JP3793375B2 - Power window switch circuit - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a power window switch circuit.
[0002]
[Prior art]
In general, a power window device is used to automatically open and close a window glass such as a side door of a vehicle. Then, when the passenger turns on a manual up switch (up switch) or down switch (down switch) provided on the power window device, the window glass is driven up or down. Has been.
[0003]
FIG. 2 is an electric circuit diagram of the power window switch circuit 10 in the conventional power window device. The drive circuit 20 of the power window switch circuit 10 is provided for the control circuit 12, the down switch 28, the up switch 29, the auto switch 30, and the drive motor M. The down switch 28 and the up switch 29 are, for example, two-stage click type switches and are tumbler-type, and function as the down switch 28 when one side (hereinafter referred to as the down side) is pressed one step, that is, the down switch The movable contact 31 of the switch 28 is connected to the fixed contact DN. Further, when the other side (hereinafter referred to as the up side) is pressed by one step, it functions as the ascending switch 29, that is, the movable contact 32 of the ascending switch 29 is connected to the fixed contact UP.
[0004]
Further, when the down side is pressed by two steps, both the lowering switch 28 and the auto switch 30 are turned on. When the up side is pressed by two steps, both the lift switch 29 and the auto switch 30 are turned on. In the case of automatic operation, after pressing two steps, the pressing of the lowering switch 28 and the uppering switch 29 is released. Therefore, as shown in FIG. 2, the lowering switch 28 and the raising switch 29 are both in the off position. Note that when the down switch 28 and the up switch 29 are not operated, they are urged by a spring (not shown) and turned off. The drive motor M is a DC motor that drives a window glass of a vehicle (not shown) up or down.
[0005]
Next, the drive circuit 20 will be described.
When the auto switch 30 is turned on to the down side in accordance with the operation of the lowering switch 28, the control circuit 12 opens the window glass even if the pressing operation of the lowering switch 28 is released based on the on operation. Until reaching the position, a high (H) level relay drive signal is output to the base of the transistor TR3, and an ON signal (control signal) is output to the base of the transistor TR1. The transistor TR3 is turned on based on the relay drive signal, and the exciting current is supplied to the relay coil 21 of the first relay 22 by turning on the transistor TR1.
[0006]
As a result, excitation of the relay coil 21 causes the movable contact 25c of the relay contact 25 of the first relay 22 to be switched and connected from the ground-side fixed contact 25a to the power-side fixed contact 25b, so that a drive current is supplied to the drive motor M. The drive motor M is rotated forward. By this normal rotation, a wire type or arm type regulator (not shown) is driven by the drive motor M, and the window glass is lowered. When the window glass is located at the fully open position, a fully open position limit switch (not shown) is detected and operated. Based on the detection, the control circuit 12 stops applying the relay drive signal and drives the drive motor M. It is made to stop and hold | maintain a window glass in a fully open position.
[0007]
In addition, when the auto switch 30 is turned on to the up side in accordance with the operation of the raising switch 29, the control circuit 12 does not turn on the window glass even if the pushing operation of the raising switch 29 is released based on the on operation. Until the fully closed position is reached, a high (H) level relay drive signal is output to the base of the transistor TR2, and an ON signal (control signal) is output to the base of the transistor TR1. The transistor TR2 is turned on based on the relay drive signal, and the exciting current is supplied to the relay coil 23 of the second relay 24 by turning on the transistor TR1.
[0008]
As a result, excitation of the relay coil 23 causes the movable contact 26c of the relay contact 26 of the second relay 24 to be switched and connected from the ground-side fixed contact 26a to the power-side fixed contact 26b, so that a drive current is supplied to the drive motor M. The drive motor M is reversed. By this reverse rotation, a wire type or arm type regulator (not shown) is driven by the drive motor M, and the window glass is raised. When the window glass is located at the fully closed position, a fully closed position limit switch (not shown) is detected and actuated. Based on the detection, the control circuit 12 stops applying the relay drive signal and turns on the drive motor M. The driving is stopped and the window glass is held in the fully closed position.
[0009]
Further, when the window glass is to be lowered by manual operation, the lowering switch 28 is turned on by one step down. Based on this operation, the control circuit 12 outputs a high (H) level relay drive signal to the base of the transistor TR3 and outputs an ON signal (control signal) to the base of the transistor TR1. The transistor TR3 is turned on based on the relay drive signal. When the transistor TR1 is turned on, the exciting current flows through the relay coil 21 while the lowering switch 28 is turned on. ing. For this reason, while the lowering switch 28 is turned on, the drive motor M is rotated forward and the window glass is lowered.
