JP2021127824A - Fail-safe control device - Google Patents

Abstract

To provide a fail-safe control device capable of appropriately performing fail-safe by maintaining as much convenience as possible in consideration of the intention of a user.SOLUTION: An SBW device 1 and/or an EPKB device 2 identifies where disconnection occurs among a main battery 9, an auxiliary battery 10 and power supply lines W1 to W7 formed between the SBW device 1 and the EPKB device 2 on the basis of power supply sharing information which shares a power supply state of the main battery 9 to the SBW device 1 and the EPKB device 2, and a power supply state of the auxiliary battery 10 to the SBW device 1 and the EPKB device 2. The SBW device 1 and/or the EPKB device 2 performs fail-safe on the basis of an identified result of a disconnection place.SELECTED DRAWING: Figure 1

Description

The present invention relates to a fail-safe control device.

The shift-by-wire device (hereinafter referred to as SBW device) is configured so that power can be supplied from the main battery and power can be supplied from an auxiliary battery different from the main battery when the main battery fails. As a result, the SBW device can operate the actuator by the power supply of either of the batteries to control the shift position of the transmission with high reliability. According to such a technique, when the failure detection unit detects the failure of the main battery, the number of power supply destinations is reduced as compared with the case where the power is supplied from the main battery, so that the power consumption of the auxiliary battery is suppressed. ing.

On the other hand, when a braking request is given to the electric parking brake device, it is determined whether or not the electric parking brake device is out of order, and when it is determined that the electric parking brake device is out of order, the automatic transmission A technique for switching a shift range to a parking range by a range switching mechanism is provided (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2015-86936

However, in the technique described in the background technology column, the shift range is controlled by the parking range regardless of the convenience of the vehicle user, which may impair the convenience of the vehicle user. In addition, there are cases where the fail-safe is excessive even though the normal control can be continued.

An object of the present invention is to provide a fail-safe control device that can improve the convenience of the user as much as possible in consideration of the user's convenience and can appropriately fail-safe.

The invention according to claim 1 is a shift-by-wire device (hereinafter referred to as an SBW device) that is powered by a main battery (9) and an auxiliary battery (10) and controls a shift position, and the main battery and the auxiliary. It is intended for a fail-safe control device in a vehicle system including an electric parking brake device (hereinafter referred to as an EPKB device) that can be powered by a battery and can electrically operate the parking brake.

The disconnection location identification units (11, 25) are based on the power supply sharing information sharing the power supply state of the main battery to the SBW device and the EPKB device and the power supply state of the auxiliary battery to the SBW device and the EPKB device. , The location of the power supply line composed between the main battery, the auxiliary battery, the SBW device, and the EPKB device is specified. The fail-safe execution unit (13, 27) fails-safe based on the specific result of the disconnection location identification unit.

According to the invention of claim 1, it is possible to more appropriately determine whether the vehicle can continue running or cannot continue running, and it is possible to appropriately fail-safe the vehicle. In addition, depending on the location of the disconnection, the vehicle can be continuously driven without stopping. As a result, the convenience of the user can be improved as much as possible in consideration of the convenience of the user. In addition, since the broken part and the faulty part can be identified, the broken part can be easily grasped when the dealer or the repair company inspects the vehicle.

An electrical configuration diagram schematically showing a partial configuration of a vehicle system according to an embodiment. Functional configuration diagram of SBW device Functional block diagram of EPKB device The figure which shows the correspondence relationship between the power supply state to SBW apparatus and EPKB apparatus, and the disconnection part. Flow chart for roughly explaining the processing contents of the SBW device The figure which shows the example of the data which is sent and received between the SBW apparatus and EPKB apparatus. Flow chart for roughly explaining the processing contents of the EPKB device Explanatory diagram schematically showing the processing contents of fail-safe

Hereinafter, an embodiment of the fail-safe control device will be described with reference to the drawings. FIG. 1 schematically shows a part of a vehicle system. Electronic control devices for vehicles such as a shift-by-wire device 1 (hereinafter abbreviated as SBW device 1) and an electric parking brake device 2 (hereinafter abbreviated as EPKB device 2) are incorporated in the vehicle, and they are mounted on each other. It is connected to the network by LAN (not shown).

