KR20080034764A - Apparatus for controlling trip of power breaker and method therefor - Google Patents

Abstract

An apparatus and a method for controlling trip of a power breaker are provided to accurately measure the amount of remaining heat by simulating data for the amount of heat of a line and a load, and an elapsed time by using the heat management unit such as an RTC(Real Time Counter) element. An apparatus(100) for controlling trip of a power breaker includes a break switch(110), a current sensor(130), a heat management unit(150), and a microprocessor(170). The break switch is provided on a current path along which an external power is supplied to a load and breaks the power supplied to the load through a trip coil(190). The current sensor is provided at a rear end of the break switch and senses a current supplied to the load. The heat management unit stores externally received heat amount data in matching with a time on which data about the amount of heat is transferred for the stored data to be maintained by power received from a battery in power-off. The microprocessor calculates the amount of heat of a load system due to an overcurrent during a predetermined trip delay time.

Description

Trip control device of circuit breaker and its method {APPARATUS FOR CONTROLLING TRIP OF POWER BREAKER AND METHOD THEREFOR}

The present invention relates to a trip control device of a circuit breaker, and more particularly, to manage calorie related data through a calorific management unit that operates even when the power is cut off, and when an overcurrent occurs, using a calorific value and an elapsed time stored in the calorific value management unit. The present invention relates to a trip control device and a method of a circuit breaker for variably determining a trip delay time of a circuit breaker by analyzing the residual heat remaining in the circuit.

1 is a circuit diagram showing a trip control device of a circuit breaker according to the prior art.

The trip control device 10 includes a disconnect switch 11 and a current sensor 12, a switch unit 13, a diode D1, a charging circuit unit 14, a voltage follower circuit unit 15, and a microprocessor 16. Consists of

The cutoff switch 11 is configured to cut off the power supplied to the load by the trip coil 17 is installed on the line supplied with the external power to the load.

The current sensor 12 is installed in a line between the cutoff switch 11 and the load is configured to detect the current supplied to the load. In addition, the current sensor 12 detects the current supplied to the load, but also obtains and supplies the operating power of the circuit breaker from the line.

The switch unit 13 is turned on to receive a control signal output from the microprocessor 16 during a trip delay time when the current detected by the current sensor 12 is overcurrent, so that the current of the power supply terminal VCC through the resistor is turned on. And a transistor Q1 that interrupts the path to flow.

Diode D1 is configured to prevent current from flowing in the reverse direction when the transistor Q1 is turned on.

The charging circuit unit 14 charges the voltage by the power current flowing through the current path of the transistor Q1, and is charged when the cutoff switch 11 is opened, that is, when the power supply voltage is not supplied through the transistor. The capacitor C1 discharges the voltage to the ground voltage through the first resistor R1.

The voltage follower circuit unit 15 is configured to provide the microprocessor 16 with the magnitude of the voltage remaining in the capacitor C1 of the charging circuit unit 14 when the open disconnect switch 11 is closed again.

The microprocessor 16 controls the switch unit 13 during the trip delay time set when the current detected by the current sensor 12 is overcurrent to charge the power supply voltage to the charging circuit unit 14 and set the trip delay time. When the elapsed time, the trip coil 17 is controlled to open the cutoff switch 11, and when the power is supplied again after a certain time, the residual voltage remaining in the charging circuit unit 14 is calculated to calculate the residual voltage on the line based on the residual voltage. It is configured to estimate residual calories.

In the conventional trip control method configured as described above, first, when the current detected by the current sensor 12 is an overcurrent, the microprocessor 16 controls the switch unit 13 to turn on. Accordingly, the current of the power supply terminal VCC flows through the switch unit 13 to the capacitor C1 of the charging circuit unit 14, and the capacitor C1 is connected to the time constant determined by the first resistor R1. As a result, charging starts.

Subsequently, when the set trip delay time elapses, the microprocessor 16 controls the trip coil 17 to open the cutoff switch 11.

When the cutoff switch 11 is opened, the power supply voltage VCC is no longer charged to the capacitor C1 of the charging circuit unit 14, and the charged voltage gradually begins to discharge through the first resistor R1.

On the other hand, the microprocessor 16 of the circuit breaker is operated by using the power obtained through the current sensor 12. When the current supplied to the load is an overcurrent or a short-circuit state, the microprocessor 16 may trip the coil (17). By automatically opening the cutoff switch 11 through) it can no longer be operated because the operation power can not be supplied.

