KR102599288B1 - Control apparatus for vehicle - Google Patents

Abstract

Embodiments include a shift control device powered from a battery; and a first power supply line wired between the battery and the shift control device; and a second power supply line branched from a first node on the first power supply line and connected between the first power supply line and the shift control device, wherein the shift control device supplies the first power supply. a motor switching unit connected to a second node arranged on the line; and a power supply device connected to a third node disposed on the first power supply line and the second power supply line; a first rectifier disposed between the second node and the third node; and a second rectifier connected to a third node and disposed on the second power supply line.

Description

Vehicle control device {CONTROL APPARATUS FOR VEHICLE}

The embodiment relates to a vehicle control device.

The rotating shaft of the motor is connected to the actuator to transmit driving force. At this time, depending on the characteristics of the actuator, the motor and actuator may be manufactured as one piece. For example, a motor and an actuator can be implemented together in the same housing, or a tube-shaped rotor can be used so that the drive shaft of the actuator and the rotation shaft of the motor are integrated. Additionally, a control unit that controls the motor according to the state of the actuator may be provided.

Conventional actuators have a problem in that it is difficult to accurately determine whether the battery power line that supplies power is disconnected.

Additionally, when the battery power line is disconnected, there is a limit to the circuit being damaged by the high current flowing through the motor and battery power line.

The embodiment provides a vehicle control device that protects lines from overcurrent.

Additionally, a vehicle control device that blocks current caused by back electromotive force of a motor is provided.

The problem to be solved in the embodiment is not limited to this, and it will also include means of solving the problem described below and purposes and effects that can be understood from the embodiment.

A vehicle control device according to an embodiment includes a shift control device that receives power from a battery; and a first power supply line wired between the battery and the shift control device; and a second power supply line branched from a first node on the first power supply line and connected between the first power supply line and the shift control device, wherein the shift control device supplies the first power supply. a motor switching unit connected to a second node arranged on the line; and a power supply device connected to a third node disposed on the first power supply line and the second power supply line; a first rectifier disposed between the second node and the third node; and a second rectifier connected to a third node and disposed on the second power supply line.

The first rectifying part includes a first diode, and the second rectifying part includes a second diode, and the cathode of the first diode and the second diode may be connected to the third node.

The anode of the first diode may be connected to the second node.

It may further include a charging/discharging unit disposed between the first node and the shift control device on the first power supply line.

The motor switching unit,

It includes a plurality of switching elements and can be connected to a motor.

The shift control device,

Further comprising a motor control unit connected to the third node,

The motor control unit,

A control signal that controls the three phases of the motor can be transmitted.

The third node may be disposed between the power supply device and the second node.

A vehicle according to an embodiment includes a battery; a vehicle control device that receives power from the battery; and a motor that receives output from the vehicle control device, wherein the vehicle control device includes: a shift control device that receives power from a battery; a first power supply line wired between the battery and the shift control device; and a second power supply line branched from a first node on the first power supply line and connected between the first power supply line and the shift control device, wherein the shift control device supplies the first power supply. a motor switching unit connected to a second node arranged on the line; and a power supply device connected to a third node disposed on the first power supply line and the second power supply line; a first rectifier disposed between the second node and the third node; and a second rectifier connected to a third node and disposed on the second power supply line.

According to the embodiment, a vehicle control device that protects lines from overcurrent can be implemented.

Additionally, it is possible to manufacture a vehicle control device that blocks the current caused by the back electromotive force of the motor.

The various and beneficial advantages and effects of the present invention are not limited to the above-described content, and may be more easily understood through description of specific embodiments of the present invention.

1 is a conceptual diagram showing a vehicle control device, battery, and motor according to an embodiment;
2 is a conceptual diagram of a vehicle control device according to an embodiment,
3 is a circuit diagram of a vehicle control device according to an embodiment,
4 is a diagram explaining control of a vehicle control device according to an embodiment,
5 is a circuit diagram illustrating the connection of the shift control device and the first power supply line and the second power supply line in the vehicle control device according to the embodiment;
Figure 6 is a diagram explaining the effect of the vehicle control device according to the embodiment,
7 is a circuit diagram of another vehicle control device illustrating the effects of the vehicle control device according to the embodiment;
FIG. 8 is a diagram illustrating a problem in the vehicle control device of FIG. 7.

