KR102492673B1 - Jig for measuring compression force of hydraulic press - Google Patents

Abstract

A jig for measuring compression force of a hydraulic press is disclosed. The jig for measuring the compressive force of the hydraulic press is formed on a horizontal first load cell coupling surface having a first load cell insertion hole into which one end of the load cell is inserted and the back surface of the first load cell coupling surface, and the upper inner surface of the head of the press and the head A first jig body including a first jig rear surface coupled to or in close contact with any one of the inner surfaces of the ram facing the upper inner surface of the; And a second horizontal load cell coupling surface having a second load cell insertion hole into which the other end of the load cell is inserted and formed on the back surface of the second load cell coupling surface and facing the upper inner surface of the head of the compactor and the upper inner surface of the head A second jig body including a rear surface of a second jig that is coupled to or in close contact with the other one of the inner surfaces of the ram, and the first load cell insertion hole and the second load cell insertion hole allow the load cell to In a state coupled between the second jig bodies, the first load cell coupling surface and the second load cell coupling surface may have a depth set to be spaced apart from each other by a predetermined distance.

Description

Jig for measuring compression force of hydraulic press {JIG FOR MEASURING COMPRESSION FORCE OF HYDRAULIC PRESS}

The present invention relates to a jig for measuring the compressive force of a hydraulic press, and more particularly, to a jig for measuring the compressive force of a hydraulic press that is easy to carry and use.

The portable hydraulic press is used as a tool for connecting wires to wires by biting terminals on wires at places such as power plant construction sites.

The construction quality of the wire connection is related to the compression force of the hydraulic press. That is, when the hydraulic press in a state in which the compression force of the hydraulic press is reduced is used, the construction quality of the wire connection is lowered.

Therefore, in order to secure the construction quality of the wire connection, the performance of the hydraulic compactor is managed by periodically measuring the compression force of the hydraulic compactor.

The compression force measurement of the hydraulic press is performed by placing the load cell between the head and the ram of the hydraulic press and pressing the load cell between the head and the ram as the ram moves forward.

Conventionally, an analog measuring type load cell was used, and the load cell of the analog measuring type was placed between the head and the ram of a hydraulic press while the operator was holding the load cell with one hand, and then the load cell was pressed to measure the compressive force.

In this conventional compression force measurement process, since the operator must directly hold and position the load cell, it is difficult for the operator to measure the compression force alone, and the compression force measurement process is inconvenient and cumbersome.

Therefore, the problem to be solved by the present invention is that the process of locating the sensor for measuring the compression force of the hydraulic press between the head and the ram of the press and the process of measuring the compression force of the press is simple and quick, and a hydraulic press that makes it easy to carry and store It is to provide a jig for measuring compression force.

For another purpose, it is to provide a jig for measuring the compression force of a hydraulic press to protect a cable that transmits a measurement value of a sensor from problems such as disconnection.

A jig for measuring compression force of a hydraulic press according to an embodiment of the present invention is formed on a horizontal first load cell coupling surface having a first load cell insertion hole into which one end of the load cell is inserted and the back surface of the first load cell coupling surface, and A first jig body including a rear surface of a first jig coupled to or in close contact with either one of an upper inner surface of the head and an inner surface of the ram facing the upper inner surface of the head; And a second horizontal load cell coupling surface having a second load cell insertion hole into which the other end of the load cell is inserted and formed on the back surface of the second load cell coupling surface and facing the upper inner surface of the head of the compactor and the upper inner surface of the head A second jig body including a rear surface of a second jig that is coupled to or in close contact with the other one of the inner surfaces of the ram, and the first load cell insertion hole and the second load cell insertion hole allow the load cell to In a state coupled between the second jig bodies, the first load cell coupling surface and the second load cell coupling surface may have a depth set to be spaced apart from each other by a predetermined distance.

