JP2006111132A - Power window device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power window device hardly generating erroneous operation of a window glass at submersion. <P>SOLUTION: A switch circuit 7a is provided with a first transistor 13 and a second transistor 14. When output terminals 16, 18 are flooded at submersion, GND leak is generated on the output terminals 16, 18 and leak resistances RLUP, RLDN are generated on each of the output terminals 16, 18. In this state, when both switches 11, 12 are in the OFF state, both first and second transistors 13, 14 becomes in the ON state by the GND leak. Accordingly, the output terminal 16 (output terminal 18) becomes in the pull up state through respective pull up resistances 20, 27 (pull up resistances 15, 26). Accordingly, CPU 24 inputs an H level signal at an UP input terminal 24a by an UP terminal voltage VUP and maintains the state that the H level signal is inputted at a DN input terminal 24b by a DN terminal voltage VDN. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a power window device that automatically raises and lowers a window glass by a switch operation.

2. Description of the Related Art Conventionally, for the purpose of improving the convenience of a vehicle, a power window device that drives a DC motor or the like by a switch operation and automatically raises or lowers a window glass is mounted on the vehicle. In the power window device, when the operation switch is raised or lowered, the motor electronic control unit (that is, the motor ECU) raises or lowers the window glass by rotating the motor forward or backward via the drive circuit. . Moreover, the board | substrate which mounted motor ECU etc. has taken the waterproof structure shown, for example in patent document 1 so that it may not be flooded at the time of vehicle submersion.
JP 2002-13964 (page 3-6, Fig. 1)

  However, although Patent Document 1 has a structure in which various switch circuits and a motor ECU (including a drive circuit) are integrated parts, for example, a structure in which the switch circuit and the motor ECU are separated can be considered. In this case, it is necessary to connect the switch circuit and the motor ECU by wiring. In this case, if the vehicle, that is, the power window device is submerged for some reason such as an accident, the connection portion between the switch circuit and the wiring or the connection portion between the motor ECU and the wiring may be submerged. In such a situation, the connection portion is leaked to GND, and the motor ECU erroneously recognizes the output signal of the switch circuit.

  Here, a power window device in which the motor ECU drives and controls the motor by low active control will be specifically described. In this device, when an H level output signal is input from both the up switch and the down switch, for example, when an L level output signal is input from the up switch by operating the up switch, the motor ECU Perform ascent control. In this apparatus, if a GND leak occurs in the wiring portion between the switch circuit and the motor ECU due to submergence, the window glass may malfunction.

  The objective of this invention is providing the power window apparatus which can make it difficult to produce the malfunction of a window glass at the time of submergence.

  In order to solve the above problems, in the invention according to claim 1, when the rising switch for raising the window glass or the lowering switch for lowering the window glass is operated, a combination of signal level states corresponding to the operation is performed. And a switch unit for outputting output signals from a plurality of signal output terminals, and a separate unit for the switch unit, and driving the actuator by inputting the plurality of output signals by an internal control circuit. In the power window device comprising a control unit for raising and lowering the window glass, when the switch unit leaks on the wiring path connecting the switch unit and the control unit due to water immersion, each signal of the control circuit The signal is input so that each input terminal inputs a signal at the same level as before the leak occurred. And summarized in that with a signal level holding means for holding a level state of the input terminal.

  According to the present invention, when the switch unit and the control unit have separate structures, it is necessary to connect the two with wiring. However, when the power window device, that is, the switch unit is submerged, the connection portion of the wiring is submerged in water. It is also possible to fall into a soaking condition. At this time, a leak (GND leak or power supply leak) occurs on the wiring path connecting the switch unit and the control unit, and it cannot be denied that the control circuit inputs an incorrect output signal from the switch unit. May work.

  However, even if a leak occurs on the wiring path that connects the switch unit and the control unit due to flooding, the signal level holding means so that each signal input terminal of the control circuit inputs a signal in the same level state as before the leak occurred. Holds the level state of the signal input terminal. Therefore, even if a leak occurs during flooding, each signal input terminal of the control circuit is in a state of inputting a signal at the same level as before the leak occurrence, regardless of whether the switch is operated or not. Therefore, even if a leak occurs due to flooding, the control circuit does not need to input an erroneous signal, and it is possible to make it difficult for the window glass to malfunction during flooding (during flooding).

  According to a second aspect of the present invention, in the first aspect of the present invention, the control unit drives and controls the actuator by low active control based on the output signal, and the signal level holding means has a control terminal connected to the control terminal. A first switching element connected to the lower switch and the signal output terminal on the lower side, an input terminal connected to a power source, an output terminal connected to the up switch and the signal output terminal on the upper side, and a control terminal A second switching element connected to the up switch and the signal output terminal on the up side, an input terminal connected to a power source, and an output terminal connected to the down switch and the down signal output terminal; The gist is that pull-up resistors are connected in series to the output terminals of the first switching element and the second switching element, respectively.

  According to the present invention, in addition to the operation of the invention described in claim 1, since the switch unit includes the pull-up resistor, the signal output terminal (each signal output terminal on the rising side and the lowering side) has an H level. When outputting the output signal, it becomes possible to output a stable H level signal.

