KR101983004B1 - Grounding resistance measuring apparatus - Google Patents

Abstract

An invention relating to a grounding resistance measuring apparatus is disclosed. The ground resistance measuring apparatus of the present invention comprises: a manipulating rod; A fixing bracket installed on the operating rod; A slide portion provided on the fixing bracket; A first clamp movably coupled to the slide portion and being pivoted about the slide portion after being moved from the fixed bracket to one side; And a second clamp which is rotatably coupled to the first clamp so as to catch the ground wire together with the first clamp.

Description

{GROUNDING RESISTANCE MEASURING APPARATUS}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a grounding resistance measuring apparatus, and more particularly, to a grounding resistance measuring apparatus capable of easily measuring a grounding resistance of a grounding line on the ground.

In general, grounding is classified according to its use field and purpose. These grounds include a security ground for the purpose of safety of persons or equipment, and a function ground for the purpose of stable operation or operation of the equipment or system.

So far, grounding has been mainly dealt with in the field of electricity and electric power in order to prevent damage to persons and facilities caused by transmission and distribution facilities and lightning.

However, the development of today's electric, electronic, communication and semiconductor technologies enables miniaturization and high integration of almost all facilities, and enables to provide all kinds of information including data, voice, and image by using a high-speed integrated information communication network , And also enables a highly information age in which all information can be shared via computers.

In the electric, electronic, and electric fields, it is required to prevent damage to persons and facilities due to lightning, and to provide efficient and stable operation and high reliability and good grounding.

The ground electrode is a terminal for constituting the ground by electrically connecting various electrical, electronic, and communication facilities to the ground. The electrical resistance that occurs between the ground electrode and the ground is the ground resistance. When a ground fault current or a noise current is generated, the ground potential of the ground electrode rises to cause various troubles in the system. It is ideal to have a ground resistance of zero ohms (zero ohms), but practically impossible, so it is necessary to configure the grounding system so that there is no obstacle to the equipment or equipment connected to the ground.

However, since the ground resistance may not be constant depending on the season due to the influence of temperature and humidity change in the ground, the ground resistance measurement is periodically measured during construction and during use in order to prevent electric shock and safety accidents due to electric leakage. By regularly measuring the ground resistance, the ground resistance can be maintained below the specified value specified in the Electricity Business Act.

In order to measure and manage the grounding resistance periodically at the current distribution line, it is inevitable to win the pole pole. It is a reality that it is difficult to utilize the manpower efficiently because only the engineer who has the qualification of distribution (live wire) can measure the grounding resistance of the machined wiring line, which increases the economic cost.

Therefore, there is a need to develop a non-conductive grounding resistance measuring device capable of preventing safety accidents by measuring the grounding resistance without standing on the pole of the working distribution line,

Background Art [0002] The background art of the present invention is disclosed in Korean Patent Laid-Open Publication No. 2005-0048407 (published on November 19, 2005, entitled Ground Resistance Measuring Apparatus).

SUMMARY OF THE INVENTION It is an object of the present invention to provide a grounding resistance measuring apparatus capable of easily measuring a grounding resistance of a grounding wire on the ground.

A grounding resistance measuring apparatus according to the present invention comprises: an operating rod; A fixing bracket installed on the operating rod; A slide unit installed on the fixing bracket; A first clamp movably coupled to the slide portion and being pivotally moved about the slide portion after being moved from the fixed bracket to one side; And a second clamp rotatably coupled to the first clamp so as to catch the ground wire together with the first clamp.

The first clamp may be inserted into the fixing bracket when the operating rod is pulled downward, and may be coupled to the slide portion so as to be drawn out from the fixing bracket and then pivoted when the operating rod is pushed upward.

The fixing bracket includes a bracket body coupled to the operating rod; And a guide unit for guiding the first clamp to be drawn out in a linear direction from the fixing bracket and releasing the constraint of the first clamp when the first clamp is pulled out so as to be pivoted after the first clamp is pulled out .

The guide portion includes a first guide rib formed opposite to an end of the first clamp; And a second guide rib facing the opposite side of the second clamp in the first clamp and supporting a side surface of the first clamp when the first clamp is pulled out.

Wherein the first clamp is formed with a slot so that the slide portion is slidably fitted in the first clamp and the first clamp is pulled out so that the slide portion is positioned on the end side of the slot, .

The sheet may be formed in parallel with the second guide rib.

The shortest distance between the second guide rib and the slide part may be shorter than the length of the long guide.

When the distance between the slide part and the end of the first clamp is shorter than the shortest distance between the slide part and the second guide rib when the first clamp is drawn out, the first clamp may be turned around the slide part have.

The second clamp may be formed with a mounting part protruding from the first clamp so that the ground wire is mounted.

