KR20180123834A - Voltage sensing apparatus - Google Patents

Abstract

The present invention relates to a voltage sensing apparatus for sensing an output voltage of a battery included in an electric vehicle. Specifically, the present invention provides a voltage sensing apparatus for controlling to supply a voltage to a communication controller of an electric vehicle (EVCC) from a battery only when the voltage output by the battery is within a preset input range. Furthermore, the voltage sensing apparatus senses how large a voltage actually output by the battery is.

Description

[0001] DESCRIPTION [0002] Voltage sensing apparatus [

 The present invention relates to a voltage sensing device for sensing an output voltage of a battery included in an electric vehicle. More specifically, the present invention relates to a voltage sensing device for detecting an output voltage of a battery included in an electric vehicle. EVCC to be supplied with a voltage.

An electric vehicle is an automobile that derives its drive energy from electric energy, not from combustion of fossil fuels like existing vehicles. Therefore, such an electric vehicle secures the driving force by charging electric energy into the battery.

It is necessary to supply a stable voltage required by a communication controller of electric vehicles (EVCC) as well as a motor of an electric vehicle from a battery mounted in the electric vehicle.

The voltage output by the battery differs depending on the type of automobile, for example, a compact car or a large car. It is necessary to supply a stable voltage required by the electric vehicle communication controller regardless of the magnitude of the voltage outputted from the battery.

At this time, it is necessary to propose a voltage sensing device that senses the voltage that the battery actually outputs.

Furthermore, when the voltage actually outputted from the battery is not within the predetermined range, it is necessary to prevent the unstable operation by cutting off the voltage supply to the communication control of the electric vehicle.

Furthermore, when sensing the voltage output from the battery, it is necessary to precisely feedback the output voltage in units of 0.1 V or less by sensing a voltage whose actual output voltage is reduced to a predetermined ratio.

Furthermore, it is necessary to reduce the design cost by implementing a voltage sensing device as a surface mount device resistor (SMD Registor) or a multilayer ceramic capacitor (MLCC).

Furthermore, it is necessary to implement a voltage sensing device in which the input terminal and the output terminal of the voltage sensing device are insulated from each other to protect various devices from unstable noise of the battery power source.

The present invention proposes a voltage sensing device that senses the voltage that the battery actually outputs.

Further, the present invention prevents the unstable operation by interrupting the voltage supply to the communication control of the electric vehicle when the voltage actually output by the battery is not within the predetermined range.

Further, the present invention senses a voltage that is a reduction of the actual output voltage by a predetermined ratio when sensing a voltage output from the battery, and precisely feeds back the output in units of 0.1 V or less.

Furthermore, the present invention reduces the design cost by implementing a voltage sensing device as a surface mount device resistor (SMD Registor) or a multilayer ceramic capacitor (MLCC).

Furthermore, the present invention implements a voltage sensing device in which an input terminal and an output terminal of a voltage sensing device are insulated, thereby protecting various devices from unstable noise of a battery power source.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.

After the claim is finalized

The present invention can suggest a voltage sensing device that senses the voltage that the battery actually outputs.

Further, the present invention can prevent the unstable operation by shutting off the voltage supply to the communication control of the electric vehicle when the voltage actually outputted from the battery is not within the predetermined range.

Furthermore, the present invention can precisely feed back a unit of 0.1 V or less by sensing a voltage obtained by reducing the actual output voltage by a predetermined ratio when sensing a voltage output from the battery.

Furthermore, the present invention can reduce the design cost by implementing a voltage sensing device as a surface mount device resistor (SMD Registor) or a multilayer ceramic capacitor (MLCC).

Furthermore, the present invention implements a voltage sensing device in which an input terminal and an output terminal of a voltage sensing device are insulated from each other, thereby protecting various devices from unstable noise of the battery power source.

The effects of the present invention are not limited to the above-mentioned effects, and various effects can be included within the range that is obvious to a person skilled in the art from the following description.

1A is a block diagram showing the configuration of a voltage sensing device, a battery, a first conversion unit, and an MCU of an EVCC.
1B is a block diagram showing the configuration of a voltage sensing device, a battery, a first conversion unit, and an MCU of an EVCC.
2A is a block diagram showing the configuration of a voltage sensing device, a battery, a first conversion unit, a second conversion unit, and an MCU of an EVCC.
2B is a block diagram showing the configuration of a voltage sensing device, a battery, a first conversion unit, a second conversion unit, and an MCU of an EVCC.
3 is a block diagram showing the configuration of an insulation type voltage sensing device, a battery, a first converter, and an MCU of an EVCC.
4 is a block diagram showing the configuration of an insulation type voltage sensing device, a battery, a first conversion unit, a second conversion unit, and an MCU of an EVCC.
5 is a circuit diagram showing the overall configuration of a voltage sensing device according to an embodiment.
6 is a circuit diagram showing the overall configuration of a voltage sensing device according to an embodiment.
7 is a circuit diagram showing the overall configuration of a voltage sensing device according to an embodiment.
8 is a circuit diagram showing the overall configuration of a voltage sensing device according to an embodiment.
9 is a graph showing a voltage waveform supplied to the MCU of the EVCC according to the output voltage waveform of the battery and the output voltage of the battery.
10 is a graph showing voltage waveforms supplied to the MCU of the EVCC according to the output voltage waveform of the battery and the output voltage of the battery.

The foregoing and further aspects are embodied through the embodiments described with reference to the accompanying drawings. It is to be understood that the components of each embodiment are capable of various combinations within an embodiment as long as no other mention or mutual contradiction exists. Furthermore, the proposed invention may be embodied in many different forms and is not limited to the embodiments described herein.

