JP2019206821A - Opening and closing member control device - Google Patents

Abstract

To provide a power window system capable of being simplified.SOLUTION: An opening and closing switch 22 of a driver's seat door 10 and an opening and closing switch 33 of a front passenger seat door 30 are connected in series, and the opening and closing switch 33 is connected to a power window motor 31 that opens and closes a window glass of the front passenger seat door 30. An ECU 35 of the power window motor 31 opens and closes the window glass provided in the front passenger seat door 30 based on a terminal voltage Vi of an input terminal 35a.SELECTED DRAWING: Figure 2

Description

  The present disclosure relates to an opening / closing member control device.

  2. Description of the Related Art Conventionally, an opening / closing member control device opens and closes a window glass as an opening / closing member based on an operation of an opening / closing switch provided at each door of a vehicle. The driver's seat door is provided with an open / close switch corresponding to the window glass of the other door. The power window system opens and closes the window glass of the door corresponding to the operated open / close switch based on the open / close switch operation provided on the door of the driver's seat (see, for example, Patent Document 1).

JP-A-5-18158

Incidentally, there is room for simplification in the above-described opening / closing member control device.
An object of the present disclosure is to provide an opening / closing member control device that can be simplified.

  An opening / closing member control apparatus that solves the above-described problem is provided with a first opening / closing switch provided on a driver's seat door of a vehicle, and a first opening / closing switch provided in another seat door different from the driver seat door and connected in series to the first opening / closing switch. 2 open / close switch, provided on the other-seat door, the second open / close switch connected to an input terminal, and based on the terminal voltage of the input terminal according to the first open / close switch and the second open / close switch And a controller that opens and closes an opening and closing member provided in the other seat door.

  According to this configuration, the operation of the opening / closing switch of the driver's door and the operation of the opening / closing switch of the other-seat door can be detected based on the terminal voltage of the input terminal. it can.

  In the opening / closing member control apparatus, the first opening / closing switch and the second opening / closing switch have different terminal voltages when opening and closing the opening and closing members and terminal voltages when closing and opening the opening and closing member. It is preferable to be configured as described above.

According to this configuration, the opening operation and the closing operation can be easily detected by the terminal voltage.
In the above-described opening / closing member control device, it is preferable that the first opening / closing switch is connected to a battery of the vehicle via a power supply switch.

According to this configuration, the state of the power supply switch can be easily detected by the terminal voltage.
In the opening / closing member control device, it is preferable that the first opening / closing switch is connected to the power supply switch via an opening / closing prohibiting switch for prohibiting opening / closing of the opening / closing member of the other-seat door.

According to this configuration, the state of the open / close prohibition switch can be easily detected by the terminal voltage.
In the above-described open / close member control device, the first open / close switch and the second open / close switch each include a resistor, and the control unit includes a resistor connected to the input terminal, and the first open / close switch or the second open / close switch The terminal voltage is preferably a voltage obtained by dividing the battery voltage of the battery by the resistance of the switch and the resistance of the control unit.

According to this configuration, the terminal voltage can be easily set by the resistance of the first opening / closing switch and the second opening / closing switch and the resistance of the control unit.
In the opening / closing member control apparatus, it is preferable that the resistance of the first opening / closing switch and the resistance of the second opening / closing switch have different resistance values.

According to this configuration, the operation of the first opening / closing switch and the operation of the second opening / closing switch can be easily discriminated by the terminal voltage.
In the opening / closing member control apparatus, it is preferable that the resistance of the first opening / closing switch and the resistance of the second opening / closing switch have the same resistance value.

According to this configuration, the same one can be used for the first opening / closing switch and the second opening / closing switch.
In the above open / close member control device, the resistances of the first open / close switch and the second open / close switch include a first resistor for closing the open / close member and a second resistor for opening the open / close member. The resistance value of the first resistor is different from the resistance value of the second resistor, and the control unit closes the opening / closing member while detecting the terminal voltage by the first resistor, and It is preferable to open the opening / closing member while detecting the terminal voltage by the second resistor.

According to this configuration, the position of the opening / closing member can be easily changed by the first opening / closing switch or the second opening / closing switch.
In the open / close member control apparatus, when the resistance of the first open / close switch and the second open / close switch includes a third resistor, the control unit detects the terminal voltage generated by the third resistor, and the fully open position. Alternatively, it is preferable to operate the opening / closing member to the fully closed position.

According to this configuration, the opening / closing member can be automatically operated to the fully closed position or the fully opened position by operating the first opening / closing switch or the second opening / closing switch.
In the opening / closing member control device, the other seat door is a passenger seat door, a rear seat right door, and a rear seat left door of the vehicle, and the second opening / closing switch is the passenger seat door and the rear seat right door. It is preferable that the driver's seat door is provided corresponding to each of the left door and the rear seat left door.

  According to this configuration, the configuration and control of the vehicle opening / closing member control device including the passenger seat door, the rear seat right door, and the rear seat left door as the other seat doors can be simplified.

  According to an embodiment of the present disclosure, it is possible to provide an opening / closing member control device that can be simplified.

The block circuit diagram which shows the outline of the power window system of 1st Embodiment. Partial block circuit diagram of the power window system. Operation waveform diagram of the power window system. (A) and (b) are some block circuit diagrams of the power window system of a comparative example. The partial block circuit diagram which shows the outline of the power window system of 2nd Embodiment. Operation waveform diagram of the power window system.

Hereinafter, each embodiment will be described.
(First embodiment)
Hereinafter, the first embodiment will be described.

  As shown in FIG. 1, the power window system mounted on the vehicle includes power window motors 11, 31, 41, 51 (“PWM”) provided inside the doors 10, 30, 40, 50 of the vehicle 1. Is provided). Each power window motor 11, 31, 41, 51 includes an ECU as a control unit, a motor as a drive source, and the like, and window glasses 12, 32, 42 provided on each door 10, 30, 40, 50. , 52 (denoted as “WG”). Each power window motor 11, 31, 41, 51 is connected to a vehicle battery 2 (indicated as “BAT”), and power for driving is supplied from the battery 2.