Wherein the second clamp is rotatably installed on the first clamp by a hinge portion, the hinge portion is provided with an elastic member, and the elastic member is fixed to the first clamp by the second clamp so that the second clamp and the first clamp are gathered, As shown in Fig.

The first clamp includes a first clamp body on which the elongated body is formed; A first induced voltage generator installed in the first clamp body; And a first signal measurement unit installed on the first clamp body, the second clamp includes a second clamp body rotatably installed on the first clamp body; A second induced voltage generator installed in the second clamp body and grounded to the first induced voltage generator; And a second signal measuring unit installed on the second clamping body and grounded with the first signal measuring unit.

A first measurement groove is formed in the first clamp body and a second measurement groove is formed in the second clamp body so as to correspond to the first measurement groove, And the second induced voltage generating portion may be disposed at a peripheral portion of the second measurement groove portion.

The operation rod may include a plurality of unit operation rods assembled in the longitudinal direction.

Wherein the unit operating rod comprises: an insulating portion forming an outer tube; A joint portion connected to an end portion of the insulation portion and coupled to a neighboring unit operation rod; An input line disposed inside the insulation portion and connected to the first induced voltage generating portion and the second induced voltage generating portion; And an output line disposed inside the insulation portion and connected to the first signal measurement portion and the second signal measurement portion.

The input line and the output line may be arranged to face each other on the inner surface of the insulating portion.

The joint portion may be provided with a rotation preventing portion to prevent the insulating portion from rotating.

The ground resistance measuring device includes a battery disposed inside the operating rod and connected to the input line; And a circuit board disposed inside the operation rod and connected to the output line.

The battery and the circuit board may be installed in the uppermost unit operation rod.

And a ground resistance measuring unit connected to the operating rod.

The ground resistance measuring apparatus may further include a claw portion coupled to the fixing bracket and installed to pull the ground wire.

According to the present invention, when the operating rod is pulled downward, the ground wire is drawn between the first clamp and the second clamp. When the operating rod is pushed upward, the first clamp and the second clamp are pivoted from the fixed bracket, The ground wire is easily drawn out between the first clamp and the second clamp. Therefore, it is possible to easily measure the grounding resistance of the ground wire on the ground without an operator reaching the pole.

Further, according to the present invention, since the second clamp is rotatably coupled to the first clamp, the ground wire can be easily inserted between the first clamp and the second clamp as the second clamp spreads in the first clamp. Therefore, the operator can easily measure the grounding resistance of the ground wire.

According to the present invention, since the mounting portion of the second clamp is formed so as to protrude from the first clamp, the ground wire can be easily mounted to the mounting portion of the second clamp in a state in which the first clamp and the second clamp are gathered. Thus, the ground wire can be easily inserted between the first clamp and the second clamp.

Further, according to the present invention, since the wire or the ground wire can be pulled or repositioned using the claw portion, the first clamp and the second clamp can easily approach the ground wire.

1 is a perspective view showing a state in which a grounding resistance of a ground wire is measured using a ground resistance measuring apparatus according to an embodiment of the present invention.
2 is a perspective view illustrating a ground resistance measuring apparatus according to an embodiment of the present invention.
3 is a perspective view illustrating an installation structure of a first clamp and a second clamp in a ground resistance measuring apparatus according to an embodiment of the present invention.
4 is an exploded perspective view showing the installation structure of the first clamp and the second clamp in the ground resistance measuring apparatus according to the embodiment of the present invention.
5 is a plan view showing an installation structure of a first clamp and a second clamp in a ground resistance measuring apparatus according to an embodiment of the present invention.
6 is a plan view showing a state in which a first clamp and a second clamp are pulled out from a fixing bracket of a ground resistance measuring apparatus according to an embodiment of the present invention.
7 is a plan view showing a unit operation rod in the ground resistance measuring apparatus according to an embodiment of the present invention.
8 is a cross-sectional view illustrating the operation rod in the ground resistance measuring apparatus according to an embodiment of the present invention.
9 is a perspective view showing a ground resistance measuring unit in the ground resistance measuring apparatus according to an embodiment of the present invention.
10 is a perspective view illustrating a state in which a battery and a circuit board are installed in the uppermost unit operation rod in the ground resistance measuring apparatus according to an embodiment of the present invention.
11 is a perspective view illustrating a process of assembling a unit assembly rod in the ground resistance measuring apparatus according to an embodiment of the present invention.
12 is a diagram illustrating a process of measuring a grounding resistance of a ground line in the grounding resistance measuring apparatus according to an embodiment of the present invention.