  According to a third aspect of the present invention, in the first aspect of the present invention, the control unit drives and controls the actuator by high active control based on the output signal, and the signal level holding means has a control terminal connected to the control terminal. A first switching element connected to the descending switch and the signal output terminal on the descending side, an input terminal connected to the ascending switch and the signal output terminal on the ascending side, and an output terminal grounded, and a control terminal to the up switch And a second switching element connected to the lowering signal output terminal, an input terminal connected to the lowering switch and the lowering signal output terminal, and an output terminal grounded, the first switching element and The gist is that pull-down resistors are connected in series to the input terminals of the second switching element.

  According to the present invention, in addition to the operation of the invention described in claim 1, since the switch unit includes the pull-down resistor, the L level output from the signal output terminal (the signal output terminals on the rising side and the falling side). When outputting a signal, a stable L level signal can be output.

  According to a fourth aspect of the present invention, in the invention according to the second or third aspect, when the switch unit includes the pull-up resistor, the pull-up resistor has a resistance value lower than that of the control unit. When the switch unit includes the pull-down resistor, the pull-down resistor is set to have a resistance value lower than the pull-down resistor of the control unit.

  According to this invention, in addition to the operation of the invention according to claim 2 or 3, for example, when the control unit drives the actuator by low active control, when the power window device is submerged and a GND leak occurs, both switches are In the non-operation state, the signal input terminal of the control circuit is held in the H level state by the signal level holding means. At this time, the voltage value of the H level signal is determined by the resistance values of the pull-up resistors and leak resistors of the switch unit and the control unit. The voltage value of the H level signal has a relationship that the voltage value increases as the resistance value of the pull-up resistor of the switch unit decreases due to the connection relationship of these resistors, that is, the relationship of the calculation formula of the combined resistance. is there. Therefore, if the resistance value of the pull-up resistor is set as described above, the signal level input by the control circuit at the input terminal is easily held at the H level, and the signal level falls to the L level. It is hard to become.

  On the other hand, for example, when the control unit drives and controls the actuator with high active control, when the power window device is submerged and a power leak occurs, when the switches are in the non-operating state, the signal level holding means controls the L of the control circuit. Retained in level state. At this time, the voltage value of the L level signal is determined by the resistance value of each pull-down resistor and leakage resistor of the switch unit and the control unit. The voltage value of the L level signal has a relationship that the voltage value decreases as the resistance value of the pull-down resistor of the switch unit decreases due to the connection relationship of these resistors, that is, the relationship of the calculation formula of the combined resistance. . Accordingly, if the resistance value of the pull-down resistor is set as described above, the signal level input by the control circuit at the input terminal is easily held at the L level, and the signal level rises to the H level. It ’s hard to be.

  According to a fifth aspect of the present invention, in the invention according to any one of the second to fourth aspects, the pull-up resistor or the pull-down resistor of the switch unit has a resistance value with respect to a leak resistance generated during water immersion. Is set to a value equal to or lower than that.

  According to the present invention, in addition to the operation of the invention according to any one of claims 2 to 4, the pull-up resistor of the control unit is, for example, several KΩ in order to reduce the current flowing from the power source to the control circuit. Whereas the value having the value is used, the leakage resistance generated when the power window device is submerged occurs at a value of several hundred Ω, for example. Therefore, if the pull-up resistance or pull-down resistance of the switch unit is set to a value equal to or lower than the leakage resistance, the resistance value takes a considerably low value.

  By the way, for example, when the control unit drives and controls the actuator by low active control, the voltage value of the H level signal input at the input terminal of the control circuit is a voltage value as the resistance value of the pull-up resistor of the switch unit decreases. There is a relationship that increases. Therefore, if the resistance value of the pull-up resistor is set as described above, the signal level input by the control circuit at the signal input terminal is more easily maintained at the H level when the GND leak occurs, and the signal input It becomes possible to hold the H level state at the terminal more reliably.

  On the other hand, when the control unit drives and controls the actuator with high active control, the voltage value of the L level signal input at the input terminal of the control circuit decreases as the resistance value of the pull-down resistor of the switch unit decreases. There is a relationship. Therefore, if the resistance value of the pull-down resistor is set as described above, the signal level input by the control circuit at the signal input terminal when the power supply leak occurs is more easily held in the L level state. It is possible to hold the L level state at the above with more certainty.

  According to the present invention, it is possible to make it difficult for the window glass to malfunction when submerged.

(First embodiment)
A power window device according to a first embodiment of the present invention will be described below with reference to FIGS.

  FIG. 1 is a circuit diagram showing an electrical configuration of the power window device 1. The power window device 1 is a device that automatically raises and lowers a window glass 2 of a side door of a vehicle (automobile), for example, using a drive motor 3 as a drive source by a switch operation. The power window device 1 includes a switch unit 4 that is operated by an operator (driver or passenger) when the window glass is raised and lowered, and a drive motor 3 that drives the window glass 2 based on a signal from the switch unit 4. And a control unit 5 that moves up and down. The switch unit 4 and the control unit 5 have a separate structure and are connected by wiring 6. The drive motor 3 corresponds to an actuator.

