KR20130052833A - Apparatus for protecting and detecting insulation breakdown - Google Patents

Abstract

PURPOSE: A dielectric breakdown protection and detection device is provided to solve the problem of durability decrease caused by an optical relay, and to figure out insulation properties between a high-voltage battery and a chassis as well as to prevent dielectric breakdown. CONSTITUTION: A dielectric breakdown protection and detection device(1) is composed of a connection part(10), a balancing bridge circuit part(20), a detection part(30), and a control part(40). The connection part is controlled by the control part and selectively connects a power signal generated from a high-voltage battery to the balancing bridge circuit part. The impedance value of the balancing bridge circuit part is adjusted in response to the inputted power signal, and the balancing bridge circuit part absorbs noise contained in the power signal up to a pre-set limit voltage value. The balancing bridge circuit part outputs a dielectric strength voltage, corresponding to dielectric strength, to the detection part. The detection part converts the inputted dielectric strength voltage into a digital signal and delivers to the control part. The control part monitors the dielectric strength voltage with the delivered signal, and controls the connection part by comparing the dielectric strength voltage with the pre-set limit voltage value. [Reference numerals] (40) Control part

Description

Apparatus for protecting and detecting insulation breakdown

The present invention relates to an insulation breakdown protection and detection apparatus, and more particularly, to an insulation breakdown protection and detection apparatus for preventing insulation breakdown and detecting insulation characteristics between a high voltage battery and a vehicle chassis.

Hybrid cars or electric vehicles use high voltage lithium batteries as energy storage devices. Lithium-based batteries are configured in series to optimize driving and are designed to have high voltages from 150V to 400V, depending on driving performance.

Here, in order to prevent insulation breakdown between the chassis and the high voltage battery, a method of measuring insulation resistance between the high voltage battery and the vehicle chassis has been generally used in the design of a vehicle.

For example, conventionally, a technique of measuring insulation resistance between a high voltage battery and a vehicle chassis using a circuit as shown in FIG. 1 has been used. Insulation resistance can be measured by measuring the resistance between the positive and negative parts of the battery and between the negative and chassis parts of the battery.

That is, the positive relay is turned ON, and the negative relay is turned OFF, so that " V1 = R2 / ((R1 + R2 + R _iso1 ) × Vbat) " The resistance (R _iso1 ) between the anode part and the chassis is obtained, and the cathode part is switched off and the cathode part is turned on, and " V2 = R4 / ((R3 + R4 + R _iso2 ) × Vbat) " Insulation resistance can be measured by measuring the resistance (R _iso2 ) between the cathode portion and the chassis by the same equation.

However, the measurement of the insulation resistance between the high voltage battery and the vehicle chassis in the related art has a problem that the durability of the optical relay is inferior because the anode switch and the cathode switch continue to perform on / off operation. As a result, the insulation may be broken.

In addition, the related art merely has a function of simply measuring insulation resistance, and does not have a function for preventing insulation breakdown, and merely performs measurement of insulation resistance.

KR 10-2007-0052803 A, May 23, 2007 Drawing 1

An object of the present invention is to improve the configuration for measuring the conventional insulation resistance, to solve the problem of degradation of durability by the optical relay, to determine the insulation characteristics between the high voltage battery and the chassis, and at the same time to prevent breakdown insulation And a detection device.

The present invention for achieving the above object relates to an insulation breakdown protection and detection device for preventing insulation breakdown between the high voltage battery and the chassis and to detect insulation characteristics, the present invention is an insulation breakdown protection and detection device for generating power from the high voltage battery A connection unit for selectively connecting a signal; A balancing bridge circuit for absorbing noise included in the power signal and outputting an insulation breakdown voltage corresponding to the dielectric breakdown strength until an impedance value is adjusted in response to the power signal input through the connection unit to a predetermined threshold voltage value. ; A detector converting the dielectric strength voltage output by the balancing bridge circuit into a digital signal; And a controller configured to control the connection unit to block the connection of the high voltage battery and the balancing bridge circuit unit when the limit voltage value is reached by monitoring the dielectric strength voltage converted by the detection unit. .

The connection part includes a first relay connected to the '+' electrode of the high voltage battery and a second relay connected to the '-' electrode of the high voltage battery, which are switched by the controller, and the balancing bridge circuit part includes the first relay. A first input node connected to the '+' electrode through a first relay, a second input node connected to the '-' electrode through the second relay, and a first end connected to the first input node, respectively; A first output node formed at a portion where a first inductor and a first resistor, one end of the second inductor and the second resistor connected to the second input node, and the other end of the first inductor and the other end of the second inductor are connected. And a second output node formed at a portion where the other end of the first resistor and the other end of the second resistor are connected and connected to a ground potential, wherein the first output node and the second output node are connected to the detection unit. Section above May output the voltage strength.