  The driver's seat door 10 is provided with an operation unit 13. The operation unit 13 is provided with open / close switches 21, 22, 23, 24 and a wind lock switch 25. The open / close switch 21 is a self-seat window open / close switch for opening and closing the window glass 12 of the driver's seat door 10. Open / close switches 22, 23, and 24 are for opening and closing the window glass 32 of the passenger seat door 30 corresponding to the other seat door, the window glass 42 of the rear seat right door 40, and the window glass 52 of the rear seat left door 50, respectively. It is a seat window opening / closing switch.

  The open / close switch 21 is connected to the battery 2 via the IG relay 3 and is also connected to the power window motor 11. The IG relay 3 corresponds to a power switch. As the power switch, an ignition switch (IG switch) for starting and stopping the vehicle, an electromagnetic relay that is turned on / off based on the operation of the ignition switch, and the like can be used. For example, the IG relay 3 is closed when the IG switch is turned on, and is opened when the IG switch is turned off. When the IG relay 3 is closed, the battery voltage is supplied from the battery 2 to the open / close switch 21 via the IG relay 3. The power window motor 11 of the driver's seat door 10 opens and closes the window glass 12 based on the operation of the opening / closing switch 21.

  The open / close switches 22 to 24 are connected to the battery 2 via the window lock switch 25. The open / close switch 22 is connected to the power window motor 31 via the open / close switch 33 of the passenger seat door 30. The open / close switch 23 is connected to the power window motor 41 via the open / close switch 43 of the rear seat right door 40. The open / close switch 24 is connected to the power window motor 51 via the open / close switch 53 of the rear seat left door 50.

  The window lock switch 25 is a lock for prohibiting the opening and closing of the window of the other seat, that is, the window glass 32 of the passenger seat door 30, the window glass 42 of the rear right seat door 40, and the window glass 52 of the rear seat left door 50. Switch.

  When the window lock switch 25 is turned on, the battery voltage is supplied to the open / close switch 22. Then, a voltage corresponding to the operation of the opening / closing switch 22 of the driver's seat door 10 and the opening / closing switch 33 of the passenger seat door 30 is supplied to the power window motor 31 of the passenger seat door 30. The power window motor 31 of the passenger seat door 30 detects the operation of the opening / closing switch 22 of the driver seat door 10 and the opening / closing switch 33 of the passenger seat door 30 based on the voltage, and the window glass 32 is changed in accordance with these operations. Open and close.

  Similarly, a voltage corresponding to the operation of the opening / closing switch 23 of the driver's seat door 10 and the opening / closing switch 43 of the rear seat right door 40 is supplied to the power window motor 41 of the rear seat right door 40. Based on the voltage, the power window motor 41 of the rear seat left door 50 detects the operation of the opening / closing switch 23 of the driver's seat door 10 and the opening / closing switch 43 of the rear seat right door 40, and in response to those operations, the wind glass 42 is opened and closed.

  Similarly, a voltage corresponding to the operation of the opening / closing switch 24 of the driver's seat door 10 and the opening / closing switch 53 of the rear seat left door 50 is supplied to the power window motor 51 of the rear seat left door 50. Based on the voltage, the power window motor 51 of the rear seat right door 40 detects the operation of the opening / closing switch 24 of the driver's seat door 10 and the opening / closing switch 53 of the rear seat left door 50, and in response to these operations, the wind glass 52 is opened and closed.

  On the other hand, when the window lock switch 25 is turned off, the battery voltage is not supplied to the open / close switches 22 to 24 of the driver's seat door 10. Therefore, even if the opening / closing switch 22 of the driver's seat door 10 and the opening / closing switch 33 of the passenger seat door 30 are operated, the voltage at the power window motor 31 of the passenger seat door 30 does not change. That is, when the window lock switch 25 is turned off, the operation of the open / close switches 22 and 33 becomes invalid. Similarly, the operation of the open / close switch 23 of the driver's seat door 10 and the open / close switch 43 of the rear right seat door 40 is disabled, and the operation of the open / close switch 24 of the driver seat door 10 and the open / close switch 53 of the rear seat left door 50 is disabled. become. Accordingly, the opening and closing of the window glasses 32, 42, 52 of the doors 30, 40, 50 other than the driver's seat door 10 is prohibited.

FIG. 2 shows the configuration and connection of the opening / closing switch 22 of the driver's seat door 10, the opening / closing switch 33 of the passenger seat door 30, and the power window motor 31.
The opening / closing switch 22 of the driver's seat door 10 includes a first external terminal T1a and a second external terminal T1b. Similarly, the opening / closing switch 33 of the passenger seat door 30 includes a first external terminal T2a and a second external terminal T2b.

  The first external terminal T1a of the opening / closing switch 22 of the driver seat door 10 is connected to the window lock switch 25, and the second external terminal T1b of the opening / closing switch 22 is connected to the first external terminal T2a of the opening / closing switch 33 of the passenger seat door 30. It is connected. A second external terminal T2b of the open / close switch 33 is connected to an input terminal 35a of the ECU 35 of the power window motor 31.

The opening / closing switch 22 of the driver's seat door 10 includes a switch portion 22S and resistors R11 and R12. The resistor R11 corresponds to the first resistor, and the resistor R12 corresponds to the second resistor.
The switch unit 22S includes a common contact 22c, a non-operation contact 22n, an up contact 22u, and a down contact 22d. The open / close switch 22 has an operation member (not shown) that is operated by a passenger. When the operation member is not operated, the common contact 22c is connected to the non-operation contact 22n by an elastic member (not shown). The common contact 22c is connected to the up contact 22u or the down contact 22d according to the operation on the operation member. In the present embodiment, the common contact 22c is switched from the non-operation contact 22n to the up contact 22u by operating the operation member to the up side (UP). Further, by operating the operation member to the down side (DOWN), the common contact 22c is switched and connected from the non-operation contact 22n to the down contact 22d.

  The non-operation contact 22n is connected to the first external terminal T1a, and the common contact 22c is connected to the second external terminal T1b. The up contact 22u is connected to the first external terminal T1a via the resistor R11. The down contact 22d is connected to the first external terminal T1a via the resistor R12. In the present embodiment, the resistance value of the resistor R11 and the resistance value of the resistor R12 are different from each other.