The SBW device 1 includes a power supply circuit 3, a CPU 4, a microcomputer 6 having a storage unit 5, an actuator 7, and a communication circuit 8, and is supplied with power from a main battery 9 and an auxiliary battery 10. The power supply circuit 3 is supplied with power from the main battery 9 and the auxiliary battery 10 to supply a stable power supply voltage to each component such as the microcomputer 6.

The SBW device 1 can control the shift position of the transmission (not shown) by operating the actuator 7 using the power supply of the main battery 9 or the auxiliary battery 10. As illustrated in FIG. 2, the SBW device 1 is built into the disconnection location identification unit 11, the determination unit 12, the fail-safe execution unit 13, and the vehicle by executing the program stored in the storage unit 5 by the CPU 4. It has a function as a vehicle speed acquisition unit 16 that inputs a sensor signal from the vehicle speed sensor 15 and acquires vehicle speed information. The SBW device 1 can give a warning to the outside by outputting a warning to a notification unit 14 such as a display device by the function of the fail-safe execution unit 13.

Further, the SBW device 1 is a main battery voltage determination unit 17 that compares the power supply voltage of the main battery 9 input to the power supply circuit 3 with a predetermined threshold value to determine the height thereof, and an auxiliary battery 10 input to the power supply circuit 3. Auxiliary battery voltage determination unit 18 for comparing the power supply voltage with a predetermined threshold value and determining the height thereof is provided.

On the other hand, the EPKB device 2 also includes a power supply circuit 19, a microcomputer 22 having a CPU 20 and a storage unit 21, an actuator 23, and a communication circuit 24, and is supplied with power from the main battery 9 and the auxiliary battery 10. The power supply circuit 19 is configured to be able to supply power from the main battery 9 and the auxiliary battery 10, and supplies a stable power supply voltage to each part configuration such as the internal microcomputer 22. The EPKB device 2 is configured to electrically operate the parking brake (not shown) by operating the actuator 23 when a braking request is given.

As illustrated in FIG. 3, the EPKB device 2 executes a program stored in the storage unit 21 by the CPU 20 to execute a disconnection location identification unit 25, a determination unit 26, a fail-safe execution unit 27, and a vehicle. It has a function as a vehicle speed acquisition unit 28 that inputs a sensor signal from the vehicle speed sensor 15 built in the vehicle and acquires vehicle speed information.

Further, the EPKB device 2 compares the power supply voltage of the main battery 9 input to the power supply circuit 19 with a predetermined threshold value to determine the height of the main battery voltage determination unit 29, and the auxiliary battery 10 input to the power supply circuit 19. Auxiliary battery voltage determination unit 30 for determining the height of the power supply voltage by comparing the power supply voltage with a predetermined threshold value is provided.

As illustrated in FIG. 1, when the intermediate node 31 is provided at the separation intermediate point from the main battery 9 to the SBW device 1 and the EPKB device 2, a power supply line is provided between the main battery 9 and the intermediate node 31. W1 is connected. A power supply line W2 is connected between the intermediate node 31 and the SBW device 1, and a power supply line W3 is connected between the intermediate node 31 and the EPKB device 2.

A power supply line W4 is connected between the main battery 9 and the auxiliary battery 10. Further, when the intermediate node 32 is provided at the separation intermediate point from the auxiliary battery 10 to the SBW device 1 and the EPKB device 2, the power supply line W5 is connected between the auxiliary battery 10 and the intermediate node 32. ..

A power supply line W6 is connected between the intermediate node 32 and the EPKB device 2, and a power supply line W7 is connected between the intermediate node 32 and the SBW device 1. Further, a dedicated communication line TR8 is connected between the SBW device 1 and the EPKB device 2, and the SBW device 1 and the EPKB device 2 are configured to be capable of mutual communication using the dedicated communication line TR8.

As illustrated in FIG. 4, the storage unit 5 of the SBW device 1 and the storage unit 21 of the EPKB device 2 are power supplies composed of the main battery 9, the auxiliary battery 10, the SBW device 1, and the EPKB device 2. Among the supply lines W1 to W7 and the dedicated communication line TR8, the correspondence relationship between the disconnection location and the voltage supply state when, for example, one disconnection occurs is stored.

For example, when the power supply line W1 is disconnected, the main battery 9 and the SBW device 1 and the EPKB device 2 are disconnected, so that the power supply voltage of the main battery 9 supplied to the SBW device 1 exceeds a predetermined threshold value. The lowering (that is, "Lo") is stored in advance in the storage units 5 and 21.