Since the present invention can be subject to various changes and can have various embodiments, specific embodiments will be illustrated and described in the drawings. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

Terms containing ordinal numbers, such as second, first, etc., may be used to describe various components, but the components are not limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, the second component may be referred to as the first component without departing from the scope of the present invention, and similarly, the first component may also be referred to as the second component. The term and/or includes any of a plurality of related stated items or a combination of a plurality of related stated items.

When a component is said to be "connected" or "connected" to another component, it is understood that it may be directly connected to or connected to the other component, but that other components may exist in between. It should be. On the other hand, when it is mentioned that a component is “directly connected” or “directly connected” to another component, it should be understood that there are no other components in between.

The terms used in this application are only used to describe specific embodiments and are not intended to limit the invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, terms such as “comprise” or “have” are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person of ordinary skill in the technical field to which the present invention pertains. Terms defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and unless explicitly defined in the present application, should not be interpreted in an ideal or excessively formal sense. No.

Hereinafter, embodiments will be described in detail with reference to the attached drawings, but identical or corresponding components will be assigned the same reference numbers regardless of reference numerals, and duplicate descriptions thereof will be omitted.

First, the main features of the clutch actuator according to an embodiment of the present invention will be described in order to clearly understand the present invention conceptually. However, various modifications to this description are expected, and the scope of the present invention need not be limited by the specific description. The clutch actuator according to an embodiment of the present invention may include a motor (hereinafter corresponding to (10) in FIG. 1), a cover, a piston, and a lead screw. (Each element is not shown. ) When the motor operates, the leadscrew can rotate. And as the leadscrew rotates, the piston can move in a straight line. A fluid receiving space may be disposed inside the cover, and the piston may be located in the receiving space. Here, the clutch actuator can be mounted and driven in a vehicle, and is not limited to this type, but can be applied to various driving devices that require driving force.

The motor may include a housing, a vehicle control unit, a stator assembly, a rotor, a rotation shaft, and external sensor connections.

The housing is formed in a cylindrical shape and may include a space within which a stator assembly and a rotor can be mounted. The housing may be engaged with the cover. At this time, the shape or material of the housing may be modified in various ways, but due to the nature of the housing being mounted on a vehicle, a metal material that can withstand high temperatures may be selected. For example, a portion of the housing, that is, the front side of the housing to which the actuator is connected, may be made of aluminum. Alternatively, the entire housing may be made of aluminum.

An actuator may be coupled to the front side of the housing, and a clutch actuator vehicle control device may be coupled to the rear side of the housing. Additionally, a mounting slot into which an external sensor connection part is detachably inserted may be disposed on the rear side of the housing.

The rotation axis is located at the center of the housing and a central hole is provided to form a space to which the lead screw is connected, and a mounting slot may be formed below this central hole.

The vehicle control device controls the driving of the motor based on the status of the actuator and external drive signals received from the external sensor connection unit. This clutch actuator vehicle control device may be disposed at the rear of the housing and may be formed integrally with the housing by forming a rear cover of the housing.

Additionally, a magnet and a current sensor may be combined on one side of the motor.

*37Figure 1 is a conceptual diagram showing a vehicle control device, battery, and motor according to an embodiment.

Referring to FIG. 1 , the vehicle control device 200 according to the embodiment may be disposed between the battery 90 and the motor 10. The vehicle control device 200 may receive power from the battery 90. To this end, the vehicle control device 200 and the battery 90 may be electrically connected through a plurality of lines. Here, the battery 90 may be placed outside the clutch actuator in the vehicle, but is not limited to this. Additionally, the battery 90 and the vehicle control device 200 may be electrically connected through the external sensor connection part 600.

A first power supply line (L1), a second power supply line (L2), and a third power supply line (L3) may be disposed between the vehicle control device 200 and the battery 90. However, it is not limited to this number. Here, the first power supply line (L1), the second power supply line (L2), and the third power supply line (L3) refer to electrical lines.

The first power supply line L1 may supply power provided from the battery 90 to the vehicle control device 200. A fuse switch (S1) may be disposed on the first power supply line (L1). The fuse switch S1 may be disposed between the battery 90 and the interface unit 210. For example, the first power supply line L1 may supply a voltage of 12V provided from the battery 90 to the vehicle control device 200. For example, the first power supply line (L1) may be KL30. Additionally, the first power supply line L1 may be connected to the shift control device 220 through the interface unit 210 and the charge/discharge unit 230. The first power supply line L1 may be a constant power supply line that always supplies power to the vehicle control device 200. With this configuration, the battery 90 supplies power to the shift control device 220 through the first power supply line (L1), and the shift control device 220 boosts or decompresses the supplied power to drive the motor 10. ) can drive the control circuit (hereinafter referred to as motor control unit) that drives the motor.

