JP6448077B2 - Voltage detector - Google Patents

Description

  The present invention relates to a voltage detection device that insulates and transmits information related to a voltage of a first electronic device that operates based on a first ground to a second electronic device that operates based on a second ground that is insulated from the first ground. .

  2. Description of the Related Art Conventionally, an apparatus having a voltage detection device that transmits information related to a voltage of a first electronic device that operates with a first ground as a reference to a second electronic device that operates with a second ground that is insulated from the first ground as a reference. For example, there is a power conversion system disclosed in Patent Document 1 shown below.

  This power conversion system includes a converter circuit, a voltage dividing circuit, a differential amplifier circuit, a microcomputer, and an interface circuit.

  The converter circuit operates with the high-voltage ground as a reference, and boosts and outputs the voltage of the high-voltage battery. The converter circuit is controlled by a microcomputer that operates based on a low-voltage ground that is insulated from the high-voltage ground.

  The voltage dividing circuit is a circuit that is connected to the power input end and the power output end of the converter circuit and insulates and divides the input / output voltage of the converter circuit. The voltage dividing circuit includes a high resistance body and a low resistance body. The high resistance body is a resistance having a resistance value of several MΩ. The high resistance body is configured by connecting a plurality of resistors in series. On the other hand, the low resistance body is a resistance having a resistance value of several kΩ. By using a high resistance body of several MΩ for the voltage dividing circuit, insulation can be reliably maintained. Moreover, by forming a high resistance body by connecting a plurality of resistors in series, the insulation distance can be increased and insulation can be maintained more reliably.

  The differential amplifier circuit is a circuit that is connected to the voltage dividing circuit and differentially amplifies the voltage input from the voltage dividing circuit. The microcomputer is connected to the differential amplifier circuit, operates with reference to the low-voltage system ground, and controls the converter circuit by software based on the information about the input / output voltage of the converter circuit input from the differential amplifier circuit. Generate and output control signals. The interface circuit is connected to the microcomputer and the converter circuit, and outputs the control signal input from the microcomputer to the converter circuit. The converter circuit operates based on a control signal input from the interface circuit, and boosts and outputs the voltage of the high voltage battery.

  Here, the converter circuit and the microcomputer correspond to the power conversion circuit and the control circuit, and the high-voltage ground and the low-voltage ground correspond to the first ground and the second ground.

JP 2013-038894 A

  In the power conversion system described above, the voltage dividing circuit is configured by connecting a high resistance body of several MΩ and a low resistance body of several kΩ in series. The resistance value of the resistance varies. The greater the resistance value, the greater the variation. For this reason, the divided voltage largely fluctuates due to variations in the resistance value of the high resistance body. In this case, when processing is performed based on the divided voltage, there is a possibility that erroneous processing is performed.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a voltage detection device capable of improving voltage detection accuracy while ensuring insulation.

The present invention made to solve the above problems
A voltage dividing circuit composed of a series resistor that divides and outputs the voltage of the first electronic device that operates on the basis of the first ground, and is connected to the voltage dividing circuit and processes the voltage input from the voltage dividing circuit. And a processing circuit that outputs to a second electronic device that operates on the basis of a second ground that is insulated from the first ground, and detects voltage related to the voltage of the first electronic device in an insulated manner and transmits the information to the second electronic device. In the apparatus, the processing circuit is connected to the voltage dividing circuit, converts a voltage input from the voltage dividing circuit into a digital value corresponding to the voltage, and outputs the converted circuit. A first insulation circuit that insulates and outputs the input digital value to the second electronic device, and a voltage divider circuit that determines whether there is an abnormality based on the voltage input from the voltage divider circuit and makes its own determination The result is abnormal If that is, an abnormality determination circuit that outputs a constant digital value, is connected to the abnormality determination circuit, a second insulating circuit for a is the determination result input from the abnormality judging circuit insulated from the second electronic device outputs, It is characterized by having.

According to this configuration, the conversion circuit converts the voltage input from the voltage dividing circuit into a digital value corresponding to the voltage and outputs the digital value . Then, the first insulation circuit insulates the digital value input from the conversion circuit to the second electronic device and outputs it. With the first insulation circuit, information about the voltage of the first electronic device can be insulated and transmitted to the second electronic device. Therefore, unlike the prior art, it is not necessary to use a high resistance body of several MΩ for the voltage dividing circuit in order to ensure insulation. The voltage dividing circuit can be configured by a resistor having a low resistance value. Therefore, even if the resistance value varies, the divided voltage does not fluctuate greatly. Therefore, it is possible to improve voltage detection accuracy while ensuring insulation.
When the voltage dividing circuit is configured with a high resistance body of several MΩ and a low resistance body of several kΩ as in the past, the divided voltage greatly fluctuates due to variations in the resistance value of the high resistance body. End up. Therefore, when determining the presence or absence of an abnormality based on the voltage input from such a voltage dividing circuit, a threshold is set in consideration of large fluctuations in voltage due to variations in the resistance value of the high resistor so as not to make an erroneous determination. Must. Therefore, it is difficult to improve the abnormality determination accuracy. However, according to this configuration, the voltage dividing circuit can be configured by a resistor having a lower resistance value as compared with the related art. Therefore, even if the resistance value varies, the divided voltage does not fluctuate greatly. Therefore, the threshold value can be set more appropriately. In addition, the processing circuit includes an abnormality determination circuit and a second insulation circuit. The abnormality determination circuit is connected to the voltage dividing circuit, determines the presence or absence of abnormality based on the voltage input from the voltage dividing circuit, and outputs the determination result. The second insulation circuit is connected to the abnormality determination circuit, and insulates and outputs the determination result input from the abnormality determination circuit to the second electronic device. Therefore, the abnormality determination accuracy can be improved, and the determination result can be insulated and transmitted to the second electronic device.