[0010]
Further, when the window glass is to be raised by manual operation, the raising switch 29 is turned on by one step up. Based on this operation, the control circuit 12 outputs a high (H) level relay drive signal to the base of the transistor TR2, and outputs an ON signal (control signal) to the base of the transistor TR1. The transistor TR2 is turned on based on the relay drive signal, and the transistor TR1 is turned on, so that an exciting current flows through the relay coil 23 while the raising switch 29 is turned on. ing. For this reason, while the raising switch 29 is turned on, the drive motor M is reversed and the window glass is raised.
[0011]
[Problems to be solved by the invention]
In the power window switch circuit 10 as described above, when the first and second relays 22 and 24, the control circuit 12 and the like are wet with an electrolyte solution such as rainwater, as shown by a dotted line in FIG. R11 to R15 may occur.
[0012]
For example, even when the down switch 28 is in an off state, the relay driving signal of H level is not output from the control circuit 12 to the transistor TR3, and the on signal is not output from the control circuit 12 to the transistor TR1, the leakage resistance R11 , R13 occurs, the transistors TR1 and TR3 are turned on. Then, since the relay coil 21 is excited and the movable contact 25c is connected to the power supply side fixed contact 25b, there is a problem that the drive motor M is rotated forward and the window glass is inadvertently lowered.
[0013]
Further, even when the rising switch 29 is in the OFF state, the H level relay drive signal is not output from the control circuit 12 to the transistor TR2, and the ON signal is not output from the control circuit 12 to the transistor TR1, the leakage resistance R11 , R12 occurs, the transistors TR1 and TR2 are turned on. Then, since the relay coil 23 is excited and the movable contact 26c is connected to the power supply side fixed contact 26b, there is a problem that the drive motor M is reversed and the window glass is inadvertently raised.
[0014]
Further, even when the transistor TR3 is in an OFF state, when the leakage resistances R11 and R15 are generated, the relay coil 21 is excited and the movable contact 25c is connected to the power supply side fixed contact 25b. However, there is a problem that the window glass is inadvertently lowered. Furthermore, even if the transistor TR2 is in the OFF state, if the leakage resistances R11 and R14 occur, the relay coil 23 is excited and the movable contact 26c is connected to the power supply side fixed contact 26b, so that the drive motor M is reversed. There is a problem that the window glass rises carelessly.
[0015]
Further, when the leak resistors R11 to R13 are generated, the transistors TR1 to TR3 are turned on. Then, both the relay coils 21 and 23 are excited, and the relay contacts 25 and 26 are simultaneously turned on (the movable contacts 25c and 26c are connected to the power supply side fixed contacts 25b and 26b). The drive motor M is not driven because the same potential (both are HI potential). For this reason, even if the lowering switch 28 is turned on in this state, both terminals of the driving motor M do not change at the same potential, so that the driving motor M is not driven and the window glass does not lower. . On the other hand, there is a problem in that the window glass does not rise even if the raising switch 29 is turned on when both terminals of the drive motor M are at the same potential.
[0016]
The problem that the window glass rises or falls carelessly as described above and the problem that the window glass does not rise or fall differ depending on the location where the leak resistance occurs. That is, (a) only the relay coil 23 (up side) is excited, (b) only the relay coil 21 (down side) is excited, (c) both relay coils 21 and 23 are excited, (d) both relay coils 21 , 23 are not energized. Therefore, it is uncertain whether the window glass will rise or fall. As a result, there is a problem that the power window switch circuit 10 cannot be reliably controlled based on the operation of the lower switch 28 and the upper switch 29 by the passenger.
[0017]
A first object of the present invention is to provide a power window switch circuit that can reliably lower or raise the window glass based on the ON operation of the lower switch circuit or the upper switch circuit when the power window switch circuit is submerged. There is to do. A second object is to provide a power window switch circuit that can prevent the window glass from inadvertently descending or rising when the power window switch circuit is submerged.