In one embodiment, the first jig body further includes a plurality of coupling guide rods protruding from the first load cell coupling surface, and the second jig body has a plurality of coupling guide grooves recessed in the second load cell coupling surface. Further comprising, when the coupling guide rod is coupled to the coupling guide groove, the first load cell coupling surface and the second load cell coupling surface are disposed to face each other, and the plurality of coupling guide rods are configured so that the load cell is connected to the first jig. An end of the coupling guide rod may have a length spaced apart from a bottom surface of the coupling guide groove in a state of being inserted between the body and the second jig body.

In one embodiment, each of the first jig rear part and the second jig rear part has an arc shape when viewed in cross section perpendicular to the longitudinal direction of the first jig body and the second jig body, and the arc shape It may include side surfaces extending from both sides and perpendicular to the first load cell coupling surface or the second load cell coupling surface.

In one embodiment, any one of the first jig rear surface and the second jig rear surface has a stepped portion forming a right angle to the side surface between the rear surface and the side surface, and the stepped portion arcs on the upper inner surface of the head of the compactor. It may be supported on both sides of the shape or steps protruding from both sides of the arc shape of the inner surface of the ram.

In one embodiment, the first jig rear part includes a first protrusion receiving groove formed along the circumference of the rear surface, and the second jig rear part includes a second protrusion receiving groove formed along the circumference of the rear surface, A first mounting protrusion protruding from an upper inner surface of the head of the compactor may be accommodated in the first protrusion receiving groove, and a second mounting protrusion protruding from an inner surface of the ram may be accommodated in the second protrusion receiving groove.

In one embodiment, a tube accommodating hole is provided on any one of the first load cell coupling surface and the second load cell coupling surface, and the jig for measuring the compressive force has one end inserted into the tube accommodating hole to be extended and connected to the load cell. It further includes a cable protection tube into which the cable is inserted and protected, wherein the cable protection tube has an annular ring larger than the diameter of the tube at one end, and the tube receiving hole is configured to accommodate the cable protection tube and the annular ring. It may be formed in a T-shape or a cross shape.

In one embodiment, band fastening grooves may be formed on both sides of the first jig body and the second jig body in the longitudinal direction, respectively.

The use of the jig for measuring the compression force of a hydraulic press according to the present invention simplifies the installation of the load cell between the head and the ram of the hydraulic press, and the process of measuring the compression force of the hydraulic press can be performed simply and quickly, and is easy to carry and store. In addition, there is an advantage in that the load cell cable can be protected from disconnection when measuring the compression force of the hydraulic press at a work site where the use of a hydraulic press is required.

1 is an exploded perspective view for explaining the configuration of a jig for measuring compression force of a hydraulic press according to an embodiment of the present invention.
FIG. 2 is an exploded perspective view illustrating a state in which a load cell is disposed between the first jig body and the second jig body shown in FIG. 1 .
3 is a view showing a state in which the load cell shown in FIG. 2 is accommodated between a first jig body and a second jig body.
FIG. 4 is a perspective view showing a state before a load cell is accommodated between the first jig body and the second jig body shown in FIG. 1 and mounted on a hydraulic press.
5 is a perspective view showing a state in which the first jig body and the second jig body accommodating the load cell shown in FIG. 4 are mounted on a hydraulic press.

Hereinafter, a jig for measuring compression force of a hydraulic press according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. Since the present invention can have various changes and various forms, specific embodiments will be illustrated in the drawings and described in detail in the text. However, it should be understood that this is not intended to limit the present invention to the specific disclosed form, and includes all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. Like reference numerals have been used for like elements throughout the description of each figure. In the accompanying drawings, the dimensions of the structures are shown enlarged than actual for clarity of the present invention.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. These terms are only used for the purpose of distinguishing one component from another. For example, a first element may be termed a second element, and similarly, a second element may be termed a first element, without departing from the scope of the present invention.