Similarly, even if the power supply line W1 is disconnected, the power supply lines W5 and W7 from the auxiliary battery 10 to the SBW device 1 are not disconnected, so that the power supply voltage of the auxiliary battery 10 supplied to the SBW device 1 is It is stored in the storage units 5 and 21 that it is higher than a predetermined threshold value (that is, "Hi").

Similarly, when the power supply line W1 is disconnected, the main battery 9 and the EPKB device 2 are disconnected, so that the power supply voltage of the main battery 9 supplied to the EPKB device 2 has a predetermined threshold value. It is stored in the storage units 5 and 21 that it becomes lower (that is, "Lo").

Similarly, even if the power supply line W1 is disconnected, the power supply lines W5 and W7 between the auxiliary battery 10 and the EPKB device 2 are not disconnected, so that the power supply of the auxiliary battery 10 supplied to the EPKB device 2 is not disconnected. The storage units 5 and 21 store that the voltage is higher than a predetermined threshold value (that is, “Hi”).

Here, the storage contents of the storage units 5 and 21 of the correspondence relationship between the power supply voltage determination result and the disconnection point when the power supply line W1 is disconnected have been described, but when the other power supply lines W2 to W7 are disconnected. Correspondences of the above are also stored in the storage units 5 and 21, respectively. Since this content is the same as the correspondence when the power supply line W1 is disconnected, the description thereof will be omitted.

If none of the power supply lines W1 to W7 are disconnected, the main battery 9 and the auxiliary battery 10 are normally supplied to both the SBW device 1 and the EPKB device 2. Therefore, it is stored in the storage units 5 and 21 that the power supply voltages of both the main battery 9 and the auxiliary battery 10 are higher than a predetermined threshold value (that is, “Hi”).

The characteristic operation related to the above configuration will be described. Normally, when the ignition switch in the vehicle is turned on by the user, the SBW device 1 is powered by the main battery 9 and the auxiliary battery 10. Similarly, the EPKB device 2 is also powered by the main battery 9 and the auxiliary battery 10.

FIG. 5 illustrates the processing contents of the SBW device 1. The main battery voltage determination unit 17 of the SBW device 1 acquires the detection voltage of the main battery 9, and the auxiliary battery voltage determination unit 18 acquires the detection voltage of the auxiliary battery 10. As a result, the SBW device 1 detects and acquires the power supply state in S1.

The main battery voltage determination unit 17 of the SBW device 1 determines whether the detected level of the power supply voltage of the acquired main battery 9 is low “Lo” or high “Hi” in comparison with a predetermined threshold value, and stores it. Store in part 5. Further, the auxiliary battery voltage determination unit 18 of the SBW device 1 determines whether the detected level of the power supply voltage of the acquired auxiliary battery 10 is low “Lo” or high “Hi” in comparison with a predetermined threshold value. , This determination result is converted into data “1” and “0” representing the power supply states “Hi” and “Lo” and stored in the storage unit 5.

Then, the microcomputer 6 of the SBW device 1 sets the data "1" and "0" indicating the power supply state in S2 in the communication buffer of the communication circuit 8, and in S3, the data of the power supply state is set by the communication circuit 8 in the EPKB device 2. Send to. As a result, the EPKB device 2 can receive the power supply state from the main battery 9 and the power supply state from the auxiliary battery 10 in the SBW device 1. On the left side of FIG. 6, the data transmitted from the SBW device 1 to the EPKB device 2 is shown corresponding to the power failure of the main battery 9 and the power failure of the auxiliary battery 10.

FIG. 7 illustrates the processing contents of the EPKB device 2. The main battery voltage determination unit 29 of the EPKB device 2 acquires the detection voltage of the main battery 9, and the auxiliary battery voltage determination unit 30 acquires the detection voltage of the auxiliary battery 10. As a result, as illustrated in FIG. 7, the EPKB device 2 detects and acquires the power supply state in S21.

The main battery voltage determination unit 29 of the EPKB device 2 determines whether the detected level of the power supply voltage of the acquired main battery 9 is low “Lo” or high “Hi” in comparison with a predetermined threshold value, and stores it. It is stored in the part 21. The auxiliary battery voltage determination unit 30 of the EPKB device 2 determines whether the detection level of the power supply voltage of the acquired auxiliary battery 10 is low “Lo” or high “Hi” in comparison with a predetermined threshold value, and this The determination result is converted into corresponding data "1" and "0" representing the power supply states "Hi" and "Lo", and stored in the storage unit 21.

