KR100921965B1 - Bus bar with function of preventing overheat and remote-monitoring in distributing board - Google Patents

Abstract

PURPOSE: A bus bar with an overheat prevention function and a remote control are provided to control an electric device which is controlled by a distribution board smoothly by using information stored in an embedded server. CONSTITUTION: A bus bar with an overheat prevention function and a remote control is composed of bus bar(1), a reference temperature setting unit(4), a temperature sensor(5), an AD converter(6), MICOM(7), a PCT driving unit(8), and an embedded server(14). The temperature detection sensor is installed between the top of an insulator and the bottom of the bus bar, and it detects the temperature of a bus bar in real time. The MICOM outputs a driving signal of thermoelectric element to the PCT driving unit when the temperature of the bus bar is higher than the predetermined temperature. The thermoelectric element is driven in response to the output signal of the PTC driving unit, and it prevents overheat of the bus bar by generating cool air through the insulator.

Description

Bus bar with function of preventing overheat and remote-monitoring in distributing board}

The present invention relates to a bus bar for a switchgear having a function of preventing overheating and remote monitoring. More specifically, the temperature of a bus bar is detected by detecting a temperature of a bus bar installed in a switchgear for supplying electric power to various electrical devices requiring electricity. When the temperature rises above the predetermined temperature due to overload, the thermoelectric element (PTC; combined with PTC) is installed between the bottom of the insulator and the top of the insulator fixture to cool the busbars. Equipped with a built-in server that can store the monitoring data of various components including the temperature change data of the busbar, and if necessary, it can be transferred to a central monitoring room computer or a personal computer carried by the administrator. Not only can busbars be prevented from melting due to overheating, Power loss can be prevented, and various status information of switchgear can be recognized in real time at remote locations, and necessary measures can be taken immediately in case of emergency such as overheating of busbars, so that smooth power supply can be maintained. The status information of various components generated in the switchgear can be stored in the built-in server installed in each switchgear, not stored in the server installed in the central monitoring room of the remote site. Regardless of the state of the computer, it is invented to smoothly control various electric devices controlled by each switchgear by using information stored in an embedded server.

In general, factories, buildings, hospitals, APT complexes, and various industrial facilities use three-phase AC power, which requires a large amount of power. Thousands of volts (V) supplied from power plants through power transmission lines are supplied through transformers. A switchgear is provided for reducing the voltage to an AC voltage of V and supplying the reduced AC voltage to each facility of the factory.

Such switchgear is installed in a place that requires electric power, and converts the high voltage electricity supplied from the power supply source into a low voltage and rated capacity that meets the ratings of various equipment and equipment that are actually used. It is a device for controlling and monitoring.

This switchgear is composed of a circuit breaker and various parts installed for the operation, control and monitoring of the supplied electricity.

In such a switchgear, in order to supply a high voltage high current to the facilities in each plant, the facility and the switchgear are typically connected to a bus bar, and the AC voltage reduced in the switchgear is supplied to the facility through the bus bar.

In this case, the busbar is a general term for a long metal plate-like product used in place of the power cable, and such a busbar has a wider flat plate shape than the cable, so that the heat dissipation effect is large and the surface area thereof is wide so that high frequency flows on the surface of the conductor. The impedance of the current can be lowered, which is more advantageous for high speed systems with a large current.

In addition, the shield effect can be obtained through the installation of the laminate of the busbars, and the capacitance of the distribution constant can be obtained very high. It is widely applied to the internal distribution line configuration of power distribution facilities and motor control panels.

Here, the amount of current flowing through the busbar is changed according to the load variation of the customer side or the motor, but the temperature of the busbar increases when the amount of current increases or excessive load current flows for a long time.

Conventionally, most of the busbars are made of pure copper material and formed into rectangular bar-shaped plates. In this case, by using only pure copper, the busbars are molded so that the amount of copper is high. On the other hand, due to the weak rigidity, there is a problem that the workability when installing the busbar is significantly reduced.

In addition, the rectangular bar-shaped bus bar is overheated due to the exothermicity of high-voltage current, and due to the characteristics of the electric field drawing a concentric circle, the conductivity is low, so that the installation is easy when the voltage is unstable and receives heat. There is a problem that is deformed.