Terms used in this application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, terms such as "comprise" or "have" are intended to designate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more other features It should be understood that it does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in the present application, they should not be interpreted in an ideal or excessively formal meaning. don't

1 is an exploded perspective view for explaining the configuration of a jig for measuring compression force of a hydraulic press according to an embodiment of the present invention, and FIG. 2 is a load cell disposed between a first jig body and a second jig body shown in FIG. 1 FIG. 3 is a view showing the load cell shown in FIG. 2 accommodated between the first jig body and the second jig body, and FIG. 4 is the first jig body and the second jig body shown in FIG. 2 is a perspective view showing a state before a load cell is accommodated between jig bodies and mounted in a hydraulic press, and FIG. 5 is a perspective view showing a first jig body and a second jig body accommodating the load cell shown in FIG. It is a perspective view that represents

Referring to FIGS. 1 to 3 , a jig for measuring compression force of a hydraulic press according to an embodiment of the present invention includes a first jig body 110 and a second jig body 120 .

The first jig body 110 may include a first load cell coupling surface 111 and a first jig rear part 112 .

The first load cell coupling surface 111 is a horizontal surface, and a first load cell insertion hole 1111 is formed in the center. The first load cell insertion hole 1111 may accommodate one end of the load cell 200 for measuring the compression force of the hydraulic press.

The first jig rear part 112 may be formed on the back surface of the first load cell coupling surface 111 and coupled to the upper inner surface of the head 11 of the compactor 10. The first jig rear part 112 extends from the rear surface 1121 having an arc shape and both sides of the arc shape when viewed in a cross section perpendicular to the longitudinal direction of the first jig body 110, and the first load cell coupling surface 111 ) and a side 1122 forming a right angle.

In addition, a stepped portion 1123 forming a right angle to the side surface 1122 may be formed between the rear surface 1121 and the side surface 1122 of the first jig rear part 112 . The stepped portion 1123 may be supported on the stepped portion 11b protruding from both sides of an arc shape on the upper inner surface of the head 11 of the compactor 10.

The second jig body 120 may include a second load cell coupling surface 121 and a second jig rear part 122 .

The second load cell coupling surface 121 is a horizontal surface, and a second load cell insertion hole 1211 is formed in the center. The second load cell insertion hole 1211 may accommodate the other end of the load cell 200 .

The second jig rear part 122 is formed on the back surface of the second load cell coupling surface 121 and can be coupled to the inner surface of the ram 12 facing the upper inner surface of the head 11 of the compactor 10. When viewed in cross section perpendicular to the longitudinal direction of the second jig body 120, the rear surface of the second jig 122 has a rear surface 1221 having an arc shape and a side surface 1222 perpendicular to the second load cell coupling surface 121. ) may be included.

Here, the first load cell insertion hole 1111 and the second load cell insertion hole 1211 are a state in which the load cell 200 is coupled between the first jig body 110 and the second jig body 120 may have a depth set so that the first load cell coupling surface 111 and the second load cell coupling surface 121 can be spaced apart from each other by a predetermined distance. This is because the first jig body 110 and the second jig body 120 have the load cell 200 interposed therebetween, and the compressive force by the compactor 10 is applied to the first jig body 110 and the second jig body 120. in order to make it work.

Meanwhile, the first jig body 110 further includes a plurality of coupling guide rods 113, and the second jig body 120 includes a plurality of coupling guide grooves 123.

The plurality of coupling guide rods 113 protrude from the first load cell coupling surface 111 . At this time, the plurality of coupling guide rods 113 may be disposed on both sides of the first load cell insertion hole 1111.

The plurality of coupling guide grooves 123 are formed to be recessed in the second load cell coupling surface 121 . At this time, the plurality of coupling guide grooves 123 may be disposed on both sides of the second load cell coupling surface 121 .

When the plurality of coupling guide rods 113 are coupled to the plurality of coupling guide grooves 123 in a state where the load cell 200 is inserted between the first jig body 110 and the second jig body 120 The end may have a length spaced apart from the bottom surface of the coupling guide groove 123 .

