KR102469436B1 - Temperature Measuring Device Using High Density Magnetic Field at the Bent Point of the Switchboard Busbar - Google Patents

Abstract

The present invention relates to a temperature measuring device using a high-density magnetic field at a bending point of a switchgear busbar and, more specifically, a temperature measuring device using a high-density magnetic field at a bending point of a switchgear busbar installed in a switchboard or switchgear and used for generating electric power by using electromagnetic induction by current flowing in a busbar. The temperature measuring device using a high-density magnetic field at a bending point of a switchgear busbar is easy to install on a busbar. In addition, the present invention has a simple structure, so the possibility of failure is low, maintenance is easy, and power can be generated by electromagnetic induction using the high voltage of the busbar. Also, the present invention is installed in a position where the electromagnetic wave generation density is high among the structure of the busbar so that sufficient power can be generated. The device comprises a first busbar member, a second busbar member, a pair of brackets, a cylindrical core member, a coil member, and a first fixing member.

Description

Temperature Measuring Device Using High Density Magnetic Field at the Bent Point of the Switchboard Busbar}

The present invention relates to a temperature measuring device using a high-density magnetic field at the bending point of a switchboard busbar, and more particularly, to a switchboard or switchboard busbar bending installed in a switchboard and used for generating electric power by using electromagnetic induction by a current flowing in a busbar. It relates to a temperature measuring device using a point high-density magnetic field.

The extra-high voltage power produced by the power supplier is supplied to each consumer through overhead wires or underground transmission lines. Power supplied through transmission lines is supplied to each consumer through distribution facilities.

A power distribution facility is a device equipped with circuit breakers, switches, and relays to open and close or control external power or protect power facilities. A main circuit breaker and a plurality of branch circuit breakers installed on a panel or frame to distribute power supplied from the outside. It supplies power to various facilities indoors or in a building through a bus-bar connected to and performs the function of opening and closing the supplied power.

Busbar is a general term for long metal products used in place of power cables. It has a higher heat dissipation effect than cables and a large surface area, so it can lower the impedance of high-frequency current flowing on the surface of the conductor, thereby distributing high power with a large current. It is mainly used for equipment.

The bus bar is divided into a plate type made of a rectangular bar structure according to the shape of the exterior and a cylindrical type made of a concentric pipe structure. The busbar assembly installed in the power distribution facility generates heat itself due to overcurrent as the current on the consumer side increases. When the busbar is overheated, power loss occurs, and the voltage is unstable and easily deformed due to a large decrease in conductivity, and in severe cases, the busbar itself melts and the supply of power is completely cut off. In addition, the heat generated from the busbar raises the inside of the power receiving and distributing facility to a certain temperature or higher, thereby greatly reducing the operational efficiency of various other parts and equipment. In addition, even when a problem occurs in a power distribution facility or a consumer side facility, the temperature of the busbar may rise due to overcurrent.

Although it is necessary to monitor the temperature rise of the busbar using a temperature sensor, it is difficult to directly install the sensor on the busbar due to the high voltage. For this reason, in some cases, an indirect measurement method of measuring the temperature of a busbar without contacting the busbar using an infrared temperature sensor such as a portable infrared thermometer or a thermal imaging camera is used. This method has the advantage that the possibility of occurrence of problems due to high voltage is low, but there is a problem in that it is difficult to accurately measure due to the low emissivity of metal and the change in emissivity due to oxidation of the metal surface.

In order to solve this problem, a direct measurement method should be used in which a sensor is installed on a distribution line or a bus bar so that a facility situation can be immediately grasped when an error occurs in the facility. However, it is difficult to install a sensor on a high voltage distribution line, and it is also difficult to supply power by connecting a wire to such a sensor. In particular, in the case of using external power, it may be affected by the power flowing through the busbar, and there are difficulties in configuring a device for supplying power to the sensor, and there are also problems incurring additional costs. In addition, when a device for supplying current to a sensor fails due to a failure or the like, maintenance is difficult and the temperature of the busbar cannot be monitored during that period.

Therefore, there is a need for a device that can stably supply current to a configuration such as a temperature sensor for measuring the temperature of a busbar, and has a simple configuration and less difficulty in maintenance.