Then, the microcomputer 22 of the EPKB device 2 sets the data "1" and "0" indicating the power supply state in S22 in the communication buffer of the communication circuit 24, and in S23, the data of the power supply state is set by the communication circuit 24 in the SBW device 1. Send to. As a result, the SBW device 1 can receive the power supply state from the main battery 9 and the power supply state from the auxiliary battery 10 in the EPKB device 2.

As a result, the SBW device 1 and the EPKB device 2 can share their respective power supply states. Hereinafter, the shared power supply state data will be referred to as “power supply sharing information” and will be described.

The microcomputer 6 of the SBW device 1 determines whether or not the power supply lines W1 to W7 and the dedicated communication line TR8 are disconnected based on the power supply shared information, and if the disconnection occurs, the disconnection occurs in S4. Identify the location. Similarly, the microcomputer 22 of the EPKB device 2 also determines whether or not the power supply lines W1 to W7 and the dedicated communication line TR8 are disconnected based on the power supply shared information, and if the disconnection occurs, it is determined. The disconnection point is specified in S24.

Normally, if the power supply lines W1 to W7 and the dedicated communication line TR8 are not disconnected, the power supply voltage of the main battery 9 and the power supply voltage of the auxiliary battery 10 given to the SBW device 1 and the EPKB device 2, respectively, are within a predetermined threshold value. It gets higher. Therefore, the SBW device 1 and the EPKB device 2 determine that the power supply voltages of the main battery 9 and the auxiliary battery 10 are higher than the predetermined threshold values, respectively. When the SBW device 1 and the EPKB device 2 share the data of the power supply state of each other, they all acquire the data "1" representing a high "Hi" as the power supply state sharing information.

Therefore, the microcomputer 6 of the SBW device 1 identifies the disconnection location by the disconnection location identification unit 11 based on the power supply shared information of the power supply state stored in the storage unit 5 in S4, and as a result, there is no disconnection or disconnection in S5. It is identified as a disconnection of the power supply line W4, and the processing routine of FIG. 5 is exited without any processing.

On the other hand, when the power supply lines W1 to W7 and the dedicated communication line TR8 are disconnected due to some influence, the power supply voltage input to the SBW device 1 or the EPKB device 2 changes. Therefore, when the microcomputer 6 of the SBW device 1 identifies the disconnection location based on the power supply shared information of the power supply state stored in the storage unit 5 in S4, the subsequent processing content is changed.

<When the power supply line W1 is disconnected>
For example, if the power supply line W1 is disconnected, the main battery 9 will not be supplied to the SBW device 1 and the EPKB device 2. Therefore, the main battery voltage determination units 17 and 29 of the SBW device 1 and the EPKB device 2 determine that the power supply voltage of the main battery 9 is all low “Lo”. On the other hand, since the auxiliary battery 10 is supplied to both the SBW device 1 and the EPKB device 2, the auxiliary battery voltage determination unit 18 of the SBW device 1 and the auxiliary battery voltage determination unit 30 of the EPKB device 2 are auxiliary. All the power supply voltages of the battery 10 are determined to be high "Hi".

Therefore, the microcomputers 6 and 22 of the SBW device 1 and the EPKB device 2 are supplied with power in S4 and S24 as a result of identifying the disconnection location by the disconnection location identification units 11 and 25 based on the power supply shared information in the power supply state. It is specified as a disconnection of the line W1.

The microcomputers 6 and 22 of the SBW device 1 and the EPKB device 2 determine that the power supply line W2 is broken by the functions of the discriminating units 12 and 26, respectively. This is because even if the power supply line W2 is disconnected, the power is supplied to the EPKB device 2 from the main battery 9, and the main battery 9 supplied to the SBW device 1 loses power.

At this time, the following processing is executed. The microcomputer 6 of the SBW device 1 gives a shift command to the parking range in S6. On the other hand, the microcomputer 22 of the EPKB device 2 notifies the outside through the notification unit 14 by the function of the fail-safe execution unit 13 in S26. During this period, as described above, the SBW device 1 operates the actuator 7 of the transmission, and the EPKB device 2 confirms the completion status of the transmission in the parking range in S27.

