.

The metal elastic body 20 has the fixing | fixed part 22 and the extension part 24 extended in the cantilever form from the fixed part 22. As shown in FIG.

A pair of strain gauges 30 are attached to both sides of the extension part 24. The two strain gauges 30 are one pair and are attached to both sides of the extension side by side. The strain gauge 30 is connected to a data processor (not shown) through a cable 32.

In addition, the load supporter 40 and the waer plate 50 are sequentially disposed at the upper portion of the extension part 24.

The waiter plate 50 is configured to support the measurement object, and the load supporter 40 serves to vertically transfer the load applied to the waiter plate 50 to the metal elastic body 20.

In particular, the load support 40, the upper ball cup 42 is fixed to the bottom surface of the Weier plate 50, the lower ball cup 44 and the upper ball cup 42 is fixed to the upper surface of the extension portion 24 and It is composed of a ball 46 disposed between the lower ball cup (44).

Here, the bottom surface of the upper ball cup 42 and the upper surface of the lower ball cup 44 are formed with concave surfaces 42a and 44a on which the upper and lower surfaces of the ball 46 can be seated, respectively. 44a always return the position of the ball 46 to the center of the concave surfaces 42a and 44a.

Next, the features of the load cell according to the present invention will be described in detail with reference to FIGS. 3 to 5.

First, the load cell of the present invention is provided with an elastic support member 80 for elastically rotatable support of the wafer plate 50 to the metal elastic body 20.

The elastic support member 80 is made of a material capable of elastic deformation, for example, a rubber material, and has a tubular body 82.

The tubular body 82 is configured such that one side portion 84 is fitted around the upper ball cup 42 and fixed, and the other portion 85 is fixed to the metal elastic body 20.

In particular, the other side portion 85 is fastened to the circumferential portion of the lower ball cup 44 corresponding to the circumference of the upper ball cup 42 with a screw 85a. Here, the outer circumferential surface of the upper ball cup 42 is formed with a fixing groove 84a to which one side portion 84 of the tubular body 82 is fitted and fixed.

This tubular body 82, the one side 84 is fixed to the circumference of the upper ball cup 42, the other side 85 is fixed to the metal elastic body 20, so that the upper ball cup 42 is fixed The plate 50 serves to support the metal elastic body 20.

In particular, since the tubular body 82 is made of a material that can elastically deform, the weir plate 50 is elastically supported with respect to the metal elastic body 20. Therefore, the micro flow of the wafer plate 50 generated at the time of measuring the load of the object is allowed.

In addition, since the tubular body 82 is a material that can be quickly restored after elastic deformation, the tubular body 82 attenuates the microfluidic flow of the weir plate 50 generated during load measurement. Therefore, it serves to gently hold the micro flow of the wafer plate 50.

In particular, it smoothly catches the movement between the upper ball cup 42 and the lower ball cup 44 and the ball 46. Thus, the positions of the upper ball cup 42 and the lower ball cup 44 and the ball 46 can be quickly restored.

In addition, since the tubular body 82 supports the wafer plate 50 to the metal elastic body 20 and supports the elastic plate so as to be elastically movable, the tubular body 82 reduces the lateral force of the wafer plate 50 generated during load measurement. It also plays a role. And, after the lateral force is reduced, it also serves to quickly restore the wafer plate 50 to its original position.

In addition, the tubular body 82 attenuates the lateral force of the wafer plate 50 generated at the time of the load measurement, so that excessive lateral force is not applied to the wafer plate 50 at the time of the load measurement. Therefore, the detachment phenomenon of the waer plate 50 due to excessive lateral force is prevented at the source.

On the other hand, the tubular body 82 of such a configuration is preferably composed of nitrile butadiene rubber (NBR: hereinafter abbreviated as "NBR"). This is because, in the case of the NBR material, the tensile strength is very high, whereby the elastic bearing force of the weir plate 50 with respect to the metal elastic body 20 can be increased as much as possible.