The second power supply line (L2) may be branched from the first node (N ₁ ) of the first power supply line (L1) and disposed between the shift control device 220 and the first power supply line (L1). A key switch unit (not shown) may be disposed on the second power supply line (L2). The key switch unit (not shown) can cause ignition by starting the engine. For example, when the driver of the vehicle turns on the engine, current may flow from the battery 90 to the key switch unit (not shown). And the key switch unit (not shown) can generate high current and high voltage by the first and second coils. Because of this, the high voltage can ignite the mixture (not shown). For example, the second power supply line (L2) may be KL15.

The second power supply line L2 may provide the voltage of the battery 90 supplied through the first node N ₁ to the vehicle control device 200 . For example, the second power supply line L2 may supply power provided from the battery to the vehicle control device 200 according to the operation of the key switch unit (not shown).

The third power supply line L3 may be grounded. For example, the third power supply line L3 may be electrically connected to the first power supply line L1 and the second power supply line L2 and may serve as a ground. For example, the third power supply line (L3) may be KL31.

As described above, a plurality of power supply lines may be disposed between the battery 90 and the vehicle power control unit 200. Additionally, the plurality of power supply lines L1, L2 _{, and} L3 may electrically connect the battery 90 and the power control device 200 through a plurality of ports of the interface unit 210.

FIG. 2 is a conceptual diagram of a vehicle control device according to an embodiment, and FIG. 3 is a circuit diagram of a vehicle control device according to an embodiment.

Referring to FIGS. 2 and 3 , as described above, the shift control device 220 may receive power from the battery through the first power supply line L1 and the second power supply line L2.

The vehicle control device 200 may include an interface unit 210, a shift control device 220, a first power supply line (L1), a second power supply line (L2), and a third power supply line (L3). there is.

As described above, the interface unit 210 is disposed between the battery and the shift control device 220, and includes a first power supply line (L1), a second power supply line (L2), and a third power supply line (L3). can be connected

A reverse polarity protection unit (PT) and a charge/discharge unit 230 may be disposed between the shift control device 220 and the interface unit 210 in the first power supply line L1.

The reverse polarity protection unit (PT) may be connected to the first power supply line (L1). The reverse polarity protection unit (PT) may disconnect the circuit to protect the circuit when the polarity of the voltage supplied to the shift control device 220 is different from the preset polarity. For example, a positive voltage must be provided to the shift control device 220 through the first power supply line L1, but if a negative voltage is provided, a disconnection may be performed to protect the vehicle control device 200.

The charging/discharging unit 230 may include a charging element. For example, the charging element may include a capacitor, but is not limited thereto. The charging/discharging unit 230 can charge the voltage provided from the battery. One end of the charging/discharging unit 230 may be connected to the interface unit 210 and the other end may be connected to the shift control device 220 . For example, the other end of the charging/discharging unit 230 may be connected to a power supply device (PMIC).

As described above, a key switch unit (not shown) may be disposed on the second power supply line L2.

And the shift control device 220 may include a power supply unit (PMIC), a first detection unit 221, a second detection unit 222, a motor control unit 223, and a control unit 224. Additionally, the shift control device 220 may include an internal sensor 225, an external sensor interface unit 226, a communication unit 227, and a motor switching unit 228.

The power supply unit (PMIC) can control power supply to major elements within the shift control device 220. For example, the power supply device (PMIC) may provide power provided from a battery to each element in the shift control device 220. This will be explained in detail in FIGS. 4 to 8 below.

The first detection unit 221 may be disposed within the shift control device 220. For example, the first detection unit 221 may be disposed within a power supply device (PMIC), but is not limited thereto. The first detection unit 221 may detect the first voltage, which is the voltage at the rear end of the charging and discharging unit 230, on the first power supply line (L1). The first detection unit 221 may include various voltage measurement elements. Additionally, the first detection unit 221 may detect the first voltage multiple times at the rear end of the charge/discharge unit 230 on the first power supply line (L1) of the charge/discharge unit 230. For example, the first detection unit 221 may set a plurality of nodes on the first power supply line (L1) and measure the voltage for each node. With this configuration, the first voltage measured at a plurality of nodes can be compared with the second voltage below, and the vehicle control device 200 according to the embodiment can improve stability.