If the parking range is not completed, the microcomputer 22 of the EPKB device 2 measures the time after identifying the disconnection point using the built-in timer in S28. The microcomputer 22 of the EPKB device 2 receives information indicating a situation in which the shift position is switched to the parking range by the SBW device 1 through the dedicated communication line TR8 or the in-vehicle LAN, and monitors this situation for a predetermined time.

Further, as described above, since the microcomputer 6 of the SBW device 1 gives a shift command to the parking range in S6, the parking lock mechanism is locked by operating the actuator 7. In this case, if the parking lock mechanism can be normally locked, the shift position can be fixed to the parking range. In this case, the vehicle can be stopped and safety can be ensured.

On the other hand, when the microcomputer 22 of the EPKB device 2 determines that the shift position is not completely replaced with the parking range within a predetermined time due to some influence, the microcomputer 22 shifts to S30. The microcomputer 22 receives the sensor information from the vehicle speed sensor 15 in S30 to acquire the vehicle speed information, and when it is determined that the vehicle speed information is lower than the predetermined vehicle speed, the microcomputer 22 shifts to S31. The microcomputer 22 fixes the vehicle by operating the actuator 23 in S31 and operating the parking brake. As a result, the vehicle can be stopped and safety can be ensured.

As a result, when the power supply line W1 is disconnected, the SBW device 1 and the EPKB device 2 give a warning to the outside and fix the vehicle when the above conditions are satisfied, so that fail-safe can be appropriately executed. By requesting repairs from the dealer or a repair company, the vehicle user can repair the disconnection of the power supply line W1 by the dealer or the repair company.

<When the power supply line W2 is disconnected>
Next, a description will be given when the power supply line W2 is disconnected. For example, if the power supply line W2 is disconnected, the main battery 9 will not be supplied to the SBW device 1. Therefore, the main battery voltage determination unit 17 of the SBW device 1 determines that the power supply voltage of the main battery 9 is low “Lo”, and the main battery voltage determination unit 29 of the EPKB device 2 increases the power supply voltage of the main battery 9. Judged as "Hi". On the other hand, since the auxiliary battery 10 is supplied to both the SBW device 1 and the EPKB device 2, the auxiliary battery voltage determination units 18 and 30 of the SBW device 1 and the EPKB device 2 use all the power supply voltages of the auxiliary battery 10. Judged as high "Hi".

Therefore, the microcomputers 6 and 22 of the SBW device 1 and the EPKB device 2 identify the disconnection location by the disconnection location identification units 11 and 25 based on the power supply shared information in the power supply state, and as a result, the power supply is supplied in S4 and S24, respectively. It is specified as a disconnection of the supply line W2. The microcomputers 6 and 22 of the SBW device 1 and the EPKB device 2 determine that the power supply line W2 is disconnected by the functions of the discriminating units 12 and 26, respectively. This is because when the power supply line W2 is disconnected, the main battery 9 is supplied with power to the EPKB device 2 and the main battery 9 is powered down to the SBW device 1.

At this time, the following processing is executed. As shown in FIG. 5, the microcomputer 6 of the SBW device 1 shifts to S7 as a result of checking the disconnection in S5, and in S7, the fail-safe execution unit 13 notifies the outside through the notification unit 14. On the other hand, as shown in FIG. 7, the microcomputer 22 of the EPKB device 2 notifies the outside through the notification unit 14 by the fail-safe execution unit 27 in S32.

Further, the microcomputer 22 of the EPKB device 2 determines in S33 that the power supply voltage of the auxiliary battery 10 has dropped below a predetermined threshold value by the auxiliary battery voltage determination unit 30, and the vehicle speed by the vehicle speed acquisition unit 28 in S34 is the predetermined vehicle speed. When it is determined that the voltage is further lowered, the vehicle is fixed by operating the parking brake in S35.

As a result, when the power supply line W2 is disconnected, the SBW device 1 and the EPKB device 2 give a warning to the outside, and when the conditions of S33 and S34 are satisfied, the vehicle is fixed in S35, so fail-safe is appropriate. Can be executed. By requesting repairs from the dealer or a repair company, the vehicle user can repair the disconnection of the power supply line W2 by the dealer or the repair company.

