KR101149432B1 - load cell unit of a weight-bridge - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a load cell unit of a mobile accumulator, wherein a coupling part is formed on a front and rear surface, a plurality of coupling grooves are formed along a bottom edge, and a first step portion and a second step portion are formed on an inner surface of the coupling groove. ; A pad coupled to the coupling part of the storage substrate to guide the vehicle; And a close contact with the first end of the storage substrate, a groove is formed at the center of the upper end, an inclined taper groove is formed at the bottom, a hemispherical interlocking ball is formed at the center of the taper groove, and a plurality of along the outer edges of the bottom surface. A load cell in which a flange hole is formed, and an interlocking groove for accommodating the interlocking balls of the load cell are formed at the center in a single-layered inclined top shape, and a stepped step is formed to prevent the interlocking ball from being separated as the interlocking groove flows. A foot having a bottom surface formed horizontally, and an accommodating space for accommodating the foot are formed, and a flat portion is formed at the end of the edge portion extending from the outer portion of the accommodating space to be in close contact with the second stepped portion of the storage substrate. Accordingly, it is composed of a loader cell assembly including a rubber holder of a rubber material in which a plurality of flange holes are formed in an annular shape.
In the load cell unit of the mobile accumulator according to the present invention, the rubber holder is not detached due to the loss of restoring force of the edge portion, and fine dust and rainwater do not flow between the flat portion of the rubber holder and the condensation substrate. No flow is generated and the rubber holder can be replaced quickly and easily.

Description

Load cell unit of mobile load balancer {load cell unit of a weight-bridge}

The present invention relates to a load cell unit of a mobile accumulator, and more particularly, a foot is inserted into and secured to a receiving space of a rubber holder, and a bolt having passed through the flat portion of the rubber holder has a second stepped portion and a flat portion of the condensation substrate. By tight fixing, the space between the load cell and the foot is related to the load cell unit of the mobile concentrator, which is covered from the outside by the rim.

In general, the accumulator is a device for protecting a bridge or detecting an overloaded vehicle, and measures the total load of the vehicle, measures the weight generated per side of the vehicle, prohibits entry into the bridge, and controls the amount of the load. Measurement instrument for

For example, the lower load cell, which is the most important element of the accumulator, measures the weight by the pressure that the load cell installed on the bottom of the accumulator is pressurized as the vehicle presses the accumulator and excludes the weight of the vehicle. Find out the weight of the item.

1 and 2 is an embodiment showing a load cell unit (Korean Patent No. 10-0625864, registered date: October 24, 2005) of a mobile load balancer for measuring the loading load of the vehicle, a weight lifter for measuring the weight of the vehicle ( 10) and a plurality of pads 81 for inducing the entry or passage of the vehicle to the front and rear of the accumulator 10 are coupled, and the load cell unit 100 in the unit insertion groove 17 of the bottom of the accumulator. Is inserted and coupled.

Therefore, when the vehicle enters the pad 81 and ascends directly above the condenser 10, the load cell unit 100 configured at the lower end of the condenser 10 measures the weight of the vehicle.

In this case, the pads 81 connecting the condenser 10 may be freely adjusted by extending the plurality of pads by inducing the movement of the vehicle.

The load cell unit 100 of the accumulator 10 which is operated in such a configuration and measures the weight of the vehicle is as follows.

Attached to the bottom surface of the accumulator 10, the groove 21 at the upper center and the tapered groove 22 tapered at the lower end, the hemispherical interlocking ball 23 protruding at the center of the tapered groove 22, and side edges The portion is provided with a flange portion 24 and a load cell 20 forming a stepped portion 25 which is chamfered to the outside of the flange portion 24.

In addition, a rubber material having a protrusion 32 of an edge portion 31 having an inner circumferential surface protruding from the stepped portion 25 of the load cell 20, and a receiving space 33 in which the load cell 20 is accommodated. Rubber holder 30 is provided.

In addition, the upper end of the tapered shape, the center is provided with an interlocking groove 41 formed so that the interlocking ball 23 of the load cell 20 is fitted, and a foot 40 having a horizontal base plate 42.

