KR101692868B1 - Electric compressor inverter with parallel power and driving method thereof - Google Patents

Abstract

The first parallel converter includes a first voltage converter for receiving a voltage output from the first parallel power supply and converting the voltage to a first voltage, a second voltage converter for outputting a voltage higher than the first parallel power, A second voltage conversion unit for receiving a voltage output from the two parallel power supplies and converting the received voltage to a second voltage, and a switch for passing or blocking the first voltage output from the first voltage conversion unit; And a comparator for feeding back the turn-off signal to the switch when the first voltage and the second voltage are inputted to the non-inverting terminal and the inverting terminal, respectively, and transmitting the second voltage to the power of the micom. And a driving method thereof.
According to the inverter for a motor-driven compressor and the driving method thereof, the microcomputer for controlling the motor-driven compressor inverter can be driven only by applying a low voltage. When a high voltage is applied, the motor- It is possible to selectively use the driving power of the inverter and to reduce the secondary damage on the vehicle side in the event of a problem caused by high voltage application.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an inverter for a motor-

[0001] The present invention relates to an inverter for a motor-driven compressor connected to a parallel power supply, and more particularly to an inverter for a motor-driven compressor which can activate a micom of the motor- .

In a conventional electric compressor for a vehicle air conditioner, when the high voltage is applied, the inverter of the motor-driven compressor is activated to drive the inverter, whereas when the low voltage is applied, the motor-driven compressor is not activated. Further, when a high voltage is applied in a state where the internal parts of the inverter are damaged, there is a problem that the peripheral circuits and components of the inverter are further damaged.

The present invention provides an inverter for a motor-driven compressor and a driving method thereof, which can activate a microcomputer of a motor compressor only by applying a low voltage and can selectively use power by shutting off a low voltage when a high voltage is applied.

The first parallel converter includes a first voltage converter for receiving a voltage output from the first parallel power supply and converting the voltage to a first voltage, a second voltage converter for outputting a voltage higher than the first parallel power, A second voltage conversion unit for receiving a voltage output from the two parallel power supplies and converting the received voltage to a second voltage, and a switch for passing or blocking the first voltage output from the first voltage conversion unit; And a comparator for feeding back the turn-off signal to the switch when the first voltage and the second voltage are inputted to the non-inverting terminal and the inverting terminal, respectively, and transmitting the second voltage to the power of the micom. And an inverter.

Here, the comparator applies the first voltage to the power source of the microcomputer when the first voltage is input to the non-inverting terminal and the voltage is not applied to the inverting terminal, and the second voltage is input to the inverting terminal And if the voltage is not applied to the non-inverting terminal, the second voltage may be applied to the power source of the microcomputer.

When the first voltage and the second voltage are inputted to the non-inverting terminal and the inverting terminal of the comparator and the switch is turned off, the first voltage converter may transfer the first voltage to the auxiliary power source.

The inverter for a motor compressor connected to the parallel power supply may further include a third voltage converter for converting the first voltage or the second voltage output from the comparator to a third voltage and providing the converted voltage to the power source of the microcomputer have.

Also, at least one of the first voltage converting unit, the second voltage converting unit, and the third voltage converting unit may be formed of one or more regulators.

Here, the first voltage and the second voltage may have the same magnitude.

According to another aspect of the present invention, there is provided a method of driving a microcomputer, comprising: receiving a voltage output from a first parallel power supply and down converting the voltage to a first voltage; transmitting the first voltage to a microcomputer power supply; Receiving a voltage output from a second parallel power supply connected in parallel with the first parallel power supply and down converting the voltage to a second voltage, blocking the first voltage from being transmitted to the microcomputer power supply, To a power source of the microcomputer, wherein the microcomputer is powered by the parallel power.

The driving method of the inverter for a motor-driven compressor connected to the parallel power supply may further include transmitting the first voltage to the auxiliary power when the first voltage is not transmitted to the power source of the microcomputer.

According to the present invention, when the normal operation of the inverter is confirmed after driving the microcomputer for controlling the motor-compressor inverter through the power supply by the low-voltage battery, the inverter of the motor- And drives the microcomputer through the power source of the high voltage battery so that the inverter driving power of the motor-driven compressor can be selectively used. In addition, it is possible to confirm in advance whether the internal circuit of the inverter is normal or not through the application of the voltage by the low voltage battery before using the high voltage battery, so that a problem that may occur due to the application of the high voltage in the abnormal state of the internal circuit can be prevented in advance, There is an advantage that it can reduce the secondary damage.