The present invention has been devised to satisfy the above-described needs, and has a structure capable of generating electric power using electromagnetic waves caused by high-voltage current flowing through busbars and stably supplying the electric power to temperature sensors that measure the temperature of busbars. It is an object of the present invention to provide a temperature measuring device using a high-density magnetic field at the bending point of a switchgear busbar having a

A temperature measuring device using a high-density magnetic field at a busbar bending point of the present invention to solve the above object is a first busbar member formed in a plate shape so that an extra-high voltage current flows; A second busbar member formed in a plate shape so that a high-voltage current flows and vertically connected to an end portion of the first busbar member; a pair of brackets having fixing plates mounted to face each other on both sides of the connection portions of the first and second busbar members and inner fixing holes formed in the fixing plates; a cylindrical core member disposed inside the connecting portion of the first busbar member and the second busbar member and supported at both ends by the pair of brackets; a coil member disposed in a form surrounding an outer diameter of the core member to generate electric current by being electromagnetically induced by current flowing through the first and second busbar members; And it is installed to pass through the inner fixing hole of the pair of brackets and the inner diameter of the core member, and provides force to the pair of brackets in a direction close to each other to fix the pair of brackets and the core member to the first bus bar. It is characterized in that it includes; a first fixing member fixed to the member and the second busbar member.

The temperature measuring device using the high-density magnetic field at the busbar bending point of the switchgear switchboard of the present invention has the advantage of being easy to install on the busbar. In addition, the present invention has a simple structure, low possibility of failure, easy maintenance, and the advantage of being able to generate power by electromagnetic induction using the high voltage of the busbar. In addition, the present invention has the advantage of generating sufficient power by installing the bus bar at a location where the electromagnetic wave generation density is particularly high among the structures of the busbar.

1 is a perspective view of a temperature measuring device using a high-density magnetic field at a busbar bending point of a switchgear according to an embodiment of the present invention.
FIG. 2 is an exploded perspective view of a temperature measuring device using a high-density magnetic field at a bending point of a busbar on a switchgear shown in FIG. 1;
FIG. 3 is a rear perspective view of a temperature measuring device using a high-density magnetic field at a bending point of a busbar on a switchgear shown in FIG. 1;
4 is an exploded perspective view of a temperature measuring device using a high-density magnetic field at a busbar bending point of a switchgear according to another embodiment of the present invention.

Hereinafter, a temperature measuring device using a high-density magnetic field at a busbar bending point of a switchgear according to an embodiment of the present invention will be described with reference to the accompanying drawings.

The temperature measuring device using a high-density magnetic field at the busbar bending point of the switchgear switchboard of the present invention is installed in a busbar through which extra-high voltage power flows, and is for using current generated by electromagnetic induction. As such, the current obtained by the present invention is used to supply power to other electrical devices such as a temperature sensor for detecting the temperature of a busbar or a communication device for wirelessly transmitting a sensor detection signal.

1 is a perspective view of a temperature measuring device using a high-density magnetic field at a bending point of a busbar according to an embodiment of the present invention, and FIG. 2 is an exploded perspective view of a device for measuring a temperature using a high-density magnetic field at a bending point of a busbar shown in FIG. 3 is a rear perspective view of the temperature measuring device using the high-density magnetic field at the busbar bending point of the switchgear shown in FIG. 1.

1 to 3, the temperature measuring device using a high-density magnetic field at the busbar bending point of the switchgear switchboard according to the present embodiment includes a first busbar member 110, a second busbar member 120, and a pair of brackets 210 and 220 ), a core member 410, a coil member 420, and a first fixing member 310.

The temperature measuring device using the high-density magnetic field at the busbar bending point of the switchgear according to the present embodiment is applied to a busbar formed in a form in which a metal plate is bent at right angles as shown in FIG. 1 and is implemented.

The busbars bent at right angles correspond to the first busbar member 110 and the second busbar member 120 of the present invention. The first busbar member 110 and the second busbar member 120 are formed of a plate-shaped metal material so that a special high voltage current flows. The first busbar member 110 and the second busbar member 120 are vertically connected so as to be orthogonal to each other. The connecting portion where the first busbar member 110 and the second busbar member 120 are connected is formed by rounding in an arc shape as shown in FIGS. 1 to 3 .