<When the power supply line W3 is disconnected>
The operation when the power supply line W3 is disconnected will be described. When the power supply line W3 is disconnected, the main battery voltage determination unit 17 of the SBW device 1 determines that the power supply voltage of the main battery 9 is high “Hi”. The main battery voltage determination unit 29 of the EPKB device 2 determines that the power supply voltage of the main battery 9 is low “Lo”. On the other hand, since the auxiliary battery 10 is supplied to both the SBW device 1 and the EPKB device 2, the auxiliary battery voltage determination units 18 and 30 of the SBW device 1 and the EPKB device 2 use all the power supply voltages of the auxiliary battery 10. Judged as high "Hi".

Therefore, the microcomputers 6 and 22 of the SBW device 1 and the EPKB device 2 identify the disconnection location by the disconnection location identification units 11 and 25 based on the power supply shared information in the power supply state. As shown in FIG. 5, the power supply shared information in the power supply state when the power supply line W3 is disconnected is also different from the power supply shared information when the power supply lines W1, W2, and W4 to W7 are disconnected. Therefore, in the SBW device 1 and the EPKB device 2, the main battery 9 is supplied to the SBW device 1 by the functions of the discriminating units 12 and 26, respectively, in S4 and S24, respectively, and the main battery is supplied to the EPKB device 2. It can be identified that the part where the power supply of 9 is lost is broken.

Therefore, even if the power supply line W3 is disconnected, the main battery 9 is supplied to the SBW device 1, so that the SBW device 1 can operate the shift range with high reliability. Further, since the auxiliary battery 10 is supplied to the EPKB device 2, the EPKB device 2 can operate the parking brake with high reliability. Therefore, it is desirable not to execute fail-safe more than necessary.

At this time, as shown in FIG. 5, the SBW device 1 exits the processing routine without executing any processing as a result of checking the disconnection in S5. Further, as shown in FIG. 7, the EPKB device 2 notifies the outside through the notification unit 14 by the fail-safe execution unit 27 in S36. As a result, the vehicle user can be warned that the power supply line W3 has been disconnected.

Even if the vehicle user discovers a disconnection warning of the power supply line W3 while driving the vehicle, the vehicle user can drive normally and stop at a safe place. Then, the vehicle user can request the dealer or the repair company to repair the power supply line W3 when necessary, so that the dealer or the repair company can repair the disconnection of the power supply line W3. As a result, the convenience of the user can be considered and the convenience of the user can be improved as much as possible.

<When any of the power supply lines W5 to W7 is broken>
The operation when any of the power supply lines W5 to W7 is broken will be described. For example, when any of the power supply lines W5 to W7 is broken, the main battery voltage determination units 17 and 29 of the SBW device 1 and the EPKB device 2 determine that the supply power supply voltage of the main battery 9 is high "Hi". do. On the other hand, since the auxiliary battery 10 is not supplied to either or both of the SBW device 1 and the EPKB device 2, the auxiliary battery voltage determination units 18 and 30 of the SBW device 1 and the EPKB device 2 are used as auxiliary batteries according to the disconnection location. The supply power supply voltage of 10 is determined to be high "Hi" or low "Lo".

Therefore, the SBW device 1 and the EPKB device 2 identify the disconnection location by the disconnection location identification units 11 and 25 based on the power supply shared information in the power supply state. It is identified as a disconnection of W7. As shown in FIG. 5, the power supply shared information in the power supply state when any of the power supply lines W5, W6, and W7 is disconnected is different from each other, and further, the power supply when the power supply lines W1 to W4 are disconnected. It is also different from the supply sharing information. Therefore, the microcomputers 6 and 22 of the SBW device 1 and the EPKB device 2 can identify which of the power supply lines W5, W6, and W7 is disconnected.

In the SBW device 1 and the EPKB device 2, at least the main battery 9 is supplied to the SBW device 1 and the EPKB device 2 by the functions of the discriminating units 12 and 26, respectively, and the auxiliary battery 10 loses power. It can be identified that the part where becomes the wire is broken.

Even if the power supply lines W5, W6, or W7 are disconnected, the main battery 9 is supplied to the SBW device 1, so that the SBW device 1 can operate the shift range with high reliability. Further, since the main battery 9 is also supplied to the EPKB device 2, the EPKB device 2 can operate the parking brake with high reliability. Therefore, it is desirable not to execute fail-safe more than necessary.

