JP4693290B2 - Battery rise prevention device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a battery rise prevention device for preventing battery rise of a battery mounted on a vehicle.
[0002]
[Prior art]
In general, a vehicle such as a passenger car or a truck may elapse for a long period of time after the vehicle is manufactured until it is actually delivered to a user. In addition, the battery mounted on the vehicle has a small but dark current flowing, and when charging is not performed for a long time, the charged voltage is discharged, and when the battery is delivered to the user, There may be a problem that the battery voltage is lowered and the ignition cannot be started.
[0003]
In order to solve such a problem, by installing a fuse between each electronic control device mounted on the vehicle and the battery and removing the fuse until the vehicle is delivered to the user, a dark current is obtained. A method for preventing the occurrence of this is used. However, this method is troublesome in attaching the fuse, and causes the same problem as described above when the vehicle is not used for a long period of time (for example, 30 days or more) except when the vehicle is delivered.
[0004]
Therefore, conventionally, as described in JP 2000-142275 A (hereinafter referred to as the conventional example), a keep relay is installed between the battery and the electronic control device, and the keep relay is cut off. A technique for preventing the occurrence of dark current has been proposed.
[0005]
FIG. 3 is a circuit configuration diagram schematically showing the battery rising prevention device 101 described in the conventional example. As shown in the figure, an overcurrent protection fuse F101 is installed between the battery E101 and various electronic control devices 102a to 102d mounted on the vehicle, and further, a contact 103a of the keep relay 103 is provided. Is provided.
[0006]
Furthermore, a drive circuit 104 for driving the relay coil 103c of the keep relay 103, a CPU 105, and a regulator 106 are provided. The regulator 106 converts, for example, a battery voltage of 12 volts into 5 volts and supplies it to the CPU 105.
[0007]
In the above configuration, the CPU 105 measures the time during which the ignition switch 107 of the vehicle is not turned on using a timer. For example, when the ignition switch 107 is not turned on for 30 days, the CPU 105 turns on the keep relay 103 in the drive circuit 104 Therefore, a drive signal is output, and the keep relay 103 is turned off by the operation of the drive circuit 104. As a result, dark current flowing from the battery E101 to the electronic control units 102a to 102d is prevented, and the battery is prevented from running out.
[0008]
[Problems to be solved by the invention]
However, in the conventional battery run-out prevention device 101 described above, when the ignition switch 107 is turned on, the measurement time by the timer is reset. For this reason, the ignition switch 107 is simply turned on, and the timer is reset despite the fact that the operation for charging the battery is not actually performed. Therefore, the keep relay continues to be turned on again for 30 days from this point. During this period, dark current continued to flow, causing the problem of battery exhaustion.
[0009]
The present invention has been made to solve such a conventional problem, and its purpose is not to reset the timer in response to an ON operation of an ignition switch that does not contribute to battery charging. An object of the present invention is to provide a battery run-out prevention device.
[0010]
[Means for Solving the Problems]
In order to achieve the above object, an invention according to claim 1 of the present application is arranged between an electronic control device mounted on a vehicle and a battery that outputs a drive voltage to the electronic control device, and the electronic control device In a battery rise prevention device that prevents battery run-off by appropriately disconnecting the connection with the battery, the keep relay installed on the wiring connecting the battery and the electronic control device, and the vehicle ignition switch continue. First timer means for counting the time that is turned off, second timer means for timing a continuous elapsed time after the ignition switch is turned on, and the first timer means When the ignition switch is detected to be continuously turned off for a first predetermined time or longer, the keep relay is turned off and the keep switch is turned off. At the time of layoff, when the ignition switch is turned on, a control means for outputting a switching signal to turn on the keep relay, and a switching signal output from the control means, the keep relay is turned on and off. A relay driving means for switching, and the control means has a continuous on-time of the ignition switch detected by the second timer means when the ignition switch is turned on when the keep relay is on. If the predetermined time is shorter than 2, the first timer means is not reset.
[0011]
According to a second aspect of the present invention, the control means is configured such that when the keep relay is turned on, a time during which the ignition switch is continuously turned on is longer than the second predetermined time. Even so, when the travel distance of the vehicle when the ignition switch is on is shorter than a predetermined distance, the first timer means is not reset.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a circuit diagram showing a configuration of a battery run-out prevention device according to the first embodiment of the present invention. As shown in the figure, the battery rise prevention device 1 is disposed between a battery E1 and electronic control devices (such as an electric seat control device and an air conditioner control device) 2a to 2d mounted on the vehicle. It has a keep relay 3 for switching on and off the voltage supply to each of the electronic control devices 2a to 2d.