The part where the first busbar member 110 and the second busbar member 120 are connected and form an angle of 90 degrees to each other is referred to as the inner side, and the part that forms an angle of 270 degrees to each other is referred to as the outer side and described below. .

A pair of brackets 210 and 220 are installed inside the connection portion between the first busbar member 110 and the second busbar member 120. The pair of brackets 210 and 220 are installed in close contact with both sides of the first busbar member 110 and the second busbar member 120, respectively.

The pair of brackets 210 and 220 include fixing plates 211 and 221, fixing protrusions 213 and 223, inner fixing holes 215 and 225, and outer fixing holes 217 and 227, respectively. A pair of brackets 210 and 220 are formed of a synthetic resin of an insulating material. The brackets 210 and 220 insulate the first and second busbar members 110 and 120 from the core member 410 and the coil member 420 .

As shown in FIGS. 1 to 3 , the fixing plates 211 and 221 are formed of a plate material having a substantially triangular shape. The fixing plates 211 and 221 of the pair of brackets 210 and 220 are mounted on both sides of the connection portions of the first busbar member 110 and the second busbar member 120 so as to face each other.

Two fixing protrusions 213 and 223 protrude from the fixing plates 211 and 221, respectively. The two fixing protrusions 213 and 223 are disposed to contact the outer surface of the first busbar member 110 and the outer surface of the second busbar member 120, respectively. Due to the structure of the fixing protrusions 213 and 223, the pair of brackets 210 and 220 are easily positioned at predetermined positions of the first busbar member 110 and the second busbar member 120, respectively. can be hung

A core member 410 and a coil member 420 are disposed between the pair of brackets 210 and 220 . The core member 410 is a magnetic core made of a ferromagnetic material or a ferromagnetic compound. In this embodiment, the core member 410 is formed in a cylindrical or cylindrical shape. A coil member 420 made of a conductive material is disposed around the outer circumference of the core member 410 to surround the outer diameter of the core member 410 . The core member 410 and the coil member 420 are disposed inside the connecting portion of the first busbar member 110 and the second busbar member 120, respectively, and both ends are respectively a pair of brackets 210 and 220 installed so as to be supported by With this structure, the coil member 420 is electromagnetically induced by the current flowing through the first busbar member 110 and the second busbar member 120 to generate current.

The first fixing member 310 is installed to pass through the inner fixing holes 215 and 225 of the pair of brackets 210 and 220 and the inner diameter of the core member 410, and is attached to the pair of brackets 210 and 220. The pair of brackets 210 and 220 and the core member 410 are fixed to the first busbar member 110 and the second busbar member 120 by providing force in directions approaching each other. In the case of this embodiment, the first fixing member 310 is composed of a first fixing bolt 311 and a first fixing nut 313 shown in FIGS. 1 to 3 . The first fixing bolt 311 is installed to pass through the inner fixing holes 215 and 225 of the pair of brackets 210 and 220 and the inner diameter of the core member 410, and the first fixing nut 313 is It is fastened to the end of the fixing bolt 311. In this way, the tension acting on the fixing bolt by the fastening of the first fixing bolt 311 and the first fixing nut 313 is the pair of brackets (210, 220) to the first bus bar member 110 and the second booth It is fixed in close contact with both sides of the bar member 120. As the pair of brackets 210 and 220 are fixed to the first busbar member 110 and the second busbar member 120, they are fixed to the core member 410 and the coil member 420, respectively.

In a manner similar to the first fixing member 310, the second fixing member 320 is disposed outside the connection portion of the first busbar member 110 and the second busbar member 120, and is provided with a pair of brackets ( 210 and 220) respectively. As described above, since the connecting portion of the first busbar member 110 and the second busbar member 120 is formed to be round in an arc shape, the vertex portion of the pair of triangle-shaped brackets 210 and 220 is the connecting portion. exposed to the outside of The outer fixing holes 217 and 227 are formed in the fixing plates 211 and 221 at portions exposed to the outside of the connecting portion. Therefore, when the second fixing member 320 is installed to pass through the outer fixing holes 217 and 227 and provides tension to the pair of brackets 210 and 220 in a direction close to each other, the pair of brackets 210, 220) can be stably fixed to the first busbar member 110 and the second busbar member 120.

