KR20210017388A - Tension clamp apparatus - Google Patents

Abstract

Disclosed is a tension clamp device. The tension clamp device of the present invention comprises: a case having a cable leading-in unit and a guide unit formed to be converged to the cable leading-in unit; a pair of wedge units arranged in the guide unit and restricting a cable to prevent the cable from moving toward the cable leading-in unit; a slider unit which is combined with the pair of wedge units and is movably installed in the guide unit; and a push prevention unit arranged in the cable leading-in unit to allow the cable to pass therethrough and restricting the cable to prevent the cable from being pushed toward the wedge units in a state in which the cable is restricted by the wedge units. According to the present invention, a cable can be prevented from being pushed toward the wedge units.

Description

Tension clamp device {TENSION CLAMP APPARATUS}

The present invention relates to a tension clamp device, and more particularly, to a tension clamp device capable of preventing the cable from being pushed toward the wedge by a compressive force.

In general, a wedge-type tension clamp is a device for supporting a cable on a pole. In the wedge-type tension clamp, when the cable is subjected to a tensile force in one direction, a pair of wedges slide in the direction in which the tensile force acts and pressurize the cable to restrain it. Since the installation of the wedge-type tension clamp is completed only by inserting the cable between a pair of wedges, it has excellent workability. When the cable is under tension in one direction, the cable does not come out of the wedge-shaped tension clamp.

However, when the cable vibrates due to wind speed or the like, a compressive force may momentarily act on the cable in the reverse direction of the tensile force. When a compressive force acts on the cable, the pair of wedges moves in the opposite direction to the tensile force. Subsequently, when the wedge portion cannot be moved in the direction of the tension force when the tension force is applied to the cable again, the cable may escape from the wedge-type tension clamp, resulting in an accident.

Background art of the present invention is disclosed in Korean Patent Application Publication No. 2011-01257832 (published on November 22, 2011, title of the invention: wedge-type tension clamp insulation cover).

The present invention was created to improve the above problems, and an object of the present invention is to provide a tension clamp device capable of preventing a cable from being pushed into the wedge portion by a compressive force.

The tension clamp device according to the present invention includes: a case in which a cable entry portion and a guide portion are formed to converge toward the cable entry portion; A pair of wedge portions disposed on the guide portion and constraining the cable to prevent movement of the cable toward the cable entry portion; A slider portion coupled to the pair of wedge portions and movably installed on the guide portion; And a push prevention unit disposed at the cable entry portion so that the cable passes, and restraining the cable so as to prevent the cable from being pushed toward the wedge portion while the cable is constrained to the wedge portion.

The push prevention unit includes a pair of rotating shaft units installed on both sides of the cable entry unit; A pair of gear units fixed to each of the pair of rotation shaft units and installed in engagement with each other; And a pair of eccentric cam portions installed to restrain and release the cable on the pair of rotation shaft portions.

The gear part may be formed in a fan shape on the rotation shaft part.

The push prevention unit may further include a rotation elastic member that applies an elastic force to the rotation shaft portion so that the eccentric cam portion rotates in a direction that restricts the cable.

The rotational elastic member may be a torsion spring surrounding the rotational shaft and fixed to both sides of the rotational shaft and the case.

A pulley portion installed on the rotation shaft to rotate together with the rotation shaft portion; A pulley portion installed on the wedge portion so as to move together with the wedge portion; And a wire portion connected to the pulley portion so that both sides are fixed to the case and the pulley portion, and the eccentric cam portion rotates as the wedge portion is moved.

The pulley part may be disposed under the gear part.

A polygonal groove portion is formed in the rotational shaft portion, and a manipulation pin portion for rotating the rotational shaft portion while inserted into the polygonal groove portion may be further included.

The slider part includes a slide panel part to which a pair of the wedge parts are coupled; And a movable elastic member for elastically supporting the slide panel part so that the pair of the wedge parts move toward the cable entry part.

The movable elastic member may be a coil spring elastically supporting the slide panel.

At least one of the pair of wedge portions may be formed with a wedge ring portion protruding upward of the case.

According to the present invention, when a tensile force is applied to the cable, the wedge portion restrains the cable, and when a compressive force is applied to the cable, the push prevention portion restrains the cable. Accordingly, even if a tensile force and a compressive force are repeatedly applied to the cable by vibrating the cable, it is possible to prevent the cable from falling out of the case.

