JP3024535B2 - Power supply system for sliding door - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply system for a sliding door.

[0002]

2. Description of the Related Art Various electric devices such as a full-lock motor and a control device are provided in a sliding door of a vehicle having a closer that automatically and completely closes (fully locks) a sliding door that is in a half door (half locked) state. Equipment is incorporated. It is necessary to supply power to these electric devices from the body side. For this purpose, a power supply system for a sliding door includes a power supply control unit including a microcomputer, a power supply relay, and the like, and a power supply terminal on the body side and a power supply terminal on the slide door side for supplying power from the body side. It consists of a junction switch and the like.
When the slide door is closed, the junction switch is connected immediately before the slide door is closed, and a ground signal is input to the power supply control unit to start power supply. This power supply stops after the set timer time T1 has elapsed or when the junction switch is released by opening the slide door (see FIG. 4). This prevents overdischarge of the battery and overheating of various electric devices when the vehicle is parked for a long time with the slide door closed.

[0003]

However, in the above power supply system, after the slide door is closed and power supply is stopped, in the circuit between the power supply relay and the ground, for example, an abnormality such as a contact failure of a junction switch or a connector occurs. Then, when the input signal to the microcomputer via the junction switch changes from on to off to on, power supply is started again. This allows
In the closed state of the slide door, there occurs a problem that a full lock motor that does not need to be activated operates (FIG. 5).
reference). Also, even during operation of the full lock motor,
When the junction switch is turned off due to the above-described circuit abnormality, power supply is stopped (see FIG. 6).

Further, in response to the above-mentioned problem, even if the input signal from the junction switch to the microcomputer changes from on to off to on in a short time, the junction switch is controlled so that the full lock motor does not malfunction. Power supply is set to start only when the time interval from off to on is equal to or longer than a predetermined time T2 (FIG. 4).
And the full-lock motor, which was deactivated due to power supply stop during operation, does not start power supply unless the ON signal of the junction switch is input after T2 time. It will not open (see FIG. 6). The present invention has been made in view of the above, and an object of the present invention is to provide a power supply system for a slide door in which various electric devices in the slide door do not malfunction due to erroneous power supply.

[0005]

The power supply system for a sliding door according to the present invention for achieving the above object supplies power to various electric devices provided in the sliding door from the body side. In a power supply system for a sliding door including a junction switch that is connected and turned on when closed, a feed-back signal of a courtesy switch that turns on when the sliding door is opened and turns off when the sliding door is closed is fed back. In the courtesy switch on state, the power supply is started when the junction switch is turned on, and the power supply is stopped after a lapse of a set timer time from when the courtesy switch is turned off.

[0006]

According to the power supply system for a sliding door, when the junction switch is turned on in the courtesy switch on state where the sliding door is not completely closed, the power supply relay operates to supply power to the slide door. Is started. In the closed state of the slide door where the courtesy switch is off, power supply is not started even if the junction switch is turned on. Therefore, it is possible to completely avoid the problem that the full lock motor that does not need to be operated in the closed state of the slide door is operated. After the courtesy switch is turned off, the power supply is not stopped when the junction switch is turned off. Therefore, when the power supply is stopped due to a circuit abnormality, the time is limited to the time from the start of the power supply until the courtesy switch is turned off (A region in FIG. 2).

Further, in the present system, the power supply start condition is a junction switch on in the courtesy switch on state, and the power supply does not start if the junction switch is on in the courtesy switch off state. For this reason, it is not necessary to set the predetermined time T2 from the time when the junction switch is turned on to the time when the junction switch is turned on as a power supply start condition as in the related art.
Even if an erroneous signal such that the junction switch changes from ON to OFF to ON occurs in a short time in the above-mentioned area A and power supply is stopped, power supply is started again by turning on the junction switch. There is no possibility that the slide door does not open due to the state where the motor is stopped halfway.