Therefore, some of them use only aluminum alloy or pure aluminum to form busbars, but in the case of pure aluminum busbars, it is too difficult to produce products that maintain high strength and improve electrical conductivity due to the characteristics of aluminum itself. In addition, there is a problem that is expensive, and the aluminum copper alloy busbar is a situation in which the development cost to overcome this is a huge difference between the melting temperature of aluminum and copper.

Therefore, in recent years, aluminum core busbars have been formed by forming a central body of an aluminum bar and forming a copper enclosed periphery of the aluminum center body. In this case, the characteristics of aluminum having a low specific gravity and low raw material cost, It is possible to simultaneously obtain copper properties with high strength and excellent electrical conductivity.

On the other hand, when the overcurrent due to overload flows in the busbars, there are some differences depending on the characteristics of the material, but eventually the heat generation occurs in the busbar itself in response to the overcurrent caused by the overload. When the busbar overheats due to abnormal flow, power loss loss due to reactive power is generated a lot, and the conduction is reduced due to the characteristics of the electric field, and the voltage is unstable and easily deformed. In severe cases, the busbar itself melts to supply power. There is a problem that is blocked.

Therefore, even in a conventional switchgear, a blower fan may be operated by cooling a temperature when a temperature inside a cabinet of the switchgear rises above a certain temperature or when each bus bar rises above a certain temperature. It is a method of forcibly discharging the air in the switchboard to the outside and forcibly sucking the outside air inside to reduce the temperature of the busbar by lowering the air temperature inside the switchboard. There is a problem that can not be cooled.

In addition, the conventional switchgear is not equipped with any device capable of storing status information data for various components including the temperature change data of the busbars, so that the switchgear when the situation occurs in each switchgear check or each switchgear There is a problem in that it is not possible to find the cause in the inside of the various components installed in the switchgear must be checked individually.

In addition, some switchboards are equipped with various state detection sensors as well as communication equipment for transmitting these status information to a computer installed in a remote control room. In this case, a server for storing the status information of each switchboard. Is provided in the remote control room, if the server of the control room is fixed, there is a problem that the remote monitoring and control of them, as well as the collection of information about all switchboards managed by the computer.

The present invention has been made in order to solve such a conventional problem, by detecting the temperature of the bus bar installed in the switchgear and when the temperature of the bus bar rises above a predetermined temperature due to overload, the bottom of the insulator and the insulator A thermocouple (PTC) installed between the upper surfaces is used to cool the busbars, while the switchboard is equipped with a built-in server that can store monitoring data on various components including temperature change data of the busbars. If necessary, it can be transferred to a central monitoring room computer or a manager's personal computer that is carried by a remote person. When the temperature rises in the busbar, it will generate an alarm sound or alarm light. This prevents overheating of the busbars due to overload and prevents the loss of reactive power, and prevents the busbars from being deformed or melted and cut off the power supply due to overheating. In addition, when a certain busbar is excessively overheated, the manager of the switchboard immediately recognizes the alarm sound or an alarm light and takes necessary actions in a short time, so that the switchboard can be efficiently managed. Real time can be recognized in remote area and immediate supply and demand can be maintained in case of emergency such as overheating of booth bar, so that smooth power supply can be maintained, and in particular, the status information of various components generated in each switchgear Remember the server in the surveillance room It can be stored in the built-in server installed in each switchgear, and the data can be called out and utilized when needed.It is controlled by each switchgear by using the information stored in the built-in server regardless of the computer status of the central monitoring room. It can not only control various electric devices smoothly but also manager can receive various status information in the switchboard in real time regardless of the place through the personal computer that he carries. Reliability can be greatly improved, and the bus bar itself is formed in the form of covering the copper pipe integrally on the outside of the aluminum bar, and by selectively forming heat radiation grooves on the upper, lower, left and right surfaces, or both. Overheating that can significantly improve the heat dissipation effect of the busbar itself It is an object of the present invention to provide a bus bar for switchgear with prevention and remote monitoring.