Hereinafter, an embodiment of a ground resistance measuring apparatus according to the present invention will be described with reference to the accompanying drawings. In the course of describing the grounding resistance measuring apparatus, the thicknesses of the lines and the sizes of the constituent elements shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

FIG. 1 is a perspective view illustrating a state in which a grounding resistance of a grounding line is measured using an apparatus for measuring a grounding resistance according to an embodiment of the present invention, and FIG. 2 illustrates a grounding resistance measuring apparatus according to an embodiment of the present invention FIG. 3 is a perspective view illustrating an installation structure of a first clamp and a second clamp in the ground resistance measuring apparatus according to an embodiment of the present invention. FIG. 4 is a perspective view of a ground resistance measuring apparatus according to an embodiment of the present invention. FIG. 5 is a plan view showing an installation structure of a first clamp and a second clamp in a ground resistance measuring apparatus according to an embodiment of the present invention, and FIG. 5 is a plan view showing an installation structure of a first clamp and a second clamp, 6 is a plan view showing a state in which a first clamp and a second clamp are pulled out from a fixing bracket of a ground resistance measuring apparatus according to an embodiment of the present invention.

1 to 6, an apparatus for measuring a grounding resistance according to an exemplary embodiment of the present invention includes a control rod 110, a fixing bracket 120, a slide portion 130, a first clamp 140, (150).

The operating rod 110 is formed in the form of a cylindrical tube or a polygonal tube. The operating rod 110 is formed long so that the operator can approach the grounding wire 10 by using the operating rod 110 on the ground without having to rise on the pole. Since the operating rod 110 is formed in the shape of an empty tube, the grounding resistance measuring device can be easily lifted by reducing the weight of the operating rod 110. The operating rod 110 will be described in detail below.

The fixing bracket 120 is installed in the operating rod 110. The stationary bracket 120 includes a bracket body 121 and a guide portion 125. The bracket body 121 is engaged with the operating rod 110.

The bracket body 121 includes an extension connector portion 122 extending from the bracket body 121. [ The extension connector portion 122 of the bracket body 121 is engaged with the engagement connector portion 123 which is connected to the uppermost unit operation rod 110a of the operation rod 110. [ At this time, a coupling protrusion 122a is formed in the joint joint part 112, and a coupling groove 123a is formed in the coupling connector 123 so that the coupling protrusion 122a is inserted. Further, a coupling groove portion may be formed in the joint joint portion 112, and a coupling protrusion may be formed in the coupling connector portion 123.

The guide portion 125 guides the first clamp 140 in a linear direction and when the first clamp 140 is pulled out so that the first clamp 140 is pulled out after the first clamp 140 is pulled out, Lt; / RTI > The guide part 125 may be formed in various shapes as long as it is formed to move and rotate the first clamp 140. Examples of the guide portion 125 will be described below.

An example of the guide portion 125 is as follows. The guide part 125 includes a first guide rib 125a and a second guide rib 125b. The first guide ribs 125a and the second guide ribs 125b protrude along the circumference of the bracket body 121. The first guide rib 125a is formed to face one end of the first clamp 140. The second guide rib 125b is opposed to the opposite side of the second clamp 150 in the first clamp 140 and supports the side surface of the first clamp 140 when the first clamp 140 is pulled out. The first guide rib 125a and the second guide rib 125b are connected to each other and arranged in a substantially " a " form.

When the first clamp 140 is pulled into the fixing bracket 120, the end of the first clamp 140 is supported by the first guide rib 125a. The first guide rib 125a limits the pulling range of the first clamp 140 so that the first clamp 140 is no longer extended.

Since the second guide rib 125b supports the side surface of the first clamp 140, when the first clamp 140 is pulled out, the side surface of the first clamp 140 is supported by the second guide rib 125b The first clamp 140 can be prevented from turning. When the first clamp 140 is completely drawn out so that the end of the first clamp 140 corresponds to the end of the second guide rib 125b, the first clamp 140 rotates about the slide portion 130 . Since the inlet 154 between the first clamp 140 and the second clamp 150 is directed upward as the first clamp 140 is pivoted about the slide portion 130, The ground wire 10 can be pulled out as the first clamp 140 and the second clamp 150 expand.

Another example of the guide portion 125 will be described. A guide protrusion (not shown) may be formed on the lower side of the first clamp 140 and a guide groove (not shown) may be formed in a straight line so that the guide protrusion can be movably coupled to the fixing bracket 120. At this time, in a state where the guide protrusion of the first clamp 140 is inserted into the guide groove of the fixing bracket 120, the first clamp 140 can not be rotated around the slide portion 130. In addition, when the guide protrusion is completely disengaged from the guide groove when the first clamp 140 is pulled out, the first clamp 140 can be pivoted about the slide portion 130.

In addition, a straight guide groove portion may be formed below the first clamp 140, and a guide protrusion may be formed on the fixing bracket 120. The guide portion 125 may be formed in various shapes as long as the first clamp 140 is rotated after being moved a predetermined distance from the fixing bracket 120.