[0008]

Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic block diagram of a power supply system for a sliding door according to the present invention. A power supply control unit (hereinafter referred to as a power supply ECU) 1 is provided on the body side. The power supply ECU 1 includes a power supply relay 2 and a microcomputer 3, and is connected to a power supply circuit 4 and a sliding door courtesy switch circuit 5. The sliding door courtesy switch circuit 5 is provided with a sliding door courtesy switch (hereinafter simply referred to as a courtesy switch) 6. The courtesy switch 6 is a known switch that turns on when the slide door is opened and turns off when the slide door is closed, and turns on and off a courtesy lamp (not shown).

The power supply relay 2 has fixed relay contacts 2a, 2
b and the switching relay contact 2c.
a is connected to the (+ B) terminal, and the switching relay contact 2c is connected to the (+ BOUT) terminal. The microcomputer 3 includes a CPU, a ROM, a RAM, various interfaces, and the like. Then, an on / off signal of a junction switch 31 described later is input via the signal input terminal 7, and the power supply relay 2 is controlled according to a predetermined control program by the on / off signal and the on / off signal of the courtesy switch 6. I do. Power supply relay 2
Is activated by a control signal from the microcomputer 3, and switches the switching relay contact 2c between the fixed relay contact 2a and the fixed relay contact 2b.

In the slide door, a slide door easy closer control unit (hereinafter referred to as an easy closer ECU) 11 is provided. The power supply ECU 1 and the easy closer ECU 11 are connected via a junction switch 31 connected by closing the slide door. The junction switch 31 includes power supply terminals 32a, 32b and 33a, 33 having a mail terminal and a female terminal as a pair on the body side and the slide door side, respectively.
b and ground terminals 34a and 34b. The circuit closed by the power supply terminals 32a and 32b is used as a power supply line, and is body-grounded by the ground terminal 34a. A circuit closed by the power supply terminals 33a and 33b is used as a signal feedback line, and a ground signal which is an on / off signal of the junction switch 31 is supplied to the circuit.
Input to microcomputer 3.

The easy closer ECU 11 comprises a microcomputer 12, a forward rotation relay 13, a reverse rotation relay 14, a full lock cam position switch input circuit 15, a half latch detection switch input circuit 16, and a door control switch input circuit 17 for a sliding door. Is done. The (+ B) terminal and the (GND) terminal of the easy closer ECU 11 are connected to the power supply terminal 32b and the ground terminal 34b on the slide door side of the junction switch 31, respectively. A sliding door full lock motor 18 is connected between the forward rotation relay 13 and the reverse rotation relay 14. The full lock cam position switch 19, the half latch detection switch 20, and the door control switch 21 are connected to the ground terminal 34b of the junction switch 31, respectively. A power supply terminal 33b is connected to the ground terminal 34b.

The operation of the power supply system for a sliding door having the above configuration will be described with reference to the timing charts of FIGS. When the slide door is opened, the courtesy switch 6 is turned on. When the slide door is closed to be in the half-door state, the power supply terminals 32a, 33a of the junction switch 31 and the ground terminals 34a, 34b come into contact with each other. Then, a ground signal which is an ON signal of the junction switch 31 is input to the microcomputer 3. Based on the ON signal of the courtesy switch 6 and the ON signal of the junction switch 31, a relay drive signal is output from the microcomputer 3, and the power supply relay 2 is activated to switch the switching relay contact 2c.
Is switched from the fixed relay contact 2b to the fixed relay contact 2a, and power supply is started.

As a result, the battery voltage is maintained for a predetermined time via the junction switch 31 through the easy closer E.
The voltage is applied to the CU 11 to enter a power supply state. When the half latch detection switch 20 is turned on in this state, the full lock motor 18 is operated, the slide door is closed, and the courtesy switch 6 is turned off. When the timer time T3 elapses after the courtesy switch 6 is turned off, the power supply is automatically stopped.
When the slide door is closed and the courtesy switch 6 is turned off, power is supplied again even if the junction switch 31 changes from on to off to on in a short time due to a failure in a circuit system in which the junction switch 31 is interposed. Is never started.

If the slide door is opened before the timer time T3 elapses after the courtesy switch 6 is turned off, the courtesy switch 6 is turned on and the terminals of the junction switch 31 are separated. And
The off signal is input to the microcomputer 3.
Based on the OFF signal, the relay drive signal from the microcomputer 3 is cut off, the switching relay contact 2c of the power supply relay 2 is switched to the fixed relay contact 2b, and power supply is stopped.