[0018]
[Means for Solving the Problems]
In order to achieve the above object, the invention of claim 1 is directed to a lowering switch circuit, an ascending switch circuit, and a first relay coil for lowering the window glass and an object for raising the window glass based on the ON operation of each switch circuit. And a control circuit for controlling the excitation and demagnetization of each of the second relay coils, and a power window switch circuit configured to supply a HI potential to one terminal of each of the relay coils. A first contact connected to the terminal, a second contact connected to the other terminal of the second relay coil, and a normally open contact with respect to the first contact; A first movable contact for inputting a relay coil excitation input signal; and a second movable contact that is linked to the first movable contact and that is a normally closed contact with respect to the second contact. The rising switch circuit is a first contact connected to a power supply side terminal, a second contact connected to the other terminal of the first relay coil, and a normally open contact with respect to the first contact, A first movable contact that inputs a second relay coil excitation input signal to the control circuit during an ON operation, and a second movable contact that is linked to the first movable contact and that is a normally closed contact with respect to the second contact; A first switching means is connected between the first movable contact of the down switch circuit and the other terminal of the second relay coil, and between the first movable contact of the up switch circuit and the other terminal of the first relay coil. Is connected to the second switching means, and when the switch is turned on, the second movable contacts of the lowering switch circuit and the raising switch circuit are grounded, and the first switching means or the second switching means is turned on. 3 a switching means is provided, and the gist in that a flooding detection means for turning on operation of the third switching means upon detection of a flooding.
[0019]
Therefore, in the first aspect of the invention, when the power window switch circuit is submerged and the descending switch circuit and the ascending switch circuit are turned off, the inundation is detected by the inundation detecting means, and the third switching means is based on the detection. Operates on. Then, the other terminal of each relay coil is grounded via the second movable contact and the second contact of each switch circuit, and the HI potential is supplied to one terminal of each relay coil. For this reason, both relay coils are excited, and the window glass does not descend or rise.
[0020]
As described above, when the lowering switch circuit is turned on when the power window switch circuit is submerged, the first movable contact of the lowering switch circuit is connected to the first contact, and the first switching is performed via the power supply side terminal. The means is turned on, and the HI potential is supplied to the other terminal of the second relay coil. For this reason, the second relay coil is demagnetized, and the window glass is lowered by the excitation of only the first relay coil.
[0021]
Further, when the rising switch circuit is turned on while the power window switch circuit is submerged, the first movable contact of the rising switch circuit is connected to the first contact, and the second switching means is turned on via the power supply side terminal. In operation, the HI potential is supplied to the other terminal of the first relay coil. For this reason, the first relay coil is demagnetized, and the window glass is raised by the excitation of only the second relay coil.
[0022]
The invention of claim 2 is characterized in that, in the invention of claim 1, the third switching means grounds a circuit for supplying power to the control circuit at the time of ON operation.
[0023]
Therefore, in the invention of claim 2, in addition to the action of the invention of claim 1, when the power window switch circuit is submerged and the third switching unit is turned on based on the on-operation of the submergence detection unit, the control is performed. The circuit that supplies power to the circuit is grounded. Therefore, a malfunction of the circuit (excitation / demagnetization control of each relay coil) due to a signal capable of exciting / demagnetizing each relay coil, which may be output from the control circuit for some reason during flooding, is avoided.
[0024]
According to a third aspect of the present invention, in the first or second aspect of the present invention, the control circuit is configured to control the control signal based on the input first relay coil excitation input signal or the second relay coil excitation input signal. And a fourth switching means for supplying a HI potential to one terminal of each relay coil based on the control signal and the ON operation of the third switching means. .
[0025]
Therefore, in the invention of claim 3, in addition to the operation of the invention of claim 1 or claim 2, the control signal output from the control circuit based on the input of the first or second relay coil excitation input signal and Based on the ON operation of the third switching means, the fourth switching means supplies the HI potential to one terminal of each relay coil. Then, each relay coil is energized if the other terminal is at LO potential, and is demagnetized if the other terminal is at HI potential.
[0026]
DETAILED DESCRIPTION OF THE INVENTION
DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, an embodiment of the invention will be described with reference to the drawings. FIG. 1 is an electric circuit diagram of a power window switch circuit 10 in a power window device of an automobile. In addition, the same code | symbol is attached | subjected about the structure same as the said prior art example shown in FIG. The power window device of the present embodiment is provided on a side door on the driver's seat side of an automobile. The drive circuit 20 of the power window switch circuit 10 is provided for the control circuit 12, the down switch 128, the up switch 129, the auto switch 30 and the drive motor M. The drive circuit 20 will be described.