In order to clearly illustrate the claimed invention, parts not related to the description are omitted, and like reference numerals are used for like parts throughout the specification. And, when a section is referred to as " including " an element, it does not exclude other elements unless specifically stated to the contrary.

In addition, throughout the specification, when a part is referred to as being "connected" to another part, it is not limited to a case where it is "directly connected", but also an "electrically connected" . Further, in the specification, a signal means a quantity of electricity such as a voltage or a current.

As used herein, the term " block " refers to a block of hardware or software configured to be changed or pluggable, i.e., a unit or block that performs a specific function in hardware or software.

1A is a block diagram showing the configuration of a voltage sensing device 300, a battery 100, a first conversion unit 200, and an MCU of an EVCC.

The first converter 200 and the voltage sensing device 300 shown in FIG. 1A can be implemented in a non-isolated manner. The non-isolated type is a non-isolated input and output.

The voltage sensing device 300 may be implemented as a switching device that receives the voltage of the battery 100 and supplies the voltage output from the first conversion unit 200 to the MCU of the EVCC.

The voltage sensing device 300 receives the voltage of the battery 100. The voltage of the battery 100, that is, the output voltage range of the battery 100 is 2 to 40V. The voltage sensing device 300 may be provided in an electric vehicle (EV). In detail, an insulated multi-input regulator may be provided in a Communication Controller of Electric Vehicle (EVCC).

The battery 100 outputs a voltage. The voltage range that the battery 100 outputs is, for example, 2 to 40V. But is not limited thereto and is 6 to 36V.

The first converter 200 converts the voltage of the battery 100 into a voltage required by various devices included in the electric vehicle and supplies the converted voltage. The first converter 200 supplies a voltage required for a CAN (Controller Area Network) transmitter included in a communication controller of an electric vehicle. But is not limited to this, and supplies the main voltage of the micro controller unit (MCU) included in the communication controller or the core voltage of the microcontroller unit.

A microcontroller unit refers to a computer that makes a microprocessor and an input / output module into one chip and performs predetermined functions.

The first converter 200 may include a DC to DC converter, a low drop output (LDO), and the like.

When the voltage supplied by the battery 100 is within a predetermined input range,

A voltage output from the first conversion unit 200 for converting a voltage supplied from the battery 100 is supplied to an MCU (micro controller unit) of a communication controller of an electric vehicle (EVCC).

The preset input range is 5 ~ 20V. In detail, it is 9 ~ 16V. The voltage output by the first conversion unit 200, which converts the voltage supplied from the battery 100, is 4 to 5V. In detail, it is 5V.

The voltage sensing device 300 controls the switching device so that the 5V output from the first conversion unit 200 is supplied to the MCU of the communication controller of the electric vehicle when the power supplied from the battery 100 is 9 to 16V.

1B is a block diagram showing the configuration of a voltage sensing device, a battery, a first conversion unit, and an MCU of an EVCC. In addition to the configuration shown in FIG. 1A, the EVCC MCU receives a voltage from the battery. At this time, the MCU receives a battery voltage to monitor a voltage output from the battery. The current supplied by the battery is supplied to the MCU via a resistor.

The resistance value is set so that the voltage supplied to the MCU is 5 V or less regardless of the output voltage of the battery. As a result, the MCU can monitor the output voltage of the battery in units of several mV.

FIG. 2A is a block diagram showing the configuration of the voltage sensing device 300, the battery 100, the first conversion unit 200, the second conversion unit, and the MCU of the EVCC.

The first converter 200 shown in FIG. 2A is non-isolated and the voltage sensing device 300 can be implemented as an isolated type. The voltage sensing device 300 includes a photocoupler U2 to isolate the input and output stages.

The voltage sensing device includes an optocoupler U2. When the voltage supplied by the battery 100 is within a preset input range, a second converter for converting the voltage supplied from the battery 100 outputs Voltage to the light emitting portion of the photocoupler U2 and supplies the voltage output from the first converter 200 to the communication controller of the electric vehicle through the light receiving portion of the photocoupler U2. EVCC) microcontroller unit (MCU).

As shown in FIG. 2A, the voltage sensing device 300 includes a photocoupler U2.

The preset input range is 5 ~ 20V. In detail, it is 9 ~ 16V. The voltage output by the second conversion unit for converting the voltage supplied from the battery 100 is 4 to 5V. In detail, it is 5V. However, the present invention is not limited to the voltage range described above.

The voltage sensing device 300 controls the switching device so that the 5V output from the second converting part is applied to the light emitting part of the photocoupler U2 when the power supplied from the battery 100 is 9 to 16V.

The second conversion unit may include a DC to DC converter, a low drop output (LDO), and the like.

The voltage output by the first converter 200 as the current flows through the light emitting unit of the photocoupler U2 is supplied to the communication controller of the electric vehicle EVCC through the light receiving unit of the photocoupler U2, Of the microcontroller unit (MCU).

When the power supplied from the battery 100 is 9 to 16 V, the voltage sensing device 300 controls the switching device to supply the voltage converted by the second converting unit to the light emitting unit of the photocoupler U2, The 5V output from the control unit 200 is supplied to the MCU of the communication controller of the electric vehicle. Here, the first transform unit 200 and the second transform unit may be physically separate transform units. The present invention is not limited to this, and the first conversion unit 200 and the second conversion unit may be physically identical conversion units.