  FIG. 2 is a schematic perspective view showing a schematic configuration of the switch unit 4. The switch unit 4 outputs an output signal corresponding to the switch operation. A case 8 that houses various elements (IC, resistors, capacitors, etc.) 7 for operating the unit 4 and various elements 7 of the unit 4 are mounted. The substrate 9 is provided. The case 8 has a shape with an upper opening, and the opening 8 a is covered with a substrate 9 with a rubber contact 10 interposed therebetween. The substrate 9 has a flat plate shape and is detachably locked to the case 8.

  Space holes 8 c and 10 a are formed in the upper wall 8 b and the rubber contact 10 on the opening 8 a side of the case 8 so that various elements 7 located on the back surface of the substrate 9 do not interfere with the case 8 and the rubber contact 10. ing. The rubber contact 10 is made of, for example, a rubber material and has a flat plate shape having the same area as the substrate 9. The rubber contact 10 is in close contact with both the upper wall 8 b of the case 8 and the substrate 9, and has a waterproof function so that water does not enter the case 8 from between the case 8 and the substrate 9. .

  As shown in FIG. 1, the switch unit 4 includes a switch circuit 7 a as an element 7 mounted on the substrate 9. The switch circuit 7a includes an ascending switch 11 that is turned on during an ascending operation and a descending switch 12 that is turned on during a descending operation. For example, a manual operation automatic return contact is used for the ascending switch 11 and the descending switch 12, and either one of them is turned on at the time of the switch operation, that is, both are not turned on at the same time.

  The switch circuit 7a includes a first transistor 13 and a second transistor 14 as a countermeasure when the power window device 1, that is, the switch unit 4 is submerged. For example, FETs are used as the first transistor 13 and the second transistor. The first transistor 13 has an emitter terminal (input terminal) connected to the power source + B and a collector terminal (output terminal) via the pull-up resistor 15 to the output terminal of the switch unit 4 (hereinafter referred to as the UP output terminal). 16 and the raising switch 11 are connected. The base terminal (control terminal) of the first transistor 13 is connected to a descending output terminal (hereinafter referred to as a DN output terminal) 18 and a descending switch 12 of the switch unit 4 via a resistor 17. A resistor 19 is connected between the emitter and base of the first transistor 13.

  The second transistor 14 has an emitter terminal connected to the power supply + B, a collector terminal connected to the DN output terminal 18 of the switch unit 4 via the pull-up resistor 20 and the down switch 12, and a base terminal connected via the resistor 21. The switch unit 4 is connected to the UP output terminal 16 and the raising switch 11. A resistor 22 is connected between the emitter and base of the second transistor 14. The UP output terminal 16 and the DN output terminal 18 correspond to signal output terminals.

  The pull-up resistors 15 and 20 are elements for outputting a stable H level signal from the UP output terminal 16 or the DN output terminal 18 when the first transistor 13 or the second transistor 14 is turned on. The resistors 17 and 21 are elements that adjust the value of the base current that flows into the first transistor 13 or the second transistor 14 respectively. The first transistor 13 corresponds to a first switching element (signal level holding means), and the second transistor 14 corresponds to a second switching element (signal level holding means).

  The control unit 5 includes a motor ECU 23 that drives and controls the drive motor 3 based on a switch operation in the switch unit 4 in order to raise and lower the window glass 2. The motor ECU 23 includes a CPU 24 that performs overall control of the motor ECU 23, a drive circuit 25 that drives the drive motor 3 based on a command from the CPU 24, and two pull-up resistors 26 and 27 that supply a stable H level signal to the CPU 24. I have. The control unit 5 is unitized (one part) by incorporating the motor ECU 23 into the drive motor 3. The CPU 24 corresponds to a control circuit.

  The pull-up resistor 26 has an input side connected to the power source + B and an output side connected to a rising side input terminal (hereinafter referred to as an UP input terminal) 24 a of the CPU 24 via a resistor 28. On the other hand, the pull-up resistor 27 has an input side connected to the power supply + B and an output side connected to a descending input terminal (hereinafter referred to as DN input terminal) 24b of the CPU 24 via a resistor 29. The CPU 24 has its UP input terminal 24 a connected to the UP output terminal 16 of the switch unit 4 via the resistor 28 and the wiring 6 (rising side signal input wiring 6 a). Further, the CPU 24 has a DN input terminal 24 b connected to the DN output terminal 18 of the switch unit 4 via the resistor 29 and the wiring 6 (downward signal input wiring 6 b).

  Here, the CPU 24 determines the operation state of the up switch 11 and the down switch 12 based on the combination of the level states of the signal levels input at the UP input terminal 24a and the DN input terminal 24b, and drives the window glass 2 to move up and down. The motor 3 is driven and controlled. In this example, the CPU 24 controls the drive motor 3 by low active control, and when the H level state is recognized by both the UP input terminal 24a and the DN input terminal 24b, both the up switch 11 and the down switch 12 are operated. It is judged that it is not, and the drive motor 3 is stopped and the window glass 2 is brought into a non-lifting state.