[0027]
Between the + terminal (shown by the symbol IG in FIG. 1) and the − terminal (shown by the ground symbol in FIG. 1) of the battery power source (hereinafter referred to as the power source), an emitter / collector of the transistor TR1, a diode D1, The relay coil 21 (for lowering the window glass) of the first relay 22 and the collector / emitter of the transistor TR3 are connected in series. Between the cathode terminal of the diode D1 and the ground line, the relay coil 23 (for raising the window glass) of the second relay 24 and the collector / emitter of the transistor TR2 are connected in series. A resistor R6 is connected between the positive terminal of the power supply and the base of the transistor TR1, and the base of the transistor TR1 is connected to the output terminal of the control circuit 12 via the resistor R7. The collectors of the transistors TR2 and TR3 are connected to the output terminal of the control circuit 12, respectively.
[0028]
The descending switch 128 as the descending switch circuit is a double pole single throw switch, and the first fixed contact DN1 is connected to the + terminal of the power source. When the down switch 128 is not operated, the second movable contact 133 is connected to the second fixed contact DN2, and the first movable contact 131 is not connected to the first fixed contact DN1. That is, the first movable contact 131 is configured as a normally open contact with respect to the first fixed contact DN1, and the second movable contact 133 is configured as a normally closed contact with respect to the second fixed contact DN2. The first movable contact 131 is connected to the input terminal of the control circuit 12 through the resistor R10, the second movable contact 133 is connected to the anode terminal of the diode D5, and the second fixed contact DN2 is the negative terminal (the other terminal) of the relay coil 23. Are connected to the terminal.
[0029]
The ascending switch 129 as the ascending switch circuit is a double pole single throw switch, and the first fixed contact UP1 is connected to the + terminal of the power source. When the ascent switch 129 is not operated, the second movable contact 134 is connected to the second fixed contact UP2, and the first movable contact 132 is not connected to the first fixed contact UP1. That is, the first movable contact 132 is configured as a normally open contact with respect to the first fixed contact UP1, and the second movable contact 134 is configured as a normally closed contact with respect to the second fixed contact UP2. The first movable contact 132 is connected to the input terminal of the control circuit 12 via the resistor R9, the second movable contact 134 is connected to the anode terminal of the diode D5, and the second fixed contact UP2 is the-terminal (the other side of the relay coil 21). Are connected to the terminal.
[0030]
The fixed contact of the auto switch 30 is connected to the + terminal of the power source, and the movable contact is connected to the input terminal of the control circuit 12 via the resistor R8.
A relay contact 25 of the first relay 22 is provided between the positive terminal of the power source and one terminal of the drive motor M. The movable contact 25c of the relay contact 25 is connected to one terminal of the drive motor M, the power supply side fixed contact 25b is connected to the positive terminal of the power supply, and the ground side fixed contact 25a is grounded. The relay contact 25 has a movable contact 25c connected to the ground-side fixed contact 25a when the relay coil 21 is demagnetized. The movable contact 25c is connected to the power supply side fixed contact 25b when the relay coil 21 is excited.
[0031]
On the other hand, a relay contact 26 of the second relay 24 is provided between the positive terminal of the power source and the other terminal of the drive motor M. The movable contact 26c of the relay contact 26 is connected to the other terminal of the drive motor M, the power supply side fixed contact 26b is connected to the positive terminal of the power supply, and the ground side fixed contact 26a is grounded. The relay contact 26 has a movable contact 26c connected to the ground-side fixed contact 26a when the relay coil 23 is demagnetized. The movable contact 26c is connected to the power supply side fixed contact 26b when the relay coil 23 is excited.
[0032]
The power window switch circuit 10 includes a leak detection circuit 15, transistors TR4 to TR6, diodes D2 to D8, and resistors R1 to R5 and R16. The diodes D1 to D8 including the diode D1 are diodes for preventing wraparound.
[0033]
The leak detection circuit 15 as an inundation detection circuit includes an electrode 16 connected to the positive terminal of the power source and an electrode 17 connected to the base of the transistor TR6 via a base resistor R5. They are arranged slightly apart from each other. When the leak between the electrodes 16 and 17 of the leak detection circuit 15 is leaked, a leak resistance is generated between the electrodes 16 and 17 and the leak detection circuit 15 is turned on. When there is no leak between the electrodes 16 and 17, the leak detection is performed. The circuit 15 is turned off. The leak detection circuit 15 is preferably provided at the same place as the place where the control circuit 12 or the like is provided or at a position close thereto.