2B is a block diagram showing the configuration of a voltage sensing device, a battery, a first conversion unit, a second conversion unit, and an MCU of an EVCC. In addition to the configuration shown in FIG. 2A, a photocoupler 600 is additionally provided for the EVCC's MCU to monitor the battery voltage. The light emitting portion of the photocoupler 600 receives the battery voltage. As the output voltage of the battery becomes larger, the light emitting portion irradiates more light, so that more current flows through the light receiving portion.

The resistance value connected to the light emitting portion of the photocoupler 600 is set so that the voltage supplied to the MCU is 5 V or less irrespective of the output voltage of the first conversion portion. As a result, the MCU can monitor the output voltage of the battery in units of several mV.

3 is a block diagram showing the configuration of an insulation type voltage sensing device 300, a battery 100, a first conversion unit 200, and an MCU of an EVCC. The first conversion unit 200 shown in FIG. 3 may be an insulation type and the voltage sensing device 300 may be non-integrated. The first conversion unit 200 may include a flyback converter so that an input terminal and an output terminal may be insulated.

In FIG. 3, a configuration for monitoring the battery voltage of the MCU may be added as shown in FIG. 1B or FIG. 2B.

4 is a block diagram showing the configuration of an insulation type voltage sensing device 300, a battery 100, a first conversion unit 200, a second conversion unit, and an MCU of an EVCC. The first converter 200 shown in FIG. 4 is non-isolated and the voltage sensing device 300 can also be implemented as a non-isolated type. The first conversion unit 200 may include a flyback converter so that an input terminal and an output terminal may be insulated. The voltage sensing device 300 may include an optocoupler U2 to isolate the input and output stages.

The first conversion unit 200 may be an insulation type in which an input end and an output end are insulated or a non-insulation type in which an input end and an output end are not insulated. When the input terminal and the output terminal of the first conversion unit 200 are of an insulated type, the first conversion unit 200 may include a flyback converter. When the input and output terminals of the first conversion unit 200 are non-insulated and non-insulated, the first conversion unit 200 may include a divide converter, an LDO, or the like.

In FIG. 4, a configuration for monitoring the battery voltage of the MCU may be added as shown in FIG. 1B or FIG. 2B.

The EVCC may include the first conversion unit, the voltage sensing device, the MCU of the EVCC, and may further include a second conversion unit.

5 is a circuit diagram showing the overall configuration of a voltage sensing device 300 according to an embodiment.

The voltage sensing device 300 includes a second switching device Q2 having a collector connected to an end of the first conversion unit 200; And a fifth switching element (Q5) whose collector is connected to an emitter of the second switching element (Q2) and an MCU of a communication controller of the electric vehicle, wherein a voltage supplied by the battery (100) The second switching device Q2 and the fifth switching device Q5 are all turned off.

The predetermined input range of the voltage supplied by the battery 100 is 9 to 16V. That is, when the voltage V1 output from the battery 100 is less than 9V, which is the minimum value of 9-16V, both the second switching device Q2 and the fifth switching device Q5 are turned off.

When the second switching device Q2 is turned off, the voltage V2 supplied by the first conversion unit 200 may be supplied to an MCU (micro controller unit) of a Communication Controller of Electric Vehicle (EVCC) of the electric vehicle none. V2 is, for example, 5V.

The second switching device Q2 and the fifth switching device Q5 may be implemented as a MOSFET or a non-AJI (BJT).

The voltage sensing device 300 includes a second switching device Q2 having a collector connected to an end of the first conversion unit 200; And a fifth switching element (Q5) whose collector is connected to an emitter of the second switching element (Q2) and an MCU of a communication controller of the electric vehicle, wherein a voltage supplied by the battery (100) The second switching element Q2 is turned on and the fifth switching element Q5 is turned off.

When the second switching device Q2 is turned on and the fifth switching device Q5 is turned off, the voltage V2 supplied from the first conversion unit 200 is supplied to the MCU (micro controller unit).

The voltage sensing device 300 includes a second switching device Q2 having a collector connected to an end of the first conversion unit 200; And a fifth switching element (Q5) whose collector is connected to an emitter of the second switching element (Q2) and an MCU of a communication controller of the electric vehicle, wherein a voltage supplied by the battery (100) The second switching element Q2 is turned on and the fifth switching element Q5 is turned on.

The case where the voltage supplied by the battery 100 exceeds the maximum value of the preset input range exceeds 16V. At this time, the second switching element Q2 is turned on and the fifth switching element Q5 is also turned on so that the voltage V2, which is supplied by the first conversion part 200, is supplied to the communication controller of the EVCC It can not be supplied to an MCU (micro controller unit). The second switching element Q2 is turned on and the current supplied by the first converting part 200 flows through the second switching element Q2 but the current flows to the ground through the fifth switching element Q5 Because.

That is, when the fifth switching device Q5 is turned on, current is supplied to a micro controller unit (MCU) of a Communication Controller of Electric Vehicle (EVCC) of an electric vehicle connected to the collector of the fifth switching device Q5 Can not flow.

The voltage sensing device 300 includes a first shunt regulator U1 to which an output voltage of the battery 100 is divided and is supplied to a reference terminal; A first switching element Q1 whose gate is connected to the cathode of the first shunt regulator; A fourth switching element Q4 whose base is connected to the source of the first switching element Q1; A third shunt regulator U3 in which an output voltage of the battery 100 is distributed and supplied to a reference terminal; A third switching element Q3 whose gate is connected to the cathode of the third shunt regulator; A second switching device Q2 whose base is connected to the source of the third switching device Q3 and whose collector is connected to the positive end of the first converting part 200; And a base connected to the emitter of the fourth switching device Q4 and a collector connected to the emitter of the second switching device Q2 and the MCU 400 of the communication controller of the electric vehicle Q5).