As a result, even if excessive lateral force acts on the shore plate 50 at the time of load measurement, the detachment phenomenon of the shore plate 50 is fundamentally prevented.

3 to 5, the tubular body 82 further includes a pleat 86 formed between a portion 84 and the other portion 85.

The pleats 86 are formed along the circumferential circumference of the tubular body 82, and are configured to elastically deform as they are expanded or folded when an external force is applied to the tubular body 82.

Since the wrinkles 86 are elastically deformed while being stretched or folded when an external force is applied, the creases 86 increase the elastic strain of the tubular body 82 as much as possible. As a result, the microfluidic flow and the transverse load of the wafer plate 50 generated at the time of load measurement are efficiently attenuated.

According to this invention of such a structure, since the structure which supports the wafer plate 50 to the metal elastic body 20 can be prevented from being detached from the metal elastic body 20 at the source.

In particular, when the load is measured, the lateral force acts on the wafer plate 50 so that even if the wafer plate 50 flows excessively up, down, left, or right, it is possible to prevent the departure of the wafer plate 50 at its source. do.

In addition, the present invention, since the elastic support member 80 is a structure for supporting the weir plate 50 to the metal elastic body 20, to prevent excessive flow of the weir plate 50 without the flow preventing bolt and the flow preventing plate. can do.

Therefore, it is not necessary to provide the flow prevention bolt and the flow prevention plate, and do not need to install them. As a result, manufacturing cost can be reduced, assembly time can be shortened, and productivity can be improved.

In addition, since the present invention has a structure in which the wafer plate 50 is elastically supported by the metal elastic body 20, the up, down, left, and right flows of the wafer plate 50 generated at the time of load measurement are efficiently attenuated. You can.

Therefore, when measuring the load, it is possible to reduce the flow of the wafer plate 50 as much as possible, thereby enabling accurate load measurement.

In the above described a preferred embodiment of the present invention by way of example, the scope of the present invention is not limited only to this specific embodiment, it can be changed appropriately within the scope described in the utility model registration claims.

1 is a cross-sectional view showing the configuration of a conventional load cell;

2 is a cross-sectional view taken along the line II-II of FIG. 1 showing the structure of a conventional load cell;

3 is a cross-sectional view showing the configuration of a load cell according to the present invention,

4 is a cross-sectional view taken along the line IV-IV of FIG. 3;

FIG. 5 is an exploded perspective view illustrating a waer plate, an elastic support member, and a load support constituting the load cell of the present invention.

♣ Explanation of symbols for the main parts of the drawing ♣

10: base plate 20: metal elastic body

22: fixed part 24: extension part

30: strain gauge 40: load support

42: upper support 42a: upper concave surface

42b: Foreign Exchange Jaw 44: Lower Support

44a: lower concave surface 44b: extension tube

46: Ball 50: Weigher Plate

80: elastic support member 82: tubular body

84: one side 85: the other side

86: wrinkles

Claims (3)

A metal elastic body 20, a weight plate 40 for supporting an object, and a load support 40 for transmitting a load applied to the weight body 50 to the metal elastic body 20, wherein the load The support 40 is an upper ball cup 42 fixed to the waer plate 50, a lower ball cup 44 fixed to the metal elastic body 20, and the upper ball cup 42 and the lower ball cup 44. In a load cell composed of balls 46 disposed therebetween, Elastic support for elastically moving the supporter 50 to the metal elastic body 20 so as to limit and attenuate excessive flow of the Weier plate 50 generated when measuring the load of an object. Load cell further comprises a member (80). The method of claim 1, The elastic support member 80, It includes a tubular body 82, the tubular body 82, one side portion 84 is fitted and fixed around the upper ball cup 42, the other side 85 is the circumference of the upper ball cup 42 The load cell, characterized in that fixed to the portion of the metal elastic body 20 around the lower ball cup (44) corresponding to. 3. The method of claim 2, The tubular body (82), the load cell characterized in that it further comprises a pleat (86) to increase the elastic strain while being stretched or folded during elastic deformation.

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