In order to achieve the above object, the present invention provides a bus bar for switchgear having a function of preventing overheating and a remote monitoring function. The user can determine which temperature the bus bar will reach when the bus bar is driven. A reference temperature setting unit for setting the reference temperature; A temperature detection sensor installed between the top of the insulator and the bottom of the coupling part of the busbar to detect the temperature of the busbar in real time; An A / D converter for converting the temperature of the busbar detected as an analog signal through the temperature detection sensor into a digital signal; A microcomputer for outputting a thermoelectric element driving signal to the PTC driver when the temperature of the bus bar input through the A / D converter is higher than a set temperature set by the user; A PTC driver for controlling driving of the thermoelectric element in response to the output signal of the microcomputer; Cold air is generated on one surface and heat is generated on the other surface according to the supply direction of the DC voltage, and is installed between the bottom surface of the insulator and the top surface of the insulator fixture to be driven in response to the output signal of the PTC drive unit. A thermoelectric element (PTC) for generating cold air to prevent overheating of the busbar; It is installed in the switchgear board and receives the monitoring data for the various components including the temperature change data of the busbar through the microcomputer and stores it and outputs it when the request of the microcomputer; characterized in that configured as a.

In this case, the embedded server is connected to the computer of the remote central monitoring room through wired and wireless communication lines to receive various status information in the switchboard in real time from the remote monitoring room, as well as the server or the corresponding information installed in itself. It is characterized in that it can be stored in the memory | storage device.

In addition, the embedded server allows the administrator to communicate in real time with a personal computer carried by the administrator through wired and wireless communication lines so that the administrator can receive various status information in the switchboard in real time regardless of the place. It is characterized by.

In addition, the reference temperature setting unit has a lower limit temperature for stopping the operation of the thermoelectric element when the temperature of the busbar decreases below which temperature during the operation of the thermoelectric element (PTC) when the busbar temperature reaches the set temperature. The microcomputer is further provided with a function to allow the user to set the microcomputer outputs a thermoelectric element driving signal to the PTC drive unit when the temperature of the busbar is higher than the user set temperature, and generates a cutoff signal when the temperature is lower than the lower limit temperature. It features.

The PTC driving unit may further include a timer for supplying a driving voltage to the PTC only for a predetermined time when the PTC driving signal is output from the microcomputer.

In addition, the input terminal of the microcomputer is provided with an overheat temperature setting unit for setting the overheat temperature according to whether the user will recognize the overheat when the temperature of the busbar rises above, and the alarm signal generating unit at the output terminal of the microcomputer In addition, the microcomputer is configured to drive the alarm through the alarm signal generator when the temperature of the busbar rises above the overheat temperature set by the user even though the thermoelectric element is being driven.

At this time, the alarm is characterized in that it comprises a buzzer for generating an alarm sound or an alarm light for generating an alarm light.

In addition, the driving temperature of the thermoelectric element (PTC) set by the reference temperature setting unit is any temperature between 50-70 degrees, the lower limit temperature for blocking the driving of the thermoelectric element (PTC) is less than 50 degrees, the alarm Overheating temperature to drive is characterized in that more than one temperature between 75-90 degrees.

In addition, the bus bar is integrally molded to have a rectangular bar shape through the drawing by inserting an aluminum bar extruded to have a rectangular bar shape into the inside of the copper pipe extruded to have a square pipe shape, the top of the bus bar, It is characterized in that a plurality of heat dissipation grooves are formed in the longitudinal direction on the lower surface, the left, the right side, or the upper, the lower, the left, and the right side.

As described above, according to the present invention, when the temperature of the bus bar is installed in a very useful switchgear, and the temperature of the bus bar rises above a predetermined temperature due to overload, it is installed between the bottom of the insulator and the top of the insulator fixture. A thermoelectric element (PTC) can be used to cool the busbars, and the switchboard is equipped with a built-in server that can store monitoring data on various components including the temperature change data of the busbars. It can be transferred to the central monitoring room computer or the personal computer carried by the administrator, and the temperature of the busbar is higher than the overheat temperature set by the user even though the temperature of the busbar is cooled by the thermoelectric element. To raise an alarm sound or alarm light Overheating of the busbars can be prevented from overheating to prevent reactive power loss, and overheating can prevent the busbars from being deformed or melted to cut off the power supply. When excessively overheated, the manager of the switchboard immediately recognizes the alarm sound or alarm light and takes the necessary measures in a short time so that the switchboard can be managed efficiently. In the event of an emergency such as overheating of busbars, it is possible to immediately carry out necessary measures to continue smooth supply and demand. Fourth, the status information of various components generated in each switchboard is installed in the central monitoring room of a remote site. To each switchboard without storing it on the server. It can be stored in the built-in server installed, and the relevant data can be called out and used when needed. Using the information stored in the built-in server regardless of the computer status of the central monitoring room, various electric devices controlled by each switchgear can be smoothly used. The fifth manager can receive various status information in the switchboard in real time regardless of the place through the personal computer that he carries, and greatly improves the reliability of monitoring, managing and controlling each switchboard. The sixth busbar itself may be pulled out in such a way that the copper pipes are integrally covered on the outside of the aluminum bar, but the heat sinks are selectively formed on the upper, lower, left, and right sides of the bus bar itself. High heat dissipation area allows inventors to significantly improve heat dissipation effect will be.