It is a circuit diagram of the power converter device in a reference form . It is a circuit diagram of the power converter in a 1st embodiment . It is a circuit diagram of the power converter device in 2nd Embodiment . It is a graph for demonstrating operation | movement of the voltage detection circuit of the power converter device in 2nd Embodiment . It is a graph for demonstrating operation | movement of the voltage detection circuit in the modification of 2nd Embodiment . It is a circuit diagram of the power converter device in 3rd Embodiment . It is a graph for demonstrating operation | movement of the voltage detection circuit of the power converter device in 3rd Embodiment . It is a graph for demonstrating operation | movement of the voltage detection circuit in the modification of 3rd Embodiment .

  Next, the present invention will be described in more detail with reference to embodiments. In the present embodiment, an example is shown in which the voltage detection device according to the present invention is applied to a power conversion device that converts and outputs power supplied from a high-voltage battery mounted on a vehicle.

( Reference form )
First, with reference to FIG. 1, the structure of the power converter device of a reference form is demonstrated.

  A power conversion device 1 shown in FIG. 1 is a device that is mounted on a hybrid vehicle, converts DC power supplied from a high-voltage battery B into DC power having a different voltage, and supplies the DC power to a load (not shown). The power conversion device 1 includes a converter circuit 10 (first electronic device), a voltage detection circuit 11 (voltage detection device), a control circuit 12 (second electronic device), and an insulation circuit 13.

  The converter circuit 10 is a circuit that operates based on the high-voltage system ground G1 (first ground), converts DC power supplied from the high-voltage battery B into DC power having a different voltage, and supplies the DC power to the load. The converter circuit 10 is controlled by a control circuit 12 that operates based on a low-voltage system ground G2 (second ground) that is insulated from the high-voltage system ground G1. One power input terminal of the converter circuit 10 is connected to the positive terminal of the high voltage battery B, and the other power input terminal is connected to the negative terminal of the high voltage battery B and to the high voltage system ground G1. One power output terminal is connected to the positive terminal of the load, and the other power output terminal is connected to the negative terminal of the load. The other power output terminal is connected to the other power input terminal in the converter circuit 10, and is connected to the high-voltage system ground G1 through the other power input terminal.

  The voltage detection circuit 11 is a circuit that detects an output voltage of the converter circuit 10 that is required when the converter circuit 10 is controlled, and outputs information related to the output voltage to the control circuit 12 after being insulated. The voltage detection circuit 11 includes a voltage dividing circuit 110 and a processing circuit 111.

  The voltage dividing circuit 110 is a circuit that divides and outputs the output voltage of the converter circuit 10. The voltage dividing circuit 110 includes a resistor 110a having several hundreds kΩ and a resistor 110b having several kΩ. Since the information about the output voltage of the converter circuit 10 is insulated by an insulation circuit 111b described later, it is not necessary to use a high resistance body of several MΩ for the voltage dividing circuit 110 as in the prior art. The resistors 110a and 110b are connected in series. One end of the resistor 110a is connected to one power output end of the converter circuit 10, and one end of the resistor 110b is connected to the high voltage system ground G1. The series connection point of the resistors 110 a and 110 b is connected to the processing circuit 111.

  The processing circuit 111 is a circuit that processes the voltage input from the voltage dividing circuit 110 and outputs the voltage isolated from the control circuit 12. The processing circuit 111 includes a conversion circuit 111a and an insulation circuit 111b (first insulation circuit).

  The conversion circuit 111a is a circuit that converts the voltage input from the voltage dividing circuit 110 into a pulse signal having a pulse width corresponding to the voltage and outputs the pulse signal. Specifically, the voltage input from the voltage dividing circuit 110 is converted into a pulse signal having a constant frequency with a duty ratio corresponding to the voltage and output. The input end of the conversion circuit 111a is connected to the series connection point of the resistors 110a and 110b, and the output end is connected to the insulating circuit 111b.

  The insulation circuit 111b is a circuit that insulates and outputs the pulse signal input from the conversion circuit 111a to the control circuit 12. Specifically, it is an insulating element such as a photocoupler. The input terminal of the insulating circuit 111b is connected to the output terminal of the conversion circuit 111a, and the output terminal is connected to the control circuit 12.

  The control circuit 12 is a circuit that operates based on the low-voltage system ground G <b> 2 and controls the converter circuit 10 based on information related to the output voltage of the converter circuit 10 input from the processing circuit 11 and other information. Specifically, a control signal for controlling the converter circuit 10 is generated and output based on information on the output voltage of the converter circuit 10 and other information. The input end of the control circuit 12 is connected to the output end of the insulating circuit 111 b and the output end is connected to the insulating circuit 13.

  The insulating circuit 13 is a circuit that outputs a control signal for controlling the converter circuit 10 input from the control circuit 12 while being insulated from the converter circuit 10. Specifically, it is an insulating element such as a photocoupler. The input terminal of the insulating circuit 13 is connected to the output terminal of the control circuit 12, and the output terminal is connected to the input terminal of the converter circuit 10.

Next, the operation of the power converter according to the reference embodiment will be described with reference to FIG.