Therefore, the foot 40 is coupled to the rubber holder 30 in a state in which the interlocking ball 23 of the load cell 20 is accommodated in the interlocking groove 41 of the foot 40, and the rubber holder 30. The protrusion 32 of the edge portion 31 of the edge portion 31 is fitted to the stepped portion 25 of the load cell 20, thereby covering the space between the load cell 20 and the foot 40.

At this time, as the vehicle enters and presses the condenser 10, the load cell 20 is pressed and the interlocking ball 23 is rotated by the interlocking groove 41 of the foot 40, and the load cell 20 is pressed. At the same time as the edge portion 31 of the rubber holder 30 hanging on the stepped portion 25 is increased or decreased, the angle of the load cell 20 is corrected and foreign substances and rainwater are prevented from infiltrating the outside.

However, as the load cell 20 is rotated as described above, the structure of correcting the angle of the load cell 20 while repeatedly increasing or decreasing the edge 31 of the rubber holder 30 is the rubber holder ( 30, the restoring force of the edge portion 31 is lost, and the protrusion 32 of the edge portion 31 hanging on the stepped portion 25 of the load cell 20 is detached and detached, and the protrusion of the edge portion 31 tightly coupled. As fine dust and rainwater are sucked between the 32 and the stepped portion 25 of the load cell 20, the protrusion 32 hanging on the stepped portion 25 is released due to loss of adhesion, and the rubber holder (the moment the load is applied) is removed. Foot 40 coupled to 30 is not able to accurately measure the weight of the vehicle, and when replacing the rubber holder 30 damaged by the interference of external materials, the load cell 20 and the rubber holder 30 are deflated. 10) times that the rubber holder 30 needs to be replaced along the edge of the stepped portion 25 of the load cell 20 in the state of removal There are roum.

The present invention is to solve the above problems, an object of the present invention is to insert the foot into the receiving space of the rubber holder wrapped and secured, and pass the flange to the flat portion of the rubber holder to close the flat portion in the coupling groove of the shaft substrate By fixing, the rubber holder is not detached even when the restoring force of the edge portion is lost, and the load cell unit of the mobile accumulator is prevented from being sucked in between the storage substrate and the flat portion of the rubber holder.

In order to achieve the above object, the load cell unit of the mobile concentrator according to the present invention, the coupling portion is formed on the front and rear surfaces in the shape of a plate, a plurality of coupling grooves are formed along the bottom edge, the coupling groove inner surface A condensation substrate having a first step portion and a second step portion formed therein; And a close contact with the first end of the storage substrate, a groove is formed at the center of the upper end, an inclined taper groove is formed at the bottom, and a hemispherical interlocking ball is formed at the center of the taper groove, A load cell in which a plurality of flange holes are formed along an outer portion, and an interlocking groove for accommodating an interlocking ball of the load cell is formed at the center in a single-layered inclined top shape, and as the interlocking ball flows on the periphery of the interlocking groove. Stepped to prevent the separation is formed, the foot is formed so that the bottom is horizontal, and the receiving space is formed, the end of the edge portion extending from the outer space of the receiving space is formed of the storage substrate A flat portion is formed in close contact with the second stepped portion, and a plurality of flange holes are formed in an annular shape along the flat portion. Air load cell assembly including a rubber holder of a rubber material in; that is configured to be characterized.

The load cell unit of the mobile concentrator according to the present invention is characterized in that the rubber holder has a cover extending to cover the inclined monolayer of the foot in a state in which the foot is coupled to a receiving space to prevent the foot from flowing. do.

The load cell unit of the mobile load balancer according to the present invention is characterized in that the rubber holder has an annular protrusion formed on the top surface of the flat portion to increase the adhesion between the flat portion and the load storage substrate.

The load cell unit of the mobile concentrator according to the present invention is characterized in that the rubber holder further includes a rubber holder fixing plate for enhancing adhesion between the bolt inserted into the flange hole and the flat portion.

As described above, in the load cell unit of the mobile accumulator according to the present invention, even when the restoring force of the edge portion is lost, the rubber holder is not detached, and foreign substances and rainwater do not flow between the flat part of the rubber holder closely coupled to the condensation substrate, The foot is fixed to cover the cover of the rubber holder so that no flow occurs due to the load, and only the rubber holder can be disassembled or combined in the vertical direction while the load cell is fixed to the shaft plate to perform the replacement quickly and easily. There is an advantage.