Meanwhile, the first jig rear part 112 may include a first protrusion receiving groove 114 , and the second jig rear part 122 may include a second protrusion receiving groove 124 .

The first protrusion receiving groove 114 is formed along the arc-shaped circumference of the rear surface 1121 of the first jig rear surface 112, and the second protrusion receiving groove 124 is the rear surface of the second jig rear surface 122. It is formed along the arc-shaped circumference of (1221).

A first mounting protrusion 11a protruding from the upper inner surface of the head 11 of the compactor 10 is inserted into the first protrusion receiving groove 114, and the second protrusion receiving groove 124 has a ram 12 ) The second mounting protrusion 12a protruding from the inner surface is inserted. Accordingly, the first jig body 110 and the second jig body 120 do not deviate left and right from the inner surfaces of the head 11 and the ram 12 .

Although not specifically shown, when the first mounting protrusion 11a and the second mounting protrusion 12a are supported by a spring and pressed, they enter the inside of the head 11 and the ram 12 by contraction of the spring may be configured to be returned.

Meanwhile, first band fastening grooves 115 are formed on both sides of the first jig body 110 in the longitudinal direction, and second band fastening grooves 125 are formed on both sides of the second jig body 120 in the longitudinal direction. It can be.

In the first band fastening groove 115 and the second band fastening groove 125, the first jig body 110 and the second jig body 120 face each other with the load cell 200 therebetween, and rubber bands (20) can be concluded. At this time, the rubber band 20 may fix a state in which the first jig body 110 and the second jig body 120 face each other.

Hereinafter, a process of measuring the compressive force of the compactor 10 using the jig for measuring the compressive force of the hydraulic compactor according to an embodiment of the present invention will be described.

First, one end of the load cell 200 is inserted into the first load cell coupling surface 111 of the first jig body 110, and the other end of the load cell 200 is inserted into the second load cell coupling surface of the second jig body 120. Insert at (121). At this time, the plurality of coupling guide rods 113 of the first jig body 110 are inserted into the plurality of coupling guide grooves 123 of the second jig body 120, and the first load cell coupling surface 111 and the second load cell The mating surfaces 121 face each other. In this state, the first load cell insertion hole 1111 and the second load cell insertion hole 1211 are the load cell 200, as shown in FIGS. 3 and 4, the first jig body 110 and the second jig body ( 120), the first load cell coupling surface 111 and the second load cell coupling surface 121 have a depth set so that they can be spaced apart from each other in a state of being coupled between the first load cell coupling surface 111 and the second load cell coupling surface 111. 2 The load cell coupling surface 121 is spaced a certain distance apart.

In addition, the first band fastening groove formed on both sides of each of the first jig body 110 and the second jig body 120 in a state where the first jig body 110 and the second jig body 120 face each other ( 115) and the second band fastening groove 125, as shown in FIG. 4, rubber bands 20 are fastened to surround the circumferences of the first jig body 110 and the second jig body 120, and the rubber band 20 fixes the arrangement state of the first jig body 110 and the second jig body 120.

In this way, in a state where the first jig body 110, the load cell 200, and the second jig body 120 are coupled, the first jig rear part 112 of the first jig body 110 is attached to the head of the compactor 10 ( It is pushed toward the inner surface of the head 11 of the compactor 10 from the lateral direction of 11). At this time, the first mounting protrusion 11a protruding from the inner surface of the head 11 of the compactor 10 is pressed by the first jig body 110 and enters the inside of the head 11, then the rear surface of the first jig ( When the first protrusion receiving groove 114 of 112 faces the first mounting protrusion 11a, it protrudes again and is inserted into the first protrusion receiving groove 114. Accordingly, the first jig body 110, the load cell 200 coupled to the first jig body 110, and the second jig body 120 are mounted as shown in FIG. 5 so that their positions are fixed without being left or right. can

In this state, when the ram 12 of the compactor 10 is moved forward, the inner surface of the ram 12 is in close contact with the second jig rear part 122 of the second jig body 120, and then the second jig body 120 is removed. 1 is pushed toward the jig body 110 and pressurized, and at this time, a compressive force acts on the load cell 200 inserted between the first jig body 110 and the second jig body 120, so that the load cell 200 presses the compactor ( 10) to measure the compressive force.