  A voltage dividing circuit 110 shown in FIG. 1 divides and outputs the output voltage of the converter circuit 10. The voltage dividing circuit 110 includes a resistor 110a having several hundred kΩ and a resistor 110b having several kΩ. Since there is the insulation circuit 111b, insulation can be ensured without using a high resistance body as in the prior art. Even if the resistance value varies, the divided voltage does not fluctuate as much as in the prior art. Therefore, it is possible to improve voltage detection accuracy while ensuring insulation.

  The conversion circuit 111a converts the voltage input from the voltage dividing circuit 110 into a pulse signal having a constant frequency with a duty ratio corresponding to the voltage, and outputs the pulse signal. The insulating circuit 111b insulates and outputs the pulse signal input from the conversion circuit 111a to the control circuit 12.

  The control circuit 12 generates and outputs a control signal for controlling the converter circuit 10 based on information related to the output voltage of the converter circuit 10 input from the insulating circuit 111b and other information. Then, the insulating circuit 13 insulates the control signal input from the control circuit 12 from the converter circuit 10 and outputs it.

  The converter circuit 10 operates based on the control signal input from the insulating circuit 13, converts the DC power supplied from the high voltage battery B into DC power having a different voltage, and supplies the DC power to the load.

Next, effects of the power conversion device according to the reference embodiment will be described.

According to the reference embodiment , the processing circuit 111 includes a conversion circuit 111a and an insulation circuit 111b. The conversion circuit 111a is connected to the voltage dividing circuit 110, converts the voltage input from the voltage dividing circuit 110 into a pulse signal having a pulse width corresponding to the voltage, and outputs the pulse signal. The insulating circuit 111b is connected to the conversion circuit 111a, and insulates the pulse signal input from the conversion circuit 111a from the control circuit 12 and outputs it. Information regarding the output voltage of the converter circuit 10 can be insulated and transmitted to the control circuit 12 by the insulating circuit 111b. Therefore, unlike the prior art, it is not necessary to use a high resistance body of several MΩ for the voltage dividing circuit 110 in order to ensure insulation. Therefore, the voltage dividing circuit 110 can be configured by a resistor having a low resistance value. As a result, even if the resistance value varies, the divided voltage does not fluctuate greatly. Thereby, voltage detection accuracy can be improved while ensuring insulation.

( First embodiment )
Next, the power converter device of 1st Embodiment is demonstrated. In the power conversion device of the first embodiment , the voltage detection circuit determines whether the output voltage of the converter circuit is abnormal with respect to the power conversion device of the reference mode .

First, with reference to FIG. 2, the structure of the power converter device of 1st Embodiment is demonstrated.

  The power conversion device 2 illustrated in FIG. 2 includes a converter circuit 20 (first electronic device), a voltage detection circuit 21 (voltage detection device), a control circuit 22 (second electronic device), and an insulation circuit 23. Yes.

The converter circuit 20 is the same as the converter circuit 10 of the reference form and has the same configuration.

  The voltage detection circuit 21 is a circuit that detects an output voltage of the converter circuit 20 that is required when the converter circuit 20 is controlled, and outputs information related to the output voltage to the control circuit 22 after being insulated. Further, it is also a circuit that determines whether or not the output voltage of the converter circuit 20 is abnormal and outputs information related to the determination result to the control circuit 22 after being insulated. The voltage detection circuit 21 includes a voltage dividing circuit 210 and a processing circuit 211.

The voltage dividing circuit 210 divides and outputs the output voltage of the converter circuit 20 and includes resistors 210a and 210b. The resistors 210a and 210b are the same as the resistors 110a and 110b of the reference form and have the same configuration.

  The processing circuit 211 is a circuit that processes the voltage input from the voltage dividing circuit 210 and outputs the voltage isolated from the control circuit 22, and includes a conversion circuit 211a, an insulating circuit 211b (first insulating circuit), and an abnormality determination circuit. 211c and an insulation circuit 211d (second insulation circuit).

The conversion circuit 211a and the insulation circuit 211b are the same as the conversion circuit 111a and the insulation circuit 111b of the reference form and have the same configuration.

  The abnormality determination circuit 211c is a circuit that determines whether or not the output voltage of the converter circuit 20 is abnormal based on the voltage input from the voltage dividing circuit 210 and outputs a pulse signal having a pulse width corresponding to the determination result. Specifically, the voltage input from the voltage dividing circuit 210 is compared with the threshold value Vth, the presence / absence of an abnormality is determined based on the comparison result, and a pulse signal having a pulse width corresponding to the determination result is output. More specifically, when the voltage input from the voltage dividing circuit 210 is equal to or lower than the threshold value Vth, it is determined that the output voltage of the converter circuit 20 is normal, and no pulse signal is output. On the other hand, when the voltage input from voltage dividing circuit 210 is larger than threshold value Vth, it is determined that the output voltage of converter circuit 20 is abnormal, and a pulse signal having a constant frequency with a duty ratio corresponding to the determination result is output. Here, the threshold value Vth is a reference for determining whether or not the output voltage of the converter circuit 20 is abnormal. When the voltage input from the voltage dividing circuit 210 is larger than the threshold value Vth, it is determined that the output voltage of the converter circuit 20 is high and abnormal. The input terminal of the abnormality determination circuit 211c is connected to the series connection point of the resistors 210a and 210b, and the output terminal is connected to the insulation circuit 211d.

  The insulation circuit 211d is a circuit that insulates and outputs the pulse signal input from the abnormality determination circuit 211c to the control circuit 22. Specifically, it is an insulating element such as a photocoupler. The input terminal of the insulation circuit 211d is connected to the output terminal of the abnormality determination circuit 211c, and the output terminal is connected to the control circuit 22.