Thereafter, when the cutoff switch 11 is closed according to the user's operation and the operating power is supplied to the breaker again, the microprocessor 16 checks whether an overcurrent is introduced into the load through the current sensor 12. When the overcurrent is detected again, the microprocessor 16 reads the voltage remaining in the capacitor C1 through the voltage follower circuit unit 15.

Based on the values read above, the microprocessor 16 calculates the elapsed time since the disconnect switch 11 is opened. The remaining voltage is calculated based on the previously stored data table according to the calculated elapsed time, and the amount of heat remaining on the current device and the line is determined based on the calculated remaining voltage.

The prior art operating in this way has to calculate the slope of the discharge curve of the voltage stored in the capacitor to calculate the current voltage, elapsed time and residual heat, it is difficult to calculate the exact residual heat, and expensive expensive components must be used There was this rising issue.

In addition, since the capacitor of the charging circuit part must be maintained for up to 30 minutes in a state where the power is cut off, there is a problem in that a manufacturing cost increases because a bulky component having a fairly large capacitor and a resistance value must be used.

In addition, once the charged circuit is to be discharged to reduce the current, the circuit becomes complicated, such as additional components are added, there is a problem in that the control is inconvenient and complicated in hardware and software.

The present invention was devised to solve the problems of the prior art as described above, and an object of the present invention is to manage calorie related data through a calorie management unit operating even when the power is cut off, and the calorific value and elapsed value stored in the calorie management unit when an overcurrent occurs By analyzing the residual heat remaining in the current line by using the time, the trip delay time of the breaker is variably determined, and the breaker switch is quickly controlled according to the heat state remaining in the current load system. The present invention provides a trip control device and a method of a circuit breaker to reduce damage of overload.

The trip control device of the present invention for achieving the above object is provided with a current switch to the external power supply to the load is cut off the switch to cut off the power supplied to the load by the trip coil; A current sensor installed at a rear end of the cutoff switch and sensing a current supplied to a load; Stores the calorie data transmitted from the outside in accordance with the time when the calorie data is delivered, but maintains the stored data by receiving the power supplied from the battery when the power is cut off, and the stored calorie data and the calorie data at the external request and Calorie management unit for transmitting calorie-related data including the current time; And when the current input from the current sensor is an overcurrent, calculates the heat quantity of the load system due to the overcurrent during the set trip delay time, transfers the calculated calorie data to the calorie management unit, and trips the power supplied to the load to be cut off. And a microprocessor for controlling the coil, calculating an amount of residual heat based on calorie-related data stored in the calorific value management unit when an overcurrent is detected again after the power is again supplied, and determining a trip delay time based on the calculated residual calorific value. It features.

The breaker is characterized in that the low voltage breaker to operate by receiving the operating power through the current sensor.

The calorie management unit may include: a memory configured to store calorie data transferred from the microprocessor and a time at which calorie data is transferred; And checking and storing the calorie data and the calorie data delivered from the microprocessor in the memory, and checking the time and the current time of the calorie data and calorie data stored in the memory upon request of calorie-related data of the microprocessor. It characterized in that it comprises a;

The time at which the calorie data is transmitted is approximately the same as the time when the operating power of the microprocessor is removed, and the current time is approximately the same as the time when the overcurrent is detected secondarily.

The microprocessor controls the trip coil so that the power supplied to the load is cut off when the calculated calorie data is greater than or equal to a set value.

The trip control method of the present invention for achieving the above object, the step of calculating the amount of heat of the load system due to the overcurrent during the set trip delay time when the current detected by the microprocessor through the current sensor is an overcurrent; Controlling the calculated calorie data to be stored in the calorie management unit, and cutting off the power supplied to the load by controlling a trip coil if the calorie data is greater than or equal to a set value; When the power is cut off, the calorie management unit maintains the stored calorie data and the information on the time at which the calorie data is transferred according to the power applied from the battery; If an overcurrent is detected again after the interrupted power is supplied again, the microprocessor receives calorie related data from a calorie management unit and calculates residual calorific value of the load system; And variably determining a set trip delay time based on the calculated residual heat amount.

When the power is cut off, the power supplied to the microprocessor is cut off.

The microprocessor calculates the elapsed time from which the calorie data is stored in the calorie management unit, obtains residual calories, or calculates the elapsed time of the calorie data stored in the calorie management unit, and then calculates the elapsed time of the calorie data from the calorie management unit, and then calculates the elapsed time of the calorie data through the prestored reference table. It is characterized in that to obtain the residual heat by searching for.

As described above, the trip control method according to the present invention simulates data on calories and elapsed time of a line and a load during overcurrent by using a calorific control unit such as an RTC element, thereby more precisely measuring residual calories. The error that occurs when the analog device is implemented can be minimized, and the circuit can be simplified to achieve more reliable and accurate operation in a continuous overcurrent failure situation.