[0013]
Further, a driving circuit (relay driving means) 4 that outputs an operating voltage to the relay coil 3c of the keep relay 3, a CPU 5 (control means) that outputs a driving signal (switching signal) to the driving circuit 4, and a battery E1. And a regulator 6 that outputs a voltage (for example, 5 volts) supplied to the CPU 5 by stepping down a voltage (for example, 12 volts) that is output more.
[0014]
The CPU 5 outputs a drive signal to the drive circuit 4 to turn the keep relay 3 on or off based on a predetermined condition (described later). The CPU 5 has a first timer circuit (first timer means) 5a and a second timer circuit (second timer means) 5b, and the ignition switch 7 is turned off in the timer circuit 5a. The timer circuit 5b counts the time for which the ignition switch 7 is turned on.
[0015]
Further, travel distance data is input to the CPU 5 from a travel distance detector (not shown) mounted on the vehicle. In addition, the code | symbol F1 shown to the same figure is a fuse for overcurrent protection.
[0016]
FIG. 2 is a flowchart showing the operation of the present embodiment, and the operation of the battery running prevention device 1 according to the first embodiment will be described with reference to the flowchart.
[0017]
During normal operation, the on / off state of the ignition switch 7 is monitored under the control of the CPU 5, and the keep relay 3 is switched on / off accordingly. That is, the first timer circuit 5a measures the continuous off time of the ignition switch 7, and when the ignition switch 7 is continuously off for a first predetermined time (for example, 30 days), the drive circuit 4 outputs a drive signal to turn off the keep relay 3, and the drive circuit 4 applies a voltage to the relay coil 3c to turn off the relay contact 3a.
[0018]
Thereby, since the electrical connection between the battery E1 and each electronic controller 2a-2d is interrupted | blocked, generation | occurrence | production of a dark current can be suppressed and a battery run-up can be prevented.
[0019]
Further, when the ignition switch 7 is operated with the keep relay 3 turned off, an on signal of the ignition switch 7 is supplied to the CPU 5, and the relay contact 3a of the keep relay 3 is controlled by the control of the CPU 5. Turn on. Thereby, the voltage output from the battery E1 is supplied to each of the electronic control devices 2a to 2d and becomes operable.
[0020]
Here, when the ignition switch 7 is turned off and the time is measured by the first timer circuit 5a, that is, after the ignition switch 7 is turned off, 30 days have not passed and the keep relay 3 is turned on. When the ignition switch 7 is turned on (YES in step ST1 in FIG. 2), the on-time of the ignition switch 7 is timed by the second timer circuit 5b, and this on-time T1 is preset. It is determined whether it is longer than the set predetermined time (second predetermined time; for example, 30 seconds) (step ST2).
[0021]
If it is 30 seconds or less (NO in step ST2), the process returns without resetting the first timer circuit 5a. That is, even if the ignition switch 7 is turned on, if the ignition switch 7 is on for a short time of 30 seconds or less, the battery is not charged or is equivalent to not being charged. The first timer circuit 5a for measuring the first predetermined time is not reset.
[0022]
On the other hand, when the on-time T1 of the ignition switch 7 is longer than the second predetermined time (30 seconds) (YES in step ST2), the vehicle is calculated based on the travel distance data given from the travel distance detector (not shown). It is determined whether or not the vehicle has traveled 10 km or more (step ST3). If the travel distance L1 is 10 km or less (NO in step ST3), it is determined that the battery is not charged as described above, and the first timer circuit 5a is not reset.
[0023]
If the travel distance L1 is greater than 10 km (YES in step ST3), it is determined that the battery is being charged, and the time count by the first timer circuit 5a is reset (step ST4).
[0024]
Thus, even when the ignition switch 7 is turned on, it is determined whether or not the battery E1 is substantially charged based on the on-time of the ignition switch 7 and the travel distance of the vehicle, When substantial charging is not performed, control is performed so as not to reset the time count by the first timer circuit 5a.
[0025]
Thus, in the battery run-off prevention device 1 according to the present embodiment, when the ignition switch 7 is turned off and the ignition switch 7 is turned on when the time is measured by the first timer circuit 5a. However, when the on-time, that is, the time T1 measured by the second timer circuit 5b is shorter than the second predetermined time, the time measurement by the first timer circuit 5a is not reset.