  The control circuit 22 operates with the low-voltage system ground G2 as a reference, information relating to the output voltage of the converter circuit 20 input from the insulating circuit 211b, and information relating to the presence or absence of an abnormality in the output voltage of the converter circuit 20 input from the insulating circuit 211d. And a circuit for controlling the converter circuit 20 based on other information. Specifically, a control signal for controlling the converter circuit 20 is generated and output based on information on the output voltage of the converter circuit 20, information on the presence or absence of abnormality of the output voltage, and other information. More specifically, when the output voltage of the converter circuit 20 is normal, a control signal is generated and output based on information on the output voltage and other information. However, when the output voltage of the converter circuit 20 is abnormal, no control signal is output. That is, the converter circuit 20 is stopped. One input terminal of the control circuit 22 is connected to the output terminal of the insulation circuit 211b, the other input terminal is connected to the output terminal of the insulation circuit 211d, and the output terminal is connected to the insulation circuit 23.

The insulating circuit 23 is the same as the insulating circuit 13 of the reference form and has the same configuration.

Next, the operation of the power conversion device of the reference embodiment will be described with reference to FIG.

  A voltage dividing circuit 210 shown in FIG. 2 divides and outputs the output voltage of the converter circuit 20.

  The conversion circuit 211a converts the voltage input from the voltage dividing circuit 210 into a pulse signal having a constant frequency with a duty ratio corresponding to the voltage, and outputs the pulse signal. Then, the insulating circuit 211b insulates and outputs the pulse signal input from the conversion circuit 211a to the control circuit 22.

  On the other hand, when the voltage input from voltage dividing circuit 210 is larger than threshold value Vth, abnormality determination circuit 211c determines that the output voltage of converter circuit 20 is abnormal, and has a constant frequency with a duty ratio according to the determination result. Outputs a pulse signal. However, when the voltage input from the voltage dividing circuit 210 is equal to or lower than the threshold value Vth, it is determined that the output voltage of the converter circuit 20 is normal, and no pulse signal is output.

  When the output voltage of the converter circuit 20 is normal, the control circuit 22 generates and outputs a control signal based on information on the output voltage and other information. However, when the output voltage of the converter circuit 20 is abnormal, no control signal is output. That is, the converter circuit 20 is stopped.

  The insulating circuit 23 insulates the control signal for controlling the converter circuit 20 input from the control circuit 22 from the converter circuit 20 and outputs the control signal.

  The converter circuit 20 operates based on the control signal input from the insulation circuit 23, converts the DC power supplied from the high voltage battery B into DC power having a different voltage, and supplies the DC power to the load.

Next, the effect of the power converter of the first embodiment will be described.

According to the first embodiment , the same effect as the reference embodiment can be obtained.

When the voltage dividing circuit 210 is configured with a high resistance body of several MΩ and a low resistance body of several kΩ as in the past, the divided voltage greatly fluctuates due to variations in the resistance value of the high resistance body. End up. Therefore, when determining the presence or absence of an abnormality based on the voltage input from such a voltage dividing circuit, the threshold value Vth is set in consideration of a large voltage variation due to variations in the resistance value of the high resistor so as not to make an erroneous determination. Must be set. Therefore, it is difficult to improve the abnormality determination accuracy. However, according to the first embodiment , the voltage dividing circuit 210 is configured by a resistor having a lower resistance value than the conventional one. Therefore, even if the resistance value varies, the divided voltage does not fluctuate greatly. Therefore, the threshold value Vth can be set more appropriately. In addition, the processing circuit 211 includes an abnormality determination circuit 211c and an insulation circuit 211d. The abnormality determination circuit 211c is connected to the voltage dividing circuit 210, determines the presence or absence of abnormality based on the voltage input from the voltage dividing circuit 210, and outputs the determination result. The insulation circuit 211d is connected to the abnormality determination circuit 211c, and insulates and outputs the determination result input from the abnormality determination circuit 211c to the control circuit 22. Therefore, the abnormality determination accuracy can be improved, and the determination result can be insulated and transmitted to the control circuit 22.

( Second Embodiment )
Next, the power converter device of 2nd Embodiment is demonstrated. The power conversion device of the second embodiment is such that the conversion circuit and the insulation circuit for the conversion circuit also serve as the abnormality determination circuit and the insulation circuit for the power conversion device of the first embodiment .

First, with reference to FIG. 3, the structure of the power converter device of 2nd Embodiment is demonstrated.

  The power conversion device 3 illustrated in FIG. 3 includes a converter circuit 30 (first electronic device), a voltage detection circuit 31 (voltage detection device), a control circuit 32 (second electronic device), and an insulation circuit 33. Yes.

The converter circuit 30 is the same as the converter circuit 20 of the first embodiment and has the same configuration.

Voltage detecting circuit 31, the voltage detecting circuit 21 of the first embodiment which different internal structure part, a circuit having the same function as the voltage detection circuit 21 of the first embodiment. The voltage detection circuit 31 includes a voltage dividing circuit 310 and a processing circuit 311.

The voltage dividing circuit 310 is a circuit that divides and outputs the output voltage of the converter circuit 30, and includes resistors 310a and 310b. The resistors 310a and 310b are the same as the resistors 210a and 210b of the first embodiment and have the same configuration.

Processing circuit 311, the processing circuit 211 of the first embodiment which different internal structure part, a circuit having a processing circuit 211 and the same function of the first embodiment. The processing circuit 311 includes a conversion circuit 311a (conversion circuit, abnormality determination circuit) and an insulation circuit 311b (first insulation circuit, second insulation circuit).