When the value of the insulation strength voltage monitored by the controller does not reach the threshold voltage value, the power signal input through the first input node is absorbed so that the noise included in the power signal is absorbed. And the power signal circulated through the second inductor and the second input node, and when the value of the dielectric strength voltage reaches the threshold voltage value, the power signal input through the first input node is connected to the first resistor. It may be circulated through the second resistor and the second input node.

In addition, the threshold voltage value may be set by adjusting specifications of the passive elements, which are the first inductor, the second inductor, the first resistor, and the second resistor, to prevent insulation breakdown. Here, the specification of the passive element, the magnitude of the product of the impedance value of the first inductor and the impedance value of the second resistor, the magnitude of the product of the impedance value of the second inductor and the impedance value of the first resistor is the same. It is set so that, the impedance value of the second resistor may be provided as a variable resistor controlled by the controller.

Here, the second resistance may be adjusted by the controller such that the insulation resistance voltage output through the first output node and the second output node becomes substantially '0V' during initial setting.

As described above, the present invention absorbs the noise included in the power signal and measures the value corresponding to the dielectric strength voltage until the preset threshold voltage value is adjusted according to the input power signal. It solves the problem of deterioration of durability by relay, and understands the insulation characteristics between high voltage battery and chassis and prevents breakdown.

In addition, the present invention monitors the dielectric strength voltage, and when the value of the dielectric strength voltage does not reach the limit voltage value, it is possible to provide a power signal with noise canceled to the electric load, and the value of the dielectric strength voltage is the threshold voltage value. When it reaches, the breakdown of the high voltage battery and the balancing bridge circuit can be prevented.

1 is a circuit diagram of a conventional dielectric breakdown protection and detection apparatus.
2 is a circuit diagram of a dielectric breakdown protection and detection apparatus according to an embodiment of the present invention.
3 is a view for explaining the design conditions of the balancing bridge circuit according to an embodiment of the present invention.

Hereinafter, a dielectric breakdown protection and detection apparatus according to an embodiment of the present invention will be described with reference to the accompanying drawings.

2 is a circuit diagram of a dielectric breakdown protection and detection apparatus according to an embodiment of the present invention. As shown in FIG. 2, the insulation breakdown protection and detection device 1 is a device for preventing insulation breakdown between a high voltage battery and a chassis and detecting insulation characteristics. The connection part 10, the balancing bridge circuit part 20, and the detection part 30 and the controller 40 may be provided.

The connection unit 10 is controlled by the control unit 40 to selectively connect the power signal generated from the high voltage battery to the balancing bridge circuit unit 20. The connection unit 10 may include a first relay 12 and a second relay 14 that are switched by the control of the controller 40. The first relay 12 may be connected to the '+' electrode of the high voltage battery, and the second relay 14 may be connected to the '-' electrode of the high voltage battery.

The balancing bridge circuit 20 may absorb the noise included in the power signal up to a preset threshold voltage value by adjusting an impedance value in response to the power signal input through the connection unit 10. In addition, the balancing bridge circuit 20 may output an insulation strength voltage corresponding to the dielectric breakdown strength to the detector 30.

Specifically, referring to FIG. 2, the balancing bridge circuit 20 may include the first input node 22 connected to the '+' electrode through the first relay 12 and the second relay 14 through the first input node 22. And a second input node 24 connected to the '-' electrode.

In addition, the balancing bridge circuit 20 may include a first inductor L1 and a first resistor R1 having one end connected to the first input node 22 and a first end connected to the second input node 24, respectively. And a second inductor L2 and a second resistor R2.

In addition, the balancing bridge circuit 20 includes a first output node 26 formed at a portion where the other end of the first inductor L1 and the other end of the second inductor L2 are connected, and the other end and the second end of the first resistor R1. A second output node 28 formed at a portion to which the other end of the resistor R2 is connected and connected to a ground potential, and a first output node 26 and a second output node 28 are connected to the detection unit 30. It is connected and outputs insulation strength voltage.

Here, the power signal input through the first input node 22, when the value of the dielectric strength voltage monitored by the controller 40 does not reach the limit voltage value, so that the noise contained in the power signal is absorbed, It is circulated through the first inductor L1, the second inductor L2, and the second input node 24.

On the other hand, when the value of the dielectric strength voltage monitored by the control unit 40 reaches the threshold voltage value, the power signal input through the first input node 22 is the first resistor (R1), the second resistor (R2) ) And the second input node 24.

In this case, the control unit 40 may control the connection unit 10 to block the connection of the high voltage battery and the balancing bridge circuit unit 20.

Here, the threshold voltage value may be set by adjusting the specifications of the passive elements, which are the first inductor L1, the second inductor L2, the first resistor R1, and the second resistor R2, to prevent breakdown. have.