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

Figure 1 shows a block diagram of the present invention, Figures 2 to 3 show a perspective view of the busbars applied in the present invention.

According to the present invention, in the configuration of a bus bar for switchgear having overheat prevention and remote monitoring,

A reference temperature setting unit 4 for allowing a user to set whether to drive the thermoelectric element (PTC) 10 when the temperature of the bus bar 1 reaches which temperature T1;

A temperature detection sensor 5 installed between the top surface of the insulator 2 and the bottom surface of the coupling portion of the busbar 1 to detect the temperature of the busbar 1 in real time;

An A / D converter 6 for converting the temperature of the bus bar 1 detected as an analog signal through the temperature detection sensor 5 into a digital signal;

A microcomputer 7 for outputting a thermoelectric element driving signal to the PTC driver 8 when the temperature of the bus bar 1 input through the A / D converter 6 is higher than the set temperature T1 set by the user;

A PTC driver (8) for controlling the driving of the thermoelectric element (10) in response to the output signal of the microcomputer (7);

Cold air is generated on one surface and heat is generated on the other surface according to the supply direction of the DC voltage supplied through the PTC driver 8, and between the bottom surface of the insulator 2 and the top surface of the insulator fixture 3. A PTC (10) installed and driven in response to an output signal of the PTC driver (8), generating cold air through the insulator (2), and transferring it to the bus bar (1) to prevent overheating;

Built-in type installed in the switchgear to receive the monitoring data for the various components including the temperature change data of the busbar (1) through the microcomputer (7) and to store it and output it when the request of the microcomputer (7) Server 14; characterized in that configured as.

At this time, the embedded server 14 is connected to the computer of the remote central monitoring room via a wired or wireless communication line to allow the remote monitoring room to receive various status information in the switchboard in real time, as well as the corresponding information. It is characterized in that they can be stored in a server or a storage device 16 installed therein.

In addition, the embedded server 14 allows the administrator to communicate in real time with the personal computer 17 carried by the administrator through a wired or wireless communication line, so that the administrator can be in real time and various state information in the switchboard regardless of place. Characterized in that it can be delivered to.

In the reference temperature setting section 4, when the temperature of the busbar 1 reaches the set temperature T1 and the temperature of the busbar 1 falls below a certain temperature while the PTC 10 is being driven. The microcomputer 7 further includes a function of allowing the user to set a lower limit temperature T2 on whether to shut off the operation of the thermoelectric element 10, and the microcomputer 7 has a temperature of the busbar 1 set by the user. Is higher than), the thermoelectric element driving signal is output to the PTC driving unit 8, and when the temperature is lower than the predetermined lower limit temperature T2, a cutoff signal is generated.

The PTC driver 8 supplies a driving voltage to the PTC 10 only for a predetermined time t (for example, 1-5 minutes) when the PTC driving signal is output from the microcomputer 7. Characterized in that further provided.

In addition, the input terminal of the microcomputer (7) is added to the overheat temperature setting unit 13 that can set the overheat temperature (T3) according to whether the user will recognize the overheat when the temperature of the bus bar (1) In addition, an alarm signal generator 11 is additionally installed at the output terminal of the microcomputer 7 so that the microcomputer 7 is driven only by the thermoelectric element 10 and the superheat temperature T3 set by the user. When the temperature of the bus bar 1 rises above), the alarm 12 is driven through the alarm signal generator 11.

At this time, the alarm 12 is characterized in that it comprises a buzzer for generating an alarm sound or an alarm light for generating an alarm light.

In addition, the driving temperature T1 of the PTC 10 set by the reference temperature setting unit 4 is any temperature between 50 and 70 degrees, and the lower limit temperature T2 for interrupting the driving of the PTC 10. Is less than 50 degrees, the overheat temperature (T3) for driving the alarm 12 is characterized in that more than one temperature between 75-90 degrees.