The conversion circuit 311a is a circuit having the same function as the conversion circuit 311a of the first embodiment . Further, also serves as the abnormality determination circuit 211c of the first embodiment is also a circuit with an abnormality determination circuit 211c and the same function of the first embodiment. The conversion circuit 311a converts the voltage input from the voltage dividing circuit 310 into a pulse signal having a pulse width corresponding to the voltage, determines whether there is an abnormality based on the voltage, and receives the voltage input from the voltage dividing circuit 310. The determination result is combined with a pulse signal having a pulse width corresponding to the voltage to be output. Specifically, as shown in FIG. 4, when the voltage input from the voltage dividing circuit 310 is equal to or lower than the threshold value Vth, the output voltage of the converter circuit 30 is determined to be normal, and the duty corresponding to the voltage is determined. A pulse signal having a constant frequency of the ratios D1 to D2 (0 <D1 <D2) is output. On the other hand, when the voltage input from voltage dividing circuit 310 is larger than threshold value Vth, it is determined that the output voltage of converter circuit 30 is abnormal, and duty ratio D3 that is not output when it is determined to be normal. A pulse signal having a constant frequency of (D2 <D3) is output. The input terminal of the conversion circuit 311a is connected to the series connection point of the resistors 310a and 310b, and the output terminal is connected to the insulating circuit 311b.

The insulation circuit 311b is a circuit having the same function as the insulation circuit 211b of the first embodiment . Further, also serves as an insulating circuit 211d of the first embodiment is also a circuit having an isolation circuit 211d same function of the first embodiment. The insulating circuit 311b insulates and outputs to the control circuit 32 a pulse signal having a pulse width corresponding to the voltage input from the combined voltage dividing circuit 310 input from the conversion circuit 311a and the determination result. Specifically, the pulse signal input from the conversion circuit 311a is insulated from the control circuit 32 and output. The input terminal of the insulating circuit 311b is connected to the output terminal of the conversion circuit 311a, and the output terminal is connected to the control circuit 32.

  The control circuit 32 operates with the low-voltage system ground G2 as a reference, and based on the pulse signal having a pulse width corresponding to the voltage input from the synthesized voltage dividing circuit 310 input from the insulating circuit 311b and the determination result, the converter circuit 30 This is a circuit for obtaining information relating to the output voltage and information relating to the presence or absence of abnormality of the output voltage and controlling the converter circuit 30 based on these information and other information. Specifically, a control signal for controlling the converter circuit 30 is generated and output based on the obtained information on the output voltage of the converter circuit 30, information on the presence or absence of abnormality of the output voltage, and other information. More specifically, when the output voltage of the converter circuit 30 is normal, a control signal is generated and output based on information on the output voltage and other information. However, when the output voltage of the converter circuit 30 is abnormal, no control signal is output. That is, the converter circuit 30 is stopped. The input end of the control circuit 32 is connected to the output end of the insulating circuit 311 b, and the output end is connected to the insulating circuit 33.

The insulation circuit 33 is the same as the insulation circuit 23 of the first embodiment and has the same configuration.

Next, with reference to FIG.3 and FIG.4, operation | movement of the power converter device of 2nd Embodiment is demonstrated.

  3 divides the output voltage of the converter circuit 30 and outputs the divided voltage.

  As shown in FIG. 4, when the voltage input from the voltage dividing circuit 310 is equal to or lower than the threshold value Vth, the conversion circuit 311a determines that the output voltage of the converter circuit 30 is normal, and the duty corresponding to the voltage is determined. A pulse signal having a constant frequency of the ratios D1 to D2 (0 <D1 <D2) is output. On the other hand, when the voltage input from voltage dividing circuit 310 is larger than threshold value Vth, it is determined that the output voltage of converter circuit 30 is abnormal, and duty ratio D3 that is not output when it is determined to be normal. A pulse signal having a constant frequency of (D2 <D3) is output. Then, the insulating circuit 311b shown in FIG. 3 insulates and outputs the pulse signal input from the conversion circuit 311a to the control circuit 32.

  The control circuit 32 obtains information relating to the output voltage of the converter circuit 30 and information relating to the presence or absence of abnormality of the output voltage from the pulse signal input from the insulating circuit 311b. When the output voltage of the converter circuit 30 is normal, a control signal is generated and output based on information on the output voltage and other information. However, when the output voltage of the converter circuit 30 is abnormal, no control signal is output. That is, the converter circuit 30 is stopped.

  The insulation circuit 33 insulates the control signal for controlling the converter circuit 30 input from the control circuit 32 from the converter circuit 30 and outputs the control signal.

  The converter circuit 30 operates based on the control signal input from the insulating circuit 33, converts the DC power supplied from the high voltage battery B into DC power having a different voltage, and supplies the DC power to the load.

Next, the effect of the power converter of 2nd Embodiment is demonstrated.

According to the second embodiment , the same effect as that of the first embodiment can be obtained.

According to the second embodiment , the conversion circuit 311a also serves as the abnormality determination circuit 211c of the first embodiment , and converts the voltage input from the voltage dividing circuit 310 into a pulse signal having a pulse width corresponding to the voltage. In addition, the presence or absence of abnormality is determined based on the comparison result compared with the threshold value Vth. Then, the determination result is combined with a pulse signal having a pulse width corresponding to the voltage input from the voltage dividing circuit 310 and output. On the other hand, the insulating circuit 311b also serves as the insulating circuit 211d of the first embodiment , and the pulse signal determination result of the pulse width corresponding to the voltage input from the synthesized voltage dividing circuit input from the conversion circuit 311a is The output is insulated from the control circuit 32. Therefore, the configuration can be simplified as compared with the voltage detection circuit of the first embodiment while having the same function as the voltage detection circuit of the first embodiment . Therefore, it is possible to reduce the size of the power conversion device 3 and to reduce the cost.