[0034]
The resistor R4 is connected between the base of the transistor TR6 and the ground line, the emitter of the transistor TR6 is grounded, and the cathode terminals of the diodes D4 to D8 are connected to the collector of the transistor TR6. The anode terminal of the diode D4 is connected to the power supply line of the control circuit 12, and a resistor R16 is connected between the positive terminal of the power supply and the power supply line. The anode terminal of the diode D6 is connected to the base of the transistor TR1 through the resistor R1, the anode terminal of the diode D7 is connected to the base of the transistor TR4 through the resistor R2, and the anode terminal of the diode D8 is connected to the transistor through the resistor R3. It is connected to the base of TR5.
[0035]
The emitter of the transistor TR4 is connected to the first movable contact 131 of the descending switch 128, and the collector of the transistor TR4 is connected to the negative terminal of the relay coil 23 via the diode D2. The emitter of the transistor TR5 is connected to the first movable contact 132 of the rising switch 129, and the collector of the transistor TR5 is connected to the negative terminal of the relay coil 21 via the diode D3.
[0036]
In the present embodiment, the relay coil 21 constitutes a first relay coil, and the relay coil 23 constitutes a second relay coil. The transistor TR4 constitutes first switching means, the transistor TR5 constitutes second switching means, the transistor TR6 constitutes third switching means, and the transistor TR1 constitutes fourth switching means. The first fixed contacts DN1 and UP1 each constitute a first contact, and the second fixed contacts DN2 and UP2 each constitute a second contact. The + terminal of the power supply (shown by the symbol IG in FIG. 1) constitutes a power supply side terminal. Each + terminal of the relay coils 21 and 23 constitutes one terminal.
[0037]
Next, the operation of the power window switch circuit 10 configured as described above will be described.
Now, the operation when the power window switch circuit 10 is not wet with an electrolyte solution such as rainwater and both the lowering switch 128 and the raising switch 129 are in the off state (during off operation) will be described. During the off operation, the second movable contacts 133 and 134 of the lowering switch 128 and the raising switch 129 are connected to the second fixed contacts DN2 and UP2, and the first movable contacts 131 and 132 are connected to the first fixed contacts DN1 and UP1. Are not connected. Accordingly, the HI potential is not supplied to the respective negative terminals of the relay coils 21 and 23 from the positive terminal of the power source, and the HI potential is not supplied to each of the positive terminals, so that neither of the relay coils 21 and 23 is excited. Therefore, the drive motor M is not driven, and the window glass does not descend or rise.
[0038]
Next, when the lowering switch 128 is turned on (ON operation) in a state where the power window switch circuit 10 is not wet with the electrolyte liquid such as rainwater, the second movable contact 133 is separated from the second fixed contact DN2. After (off operation), the first movable contact 131 is switched and connected (on operation) to the first fixed contact DN1 with a slight delay. Then, based on the on operation of the lowering switch 128 (the first movable contact 131 inputs the first relay coil excitation input signal to the control circuit 12), the transistors TR1 and TR3 are turned on as in the conventional example. Thus, the relay coil 21 is excited (HI potential is supplied to the positive terminal of the relay coil 21 based on the ON operation of the transistor TR1). As a result, the drive motor M is rotated forward and the window glass is lowered.
[0039]
Next, when the raising switch 129 is turned on (ON operation) in a state where the power window switch circuit 10 is not wet with the electrolyte liquid such as rainwater, the second movable contact 134 is separated from the second fixed contact UP2. After (off operation), the first movable contact 132 is switched and connected (on operation) to the first fixed contact UP1 with a slight delay. Then, based on the ON operation of the ascent switch 129 (the first movable contact 132 inputs the second relay coil excitation input signal to the control circuit 12), the transistors TR1 and TR2 are ON as in the conventional example. Thus, the relay coil 23 is excited (the HI potential is supplied to the positive terminal of the relay coil 23 based on the ON operation of the transistor TR1). As a result, the drive motor M is reversed and the window glass rises.