In addition, the bus bar 1 is integrally formed to have a rectangular bar shape through drawing by inserting an aluminum bar 102 extruded to have a rectangular bar shape into the inside of the copper pipe 101 extruded to have a rectangular pipe shape. Molded to, but characterized in that formed on the top, bottom, left, right side of the bus bar (1), or several heat dissipation grooves 103 in the longitudinal direction on both the top, bottom, left, right side. .

Referring to the effect of the present invention configured as a busbar as follows.

First, the busbar for switchgear having the overheat prevention and remote monitoring function to which the present invention is applied is largely divided into a reference temperature setting unit 4, a temperature detection sensor 5, an A / D converter 6, a microcomputer 7, and a PTC. What constitutes the drive part 8, the PTC 10, and the built-in server 14 is a main technical component.

At this time, the reference temperature setting unit 4 is based on the user to set whether to drive the thermoelectric element (PTC) 10 when the temperature of the bus bar 1 reaches a certain temperature (T1) do,

In addition, when the lower limit temperature T2 setting function is added to the reference temperature setting unit 4, a temperature T1 of the bus bar 1 has been reached by the user through the reference temperature setting unit 4. When the PTC 10 is to be driven and the temperature of the busbar 1 has reached the set temperature T1, the temperature of the busbar 1 has fallen below a certain temperature during the operation of the PTC 10. In order to prevent unnecessary power consumption when the lower limit temperature (T2) can be set whether to shut off the drive of the thermoelectric element (10).

At this time, the driving temperature (T1) of the PTC 10 set by the reference temperature setting unit 4 may vary depending on what material the busbar 1 is formed of, which is widely used in the art in recent years. Considering that it is an aluminum-copper bus bar or a bus bar (1) made of aluminum alloy or aluminum itself, the temperature is set at any temperature between 50 and 70 degrees, and the lower limit temperature (T2) for blocking the operation of the PTC (10). It was also set to less than 50 degrees in consideration of the bus bar (1) molded from an aluminum-copper bus bar or an aluminum alloy or aluminum itself.

In addition, the temperature detection sensor 5 is installed between the upper surface of the insulator 2 and the bottom of the coupling portion of the busbar 1 to detect the temperature of the busbar 1 in real time, and the A / D converter ( 6) converts the temperature of the busbar 1 detected as an analog signal through the temperature detection sensor 5 into a digital signal and then transfers it to the microcomputer 7.

The microcomputer 7 may further include a PTC driver (if the temperature of the bus bar 1 input through the A / D converter 6 is higher than the set temperature T1 set by the user through the reference temperature setting unit 4). The thermoelectric element driving signal is output to 8).

However, when the reference temperature setting unit 4 is provided with a lower limit temperature T2 setting function, the microcomputer 7 has a higher temperature than the user's set temperature T1 as described above. Outputs the thermoelectric element driving signal to the PTC driver 8 to drive the PTC 10 until the temperature of the busbar 1 falls below the lower limit temperature T2 regardless of time, and the PTC 10 as described above. If the temperature of the bus bar 1 is lowered below the lower limit temperature T2 while driving), the thermoelectric element blocking signal is output to the PTC driver 8.

In addition, the PTC driver 8 directly controls the driving of the thermoelectric element 10 in response to the output signal of the microcomputer 7.

When the timer 9 is additionally installed in the PTC driver 8 as described above, when the PTC drive signal is output from the microcomputer 7, the PTC driver 8 is set by the timer 9 at a time t; For example, the driving voltage is supplied to the PTC 10 only for 1-5 minutes.

Accordingly, when the timer 9 is additionally installed in the PTC driver 8, the temperature of the busbar 1 reaches the set temperature T1 in the reference temperature setting unit 4 so that the PTC 10 is driven. It is not necessary to provide a function for setting the lower limit temperature T2 for stopping the driving of the thermoelectric element 10 when the temperature of the busbar 1 falls below a certain temperature during the process.

That is, when the timer 9 is additionally installed in the PTC driver 8, the PTC 10 is unchanged for only 1-5 minutes determined by the timer 9 whenever the PTC drive signal is output from the microcomputer 7. This is because it is not necessary to detect the lower limit temperature T2 since the voltage supplied to the PTC 10 is cut off after the predetermined time elapses after the driving voltage is supplied.