The output voltage of the battery 100 is distributed to the resistor R12 and the resistor R14 so that the voltage across the resistor R14 is applied to the reference terminal of the first shunt regulator U1. When a voltage equal to or higher than the reference voltage is applied to the reference terminal of the first shunt regulator (U1), the first shunt regulator (U1) is turned on. The reference voltage is, for example, 1 to 4 V, and specifically 2.5 V.

A resistor R3 is connected to the cathode of the first shunt regulator and a ground is connected to the eNode.

The gate of the first switching device Q1 is connected to the cathode of the first shunt regulator. The first switching element Q1 may be implemented as a MOSFET or a non-AJI (BJT). In detail, it can be implemented as a P-channel MOSFET (MOSFET).

When a voltage equal to or higher than the reference voltage is applied to the reference terminal of the first shunt regulator U1, a voltage equal to or lower than the reference voltage is applied to the gate of the first switching device Q1. Since the first switching device Q1 is a P-channel MOSFET, the first switching device Q1 is turned on.

The base of the fourth switching device Q4 is connected to the source of the first switching device Q1. The fourth switching element Q4 is a MOSFET or a non-ATI, and in detail, a non-ATI. When the first switching element Q1 is turned on, the fourth switching element Q4 is also turned on. When the fourth switching device Q4 is turned on, the current supplied from the first conversion unit 200 is applied to the base of the fifth switching device Q5 through the fourth switching device Q4.

And is connected to the collector of the fourth switching device Q4 and the positive terminal of the first converter 200. And is connected to the emitter of the fourth switching device Q4 and the base of the fifth switching device Q5.

That is, when the fourth switching device Q4 is turned on, the fifth switching device Q5 is also turned on.

The output voltage of the battery 100 is distributed to the third shunt regulator U3 and supplied to the reference terminal. The output voltage of the battery 100 is distributed to the resistor R13 and the resistor R17 so that the voltage across the resistor R17 is applied to the reference terminal of the third shunt regulator U3. When a voltage equal to or higher than the reference voltage is applied to the reference terminal of the third shunt regulator (U3), the third shunt regulator (U3) is turned on. The reference voltage is, for example, 1 to 4 V, and specifically 2.5 V.

A resistor R2 is connected to the cathode of the third shunt regulator, and the node E is connected to the ground.

And the gate of the third switching device Q3 is connected to the cathode of the third shunt regulator. And the gate of the third switching device Q3 is connected to the cathode of the third shunt regulator. The third switching element Q3 may be implemented as a MOSFET or a non-AJT (BJT). In detail, it can be implemented as a P-channel MOSFET (MOSFET).

When a voltage equal to or higher than the reference voltage is applied to the reference terminal of the third shunt regulator U3, a voltage lower than the reference voltage is applied to the gate of the third switching device Q3. When a voltage lower than the reference voltage is applied to the gate of the third switching device Q3, since the third switching device Q3 is a P-channel MOSFET, the third switching device Q3 is turned on.

The second switching device Q2 has a base connected to the source of the third switching device Q3 and a collector connected to the positive end of the first converting part 200. [

And the base of the second switching element Q2 is connected to the source of the third switching element. The second switching element Q2 is a MOSFET or non-ATI, and in detail, non-ATI. When the third switching element Q3 is turned on, the second switching element Q2 is also turned on. When the second switching device Q2 is turned on, the current supplied by the first converter 200 is supplied to the MCU 400 of the communication controller of the electric vehicle through the second switching device Q2.

The fifth switching device Q5 has a base connected to the emitter of the fourth switching device Q4 and a collector connected to the emitter of the second switching device Q2 and the MCU 400 of the communication controller of the electric vehicle .

V4 shown in Fig. 5 is a voltage supplied to the MCU 400 of the communication controller of the electric vehicle. If both the fifth switching element Q5 and the second switching element Q2 are turned on, the current flowing through the second switching element Q2 flows to the fifth switching element Q5. In this case, no current is supplied to the MCU 400 of the communication controller of the electric vehicle.

The voltage sensing device 300 includes a fifth resistor R5 having one end connected to the positive end of the first conversion unit 200 and the other end connected to the collector of the fourth switching device Q4. The voltage sensing device 300 includes a tenth resistor R10 whose one end is connected to the positive end of the first converter 200 and the other end is connected to the collector of the second switching device Q2.

The operation of the switching devices according to the voltage of the battery 100 will be described.

The resistors R12, R14, R13, and R17 are designed such that a voltage less than the reference voltage is applied to the first shunt regulator U1 and the third shunt regulator U3 when the voltage of the battery 100 is less than 9V. When the voltage of the battery 100 is less than 9 V, the first shunt regulator U1 and the third shunt regulator U3 are not turned on, so that the first switching device Q1 and the third switching device Q3 are turned off . As the first switching device Q1 is turned off, the fourth switching device Q4 is turned off. As the fourth switching device Q4 is turned off, the fifth switching device Q5 is also turned off.

As the third switching element Q3 is turned off, the second switching element Q2 is also turned off.

All the switching elements are turned off and no current is supplied to the MCU 400 of the communication controller.

A case where the voltage of the battery 100 is 9 to 16 V will be described. In this case, the resistors R13 and R17 are designed so that a voltage equal to or higher than the reference voltage of the third shunt regulator U3 is applied. The resistors R12 and R14 are designed so that a voltage lower than the reference voltage of the first shunt regulator U1 is applied. As a result, R17 / (R13 + R17) is larger than R14 / (R12 + R14).