The first clamp 140 is formed with a slot 142 so that the slide unit 130 slidably fits and the first clamp 140 is positioned such that the slide unit 130 is positioned on the end side of the slot 142. [ The first clamp 140 is pivoted about the slide part 130. The long sheet 142 is formed long along the longitudinal direction of the first clamp 140. The slide portion 130 is moved relative to the first clamp 140 along the elongated portion 142 when the first clamp 140 is moved. The sheet slot 142 guides the first clamp 140 to move along a straight line, and limits the moving distance of the first clamp 140.

The long sheet 142 is formed in parallel with the second guide rib 125b of the guide portion 125. [ Since the long shelf 142 is formed in parallel to the second guide rib 125b, the first clamp 140 can be moved linearly by the guide of the second guide rib 125b.

The shortest distance L1 between the second guide rib 125b and the slide part 130 is shorter than the length of the slot 142. [ The distance L2 between the slide part 130 and the end of the first clamp 140 is smaller than the shortest distance between the second guide rib 125b and the slide part 130 when the first clamp 140 is pulled out The first clamp 140 is moved in a straight line until immediately before it becomes equal to the first clamp 140. [ If the distance L2 between the slide part 130 and the end of the first clamp 140 is equal to or shorter than the shortest distance L1 between the second guide rib 125b and the slide part 130, The first clamp 140 can be pivoted about the slide portion 130. [

The slide part 130 is installed in the stationary bracket 120. The slide part 130 may be a slide pin inserted into the slot 142 of the fixing bracket 120. When the first clamp 140 is formed with a straight long groove portion (not shown), the slide portion 130 may be a slide pin inserted into the long groove portion formed along the longitudinal direction of the fixing bracket 120 have. The head portion 133 may be formed at the end of the slide portion 130 so as not to be pulled out from the elongated portion 142 or the long groove portion. The diameter of the head portion 133 is formed to be larger than the diameter of the slide portion 130.

The first clamp 140 is movably coupled to the slide part 130 and is pivoted about the slide part 130 after being moved from the fixed bracket 120 to one side. The first clamp 140 is moved in a straight line from the fixing bracket 120 when the operating rod 110 is pulled downward, but is prevented from turning, so that when the operating rod 110 is pushed upward, the first clamp 140 is pulled out of the fixing bracket 120 And is then turned in a linear direction.

Accordingly, when the operating rod 110 is pulled downward, the ground wire 10 is drawn between the first clamp 140 and the second clamp 150. When the operating rod 110 is pushed upward, the first clamp 140 And the second clamp 150 are pivoted in the fixing bracket 120, the inlet 154 of the first clamp 140 and the second clamp 150 faces upward. At this time, if the operating rod 110 is pulled back downward, the ground wire 10 is easily drawn out between the first clamp 140 and the second clamp 150. Therefore, it is possible to easily measure the grounding resistance of the grounding wire 10 on the ground without an operator reaching the pole.

The second clamp 150 is rotatably coupled to the first clamp 140 so as to catch the ground wire 10 together with the first clamp 140. The second clamp 150 is rotatably coupled to the first clamp 140 so that the first clamp 140 and the second clamp 150 are moved in a direction in which the second clamp 150 is extended from the first clamp 140. [ The ground wire 10 can be easily inserted. When the operating rod 110 is pushed upward, the second clamp 150 is rotated while being rotated by the first clamp 140, so that the ground wire 10 is held between the first clamp 140 and the second clamp 150 Lt; / RTI >

The second clamp 150 is formed with a mounting portion 152 protruded from the first clamp 140 so that the ground wire 10 is mounted. One side of the mounting part 152 is formed to be rounded so that the grounding wire 10 is slidably inserted between the first clamp 140 and the second clamp 150. Since the mounting portion 152 of the second clamp 150 protrudes from the end of the first clamp 140 on the inlet 154 side, The ground wire 10 can be mounted on the mounting portion 152 of the second clamp 150 in a state in which the ground wire 154 is closed.

The second clamp 150 is rotatably installed in the first clamp 140 by the hinge 157. The hinge 157 is provided with an elastic member 158 and the elastic member 158 is connected to the second And is provided to apply an elastic force to the second clamp 150 so that the clamp 150 and the first clamp 140 are gathered. Therefore, if an external force is not applied to the second clamp 150, the second clamp 150 and the first clamp 140 are gathered together by the elastic force of the elastic member 158. Further, when an external force is applied to the second clamp 150, the second clamp 150 is rotated so as to be opened with the first clamp 140.