According to the second embodiment , the conversion circuit 311a outputs a pulse signal having a pulse width corresponding to the voltage input from the voltage dividing circuit 310 when the determination result thereof is normal. If the determination result indicates an abnormality, a pulse signal having a pulse width that is not output when it is determined to be normal is output. Therefore, it is possible to reliably combine information relating to the output voltage of the converter circuit 30 and information relating to the output voltage determination result in a distinguishable state. Therefore, the conversion circuit 311a can also serve as the abnormality determination circuit 211c of the first embodiment , and the power conversion device 3 can be reliably simplified.

In the second embodiment , as shown in FIG. 4, when the voltage input from the voltage dividing circuit 310 is larger than the threshold value Vth, the conversion circuit 311a determines that the output voltage of the converter circuit 30 is abnormal, Although an example in which a pulse signal having a duty ratio D3 larger than the duty ratio D2 that is not output when it is determined that the output voltage is normal is given, the present invention is not limited to this. As shown in FIG. 5, in this case, a pulse signal having a duty ratio D4 smaller than the duty ratio D1 that is not output when it is determined that the output voltage is normal may be output. A pulse signal having a pulse width that is not output when it is determined that the output voltage is normal may be output.

( Third embodiment )
Next, the power converter device of 3rd Embodiment is demonstrated. The power converter of 3rd Embodiment adds the synthetic | combination circuit which synthesize | combines the determination result of the presence or absence of own abnormality input from a converter circuit with respect to the power converter of 2nd Embodiment .

First, with reference to FIG. 6, the structure of the power converter device of 3rd Embodiment is demonstrated.

  The power conversion device 4 illustrated in FIG. 6 includes a converter circuit 40 (first electronic device), a voltage detection circuit 41 (voltage detection device), and a control circuit 42 (second electronic device).

The converter circuit 40 is the same as the converter circuit 30 of the second embodiment and has the same configuration.

  The voltage detection circuit 41 is a circuit that detects the output voltage of the converter circuit 40 required when controlling the converter circuit 40 and outputs the information related to the output voltage to the control circuit 42 after being insulated. Further, it is also a circuit that determines whether there is an abnormality in the output voltage of the converter circuit 40, and outputs information related to the determination result isolated from the control circuit 42. Further, it is a circuit that insulates the control circuit 42 from the information relating to its own abnormality determined by the converter circuit 40 and outputs it. The voltage detection circuit 41 includes a voltage dividing circuit 410 and a processing circuit 411.

The voltage dividing circuit 410 is a circuit that divides and outputs the output voltage of the converter circuit 40, and includes resistors 410a and 410b. The resistors 410a and 410b are the same as the resistors 310a and 310b of the second embodiment and have the same configuration.

  The processing circuit 411 is a circuit that processes the voltage input from the voltage dividing circuit 410 and outputs information related to an abnormality input from the converter circuit 40 while being insulated from the control circuit 42. The conversion circuit 411a (conversion circuit, An abnormality determination circuit), an insulation circuit 411b (first insulation circuit, second insulation circuit), an insulation circuit 411e (third insulation circuit), and a synthesis circuit 411f.

The conversion circuit 411a and the insulation circuit 411b are the same as the conversion circuit 311a and the insulation circuit 311b of the second embodiment , and have the same configuration.

  The insulation circuit 411e is a circuit that insulates and outputs the determination result of the presence or absence of its own abnormality input from the converter circuit 40. Specifically, it is an insulating element such as a photocoupler. The input terminal of the insulation circuit 411e is connected to the determination result output terminal of the converter circuit 40, and the output terminal is connected to the synthesis circuit 411f.

  The combining circuit 411f combines the determination result input from the insulating circuit 411e with the pulse signal having the pulse width corresponding to the voltage input from the combined voltage dividing circuit input from the insulating circuit 411b and the determination result. Output circuit. Specifically, when the determination result input from the insulating circuit 411e indicates normality, the input from the insulating circuit 411b is output as it is. On the other hand, if the determination result input from the insulating circuit 411e indicates an abnormality, a pulse signal having a pulse width that is not input from the insulating circuit 411b is output. More specifically, as shown in FIG. 7, when the determination result input from the insulating circuit 411e indicates that the converter circuit 40 is normal, the voltage input from the voltage dividing circuit 410 is When it is equal to or lower than the threshold value Vth, it is determined that the output voltage of the converter circuit 40 is normal, and a pulse signal having a constant frequency with a duty ratio D1 to D2 (0 <D1 <D2) corresponding to the voltage is output. When the determination result input from the insulating circuit 411e indicates that the converter circuit 40 is normal, and the voltage input from the voltage dividing circuit 410 is greater than the threshold value Vth, the output voltage of the converter circuit 40 is A pulse signal having a constant frequency with a duty ratio D3 (D2 <D3) that is not output when the output voltage is determined to be normal is determined. On the other hand, when the determination result input from the insulating circuit 411e indicates that the converter circuit 40 is abnormal, the converter circuit 40 is normal regardless of the magnitude of the voltage input from the voltage dividing circuit 410. In some cases, a pulse signal having a constant frequency with a duty ratio D5 (0 <D5 <D1) that is not output is output. One input terminal of the synthesis circuit 411 f is connected to the output terminal of the isolation circuit 411 b, the other input terminal is connected to the output terminal of the isolation circuit 411 e, and the output terminal is connected to the control circuit 42.