As the third shunt regulator U3 conducts, the third switching device Q3 is turned on and the second switching device Q2 is also turned on. The first shunt regulator is not conducted, and the fourth switching device Q4 is turned off. As the fourth switching device Q4 is turned off, the fifth switching device Q5 is also turned off.

The current output from the first converter 200 is finally supplied to the MCU 400 of the communication controller through the second switching device Q2.

The case where the voltage of the battery 100 exceeds 16V will be described. In this case, the resistors R12, R14, R13, and R17 are designed such that both the third shunt regulator U3 and the first shunt regulator U1 are conductive.

As the third shunt regulator U3 conducts, the third switching device Q3 is turned on and the second switching device Q2 is also turned on. As the first shunt regulator becomes conductive, the fourth switching device Q4 is turned on. As the fourth switching element Q4 is turned on, the fifth switching element Q5 is also turned on.

The current output by the first converter 200 is finally passed through the second switching element Q2 but flows through the fifth switching element Q5. As a result, no current is supplied to the MCU 400 of the communication controller.

As described above, the voltage sensing device 300 controls the MCU 400 of the communication controller to supply current only when the voltage of the battery 100 is 9 to 16V. The first converter 200 is designed to output a voltage of 5 V regardless of the output voltage of the battery 100. Since the battery 100 has a voltage range of 40 V or less, when the voltage of the battery 100 is too high or too low, the first conversion unit 200 may fail to output a voltage of 5 V correctly. 5V should be applied as the main voltage of the MCU 400 of the communication controller. If 5V is not applied, the MCU 400 may perform an abnormal operation.

It is necessary to supply the voltage to the MCU 400 of the communication controller only in the voltage range of the battery 100 in which the first converter 200 can stably supply 5V.

6 is a circuit diagram showing the overall configuration of the voltage sensing device 300 according to one embodiment. Description of the same components as those shown in Fig. 5 will be omitted.

The voltage sensing device 300 may further include a first diode whose node E is connected to the source terminal of the first switching device Q1. The voltage sensing device 300 may further include a second diode whose eNode is connected to the source terminal of the third switching device Q3. The voltage sensing device 300 may further include a seventh diode whose node E is connected to the positive end of the first transforming part 200.

The first diode, the second diode, and the seventh diode prevent a reverse current from flowing.

The voltage sensing device 300 may further include a second capacitor C2 having one end connected to the cathode of the first diode and the other end connected to the ground. The voltage sensing device 300 may further include a third capacitor C3 having one end connected to the cathode of the second diode and the other end connected to the ground. The voltage sensing device 300 may further include a first capacitor C1 having one end connected to the collector of the fifth switching device Q5 and the other end connected to the emitter of the fifth switching device Q5.

The second capacitor C2, the third capacitor C3 and the first capacitor C1 remove the noise and the ripple included in the current output from the battery 100 or the first conversion unit 200.

The voltage sensing device 300 includes a first resistor R1 having one end connected to the cathode of the first diode and the other end connected to the base of the fourth switching device Q4. The voltage sensing device 300 includes a fifth resistor R5 having one end connected to the cathode of the seventh diode and the other end connected to the collector of the fourth switching device Q4. The voltage sensing device 300 includes a tenth resistor R10 having one end connected to the cathode of the seventh diode and the other end connected to the collector of the second switching device Q2. The voltage sensing device 300 may further include an eleventh resistor R11 having one end connected to the collector of the fifth switching device Q5 and the other end connected to the emitter of the fifth switching device Q5. The voltage sensing device 300 includes a second resistor R2 having one end connected to the cathode of the second diode and the other end connected to the base of the second switching device Q2.

The first resistor R1, the fifth resistor R5, the second resistor R2 and the tenth resistor R10 prevent an overcurrent from flowing to the switching element and the eleventh resistor is connected to the dummy resistor Thereby preventing an overcurrent from flowing to the MCU 400 of the controller.

7 is a circuit diagram showing the overall configuration of a voltage sensing device 300 according to an embodiment. Fig. 7 shows the overall configuration of an insulation type voltage sensing device 300. Fig.

The voltage sensing device 300 includes a light receiving unit having one end connected to the positive end of the first conversion unit 200 and the other end connected to the MCU 400 of the communication controller of the electric vehicle, U2); A second switching element Q2 whose collector is connected to the positive terminal of the first converter 200; And a fifth switching element (Q5) having a collector connected to an emitter of the second switching element (Q2) and one end of the light emitting portion, wherein a voltage supplied from the battery (100) When the voltage is less than the minimum value, both the second switching element Q2 and the fifth switching element Q5 are turned off.

The second switching device Q2 and the fifth switching device Q5 may be implemented as a MOSFET or a non-AJI (BJT).

The predetermined input range of the voltage supplied by the battery 100 is 9 to 16V. That is, when the voltage V1 output from the battery 100 is less than 9V, which is the minimum value of 9-16V, both the second switching device Q2 and the fifth switching device Q5 are turned off.

When the second switching device Q2 is turned off, the voltage V2 supplied from the first conversion unit 200 is supplied to the MCU 400 (micro controller unit) of the EVCC Can not be supplied. V2 is, for example, 5V.

In detail, when the second switching element Q2 is turned off, a current corresponding to the voltage V3 outputted by the second conversion section can not be applied to the light emitting portion. Accordingly, the current corresponding to the voltage V2 output by the first converter 200 through the light-receiving unit can not pass through the light-receiving unit. V4 is a voltage supplied to the MCU 400 (micro controller unit) of a communication controller of an electric vehicle (EVCC) with a voltage applied to the load.