The second detection unit 222 may be disposed in the shift control device 220 like the first detection unit 221. For example, the second detection unit 222 may be disposed within a power supply device (PMIC), but is not limited thereto. The second detection unit 222 may detect the second voltage at the rear end of the key switch unit (not shown) on the second power supply line L2. The second detection unit 222 may include various voltage measurement elements.

The motor control unit 223 may be disposed within the shift control device 220. The shift control device 223 may be electrically connected to the first power supply line (L1). As a result, the motor control unit 223 can receive power from the battery. For example, the motor control unit 223 may transmit a motor control signal for controlling the three phases (U, V, W) of the motor to the motor switching unit 228. Accordingly, the motor switching unit 228 can switch a plurality of switches disposed therein according to the received motor control signal. Accordingly, the motor can be driven to the desired output level.

The control unit 224 may be disposed within the shift control device 220. The control unit 224 may receive power from a power supply unit (PMIC). As mentioned earlier, the power supply unit (PMIC) boosts or reduces the battery voltage provided from the first power supply line (L1) to connect the internal sensor 225 or external sensor interface 226, communication unit 227, and control unit ( 224), and can be provided to the motor control unit 223.

The control unit 224 may receive the first voltage and the second voltage from the first detection unit 221 and the second detection unit 222. Additionally, the control unit 224 may transmit a signal to stop the operation of the motor to the motor control unit 224 when the difference between the first voltage and the second voltage is greater than a preset value.

In addition, the control unit 224 will not transmit a control signal to stop the operation of the motor to the motor control unit 223 when the second voltage is 0V, even if the voltage difference between the first voltage and the second voltage is greater than a preset value. You can. When the second voltage is 0V, the control unit 224 may determine that the vehicle user has turned off the power. Accordingly, the control unit 224 can determine that the fuse switch S1 is disconnected only when the vehicle switch is turned on. With this configuration, the vehicle control device 200 according to the embodiment can block freewheeling of the motor by detecting a disconnection of the fuse switch S1 when the ignition is turned on.

The internal sensor 225 may include a temperature sensor, a pressure sensor, a multi-turn sensor, and a single-turn sensor. The internal sensor 225 is not limited to this and may include various sensors. The internal sensor 225 may receive power from a power supply (PMIC).

For example, a temperature sensor can detect the temperature of the vehicle control device, and a pressure sensor can detect the pressure of the vehicle control device. Additionally, the multi-turn sensor can transmit a signal that detects the number of rotations of the motor to the control unit 224. With this configuration, the control unit 224 can detect the position of the actuator.

The external sensor interface unit 226 may be connected to an external sensor. The external sensor interface unit 226 may receive power from a power supply unit (PMIC). And the external sensor interface unit 226 can provide the supplied power to an external sensor. The external sensor interface unit 226 is electrically connected to an external sensor through the interface unit 210 and can supply power to the external sensor.

The communication unit 227 is connected to the ABS system inside the vehicle and can perform data communication. The communication unit 227 may be electrically connected to the control unit 224. The communication unit 227 may transmit a control signal received from the outside to the control unit 224.

Additionally, the communication unit 227 may be connected to the outside through the interface unit 210. For example, the communication unit 227 may include a receiver and a transmitter for CAN communication so that CAN communication can be performed.

The motor switching unit 228 may receive a control signal from the motor control unit 223 and provide a desired three-phase output to the motor. For example, the motor switching unit 228 may be comprised of a plurality of switching elements. For example, the motor switching unit 228 may include six field effect transistors (FETs), but is not limited to this type. The motor switching unit 228 controls the on/off of a plurality of switching elements according to a control signal, provides various three-phase (U, V, W) outputs to the motor, and the motor can be driven according to the provided output. This will be explained in detail in FIG. 4 below.

Figure 4 is a diagram explaining control of a vehicle control device according to an embodiment.

Referring to FIG. 4, the vehicle control device according to the embodiment may include a control unit 224, a motor control unit 223, a motor switching unit 228, and an output control element.

First, the motor 10 may be electrically connected to the six switching elements FE1 to FE6 of the motor switching unit 228, as described above. And the signal that controls the on/off of the six switching elements (FE1 to FE6) is the six terminals (GHA, GHB, GHC, GLA, GLB, GLC) of the motor control unit 223 (corresponding to the gate driver control unit in the motor). It can be provided from . For example, the six terminals may include the first terminal (GHA) to the sixth terminal (GLC).