1 is a bottom perspective view showing a state in which a load cell unit of a mobile concentrator according to the prior art is separated;
Figure 2 is an exploded perspective view of the load cell unit of the mobile concentrator according to the prior art.
Figure 3 is a side cross-sectional view of a load cell unit of a mobile concentrator according to the prior art.
Figure 4 is a perspective view showing a state in which the load cell assembly of the load cell unit of the mobile concentrator according to the present invention is separated.
Figure 5 is an exploded perspective view of the load cell assembly of the load cell unit of the mobile concentrator according to the present invention.
Figure 6 is a side cross-sectional view showing a state in which the load cell unit of the mobile concentrator according to the invention is operated.
Figure 7 is a perspective view showing a state in which the load cell assembly of the load cell unit of the mobile concentrator according to the present invention is used in combination.

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

Figure 4 is a bottom perspective view showing a state in which the load cell unit of the mobile concentrator according to the present invention is separated, Figure 5 is an exploded perspective view of the load cell unit of the mobile concentrator according to the present invention, Figure 6 is a state in which Figure 5 is used Figure 7 is a side cross-sectional view, Figure 7 is a perspective view showing a state in which the load cell unit of the mobile lifting device according to the invention is used in combination.

The condensation substrate 100 has a joining portion 101 formed on a front and back surface in a plate shape, and a plurality of joining grooves 102 are formed along a bottom edge thereof, and a first step portion is formed on the inner surface of the joining groove 102. 102a and the second stepped portion 102b are formed.

The accumulator substrate 100 is pressed downward by the weight of the vehicle entered into the upper surface.

The storage substrate 100 is provided with handles 104 at both sides to be easily gripped when carrying or moving.

The pad 200 is coupled to the coupling portion 101 of the storage substrate 100 to induce a vehicle to enter or pass through.

The pad 200 may be extended between the storage substrate 100 and the storage substrate 100 to form a passageway through which the vehicle moves.

The pad 200 is made of rubber to prevent flow when the vehicle moves.

The load cell assembly 300 includes a load cell 310, a foot 320, and a rubber holder 330.

The load cell 310 is tightly coupled to the first stepped portion 102a of the storage substrate 100, the groove 312 is formed at the center of the upper end, and the tapered groove 314 is formed at the lower end thereof. The hemispherical interlocking ball 316 is formed at the center of the tapered groove 314, and a plurality of flange holes 318 are formed along the outer portion of the bottom surface.

The load cell 310 passes through the bolt b through the flange hole 318 and is tightly coupled to the first stepped portion 102a in the coupling groove 102 of the storage substrate 100.

The load cell 310 detects the amount of deformation while being compressed by the shaft substrate 100 provided on the upper portion of the load cell 310 as an electrical signal and outputs it as a digital signal through a display device (not shown). Will be weighed.

The load cell 310 is tilted or rotated in a state where the hemispherical linking ball 316 is fitted into the linking groove 322 of the foot 320 and then returned to its original state.

The load cell 310 is prevented from contacting the foot 320 while the load cell 310 is inclined or rotated by the tapered groove 314 inclined at the bottom thereof.

The foot 320 has an interlocking groove 322 for accommodating the interlocking ball 316 of the load cell 310 at the center in a single-layered inclined top shape, and the interlocking ball at the periphery of the interlocking groove 322. Step 324 is formed to prevent the 316 is separated as it flows, the bottom surface is formed to be horizontal.

The foot 320 receives the linkage ball 316 of the load cell 310 in the linkage groove 322 to support the load cell 310 in a horizontal state while the load cell 310 is compressed, tilted or rotated. .

The rubber holder 330 is formed with a receiving space 332 for receiving the foot 320, the end of the edge portion 334 formed in the outer portion of the receiving space 332 of the storage substrate 100 A flat portion 336 is formed to be in close contact with the second stepped portion 102b, and a plurality of flange holes 337 are formed in a ring shape along the flat portion 336.

The rubber holder 330 includes the flat portion 336 at the end of the edge portion 334 at the second stepped portion 102b of the storage substrate 100 while the foot 320 is provided in the accommodation space 332. By tightly coupling to the bolt (b) to the space between the load cell 310 and the foot 320 is covered from the outside by the rubber holder 330 to prevent foreign substances and rainwater from flowing.