Hereinafter, a trip control device of a circuit breaker according to the present invention and a preferred embodiment of the method will be described in detail with reference to FIGS.

Figure 2 is a block diagram showing a trip control device of the circuit breaker according to an embodiment of the present invention, the circuit breaker 100 is a disconnect switch 110, the current sensor 130, the heat management unit 150, microprocessor 170 and It consists of a trip control device including a trip coil 190.

The cutoff switch 110 is configured to cut off the power supplied to the load by the trip coil 190 is installed on the line supplied with the external power to the load.

The current sensor 130 is installed on the line between the cutoff switch 110 and the load is configured to detect the current supplied to the load. In addition, the current sensor 130 detects the current supplied to the load, but also obtains and supplies the operating power of the circuit breaker from the line.

The calorie management unit 150 stores the calorie data transmitted from the microprocessor 170 in accordance with the time at which the calorie data is delivered, and maintains the stored data by receiving the power supplied from the battery 160 when the power is cut off. At the request of 170, the calorie-related data including the stored calorie data and the time at which the calorie data is delivered and the current time is transmitted to the microprocessor 170. The calorie management unit 150 may be configured using a conventional RTC (Real Time Counter) device.

The calorie management unit 150 includes a memory 155 and a time controller 151. The memory 155 stores the calorie data transferred from the microprocessor 170 and the time at which the calorie data is transferred. The time controller 151 checks the calorie data transmitted from the microprocessor 170 and the time at which the calorie data is delivered to the memory 155 and requests the calorie-related data of the microprocessor 170. The calorie data and the calorie data stored in the memory 155 are configured to check and deliver the time and the current time.

In addition, the time controller 151 calculates and obtains time using a clock signal generated through a predetermined crystal oscillator.

When the current detected by the current sensor 130 is an overcurrent, the microprocessor 170 accumulates the calorific value of the load system due to the overcurrent during a preset trip delay time, and then calculates the calorie data calculated by the calorific management unit 150. In addition, when the calculated calorie data is greater than or equal to the set value, the trip coil 190 is controlled so that the power supplied to the load is cut off. When the microprocessor 170 receives the operating power through the current sensor 130 and the cutoff switch 110 is opened and the power is cut off, the microprocessor 170 may not receive the operating power through the current sensor 130 to operate. It becomes impossible.

When the external power is supplied again through the current sensor 130, the microprocessor 170 detects the current through the current sensor 130 again, and when the overcurrent is detected again, the heat related data stored in the calorific management unit 150. It is configured to calculate the residual heat of the load system and to determine the set trip delay time based on the calculated residual heat.

The microprocessor 170 calculates the residual heat amount by checking the elapsed time of the calorie data, and sets a shorter trip delay time as the residual heat amount increases. The large amount of residual heat indicates that the load system is still overheated due to the previous overcurrent, so that the trip coil 190 is opened by controlling the trip coil 190 earlier than the trip delay time of normal operation (when the residual heat is zero). In order to protect the load system.

The calorie management unit 150 delivers calorie related data at the request of the microprocessor 170. The calorie related data includes a calorie data, a time at which calorie data is transferred, and a current time.

The time at which the microprocessor 170 delivers the calorie data to the calorie management unit 150 is approximately the same as the time at which the operating power of the microprocessor 170 is removed, and the calorie management unit 150 transmits the calorie data to the microprocessor 170. The current time is approximately equal to the time when the overcurrent was detected secondarily.

On the other hand, the microprocessor 170 controls the trip coil 190 to open the cutoff switch 110 only when the calorie data of the load system calculated during the trip delay time is greater than or equal to a set value. Of course, when the calorie data of the load system calculated during the trip delay time is less than or equal to the set value, the cutoff switch 110 is not opened.

In addition, for convenience of description, the microprocessor 170 calculates calorie data and stores the calorie data when the overcurrent flows, but stores the calorie data in the calorific management unit 150, but the current detected by the current sensor 130 is set in advance. Even if it does not exceed, it is preferable to periodically store calorie data and store calories in the calorie management unit 150. If more than 110% of the rated current is called an overcurrent, the range of 90% to 109% close to the rated current may cause deterioration of the load or line, and thus need to be stored periodically.

The trip control apparatus 100 according to the present invention can be applied to a circuit breaker that receives operating power through a current sensor 130 or a current inductor built in the current sensor, and is particularly useful when applied to a low voltage circuit breaker.