The voltage sensing device 300 includes a light receiving unit having one end connected to the positive end of the first conversion unit 200 and the other end connected to the MCU 400 of the communication controller of the electric vehicle, U2); A second switching element Q2 whose collector is connected to the positive terminal of the first converter 200; And a fifth switching element (Q5) having a collector connected to an emitter of the second switching element (Q2) and one end of the light emitting portion, wherein a voltage supplied by the battery (100) If so, the second switching element Q2 is turned on and the fifth switching element Q5 is turned off.

When the second switching element Q2 is turned on and the fifth switching element Q5 is turned off, the current supplied from the second converting part flows to the light emitting part. Accordingly, the voltage V2 output by the first conversion unit 200 may be supplied to an MCU (micro controller unit) 400 of a communication controller of an electric vehicle (EVCC).

The voltage sensing device 300 includes a light receiving unit having one end connected to the positive end of the first conversion unit 200 and the other end connected to the MCU 400 of the communication controller of the electric vehicle, U2); A second switching element Q2 whose collector is connected to the positive terminal of the first converter 200; And a fifth switching element (Q5) having a collector connected to an emitter of the second switching element (Q2) and one end of the light emitting portion, wherein a voltage supplied by the battery (100) If the maximum value is exceeded, the second switching element Q2 is turned on and the fifth switching element Q5 is turned on.

The case where the voltage supplied by the battery 100 exceeds the maximum value of the preset input range exceeds 16V. At this time, the second switching element Q2 is turned on and the fifth switching element Q5 is also turned on so that the current supplied by the second converting element flows through the second switching element Q2, but the current flows through the fifth switching element Q5 ) To ground.

In other words, when the fifth switching element Q5 is on, a current flows to the fifth switching element Q5, and a current can not flow through the light emitting portion. Accordingly, the current supplied by the first conversion unit 200 can not flow to the MCU 400 (micro controller unit) of the EVCC (Communication Controller of Electric Vehicle).

The voltage sensing device 300 includes a light receiving unit having one end connected to the positive end of the first conversion unit 200 and the other end connected to the MCU 400 of the communication controller of the electric vehicle, U2); A first shunt regulator (U1) in which the output voltage of the battery (100) is distributed and supplied to a reference terminal; A first switching element Q1 whose gate is connected to the cathode of the first shunt regulator; A fourth switching element Q4 whose base is connected to the source of the first switching element Q1; A third shunt regulator U3 in which an output voltage of the battery 100 is distributed and supplied to a reference terminal; A third switching element Q3 whose gate is connected to the cathode of the third shunt regulator; A second switching device Q2 whose base is connected to the source of the third switching device Q3 and whose collector is connected to the positive end of the first converting part 200; And a fifth switching element Q5 whose base is connected to the emitter of the fourth switching element Q4 and whose collector is connected to the emitter of the second switching element Q2.

Repeated description of FIG. 5 will be omitted. One end of the light emitting portion of the photocoupler U2 is connected to the collector of the fifth switching element Q5 and the other end is connected to the emitter of the fifth switching element Q5. The light receiving unit has one end connected to the positive end of the first converting unit 200 and the other end connected to the MCU 400 (micro controller unit) of the EVCC. The current output from the first converter 200 is supplied to the MCU 400 (micro controller unit) of the Communication Controller of Electric Vehicle (EVCC) only when current flows in the light emitting unit.

The operation of the switching devices according to the voltage of the battery 100 will be described.

The resistors R12, R14, R13, and R17 are designed such that a voltage less than the reference voltage is applied to the first shunt regulator U1 and the third shunt regulator U3 when the voltage of the battery 100 is less than 9V. When the voltage of the battery 100 is less than 9 V, the first shunt regulator U1 and the third shunt regulator U3 are not turned on, so that the first switching device Q1 and the third switching device Q3 are turned off . As the first switching device Q1 is turned off, the fourth switching device Q4 is turned off. As the fourth switching device Q4 is turned off, the fifth switching device Q5 is also turned off.

As the third switching element Q3 is turned off, the second switching element Q2 is also turned off.

All the switching elements are turned off, no current flows through the light emitting portion, and accordingly no current is supplied to the MCU 400 of the communication controller.

A case where the voltage of the battery 100 is 9 to 16 V will be described. In this case, the resistors R13 and R17 are designed so that a voltage equal to or higher than the reference voltage of the third shunt regulator U3 is applied. The resistors R12 and R14 are designed so that a voltage lower than the reference voltage of the first shunt regulator U1 is applied. As a result, R17 / (R13 + R17) is larger than R14 / (R12 + R14).

As the third shunt regulator U3 conducts, the third switching device Q3 is turned on and the second switching device Q2 is also turned on. The first shunt regulator is not conducted, and the fourth switching device Q4 is turned off. As the fourth switching device Q4 is turned off, the fifth switching device Q5 is also turned off.

The current output by the second conversion unit eventually flows to the light emitting unit through the second switching device Q2. Accordingly, the current supplied by the first conversion unit 200 is supplied to the MCU 400 of the communication controller.

The case where the voltage of the battery 100 exceeds 16V will be described. In this case, the resistors R12, R14, R13, and R17 are designed such that both the third shunt regulator U3 and the first shunt regulator U1 are conductive.

As the third shunt regulator U3 conducts, the third switching device Q3 is turned on and the second switching device Q2 is also turned on. As the first shunt regulator becomes conductive, the fourth switching device Q4 is turned on. As the fourth switching element Q4 is turned on, the fifth switching element Q5 is also turned on.