1 is a perspective view showing a tension clamp device according to an embodiment of the present invention.
2 is a plan view showing a tension clamp device according to an embodiment of the present invention.
3 is a perspective view showing a coupling structure of a wedge portion and a slider portion in a tension clamp device according to an embodiment of the present invention.
4 is a cross-sectional view showing a push prevention part in a tension clamp device according to an embodiment of the present invention.
5 is a cross-sectional view showing a push prevention part and a wedge part in a tension clamp device according to an embodiment of the present invention.
6 is a cross-sectional view showing a state in which a cable is constrained by a wedge when a tensile force is applied to the cable in the tension clamp device according to an embodiment of the present invention.
7 is a cross-sectional view showing a state in which the cable is constrained by the anti-pushing part when a compressive force is applied to the cable in the tension clamp device according to an embodiment of the present invention.

Hereinafter, an embodiment of a tension clamp device according to the present invention will be described with reference to the accompanying drawings. In the process of describing the tension clamp device, the thickness of the lines or the size of components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms to be described later are terms defined in consideration of functions in the present invention and may vary according to the intention or custom of users or operators. Therefore, definitions of these terms should be made based on the contents throughout the present specification.

1 is a perspective view showing a tension clamp device according to an embodiment of the present invention, Figure 2 is a plan view showing a tension clamp device according to an embodiment of the present invention, Figure 3 is an embodiment of the present invention A perspective view showing a coupling structure of a wedge part and a slider part in the tension clamp device according to the present invention, FIG. 4 is a cross-sectional view showing a slip prevention part in a tension clamp device according to an embodiment of the present invention, and FIG. 5 is an embodiment of the present invention. It is a cross-sectional view showing the push prevention part and the wedge part in the tension clamp device according to.

1 to 5, the tension clamp device 100 according to an embodiment of the present invention includes a case 110, a pair of wedges 120, a slider 130, and a slip prevention part 140 Includes.

The case 110 includes a cable entry portion 111 and a guide portion 113 to converge toward the cable entry portion 111. The width of the guide part 113 gradually decreases toward the cable entry part 111. An opening (not shown) is formed on the upper side of the case 110.

The cable entry part 111 is provided with a stopping part 112 to prevent the operation pin part 150 from being rotated by a certain angle or more. At this time, after the operation pin part 150 is rotated to completely open the eccentric cam part 144, the handle part 153 of the operation pin part 150 is pushed in and the operation pin part 150 rotates as it is caught by the stop part 112. This is prevented.

A pair of wedge portions 120 are disposed on the guide portion 113 and constrain the cable 10 to prevent the cable 10 from being moved toward the cable entry portion 111. The wedge portion 120 is disposed on both sides of the guide portion 113 in the width direction. Since the cable 10 is constrained to prevent the wedge part 120 from moving toward the cable entry part 111, the wedge part 120 presses the cable 10 while a tension force is applied to the cable 10. .

At least one of the pair of wedge portions 120 is formed with a wedge ring portion 122 protruding upward from the case 110. A hole portion (not shown) is formed in the wedge ring portion 122 so that a device can be inserted. Therefore, when the operator moves the wedge ring portion 122 using a mechanism (not shown), the wedge portion 120 may be moved in the case 110.

A cable restriction groove 124 is formed inside the wedge 120 in the width direction so that the cable 10 is inserted. The cable constraining groove 124 is disposed along the length direction of the wedge 120. A pair of locking protrusions 125 formed in the width direction of the wedge portion 120 is formed below the wedge portion 120.

The slider unit 130 is coupled to a pair of wedge portions 120 and is movably installed on the guide unit 113. As the slider unit 130 is moved from the guide unit 113, the pair of wedge units 120 are also moved together.

The slider unit 130 includes a slide panel unit 131 and a movable elastic member 135. A pair of wedge portions 120 are coupled to the slide panel portion 131. The movable elastic member 135 elastically supports the slide panel portion 131 so that the pair of wedge portions 120 are moved toward the cable entry portion 111. Since the movable elastic member 135 presses the slide panel portion 131 toward the cable entry portion 111, the slider portion 130 and a pair of wedge portions 120 are formed when an external force is not applied to the slider portion 130. It moves to the cable entry part 111 side. Thus, the cable 10 is constrained by a pair of wedge portions 120.

The slide panel part 131 is formed with a locking rib 132 so as to be caught in the locking protrusion 125 of the wedge part 120. Engaging protrusions 125 are disposed on both sides of the locking ribs 132. Accordingly, since the locking protrusion 125 of the wedge portion 120 is constrained by the locking rib 132 of the slide panel portion 131, the slide panel portion 131 can be moved together with the wedge portion 120.