The overall operation of the trip control device configured as described above will be described using the flowcharts of FIGS. 3A and 3B.

First, the breaker 100 operates by receiving operating power from the current sensor 130 side. Here, the current sensor 130 may be any sensor such as a current transformer, a Rogowski, and a shunt.

Subsequently, the microprocessor 170 of the circuit breaker 100 detects a current supplied to the load through the current sensor 130, and determines whether the detected current is an overcurrent (S1).

When the detected current is the overcurrent, the microprocessor 170 accumulates and calculates the amount of heat according to the overcurrent generated in the line and the load system during the preset trip delay time (S2). The calorific value Q is obtained by calculating (Q = I ² × T) the duration T of the current I during the trip delay time.

Subsequently, when the trip delay time elapses, the microprocessor 170 transmits the calculated calorie data to the calorie management unit 150 and determines whether the calculated calorie data exceeds a preset reference value (S3).

Subsequently, when the trip delay time elapses and the calorie data exceeds the reference value, the microprocessor 170 controls the trip coil 190 to open the cutoff switch 110 to cut off the power supplied to the load. (S4). When the cutoff switch 110 is opened, the microprocessor 170 is in a state in which it cannot operate because the operating power is not supplied through the current sensor 130.

Meanwhile, the time controller 151 of the calorie management unit 150 receives the calorie data transmitted from the microprocessor 170, checks the time at which the calorie data is transferred, and checks the time at which the calorie data and the calorie data are transferred to the memory 155. ) Is stored in (S5).

Subsequently, when the operation power is cut off according to the opening of the cutoff switch 110, the calorific value management unit 150 receives power applied from the battery 160, which is an auxiliary power supply means, and calories data and calories stored in the memory 155. Information about the time at which the data is delivered is maintained (S6). The calorie management unit 150 is normally operated by receiving the power supplied through the current sensor 130, but is configured to automatically supply the power of the battery 160 to the calorie management unit 150 when the power is cut off.

Then, when the cutoff switch 110 is closed again according to the user's action, the microprocessor 170 of the breaker is operated by receiving operating power from the current sensor 130 side. Of course, the calorie management unit 150 is also automatically operated by receiving the operating power from the current sensor 130 side.

Subsequently, the microprocessor 170 of the circuit breaker detects the current supplied to the load through the current sensor 130 again, and determines whether the detected current is an overcurrent (S7).

If the detected current is the overcurrent, the microprocessor 170 requests the transfer of the calorie-related data stored in the calorific management unit 150 (S8).

Accordingly, the time controller 151 of the calorie management unit 150 checks the calorie data stored in the memory 155 and the time and current time at which the calories are transferred to the microprocessor 170 (S9).

Subsequently, the microprocessor 170 receives calorie data from the calorie management unit 150 and calorie related data including a time at which the calorie data is transmitted and a current time, and calculates residual calories of the line and the load system (S10). The residual calories are obtained by calculating the elapsed storage time of the calorie data through the time at which the calorie data is transferred and the current time.

Of course, the microprocessor 170 may calculate the elapsed time of the calorie data stored in the calorie management unit 150 and then obtain a residual calorie value by searching for a value corresponding to the calorie data and the elapsed time through a previously stored reference table. .

The microprocessor 170 obtains the residual heat amount as described above, and sets the trip delay time shorter as the residual heat amount increases. This is because the line and the load system are still overheated due to the previous overcurrent, so the trip delay time is set shorter than usual (that is, when the residual heat amount is zero), that is, as the breaker switch 110 is opened quickly. This is to protect the load system from deterioration or damage.

Subsequently, the microprocessor 170 variably determines the set trip delay time based on the calculated amount of residual heat (S11).

On the other hand, the microprocessor 170 calculates the amount of heat according to the overcurrent generated in the line and the load system during the trip delay time determined above (S12).

Subsequently, when the trip delay time elapses, the microprocessor 170 transmits the calculated calorie data to the calorie management unit 150 and determines whether the calculated calorie data exceeds a preset reference value (S13).

Subsequently, as the trip delay time elapses and the calorie data exceeds the reference value, the microprocessor 170 controls the trip coil 190 to open the cutoff switch 110 to cut off the power supplied to the load ( S14).

Meanwhile, the time controller 151 of the calorie management unit 150 receives the calorie data transmitted from the microprocessor 170, checks the time at which the calorie data is transferred, and checks the time at which the calorie data and the calorie data are transferred to the memory 155. ).

Subsequently, when the operation power is cut off according to the opening of the cutoff switch 110, the calorific management unit 150 receives power supplied from the battery 160 and the calorie data and the calorie data stored in the memory 155 are transferred. Information about is maintained (S15).