And the first terminal (GHA) is connected to the first switching element (FE1), the second terminal (GHB) is connected to the second switching element (FE2), and the third terminal (GHC) is connected to the third switching element (FE3). ), the fourth terminal (GLA) is connected to the fourth switching element (FE4), the fifth terminal (GLB) is connected to the fifth switching element (FE5), and the sixth terminal (GLC) is connected to the sixth switching element (FE4). It can be connected to the switching element (FE6). In addition, the on/off of the first terminal (GHA) to the sixth terminal (GLC) may be controlled according to the signal transmitted to each switching element.

Additionally, one end of the first switching element FE1 may be connected to the battery (B+) voltage, and the other end may be connected to the U phase of the motor 10. One end of the second switching element FE2 may be connected to the battery (B+) voltage, and the other end may be connected to the V phase of the motor 10. One end of the third switching element FE3 may be connected to the battery (B+) voltage, and the other end may be connected to the W phase of the motor 10.

Additionally, one end of the fourth switching element FE4 may be connected to ground, and the other end may be connected to the U phase of the motor 10. One end of the fifth switching element FE5 may be connected to ground, and the other end may be connected to the V phase of the motor 10. One end of the sixth switching element FE6 may be connected to ground, and the other end may be connected to the W phase of the motor 10.

By this configuration, the first switching elements (FE1) to the sixth switching elements (FE6) can be controlled on/off, and the on/off control of the first switching elements (FE1) to the sixth switching elements (FE6) can be controlled. Accordingly, the motor 10 may be provided with different voltages for each phase.

As described above, the motor control unit 223 may provide a motor 10 control signal for controlling a plurality of switching elements FE1 to FE6 to the motor switching unit 228. And the motor control unit 223 may determine the motor 10 control signal according to the output signal provided from the control unit 224. For example, the control unit 224 may provide a PWM signal to the motor control unit 223. The PWM signal may be transmitted through a plurality of lines (C1 to C6). And as described above, the motor control unit 223 can receive six output signals (HA to LC) in response to the six switching elements (FE1 to FE6) of the motor switching unit 228. And six output signals (HA to LC) can be transmitted from the control unit 224 to the motor control unit 223 through six lines (C1 to C6). For example, the control unit 224 may transmit a low signal to the motor control unit 223 through the first line C1. In this case, the first output signal HA becomes a low signal, and the first switching element FE1 may be turned off. To this end, the motor control unit 223 is connected to the gate electrode of the first switching element (FE1) through the first terminal (GHA) and sends an appropriate voltage level signal to the first switching element (FE1) to turn off the first switching element (FE1). It can be provided as (FE1). This control method is equally applied to all the second to sixth lines C2 to C6, and the second to sixth switching elements FE2 to FE6 also operate in the same manner.

As described above, the motor switching unit 228 turns on/off a plurality of switching elements (FE1 to FE6) by a plurality of motor 10 control signals transmitted from the first terminal (GHA) to the sixth terminal (GLC). can be performed.

And a plurality of output control elements may be arranged on a plurality of lines. A plurality of output control elements (PU1 to PU3) may be disposed on a line connected to a plurality of switching elements whose ends are connected to the same voltage. The output control elements PU1 to PU3 may be disposed on the first line C1 to the third line C3. For example, a plurality of output control elements PU1 to PU3 may be respectively disposed in the fourth line C4 to the sixth line C6.

The output control elements (PU1 to PU3) are, for example, disposed on the fourth line (C4) to the sixth line (C6) and can be transformed into a high signal when a floating signal is provided to each line (in the case of a pull-up resistor). . And the output control elements (PU1 to PU3) may be pull-up resistors or pull-down resistors, but are not limited thereto.

And in Figure 4, the fourth line (C4) to the sixth line (C6) is connected to the fourth switching element (FE4) to the sixth switching element (FE6), and the fourth switching element (FE4) to the sixth switching element (FE4) FE6) can have both ends connected to ground.

In addition, the motor 10 is high at the first terminal (GHA), low at the second terminal (GHB), low at the third terminal (GHC), low at the fourth terminal (GLA), and low at the fifth terminal (GLB). When high, current can flow to the sixth terminal (GLC). It is not limited to this, and the motor 10 is low at the first terminal (GHA), high at the second terminal (GHB), low at the third terminal (GHC), high at the fourth terminal (GLA), and high at the fifth terminal. Low to (GLB), high to the 6th terminal (GLC), low to the 1st terminal (GHA), low to the 2nd terminal (GHB), high to the 3rd terminal (GHC), and high to the 4th terminal (GLA). Current may flow when low to the fifth terminal (GLB) and low to the sixth terminal (GLC). In this way, the switching elements (FE1 to FE6) provide current to the motor 10 as the control signal changes, enabling three-phase driving.