  Further, when the CPU 24 recognizes the L level state at the UP input terminal 24a and recognizes the H level state at the DN input terminal 24b, the CPU 24 determines that the raising switch 11 has been operated, and rotates the drive motor 3 forward, for example. Raise 2 Similarly, when the CPU 24 recognizes the H level state at the UP input terminal 24a and recognizes the L level at the DN input terminal 24b, the CPU 24 determines that the lowering switch 12 has been operated, and reverses the drive motor 3 to reverse the window glass 2, for example. Lower.

Next, the operation of the power window device 1 when not submerged will be described.
When both the ascending switch 11 and the descending switch 12 are in the off state, both the UP output terminal 16 and the DN output terminal 18 are pulled up by the power source + B from the motor ECU 23 via the pull-up resistors 26 and 27. It becomes. Therefore, the CPU 24 determines that both the UP input terminal 24a and the DN input terminal 24b are input with the H level signal, determines that both the ascending switch 11 and the descending switch 12 are not operated, and stops the drive motor 3. The window glass 2 is brought into a non-lifting state.

  On the other hand, when the switch operation is performed, if the up switch 11 is first turned on, the UP output terminal 16 becomes the GND level, and thereby the second transistor 14 is turned on. Therefore, the DN output terminal 18 is pulled up with the voltage value of the power source + B via the pull-up resistor 20 of the switch circuit 7a and the pull-up resistor 27 of the motor ECU 23. Therefore, the CPU 24 is in a state where an L level signal is input at the UP input terminal 24a and an H level signal is input at the DN input terminal 24b, and the drive motor 3 is rotated forward by determining that the ascent switch 11 has been operated. Glass 2 is raised.

  If the lowering switch 12 is turned on, the DN output terminal 18 goes to the GND level, and the first transistor 13 is turned on. Therefore, the UP output terminal 16 is pulled up at the voltage value of the power source + B via the pull-up resistor 15 of the switch circuit 7a and the pull-up resistor 26 of the motor ECU 23. Therefore, the CPU 24 enters the state in which the H level signal is input from the UP input terminal 24a and the L level signal is input from the DN input terminal 24b. The CPU 24 determines that the lowering switch 12 is operated, reverses the drive motor 3, and reverses the window glass. 2 is lowered.

Next, the operation of the power window device 1 when submerged will be described.
When the switch circuit 7a (switch unit 7) has a waterproof structure by the rubber contact 10 and the motor ECU 23 has the waterproof structure of Patent Document 1, for example, even if such a waterproof measure is taken, the UP output terminal 16 and the DN when submerged. The output terminal 18 may be submerged. At this time, a leak (GND leak) occurs between the UP output terminal 16 and the GND and between the DN output terminal 18 and the GND, and the leak resistances RLUP and RLDN are respectively present in the UP output terminal 16 and the DN output terminal 18. It occurs.

  In this state, when both the ascending switch 11 and the descending switch 12 are in the OFF state, the emitters of the first transistor 13 and the second transistor 14 are generated due to leakage between the UP output terminal 16 (DN output terminal 18) and GND. A voltage is induced between the base and each of the first transistor 13 and the second transistor 14 is turned on. Therefore, the UP output terminal 16 is pulled up by the terminal voltage (hereinafter referred to as UP terminal voltage) VUP of the UP output terminal 16 via the pull-up resistors 15 and 26. The DN output terminal 18 is pulled up by the terminal voltage (hereinafter referred to as DN terminal voltage) VDN of the DN output terminal 18 via the pull-up resistors 20 and 27.

  The CPU 24 is in a state where an H level signal is input at the UP input terminal 24a by the UP terminal voltage VUP and an H level signal is input at the DN input terminal 24b by the DN terminal voltage VDN. Therefore, the CPU 24 determines that both the ascending switch 11 and the descending switch 12 are not operated, and stops the drive motor 3 to bring the window glass 2 into a non-lifting state. Therefore, even if the power window device 1 is submerged and a GND leak occurs in the output terminals 16 and 18, the CPU 24 maintains the H level state at both the UP input terminal 24a and the DN input terminal 24b, and does not input an erroneous signal. Therefore, it does not malfunction.

  Here, the voltage value of the power source + B is Vin, the resistance value of the pull-up resistor 15 is Ra, the resistance value of the pull-up resistor 26 is Rb, the resistance value of the pull-up resistor 20 is Rc, and the resistance value of the pull-up resistor 27 is Rd. Then, the UP terminal voltage VUP and the DN terminal voltage VDN are calculated by the following equations (1) and (2). Note that “//” in the following equation means a parallel combined resistance.

VUP = Vin × RLUP / {(Ra // Rb) + RLUP} (1)
VDN = Vin × RDN / {(Rc // Rd) + RLDN} (2)
Incidentally, although the UP terminal voltage VUP and the DN terminal voltage VDN have values lower than Vin, these values need to take operation guarantee voltages of the CPU 24, that is, voltage values that the CPU 24 can recognize as H level. Therefore, it is preferable that the UP terminal voltage VUP (DN terminal voltage VDN) be as large as possible.