Then, if the overcurrent is detected again after the interrupted power is supplied again, the microprocessor 170 receives the calorie related data from the calorific management unit 150 to calculate the residual calorific value of the load system and based on the calculated residual calorific value. In this case, the process of variably determining the set trip delay time is repeatedly performed (S7 to S15).

As described above, the trip control method according to the present invention simulates data on the calories and elapsed time of the line and the load during overcurrent by using a calorific control unit such as an RTC element, thereby more precisely measuring the residual calories The trip operation can be performed.

The present invention has been described in detail with reference to exemplary embodiments, but those skilled in the art to which the present invention pertains can make various modifications without departing from the scope of the present invention. Will understand.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

1 is a circuit diagram illustrating a trip control apparatus of a circuit breaker according to the prior art.

2 is a block diagram illustrating a trip control apparatus of a circuit breaker according to an exemplary embodiment of the present invention.

3A and 3B are flowcharts illustrating a trip control process of a circuit breaker according to an exemplary embodiment of the present invention.

* Explanation of symbols for the main parts of the drawings

100: breaker 110: disconnect switch

130: current sensor 150: heat management unit

151: time controller 155: memory

160: battery 170: microprocessor

190: trip coil

Claims (11)

A cutoff switch installed in a current path through which external power is supplied to the load to cut off the power supplied to the load by the trip coil; A current sensor installed at a rear end of the cutoff switch and sensing a current supplied to a load; Stores the calorie data transmitted from the outside in accordance with the time when the calorie data is delivered, but maintains the stored data by receiving the power supplied from the battery when the power is cut off, and the stored calorie data and the calorie data at the external request and Calorie management unit for transmitting calorie-related data including the current time; And If the current input from the current sensor is overcurrent, the trip coil is applied to calculate the calorie of the load system due to the overcurrent during the set trip delay time and then transfer the calorie data to the calorific management unit and to cut off the power supplied to the load. A microprocessor for controlling the control unit and calculating an amount of residual heat based on the calorie-related data stored in the calorific management unit when an overcurrent is detected again after the power is supplied again, and determining a trip delay time based on the calculated residual calorie value. Trip control. The method according to claim 1, The circuit breaker trip control device of the circuit breaker, characterized in that the low voltage cut-off is operated by receiving the operating power through the current sensor. The method according to claim 1, wherein the calorie management unit, A memory for storing the calorie data transferred from the microprocessor and the time at which the calorie data was transferred; And Check the time when the calorie data and calorie data transferred from the microprocessor is stored in the memory, and when the calorie related data of the microprocessor is requested, the time and current time when the calorie data and calorie data stored in the memory are transferred and checked Trip control device of a circuit breaker comprising a; time control unit for transmitting. The method according to any one of claims 1 to 3, And the time at which the calorie data is transmitted is approximately equal to the time at which the operating power of the microprocessor is removed, and the current time is approximately equal to the time at which the overcurrent was detected secondarily. The method according to any one of claims 1 to 3, And the microprocessor calculates residual calories by checking elapsed time of calorie data. The method according to any one of claims 1 to 3, And the microprocessor controls the trip coil so that the power supplied to the load is cut off when the calculated calorie data is greater than or equal to a set value. Calculating a heat amount of the load system due to the overcurrent during the set trip delay time when the current detected by the microprocessor is an overcurrent; Controlling the calculated calorie data to be stored in the calorie management unit, and cutting off the power supplied to the load by controlling a trip coil if the calorie data is greater than or equal to a set value; When the power is cut off, the calorie management unit maintains the stored calorie data and the information on the time at which the calorie data is transferred according to the power applied from the battery; If an overcurrent is detected again after the interrupted power is supplied again, the microprocessor receives calorie related data from a calorie management unit and calculates residual calorific value of the load system; And And variably determining a set trip delay time based on the calculated residual heat amount. The method according to claim 7, When the power is cut off, the trip control method of the breaker, characterized in that the power supplied to the microprocessor is cut off. The method according to claim 7, The calorie-related data includes a calorie data, a time at which the calorie data is transmitted, and a current time. The method according to any one of claims 7 to 9, The microprocessor is a trip control method of a circuit breaker, characterized in that the calorie data is obtained by calculating the elapsed time stored in the calorie management unit. The method according to any one of claims 7 to 9, The microprocessor calculates the elapsed time of the calorie data stored in the calorie management unit, and then searches for a value corresponding to the calorie data and the elapsed time through a pre-stored reference table to obtain residual calories. .

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