The open / close switch 33 of the passenger seat door 30 includes a switch portion 33S and resistors R21 and R22. The resistor R21 corresponds to the first resistor, and the resistor R22 corresponds to the second resistor.
The switch unit 33S includes a common contact 33c, a non-operation contact 33n, an up contact 33u, and a down contact 33d. The opening / closing switch 33 has an operation member (not shown) that is operated by a passenger. When the operation member is not operated, the common contact 33c is connected to the non-operation contact 33n by an elastic member (not shown). The common contact 33c is connected to the up contact 33u or the down contact 33d according to the operation on the operation member. In the present embodiment, the common contact 33c is switched from the non-operation contact 33n to the up contact 33u by operating the operation member to the up side (UP). Further, by operating the operation member to the down side (DOWN), the common contact 33c is switched and connected from the non-operation contact 33n to the down contact 33d.

  The non-operation contact 33n is connected to the first external terminal T2a, and the common contact 33c is connected to the second external terminal T2b. The up contact 33u is connected to the first external terminal T2a via the resistor R21. The down contact 33d is connected to the first external terminal T2a via the resistor R22. In the present embodiment, the resistance value of the resistor R21 and the resistance value of the resistor R22 are different from each other.

The power window motor 31 includes an ECU 35 and a motor 36.
The ECU 35 includes a microcomputer 35c and a resistor R30. The resistor R30 is connected between the input terminal 35a and the ground terminal 35g. The ground terminal 35g is connected to the negative terminal of the battery 2 via the ground of the vehicle, for example, a frame.

  A microcomputer 35c is connected to the input terminal 35a. In the present embodiment, the microcomputer 35c has an A / D conversion function and a timer function. The microcomputer 35c converts the voltage at the input terminal 35a into a digital value by an A / D conversion function. This digital value is a voltage value at the input terminal 35a. That is, the microcomputer 35c obtains the voltage value Vi at the input terminal 35a. Further, the microcomputer 35c obtains a voltage value at the input terminal 35a at a predetermined sampling interval by a timer function. Therefore, the microcomputer 35c can capture the change in the voltage value Vi at the input terminal 35a. The microcomputer 35c performs processing using a digital voltage value Vi, which will be described as a terminal voltage Vi.

  The ECU 35 controls the operation of the motor 36 based on the terminal voltage Vi of the input terminal 35a obtained by the microcomputer 35c. By the operation of the motor 36, the window glass 32 of the passenger seat door 30 shown in FIG.

  In FIG. 2, the configuration and connection of the opening / closing switch 22 of the driver seat door 10, the opening / closing switch 33 of the passenger seat door 30, and the power window motor 31 are shown. The open / close switches 23 and 24 of the driver's seat door 10, the open / close switch 43 and the power window motor 41 of the rear seat right door 40, and the open / close switch 53 and the power window motor 51 of the rear seat left door 50 shown in FIG. Since it is the same as the structure and connection shown, drawings and description are omitted.

(Function)
Next, the operation of the power window system of this embodiment will be described.
First, the terminal voltage Vi of the input terminal 35a by the open / close switches 22 and 33 will be described.

  As shown in FIG. 2, in the driver's seat door 10 and the passenger seat door 30, when the open / close switches 22 and 33 are in the non-operating state, the common contacts 22c and 33c are connected to the non-operating contacts 22n and 33n. These non-operation contacts 22n and 33n are directly connected to the first external terminals T1a and T2a of the open / close switches 22 and 33. The first external terminal T1a of the open / close switch 22 is connected to the positive terminal of the battery 2 via the wind lock switch 25 and the IG relay 3. The second external terminal T2b of the open / close switch 33 is connected to an input terminal 35a of the ECU 35, and a resistor R30 is connected between the input terminal 35a and the ground terminal 35g.

  Accordingly, the opening / closing switch 22 is disconnected from the battery 2 when at least one of the IG relay 3 and the window lock switch 25 is turned off. Therefore, the terminal voltage Vi of the input terminal 35a becomes the ground level (0V). The terminal voltage Vi of 0V is detected by the ECU 35 of the power window motor 31.

  When the IG relay 3 and the window lock switch 25 are turned on and both the open / close switches 22 and 33 are not operated, the battery voltage of the battery 2 is applied to the input terminal 35a of the ECU 35. Accordingly, the terminal voltage Vi of the input terminal 35a is equal to the battery voltage VB of the battery 2. A terminal voltage Vi equal to the battery voltage VB is detected by the ECU 35 of the power window motor 31.

  When the opening / closing switch 22 of the driver's seat door 10 is operated to the up side, the common contact 22c is connected to the up contact 22u. Accordingly, the resistor R11 of the opening / closing switch 22 is connected to the input terminal 35a of the power window motor 31 via the opening / closing switch 33 of the passenger seat door 30. The terminal voltage at the input terminal 35a is a voltage (first voltage V1) obtained by dividing the battery voltage VB by the resistor R11 and the resistor R30. The first voltage V1 is detected by the ECU 35 of the power window motor 31.

  When the open / close switch 22 of the driver's seat door 10 is operated to the down side, the common contact 22c is connected to the down contact 22d. Accordingly, the resistor R12 of the opening / closing switch 22 is connected to the input terminal 35a of the power window motor 31 via the opening / closing switch 33 of the passenger seat door 30. The terminal voltage at the input terminal 35a is a voltage (second voltage V2) obtained by dividing the battery voltage VB by the resistor R12 and the resistor R30. The second voltage V2 is detected by the ECU 35 of the power window motor 31.

  When the opening / closing switch 33 of the passenger seat door 30 is operated to the up side, the common contact 33c is connected to the up contact 33u. Thereby, the resistor R21 of the open / close switch 33 is connected to the input terminal 35a of the power window motor 31. The terminal voltage at the input terminal 35a is a voltage (third voltage V3) obtained by dividing the battery voltage VB by the resistor R21 and the resistor R30. The third voltage V3 is detected by the ECU 35 of the power window motor 31.

  When the opening / closing switch 33 of the passenger seat door 30 is operated to the down side, the common contact 33c is connected to the down contact 33d. Accordingly, the resistor R22 of the open / close switch 33 is connected to the input terminal 35a of the power window motor 31. The terminal voltage at the input terminal 35a is a voltage (fourth voltage V4) obtained by dividing the battery voltage VB by the resistor R22 and the resistor R30. The fourth voltage V4 is detected by the ECU 35 of the power window motor 31.