The measured value of the compression force measured by the load cell 200 is output to a compression force measurement value display terminal (not shown) connected to the load cell 200 through a cable 201.

In the above description, it has been described that the first jig body 110 is coupled to the upper inner surface of the head 11 of the compactor 10 and mounted, but the first jig body 110 is coupled to the inner surface of the ram 12 and mounted You may. At this time, the stepped portion 1123 of the first jig rear surface 112 of the first jig body 110 is supported on the stepped portion 11b protruding from both sides of the arc shape of the inner surface of the ram 12 of the compactor 10 The first protrusion receiving groove 114 of the first jig body 110 can accommodate the second mounting protrusion 12a on the inner surface of the ram 12 .

On the other hand, the jig for measuring the compression force of the hydraulic press according to an embodiment of the present invention may further include a cable protection tube 130, the first load cell coupling surface 111 and the second load cell coupling surface 121 Any one of them may be provided with a tube receiving hole 116.

The cable protection tube 130 may protect the cable 201 by inserting the cable 201 connected to the load cell 200 . An annular ring 131 larger than the diameter of the tube may be provided at one end of the cable protection tube 130 .

One end of the cable protection tube 130, that is, one end where the annular ring 131 is located, is inserted into the tube receiving hole 116, and the other end can extend away from the tube receiving hole 116. .

The tube accommodating hole 116 may be formed in a T-shape or a cross shape to accommodate the cable protection tube 130 and the annular ring 131 . For example, the tube receiving hole 116 may be provided on the first load cell coupling surface 111 and may be formed in a cross shape extending from the first load cell insertion hole 1111. The annular ring 131 may be inserted into the horizontal axis of the cross shape, and one end of the cable protection tube 130 may be inserted into the vertical axis of the cross shape.

Using the jig for measuring the compressive force of the hydraulic compactor according to an embodiment of the present invention, the load cell 200 for measuring the compressive force of the compactor 10 is simply placed between the head 11 and the ram 12 of the compactor 10 , and due to the simple and quick installation of the load cell 200, the process of measuring the compression force of the hydraulic press 10 can be performed simply and quickly without any hassle.

In addition, after the load cell 200 is inserted between the first jig body 110 and the second jig body 120, the first band fastening grooves on both sides of the first jig body 110 and the second jig body 120 ( 115) and a state in which the load cell 200 is inserted into the first jig body 110 and the second jig body 120 by fastening the rubber band 20 to the second band fastening groove 125 and the first jig body ( 110) and the second jig body 120 can be simply installed on the head 11 or ram 12 of the compactor 10 by fixing the state in which they are disposed facing each other, and by storing the load cell 200 in this state The load cell 200 can be safely protected from external impact, etc., and it is easy to carry.

In addition, since the cable protection tube 130 is provided to protect the cable 201 of the load cell 200, the cable 201 of the load cell 200 is not easily disconnected when used at a work site where the hydraulic press 10 is used. can protect

The description of the presented embodiments is provided to enable any person skilled in the art to use or practice the present invention. Various modifications to these embodiments will be apparent to those skilled in the art, and the general principles defined herein may be applied to other embodiments without departing from the scope of the present invention. Thus, the present invention is not to be limited to the embodiments presented herein, but is to be construed in the widest scope consistent with the principles and novel features presented herein.