The movable elastic member 135 may be a coil spring that presses the slide panel portion 131 toward the cable entry portion 111. The coil spring is accommodated in a groove (not shown) formed on the lower surface of the guide part 113 along the longitudinal direction of the guide part 113.

The push prevention unit 140 is disposed at the cable entry portion 111 so that the cable 10 passes, and the cable 10 prevents the cable from being pushed toward the wedge portion 120 while the cable is constrained by the wedge portion 120. ) Is bound. Therefore, when vibration occurs in the cable 10 due to wind, etc., even if a compressive force (in the opposite direction of the tensile force) acts on the cable 10, the wedge 120 is prevented from being pushed to the opposite side of the cable entry 111 can do. Furthermore, since the binding force of the wedge portion 120 is prevented from being reduced, the cable 10 can be prevented from being detached from the case 110 even if a compressive force acts on the cable 10.

The push prevention unit 140 includes a pair of rotation shaft portions 141, a pair of gear portions 143, and a pair of eccentric cam portions 144.

A pair of rotation shaft portions 141 are installed on both sides of the cable entry portion 111. The rotation shaft part 141 is rotatably inserted into the cable entry part 111.

A pair of gear units 143 are fixed to the pair of rotation shaft units 141, respectively, and are installed to mesh with each other. The gear part 143 is integrally formed with the rotation shaft part 141 to rotate together with the rotation shaft part 141. Since the gear units 143 are installed to mesh with each other, the pair of gear units 143 are rotated together.

The gear part 143 is formed in a fan shape on the rotation shaft part 141. Since the gear portion 143 is formed in a fan shape, the width of the case 110 can be relatively reduced compared to a structure in which the gear portion 143 is formed in a circular shape. Therefore, it is possible to reduce the weight of the tension clamp device 100.

A pair of eccentric cam portions 144 are installed to restrain and release the cable 10 on the pair of rotation shaft portions 141. The eccentric cam part 144 is integrally formed with the rotation shaft part 141 to rotate together with the rotation shaft part 141. The radius of the outer surface of the eccentric cam part 144 is formed to gradually increase from one side to the other side based on the center of the rotation shaft part 141. When the end radius of the eccentric cam portion 144 is positioned toward the center of the cable entry portion 111, the cable 10 may be inserted between the pair of eccentric cam portions 144. In addition, when the long radius of the eccentric cam portion 144 is positioned toward the center of the cable entry portion 111, the eccentric cam portion 144 is constrained while pressing the cable 10.

The push prevention unit 140 further includes a rotational elastic member 145 for applying an elastic force to the rotational shaft 141 so that the eccentric cam 144 rotates in a direction constraining the cable 10. The rotational elastic member 145 may be a torsion spring that surrounds the rotation shaft part 141 and is fixed to both sides of the rotation shaft part 141 and the case 110. Since the rotational elastic member 145 exerts an elastic force on the rotational shaft 141 so that the eccentric cam 144 rotates in the direction constraining the cable 10, the eccentric cam 144 is in a state in which the cable 10 is constrained. You can keep it going.

The push prevention part 140 further includes a pulley part 146, a pulley part 147, and a wire part 148.

The pulley part 146 is installed on the rotation shaft part 141 to rotate together with the rotation shaft part 141. The pulley part 146 is press-fit into the rotation shaft part 141 or integrally formed to rotate together with the rotation shaft part 141. The pulley part 146 is installed to be concentric with the rotation shaft part 141. As the pulley part 146 rotates, the rotation shaft part 141, the gear part 143, and the eccentric cam part 144 are simultaneously rotated.

The pulley portion 147 is installed on the wedge portion 120 to move together with the wedge portion 120. The pulley portion 147 is rotatably installed on the cable entry portion 111 of the wedge portion 120.

The wire part 148 is connected to the pulley part 147 so that both sides are fixed to the case 110 and the pulley part 146, and the eccentric cam part 144 rotates as the wedge part 120 is moved. As the wedge portion 120 is moved, the wire portion 148 is wound or released on the pulley portion 146.

The pulley part 146 is disposed under the gear part 143. At this time, the pulley portion 147 is installed at the same height or substantially the same as the pulley portion 146. Therefore, since the wire portion 148 is disposed under the cable 10, the wire portion 148 can be installed to avoid the installation section of the cable 10. Accordingly, it is possible to prevent the wire portion 148 from being damaged due to interference with the cable 10.