  Here, considering the UP terminal voltage VUP, in the case of taking the structure of this example, the pull-up resistor 26 is a conventional one, and what is added as a new element is the pull-up resistor 15. At the time of setting, the resistance value Ra of the pull-up resistor 15 is set to a suitable value. As seen from the equation (1), there is a relationship between the pull-up resistor 15 and the UP terminal voltage VUP that the UP terminal voltage VUP decreases as the resistance value Ra of the pull-up resistor 15 increases. Therefore, in order to ensure a high voltage UP terminal voltage VUP, it is necessary to make the resistance value Ra of the pull-up resistor 15 as small as possible. However, if the resistance value Ra is too low, a large amount of current flows into the CPU 24. Therefore, to avoid this, the resistance value Ra needs to be balanced.

  From the above, the resistance value Ra of the pull-up resistor 15 is set to a value sufficiently lower than the resistance value Rb of the pull-up resistor 26 of the motor ECU 23 and a value equal to or lower than the value of the leak resistance RLUP. ing. Here, for example, it is assumed that the operation guarantee voltage of the CPU 24 is 3V, the voltage value Vin of the power source + B is 12V, the resistance value Rb of the pull-up resistor 26 is 1.2 KΩ, and the leak resistance RLUP is 100Ω. In this case, if the resistance value Ra of the pull-up resistor 15 is set to 100Ω, the UP terminal voltage VUP is about 6.24 V and takes a voltage value sufficiently larger than the operation guarantee voltage of the CPU 24. The H state can be reliably recognized. The above also applies to the DN terminal voltage VDN.

  On the other hand, when the switch operation is performed in the submerged state, if the up switch 11 is first turned on, the UP output terminal 16 becomes the GND level, and the second transistor 14 is turned on regardless of the presence or absence of leakage. . Therefore, the DN output terminal 18 is pulled up with the voltage value of the power source + B via the pull-up resistors 20 and 27. Therefore, the CPU 24 is in a state where an L level signal is input at the UP input terminal 24a and an H level signal is input at the DN input terminal 24b, and the drive motor 3 is rotated forward by determining that the ascent switch 11 has been operated. Glass 2 is raised.

  If the lower switch 12 is turned on in the submerged state, the DN output terminal 18 becomes the GND level, and the first transistor 13 is turned on regardless of the presence or absence of leakage. Therefore, the UP output terminal 16 is pulled up with the voltage value of the power source + B via the pull-up resistors 15 and 26. Therefore, the CPU 24 enters a state in which an H level is input from the UP input terminal 24a and an L level signal is input from the DN input terminal 24b, and the drive motor 3 is reversed by determining that the lowering switch 12 has been operated, and the window glass 2 Is lowered.

According to the configuration of the first embodiment, the following effects can be obtained.
(1) Even if the power window device 1 is submerged and a GND leak occurs at the output terminals 16 and 18 of the switch unit 4, the input terminals 24a and 24b of the CPU 24 input signals of the same combination as before the flooding. In addition, the switch unit 4 is provided with first and second transistors 13 and 14. Therefore, even if a GND leak occurs in the output terminals 16 and 18 due to submergence, an erroneous signal input to the CPU 24 due to the occurrence of the GND leak does not occur, and malfunction of the window glass 2 can be made difficult to occur.

  (2) The resistance value Ra of the pull-up resistor 15 is set to a value sufficiently lower than the resistance value Rb of the pull-up resistor 26 of the motor ECU 23 and a value equal to or lower than the value of the leak resistance RLUP. Therefore, when the GND leak occurs, the UP terminal voltage VUP (DN terminal voltage VDN) takes a sufficiently high value, and the input terminals 24a and 24b of the CPU 24 have a sufficient voltage value that can be recognized as the H level state. can do.

  (3) Since the waterproof measure for the switch unit 4 of this example is implemented using the first and second transistors 13 and 14, the structure is simple. Also, since this type of transistor is easily available, it is easy to implement.

  (4) Since the switch unit 4 is waterproofed by the rubber contact 10, the inside of the case 8 is difficult to be submerged, and a high waterproof effect can be secured. At the same time, if an erroneous signal output prevention structure using the first and second transistors 13 and 14 is employed, a higher prevention effect can be obtained.

(Second Embodiment)
Next, a second embodiment will be described with reference to FIG. This example is different from the first embodiment only in the connection structure of each element. Accordingly, the same parts as those in the first embodiment are denoted by the same reference numerals, detailed description thereof is omitted, and only different parts will be described.

  FIG. 3 is a circuit diagram showing an electrical configuration of the power window device 1. The rising switch 11 has an input side connected to the power source + B and an output side connected to the control terminal of the first transistor 13 via the resistor 17. The first transistor 13 has an emitter terminal connected to GND and a collector terminal connected to the rising switch 11 and the UP output terminal 16 via a pull-down resistor 31. The base terminal of the first transistor 13 is connected to the lowering switch 12 and the DN output terminal 18 via a resistor 17.