[0040]
Next, the operation when the power window switch circuit 10 is wetted by an electrolyte solution such as rainwater and both the lowering switch 128 and the raising switch 129 are in the off state (during off operation) will be described. In this embodiment, since the leak detection circuit 15 is provided, when the power window switch circuit 10 gets wet with an electrolyte solution such as rainwater, that is, when it is submerged, the leak between the electrodes 16 and 17 of the leak detection circuit 15 leaks. The leak detection circuit 15 is turned on.
[0041]
Then, the transistor TR6 is turned on. Based on the on operation of the transistor TR6, the transistor TR1 is turned on, and the transistors TR4 and TR5 are turned on. Then, based on the ON operation of the transistor TR1, the potential of the + terminal of the relay coil 21 and the potential of the + terminal of the relay coil 23 become the HI potential via the diode D1, respectively. Further, based on the ON operation of the transistor TR6, the potential of the negative terminal of the relay coil 21 and the potential of the negative terminal of the relay coil 23 become the LO potential (corresponding to the ground) via the diode D5. Then, both the relay coils 21 and 23 are excited (excitation current is supplied), and the relay contacts 25 and 26 are simultaneously turned on (the movable contacts 25c and 26c are connected to the power supply side fixed contacts 25b and 26b). Both terminals of the drive motor M are at the same potential (both HI potential), and the drive motor M is not driven.
[0042]
The transistors TR4 and TR5 are turned on based on the ON operation of the transistor TR6. However, since the switches 128 and 129 are turned off, the HI potential is not supplied to the respective emitters. As a result, no current flows between each emitter and collector.
[0043]
Here, even if a leak resistance occurs in the power window switch circuit 10, the potentials of the + terminals of the relay coils 21 and 23 are set to the HI potential by the ON operation of the transistor TR1, and the potentials of the respective − terminals. Are set to the LO potential by the ON operation of the transistor TR6. Therefore, since both the relay coils 21 and 23 are excited, the drive motor M is not driven, and the window glass does not fall or rise carelessly.
[0044]
Further, since the power supply line of the control circuit 12 (circuit supplying power to the control circuit 12) is connected to the collector of the transistor TR6 via the diode D4, the power supply line is based on the ON operation of the transistor TR6. Thus, the potential becomes LO potential (corresponding to grounding). Therefore, when the power window switch circuit 10 is submerged, the control circuit 12 is not supplied with a predetermined power supply voltage necessary for the circuit operation, and the drive circuit 20 malfunctions due to the output signal from the control circuit 12 (the transistor TR1 for some reason). (Excitation of relay coils 21 and 23 due to ON operation of TR3) is prevented.
[0045]
Next, when the lowering switch 128 is turned on while the power window switch circuit 10 is wet with the electrolyte solution such as rainwater, the second movable contact 133 is separated from the second fixed contact DN2 (off operation). Thereafter, the first movable contact 131 interlocked with the second movable contact 133 is switched and connected to the first fixed contact DN1 (ON operation) with a slight delay. Then, since the transistor TR4 is connected between the first movable contact 131 and the negative terminal of the relay coil 23, the HI potential is supplied from the positive terminal of the power source to the emitter of the transistor TR4 via the fixed contact DN1.
[0046]
Then, a current flows between the emitter and collector of the transistor TR4, and the potential of the negative terminal of the relay coil 23 changes from the LO potential to the HI potential via the diode D2. Then, both terminals of the relay coil 23 become the same potential (both HI potential), and the relay coil 23 is demagnetized. As a result, only the relay coil 21 is excited, that is, the movable contact 26c of the relay contact 26 is switched and connected from the power supply side fixed contact 26b to the ground side fixed contact 26a. Is supplied, the drive motor M is rotated forward, and the window glass is lowered.
[0047]
Next, when the lift switch 129 is turned on while the power window switch circuit 10 is wet with an electrolyte solution such as rainwater, the second movable contact 134 is separated from the second fixed contact UP2 (off operation). Thereafter, the first movable contact 132 interlocked with the second movable contact 134 is switched and connected to the first fixed contact UP1 (ON operation) with a slight delay. Then, since the transistor TR5 is connected between the first movable contact 132 and the negative terminal of the relay coil 21, the HI potential is supplied from the positive terminal of the power source to the emitter of the transistor TR5 via the fixed contact UP1.