The rubber holder 330 corrects the angle at which the load cell 310 is inclined while the edge portion 334 is increased or decreased according to the inclination of the load cell 310.

The rubber holder 330 may be manufactured in a molding manner to be integrally formed with the foot 320.

The rubber holder 330 extends a cover 338 to cover the inclined monolayer of the foot 320 while the foot 320 is coupled to the receiving space 332 to prevent the foot 320 from flowing. Is formed.

The rubber holder 330 is formed with an annular protrusion 336a on the upper surface of the flat portion 336 to increase the adhesion between the flat portion 336 and the storage substrate 100.

The annular projection 336a is made of a rubber material, so that the annular protrusion 336a is tightly coupled to the second stepped portion 102b of the storage substrate 100 by a bolt b. Is pressed to increase the adhesion.

The rubber holder 330 further includes a rubber holder fixing plate 339 that enhances adhesion between the bolt b inserted into the flange hole 337 and the flat portion 336.

The rubber holder fixing plate 339 is provided between the bottom surface of the flat portion 336 of the rubber holder 330 and the bolt b to increase the adhesion by pressing the bottom surface of the flat portion 336.

The load cell unit of the mobile concentrator according to the present invention configured as described above is used as follows.

First, the pad 200 is coupled to the coupling portion 101 formed on the front and rear surfaces of the storage substrate 100, and the first stepped portion is formed in the plurality of coupling grooves 102 formed on the bottom surface of the storage substrate 100. The load cell 310 of the load cell assembly 300 is tightly coupled to the 102 by a bolt b passing through the flange hole 318, and the rubber having the foot 320 in the receiving space 332. The flat portion 336 of the holder 330 is in close contact with the second stepped portion 102b of the coupling groove 102 and is tightened by a bolt b passing through the flange hole 337 of the rubber holder 330. When the vehicle enters the top surface of the storage substrate 100 in a fixed state while the pad 200 of the storage substrate 100 is pressed, the storage cell 100 is pressed to press the load cell 310 to press the load cell. The deformation measurement apparatus (not shown) detects the amount of deformation of the 310 as an electric signal and outputs it as a digital signal through a display device (not shown). It is weighed. At this time, the flat portion 336 of the rubber holder 330 is coupled to the second stepped portion 102b of the coupling groove 102 and at the same time the foot provided in the receiving space 332 of the rubber holder 330 The interlocking ball 316 of the load cell 310 is fitted into the interlocking groove 322 of the 320 to be supported by the foot 320 while the load cell 310 is compressed.

In addition, an annular protrusion 336a is formed on an upper surface of the flat portion 336 of the rubber holder 330 so that the annular protrusion 336a is formed as the flat portion 336 is brought into close contact with the bolt b. The adhesiveness is increased between the flat part 336 of the rubber holder 330 and the second step part 102b of the storage substrate 100 by being pressed by the second step part 102b.

In addition, when the rubber holder fixing plate 339 is provided between the bolt b passing through the flange hole 337 and the bottom of the flat part 336 in the flat part 336 of the rubber holder 330. As the holder fixing plate 339 is tightened by the bolt b, the rubber holder fixing plate 339 is pressed against the bottom surface of the flat part 336 to completely block foreign substances and rainwater introduced from the outside. Can be.

In addition, the plurality of pads 200 may be extended to the coupling portion 101 of the storage substrate 100 so as to be spaced apart at predetermined intervals so that the storage substrate 100 may be simultaneously positioned on the front and rear wheels of the vehicle.

On the other hand, when the vehicle is inclined when the vehicle enters the upper surface of the shaft substrate 100, the shaft ball 100 is interlocked ball 316 of the load cell 310 fitted in the link groove 322 of the foot 320 As a reference, the load cell 310 is tilted.

At this time, the inclined angle a of the load cell 310 is corrected while the edge 334 of the rubber holder 330 is increased or decreased as the load cell 310 is inclined.

In addition, the edge portion 334 of the rubber holder 330 covers the space between the load cell 310 and the foot 320 from the outside to prevent foreign substances and rainwater from flowing in, thereby accurately weighing the weight of the vehicle. It can be measured.