The specification of the passive element may include a magnitude of a product of an impedance value of the first inductor L1 and an impedance value of the second resistor R2, an impedance value of the second inductor L2, and an impedance value of the first resistor R1. The size of the product of is set to be the same. Here, the second resistor R2 may be provided as a variable resistor whose impedance value is controlled by the controller 40, and is output through the first output node 26 and the second output node 28 at initial setting. The dielectric strength voltage may be adjusted by the controller 40 to be approximately '0V'.

Meanwhile, the power signal input through the first input node 22 is input through the first input node 22 when the value of the insulation strength voltage monitored by the controller 40 reaches the limit voltage value. The power signal is circulated through the first resistor R1, the second resistor R2, and the second input node 24.

3 is a circuit diagram for explaining the principle of the balancing bridge circuit 20 according to the present embodiment. In this case, the first inductor L1 corresponds to 'Z1', the second inductor L2 corresponds to 'Z2', the first resistor R1 corresponds to 'Z3', and the second resistor R2 corresponds to 'Z4'. Withstand voltage corresponds to 'V _G '.

The impedance elements of FIG. 3 must satisfy the following Equations 1 and 2 in order to satisfy the design conditions of the balancing bridge circuit 20 above.

The detector 30 illustrated in FIG. 2 converts the dielectric strength voltage output by the balancing bridge circuit 20 into a digital signal that can be processed by the controller 40 and transmits the converted digital signal to the controller 40.

The controller 40 may monitor the insulation strength voltage by the signal transmitted from the detector 30, and control the connection unit 10 as described above by comparing the monitored insulation strength voltage with a preset threshold voltage value. . In addition, the controller 40 may adjust the impedance value of the second resistor R2 to form an appropriate dielectric strength voltage.

As described above, the insulation breakdown protection and detection device 1 according to the present embodiment monitors the dielectric breakdown voltage, and provides a power signal with noise canceled to the electric load when the dielectric breakdown voltage does not reach the limit voltage value. When the value of the dielectric strength voltage reaches the threshold voltage value, the breakdown of the high voltage battery and the balancing bridge circuit 20 may be cut off.

1: Breakdown protection and detection device
10: connection
12: first relay
14: second relay
20: balancing bridge circuit
22: first input node
24: second input node
26: first output node
28: second output node
30: detection unit
40:

Claims (6)

In the insulation breakdown protection and detection device for preventing insulation breakdown between high voltage battery and chassis and detecting insulation characteristics,
A connection unit for selectively connecting the power signal generated from the high voltage battery;
A balancing bridge circuit for absorbing noise included in the power signal and outputting an insulation breakdown voltage corresponding to the dielectric breakdown strength until an impedance value is adjusted in response to the power signal input through the connection unit to a predetermined threshold voltage value. ;
A detector converting the dielectric strength voltage output by the balancing bridge circuit into a digital signal; And
A controller configured to control the connection unit to block the connection of the high voltage battery and the balancing bridge circuit unit when the threshold voltage value is reached by monitoring the dielectric strength voltage converted by the detector;
Breakdown protection and detection apparatus comprising a. The method of claim 1,
The connection part includes a first relay connected to the '+' electrode of the high voltage battery and a second relay connected to the '-' electrode of the high voltage battery, switched by the controller.
The balancing bridge circuit unit includes a first input node connected to the '+' electrode through the first relay, a second input node connected to the '−' electrode through the second relay, and one end of the first input node. A first inductor and a first resistor connected to an input node, respectively, a second inductor and a second resistor connected to the second input node, respectively, and the other end of the first inductor and the other end of the second inductor are connected to each other. A first output node formed at a portion, and a second output node formed at a portion to which the other end of the first resistor and the other end of the second resistor are connected and connected to a ground potential, wherein the first output node and the second output are provided. Breakdown protection and detection device, characterized in that the node is connected to the detection unit to output the dielectric strength voltage. The method of claim 2,
When the value of the insulation strength voltage monitored by the controller does not reach the threshold voltage value, the power signal input through the first input node is absorbed so that the noise included in the power signal is absorbed. And circulated through the second inductor and the second input node,
When the value of the dielectric strength voltage reaches the threshold voltage value, the power signal input through the first input node is circulated through the first resistor, the second resistor, and the second input node. Breakdown protection and detection equipment. The method of claim 2,
The threshold voltage value is set by adjusting specifications of the passive elements, which are the first inductor, the second inductor, the first resistor, and the second resistor, so as to prevent breakdown. Detection device. 5. The method of claim 4,
The specification of the passive elements may be such that the magnitude of the product of the impedance value of the first inductor and the impedance value of the second resistor is equal to the magnitude of the product of the impedance value of the second inductor and the impedance value of the first resistor. Is set,
Insulation destruction protection and detection apparatus, characterized in that the impedance of the second resistor is a variable resistor controlled by the control unit. The method of claim 5,
The second resistor is controlled by the control unit so that the insulation resistance voltage output through the first output node and the second output node is set to '0V' during initial setting. .

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