The first clamp 140 includes a first clamp body 141 on which the elongated body 142 is formed, a first induced voltage generator 145 provided on the first clamp body 141, And a first signal measurement unit 146 installed in the first signal measurement unit 141. The second clamp 150 includes a second clamp body 151 rotatably mounted on the first clamp body 141 and a second clamp body 151 provided on the second clamp body 151 and connected to the first induction voltage generator 145 And a second signal measurement unit 156 provided on the second clamp body 151 and grounded to the first signal measurement unit 146. The second signal measurement unit 156 is connected to the second signal measurement unit 146,

A first measurement groove 143 is formed in the first clamp body 141 and a second measurement groove 153 is formed in the second clamp body 151 to correspond to the first measurement groove 143 The first induced voltage generating unit 145 is disposed at the periphery of the first measurement trench 143 and the second induced voltage generating unit 155 is disposed at the periphery of the second measurement trench 153. The inner diameters of the first measurement trench 143 and the second measurement trench 153 are 25 mm or more.

Power is supplied to the first induced voltage generating unit 145 and the second induced voltage generating unit 155. An induced voltage is applied to the periphery of the ground line 10 between the first clamp body 141 and the second clamp body 151 as the first induced voltage generating unit 145 and the second induced voltage generating unit 155 are grounded . The first signal measuring unit 146 and the second signal measuring unit 156 can measure the grounding resistance from the grounding line 10 as the induced current is generated by the grounding resistance of the grounding line 10.

The fixing bracket 120 is provided with a pawl portion 160 for pulling the wire or the ground wire 10 around the ground wire 10. The claw portion 160 includes a hook body 161 coupled to the fixing bracket 120 and a hook portion 163 extending from the hook body 161 to the opposite side of the first clamp 140 and the second clamp 150, . The hook portion 163 is formed to be pointed so as to be accessible with a narrow clearance. The first clamp 140 and the second clamp 150 can be easily moved to the ground wire 10 because the wire (not shown) or the ground wire 10 can be pulled or repositioned using the claw portion 160 can do.

FIG. 7 is a plan view showing a unit operation rod in the ground resistance measuring apparatus according to an embodiment of the present invention, FIG. 8 is a sectional view showing the operation rod in the ground resistance measuring apparatus according to an embodiment of the present invention, 9 is a perspective view illustrating a grounding resistance measuring unit in a grounding resistance measuring apparatus according to an embodiment of the present invention, FIG. 10 is a perspective view illustrating a grounding resistance measuring apparatus according to an embodiment of the present invention, Fig.

7 to 10, the operating rod 110 is installed to be adjustable in length. For example, the operating rod 110 includes a plurality of unit operating rods 110a assembled in the longitudinal direction. It is possible to assemble an appropriate number of unit operation rods 110a according to the height of the grounding line 10 so that it is possible to easily measure the grounding resistance of the grounding line 10 positioned at various heights without an operator standing.

The unit operation rod 110a includes an insulating portion 111, a joint portion 112, an input line 115, and an output line 116. [

The insulating portion 111 forms an outer appearance of the unit operation rod 110a. The insulating portion 111 may be formed in the form of a circular pipe or a polygonal pipe.

The end of the insulating portion 111 is connected to the joint portion 112, and the neighboring unit operation rods 110a are coupled. Since the unit operation rod 110a is coupled to the joint portion 112, the length of the operation rod 110 can be adjusted by assembling a plurality of unit operation rods 110a.

The joint portion 112 is formed with a rotation preventing portion 113 to prevent the insulating portion 111 from rotating. The rotation preventing portion 113 may be a polygonal structure or an engaging portion formed on the inner surface of the joint portion 112. The joint portions 112 are provided with the rotation preventing portions 113 so that the input lines 115 or the output lines 116 can be connected to each other when the unit operation rods 110a are assembled. It is also possible to prevent the input line 115 and the output line 116 from being grounded.

The input line 115 is disposed inside the insulating portion 111 and connected to the first induced voltage generating portion 145 and the second induced voltage generating portion 155. The input line 115 is a power supply line, and supplies power to the first induced voltage generating unit 145 and the second induced voltage generating unit 155. The input line 115 includes a positive line to which positive power is input, a negative line to which negative power is input, and a neutral line to form a ground line.

The output line 116 is disposed inside the insulating portion 111 and is connected to the first signal measuring portion 146 and the second signal measuring portion 156. The output line 116 is a signal line that transmits a signal related to the ground resistance measured by the first signal measurement unit 146 and the second signal measurement unit 156. The input line 115 and the output line 116 are electrically insulated by the inner insulator 117.

The first clamp 140 and the uppermost unit operating rod 110a are connected by a cable 147 and the cable 147 is provided with an input line 115 and an output line 116. The input line 115 of the cable 147 is connected to the first induced voltage generating unit 145 and the second induced voltage generating unit 155. The output line 116 of the cable 147 is also connected to the first signal measurement unit 146 and the second signal measurement unit 156.