In addition, since the flat portion 336 of the rubber holder 330 is tightly coupled to the second stepped portion 102b with a bolt b, there is no fear that the rubber holder 330 may be separated.

In addition, the rubber holder 330 may be manufactured in a molding manner to be integrally formed with the foot 320.

In addition, the rubber holder 330 prevents the foot 320 from flowing by extending the cover 338 to cover and fix the monolayer of the foot 320.

In addition, the load cell 310 is supported by the foot 320 when pressed, rotated or inclined.

Meanwhile, the foot 320 is horizontal with the ground in a state provided in the accommodation space 332 of the rubber holder 330.

In addition, the foot 320 prevents the interlocking ball 316 coupled to the interlocking groove 322 from being separated as the flow is generated as the load cell 310 is tilted or rotated at the edge of the interlocking groove 322. The step 324 is formed so that it may become.

In this way, the foot 320 supports the load cell 310 coupled to the coupling groove 102 of the storage substrate 100, and the foot 320 is provided in the accommodation space 332 of the rubber holder 330. In the state in which the flat portion 336 is tightly coupled to the second stepped portion 102b of the storage substrate 100 with the bolt b, the edge portion 334 of the rubber holder 330 is the load cell. Covering the space between the 310 and the foot 320 from the outside to prevent foreign substances and rain water is sucked in, the rubber holder 330 is tightly coupled to the storage substrate 100 with a bolt (b) There is no fear of departure, and when the rubber holder 330 can be replaced quickly and easily.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, It should be understood that all of the techniques that can be easily changed and used by those skilled in the art are included in the technical scope of the present invention.

100: storage shaft 101: coupling portion
102: coupling groove 102a: first stepped portion
102b: second step portion 104: the handle
200: pad 300: load cell assembly
310: load cell 312: home
314: tapered groove 316: interlocking ball
318,337: flange hole 320: foot
322: interlocking groove 324: step
330: rubber holder 332: accommodation space
334: edge portion 336: flat portion
336a: annular projection 338: cover
339: rubber holder fixing plate a: angle

Claims (4)

Coupling portion 101 is formed on the front and back surface in a plate shape, a plurality of coupling grooves 102 are formed along the bottom edge, the first step portion (102a) and the second to the inner surface of the coupling groove 102 A condensation substrate 100 having a stepped portion 102b formed therein; and
A pad 200 coupled to the coupling portion 101 of the storage substrate 100 to induce a vehicle to enter or pass through; And
Intimately coupled to the first stepped portion 102a of the storage substrate 100, a groove 312 is formed at the center of the upper end, and an inclined taper groove 314 is formed at the lower end thereof, and the tapered groove 314 is formed. A hemispherical interlocking ball 316 is formed at the center, a load cell 310 having a plurality of flange holes 318 formed along the outer edge of the bottom, and the load cell 310 at the center in a single-layered inclined shape. The interlocking groove 322 is received to accommodate the interlocking ball 316 of the), and the stepped 324 is formed on the edge of the interlocking groove 322 to prevent the interlocking ball 316 from being separated. The foot 320 is formed so that the bottom is horizontal, and an accommodation space 332 is formed to accommodate the foot 320, and an edge portion 334 extending from an outer portion of the accommodation space 332. Flat portion 336 that is in close contact with the second end portion 102b of the storage substrate 100 at the end of the And a load cell assembly 300 including a rubber holder 330 of a rubber material in which a plurality of flange holes 337 are formed in an annular shape along the flat portion 336. Load cell unit of a mobile condenser. The method of claim 1,
The rubber holder 330 extends a cover 338 to cover the inclined monolayer of the foot 320 while the foot 320 is coupled to the receiving space 332 to prevent the foot 320 from flowing. A load cell unit of a mobile accumulator, characterized in that it is formed. The method according to claim 1 or 2,
The rubber holder 330 has a load cell of a mobile accumulator, characterized in that an annular protrusion 336a is formed on an upper surface of the flat portion 336 to increase the adhesion between the flat portion 336 and the condensation substrate 100. Unit. The method according to claim 1 or 2,
The rubber holder 330 further includes a rubber holder fixing plate 339 which increases adhesion between the bolt b inserted into the flange hole 337 and the flat portion 336. Load cell unit.

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