Polygonal grooves 142 are formed in the rotating shaft part 141. The tension clamp device 100 further includes an operation pin 150 for rotating the rotation shaft 141 in a state inserted into the polygonal groove 142. The manipulation pin 150 includes a handle portion 153, a polygonal wrench portion 152 extending from the handle portion 153, and a circular rod portion 151 extending from the wrench portion 152. When the handle portion 153 is rotated while the wrench portion 152 is inserted into the polygonal groove portion 142, the rotation shaft portion 141 is rotated. Accordingly, as the operation pin 150 is rotated, the rotational position of the eccentric cam 144 is adjusted to constrain or release the cable 10.

In addition, it is possible to prevent the operation pin unit 150 from rotating by pushing the operation pin unit 150 toward the circular rod unit 151 to the stop unit 112 installed in the cable entry unit 111 of the case 110.

The operation of the tension clamp device according to the present invention configured as described above will be described.

5 is a cross-sectional view showing a push prevention part and a wedge part in a tension clamp device according to an embodiment of the present invention, and FIG. 6 is a wedge of a cable when a tensile force is applied to the cable in the tension clamp device according to an embodiment of the present invention. It is a cross-sectional view showing a state constrained by a part, and FIG. 7 is a cross-sectional view illustrating a state in which a cable is constrained by a push prevention part when a compressive force is applied to a cable in a tension clamp device according to an embodiment of the present invention.

5 to 7, when inserting the cable 10 between a pair of wedge portions 120, one side after inserting the operation pin portion 150 into the polygonal groove portion 142 of the rotation shaft portion 141 When rotated to the rotation shaft portion 141 is rotated to one side. As the rotation shaft part 141 is rotated, the gear part 143 is engaged and rotated, and the eccentric cam part 144 is also rotated. At this time, the end radius of the eccentric cam portion 144 is moved toward the center of the case 110 to form a space through which the cable 10 can be inserted between the eccentric cam portions 144. In FIG. 5, L1 is the distance between the eccentric cam part 144 and the pulley part 147 in the state where the wedge part 120 is opened to insert the cable 10.

In addition, another method of inserting the cable 10 into the tension clamp device 100 is as follows. When the wedge portion 122 of the wedge portion 120 is moved to the opposite side of the cable entry portion 111, the wedge portion 120 due to the action of the wedge portion 120 and a groove (not shown) formed in the slider portion 130 ) Is fixed. At the same time, the wire portion 148 connected to the pulley portion 147 of the wedge portion 120 rotates the pulley portion 144 connected to the eccentric cam portion 144, and the eccentric cam portion 144 can insert the cable 10. It is opened so that the wedge portion 120 is also opened. When the cable 10 is inserted between the open wedge portions 120 and then the wedge ring portion 122 is pushed toward the cable entry portion 111 and moved, the wedge portion 120 compresses the cable 10.

On the other hand, according to the present invention, when the operator installs the cable 10 according to the existing working method, the slip prevention unit 140 operates at the same time. In addition, even if the wire part 148 is broken, the eccentric cam part 144 can be operated after inserting the wrench part 152 of the operation pin part 150 into the polygonal groove part 142 of the rotating shaft part 141. In addition, the amount of movement of the wedge portion 120 may be difficult to move the eccentric cam portion 144 sufficiently wide, but in the present invention, the pulley portion 147 is installed on the wedge portion 120, and the wire portion 148 is Since it is installed to be supported by the pulley part 147, the rotation amount of the pulley part 146 can be increased by about twice by using the principle of the pulley when the pulley part 146 rotates.

In addition, since the rotational elastic member 145 installed on the eccentric cam 144 always exerts an elastic force in the direction in which the eccentric cam 144 is locked, the operation pin 150 is used when opening the eccentric cam 144, but the eccentric When locking the cam portion 144, it is not necessary to deliberately rotate the eccentric cam portion 144 by using the operation pin portion 150.

When a tensile force (pressure in the direction of the arrow in Fig. 6) is applied to the cable 10, the wedge portion 120 is pulled toward the cable entry portion 111 by the tensile force of the cable 10. Constrain while pressing (10). Accordingly, when a tensile force is applied to the cable 10, the cable 10 is constrained by the wedge portion 120 to prevent the cable 10 from falling out of the case 110.