  The descending switch 12 has an input side connected to the power source + B and an output side connected to the second transistor 14 via the resistor 21. The second transistor 14 has an emitter terminal connected to GND and a collector terminal connected to the lower switch 12 and the DN output terminal 18 via a pull-down resistor 32. The base terminal of the second transistor 14 is connected to the rising switch 11 and the UP output terminal 16 via the resistor 21.

  The control unit 5 includes two pull-down resistors 33 and 34. The pull-down resistor 33 has an input side connected to the UP input terminal 24a via the resistor 28, and an output side connected to GND. On the other hand, the pull-down resistor 34 has an input side connected to the DN input terminal 24b via the resistor 29, and an output side connected to GND.

  Here, the CPU 24 controls the drive motor 3 by determining the operation state of the up switch 11 and the down switch 12 based on the level state of the signal level input at the UP input terminal 24a and the DN input terminal 24b. . In this example, the CPU 24 controls the drive motor 3 with high active, and when the L level state is recognized by both the UP input terminal 24a and the DN input terminal 24b, both the up switch 11 and the down switch 12 are operated. It judges that it is not, and makes the drive motor 3 a stop state, and makes the window glass 2 a non-elevating state.

  Further, when the CPU 24 recognizes the H level state at the UP input terminal 24a and recognizes the L level state at the DN input terminal 24b, the CPU 24 determines that the ascent switch 11 has been operated, and rotates the drive motor 3 forward, for example. Move 2 up and down. Similarly, when the CPU 24 recognizes the L level state at the UP input terminal 24a and recognizes the H level at the DN input terminal 24b, the CPU 24 determines that the lowering switch 12 has been operated, and reverses the drive motor 3 to reverse the window glass 2, for example. Lower.

Next, the operation of the power window device 1 when not submerged will be described.
When both the ascending switch 11 and the descending switch 12 are in the OFF state, both the UP output terminal 16 and the DN output terminal 18 are pulled down to the GND level from the motor ECU 23 via the pull-down resistors 33 and 34. . Accordingly, the CPU is in a state in which an L level signal is input at both the UP input terminal 24a and the DN input terminal 24b, and determines that both the up switch 11 and the down switch 12 are not operated, and the drive motor 3 is stopped. The window glass 2 is brought into a non-lifting state.

  On the other hand, when the switch operation is performed, if the up switch 11 is first turned on, the UP output terminal 16 becomes H level and the DN output terminal 18 maintains the GND level. At this time, the second transistor 14 is turned on, but does not affect the circuit of the power window device 1. Accordingly, the CPU 24 enters the state in which the H level signal is input at the UP input terminal 24a and the L level signal is input at the DN input terminal 24b, and the drive motor 3 is rotated forward by determining that the ascent switch 11 has been operated. Glass 2 is raised.

  If the lower switch 12 is turned on, the DN output terminal 18 becomes H level, while the UP output terminal 16 maintains the GND level. At this time, the first transistor 13 is turned on, but the circuit of the power window device 1 is not affected. Accordingly, the CPU 24 enters the state in which the L level signal is input through the UP input terminal 24a and the L level signal is input through the DN input terminal 24b. The CPU 24 determines that the lowering switch 12 has been operated, reverses the drive motor 3, and reverses the window glass. 2 is lowered.

Next, the operation of the power window device 1 when submerged will be described.
Here, for example, it is assumed that the power window device 1 is submerged due to an accident or the like, and the UP output terminal 16 and the DN output terminal 18 are submerged. At this time, a leak (power supply leak) occurs between the UP output terminal 16 and the power source + B (12 V) and between the DN output terminal 18 and the power source + B (12 V), and the UP output terminal 16 and the DN output terminal 18 Leak resistances RLUP and RLDN may occur in each.

  In this state, when both the ascending switch 11 and the descending switch 12 are in the off state, the first transistor 13 and the second transistor 14 are caused to leak due to leakage between the power supply + B-UP output terminal 16 (DN output terminal 18). Both are turned on. Therefore, the UP output terminal 16 is pulled down to the GND level (actually, the UP terminal voltage VUP) via the pull-down resistors 31 and 33. The DN output terminal 18 is also pulled down to the GND level (DN terminal voltage VDN) via the pull-down resistors 32 and 34.

  Therefore, the CPU 24 is in a state where an L level signal is input at the UP input terminal 24a and an L level signal is input at the DN input terminal 24b. Therefore, the CPU 24 determines that both the ascending switch 11 and the descending switch 12 are not operated, and the drive motor 3 is stopped and the window glass 2 is brought into the non-lifting state. For this reason, even if the power window device 1 is submerged and a power leakage occurs in the output terminals 16 and 18, the CPU 24 maintains the L level state at both the UP input terminal 24a and the DN input terminal 24b, and inputs an incorrect signal. Because it does not, it does not need to malfunction.