[0026]
Therefore, even if the ignition switch 7 is turned on, if the battery E1 is not substantially charged, this operation is ignored and the first switch after the ignition switch 7 is turned off the first time is ignored. When the predetermined time (for example, 30 days) elapses, the keep relay 3 can be turned off, and the battery can be reliably prevented from running out due to dark current.
[0027]
Further, even when the on-time T1 of the ignition switch 7 is longer than the second predetermined time, when the travel distance of the vehicle at this time is not more than a predetermined distance (for example, 10 km), the same as above. Therefore, it is determined that the battery E1 is not substantially charged, and the time measurement by the first timer circuit 5a is not reset. As a result, it is possible to more reliably prevent the battery from rising due to dark current.
[0028]
As mentioned above, although the battery rising prevention apparatus of this invention was demonstrated based on embodiment of illustration, this invention is not limited to this, The structure of each part is replaced with the thing of the arbitrary structures which have the same function. be able to.
[0029]
For example, in the above-described embodiment, the first predetermined time measured by the first timer circuit 5a is set as 30 days, and the second predetermined time measured by the second timer circuit 5b is set as 30 seconds. However, the present invention is not limited to this, and can be set at other times.
[0030]
Moreover, although embodiment mentioned above demonstrated the example in which the four electronic control apparatuses 2a-2d were provided, this invention is not limited to this, 1-3 or five or more electrons are provided. It is also possible to use a control device.
[0031]
【The invention's effect】
As described above, in the battery rising prevention device according to the present invention, even when the ignition switch is turned on when the ignition switch is turned off and the first timer means is operating, If the on-time is short (within the second predetermined time), it is determined that the battery is not substantially charged, and the first timer means is not reset. Therefore, even if the ignition switch is operated after the ignition switch is turned off, if the battery is not substantially charged, the first predetermined time (for example, 30 days) Since the keep relay is interrupted after the lapse of time, it is possible to reliably prevent the battery from being increased due to dark current.
[0032]
Even if the ignition switch is turned on and the on state continues for a second predetermined time (for example, 30 seconds), if the vehicle does not travel a predetermined distance, the battery is substantially charged. If it is determined not to be performed and the first timer means is configured not to be reset, it is possible to further improve the reliability of preventing the battery from running out.
[Brief description of the drawings]
FIG. 1 is a circuit diagram showing a configuration of a battery rising prevention device according to an embodiment of the present invention.
FIG. 2 is a flowchart showing an operation of the battery running prevention device according to the embodiment of the present invention.
FIG. 3 is a circuit diagram showing a configuration of a conventional battery run-off prevention device.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Battery rising prevention apparatus 2a-2d Electronic controller 3 Keep relay 3a Relay contact 3c Relay coil 4 Drive circuit (relay drive means)
5 CPU (control means)
5a First timer circuit (first timer means)
5b Second timer circuit (second timer means)
6 Regulator 7 Ignition switch E1 Battery F1 Fuse

Claims (2)

A battery that is disposed between an electronic control device mounted on a vehicle and a battery that outputs a drive voltage to the electronic control device, and prevents the battery from rising by appropriately disconnecting the connection between the electronic control device and the battery. In the rise prevention device,
A keep relay installed on a wiring connecting the battery and the electronic control unit;
First timer means for timing the time during which the ignition switch of the vehicle is continuously turned off;
Second timer means for measuring a continuous elapsed time after the ignition switch is turned on;
When the first timer means detects that the ignition switch is continuously turned off for a first predetermined time or more, the keep relay is turned off, and when the keep relay is turned off, the ignition switch is turned off. Control means for outputting a switching signal to turn on the keep relay when is turned on,
Relay drive means for switching on and off the keep relay according to a switching signal output from the control means,
When the ignition switch is turned on when the keep relay is turned on, the control means detects that the continuous on time of the ignition switch detected by the second timer means is shorter than a second predetermined time. A battery run-out prevention device, wherein the first timer means is not reset. When the ignition switch is turned on even when the ignition switch is continuously on when the keep relay is on, the control means is longer than the second predetermined time. 2. The battery run-out prevention device according to claim 1, wherein the first timer means is not reset when the travel distance of the vehicle is shorter than a predetermined distance.

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