In this way, the PTC driver 8 is provided with the timer 9 so that the PTC 10 can be turned on only for 1-5 minutes determined by the timer 9 whenever the PTC driving signal is output from the microcomputer 7. By driving it, unnecessary waste of power can be prevented.

Of course, as described above, after driving the PTC 10 for 1-5 minutes determined by the timer 9 and then shutting off the drive, the temperature of the busbar 1 is detected and is less than the user's set temperature T1. If it is not lowered, the microcomputer 7 outputs a PTC drive signal to the PTC driver 8 again, so that the PTC 10 is repeatedly operated for a predetermined time by the timer 9. .

In addition, the PTC 10 has a function in which cold air is generated on one surface and heat is generated on the other surface according to the supply direction of the DC voltage supplied through the PTC driver 8, and the bottom surface of the insulator 2 and the insulator are fixed. It is provided between the upper surface of (3), but the surface where cold air is generated is installed so that it is located in the bottom surface side of the insulator (2).

Therefore, since the PTC 10 is operated in response to the driving voltage output from the PTC driver 8 and generates cold air through the insulator 2, the cold air generated from the PTC 10 is insulated from the insulator 2. It is transmitted to the bus bar 1 through the cooling) to prevent the bus bar 1 from overheating due to overloading, thereby significantly improving the efficiency of the bus bar 1 itself, The reactive power loss can be prevented, and the bus bar 1 can be prevented from being deformed or melted due to overload, thereby preventing the power supply from being cut off.

Meanwhile, the embedded server 14 receives and stores monitoring data about various components in real time through the microcomputer 7, including temperature change data of the busbars 1 in the switchgear while installed in the switchgear. Then, it acts as a data backup device that performs a function of outputting the request when the request of the microcomputer (7).

In this way, when the embedded server 14 is installed in each switchgear, the embedded server installed in the switchgear does not store the state information of various components generated in each switchgear in a server installed in the central monitoring room at a remote location. 14) can be recalled and utilized if necessary, so that the history using the information stored in the embedded server 14 can be tracked regardless of the state of the server including the computer (15) of the central monitoring room, In addition, it is possible to smoothly control various electric devices controlled by each switchgear.

That is, even when the computer 15 or the server of the control room that remotely controls and monitors each switchboard is fixed, the state information of various parts in the switchboard is collected through the embedded server 14 installed in the switchboard. By using the information it is possible to smoothly control the various electrical equipment controlled by each switchgear.

In addition, the embedded server 14 installed in each switchgear may be connected to the computer 15 of the remote central monitoring room through a wired or wireless communication line, and a personal computer 17 carried by an administrator. It may be possible to communicate in real time.

In this case, the computer 15 of the central monitoring room of the remote location of the various parts including the temperature information for each of the busbars (1) in the switchboard that is transmitted from the embedded server 14 through a wired or wireless communication line It receives real-time status information and displays it on its own monitor in real time, displaying it to the administrator who resides in the monitoring room, and storing the information on the server or storage device 16 installed in the system. This can be usefully used as history tracking information.

In addition, on the monitor of the personal computer 17 carried by the manager, the status information of various parts is displayed in real time, including temperature information on each of the busbars 1 in the switchboard, so that the manager is free from any location. Through the personal computer 17 he carries, he can check various status information in the switchboard in real time and take necessary measures promptly due to overheating of the busbar 1, so as to monitor, manage and control each switchboard. The reliability can be greatly improved.

On the other hand, if the bus bar (1) is overloaded and continuously overcurrent flows, as well as driving the PTC (10) as described above, the temperature of the bus bar (1) may increase.

Therefore, in the present invention, the overheat temperature setting unit for setting the overheat temperature (T3) according to whether the user will recognize the overheat when the temperature of the bus bar (1) rises over the input terminal of the microcomputer (7) 13) was further provided, and an alarm signal generator 11 was additionally installed at the output terminal of the microcomputer 7.

In addition, by changing a part of the control program of the microcomputer (7), the temperature of the bus bar (1) is raised above the user's set temperature (T1) to drive the thermoelectric element (10), but only busbar (1) When the temperature rises above the overheating temperature T3 set by the user, the alarm signal generating unit 11 may drive an alarm 12 including a buzzer or an alarm lamp to inform the administrator in the vicinity of the switchboard. Will be.

