KR19980080886A - Vehicle Control - Google Patents

Abstract

The present invention provides a control device for a vehicle that can be composed of small-sized electronic components of low cost and can always supply electric power to the driver's side airbag system 32 and the like.

A first boost circuit for raising a battery voltage to a predetermined first voltage, a second boost circuit for boosting the battery voltage to a second voltage lower than the first boost circuit, and a constant voltage for constant voltage raising the second boost circuit A main control means powered by the first booster circuit to operate the main control function, and at least one sub control means which is supplied from the constant voltage circuit through the power supply line to operate the sub control function. And multiple communication via the power line with control means.

Description

Vehicle Control

TECHNICAL FIELD The present invention relates to a vehicle control apparatus which can be applied to an occupant protection device provided with an airbag for protecting an occupant, for example, in a crash accident from the front and the side. .

A conventional vehicle control device of this kind will be described based on the occupant protection device shown in FIG.

First, the driver's seat airbag system (main control means) 23 which is the main occupant protection device will be described.

That is, 3 is a boosting circuit and boosts the input voltage from the battery 1 supplied through the ignition switch 2 to back-up condenser through the resistor 4 ( 5) The driver's seat side airbag system, which is a secondary occupant protection device through the first switch circuit 7 and the resistor 8 inserted in series with the power supply line 6, is charged (sub-control means). The boosted voltage is supplied to (32).

Reference numeral 9 denotes a front-rear acceleration sensor for detecting acceleration occurring in the front-rear direction of the vehicle, and the acceleration signal, which is a detection signal, is supplied to the microcomputer 10 described later.

The microcomputer 10 has a collision determination function and backs up by turning on the second switch circuit 11 when it is determined that a serious collision is made based on the acceleration signal supplied from the forward and backward acceleration sensor 9. The charge charged in the condenser 5 is discharged through the discharge diode 12, and an ignition current is sent in series to the primer 13 and the mechanical acceleration switch 14 to deploy the airbag attached to the handle. It goes without saying that the mechanical acceleration switch 14 is on at this time.

In addition, the microcomputer 10 has a failure diagnosis function of the backup capacitor 5, the primers 13 and 18, the mechanical acceleration switch 14, and the like. Immediately after the on operation of (2), the first switch circuit 7 is turned off via the signal line Y so that the charge charge of the backup capacitor 5 is reduced in each circuit of the driver's side airbag system 32. Do not discharge as a dark current. Thereafter, the switching transistor 16 is turned on, and the charge charged in the backup capacitor 5 is discharged through the resistor 15, and the change amount of the terminal capacitor voltage during the predetermined time is changed to the microcomputer 10. When the controller calculates the capacitance, diagnoses the capacity, and determines the capacity value as abnormal, the passenger is informed by using a lamp lamp alarm device (not shown).

In addition, the disconnection diagnosis of the primers 13 and 18 and the mechanical acceleration switch 14 is performed by the terminal voltages of the primers 13 and 18 and the mechanical acceleration switch 14 and the voltage difference thereof. If the microcomputer 10 judges that it is determined as disconnection or the like, the passenger is informed using an alarm device such as a lamp as described above.

In addition, the microcomputer 10 connects a request signal to a signal line X, a first communication circuit 20, a switching transistor 21, a resistor 22, a power line 6, and the like in series. A request signal from 23 is output, and various diagnostic signals are sent as response signals from the driver's side airbag system 32 through the switching transistor 28, the resistor 29, the power supply line 6, and the like. And make the same diagnosis as above.

17 is a third switch circuit, which is turned on when the microcomputer 10 receives a response signal of a major collision from the microcomputer 25 of the driver's side airbag system 32 and turns on the driver's side airbag primer 18. It works.

19 is a fourth switch circuit, which is on-controlled by the microcomputer 10 only for a predetermined time after the first switch circuit 7 is switched from an off state to an on state, and the smoothing capacitor of the constant voltage circuit 31平 위한 用 condenser to charge rapidly.

Next, the driver's side airbag system 32 will be described.

24 is the same acceleration sensor as the front and rear acceleration sensor 9, and the detection direction is different from the front and rear acceleration sensor 9, and is attached to detect the acceleration in the left and right directions of the vehicle, and the acceleration signal which is the detection output thereof is a microcomputer ( 25).