As such, the first fixing member 310 and the second fixing member 320 have a pair of brackets 210 inside and outside the connection portion of the first busbar member 110 and the second busbar member 120, respectively. 220), the pair of brackets 210 and 220 are stably fixed to the first busbar member 110 and the second busbar member 120.

Like the first fixing member 310, the second fixing member 320 includes a second fixing bolt 321 and a second fixing nut 323. The second fixing bolt 321 is installed to pass through the outer fixing holes 217 and 227 of the pair of brackets 210 and 220, and the second fixing nut 323 is attached to the end of the second fixing bolt 321. concluded

Hereinafter, the operation of the temperature measuring device using the high-density magnetic field at the busbar bending point of the switchgear constructed as described above will be described.

As shown in FIGS. 1 to 3, the bus bar often uses a structure in a form bent at right angles. In order to secure a connection space and structure for a switchboard or switchboard while being connected to a power supply line and supplying power to a switchboard or switchboard, a busbar having a structure bent at right angles is often used.

In this way, a magnetic field is concentrated at the connecting portion of the busbar having a structure in which the first busbar member 110 and the second busbar member 120 are connected and bent, so that a magnetic field twice as high as the surrounding area is generated. Therefore, if the coil is installed at the point where such a strong magnetic field is generated, sufficient power can be obtained by electromagnetic induction, and the power obtained in this way can be stably supplied to the surrounding components for safety, such as a temperature sensor, to reduce the risk of fire. It can be used for preventive purposes.

In order to effectively use the high magnetic field generated at the bending point of the busbar as described above, in the case of the temperature measuring device using the high-density magnetic field at the bending point of the busbar according to the present embodiment, the brackets 210 and 220 of the form shown in FIGS. 1 to 3 ) is used.

The brackets 210 and 220 having fixing plates 211 and 221 formed in a triangular plate shape are effectively seated at corners formed by the first busbar member 110 and the second busbar member 120. In addition, the brackets 210 and 220 are in close contact with the side surfaces of the first busbar member 110 and the second busbar member 120 by the fixing protrusions 213 and 223 formed on the fixing plates 211 and 221. It has a structure that can effectively fix the position. In this state, when the first fixing member 310 is fixed through the inner fixing holes 215 and 225 of the brackets 210 and 220 and the first fixing bolt 311 and the first fixing nut 313 are fastened, The pair of brackets 210 and 220 adhere to both sides of the first busbar member 110 and the second busbar member 120 by the tension acting on the first fixing bolt 311, and the first busbar member 110 and the second busbar member 120 can be firmly fixed.

In addition, the second fixing member 320 disposed outside the connection portion of the first busbar member 110 and the second busbar member 120 is also passed through the outer fixing holes 217 and 227 of the brackets 210 and 220. By fastening, the brackets 210 and 220 are fixed to the first busbar member 110 and the second busbar member 120. As such, the first fixing member 310 and the second fixing member 320 exert tension on the brackets 210 and 220 inside and outside the connection parts of the first busbar member 110 and the second busbar member 120, respectively. By providing, the brackets 210 and 220 can be more firmly fixed to the first busbar member 110 and the second busbar member 120. As described above, if the outside of the connection portion of the first busbar member 110 and the second busbar member 120 is formed in a round shape, the space where the second connection member can be connected to the brackets 210 and 220 is effectively created. can be secured

At this time, both ends of the core member 410 supported by the first fixing bolt 311 are also firmly fixed while being pressed by the pair of brackets 210 and 220 .

Meanwhile, in the process of installing the first fixing member 310, the core member 410 and the coil member 420 are each inserted into the first fixing member 310 and fixed between the pair of brackets 210 and 220. do.

Due to the structure of the temperature measuring device using the high-density magnetic field at the busbar bending point of the switchgear according to this embodiment, the core member 410 and the coil member 420 are respectively the first busbar member 110 and the second busbar member ( 120) is effectively fixed at a position very close to the edge of the connection part, while maintaining an insulation state with respect to the second busbar member 120 other than the first busbar member 110.