  Here, the UP terminal voltage VUP and the DN terminal voltage VDN in this example are calculated by the following equations (3) and (4). In this case, the resistance value of the pull-down resistor 31 is Re, the resistance value of the pull-down resistor 33 is Rf, the resistance value of the pull-down resistor 32 is Rg, and the resistance value of the pull-down resistor 34 is Rh.

VUP = Vin × (Re // Rf) / {(Re // Rf) + RLUP} (3)
VDN = Vin × (Rg // Rh) / {(Rg // Rh) + RLDN} (4)
By the way, although it is in the L level state, the UP terminal voltage VUP and the DN terminal voltage VDN are not completely “0” volts (that is, in the GND level state) but are in a state where some voltage is generated. However, when the switches 11 and 12 are not operated, the UP terminal voltage VUP and the DN terminal voltage VDN need to take voltage values that the CPU 24 can recognize as the L level. Good.

  Here, considering the UP terminal voltage VUP, the element to be newly added in this example is the pull-down resistor 31. Therefore, when setting the UP terminal voltage VUP, the resistance value Re of the pull-down resistor 31 is set to a suitable value. To do. Here, looking at the equation (3), the resistance value Rf of the pull-down resistor 33 is significantly larger than the leakage resistance RLUP, and therefore, the pull-down resistor 31 has a value between the pull-down resistor 31 and the UP terminal voltage VUP. As the resistance value Re increases, the UP terminal voltage VUP increases. Therefore, in order to secure the UP terminal voltage VUP having a low voltage value, it is necessary to make the resistance value Re of the pull-down resistor 31 as small as possible. However, if the resistance value Re is too low, a large amount of current flows into the CPU 24. Therefore, in order to avoid this, the resistance value Ra needs to be balanced.

  From the above, the resistance value Re of the pull-down resistor 31 is set to a value sufficiently lower than the resistance value Rf of the pull-down resistor 33 of the motor ECU 23 and a value equal to or lower than the value of the leak resistance RLUP. . Here, for example, it is assumed that the voltage value Vin of the power source + B is 12 V, the resistance value Rf of the pull-down resistor 33 is 1.2 KΩ, and the leak resistance RLUP is 100 Ω. In this case, if the resistance value Re of the pull-down resistor 31 is 10Ω, the UP terminal voltage VUP takes a very low voltage value of about 1.08 V, so that the CPU 24 can reliably recognize the L state when submerged. . The above also applies to the DN terminal voltage VDN.

  On the other hand, when the switch operation is performed in the submerged state, if the up switch 11 is first turned on, the UP output terminal 16 is in the H level state by the power supply + B, and the DN output terminal 18 is connected to the pull-down resistors 31 and 33. The state is pulled down to the GND level, and the L level state is obtained. Accordingly, the CPU 24 enters the state in which the H level signal is input from the UP input terminal 24a and the L level signal is input from the DN input terminal 24b, and the drive motor 3 is rotated forward by determining that the ascent switch 11 has been operated. Glass 2 is raised.

  Also, assuming that the descent switch 12 is turned on in the submerged state, the DN output terminal 18 is set to the H level state by the power source + B, and the UP output terminal 16 is pulled down to the GND level via the pull-down resistors 32 and 34. And becomes the L level state. Therefore, the CPU 24 enters the state in which the L level is input from the UP input terminal 24a and the H level signal is input from the DN input terminal 24b. The CPU 24 determines that the lowering switch 12 has been operated, reverses the drive motor 3, and the window glass 2 Is lowered.

According to the structure of 2nd Embodiment, in addition to the effect as described in (1)-(4) of 1st Embodiment, the effect as described below can be acquired.
(5) Even in the power window device 1 in which the control unit 5 drives and controls the drive motor 3 by the high active control, an erroneous signal input to the CPU 24 due to the occurrence of leakage does not occur, and malfunction of the window glass 2 is less likely to occur. be able to.

  (6) Since the switch unit 4 includes the pull-down resistors 31 and 32, a stable L level signal can be output to the control unit 5. This is also true for the first embodiment.

In addition, you may change the said embodiment not only to the said structure but to the following aspects.
-In 1st and 2nd embodiment, each switch of the raising switch 11 and the descending switch 12 is good also as a switch in which raising / lowering speed can be varied by providing various switches of high-speed rise, low-speed rise, high-speed fall, and low-speed fall. .

  In the first and second embodiments, this example describes the case where the GND leak occurs in the UP output terminal 16 and the DN output terminal 18 of the switch unit 4, but the GND leak occurs in the input terminal of the control unit 5. Also in the case, erroneous signal input of the CPU 24 can be prevented similarly.

  In the first and second embodiments, the resistance values of the pull-up resistors 15, 20, 26, 27, the pull-down resistors 31 to 34, and the resistors 17, 19, 21, 22, 28, and 29 may be appropriately changed. Good. Further, the switch circuit 7a and the motor ECU 23 are not limited to the same power source (that is, the power source + B), and may be different from each other.

  -In 1st and 2nd embodiment, the 1st transistor 13 and the 2nd transistor 14 are not limited to FET, For example, you may employ | adopt other switching elements, such as MOSFET.