At this time, as shown in FIG. 5, as a result of checking the disconnection in S5, the SBW device 1 only gives a warning to the outside through the notification unit 14 by the fail-safe execution unit 13 in S7, and does not shift to the parking range. Further, as shown in FIG. 7, the EPKB device 2 also only notifies the outside through the notification unit 14 by the fail-safe execution unit 27 in S36, and does not operate the parking brake. As a result, although the vehicle user is warned that the power supply lines W5, W6, or W7 are disconnected, fail-safe is not executed more than necessary.

In this case, even if the vehicle user discovers the disconnection warning information of the power supply lines W5, W6, or W7 while driving the vehicle, the vehicle user can drive normally and stop at a safe place. Then, the vehicle user can repair the disconnection of the power supply lines W5, W6, or W7 by requesting the dealer or the repair company to repair the power supply line W5, W6, or W7 when necessary. Since it is not necessary to perform fail-safe more than necessary, it is possible to consider the convenience of the user and improve the convenience of the user as much as possible.

<When other power supply line W4 and dedicated communication line TR8 are disconnected>
When the power supply line W4 is disconnected, it cannot be distinguished from the case where the wire is not disconnected. Therefore, the SBW device 1 and the EPKB device 2 exit the processing routine after checking the disconnection in S5 and S25. Further, when the dedicated communication line TR8 is disconnected, the SBW device 1 and the EPKB device 2 can detect that a communication abnormality has occurred through the communication circuits 8 and 24. Therefore, when the dedicated communication line TR8 is disconnected, the SBW device 1 and the EPKB device 2 give a warning to the outside in S7 and S38.

In this case, even if the vehicle user discovers a warning while driving the vehicle, the vehicle user can drive normally and stop at a safe place. Then, the vehicle user can repair the disconnection of the dedicated communication line TR8 by requesting repair from the dealer or the repair company when necessary. Since it is not necessary to perform fail-safe more than necessary, it is possible to consider the convenience of the user and improve the convenience of the user as much as possible.

<Summary when power supply lines W1 to W3 and W5 to W7 are disconnected>
FIG. 8 summarizes and illustrates the contents of fail-safe. As illustrated in FIG. 8, when the power supply line W1 is disconnected, the SBW device 1 gives a shift command to the parking range, but the EPKB device 2 is moved to the parking range by the SBW device 1 within a predetermined time from the disconnection specific timing. If the shift is not completed, the vehicle will be fixed. As a result, fail-safe can be properly executed.

Further, when the power supply line W2 is disconnected, the SBW device 1 gives a warning to the outside, and the EPKB device 2 monitors the power supply voltage of the auxiliary battery 10 and gives a warning to the outside, and then activates the parking brake to activate the vehicle. To fix. As a result, fail-safe can be properly executed.

Further, when the power supply line W3 is disconnected, the EPKB device 2 warns the outside and ends the fail-safe process, so that the fail-safe process is not executed more than necessary. As a result, the convenience of the user can be considered and the convenience of the user can be improved as much as possible.

When any of the power supply lines W5 to W7 is disconnected, the SBW device 1 and / and the EPKB device 2 perform a fail-safe process more than necessary by giving a warning to the outside and terminating the fail-safe. There will be no such thing. As a result, the convenience of the user can be considered and the convenience of the user can be improved as much as possible.

(Other embodiments)
The present disclosure is not limited to the above-described embodiment, and can be implemented in various modifications, and can be applied to various embodiments without departing from the gist thereof. For example, the following modifications or extensions are possible.

The "fail-safe control device" according to the present invention may be configured such that the SBW device 1 and the EPKB device 2 cooperate with each other as shown in the above-described embodiment, or may be configured to perform parallel processing.

Further, the configuration requirements of the "fail-safe control device" are not limited to the SBW device 1 and the EPKB device 2 shown in the above-described embodiment, and other vehicle devices connected to the SBW device 1 and the EPKB device 2 via the in-vehicle LAN. It may be incorporated into. At this time, the other vehicle device shares the power supply state of the main battery 9 to the SBW device 1 and the EPKB device 2 and the power supply state of the auxiliary battery 10 to the SBW device 1 and the EPKB device 2. The supply shared information is received, and based on the power supply shared information, at any place in the power supply lines W1 to W7 composed between the main battery 9, the auxiliary battery 10, the SBW device 1 and the EPKB device 2. It is good to identify whether the disconnection has occurred, and it is good to fail-safe based on this specific result.