At this time, an inner insulator 117 is stacked on the inner surface of the insulating portion 111, and an input line 115 and an output line 116 are stacked on the inner insulator 117. The protective film 118 may be laminated so that the outside of the input line 115 and the output line 116 are also protected by moisture or foreign matter. The insulating portion 111 may be made of a reinforced plastic (FRP) material. The inner insulator 117 may be formed of Teflon, an epoxy material, or the like.

The input line 115 and the output line 116 are arranged to face each other on the inner surface of the insulating portion 111. Since the input line 115 and the output line 116 are disposed opposite to each other, it is possible to prevent the input line 115 and the output line 116 from being grounded when assembling a plurality of unit operation rods 110a.

The grounding resistance measuring apparatus includes a battery 171 disposed inside the operating rod 110 and connected to the input line 115, a circuit 171 disposed inside the operating rod 110, connected to the output line 116, And further includes a substrate 175. The battery 171 is connected to the input line 115 so that the power of the battery 171 is supplied to the first induced voltage generating unit 145 and the second induced voltage generating unit 155 through the input line 115 . A switch unit (not shown) is provided on the circuit board 175 to supply and cut off the power of the battery 171. Since the circuit board 175 is connected to the output line 116, signals related to the ground resistance measured by the first signal measuring unit 146 and the second signal measuring unit 156 are transmitted to the circuit board 175 .

In addition, the battery 171 and the circuit board 175 may be installed in the uppermost unit operation rod 110a. In this case, it is not necessary to provide the input line 115 and the output line 116 in the unit operation rods 110a other than the uppermost unit operation rods 110a. Therefore, it is not necessary to pay attention to connect the input line 115 and the output line 116 when assembling the unit operation rod 110a, and the risk that the input line 115 and the output line 116 are grounded from each other Can be blocked.

When the circuit board 175 is mounted on the uppermost unit operation rod 110a, the circuit board 175 is provided with a transmission / reception unit (not shown) for transmitting a signal relating to the received ground resistance to the ground resistance measurement unit 180 Can be installed.

The grounding resistance measuring apparatus further includes a grounding resistance measuring unit (180) connected to the operating rod (110). The grounding resistance measuring unit 180 includes a measuring unit body 181 and a holder unit 182 extending to the measuring unit body 181 and coupled to the operating rod 110. The holder 182 is formed in an arc shape having one side opened so that the operating rod 110 is fitted.

The display unit 183 may be provided in the measurement unit body 181 to notify the measured ground resistance. A menu key 184 is provided in the measurement unit body 181 so as to input a menu of the grounding resistance measurement device and a power button 185 may be provided to turn on / off the power of the measurement unit . The measurement unit body 181 may be provided with a navigation button 186 for selecting the position of the pole. In the measurement unit body 181, a communication unit 187 capable of transmitting the electric pole and the measured grounding resistance to a remote server (not shown) through wireless communication may be installed.

Operation of the apparatus for measuring a grounding resistance according to an embodiment of the present invention will be described.

FIG. 11 is a perspective view illustrating a process of assembling a unit assembly rod in an apparatus for measuring a ground resistance according to an embodiment of the present invention. FIG. 12 is a view illustrating a ground resistance of a ground wire in the apparatus for measuring a ground resistance according to an exemplary embodiment of the present invention FIG.

11 and 12, an appropriate number of unit operation rods 110a are assembled according to the height of the ground wire 10 to adjust the length of the operation rods 110. As shown in FIG. When the operation rod 110 is assembled to an appropriate length, the ground wire 10 is set up and then the ground wire 10 is pulled by using the claw portion 160 or wires around the ground wire 10 are arranged.

The operating rod 110 is moved so that the first clamp 140 and the second clamp 150 approach the ground wire 10. When the mounting portion 152 of the second clamp is caught by the ground wire 10, the operating rod 110 is pulled downward. At this time, as the second clamp 150 is rotated about the hinge portion 157, the second clamp 150 is opened at the first clamp 140.

When the second clamp 150 is moved upward while being opened in the first clamp 140, the mounting portion 152 of the second clamp 150 is arranged to be inclined upward. At this time, the ground wire 10 slides along the side surface of the mounting part 152 and is inserted between the first clamp 140 and the second clamp 150.

When the ground wire 10 is positioned between the first measurement groove 143 of the first clamp 140 and the second measurement groove 153 of the second clamp 150, The pressure of the ground wire 10 becomes weak. The second clamp 150 is rotated toward the first clamp 140 by the elastic force of the elastic member 158 to close the inlet 154 between the first clamp 140 and the second clamp 150. [

When a voltage is applied to the first induced voltage generating unit 145 and the second induced voltage generating unit 155 through the input line 115, the first induced voltage generating unit 145 and the second induced voltage generating unit 155 The induced voltage is induced in the ground line 10 according to the turns ratio of the ground wire 10. Current flows to the ground line 10 by the individual ground resistance Rx of the ground line 10. [ Therefore, the individual ground resistances can be obtained by the relational expression Rx = V / I.