  The control circuit 42 operates with the low-voltage system ground G2 as a reference, and a pulse signal having a pulse width corresponding to the voltage input from the combined voltage dividing circuit 410 input from the combining circuit 411f and the determination result of the conversion circuit 411a. Based on the determination result of the converter circuit 40, information on the output voltage of the converter circuit 40, information on the presence / absence of abnormality of the output voltage, and information on the presence / absence of abnormality of the converter circuit 40 are obtained, and the converter circuit is based on these information and other information. 40 is a circuit for controlling 40. Specifically, in order to control the converter circuit 40 based on the obtained information on the output voltage of the converter circuit 40, information on the presence or absence of abnormality of the output voltage, information on the presence or absence of abnormality of the converter circuit 40, and other information The control signal is generated and output. More specifically, when the output voltage of the converter circuit 40 is normal and the converter circuit 40 itself is also normal, a control signal is generated and output based on information on the output voltage of the converter circuit 40 and other information. To do. However, if the output voltage of the converter circuit 40 is abnormal or the converter circuit 40 itself is abnormal, no control signal is output. That is, the converter circuit 40 is stopped. The input terminal of the control circuit 42 is connected to the output terminal of the synthesis circuit 411 f, and the output terminal is connected to the insulating circuit 43.

The insulation circuit 43 is the same as the insulation circuit 33 of the second embodiment and has the same configuration.

Next, with reference to FIG.6 and FIG.7, operation | movement of the power converter device of 3rd Embodiment is demonstrated.

  The voltage dividing circuit 410 shown in FIG. 6 divides and outputs the output voltage of the converter circuit 40.

  When the voltage input from voltage dividing circuit 410 is equal to or lower than threshold value Vth, conversion circuit 411a itself determines that the output voltage of converter circuit 40 is normal, and duty ratios D1 to D2 (0 < A pulse signal having a constant frequency of D1 <D2) is output. On the other hand, when the voltage input from the voltage dividing circuit 410 is larger than the threshold value Vth, it is determined that the output voltage of the converter circuit 40 is abnormal, and the duty ratio D3 is not output when it is determined to be normal. A pulse signal having a constant frequency of (D2 <D3) is output. The insulating circuit 411b insulates and outputs the pulse signal input from the conversion circuit 411a to the synthesis circuit 411f.

  The insulating circuit 411e insulates and outputs the determination result of the presence or absence of its own abnormality input from the converter circuit 40.

  In the case where the determination result input from the insulating circuit 411e indicates that the converter circuit 40 is normal and the voltage input from the voltage dividing circuit 410 is equal to or lower than the threshold value Vth, the synthesis circuit 411f Since the output voltage of the circuit 40 is normal, a pulse signal having a constant frequency with a duty ratio D1 to D2 (0 <D1 <D2) corresponding to the voltage is output. When the determination result input from the insulating circuit 411e indicates that the converter circuit 40 is normal, and the voltage input from the voltage dividing circuit 410 is greater than the threshold value Vth, the output voltage of the converter circuit 40 is Since it is abnormal, a pulse signal having a constant frequency with a duty ratio D3 (D2 <D3) that is not output when it is determined that the output voltage is normal is output. On the other hand, when the determination result input from the insulating circuit 411e indicates that the converter circuit 40 is abnormal, the converter circuit 40 is normal regardless of the magnitude of the voltage input from the voltage dividing circuit 410. In some cases, a pulse signal having a constant frequency with a duty ratio D5 (0 <D5 <D1) that is not output is output.

  The control circuit 42 obtains information relating to the output voltage of the converter circuit 40, information relating to the presence / absence of abnormality of the output voltage, and information relating to the presence / absence of abnormality of the converter circuit 40 from the pulse signal input from the synthesis circuit 411f. When the output voltage of the converter circuit 40 is normal and the converter circuit 40 itself is also normal, a control signal is generated and output based on information on the output voltage of the converter circuit 40 and other information. However, if the output voltage of the converter circuit 40 is abnormal or the converter circuit 40 itself is abnormal, no control signal is output. That is, the converter circuit 40 is stopped.

  The insulation circuit 43 insulates the control signal for controlling the converter circuit 40 input from the control circuit 42 from the converter circuit 40 and outputs the control signal.

  The converter circuit 40 operates based on the control signal input from the insulating circuit 43, converts the DC power supplied from the high voltage battery B into DC power having a different voltage, and supplies the DC power to the load.

Next, the effect of the power converter of 3rd Embodiment is demonstrated.

According to the third embodiment , the same effect as that of the second embodiment can be obtained.

According to the third embodiment , the processing circuit 411 includes an insulating circuit 411e and a synthesis circuit 411f. The insulating circuit 411e is connected to the converter circuit 40, and insulates and outputs the determination result of the presence or absence of abnormality of the converter circuit 40 input from the converter circuit 40. Then, the synthesis circuit 411f is connected to the insulation circuits 411b and 411e, and the pulse signal having a pulse width corresponding to the voltage inputted from the synthesized voltage dividing circuit 410 inputted from the insulation circuit 411b and the determination result, The determination results input from the insulating circuit 411e are combined and output. Therefore, information relating to the abnormality of the converter circuit 40 can be transmitted to the control circuit 42 with a simple configuration. Therefore, it is possible to reduce the size of the power conversion device 4 and to reduce the cost.