Therefore, the manager of the switchboard immediately overheats the busbar 1 through the alarm sound or the alarm light generated from the alarm 12 (ie, through hearing or vision) without opening the door installed in the switchboard enclosure. By recognizing the status and taking necessary measures in a short time, it is possible to manage the switchgear more efficiently by preventing power interruption and fire caused by overheating of the busbar.

In addition, in the above, the superheat temperature T3 for driving the alarm 12 is also any temperature between 75 and 90 degrees in view of the fact that the busbar itself is an aluminum-copper busbar, an aluminum alloy or aluminum as described above. The above was set.

In addition, although not shown in the drawing, the computer 15 or the manager portable computer 17 of the remote central monitoring room also includes an administrator who is standing near the central monitoring room when the alarm driving function according to the above-described overheating temperature is added. The manager who is carrying the portable computer 17 and is moving also recognizes when the bus bar 1 installed in a specific switchgear is overheated above a predetermined temperature (T3) by hearing or vision and takes a corresponding action. It can be taken in a short time.

Meanwhile, the bus bar 1 applied in the present invention inserts an aluminum bar 102 extruded to have a rectangular bar shape in the inside of the copper pipe 101 extruded to have a square pipe shape, and then draws the same. It has a rectangular bar shape and has a constitution molded integrally.

In this case, when the bus bar 1 is simply formed to have a rectangular bar shape, the area of the outer circumferential surface of the bus bar that is in direct contact with air and that performs heat radiation may have a small heat dissipation effect.

Therefore, in the present invention, as shown in FIG. 2, a plurality of heat dissipation grooves 103 are formed in the longitudinal direction at regular intervals from the upper and lower surfaces of the bus bar 1, or as shown in FIG. On the right side, a plurality of heat dissipation grooves 103 are formed at regular intervals in the longitudinal direction or as shown in FIG. It was formed at regular intervals.

Therefore, the outer circumferential surface area of the busbar 1 becomes larger as corresponding to several heat generating grooves 103 formed on the upper, lower surface, the left, the right side, or the slope, so that the air contact surface of the busbar 1 can be increased by that much. Therefore, the heat dissipation efficiency of the busbar itself can be increased.

In the above description, the heat dissipation area is most wide when the heat dissipation grooves 103 are formed in all of the top, bottom, left and right sides of the bus bar 1 as shown in FIG. In the case of forming a plurality of heat dissipation grooves 103 on the upper and lower surfaces of (1), the case of the smallest heat dissipation area is the number of heat dissipation grooves 103 on the left and right sides of the bus bar 1 as shown in FIG. This is the case.

Accordingly, when the heat dissipation groove 103 is to be formed on the outer circumferential surface of the bus bar 1 during the design of the bus bar or during the manufacture of the bus bar, the purpose or installation position of the bus bar 1, or Considering the total volume of the busbar itself, including the magnitude of the supply voltage and the amount of current to flow through it, the appropriate position and number, etc., may be determined and drawn.

Further, when the heat dissipation groove 103 is formed on the top, bottom, left, right, or four sides of the busbar 1, the positive cross section has a "∨" shape, a "∧" shape, a "∪" shape, and a "∩" shape. "Although it may be formed in a shape, in the present invention, in order to maximize the heat dissipation area of the heat dissipation groove 103 itself, the heat dissipation efficiency of the bus bar 1 itself is formed to have a" T "shape and a" ⊥ ". It can be greatly increased.

Although the above-described embodiments have been described with respect to the most preferred embodiments of the present invention, it is not limited to the above embodiments, and it will be apparent to those skilled in the art that various modifications can be made without departing from the technical spirit of the present invention.

1 is a block diagram of the present invention.

2 to 4 is a perspective view of the busbars applied in the present invention.