Figure 5 is a circuit diagram illustrating the connection of the shift control device and the first power supply line and the second power supply line in the vehicle control device according to the embodiment.

Referring to FIG. 5, as described above, the first power supply line (L1) and the second power supply line (L2) are disposed between the interface unit 210 and the power supply device (PMIC), and the interface unit 210 and the power supply unit (PMIC) can be electrically connected to each other.

And the shift control device 220 may include a motor switching unit 228 and a power supply unit (PMIC) as described above. The content described above applies equally to this configuration.

Specifically, the motor switching unit 228 is electrically connected to the second node N2 disposed on the first power supply line L1.

The second node N2 is disposed at the rear end of the charging and discharging unit 230 and may be the same node as the rear end of the charging and discharging unit 230. In addition, the second node (N2) may be electrically connected to the third power supply line (L3) and the third node (N3) in addition to the motor switching unit 228 and the charging/discharging unit 230.

The second node (N2) is disposed on the first power supply line (L1), and is connected to the motor control unit 223 from the battery through the interface unit 210 unless the fuse switch on the first power supply line (L1) is blown. , power supply unit (PMIC), and power can be supplied to the motor switching unit 228. Additionally, the second node N2 may be electrically connected to the motor 10 connected to the motor switching 228.

And the power supply device (PMIC) is electrically connected to the third node (N3) disposed on the first power supply line (L1) and the second power supply line (L2). The third node N3 may be electrically connected to the second power supply line L2. Additionally, the third node N3 may be electrically connected to the first power supply line L1, the motor control unit 223, and the power supply device (PMIC). That is, the third node N3 may be a common node of the first power supply line N1 and the second power supply line N2. Accordingly, when the fuse switch on the first power supply line (N1) is blown, power can be supplied to the power supply device (PMIC), the motor control unit 223, etc. through the second power supply line (N2). Accordingly, a multi-turn sensor, etc. can be driven even when the motor is freewheeling to store the number of times the motor has been driven.

Additionally, the first node, second node N2, and third node N3 may all be disposed on the first power supply line L1. And the first node, second node N2, and third node N3 may be arranged in order from the battery toward the power supply device (PMIC).

Additionally, the first rectifier DO1 may be disposed between the second node N2 and the third node N3. The first rectifier DO1 may allow current to flow from the second node N2 to the third node N3. The first rectifier DO1 may include a diode, but is not limited to this device. For example, the first rectifier DO1 may include a first diode. And the anode of the first diode may be electrically connected to the second node (N2). And the cathode of the first diode may be electrically connected to the third node (N3).

The first rectifier DO1 may prevent current from flowing from the third node n3 to the second node N2 through the second power supply line L2. That is, when the fuse switch is blown, the first rectifier DO1 supplies power to the power supply device PMIC through the second power supply line L2, and at the same time allows the second power supply line L2 to operate. Current exceeding the current may be blocked from being supplied to the motor switching unit 228 through the power supply device (PMIC) as well as the second node (N2). That is, the first rectifier DO1 may block the power path CP1 from the second power supply line L2 to the second node N2. Here, the power path refers to a path through which current can flow. As a result, the motor switching unit 228 can be protected from overcurrent when the fuse switch is disconnected.

The second rectifier DO2 may be disposed on the second power supply line L2. The second rectifier DO2 may allow current to flow from the power supply line L2 toward the third node N3. The second rectifier DO2 may include a diode, but is not limited to this device. For example, the second rectifier DO2 may include a second diode. Additionally, the anode of the second diode may be connected to the interface unit 210, and the cathode of the second diode may be connected to the third node (N3). The second diode may be directly connected to the third node (N3), but is not limited to this.

Additionally, the second rectifier DO2 may form a power path CP2 toward the second power supply line L2 and the third node N3 when the fuse switch is blown. Accordingly, the second rectifier DO2 can supply power to the motor control unit 223 and the power supply device (PMIC) through the second power supply line L2 and the third node N3. .