According to the third embodiment , the synthesis circuit 411f outputs the input from the isolation circuit 411b as it is when the determination result input from the isolation circuit 411e indicates normality. On the other hand, if the determination result input from the insulating circuit 411e indicates an abnormality, a pulse signal having a pulse width that is not input from the insulating circuit 411b is output. Therefore, information relating to the output voltage of the converter circuit 40, information relating to the determination result of the output voltage, and information relating to the abnormality of the converter circuit 40 can be reliably combined in a distinguishable state. Therefore, the power conversion device 4 can be reliably simplified.

In the third embodiment , as illustrated in FIG. 7, when the determination result input from the insulating circuit 411 e indicates that the converter circuit 40 is abnormal, the combining circuit 411 f is replaced by the converter circuit 40. Although an example is given in which a pulse signal having a duty ratio D5 smaller than the duty ratio D1 that is not output when it is normal is output, the present invention is not limited to this. As shown in FIG. 8, when the converter circuit 40 is normal, a pulse signal having a duty ratio D6 (D2 <D6 <D3) larger than the duty ratio D2 and smaller than the duty ratio D3 is output. You may do it. What is necessary is just to output the pulse signal of the pulse width which is not output when the converter circuit 40 is normal.

Finally, related variations will be described.

In the reference form and the first to third embodiments , the processing circuit converts the voltage input from the voltage dividing circuit into a pulse signal having a pulse width corresponding to the voltage, or based on the voltage input from the voltage dividing circuit. In this example, the presence or absence of abnormality in the output voltage of the converter circuit is determined and converted into a pulse signal having a pulse width corresponding to the determination result. However, the present invention is not limited to this. You may convert into the digital value corresponded to the pulse width according to the voltage or its determination result. That is, you may convert into the digital value according to the voltage and its determination result.

In the reference form and the first to third embodiments , the voltage detection circuit detects the output voltage of the converter circuit. However, the present invention is not limited to this. In the case where the control circuit controls the converter circuit based on the input / output voltage of the converter circuit, the same configuration can be used when detecting the input voltage of the converter circuit.

DESCRIPTION OF SYMBOLS 1 ... Power converter device, 10 ... Converter circuit (1st electronic device), 11 ...... Voltage detection circuit (voltage detection device), 110 ... Voltage divider circuit, 110a, 110b ... Resistance , 111... Processing circuit, 111a... Conversion circuit, 111b... Insulation circuit (first insulation circuit), 12... Control circuit (second electronic device), 13. ..High voltage battery

Claims (5)

A voltage dividing circuit (210, 310, 410) composed of a series resistor that divides and outputs the voltage of the first electronic device operating with reference to the first ground;
A processing circuit (211) connected to the voltage dividing circuit, processing a voltage input from the voltage dividing circuit, and outputting the processed voltage to a second electronic device operating with a second ground insulated from the first ground as a reference 311 and 411),
In a voltage detection device comprising: information relating to the voltage of the first electronic device is insulated and transmitted to the second electronic device;
The processing circuit includes:
A conversion circuit (211a, 311a, 411a) that is connected to the voltage dividing circuit and converts the voltage input from the voltage dividing circuit into a digital value corresponding to the voltage;
A first insulation circuit (211b, 311b, 411b) connected to the conversion circuit and insulating and outputting a digital value input from the conversion circuit to the second electronic device;
An abnormality that is connected to the voltage dividing circuit, determines the presence or absence of an abnormality based on the voltage input from the voltage dividing circuit, and outputs a constant digital value when its own determination result indicates an abnormality A determination circuit (211c, 311a);
A second insulation circuit (211d, 311b) that is connected to the abnormality determination circuit and insulates and outputs a determination result input from the abnormality determination circuit to the second electronic device;
A voltage detection device comprising: The conversion circuit (311a) also serves as the abnormality determination circuit, converts the voltage input from the voltage dividing circuit into a digital value corresponding to the voltage, and determines whether there is an abnormality based on the voltage. Then, the determination result is synthesized and output to a digital value corresponding to the voltage input from the voltage dividing circuit,
The first insulation circuit (311b) also serves as the second insulation circuit, and the digital value and the determination result according to the voltage inputted from the synthesized voltage dividing circuit inputted from the conversion circuit, The voltage detection device according to claim 1, wherein the voltage detection device outputs the signal while being insulated from the second electronic device. The conversion circuit outputs a digital value corresponding to the voltage input from the voltage dividing circuit when the determination result of the conversion circuit indicates normal, and the determination result of the conversion circuit indicates abnormality The voltage detection device according to claim 2, wherein a constant digital value that is not output when it is determined to be normal is output. A third insulation circuit (411e) that is connected to the first electronic device and insulates and outputs the determination result of the presence or absence of abnormality of the first electronic device input from the first electronic device;
The digital value corresponding to the voltage inputted from the synthesized voltage dividing circuit connected to the first insulation circuit and the third insulation circuit and inputted from the first insulation circuit and the determination result are further added to the first result. A synthesis circuit (411f) for synthesizing and outputting the determination results input from the three insulation circuits;
The voltage detection device according to claim 2, wherein the voltage detection device includes: When the determination result input from the third insulation circuit indicates normality, the synthesis circuit outputs the input from the first insulation circuit as it is and the determination is input from the third insulation circuit 5. The voltage detection device according to claim 4, wherein when the result indicates abnormality, a constant digital value that is not input from the first insulation circuit is output.

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