The timing chart of FIG. 3 shows that the power supply is started in the half-door state by the closing operation of the slide door, the slide door full lock motor 18 is driven, and immediately before the slide door closes (the courtesy switch 6).
FIG. 3 shows an operation when the junction switch 31 changes from ON to OFF to ON in a short time due to a failure in the circuit system. In this case, the off signal of the junction switch 31 is input to the microcomputer 3 and the power supply is temporarily stopped. Junction switch 31
Is turned on again in a short time, the power supply is started and the stopped slide door full lock motor 18 is restarted. The slide door full lock motor 18 temporarily stops after the forward rotation for a predetermined time, and then reversely drives for a short time and stops. As a result, the slide door enters the full lock state. During this time, the full lock cam position switch 19 is turned on / off. Then, when the timer time T3 elapses after the courtesy switch 6 is turned off, the power supply is automatically stopped.

As described above, in the power supply system for a sliding door according to the present invention, the ON signal of the junction switch 31 is input to the microcomputer 3 when the courtesy switch 6 is turned on because the sliding door is not completely closed. Then, the power supply relay 2 operates to start power supply. When the courtesy switch 6 is off and the slide door is closed, power is not started even if the junction switch 31 is turned on. Therefore, the slide door full lock motor 18, which does not need to be operated in the closed state of the slide door, does not malfunction.

After the courtesy switch 6 is turned off, the power supply is not stopped when the junction switch 31 is turned off. Therefore, when the power supply stops due to a circuit abnormality,
It is limited to a period from the start of power supply until the courtesy switch is turned off (A region in FIG. 2). Further, turning on the junction switch 31 in the on state of the courtesy switch 6 is a power supply start condition, and power supply does not start when the junction switch 31 is on in the off state of the courtesy switch 6. For this reason, it is not necessary to set the predetermined time T2 from the time when the junction switch 31 is turned on to the time when the junction switch 31 is turned on as a condition for starting power supply as in the related art. Even if power supply is stopped in the above-described area A even if an erroneous signal such that the junction switch 31 changes from ON to OFF to ON occurs in a short time while the slide door full lock motor 18 is operating, power supply is stopped.
Since the power supply is started again when the junction switch 31 is turned on, the state in which the slide door full lock motor 18 is stopped halfway continues and the slide door does not stop opening.

[Brief description of the drawings]

FIG. 1 is a schematic block diagram of a power supply system for a sliding door.

FIG. 2 is a timing chart showing the operation of the power supply system for a sliding door.

FIG. 3 is a timing chart showing the operation of the power supply system for a sliding door.

FIG. 4 is a timing chart showing the operation of a conventional power supply system for a sliding door.

FIG. 5 is a timing chart showing the operation of a conventional slide door power supply system.

FIG. 6 is a timing chart showing an operation of a conventional power supply system for a slide door.

[Explanation of symbols]

 Reference Signs List 1 power supply ECU 2 power supply relay 3 microcomputer 5 courtesy switch circuit 6 courtesy switch 11 easy closer ECU 12 microcomputer 18 slide door full lock motor 31 junction switch

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-7-229344 (JP, A) JP-A-7-279513 (JP, A) JP-A-6-344772 (JP, A) 98045 (JP, U) Japanese Utility Model Hei 2-30747 (JP, U) Japanese Utility Model Hei 4-39093 (JP, U) Japanese Utility Model Hei 5-41991 (JP, U) (58) Fields surveyed (Int. Cl. ⁷ , DB name) B60J 5/06

Claims (1)

(57) [Claims] 1. A power supply system for a slide door, comprising: a junction switch that is connected and turned on when the slide door is closed in order to supply power from a body side to various electric devices disposed in the slide door. Turn on when the slide door is opened, feedback the on / off signal of the courtesy switch that turns off when closed, in the courtesy switch on state, start power supply when the junction switch is turned on,
A power supply system for a sliding door, wherein power supply is stopped after a set timer time has elapsed from when the courtesy switch was turned off.