Claims (7)

A first horizontal load cell coupling surface 111 having a first load cell insertion hole 1111 into which one end of the load cell 200 is inserted and formed on the back surface of the first load cell coupling surface 111 and the head of the compactor 10 A first jig body 110 including a first jig rear part 112 coupled to or in close contact with any one of the upper inner surface of (11) and the inner surface of the ram 12 facing the upper inner surface of the head 11; and
A horizontal second load cell coupling surface 121 having a second load cell insertion hole 1211 into which the other end of the load cell 200 is inserted and formed on the back surface of the second load cell coupling surface 121, and the compactor 10 A second jig body 120 including a second jig rear part 122 coupled to or in close contact with the other of the upper inner surface of the head 11 and the inner surface of the ram 12 facing the upper inner surface of the head 11 ),
The first load cell insertion hole 1111 and the second load cell insertion hole 1211 are provided in a state where the load cell 200 is coupled between the first jig body 110 and the second jig body 120. Having a depth set so that the first load cell coupling surface 111 and the second load cell coupling surface 121 can be spaced apart by a predetermined distance,
A jig for measuring the compression force of a hydraulic press. According to claim 1,
The first jig body 110 further includes a plurality of coupling guide rods 113 protruding from the first load cell coupling surface 111,
The second jig body 120 further includes a plurality of coupling guide grooves 123 recessed in the second load cell coupling surface 121,
When the coupling guide rod 113 is coupled to the coupling guide groove 123, the first load cell coupling surface 111 and the second load cell coupling surface 121 are disposed to face each other,
The plurality of coupling guide rods 113 have the ends of the coupling guide rods 113 in a state where the load cell 200 is inserted between the first jig body 110 and the second jig body 120. Having a length that is spaced apart from the bottom surface of the coupling guide groove 123,
A jig for measuring the compression force of a hydraulic press. According to claim 2,
Each of the first jig rear part 112 and the second jig rear part 122,
When viewed in cross section perpendicular to the longitudinal direction of the first jig body 110 and the second jig body 120, the first load cell extends from both sides of the arc-shaped rear surfaces 1121 and 1221 and the arc-shaped Comprising side surfaces 1122 and 1222 perpendicular to the coupling surface 111 or the second load cell coupling surface 121,
A jig for measuring the compression force of a hydraulic press. According to claim 3,
In one of the first jig rear part 112 and the second jig rear part 122, a stepped part 1123 forming a right angle to the side surface 1122 is formed between the rear surface 1121 and the side surface 1122. become,
The stepped portion 1123 is supported on the step 11b protruding from both sides of the arc shape of the upper inner surface of the head 11 of the compactor 10 or from both sides of the arc shape of the inner surface of the ram 12,
A jig for measuring the compression force of a hydraulic press. According to claim 4,
The first jig rear part 112 includes a first protrusion receiving groove 114 formed along the circumference of the rear surface 1121,
The second jig rear part 122 includes a second protrusion receiving groove 124 formed along the circumference of the rear surface 1221,
The first protrusion receiving groove 114 accommodates a first mounting protrusion 11a protruding from the upper inner surface of the head 11 of the compactor 10,
In the second protrusion receiving groove 124, the second mounting protrusion 12a protruding from the inner surface of the ram 12 is accommodated.
A jig for measuring the compression force of a hydraulic press. According to claim 1,
One of the first load cell coupling surface 111 and the second load cell coupling surface 121 is provided with a tube receiving hole 116,
The jig for measuring the compressive force further includes a cable protection tube 130 having one end inserted into the tube receiving hole 116 and extending and protecting the cable 201 connected to the load cell 200 by being inserted therein,
The cable protection tube 130 is provided with an annular ring 131 larger than the diameter of the tube at one end,
The tube receiving hole 116 is formed in a T-shape or a cross shape to accommodate the cable protection tube 130 and the annular ring 131,
A jig for measuring the compression force of a hydraulic press. According to claim 6,
Band fastening grooves 115 and 125 are formed on both sides of the first jig body 110 and the second jig body 120 in the longitudinal direction, respectively.
A jig for measuring the compression force of a hydraulic press.

Images