Next, the operation of the power window motor 31 will be described.
FIG. 3 shows the state of the IG relay 3, the wind lock switch 25, the open / close switches 22 and 33, and the change in the terminal voltage Vi. In FIG. 3, in the open / close switches 22 and 33, the contacts 22u, 22d, 33u, and 33d to which the common contacts 22c and 33c are connected are shown as “ON” when connected to the common contacts 22c and 33c.

  As shown in FIG. 3, when the IG relay 3 is off and the window lock switch 25 is on, the terminal voltage Vi is 0V. The ECU of the power window motor 31 detects this 0V terminal voltage Vi and prohibits the operation.

  When the IG relay 3 is turned on, since the window lock switch 25 is turned on, the battery voltage VB is input to the power window motor 31 via the opening / closing switch 22 of the driver's seat door 10 and the opening / closing switch 33 of the passenger seat door 30. It is supplied to the terminal 35a. Accordingly, the terminal voltage Vi at the input terminal 35a is equal to the battery voltage VB. The ECU of the power window motor 31 detects a terminal voltage Vi equal to the battery voltage VB and determines that it can be operated.

  Next, when the window lock switch 25 is turned off, the battery voltage VB is not supplied to the input terminal 35a, so that the terminal voltage Vi becomes 0V. The ECU of the power window motor 31 detects this 0V terminal voltage Vi and prohibits the operation.

When operable, the terminal voltage Vi changes from the battery voltage VB to a voltage corresponding to the resistance of the open / close switch to be operated.
When the opening / closing switch 22 of the driver's seat door 10 is operated to the up side, the terminal voltage Vi of the input terminal 35a becomes the first voltage V1 due to the resistance R11 of the opening / closing switch 22 and the resistance R30 of the power window motor 31. At this time, the ECU 35 of the power window motor 31 detects that the open / close switch 22 of the driver's seat door 10 has been operated to the up side based on the first voltage V1. Then, the ECU 35 drives the motor 36 and raises the window glass 32, that is, closes it (UP operation). When the open / close switch 22 is not operated, the terminal voltage Vi becomes equal to the battery voltage VB. The ECU 35 of the power window motor 31 stops the operation of the window glass 32 based on the terminal voltage Vi. That is, the ECU 35 of the power window motor 31 closes the window glass 32 while detecting the first voltage V1 as the terminal voltage Vi.

  When the opening / closing switch 22 of the driver's seat door 10 is operated to the down side, the terminal voltage Vi of the input terminal 35a becomes the second voltage V2 due to the resistance R12 of the opening / closing switch 22 and the resistance R30 of the power window motor 31. At this time, the ECU 35 of the power window motor 31 detects that the opening / closing switch 22 of the driver's seat door 10 has been operated to the down side based on the second voltage V2. Then, the ECU 35 drives the motor 36 to bring down the window glass 32, that is, open operation (DOWN operation). When the open / close switch 22 is not operated, the terminal voltage Vi becomes equal to the battery voltage VB. The ECU 35 of the power window motor 31 stops the operation of the window glass 32 based on the terminal voltage Vi. That is, the ECU 35 of the power window motor 31 opens the window glass 32 while detecting the second voltage V2 as the terminal voltage Vi.

  When the opening / closing switch 33 of the passenger seat door 30 is operated to the up side, the terminal voltage Vi of the input terminal 35a becomes the third voltage V3 due to the resistance R21 of the opening / closing switch 33 and the resistance R30 of the power window motor 31. At this time, the ECU 35 of the power window motor 31 detects that the open / close switch 33 of the passenger seat door 30 has been operated to the up side based on the third voltage V3. Then, the ECU 35 drives the motor 36 to raise the window glass 32, that is, to close it. When the open / close switch 33 is not operated, the terminal voltage Vi becomes equal to the battery voltage VB. The ECU 35 of the power window motor 31 stops the operation of the window glass 32 based on the terminal voltage Vi. That is, the ECU 35 of the power window motor 31 closes the window glass 32 while detecting the third voltage V3 as the terminal voltage Vi.

  When the opening / closing switch 33 of the passenger seat door 30 is operated to the down side, the terminal voltage Vi of the input terminal 35a becomes the fourth voltage V4 due to the resistance R22 of the opening / closing switch 33 and the resistance R30 of the power window motor 31. At this time, the ECU 35 of the power window motor 31 detects that the open / close switch 33 of the passenger door 30 has been operated to the down side based on the fourth voltage V4. Then, the ECU 35 drives the motor 36 to bring down the window glass 32, that is, to open it. When the open / close switch 33 is not operated, the terminal voltage Vi becomes equal to the battery voltage VB. The ECU 35 of the power window motor 31 stops the operation of the window glass 32 based on the terminal voltage Vi. That is, the ECU 35 of the power window motor 31 opens the window glass 32 while detecting the fourth voltage V4 as the terminal voltage Vi.

Next, a comparative example for this embodiment will be described. In addition, the same code | symbol is attached | subjected about the same member as said 1st Embodiment.
FIG. 4A shows a comparative example using serial communication.

  The driver's seat door 10 is provided with an ECU 71 to which a wind lock switch 25, an up switch S1, and a down switch S2 are connected. The ECU 71 detects the on / off of the windlock switch 25, the up switch S1, and the down switch S2, generates a serial signal corresponding to the detection result, and sends it to the ECU 73 of the passenger seat door 30 through one cable 72. Output. An up switch S3 and a down switch S4 provided on the passenger seat door 30 are connected to the ECU 73. The ECU 73 performs serial communication, detects ON / OFF of the up switch S3 and the down switch S4, and receives the detection result and the window lock switch 25, the up switch S1, and the down switch S2 of the driver's door 10 which are received by serial communication. The motor 74 is driven based on on / off. The motor 74 opens and closes the window glass 32 provided on the passenger seat door 30.

  Thus, the driver's seat door requires on / off detection of the wind lock switch 25, the up switch S1, and the down switch S2, and serial communication corresponding to the detection result. In the passenger seat door, serial communication and on / off detection of the up switch S3 and the down switch S4 are required. Thus, complicated control is required.