[0048]
Then, a current flows between the emitter and collector of the transistor TR5, and the potential of the negative terminal of the relay coil 21 changes from the LO potential to the HI potential via the diode D3. Then, both terminals of the relay coil 21 become the same potential (both HI potential), and the relay coil 21 is demagnetized. As a result, only the relay coil 23 is excited, that is, the movable contact 25c of the relay contact 25 is switched and connected from the power supply side fixed contact 25b to the ground side fixed contact 25a. Is supplied, the drive motor M is reversed, and the window glass is raised.
[0049]
Therefore, according to the present embodiment, the following effects can be obtained.
(1) In the present embodiment, when the power window switch circuit 10 is submerged, the window glass can be reliably lowered or raised based on the ON operation of the lowering switch 128 or the raising switch 129.
[0050]
(2) In the present embodiment, when the power window switch circuit 10 is submerged, it is possible to prevent the window glass from being inadvertently lowered or raised when the lowering switch 128 or the raising switch 129 is turned off.
[0051]
(3) In this embodiment, when the power window switch circuit 10 is submerged and the transistor TR6 is turned on based on the ON operation of the leak detection circuit 15, the power line of the control circuit 12 is grounded. Therefore, the malfunction of the drive circuit 20 due to a signal that can be output from the control circuit 12 for some reason when it is flooded, which can control the excitation and demagnetization of the relay coils 21 and 23 (excitation and demagnetization control of the relay coils 21 and 23, etc.) ) Can be avoided.
[0052]
(4) In this embodiment, when the power window switch circuit 10 is submerged and the lowering switch 128 is turned on, the transistor TR6 is turned on based on the on operation of the leak detection circuit 15, and the emitter of the transistor TR4. Current flows between the collectors. Then, no exciting current is supplied to the relay coil 23, only the relay coil 21 is excited, and the window glass is lowered. That is, even when the power window switch circuit 10 is submerged, the window glass can be reliably lowered based on the ON operation of the lowering switch 128.
[0053]
(5) In the present embodiment, when the power window switch circuit 10 is submerged and the rising switch 129 is turned on, the transistor TR6 is turned on based on the on action of the leak detection circuit 15, and the emitter of the transistor TR5, Current flows between the collectors. Then, no exciting current is supplied to the relay coil 21, only the relay coil 23 is excited, and the window glass rises. That is, even when the power window switch circuit 10 is submerged, the window glass can be reliably raised based on the ON operation of the raising switch 129.
[0054]
(6) In this embodiment, when the down switch 128 or the up switch 129 is operated, first, the second movable contact (reference numeral 133 or 134) of the operated switch is the second fixed contact (reference numeral DN2 or UP2). After that, the first movable contact (reference numerals 131 and 132) is turned on with respect to the first fixed contact (reference numerals DN1 and UP1). Therefore, when the second movable contact is turned off and the first movable contact is turned on simultaneously, or when the first movable contact is turned on earlier than the second movable contact is turned off. Dead short (in this embodiment, a short circuit between the positive terminal of the power supply and the anode terminal of the diode D5) can be avoided.
[0055]
In addition, you may change the said embodiment as follows.
In the embodiment, PNP type transistors are used for the transistors TR1, TR4, and TR5, respectively, but NPN type transistors may be used. In this case, the collector of the transistor TR1 is connected to the positive terminal of the power supply, and the emitter is connected to the anode of the diode D1. The collector of the transistor TR4 is connected to the first movable contact 131 of the lowering switch 128, and the emitter is connected to the anode of the diode D2. Further, the collector of the transistor TR5 is connected to the first movable contact 132 of the ascending switch 129, and the emitter is connected to the anode of the diode D3.
[0056]
In the embodiment, NPN transistors are used for the transistors TR2, TR3, and TR6, respectively, but PNP transistors may be used. In this case, the emitter of the transistor TR2 is connected to the negative terminal of the relay coil 23, and the collector is grounded. Further, the emitter of the transistor TR3 is connected to the negative terminal of the relay coil 21, and the collector is grounded. Further, the emitter of the transistor TR6 is connected to the cathodes of the diodes D4 to D8, and the collector is grounded.
[0057]
In the above embodiment, the transistors TR2 and TR3 are used, but a transistor array having two transistor elements may be used. In this case, the power window device can be reduced in size.
[0058]
In the above embodiment, the transistors TR4 and TR5 are used, but a transistor array having two transistor elements may be used. In this case, the power window device can be reduced in size.