In addition, when a compressive force (pressure in the direction of the arrow in FIG. 7) is applied to the cable 10 by wind or the like, the cable 10 is further pressed by the long radius of the eccentric cam portion 144 of the push prevention portion 140. Accordingly, even if a compressive force is applied to the cable 10, the cable 10 is pressed by the eccentric cam 144 and is prevented from being pushed toward the wedge 120. Since the cable 10 is not pushed toward the wedge portion 120, the wedge portion 120 can also be prevented from being moved to the opposite side of the cable entry portion 111. Therefore, even if a tensile force is again applied to the cable 10 due to wind or the like, the cable 10 can be prevented from falling out of the case 110. In FIG. 7, L2 is a distance between the eccentric cam portion 144 and the pulley portion 147 in a state in which the cable 10 is fixed by closing the wedge portion 120 (L1>L2).

In this way, when a tensile force is applied to the cable 10, the wedge portion 120 restrains the cable 10, and when a compressive force is applied to the cable 10, the anti-slip portion 140 restrains the cable 10. Accordingly, even if the tensile force and the compressive force are repeatedly applied to the cable 10 by vibrating the cable 10, the cable 10 can be prevented from falling out of the case 110.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is only illustrative, and those of ordinary skill in the field to which the technology pertains, various modifications and other equivalent embodiments are possible. I will understand.

Therefore, the true technical protection scope of the present invention should be determined by the claims.

100: tension clamp device 110: case
111: cable entry part 113: guide part
120: wedge portion 122: wedge hook portion
124: cable restraint groove 125: locking projection
130: slider unit 131: slide panel unit
132: locking rib 135: movable elastic member
140: slip prevention part 141: rotation shaft part
142: polygonal groove 143: gear
144: eccentric cam portion 145: rotation elastic member
146: pulley part 147: pulley part
148: wire part 150: operation pin part
151: circular rod portion 152: wrench portion
153: handle
L1: Distance between the eccentric cam part and the pulley part with the wedge part open to insert the cable
L2: The distance between the eccentric cam part and the pulley part when the cable is fixed by closing the wedge part

Claims (11)

A case in which a cable entry portion and a guide portion are formed to converge toward the cable entry portion;
A pair of wedge portions disposed on the guide portion and constraining the cable to prevent movement of the cable toward the cable entry portion;
A slider portion coupled to the pair of wedge portions and movably installed on the guide portion; And
A tension clamping device comprising: a push prevention unit disposed at the cable entry portion so that the cable passes, and restraining the cable to prevent the cable from being pushed toward the wedge portion while the cable is constrained to the wedge portion.
The method of claim 1,
The push prevention unit,
A pair of rotating shaft portions installed on both sides of the cable entry portion;
A pair of gear units fixed to each of the pair of rotation shaft units and installed in engagement with each other; And
A tension clamp device comprising a pair of eccentric cam portions installed to restrain and release the cable on the pair of rotation shaft portions.
The method of claim 2,
The tension clamp device, characterized in that the gear portion is formed in a fan shape on the rotation shaft portion.
The method of claim 2,
The tension clamp device further comprises a rotation elastic member for applying an elastic force to the rotation shaft portion so that the push prevention portion rotates in a direction in which the eccentric cam portion restrains the cable.
The method of claim 4,
The rotational elastic member is a tension clamp device, characterized in that the torsion spring surrounding the rotational shaft portion and fixed to both sides of the rotational shaft portion and the case.
The method of claim 2,
The push prevention unit,
A pulley portion installed on the rotation shaft to rotate together with the rotation shaft portion;
A pulley portion installed on the wedge portion so as to move together with the wedge portion; And
Both sides are fixed to the case and the pulley, the tension clamp device further comprising a wire portion connected to the pulley portion so that the eccentric cam portion is rotated as the wedge portion is moved.
The method of claim 4,
The pulley portion tension clamp device, characterized in that disposed under the gear portion.
The method of claim 2,
A polygonal groove is formed in the rotation shaft part,
Tensile clamp device, characterized in that it further comprises a manipulation pin for rotating the rotation shaft in a state inserted into the polygonal groove.
The method of claim 1,
The slider part,
A slide panel portion to which a pair of the wedge portions are coupled; And
And a movable elastic member for elastically supporting the slide panel portion so that the pair of the wedge portions move toward the cable entry portion.
The method of claim 9,
The movable elastic member is a tension clamp device, characterized in that the coil spring elastically supporting the slide panel.
The method of claim 1,
A tension clamp device, characterized in that at least one of the pair of wedge portions is formed with a wedge ring portion protruding upward of the case.

Images