  FIG. 4A shows a configuration for opening and closing the window glass of the passenger seat door 30, but the same configuration is required for the rear seat right door and the rear seat left door. That is, the number of ECUs corresponding to the other-seat door controlled from the driver's seat door 10 is required, and the configuration and control of the power window system in the vehicle are complicated.

  4B shows an example in which the window lock switch 25, the up switch S1, and the down switch S2 provided on the driver's seat door 10 are directly connected to the ECU 81 of the passenger seat door 30. FIG. The wind lock switch 25, the up switch S1, and the down switch S2 are connected to the ECU 81 of the passenger seat door 30 via cables 82, 83, and 84, respectively. An up switch S3 and a down switch S4 provided on the passenger seat door 30 are connected to the ECU 81. The ECU 35 needs to detect ON / OFF of the wind lock switch 25, the up switch S1, and the down switch S2 of the driver seat door 10, and ON / OFF of the up switch S3 and the down switch S4 of the passenger seat door 30, respectively.

  FIG. 4B shows a configuration in which the window glass of the passenger seat door 30 is opened and closed, but the same configuration is required for the rear seat right door and the rear seat left door. That is, the number of cables connected to the driver's seat door 10 increases, and the configuration and control of the power window system in the vehicle become complicated.

  On the other hand, the power window system of this embodiment opens and closes the window glass 32 according to the terminal voltage Vi of the input terminal 35a of the power window motor 31. That is, the ECU 35 of the passenger door 30 only needs to detect the terminal voltage Vi of one input terminal 35a. Further, the opening / closing switch 22 of the driver's seat door 10 and the opening / closing switch 33 of the passenger seat door 30 may be connected by a single cable. For this reason, the configuration and control of the power window system in the vehicle are simplified.

  Further, as shown in FIG. 1, the open / close switches 22 to 24 for the other seats provided on the driver's seat door 10 are connected to the battery 2 via the window lock switch 25 and the IG relay 3. Therefore, it is possible to easily transmit to the power window motors 31, 41, 51 of the other seats shown in FIG. 2 whether the window lock switch 25 is on or off, that is, whether the window glass 32, 42, 52 is operable or not. Further, on / off of the IG relay 3, that is, on / off of the ignition switch can be received without going through an ECU for controlling the vehicle, for example.

As described above, according to the present embodiment, the following effects can be obtained.
(1-1) The open / close switch 22 of the driver's seat door 10 of the vehicle 1 and the open / close switch 33 of the passenger seat door 30 are connected in series, and the open / close switch 33 operates to open and close the window glass 32 of the passenger seat door 30. It is connected to the wind motor 31. The ECU 35 of the power window motor 31 opens and closes the window glass 32 provided on the passenger seat door 30 based on the terminal voltage Vi of the input terminal 35a. Therefore, since the operation of the opening / closing switch 22 of the driver's seat door 10 and the operation of the opening / closing switch 33 of the passenger seat door 30 can be detected based on the terminal voltage Vi of the input terminal 35a, both the opening / closing switches 22, 33 for the power window motor 31 are detected. Connection and control can be simplified.

  (1-2) The open / close switch 22 and the open / close switch 33 are configured such that the terminal voltage Vi when the window glass 32 is opened is different from the terminal voltage Vi when the window glass 32 is closed. Therefore, the opening operation and the closing operation can be easily detected by the terminal voltage Vi.

  (1-3) The open / close switch 22 of the driver's seat door 10 is connected to the battery 2 of the vehicle 1 via the IG relay 3. Therefore, on / off of the IG relay 3, that is, on / off of the ignition switch, can be received by the terminal voltage Vi, for example, without going through the ECU that controls the vehicle.

  (1-4) The opening / closing switch 22 of the driver's seat door 10 is connected to the battery 2 via the window lock switch 25 and the IG relay 3 for prohibiting the opening / closing of the window glass 32 of the passenger seat door 30. Therefore, the state of the window lock switch 25 can be easily transmitted from the driver seat door 10 to the power window motor 31 of the passenger seat door 30 by the terminal voltage Vi.

  (1-5) The open / close switch 22 and the open / close switch 33 include resistors R11, R12, R21, and R22, respectively. The power window motor 31 includes a resistor R30 connected to the input terminal 35a. The battery voltage VB of the battery 2 is divided by the resistors R11, R12, R21, R22 of the open / close switch 22 or the open / close switch 33 and the resistor R30 of the power window motor 31. Therefore, the terminal voltage Vi can be easily set by the resistors R11, R12, R21, R22 of the open / close switch 22, the open / close switch 33, and the resistor R30 of the power window motor 31.

  (1-6) The resistors R11 and R12 of the opening / closing switch 22 of the driver's seat door 10 and the resistors R21 and R22 of the opening / closing switch 33 of the passenger seat door 30 have different resistance values. Therefore, the operation of the open / close switch 22 and the operation of the open / close switch 33 can be easily discriminated by the terminal voltage Vi.

  (1-7) The ECU 35 of the power window motor 31 opens and closes the window glass 32 while detecting the terminal voltage Vi according to the operation of the open / close switches 22 and 33. Therefore, the position of the window glass 32 can be easily changed by the open / close switch 22 or the open / close switch 33.

(Second Embodiment)
The second embodiment will be described below.
In addition, in this embodiment, the same code | symbol is attached | subjected about the same structural member as the said embodiment. Moreover, about the same structure as 1st Embodiment, the one part or all part of the description may be abbreviate | omitted.

  In the present embodiment, the schematic configuration of the power window system is the same as that of the first embodiment. Therefore, the driver's seat door 10 and the passenger seat door 30 will be described as one other seat door.

FIG. 5 shows the configuration and connection of the opening / closing switch 22 of the driver seat door 10, the opening / closing switch 33 of the passenger seat door 30, and the power window motor 31 according to the present embodiment.
The opening / closing switch 22 of the driver's seat door 10 includes a switch portion 22S and resistors R11, R12, R13, and R14. The resistor R11 corresponds to the first resistor, and the resistor R12 corresponds to the second resistor. The resistors R13 and R14 correspond to a third resistor.

  The switch unit 22S includes a common contact 22c, a non-operation contact 22n, an up contact 22u, an auto up contact 22ua, a down contact 22d, and an auto down contact 22da. The open / close switch 22 has an operation member (not shown) that is operated by a passenger. When the operation member is not operated, the common contact 22c is connected to the non-operation contact 22n by an elastic member (not shown). The common contact 22c is connected to the up contact 22u, the auto up contact 22ua, the down contact 22d, or the auto down contact 22da according to the operation on the operation member.