 The first signal measuring unit 146 and the second signal measuring unit 156 measure the grounding resistance of the grounding line 10 and the signal of the measured grounding resistance is output to the grounding resistance measuring unit (180). The measured ground resistance value is displayed on the display unit 183 of the grounding resistance measuring unit 180. Also, the grounding resistance measuring unit 180 can transmit a signal relating to the grounding resistance of the grounding wire 10 to a remote server.

When the grounding resistance measurement of the grounding wire 10 is completed, the operator pushes the operating rod 110 upward. Since the first clamp 140 and the second clamp 150 are closed with the inlet 154 by the elastic member 158, the first clamp 140 and the second clamp 150 simultaneously move downward .

At this time, the slide part 130 passes through the slot 142 of the first clamp 140, and the side surface of the first clamp 140 is supported by the guide part 125 of the fixing bracket 120. The first clamp 140 is moved downward along the rectilinear direction at the fixing bracket 120 because the slide portion 130 is slid along the elongated portion 142. [

The distance L2 between the slide part 130 and the end of the first clamp 140 at the time of pulling out the first clamp 140 is the shortest distance L1 between the second guide rib 125b and the slide part 130, The first clamp 140 is moved in a straight line until just before the first clamp 140 is formed. At this time, since the side surface of the first clamp 140 is supported by the guide portion 125, the first clamp 140 can not be rotated.

When the first clamp 140 is completely drawn out from the fixing bracket 120, the distance L2 between the slide part 130 and the end of the first clamp 140 is smaller than the distance L2 between the second guide rib 125b and the slide part 130 Of the shortest distance L1. Therefore, since the side surface of the first clamp 140 is not caught by the guide portion 125, the first clamp 140 is pivoted about the slide portion 130 as the operation rod 110 is pulled slightly downward . At this time, the second clamp 150 is also rotated together with the first clamp 140.

The first clamp 140 and the second clamp 150 are simultaneously rotated about the slide portion 130 so that the inlet 154 of the first clamp 140 and the second clamp 150 faces upward. When the operating rod 110 is further pulled downward, the second clamp 150 is rotated upward by the pressure of the ground wire 10. The first clamp 140 and the second clamp 150 are opened so that the ground wire 10 is discharged between the first clamp 140 and the second clamp 150. [ Accordingly, the first clamp 140 and the second clamp 150 can be easily separated from the ground wire 10.

As described above, when the operating rod 110 is pulled downward, the ground wire 10 is drawn between the first clamp 140 and the second clamp 150. When the operating rod 110 is pushed upward, the first clamp The ground wire 10 is easily drawn out between the first clamp 140 and the second clamp 150 as the first clamp 140 and the second clamp 150 are pivoted from the fixed bracket 120. Therefore, it is possible to easily measure the grounding resistance of the grounding wire 10 on the ground without an operator reaching the pole.

Since the second clamp 150 is rotatably coupled to the first clamp 140 so that the second clamp 150 can be separated from the first clamp 140 and the second clamp 140 as the first clamp 140 opens, The ground wire 10 can be easily inserted into the space between the electrodes 150 and 150. Therefore, the operator can easily measure the grounding resistance of the grounding wire 10. [

Since the mounting portion 152 of the second clamp 150 protrudes from the first clamp 140, the first clamp 140 and the second clamp 150 are assembled together, The grounding wire 10 can be easily mounted on the mounting portion 152 of the main body 100. [ Accordingly, the ground wire 10 can be easily inserted between the first clamp 140 and the second clamp 150.

The first clamp 140 and the second clamp 150 can be easily accessed to the ground wire 10 because the wire or ground wire 10 can be pulled or repositioned using the claw portion 160 have.

It is possible to measure the grounding resistance of the grounding wire 10 without having to walk on the pole, so that the resistance of the resistance to check the resistance of the grounding resistance can be reduced, and a constantly qualified power source can be easily measured. In addition, it is possible to inspect vulnerable areas and observing facilities from time to time and reduce the time for measurement of grounding resistance, so that electric power facilities can be protected by lightning, short-circuit and accident current, and damage to persons can be prevented.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand.

Accordingly, the true scope of protection of the present invention should be defined by the claims.