In the first and second embodiments, the actuator is not limited to the drive motor 3 and may be a cylinder, for example.
-In 1st and 2nd embodiment, the power window apparatus 1 of this example may be employ | adopted not only for a motor vehicle but for vehicles other than a motor vehicle. The employer is not limited to a vehicle, and may be employed other than a vehicle such as a house.

Next, the technical idea that can be grasped from the above embodiment and other examples will be described below.
(1) In any one of claims 1 to 5, the control unit drives the actuator in a low active manner based on a plurality of the output signals.

(2) In any one of Claims 1-5, the said control unit drives the said actuator by high active based on the said some output signal.
(3) In any one of claims 1 to 5, the operation switch includes a rising switch operated when the window glass is raised and a lowering switch operated when the window glass is lowered, The signal level holding means includes a first switching element and a second switching element that are paired with the up switch and the down switch, respectively, and when the leak resistance occurs, the first switching element and the second switching element are The switch unit is turned on to maintain the signal input terminal in a level state before submersion, and the switch unit outputs the output signal based on the change of the switch contact when the up switch or the down switch is operated when a leak occurs. Output.

  (4) In any one of Claims 1-5, the said operation switch consists of a raising switch operated when the said window glass raises, and a lowering switch operated when the said window glass descends, The said signal level holding | maintenance The means comprises a first transistor paired with the up switch and a second transistor paired with the down switch, wherein the first transistor has an input terminal as a power source and an output terminal as the switch. A control terminal is connected to each of the rising side output terminal and the rising switch of the unit, a control terminal is connected to the lowering output terminal of the switch unit and the lowering switch, and the second transistor has an input terminal connected to a power source and an output terminal The control terminal is located in front of the switch unit at the lower output terminal of the switch unit and the lower switch. They are respectively connected to the rise side output terminal and the down switch.

The circuit diagram which shows the electric constitution of the power window apparatus in 1st Embodiment. The model perspective view which shows schematic structure of a switch unit. The circuit diagram which shows the electric constitution of the power window apparatus in 2nd Embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Power window apparatus, 2 ... Window glass, 3 ... Drive motor as actuator, 4 ... Switch unit, 5 ... Control unit, 6 ... Wiring, 11 ... Raising switch, 12 ... Decreasing switch, 13 ... Signal level holding means ( A first transistor constituting a first switching element), 14 a second transistor constituting a signal level holding means (second switching element), 15, 20, 26, 27 a pull-up resistor, 16 a signal output terminal UP output terminal, 18 ... DN output terminal constituting signal output terminal, 24 ... CPU as control circuit, 24a, 24b ... signal input terminal, 31-34 ... pull-down resistor, + B ... power source, RLUP, RLDN ... leakage resistor , Ra, Rc, Re, Rg: Resistance values.

Claims (5)

A switch unit that outputs an output signal from each of a plurality of signal output terminals in combination with a signal level state corresponding to the operation when the window glass ascent switch or the window glass descending switch is operated; In a power window device provided separately from the switch unit, including a control unit that raises and lowers the window glass by inputting a plurality of the output signals by an internal control circuit and driving an actuator,
When a leak occurs on the wiring path that connects the switch unit and the control unit due to water immersion, the signal input terminals of the control circuit each input a signal in the same level state as before the leak occurs. As described above, a power window device comprising signal level holding means for holding the level state of the signal input terminal. The control unit drives and controls the actuator by low active control based on the output signal,
The signal level holding means is
A first switching element having a control terminal connected to the lower switch and the signal output terminal on the lower side, an input terminal connected to a power source, and an output terminal connected to the up switch and the signal output terminal on the upper side;
A control terminal connected to the rising switch and the signal output terminal on the rising side, an input terminal connected to a power source, and an output terminal connected to the lowering switch and the signal output terminal on the lowering side. Prepared,
2. The power window device according to claim 1, wherein pull-up resistors are connected in series to the output terminals of the first switching element and the second switching element, respectively. The control unit drives and controls the actuator with high active control based on the output signal,
The signal level holding means is
A first switching element having a control terminal connected to the lowering switch and the lower signal output terminal, an input terminal connected to the ascending switch and the upper signal output terminal, and an output terminal grounded;
A control terminal connected to the up switch and the signal output terminal on the up side, an input terminal connected to the down switch and the signal output terminal on the down side, and a second switching element having an output terminal grounded,
2. The power window device according to claim 1, wherein pull-down resistors are connected in series to the input terminals of the first switching element and the second switching element, respectively.   When the switch unit includes the pull-up resistor, the pull-up resistor is set to have a resistance value lower than the pull-up resistor of the control unit, and when the switch unit includes the pull-down resistor, the pull-down resistor 4. The power window device according to claim 2, wherein a resistance value is set lower than a pull-down resistance of the unit.   The pull-up resistor or the pull-down resistor of the switch unit is set to have a resistance value equal to or lower than a leak resistance generated at the time of flooding. The power window apparatus as described in any one of Claims.

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