  In the present embodiment, the common contact 22c is switched from the non-operation contact 22n to the up contact 22u by operating the operation member to the up side (UP). Further, by operating the operating member to the up side (AUTO), the common contact 22c is connected to the up contact 22u and the auto up contact 22ua. On the other hand, by operating the operation member to the down side (DOWN), the common contact 22c is switched and connected from the non-operation contact 22n to the down contact 22d. Further, by operating the operation member to the down side (AUTO), the common contact is connected to the down contact 22d and the auto-down contact 22da.

  The up contact 22u is connected to the first external terminal T1a via the resistor R11. The auto-up contact 22ua is connected to the first external terminal T1a via the resistor R13. The down contact 22d is connected to the first external terminal T1a via the resistor R12. The auto-down contact 22da is connected to the first external terminal T1a via the resistor R14.

  In the present embodiment, the resistance value of the resistor R11 and the resistance value of the resistor R12 are different from each other. Further, the resistance value of the resistor R11 and the resistance value of the resistor R14 are different from each other, and the resistance value of the resistor R12 and the resistance value of the resistor R14 are different from each other. In the present embodiment, the resistance value of the resistor R11 and the resistance value of the resistor R14 are set to the same value, and the resistance value of the resistor R12 and the resistance value of the resistor R13 are set to the same value.

  The open / close switch 33 of the passenger seat door 30 includes a switch portion 33S and resistors R21, R22, R23, and R24. The resistor R21 corresponds to the first resistor, and the resistor R22 corresponds to the second resistor. The resistors R23 and R24 correspond to a third resistor.

  The switch unit 33S includes a common contact 33c, a non-operation contact 33n, an up contact 33u, an auto up contact 33ua, a down contact 33d, and an auto down contact 33da. The opening / closing switch 33 has an operation member (not shown) that is operated by a passenger. When the operation member is not operated, the common contact 33c is connected to the non-operation contact 33n by an elastic member (not shown). The common contact 33c is connected to the up contact 33u, the auto up contact 33ua, the down contact 33d, or the auto down contact 33da in accordance with an operation on the operation member.

  In the present embodiment, the common contact 33c is switched from the non-operation contact 33n to the up contact 33u by operating the operation member to the up side (UP). Further, by operating the operation member to the up side (AUTO), the common contact 33c is connected to the up contact 33u and the auto up contact 33ua. On the other hand, by operating the operation member to the down side (DOWN), the common contact 33c is switched and connected from the non-operation contact 33n to the down contact 33d. Further, by operating the operation member to the down side (AUTO), the common contact is connected to the down contact 33d and the auto-down contact 33da.

  The up contact 33u is connected to the first external terminal T2a via the resistor R21. The auto-up contact 33ua is connected to the first external terminal T2a via the resistor R23. The down contact 33d is connected to the first external terminal T2a via the resistor R22. The auto-down contact 33da is connected to the first external terminal T2a via the resistor R24.

  In the present embodiment, the resistance value of the resistor R21 and the resistance value of the resistor R22 are different from each other. Further, the resistance value of the resistor R21 and the resistance value of the resistor R24 are different from each other, and the resistance value of the resistor R22 and the resistance value of the resistor R24 are different from each other. In the present embodiment, the resistance value of the resistor R21 and the resistance value of the resistor R24 are set to the same value, and the resistance value of the resistor R22 and the resistance value of the resistor R23 are set to the same value.

  In FIG. 5, the configuration and connection of the opening / closing switch 22 of the driver's seat door 10, the opening / closing switch 33 of the passenger seat door 30, and the power window motor 31 are shown. The open / close switches 23 and 24 of the driver's seat door 10, the open / close switch 43 and the power window motor 41 of the rear right door 40, and the open / close switch 53 and the power window motor 51 of the rear left door 50 shown in FIG. Since it is the same as the structure and connection shown, the drawings and description are omitted.

(Function)
Next, the operation of the power window system of this embodiment will be described.
When the opening / closing switch 22 of the driver's seat door 10 is operated to the up side, the common contact 22c is connected to the up contact 22u. Accordingly, the resistor R11 of the opening / closing switch 22 is connected to the input terminal 35a of the ECU 35 included in the power window motor 31 via the opening / closing switch 33 of the passenger seat door 30. The terminal voltage at the input terminal 35a is a voltage (first voltage V1) obtained by dividing the battery voltage VB by the resistor R11 and the resistor R30. The first voltage V1 is detected by the ECU 35 of the power window motor 31.

  When the open / close switch of the driver's seat door 10 is further operated to the up side (AUTO), the common contact 22c is connected to the up contact 22u and the auto up contact 22ua. Accordingly, the terminal voltage at the input terminal 35a is a voltage (fifth voltage V5) obtained by dividing the battery voltage VB by the combined resistance of the resistors R11 and R13 connected in parallel and the resistor R30. The fifth voltage V5 is detected by the ECU 35 of the power window motor 31. That is, the ECU 35 detects a change from the first voltage V1 to the fifth voltage V5 as the terminal voltage Vi.

  When the open / close switch 22 of the driver's seat door 10 is operated to the down side, the common contact 22c is connected to the down contact 22d. Accordingly, the resistor R12 of the opening / closing switch 22 is connected to the input terminal 35a of the power window motor 31 via the opening / closing switch 33 of the passenger seat door 30. The terminal voltage at the input terminal 35a is a voltage (second voltage V2) obtained by dividing the battery voltage VB by the resistor R12 and the resistor R30. The second voltage V2 is detected by the ECU 35 of the power window motor 31.

  When the open / close switch of the driver's seat door 10 is further operated to the down side (AUTO), the common contact 22c is connected to the down contact 22d and the auto-down contact 22da. Accordingly, the terminal voltage at the input terminal 35a is a voltage obtained by dividing the battery voltage VB by the combined resistance of the resistor R12 and the resistor R14 connected in parallel and the resistor R30. In this embodiment, the resistance values of the resistors R11 and R14 are equal to each other, and the resistance values of the resistors R12 and R13 are equal to each other. Accordingly, the terminal voltage Vi at this time is the fifth voltage V5. The fifth voltage V5 is detected by the ECU 35 of the power window motor 31. That is, the ECU 35 detects a change from the second voltage V2 to the fifth voltage V5 as the terminal voltage Vi.