The microcomputer 25 has a collision determination function similar to that of the microcomputer 10, and determines a collision size based on an acceleration signal supplied from the left and right acceleration sensors 24, and a diagnosis result to describe the determination result described later. And output to the microcomputer 10 via the second communication circuit 27 as a response signal.

In addition, the microcomputer 25 has the same diagnostic function as that of the microcomputer 10, and performs fault diagnosis of the left and right acceleration sensor 24 and the acceleration switch 26, and the first communication circuit 20 in the microcomputer 10. Each time a request signal is supplied from the power supply line 6 through the power supply line 6, the diagnosis result is used as a response signal. To the microcomputer 10.

The acceleration switch 26 is composed of a semiconductor acceleration sensor and a comparison circuit for inputting the detection output thereof, and outputs a switch signal when the output from the semiconductor acceleration sensor exceeds the reference value of the comparison circuit.

Numeral 28 is a switching transistor such as a field effect transistor, which outputs a response signal formed by a signal indicating a collision by being turned on and off by an output signal of the second communication circuit 27 and indicating a collision.

29 is a resistor sandwiched between the switching transistor 28 and the power supply line 6, which is connected in series with the resistor 8 via the power supply line 6, and is an anode of the reverse flow prevention diode 30. When the voltage on the side of the switching transistor 21 or the switching transistor 28 is turned on, the lowest level does not become 0 level and is maintained at a constant voltage V1 (see Fig. 3) so that it is always input to the constant voltage circuit 31 described later. Allow the power to be fed. In addition, the constant voltage circuit 31 receives an input voltage at all times and supplies power to each circuit constituting the driver's side airbag system 32.

In addition, when the power supply line 6 communicates between the driver's seat airbag system 23 and the driver's seat side airbag system 32, the power supply line 6 has a voltage waveform as shown in FIG.

That is, in FIG. 3, the voltage V1 divides the output voltage V3 of the boosting circuit 3 when the switching transistor 21 and the switching transistor 28 are turned on into a resistor 8 and a resistor 29. The voltage V2 is determined by the value of the resistor 8 as the voltage when the switching transistor 21 (or the switching transistor 28) is turned off.

Next, the operation of the above configuration will be described.

① When the diagnosis function works

When the ignition switch 2 is turned on and the microcomputer 10 of the driver's seat airbag system 23 starts operation and diagnoses capacitance, the microcomputer 10 passes the first switch circuit (i) through the signal line (Y). 7) and the fourth switch circuit 19 are turned off, and the switching transistor 16 is turned on for a predetermined time to discharge the fully charged backup capacitor 5 through the resistor 4, at which time the backup capacitor ( By reading the terminal voltage of 5) by the microcomputer 10, the microcomputer 10 obtains the voltage change amount of the terminal voltage of the backup capacitor 5, determines whether the obtained capacitance is a specified value or not, and alarms when it is abnormal. Notify by operating the device.

In addition, the diagnosis of the disconnection of the primer (13, 18) and the like, even if it is determined that the failure to operate the alarm device.

Thereafter, the first switch circuit 7 is turned on to supply a diagnostic request signal to the microcomputer 25 of the driver's side airbag system 32 via the first communication circuit 20 and the power supply line 6. The fourth switch circuit 19 is turned on for a predetermined period of time until the next data is transmitted in synchronization with the completion of the header transmission of the header, thereby rapidly charging the smoothing capacitor of the constant voltage circuit 31 through the power supply line 6. Let's do it.

In addition, the microcomputer 25 having received the request signal reads the terminal voltage of each part of the driver's side airbag system 32, for example, the left and right acceleration sensors 24, and the like by the output of the second communication circuit 27. By switching on and off the switching transistor 28, the microcomputer 10 of the driver's seat airbag system 23 is transmitted through the power line 6 and transmitted through the signal line Z to diagnose the microcomputer 10. If it is determined that the failure is a result, the alarm device is operated as described above.

② When the collision judgment function is activated

When the vehicle makes a frontal collision such as a collision after the end of each diagnosis (or when not being performed), the mechanical acceleration switch 14 of the driver's seat airbag system 23 is turned on and the microcomputer 10 is moved back and forth. Based on the acceleration signal from the directional acceleration sensor 9, the microcomputer 10 turns on the second switch circuit 11 to control the charges charged in the backup capacitor 5 based on the acceleration signal. 12) to energize the primer 13 to spread the driver's seat airbag to protect the occupant from a frontal collision.