The current outputted by the second conversion section eventually flows through the second switching element Q2 but flows through the fifth switching element Q5. As a result, no current flows through the light emitting portion, and the current output from the first conversion portion 200 is not supplied to the MCU 400 of the communication controller.

8 is a circuit diagram showing the overall configuration of the voltage sensing device 300 according to one embodiment.

The voltage sensing device 300 may further include a first diode whose node E is connected to the source terminal of the first switching device Q1. The voltage sensing device 300 may further include a second diode whose eNode is connected to the source terminal of the third switching device Q3. The voltage sensing device 300 may further include a seventh diode whose node E is connected to the positive end of the second transforming part.

The first diode, the second diode, and the seventh diode prevent a reverse current from flowing.

The voltage sensing device 300 may further include a second capacitor C2 having one end connected to the cathode of the first diode and the other end connected to the ground. The voltage sensing device 300 may further include a third capacitor C3 having one end connected to the cathode of the second diode and the other end connected to the ground. The voltage sensing device 300 may further include a first capacitor C1 having one end connected to the collector of the fifth switching device Q5 and the other end connected to the emitter of the fifth switching device Q5.

The second capacitor C2, the third capacitor C3 and the first capacitor C1 remove the noise and the ripple included in the current output from the battery 100 or the first conversion unit 200.

The voltage sensing device 300 includes a first resistor R1 having one end connected to the cathode of the first diode and the other end connected to the base of the fourth switching device Q4. The voltage sensing device 300 includes a fifth resistor R5 having one end connected to the cathode of the seventh diode and the other end connected to the collector of the fourth switching device Q4. The voltage sensing device 300 includes a tenth resistor R10 having one end connected to the cathode of the seventh diode and the other end connected to the collector of the second switching device Q2. The voltage sensing device 300 may further include an eleventh resistor R11 having one end connected to the collector of the fifth switching device Q5 and the other end connected to the emitter of the fifth switching device Q5. The eleventh resistor R11 is also connected to the light emitting portion.

The voltage sensing device 300 may further include a fourth resistor having one end connected to the light receiving unit and the other end connected to the ground. The fourth resistor is connected in parallel with the MCU 400 of the communication controller of the electric vehicle.

The first resistor R1, the fifth resistor R5, and the tenth resistor R10 prevent the overcurrent from flowing to the switching element, and the eleventh resistor prevents the overcurrent from flowing to the light emitting portion. The fourth resistor prevents an overcurrent from flowing to the MCU 400 of the communication controller of the electric vehicle.

9 is a graph showing a voltage waveform supplied to the MCU 400 of the EVCC according to the output voltage waveform of the battery 100 and the output voltage of the battery 100. As shown in FIG.

9 is a graph showing a voltage waveform supplied to the MCU 400 of the EVCC according to the output voltage waveform of the battery 100 and the output voltage of the battery 100 in the voltage sensing apparatus 300 according to FIGS. to be. In order to output the waveform shown in Fig. 9, the sizes of the respective elements (resistors, capacitors, etc.) of Figs. 5 and 6 may be different from each other.

The green graph is a voltage waveform output from the battery 100, and the red graph is a voltage waveform supplied to the EVCC MCU 400.

Referring to FIG. 9, no voltage is supplied to the EVCC MCU 400 during a period Va in which the voltage of the battery 100 exceeds 16V. The voltage is supplied to the MCU 400 of the EVCC when the voltage of the battery 100 is in the range of 9 to 16 V during the Vb interval. The voltage is not supplied to the EVCC MCU 400 during the Vc period when the voltage of the battery 100 is less than 9V.

10 is a graph showing a voltage waveform supplied to the MCU 400 of the EVCC according to the output voltage waveform of the battery 100 and the output voltage of the battery 100. As shown in FIG.

10 is a graph showing voltage waveforms supplied to the MCU 400 of the EVCC according to the output voltage waveform of the battery 100 and the output voltage of the battery 100 in the voltage sensing apparatus 300 according to FIGS. to be. In order to output the waveform shown in Fig. 10, the sizes of the respective elements (resistors, capacitors, etc.) in Figs. 7 and 8 may be different from each other.

The green graph is a voltage waveform output by the battery 100, the blue graph is a voltage waveform supplied to the MCU 400 of the EVCC, and the red waveform is a voltage applied to the light emitting portion of the photocoupler U2.

Referring to FIG. 10, no voltage is supplied to the EVCC MCU 400 during a period Va in which the voltage of the battery 100 exceeds 16V. The voltage is supplied to the MCU 400 of the EVCC when the voltage of the battery 100 is in the range of 9 to 16 V during the Vb interval. The voltage is not supplied to the EVCC MCU 400 during the Vc period when the voltage of the battery 100 is less than 9V.

Thus, those skilled in the art will appreciate that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative only and not restrictive of the scope of the invention. It is also to be understood that the flow charts shown in the figures are merely the sequential steps illustrated in order to achieve the most desirable results in practicing the present invention and that other additional steps may be provided or some steps may be deleted .

As such, the specification is not intended to limit the invention to the precise form disclosed. While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications, and variations will be apparent to those skilled in the art without departing from the spirit and scope of the present invention as defined by the appended claims. It is possible to apply a deformation.

The scope of the present invention is defined by the appended claims rather than the foregoing description, and all changes or modifications derived from the meaning and scope of the claims and equivalents thereof are deemed to be included in the scope of the present invention. .