  When the opening / closing switch 33 of the passenger seat door 30 is operated to the up side, the common contact 33c is connected to the up contact 33u. Thereby, the resistor R21 of the open / close switch 33 is connected to the input terminal 35a of the power window motor 31. The terminal voltage at the input terminal 35a is a voltage (third voltage V3) obtained by dividing the battery voltage VB by the resistor R21 and the resistor R30. The third voltage V3 is detected by the ECU 35 of the power window motor 31.

  When the opening / closing switch of the passenger seat door 30 is further operated to the up side (AUTO), the common contact 33c is connected to the up contact 33u and the auto up contact 33ua. Therefore, the terminal voltage at the input terminal 35a is a voltage (sixth voltage V6) obtained by dividing the battery voltage VB by the combined resistance of the resistors R21 and R23 connected in parallel and the resistor R30. The sixth voltage V6 is detected by the ECU 35 of the power window motor 31. That is, the ECU 35 detects a change from the third voltage V3 to the fifth voltage V5 as the terminal voltage Vi.

  When the opening / closing switch 33 of the passenger seat door 30 is operated to the down side, the common contact 33c is connected to the down contact 33d. Accordingly, the resistor R22 of the open / close switch 33 is connected to the input terminal 35a of the power window motor 31. The terminal voltage at the input terminal 35a is a voltage (fourth voltage V4) obtained by dividing the battery voltage VB by the resistor R22 and the resistor R30. The fourth voltage V4 is detected by the ECU 35 of the power window motor 31.

  When the opening / closing switch of the passenger seat door 30 is further operated to the down side (AUTO), the common contact 33c is connected to the down contact 33d and the auto down contact 33da. Therefore, the terminal voltage at the input terminal 35a is a voltage obtained by dividing the battery voltage VB by the combined resistance of the resistor R22 and the resistor R24 connected in parallel and the resistor R30. In this embodiment, the resistance values of the resistors R21 and R24 are equal to each other, and the resistance values of the resistors R22 and R23 are equal to each other. Therefore, the terminal voltage Vi at this time is the sixth voltage V6. The sixth voltage V6 is detected by the ECU 35 of the power window motor 31. That is, the ECU 35 detects a change from the fourth voltage V4 to the sixth voltage V6 as the terminal voltage Vi.

Next, the operation of the power window motor 31 will be described.
FIG. 6 shows the state of the IG relay 3, the wind lock switch 25, the open / close switches 22 and 33, and the change in the terminal voltage Vi. In FIG. 6, in the open / close switches 22 and 33, the contacts 22u, 22ua, 22d, 22da, 33u, 33ua, 33d, and 33da to which the common contacts 22c and 33c are connected are connected to the common contacts 22c and 33c. Is shown as “ON”.

  As shown in FIG. 6, when the IG relay 3 is off and the window lock switch 25 is on, the terminal voltage Vi is 0V. The ECU of the power window motor 31 detects this 0V terminal voltage Vi and prohibits the operation.

  When the opening / closing switch 22 of the driver's seat door 10 is operated to the up side, the terminal voltage Vi of the input terminal 35a becomes the first voltage V1 due to the resistance R11 of the opening / closing switch 22 and the resistance R30 of the power window motor 31. At this time, the ECU 35 of the power window motor 31 drives the motor 36 based on the first voltage V1, and causes the window glass 32 (see FIG. 1) to perform an up operation (UP operation), that is, a close operation.

  When the open / close switch 22 is further operated to the up side, the terminal voltage Vi of the input terminal 35a becomes the fifth voltage V5 due to the resistors R11 and R13 of the open / close switch 22 and the resistor R30 of the power window motor 31. The ECU 35 detects that the open / close switch 22 of the driver's seat door 10 has been operated up to the auto-up contact 22ua based on the fifth voltage V5. Then, the ECU 35 closes the window glass 32 to the fully closed position (AUTO-UP operation). The fully closed position is detected based on a change in the voltage between the terminals of the sensor and the motor 36.

  When the opening / closing switch 22 of the driver's seat door 10 is operated to the down side, the terminal voltage Vi of the input terminal 35a becomes the second voltage V2 due to the resistance R12 of the opening / closing switch 22 and the resistance R30 of the power window motor 31. At this time, the ECU 35 of the power window motor 31 drives the motor 36 based on the second voltage V2, and causes the window glass 32 to perform a down operation (DOWN operation), that is, an opening operation.

  When the open / close switch 22 is further operated to the down side, the terminal voltage Vi of the input terminal 35a becomes the fifth voltage V5 due to the resistors R12, R14 of the open / close switch 22 and the resistor R30 of the power window motor 31. Based on the fifth voltage V5, the ECU 35 detects that the open / close switch 22 of the driver's seat door 10 has been operated to the auto-down contact 22da. Then, the ECU 35 opens the window glass 32 to the fully open position (AUTO-DOWN operation). The fully open position is detected based on a change in the voltage between the terminals of the sensor and the motor 36.

  When the opening / closing switch 33 of the passenger seat door 30 is operated to the up side, the terminal voltage Vi of the input terminal 35a becomes the third voltage V3 due to the resistance R21 of the opening / closing switch 33 and the resistance R30 of the power window motor 31. At this time, the ECU 35 of the power window motor 31 drives the motor 36 on the basis of the third voltage V3, and causes the window glass 32 to perform an up operation, that is, a closing operation.

  When the open / close switch 33 is further operated to the up side, the terminal voltage Vi of the input terminal 35a becomes the sixth voltage V6 due to the resistors R21 and R23 of the open / close switch 33 and the resistor R30 of the power window motor 31. Based on the sixth voltage V6, the ECU 35 detects that the open / close switch 33 of the passenger seat door 30 has been operated to the auto-up contact 33ua. Then, the ECU 35 closes the window glass 32 to the fully closed position.