1 is a configuration diagram of an inverter for a motor-driven compressor connected with a parallel power supply according to an embodiment of the present invention.
Fig. 2 is a flowchart showing a driving method of the inverter for an electric compressor using Fig. 1. Fig.

[0001] The present invention relates to an inverter for a motor-driven compressor connected to a parallel power supply, and a micom for controlling an electric compressor inverter of an air conditioner for an electric vehicle (EV, HEV, FCEV) can be driven only by applying a low voltage. Further, according to the present invention, when the high voltage is applied, the low voltage is cut off and the microcomputer is driven at a high voltage, so that the inverter driving power of the motor-driven compressor can be selectively used.

1 is a configuration diagram of an inverter for a motor-driven compressor connected with a parallel power supply according to an embodiment of the present invention. 1, the inverter 100 for a motor-operated compressor connected to the parallel power supply includes a first voltage conversion unit 110, a second voltage conversion unit 120, a switch 130, a comparator 140, And a voltage conversion unit 150.

The first voltage converter 110 receives the voltage output from the first parallel power supply 10, which is a low voltage battery, and down converts the voltage to a first voltage. For example, the first voltage converter 110 receives a voltage of 12V from the first parallel power supply 10 and converts the voltage to a voltage of 5V. Here, insulation means 11 such as a photocoupler is disposed between the first parallel power supply 10 and the first voltage conversion unit 110 to minimize electrical damage.

The first voltage converter 110 includes a regulator. 1, one regulator is used for the configuration of the first voltage converter 110, but the number of the regulators is not limited thereto.

The second voltage converter 120 receives the voltage output from the second parallel power supply 20, which is a voltage battery, and down converts the voltage to a second voltage. For example, the second voltage converter 120 receives a voltage of 400V from the second parallel power supply 20 and converts it to a voltage of 5V. Here, it is apparent to those skilled in the art that the first voltage and the second voltage have the same magnitude of 5V, and that a certain degree of voltage deviation may exist.

The second parallel power supply 20 outputs a voltage higher than the first parallel power supply 10. The first parallel power supply 10 and the second parallel power supply 20 may be used as a power source for a microcomputer for controlling an inverter of an electric vehicle air conditioner. That is, one of the parallel power supplies uses the high voltage and the other one uses the low voltage as the power source of the microcomputer of the inverter.

The second voltage converting unit 120 is also configured as a regulator. In the case of a high-voltage battery, the voltage range is lower than that of a low-voltage battery. For this purpose, FIG. 1 uses a configuration in which a second regulator 121 and a third regulator 122, which are two regulators, are connected in series for the configuration of the second voltage converter 120. That is, the second regulator 121 downs a voltage of 400V to a voltage of 15V, and then the third regulator 122 drops the voltage of 15V to 5V again. Of course, the number of regulators constituting the second voltage converter 120 is not necessarily limited thereto.

The switch 130 operates to pass or block the first voltage output from the first voltage converter 110. Such a switch 130 can be implemented by various known means.

The comparator 140 has a non-inversion terminal (+) to which a first voltage is input and an inversion terminal (-) to which a second voltage is input. That is, the comparator 140 outputs a selected one of the first voltage and the second voltage to the microcomputer 140 according to whether the first voltage and the second voltage input to the non-inverting terminal (+) and the inverting terminal (- And supplies it to the power source 30. Of course, it is also possible that the first voltage is inputted to the inverting terminal (-) and the second voltage is inputted to the non-inverting terminal (+).

The third voltage converter 150 converts the first voltage or the second voltage output from the comparator 140 to a third voltage and provides the converted power to the microcomputer. For example, the voltage of 5V output from the comparator 140 may be converted to 3.3V or 1.8V depending on the application. The third voltage converter 150 may also include one or more regulators.

The function of the comparator 140 is as follows. The comparator 140 applies the first voltage to the non-inverting terminal and the first voltage to the power of the micom unless the second voltage is applied to the inverting terminal.

That is, when only the first voltage is input to the comparator 140, the first voltage supplied from the low voltage battery is used to drive the microcomputer. In other words, the microcomputer of the motor-driven compressor inverter is activated only by applying the low voltage to drive the inverter. After the normal operation of the microcomputer is confirmed by the application of the low voltage, the microcomputer can operate according to the high voltage. If the operation of the inverter is abnormal when the low voltage is applied, the application of the high voltage is prevented from proceeding to prevent the breakdown of the internal circuit or parts due to the high voltage. In other words, there is no secondary damage to the vehicle side when various problems arise due to high voltage application.