10: Ground wire 110: Operation rod
110a: unit operation rod 111:
112: joint portion 113: rotation preventing portion
115: input line 116: output line
117: inner insulator 118: protective film
120: Fixing bracket 121: Bracket body
122: extension joint portion 122a: engaging projection
123: engaging joint portion 123a: engaging groove portion
125: guide portion 125a: first guide rib
125b: second guide rib 130:
133: head part 140: first clamp
141: first clamp body 142:
143: first measurement trough 145: first induced voltage generator
146: first signal measuring unit 150: second clamp
151: second clamp body 152:
153: second measuring groove 154: inlet
155: second induced voltage generator 156: second signal measuring unit
157: hinge portion 158: elastic member
160: claw portion 161: hook body
163: hook portion 171: battery
175: circuit board 180: grounding resistance measuring unit
181: Measurement unit body 182:
183: Display section 184: Menu key
185: Power button 186: Navigation button
187:

Claims (20)

Operating rod;
A fixing bracket installed on the operating rod;
A slide unit installed on the fixing bracket;
A first clamp movably coupled to the slide portion and being pivotally moved about the slide portion after being moved from the fixed bracket to one side; And
And a second clamp which is rotatably coupled to the first clamp so as to catch the ground wire together with the first clamp,
The first clamp is coupled to the slide portion to be pulled out from the fixing bracket and then pivoted when the operation rod is pushed up,
The fixing bracket includes:
A bracket body coupled to the operating rod; And
And a guide unit for guiding the first clamp to be drawn out in a linear direction from the fixing bracket and releasing the constraint of the first clamp when the first clamp is pulled out so as to be pivoted after the first clamp is pulled out, Ground resistance measuring device.
delete delete The method according to claim 1,
The guide portion
A first guide rib formed opposite to an end of the first clamp; And
And a second guide rib facing the opposite side of the second clamp in the first clamp and supporting a side surface of the first clamp when the first clamp is pulled out.
5. The method of claim 4,
Wherein the first clamp is formed with a slot so that the slide portion is slidably fitted,
Wherein the first clamp is pivoted about the slide portion when the first clamp is pulled out so that the slide portion is located on the end side of the longwave.
6. The method of claim 5,
And wherein the elongated groove is formed in parallel with the second guide rib.
6. The method of claim 5,
Wherein the shortest distance between the second guide rib and the slide portion is shorter than the length of the long portion.
8. The method of claim 7,
When the distance between the slide portion and the end portion of the first clamp is shorter than the shortest distance between the slide portion and the second guide rib when the first clamp is pulled out, the first clamp is pivoted about the slide portion Characterized by a ground resistance measuring device.
The method according to claim 1,
Wherein the second clamp is formed with a mounting part protruding from the first clamp so that the ground wire is mounted.
The method according to claim 1,
The second clamp is rotatably installed in the first clamp by a hinge,
The hinge portion is provided with an elastic member,
Wherein the elastic member is installed to apply an elastic force to the second clamp so that the second clamp and the first clamp are gathered.
6. The method of claim 5,
The first clamp includes:
A first clamp body on which the sheet is formed;
A first induced voltage generator installed in the first clamp body; And
And a first signal measurement unit installed on the first clamp body,
And the second clamp,
A second clamp body rotatably installed on the first clamp body;
A second induced voltage generator installed in the second clamp body and grounded to the first induced voltage generator; And
And a second signal measuring unit installed on the second clamping body and grounded with the first signal measuring unit.
12. The method of claim 11,
A first measurement groove is formed in the first clamp body,
A second measurement groove is formed in the second clamp body so as to correspond to the first measurement groove,
Wherein the first induced voltage generating unit is disposed at a periphery of the first measurement groove,
Wherein the second induced voltage generating unit is disposed at a periphery of the second measurement groove.
13. The method of claim 12,
Wherein the operating rod includes a plurality of unit operation rods assembled in the longitudinal direction.
14. The method of claim 13,
The unit operation stick
An insulating part forming an appearance;
A joint portion connected to an end portion of the insulation portion and coupled to a neighboring unit operation rod;
An input line disposed inside the insulation portion and connected to the first induced voltage generating portion and the second induced voltage generating portion; And
And an output line connected to the first signal measurement unit and the second signal measurement unit, the output line being disposed inside the insulation unit.
15. The method of claim 14,
Wherein the input line and the output line are disposed so as to face each other on an inner surface of the insulating portion.
15. The method of claim 14,
Wherein the joint portion is formed with a rotation preventing portion to prevent the insulating portion from rotating.
15. The method of claim 14,
A battery disposed inside the operating rod and connected to the input line; And
And a circuit board disposed inside the operating rod and connected to the output line.
18. The method of claim 17,
Wherein the battery and the circuit board are installed in an uppermost unit operation rod.
The method according to claim 1,
And a ground resistance measuring unit connected to the operating rod.
The method according to claim 1,
Further comprising a pawl coupled to the fixing bracket and installed to pull the ground wire.

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