  When the opening / closing switch 33 of the passenger seat door 30 is operated to the down side, the terminal voltage Vi of the input terminal 35a becomes the fourth voltage V4 due to the resistance R22 of the opening / closing switch 33 and the resistance R30 of the power window motor 31. At this time, the ECU 35 of the power window motor 31 drives the motor 36 on the basis of the fourth voltage V4 and causes the window glass 32 to perform a down operation, that is, an opening operation.

  When the open / close switch 33 is further operated to the down side, the terminal voltage Vi of the input terminal 35a becomes the sixth voltage V6 due to the resistors R22 and R24 of the open / close switch 33 and the resistor R30 of the power window motor 31. Based on the sixth voltage V6, the ECU 35 detects that the open / close switch 33 of the passenger seat door 30 has been operated to the auto-down contact 33da. Then, the ECU 35 opens the window glass 32 to the fully open position.

As described above, according to this embodiment, in addition to the effects of the first embodiment, the following effects can be obtained.
(2-1) The open / close switch 22 of the driver's seat door 10 includes an auto-up contact 22ua and an auto-down contact 22da in addition to the up contact 22u and the down contact 22d. Also in such an open / close switch 22, the open / close switch 22 of the driver's seat door 10 can be connected to the power window motor 31 of the passenger's seat door 30, which is another seat, with a single cable, thus simplifying the power window system. Can be

  (2-2) By operating the opening / closing switch 22 of the driver's seat door 10, the wind glass 32 of the passenger seat 30, which is the other seat, is operated up and down, and all of the wind glass 32 is operated by the auto up operation and the auto down operation. It can be actuated to the closed and fully open positions.

In addition, you may implement each said embodiment in the following aspects.
In the above embodiment, the terminal voltage Vi of the input terminal 35a only needs to change according to the operation of the open / close switch, and the connection relationship of the contacts and the value of each resistor in the open / close switch may be changed as appropriate.

  For example, the resistance values of the resistors R11 and R21, and the resistors R12 and R22 may be the same value. In this case, switches having the same configuration can be used for the opening / closing switches 22 to 24 of the driver's seat door 10 and the opening / closing switches 33, 43, 53 of the other-seat doors, and management can be facilitated by reducing the types of switches and resistors. .

  In the second embodiment, the resistance values of the resistors R11 and R14, and the resistors R12 and R23 may be the same. Similarly, the resistance values of the resistors R21 and R14 and the resistors R22 and R23 may be the same value.

  In the second embodiment, the connection of the common contacts 22c and 33c may be changed as appropriate. For example, in the open / close switch 22, the common contact 22c is first connected only to the up contact 22u by operation, and is further connected to only the auto up contact 22ua by further operation. In this way, the voltage obtained by dividing the battery voltage VB by the resistor R14 of the open / close switch 22 and the resistor R30 of the ECU 35 becomes the terminal voltage Vi, and the auto-up operation can be performed by this terminal voltage Vi. Similarly, by configuring the common contact 22c to be connected only to the auto-down contact 22da, the voltage obtained by dividing the battery voltage VB by the resistor R14 and the resistor R30 is set as the terminal voltage Vi, and the auto-down operation is performed by the terminal voltage Vi. Can be made. The same applies to the passenger seat door 30, the rear seat right door 40, and the rear seat left door 50, which are other seat doors.

  DESCRIPTION OF SYMBOLS 2 ... Battery, 3 ... IG relay, 10 ... Driver's seat door, 30 ... Passenger seat door, 40 ... Rear seat right door, 50 ... Rear seat left door, 11, 31, 41, 51 ... Power window motor, 35 ... ECU 35a ... input terminals 12, 32, 42, 52 ... window glass, 22-24 ... open / close switch, 25 ... window lock switch, 33, 43, 53 ... open / close switch, R11-R14, R21-R24, R30 ... resistor , Vi: terminal voltage.

Claims (10)

A first opening / closing switch provided on a driver's seat door of the vehicle;
A second opening / closing switch provided in a different door from the driver's seat door and connected in series to the first opening / closing switch;
Provided in the other seat door, the second open / close switch is connected to an input terminal, and provided in the other seat door based on a terminal voltage of the input terminal according to the first open / close switch and the second open / close switch. A control unit for opening and closing the opened and closed member,
An opening / closing member control apparatus comprising:   The first open / close switch and the second open / close switch are configured such that the terminal voltage when the open / close member is opened is different from the terminal voltage when the open / close member is closed. The opening / closing member control apparatus according to 1.   The opening / closing member control apparatus according to claim 1, wherein the first opening / closing switch is connected to a battery of the vehicle via a power supply switch.   4. The opening / closing member control device according to claim 3, wherein the first opening / closing switch is connected to the power supply switch via an opening / closing prohibiting switch for prohibiting opening / closing of the opening / closing member of the other-seat door. Each of the first open / close switch and the second open / close switch includes a resistor,
The control unit includes a resistor connected to the input terminal,
A voltage obtained by dividing the battery voltage of the battery by the resistance of the first open / close switch or the second open / close switch and the resistance of the control unit is used as the terminal voltage.
The opening / closing member control apparatus according to claim 3 or 4.   The opening / closing member control apparatus according to claim 5, wherein the resistance of the first opening / closing switch and the resistance of the second opening / closing switch have different resistance values.   The opening / closing member control apparatus according to claim 5, wherein the resistance of the first opening / closing switch and the resistance of the second opening / closing switch have the same resistance value. The resistances of the first opening / closing switch and the second opening / closing switch include a first resistance for closing the opening / closing member and a second resistance for opening the opening / closing member, The resistance value is different from the resistance value of the second resistor,
The controller closes the opening / closing member while detecting the terminal voltage by the first resistor, and opens the opening / closing member while detecting the terminal voltage by the second resistor. ,
The opening / closing member control apparatus of any one of Claims 5-7. The resistance of the first opening / closing switch and the second opening / closing switch includes a third resistance,
When the control unit detects the terminal voltage generated by the third resistor, the control unit operates the open / close member to a fully open position or a fully closed position.
The opening / closing member control apparatus according to claim 8. The other seat doors are a passenger seat door, a rear seat right door and a rear seat left door of the vehicle,
The second opening / closing switch is provided in the driver's seat door corresponding to each of the passenger seat door, the rear seat right door, and the rear seat left door,
The opening-closing member control apparatus of any one of Claims 1-9.