Additionally, the second rectifier DO2 may block the power path CP3 from the second node N2 to the second power supply path L2 through the third node N3. Accordingly, when the fuse switch is blown, the second rectifier DO2 may transmit a control signal to the motor switching unit 228 to break the driving of the motor 10. However, the motor 10 has inertia due to rotation, thereby generating counter electromotive force. And the back electromotive force can generate a current flowing through the motor 10 and the motor switching unit 228. The current generated by the back electromotive force may be provided to the third node (N3) through the second node (N2). In this case, the second rectifier DO2 may block the current generated by the back electromotive force from being provided to the second power supply line L2 through the third node N3. As a result, the second rectifier DO2 can prevent current due to back electromotive force from flowing into the second power supply line L2, thereby preventing current from flowing into other devices connected to the second power supply line L2. . That is, the second rectifier DO2 can prevent the circuit device from being damaged due to current caused by electromotive force when the fuse switch is blown.

FIG. 6 is a diagram illustrating the effects of a vehicle control device according to an embodiment.

First, Figure 6a is a graph measuring the voltage at the first point (P1), which is a point on the second power supply line (L2), and Figure 6b is a graph measuring the voltage at the first point (P1), which is a point on the second power supply line (L2). It is a graph measuring the current at (P1), Figure 6c is a graph measuring the current at the second point (P2) located in each phase between the motor switching unit 228 and the motor 10, and Figure 6d is a graph measuring the current at the motor This is a graph showing the control signal of the switching unit. Hereinafter, ① is the point at which the fuse switch is disconnected, and ② is the break mode due to disconnection of the fuse switch (low on the first to third switching elements (High side FET) to break the motor operation, and the fourth to sixth switching elements ( This is an operation in which each phase of the motor is grounded by applying a high signal to the low side FET), and is performed after a preset time after disconnection. The x-axis is time, and the y-axis represents voltage at 7a, current at 7b and 7c, and pulse size at 7d. indicates.

First, referring to FIGS. 6a and 7b, when the fuse switch is disconnected (①), as described above, ignition occurs to supply power through the second power supply line, and a high current (E) and Indicates that high voltage is generated. After the fuse switch is disconnected, the first rectifier and the second rectifier can prevent current due to high current and back electromotive force of the motor from flowing into the second power supply line. Additionally, it is possible to prevent high current from being provided to the motor through the motor control unit.

In addition, as shown in Figure 6c, the change in the current of each phase provided to the motor 10 through the motor switching unit disappears in a short time. In addition, as shown in Figure 6d, it can be seen that a control signal is applied to each switching element so that the motor operation is broken in the brake mode (②).

FIG. 7 is a circuit diagram of another vehicle control device illustrating the effects of the vehicle control device according to the embodiment, and FIG. 8 is a diagram illustrating a problem in the vehicle control device of FIG. 7 .

First, referring to FIG. 7, the second power supply circuit (L2) may be connected to the first power supply line (L1) through the second node (N2). For example, the second power supply circuit L2 may be connected to the second node N2 and the front end of the charge/discharge unit 230 on the first power supply line L1.

In this case, when the fuse switch is disconnected, power is supplied through the second power supply line (L2), and the brake mode can be entered after a predetermined time as described above. However, a problem occurs in which the current flowing through the first power supply line (L1) flows through the second power supply line (L2) to the path (CP4) toward the motor switching unit 228. (The first power supply line (L1) supplies power to the entire shift control device 220, but the second power supply line (L2) supplies power to some elements for the brake mode, especially the power supply (PMIC) and the motor control unit ( Since power is supplied only to 223), the allowable current of the second power supply line (L2) is lower than the allowable current of the first power supply line (L1))

In addition, in the brake mode, for example, a low signal is applied to the first to third switch elements and a high signal is applied to the fourth to sixth switch elements to stop driving the motor, but a back electromotive force is generated in the motor to generate current. You can. There is a problem in that this current is also provided to the second power supply line (L2).

Referring to FIG. 8, FIG. 8A is a graph measuring the voltage at a first point (P1), which is a point on the second power supply line (L2), and FIG. 8B is a graph measuring the voltage at a point (P1), which is a point on the second power supply line (L2). It is a graph measuring the current at the first point (P1), and Figure 8c is a graph measuring the current at the second point (P2) located in each phase between the motor switching unit 228 and the motor 10, Figure 8d is a graph showing the control signal of the motor switching unit. Hereinafter, ① is the point at which the fuse switch is disconnected, and ② is the break mode due to disconnection of the fuse switch (low on the first to third switching elements (High side FET) to break the motor operation, and the fourth to sixth switching elements ( This is an operation in which each phase of the motor is grounded by applying a high signal to the low side FET), and is performed after a preset time after disconnection. The x-axis is time, and the y-axis represents voltage at 9a, current at 9b and 9c, and pulse size at 9d. indicates.