As described above, since a magnetic field about twice that of the surrounding area is generated at the bending point of the busbar, the coil of the temperature measuring device using the high-density magnetic field at the bending point of the busbar according to this embodiment is connected to the first busbar member 110. 2 Electric power is generated by electromagnetic induction in a state located close to the connection part of the busbar member 120. In this way, power generated from the coil member 420 is connected to a separate electrical component to supply power to the temperature sensor or the communication unit.

The preferred embodiment of the temperature measuring device using the high-density magnetic field at the bending point of the switchgear busbar according to the present invention has been described above, but the scope of the present invention is not limited to the form described and illustrated above.

For example, by providing a second fixing member 320 in addition to the first fixing member 310, the bracket 210 is also provided outside the connection portion between the first busbar member 110 and the second busbar member 120. , 220) has been described, but the temperature measuring device using the high-density magnetic field at the busbar bending point of the switchgear has been described, but in some cases, the second fixing member 320 is not provided, but only the first fixing member 310 It is also possible to implement a temperature measurement device using a high-density magnetic field at the busbar bending point of the switchgear. In addition, it is also possible to configure a temperature measuring device using a high-density magnetic field at a busbar bending point of a switchgear using a bracket having a structure without external fixing holes 217 and 227. In some cases, the inner fixing holes 215 and 225 and the outer fixing holes 217 and 227 are formed in the brackets 210 and 220, but the first fixing member 310 It is also possible to configure a temperature measuring device using a high-density magnetic field at the busbar bending point of the switchboard so that the second fixing member 320 and the second fixing member 320 are selectively used as needed.

In addition, although the first fixing member 310 composed of the first fixing bolt 311 and the first fixing nut 313 has been described as an example, the structure and shape of the first fixing member 310 are shown in FIGS. In addition to the form shown in FIG. 3, it can be modified into various other structures. The second fixing member 320 can be changed in the same way.

In addition, the structures of the brackets 210 and 220 also have various other shapes as long as the core member 410 and the coil member 420 can be fixed to the first busbar member 110 and the second busbar member 120. can be transformed into In the case of the embodiment described above with reference to FIGS. 1 to 3, the brackets 210 and 220 have been described as having two fixing protrusions 213 and 223, respectively, but in some cases, the fixing protrusions 213 and 223 are provided. It is also possible to use a bracket having a structure that does not, and it is also possible to use a bracket having a structure having three or more fixing protrusions 213 and 223.

4 is a temperature measuring device using a high-density magnetic field at a busbar bending point of a switchgear according to the present invention having brackets 230 and 240 having a different structure from the temperature measuring device using a high-density magnetic field at a bending point of a switchgear busbar shown in FIGS. 1 to 3 is shown in a separated perspective view.

In the brackets 220 and 240 of the temperature measuring device using the high-density magnetic field at the busbar bending point of the switchgear shown in FIG. 4, four fixing protrusions 233 and 243 are formed on the fixing plates 231 and 241, respectively. Each of the fixing protrusions 233 and 243 protrudes from the fixing plates 231 and 241 to contact the outer and inner surfaces of the first busbar member 110 and the second busbar member 120, respectively. . The distance between the fixing protrusions 233 and 243 facing each other is greater than the thickness of the first busbar member 110 and the second busbar member 120 . Accordingly, the first busbar member 110 and the second busbar member 120 are inserted between the fixing protrusions 233 and 243 facing each other of the brackets 230 and 240, respectively, so that the first busbar member 110 and the position fixing of the brackets 230 and 240 relative to the second busbar member 120 can be further facilitated. In addition, in some cases, it is configured in a tapered shape in which the distance between the fixing protrusions 233 and 243 facing each other decreases as they enter the inside, so that the brackets are attached to the first busbar member 110 and the second busbar member 120. It is also possible to use a structure in which the closer the 210 and 220 are, the more accurately they are seated.

The rest of the configuration except for the brackets 230 and 240 of the temperature measuring device using a high-density magnetic field at the switchboard Busbar bending point shown in FIG. Since they are the same, they are illustrated by assigning the same member numbers to each other.

The structure of the bracket can be modified into various other forms other than the form shown in FIG. 4 .