On the other hand, if the microcomputer 25 of the driver's side airbag system 32 determines that a major collision is made based on the switch signal from the acceleration switch 26 and the acceleration signal from the left and right acceleration sensors 24, the microcomputer 25 Supplies a signal indicating the signal to the microcomputer 10 as a response signal and controls the third switch 17 on to supply the charge charged in the backup capacitor 5 to the primer 18 through the power supply line 6. Unfold the side airbags formed in the seat to protect the occupants from side impacts.

In such a configuration, however, power must be supplied from the single booster circuit 3 to the driver's seat airbag system 23 and the driver's side airbag system 32, so that the booster circuit 3 must have a large power capacity. Expensive electronic circuit components and components with high breakdown voltage have to be used.

In addition, since the first switch circuit 7 is turned off while the microcomputer 10 is diagnosing the capacity of the backup condenser 5, the power supply to the driver's side airbag system 32 is stopped. Since the microcomputer 25 of the system 32 must stop the operation, the driver's side airbag system 32 cannot be diagnosed, resulting in a delay in starting the operation.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a control device for a vehicle which can be constituted by a low-cost small electronic component and can always supply electric power to the driver side airbag system 32 and the like.

1 is an explanatory diagram of a circuit block according to Embodiment 1 of the present invention;

2 is a circuit explanatory diagram showing a conventional example of the present invention;

FIG. 3 is a waveform diagram of a power supply line in FIG.

Explanation of symbols on the main parts of the drawings

7, 11, 17, 19: switch circuit 8, 22, 29: resistor

9, 24: acceleration sensor 10, 25: microcomputer

13, 18: primer (雷管) 20, 27: communication circuit

21, 28: switching transistor

26: acceleration switch

A first invention according to the vehicle control apparatus includes a first boost circuit for raising a battery voltage to a predetermined first voltage, a second boost circuit for boosting the battery voltage to a second voltage lower than the first boost circuit; A constant voltage circuit for constant voltage of the second boost circuit, main control means powered by the first boost circuit to operate the main control function, and at least one power supplied from the constant voltage circuit through a power line to operate the sub-control function. Equipped with sub-control means, the main control means multiplexes with the sub-control means via the power line.

In the second invention, the main control means and the sub control means are occupant protection means.

(Example)

(First embodiment)

A first embodiment of the present invention will be described with reference to FIG.

In Fig. 1, the same or equivalent components as those described in Fig. 2 are denoted by the same reference numerals, and the detailed description thereof will be omitted and only different portions will be described below.

That is, in FIG. 1, the fourth switch circuit 19 shown in FIG. 2 is deleted, and instead of the first switch circuit 7, a constant voltage circuit 33 is connected, and an input terminal of the constant voltage circuit 33 is connected. A second voltage booster outputting an output voltage of the first booster circuit 3 ', that is, a voltage smaller than 21V, that is, 9V between the booster circuit (hereinafter, referred to as a first booster circuit 3'). The circuit 34 is connected.

According to the above configuration, the driver's side airbag system 32 is constantly supplied with a constant voltage from the second booster circuit 34 through the constant voltage circuit 33 so that the microcomputer 25 can operate simultaneously with the microcomputer 10. There is no delay in starting operation.

In the related art, the constant voltage circuit 31 of the driver's side airbag system 32 has a large voltage loss since the voltage of the 21 V obtained by the voltage boosting circuit 3 is greatly increased to 5 V at once.

However, in the present invention, since the voltage is lowered from 9V to 5V, voltage loss can be reduced.

As described above, according to the first aspect of the present invention, since the components of the boosting circuit can be made up of small power components for small power, the effect of reducing the overall shape as well as the cost can be obtained.

According to the second aspect of the present invention, the overall shape is reduced, so that an effect that can be easily attached to a vehicle having a small space for mounting is exerted.

Claims (2)

A first boost circuit for raising a battery voltage to a first predetermined voltage; a second boost circuit for boosting the battery voltage to a second voltage lower than the first boost circuit; and a second boost circuit. A constant voltage circuit for constant voltage, main power means for feeding power from the first booster circuit to operate the main control function, and feeding power from the constant voltage circuit through a power supply line. Having at least one sub-control means for activating the sub-control function, And the main control means performs multiple communication with the sub control means via the power line. The method of claim 1, The main control means and the sub-control means is a vehicle control apparatus, characterized in that the occupant protection means.