First, referring to FIGS. 8a and 9b, when the fuse switch is disconnected (①), as described above, ignition occurs to supply power through the second power supply line, and a high current (E) and Indicates that high voltage is generated. However, after the fuse switch is disconnected, the first rectifier and the second rectifier flow a high current and a current due to the back electromotive force of the motor to the second power supply line (F). Accordingly, voltage is also generated, and it can be seen that current flows in each phase of the motor even when entering the brake mode as shown in Figure 6c. In addition, as shown in Figure 8d, it can be seen that a control signal is applied to each switching element so that the motor operation is broken in the brake mode (②).

The term '~unit' used in this embodiment refers to software or hardware components such as FPGA (field-programmable gate array) or ASIC, and the '~unit' performs certain roles. However, '~part' is not limited to software or hardware. The '~ part' may be configured to reside in an addressable storage medium and may be configured to reproduce on one or more processors. Therefore, as an example, '~ part' refers to components such as software components, object-oriented software components, class components, and task components, processes, functions, properties, and procedures. , subroutines, segments of program code, drivers, firmware, microcode, circuits, data, databases, data structures, tables, arrays, and variables. The functions provided within the components and 'parts' may be combined into a smaller number of components and 'parts' or may be further separated into additional components and 'parts'. Additionally, components and 'parts' may be implemented to regenerate one or more CPUs within a device or a secure multimedia card.

Although the above description focuses on the examples, this is only an example and does not limit the present invention, and those skilled in the art will be able to You will see that various variations and applications are possible. For example, each component specifically shown in the examples can be modified and implemented. And these variations and differences in application should be construed as being included in the scope of the present invention as defined in the appended claims.

Claims (13)

a first power supply line wired between the interface unit and the power supply device;
a second power supply line wired between the interface unit and the power supply device;
a motor switching unit connected to a second node disposed on the first power supply line;
a power supply device connected to a third node to which the first power supply line and the second power supply line are connected;
a first rectifier disposed between the second node and the third node; and
A motor control device comprising a second rectifier connected to the third node and disposed on the second power supply line. According to paragraph 1,
The first rectifier includes a first diode,
The second rectifier includes a second diode,
A motor control device in which the cathode of the first diode and the second diode is connected to the third node. According to paragraph 2,
A motor control device in which the anode of the first diode is connected to the second node. According to paragraph 1,
A motor control device comprising: a charging/discharging unit disposed on the first power supply line. According to paragraph 4,
A motor control device wherein the charging/discharging unit is connected to the second node. According to paragraph 4,
A motor control device wherein the charging/discharging unit is located in front of the second node. According to paragraph 1,
The motor switching unit,
A motor control device that includes a plurality of switching elements and is connected to a motor. In clause 7,
Further comprising a motor control unit connected to the third node,
The motor control unit,
A motor control device that transmits control signals to control three phases of the motor. According to paragraph 1,
The third node is a motor control device disposed between the power supply and the second node. According to paragraph 1,
A motor control device comprising a third power supply line connected to the second node. According to clause 10,
A motor control device wherein the third power supply line is a ground line. battery;
a motor control device powered by the battery; and
Includes a motor that receives output from the motor control device,
The motor control device,
a first power supply line wired between the battery and the power supply device;
a second power supply line wired between the battery and the power supply device;
a motor switching unit connected to a second node disposed on the first power supply line;
a first rectifier disposed between the second node and the third node; and
A second rectifier connected to the third node and disposed on the second power supply line,
The power supply device is connected to a third node disposed on the first power supply line and the second power supply line. a first power supply line wired between the interface unit and the power supply device;
a second power supply line wired between the interface unit and the power supply device;
a motor switching unit connected to a second node disposed on the first power supply line;
a power supply device connected to a third node to which the first power supply line and the second power supply line are connected;
a first rectifier disposed between the second node and the third node; and
A second rectifier connected to the third node and disposed on the second power supply line,
The first rectifier prevents current from flowing from the third node to the second node,
The second rectifier is a motor control device that prevents current from flowing from the second node toward the second power supply line.