110: first busbar member 120: second busbar member
210, 220, 230, 240: bracket 211, 221, 231, 241: fixed plate
215, 225: inner fixing hole 217, 227: outer fixing hole
213, 223, 233, 243: fixing protrusion 310: first fixing member
311: first fixing bolt 313: first fixing nut
320: second fixing member 321: second fixing bolt
323: second fixing nut 410: core member
420: coil member

Claims (7)

A first bus bar member formed in a plate shape to allow a special high voltage current to flow;
A second busbar member formed in a plate shape so that a high-voltage current flows and vertically connected to an end portion of the first busbar member;
a pair of brackets having fixing plates mounted to face each other on both sides of the connection portions of the first and second busbar members and inner fixing holes formed in the fixing plates;
a cylindrical core member disposed inside the connecting portion of the first busbar member and the second busbar member and supported at both ends by the pair of brackets;
a coil member disposed in a form surrounding an outer diameter of the core member to generate electric current by being electromagnetically induced by current flowing through the first and second busbar members; and
It is installed to pass through the inner fixing hole of the pair of brackets and the inner diameter of the core member, and provides force to the pair of brackets in a direction approaching each other to fix the pair of brackets and the core member to the first busbar member. And a first fixing member fixed to the second busbar member;
The connection part of the first busbar member and the second busbar member is formed to be round in an arc shape,
The pair of brackets further include an outer fixing hole formed in the fixing plate and disposed at a position corresponding to an outer side of the connection portion of the first and second busbar members,
Installed via the outer fixing hole of the pair of brackets to provide force to the pair of brackets in a direction approaching each other to fix the pair of brackets to the first and second busbar members A second fixing member; further comprising,
The first fixing member,
A first fixing bolt installed to pass through the inner fixing hole of the pair of brackets and the inner diameter of the core member, and a first fixing nut fastened to an end of the first fixing bolt,
The second fixing member,
A second fixing bolt installed to pass through the outer fixing hole of the pair of brackets, and a second fixing nut fastened to an end of the second fixing bolt,
The pair of brackets are in contact with the outer surfaces of the first and second busbar members and protrude from the fixing plate so as to facilitate position fixation with respect to the first and second busbar members. A temperature measuring device using a high-density magnetic field at the bending point of a busbar in a switchboard including each fixed protrusion. delete A first bus bar member formed in a plate shape to allow a special high voltage current to flow;
A second busbar member formed in a plate shape so that a high-voltage current flows and vertically connected to an end portion of the first busbar member;
a pair of brackets having fixing plates mounted to face each other on both sides of the connection portions of the first and second busbar members and inner fixing holes formed in the fixing plates;
a cylindrical core member disposed inside the connecting portion of the first busbar member and the second busbar member and supported at both ends by the pair of brackets;
a coil member disposed in a form surrounding an outer diameter of the core member to generate electric current by being electromagnetically induced by current flowing through the first and second busbar members; and
It is installed to pass through the inner fixing hole of the pair of brackets and the inner diameter of the core member, and provides force to the pair of brackets in a direction approaching each other to fix the pair of brackets and the core member to the first busbar member. And a first fixing member fixed to the second busbar member;
The connection part of the first busbar member and the second busbar member is formed to be round in an arc shape,
The pair of brackets further include an outer fixing hole formed in the fixing plate and disposed at a position corresponding to an outer side of the connection portion of the first and second busbar members,
Installed via the outer fixing hole of the pair of brackets to provide force to the pair of brackets in a direction approaching each other to fix the pair of brackets to the first and second busbar members A second fixing member; further comprising,
The first fixing member,
A first fixing bolt installed to pass through the inner fixing hole of the pair of brackets and the inner diameter of the core member, and a first fixing nut fastened to an end of the first fixing bolt,
The second fixing member,
A second fixing bolt installed to pass through the outer fixing hole of the pair of brackets, and a second fixing nut fastened to an end of the second fixing bolt,
The pair of brackets are fixed so as to be in contact with the outer and inner surfaces of the first and second busbar members, respectively, so that the positions of the first and second busbar members can be easily fixed. A temperature measuring device using a high-density magnetic field at the bending point of a switchgear busbar each including a plurality of fixing protrusions protruding from the plate. According to claim 3,
The distance between the fixing protrusions facing each other among the plurality of fixing protrusions of the pair of brackets is greater than the thickness of the first busbar member and the second busbar member. Temperature measuring device using a high-density magnetic field at the switchboard busbar bending point. delete delete delete

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