100: Battery
200: first conversion section
300: voltage sensing device
400: MCU
500: second conversion section
Q1: the first switching element
Q2: the second switching element
Q3: Third switching element
Q4: Fourth switching element
Q5: The fifth switching element
U1: First shunt regulator
U2: Photo coupler
U3: Third shunt regulator
R1: first resistance
R5: fifth resistor
R6: sixth resistor
R10: 10th resistor
R11: 11th resistor
C1: first capacitor
C2: second capacitor
C3: third capacitor

Claims (11)

If the voltage supplied by the battery is within the preset input range,
And supplies the voltage output from the first conversion unit for converting the voltage supplied from the battery to a micro controller unit (MCU) of a Communication Controller of Electric Vehicle (EVCC)
Voltage sensing device
The method according to claim 1,
Wherein the voltage sensing device comprises a photocoupler,
When the voltage supplied by the battery is within a predetermined input range,
A voltage output by the second conversion unit for converting the voltage supplied by the battery is supplied to the light emitting unit of the photocoupler,
A voltage sensing device for supplying a voltage output from the first conversion unit to a microcontroller unit (MCU) of a communication controller of an electric vehicle (EVCC) through a photoreceptor of the photocoupler;
The method according to claim 1,
The first conversion unit
Isolation type with input and output ends insulated or non-insulated type with input and output terminals
Voltage sensing device
The method according to claim 1,
The voltage sensing device
A second switching element having a collector connected to an end of the first conversion unit; And
And a fifth switching element whose collector is connected to the emitter of the second switching element and the MCU of the communication controller of the electric vehicle
When the voltage supplied by the battery is less than the minimum value of the predetermined input range, the voltage detecting device in which both the second switching device and the fifth switching device are turned off

The method according to claim 1,
The voltage sensing device
A second switching element having a collector connected to an end of the first conversion unit; And
And a fifth switching element whose collector is connected to the emitter of the second switching element and the MCU of the communication controller of the electric vehicle
When the voltage supplied by the battery is within the preset input range, the second switching element is turned on and the fifth switching element is turned off.
The method according to claim 1,
The voltage sensing device
A second switching element having a collector connected to an end of the first conversion unit; And
And a fifth switching element whose collector is connected to the emitter of the second switching element and the MCU of the communication controller of the electric vehicle
When the voltage supplied by the battery exceeds the maximum value of the predetermined input range, the second switching element is turned on and the fifth switching element is also turned on.
The method according to claim 1,
The voltage sensing device
A first shunt regulator in which an output voltage of the battery is distributed and supplied to a reference terminal;
A first switching device having a gate connected to a cathode of the first shunt regulator;
A fourth switching element whose base is connected to the source of the first switching element;
A third shunt regulator in which an output voltage of the battery is distributed and supplied to a reference terminal;
A third switching element whose gate is connected to the cathode of the third shunt regulator;
A second switching element whose base is connected to the source of the third switching element and whose collector is connected to the positive terminal of the first conversion part; And
And a fifth switching element whose base is connected to the emitter of the fourth switching element and whose collector is connected to the emitter of the second switching element and the MCU of the communication controller of the electric vehicle.
The method according to claim 1,
The voltage sensing device
A photocoupler including a light receiving portion having one end connected to the positive end of the first converting portion and the other end connected to the MCU of the communication controller of the electric vehicle, the photocoupler further including a light emitting portion;
A second switching element having a collector connected to an end of the first conversion unit; And
And a fifth switching element to which a collector is connected to the emitter of the second switching element and to one end of the light emitting portion,
When the voltage supplied by the battery is less than the minimum value of the predetermined input range, the voltage detecting device in which both the second switching device and the fifth switching device are turned off
The method according to claim 1,
The voltage sensing device
A photocoupler including a light receiving portion having one end connected to the positive end of the first converting portion and the other end connected to the MCU of the communication controller of the electric vehicle, the photocoupler further including a light emitting portion;
A second switching element having a collector connected to an end of the first conversion unit; And
And a fifth switching element to which a collector is connected to the emitter of the second switching element and to one end of the light emitting portion,
When the voltage supplied by the battery is within the preset input range, the second switching element is turned on and the fifth switching element is turned off.
The method according to claim 1,
The voltage sensing device
A photocoupler including a light receiving portion having one end connected to the positive end of the first converting portion and the other end connected to the MCU of the communication controller of the electric vehicle, the photocoupler further including a light emitting portion;
A second switching element having a collector connected to an end of the first conversion unit; And
And a fifth switching element to which a collector is connected to the emitter of the second switching element and to one end of the light emitting portion,
When the voltage supplied by the battery exceeds the maximum value of the predetermined input range, the second switching element is turned on and the fifth switching element is also turned on.
The method according to claim 1,
The voltage sensing device
A photocoupler including a light receiving portion having one end connected to the positive end of the first converting portion and the other end connected to the MCU of the communication controller of the electric vehicle, the photocoupler further including a light emitting portion;
A first shunt regulator in which an output voltage of the battery is distributed and supplied to a reference terminal;
A first switching device having a gate connected to a cathode of the first shunt regulator;
A fourth switching element whose base is connected to the source of the first switching element;
A third shunt regulator in which an output voltage of the battery is distributed and supplied to a reference terminal;
A third switching element whose gate is connected to the cathode of the third shunt regulator;
A second switching element whose base is connected to the source of the third switching element and whose collector is connected to the positive terminal of the first conversion part; And
And a fifth switching element whose base is connected to the emitter of the fourth switching element and whose collector is connected to the emitter of the second switching element,

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