When the first voltage and the second voltage are inputted to both the non-inverting terminal and the inverting terminal of the comparator 140, the comparator 140 feeds the turn-off signal to the switch 130 side, And transfers the second voltage to the power source of the microcomputer.

That is, when the first voltage and the second voltage are inputted to the comparator 140, the first voltage supplied from the low-voltage battery is cut off and the microcomputer is driven through the second voltage supplied from the high-voltage battery. Of course, when the second voltage is input to the inverting terminal and the first voltage is not applied to the non-inverting terminal according to the interruption of the first voltage, the second voltage is maintained to be applied to the microcomputer.

As described above, when the first voltage and the second voltage are inputted to the non-inverting terminal and the inverting terminal of the comparator 140 and the switch 130 is turned off, the first voltage converting unit 110 And transfers the first voltage to the auxiliary power source (40). The auxiliary power source 40 may be a communication power source of the vehicle.

Fig. 2 is a flowchart showing a driving method of the inverter for an electric compressor using Fig. 1. Fig. Hereinafter, a driving method of the inverter 100 for an electric compressor will be described with reference to FIG.

First, the voltage ex (12V) output from the first parallel power supply 10, which is a low voltage battery, is received and converted down to the first voltage ex, 5V (S210). Then, the first voltage ex, 5V is converted into a third voltage ex, 3.3V, or 1.8V, and the converted voltage is transmitted to the microcomputer power supply (S220). Accordingly, the microcomputer is driven through the first voltage supplied from the low voltage battery.

As a result, if it is confirmed that the inverter is normally driven, the voltage (ex, 400V) output from the second parallel power supply 20, which is a high voltage battery, is received and converted down to the second voltage ex, 5V at step S230. Thereafter, the first voltage provided from the first parallel power supply 10 is prevented from being transmitted to the power source of the microcomputer, and the second voltage provided from the second parallel power supply 20 is supplied to the third voltage ex, 3.3V or 1.8 V) and supplies it to the power source of the microcomputer (S240). Accordingly, the microcomputer is driven through the second voltage supplied from the high voltage battery. As described above, when the first voltage is not transmitted to the microcomputer power supply, the first voltage is transmitted to the auxiliary power supply 40 for communication (S250).

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: first parallel power supply 20: second parallel power supply
30: Microcomputer power supply 40: Auxiliary power supply
100: Inverter for motor-driven compressors with parallel power supply
110: first voltage converting unit 120: second voltage converting unit
130: Switch 140: Comparator
150: Third voltage converter

Claims (8)

A first voltage converter for receiving an output voltage of the first parallel power supply and down converting the output voltage to a first voltage;
A second voltage converter for receiving an output voltage of a second parallel power supply that outputs a voltage higher than the first parallel power supply and down converting the output voltage to a second voltage;
A switch operable to pass or block the first voltage output from the first voltage converter; And
Wherein the first voltage is input to the non-inverting terminal and the first voltage is input to the inversion terminal when the first voltage is input to the non-inverting terminal and the voltage is not applied to the inverting terminal, And when the first voltage and the second voltage are input to the non-inverting terminal and the inverting terminal, respectively, a turn-off signal is fed back to the switch to cut off the transmission of the first voltage, And a comparator for transmitting the power to the microcomputer power source,
Wherein the first voltage converting unit is connected to a parallel power supply for transmitting the first voltage to the auxiliary power supply when the switch is turned off. delete delete The method according to claim 1,
And a third voltage conversion unit for converting the first voltage or the second voltage outputted from the comparator to a third voltage and providing the converted voltage to the microcomputer power supply. The method of claim 4,
Wherein at least one of the first voltage converter, the second voltage converter, and the third voltage converter is connected to a parallel power source formed of at least one regulator. The method of claim 4,
Wherein the first voltage and the second voltage are connected in parallel to each other. A driving method of an inverter for an electric compressor,
Receiving an output voltage of the first parallel power supply and downconverting the output voltage to a first voltage;
Transmitting the first voltage to a power source of the microcomputer;
Receiving an output voltage of a second parallel power supply that outputs a voltage higher than the first parallel power supply and down converting the output voltage to a second voltage when the inverter is normally driven after transferring the first voltage; And
Blocking the transfer of the first voltage to the power source of the microcomputer and transmitting the second voltage to the power source of the microcomputer,
And a parallel power supply for transferring the first voltage to the auxiliary power supply when the first voltage is interrupted. delete

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