[0059]
In the embodiment, two relays (first and second relays 22 and 24) are used, but two relays in the same package may be used. In this case, the power window device can be reduced in size.
[0060]
Next, technical ideas other than the inventions described in the claims that can be grasped from the respective embodiments will be described below together with their effects.
(A) The first movable contact of each switch circuit is configured to be turned on with respect to the first contact after the second movable contact is turned off from the second contact. 4. The power window switch circuit according to claim 3.
[0061]
Therefore, according to the invention described in (a), when the down switch circuit or the up switch circuit is turned on, first, the second movable contact of the switch circuit that is turned on is turned off from the second contact. Thereafter, the first movable contact is turned on with respect to the first contact. Therefore, when the second movable contact is turned off and the first movable contact is turned on simultaneously, or when the first movable contact is turned on earlier than the second movable contact is turned off. Can be avoided.
[0062]
【The invention's effect】
According to the first aspect of the present invention, when the power window switch circuit is submerged, the window glass can be reliably lowered or raised based on the ON operation of the lowering switch circuit or the raising switch circuit.
[0063]
According to the invention described in claim 2, in addition to the effect of the invention described in claim 1, when the power window switch circuit is submerged, it is possible to prevent the window glass from inadvertently descending or rising. it can.
[0064]
According to the invention described in claim 3, in addition to the effect of the invention described in claim 1 or 2, the control signal output from the control circuit and the ON operation of the third switching means are provided. 4 Excitation and demagnetization of each relay coil can be realized based on the action of the switching means (supply of HI potential to one terminal of each relay coil).
[Brief description of the drawings]
FIG. 1 is an electric circuit diagram of a power window switch circuit according to an embodiment.
FIG. 2 is an electric circuit diagram of a conventional power window switch circuit.
[Explanation of symbols]
10 ... power window switch circuit, 12 ... control circuit,
15 ... Leak detection circuit as inundation detection means,
21 ... Relay coil as the first relay coil,
23 ... Relay coil as the second relay coil,
128 ... a lowering switch as a lowering switch circuit,
129 ... Ascending switch as an ascending switch circuit,
131: first movable contact, 132: first movable contact,
133: second movable contact, 134: second movable contact,
TR1 ... transistor as the fourth switching means,
TR4: transistor as first switching means,
TR5: transistor as second switching means,
TR6: transistor as third switching means,
DN1: a first fixed contact as a first contact,
DN2 ... a second fixed contact as a second contact,
UP1 ... 1st fixed contact as 1st contact,
UP2: Second fixed contact as a second contact.

Claims (3)

A descending switch circuit, an ascending switch circuit, and a control circuit for controlling the excitation and demagnetization of the first relay coil for lowering the window glass and the second relay coil for raising the window glass based on the ON operation of each switch circuit. A power window switch circuit configured to supply a HI potential to one terminal of each relay coil,
The lowering switch circuit is a first contact connected to a power supply side terminal, a second contact connected to the other terminal of the second relay coil, and a normally open contact with respect to the first contact, A first movable contact that inputs a first relay coil excitation input signal to the control circuit during an ON operation, and a second movable contact that is interlocked with the first movable contact and that is a normally closed contact with respect to the second contact. Including
The rising switch circuit is a first contact connected to a power supply side terminal, a second contact connected to the other terminal of the first relay coil, and a normally open contact with respect to the first contact, A first movable contact that inputs a second relay coil excitation input signal to the control circuit during an ON operation, and a second movable contact that is linked to the first movable contact and that is a normally closed contact with respect to the second contact; Including
A first switching means is connected between the first movable contact of the descending switch circuit and the other terminal of the second relay coil,
A second switching means is connected between the first movable contact of the rising switch circuit and the other terminal of the first relay coil,
Providing a third switching means for grounding each second movable contact of the descending switch circuit and the ascending switch circuit and turning on the first switching means or the second switching means during an on operation;
A power window switch circuit, comprising: a flood detection means for turning on the third switching means when the flood is detected. 2. The power window switch circuit according to claim 1, wherein the third switching unit grounds a circuit for supplying power to the control circuit when the switch is turned on. 3. The control circuit outputs a control signal based on the input signal for exciting the first relay coil or the input signal for exciting the second relay coil,
3. The power window according to claim 1, further comprising fourth switching means for supplying a HI potential to one terminal of each relay coil based on the control signal and the ON operation of the third switching means. Switch circuit.

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