Further, the processing contents of the disconnection location specifying units 11 and 25 and the fail-safe execution units 13 and 27 may be shared and incorporated into the SBW device 1, the EPKB device 2, or the other vehicle device described above. , The processing content may be executed in cooperation with each other by connecting with the in-vehicle LAN. In this case, parallel processing may be performed.

The configurations and functions of the plurality of embodiments described above may be combined. An embodiment in which a part of the above-described embodiment is omitted as long as the problem can be solved can also be regarded as an embodiment. In addition, any conceivable embodiment can be regarded as an embodiment without departing from the essence of the invention specified by the wording described in the claims.

Although the present disclosure has been described in accordance with the above-described embodiments, it is understood that the present disclosure is not limited to the embodiments and structures. The present disclosure also includes various modifications and modifications within a uniform range. In addition, various combinations and forms, as well as other combinations and forms, including one element, more, or less, are also within the scope and ideology of the present disclosure.

In the drawing, 1 is a shift-by-wire device (SBW device), 2 is an electric parking brake device (EPKB device), 9 is a main battery, 10 is an auxiliary battery, 11 and 25 are disconnection location identification parts, and 12 and 26 are discrimination parts. 13 and 27 are fail-safe execution units, 17 and 29 are main battery voltage determination units, and 18 and 30 are auxiliary battery voltage determination units.

Claims (6)

A shift-by-wire device (1: hereinafter referred to as an SBW device) that can supply power from the main battery (9) and the auxiliary battery (10) and controls the shift position, and can supply power from the main battery and the auxiliary battery. It is a fail-safe control device in a vehicle system provided with an electric parking brake device (2: hereinafter referred to as an EPKB device) that enables the parking brake to be electrically operated.
Based on the power supply sharing information sharing the power supply state of the main battery to the SBW device and the EPKB device, and the power supply state of the auxiliary battery to the SBW device and the EPKB device, the main battery, In the power supply line configured between the auxiliary battery, the SBW device, and the EPKB device, a disconnection location specifying portion (11, 25) for specifying where the disconnection occurred,
A fail-safe execution unit (13, 27) that fails-safe based on the specific result of the disconnection location identification unit, and
A fail-safe control device. Based on the disconnection location specified by the disconnection location identification unit, the power supply to the SBW device is lost and the power supply to the EPKB device or the power supply to the EPKB device is lost. The SBW device is provided with a discriminating unit (12, 26) for determining whether the power is supplied to the SBW device or the power supplied to the SBW device and the EPKB device is lost.
The fail-safe execution unit (13, 27)
The fail-safe control device according to claim 1, wherein the fail-safe control device performs fail-safe based on the identification result of the disconnection location identification unit and the power failure location determined by the determination unit. When the discriminating unit determines that the power failure of the main battery supplied to the SBW device is disconnected and the EPKB device is supplied with the main battery.
The fail-safe execution unit (13, 27)
The fail-safe control device according to claim 2, wherein the EPKB device determines that the parking brake can be controlled and gives a warning to the outside. Vehicle speed acquisition unit (16, 28) to acquire vehicle speed,
An auxiliary battery voltage determination unit (18, 30) for determining whether the voltage of the auxiliary battery is higher or lower than a predetermined threshold value is provided.
The fail-safe execution unit (13, 27)
When the vehicle speed acquired by the vehicle speed acquisition unit is determined to be lower than the predetermined vehicle speed, and when the auxiliary battery voltage determination unit determines that the voltage of the auxiliary battery is lower than the predetermined threshold value.
The fail-safe control device according to claim 3, wherein the parking brake is electrically operated by the EPKB device. When the discriminating unit determines that the portion of the main battery supplied to the SBW device and the EPKB device that causes a power failure is disconnected,
The fail-safe execution unit (13, 27)
The fail-safe control device according to claim 2, wherein the SBW device stops the vehicle by instructing the shift position to switch the shift position to the parking range. When the SBW device monitors the situation of switching the shift position to the parking range for a predetermined time and the replacement is not completed within the predetermined time, and when it is determined that the vehicle speed is lower than the predetermined vehicle speed,
The fail-safe execution unit (13, 27)
The fail-safe control device according to claim 5, wherein the vehicle is fixed by electrically operating the parking brake by the EPKB device.

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