Explanation of symbols on the main parts of the drawings

1: busbar 2: insulator

3: insulator fixture 4: reference temperature setting section

5: temperature detection sensor 6: A / D converter

7: microcomputer 8: PTC drive unit

9: timer 10: PTC

11: alarm signal generator 12: alarm

13: overheat temperature setting unit 14: embedded server

15: Surveillance computer 16: Server or storage device

17: laptop 101: copper pipe

102: aluminum bar 103: heat dissipation groove

Claims (12)

In constructing a busbar for switchgear with overheat protection and remote monitoring, A reference temperature setting unit for allowing a user to set whether to drive the thermoelectric element PTC when the temperature of the busbar reaches a certain temperature T1; A temperature detection sensor installed between the top of the insulator and the bottom of the coupling part of the busbar to detect the temperature of the busbar in real time; An A / D converter for converting the temperature of the busbar detected as an analog signal through the temperature detection sensor into a digital signal; A microcomputer for outputting a thermoelectric element driving signal to the PTC driver when the temperature of the bus bar input through the A / D converter is higher than a set temperature set by the user; A PTC driver configured to supply a driving voltage to the PTC only for a predetermined time when the PTC driving signal is output from the microcomputer, and to control driving of the thermoelectric element in response to the output signal of the microcomputer; Cold air is generated on one surface and heat is generated on the other surface according to the supply direction of the DC voltage, and is installed between the bottom surface of the insulator and the top surface of the insulator fixture to be driven in response to the output signal of the PTC drive unit. A thermoelectric element (PTC) for generating cold air to prevent overheating of the busbar; It is installed in the switchgear board and receives the monitoring data for the various components including the temperature change data of the busbar through the microcomputer and stores it and outputs it when the request of the microcomputer; The busbars are integrally formed to have a rectangular bar shape through drawing by inserting an aluminum bar extruded to have a rectangular bar shape into the inside of the copper pipe extruded to have a rectangular pipe shape. Booth bar for switchboard with function. The method according to claim 1, The built-in server is connected to the computer of the remote central monitoring room through wired and wireless communication lines so that the remote monitoring room can receive various status information in the switchboard in real time, as well as the server installed in the monitoring room computer itself. Or a bus bar for switchgear with overheating prevention and remote monitoring, characterized in that it can be stored in the storage device. The method according to claim 1, The built-in server allows the administrator to communicate in real time with the portable computer carried by the administrator through wired and wireless communication lines so that the administrator can receive various status information in the switchboard in real time regardless of the place. Switchgear bus bar with overheat protection and remote monitoring. The method according to claim 1, In the reference temperature setting unit, a lower limit temperature for stopping the operation of the thermoelectric element when the temperature of the busbar drops below which temperature during the operation of the thermal element (PTC) when the busbar temperature reaches the set temperature. A function of allowing the user to set T2 is added, and if the temperature of the busbar is higher than the user's set temperature T1, the microcomputer outputs a thermoelectric element driving signal to the PTC driving unit, and is less than the lower limit temperature T2. Bus bar for switchgear with overheat protection and remote monitoring, characterized in that for generating a blocking signal. delete The method according to claim 1, The input terminal of the microcomputer is provided with an overheat temperature setting unit for setting the overheat temperature (T3) according to whether the user will recognize the overheat when the temperature of the busbar rises above, and the alarm signal to the output terminal of the microcomputer An additional generation unit is provided so that the microcomputer drives the alarm through the alarm signal generation unit when the temperature of the busbar rises above the overheat temperature set by the user even though the thermoelectric element is being driven. Switchgear busbar with prevention and remote monitoring. The method according to claim 6, The alarm device is a bus bar for switchgear having overheat protection and remote monitoring function, characterized in that it comprises a buzzer for generating an alarm sound or an alarm light for generating an alarm light. The method according to claim 4, The driving temperature T1 of the thermoelectric element PTC set by the reference temperature setting unit is any temperature between 50 and 70 degrees, and the lower limit temperature T2 that blocks driving of the thermoelectric element PTC is 50 degrees. Bus bar for switchgear with overheat protection and remote monitoring, characterized in that less than. The method according to claim 6 Overheat temperature (T3) set by the overheat temperature setting unit is a bus bar for switchgear with overheat prevention and remote monitoring, characterized in that more than one temperature between 75-90 degrees. delete The method according to claim 1, A bus bar for a distribution board having an overheat prevention function, characterized in that a plurality of heat dissipation grooves are formed in a longitudinal direction at regular intervals on the top, bottom or left and right sides of the bus bar having a rectangular bar shape. The method according to claim 1, Busbar for switchgear having an overheating prevention function, characterized in that formed in the longitudinal direction of the plurality of heat dissipation grooves in the longitudinal direction on all the top, bottom, left, right side of the bus bar having a rectangular bar shape.

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