JP3898341B2 - Airbag disposal device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
TECHNICAL FIELD The present invention relates to an airbag disposal device for igniting an explosive means (squib) in a demolition factory or the like to discard and deploy (inflate) an airbag, and more specifically, includes an airbag for protecting passengers in a vehicle. In particular, the present invention relates to an apparatus in which an airbag is discarded and expanded (inflated) when the airbag is discarded.
[0002]
[Prior art]
In recent years, the number of vehicles equipped with airbags that inflate at the time of a collision and protect passengers has been increasing, and airbags are being installed not only in the driver's seat but also in the passenger seat and the rear seat. When a vehicle equipped with such an air bag is scrapped, there is a risk of unintentional eruption during scrap car work, so the air bag must be forcibly deployed (operated or inflated) in advance and then discarded with the inflator. It is desirable to do.
[0003]
In an airbag control unit, a safety sensor (switch) and a drive transistor (semiconductor switch) for energizing a squib (detonation means) are generally connected in series between the on-vehicle battery power source and the ground, and are safe. When the swing sensor is turned on and the drive transistor is turned on, the squib is energized and ignited.
[0004]
Regarding such airbag disposal technology, in JP-A-9-76855, a lead wire connecting an electronic control unit and a squib (detonation means) is short-circuited with a jumper cable from the outside and connected to an external power supply device. A technique for disposing and deploying an air bag by energizing a squib and starting it has been proposed.
[0005]
Further, in Japanese Patent Laid-Open No. 9-240416, a waste driving circuit is incorporated in the electronic control unit so as to bypass the safing sensor, and the two transistors are alternately turned on to charge and discharge the capacitor. We are proposing a technique for detonating by supplying alternating current to the squib.
[0006]
[Problems to be solved by the invention]
However, in the technique described in Japanese Patent Laid-Open No. 9-76855, it is necessary to open the cover of the inflator and take out the lead wire connected to the squib and connect it to the jumper cable at the time of disposal. There was an inconvenience that the work man-hour increased.
[0007]
In addition, since the inflator cover and the shape or position of the cover are not necessarily the same depending on the vehicle type, it is necessary to check each vehicle type, which further increases the number of work steps. In addition, there was a human error problem due to manual work.
[0008]
In the technique described in Japanese Patent Laid-Open No. 9-240416, since the two transistors are alternately turned on to charge and discharge the capacitor to obtain a driving power supply, it is difficult to sufficiently satisfy the certainty of operation. was there.
[0009]
Accordingly, the present invention provides an airbag disposal device that eliminates the above-mentioned drawbacks of the prior art, can easily and reliably discard an airbag, and reduces the possibility of human error. It is in.
[0010]
[Means for Solving the Problems]
In order to achieve the above object, in the air bag disposal apparatus according to claim 1, an explosion means accommodated in an inflator of an airbag mounted on a vehicle, and a voltage for connecting the explosion means to a voltage source A supply path, first acceleration detection means that is turned on in response to acceleration acting on the vehicle, second acceleration detection means that detects acceleration acting on the vehicle, and serial connection of the initiation means to the voltage supply path And a microcomputer for outputting an operation signal to the semiconductor switch in response to an output of the second acceleration detecting means, and controlling the airbag to inflate the airbag by energizing the initiation means When the device is provided with a device, the connector of the case housing the control device is replaceable, and is fitted through the connector External tools and supplies a second voltage source connected to the control device, the voltage of the voltage supply path compared with the first reference value, the voltage supply path is used up is connected to the first voltage source When the voltage supply path is connected to the second voltage source, the voltage of the second voltage source is compared with the second and third reference values. A comparator means for generating a second comparison output indicating that the voltage of the second voltage source is within a predetermined range defined by the second and third reference values ; A discard command input means for inputting the discard command of the operator, a second semiconductor switch inserted in the voltage supply path, and the second semiconductor switch according to the discard command of the operator and the second comparison output An energizer that outputs an operation signal to energize the initiation means It was as configuration comprises a. As a result, the airbag can be discarded easily and reliably, and the possibility of human error can be reduced. In addition, since the operation signal is output to the second semiconductor switch in response to the operator's discard command and the second comparison output and the initiation means is energized, in addition to the above-described functions and effects, The operating voltage required for disposal can be ensured, and the airbag can be discarded more reliably.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the accompanying drawings.
[0013]
FIG. 1 is a schematic view showing an airbag disposal apparatus according to the present invention, more specifically, an airbag apparatus 10 having a disposal circuit as a whole. An air bag device 10 is housed in a case 11 and is arranged near the dashboard of a driver's seat (not shown) of a vehicle (not shown).
[0014]
The airbag device 10 includes a microcomputer (hereinafter referred to as “CPU”) 12 and controls a normal deployment (inflation) operation of an airbag (not shown). That is, the CPU 12 is not for discarding the airbag but for controlling the normal operation of the airbag while the vehicle is operating, and the airbag apparatus 10 includes the CPU 12 and is premised on this.
[0015]
The operating power VB is supplied to the CPU 12 through the ignition switch 16 from a battery power supply 14 mounted on the vehicle. More specifically, the battery voltage (about 12V) is input to the airbag device 10 via the connector 17 and sent to the regulator 18, where it is adjusted to the operating voltage (5V) and supplied to the CPU 12.
[0016]
On the other hand, the battery voltage is input to the booster circuit 20 provided with a backup capacitor, and 35 V according to the command of the CPU 12 in the booster circuit 20 so that the airbag can operate even when the battery power supply 14 (battery device) is disconnected at the time of a vehicle collision. Charge the backup capacitor by boosting to a certain extent.
[0017]
The booster circuit 20 is connected to the voltage supply path 22. A squib 24 is connected to the voltage supply path 22. The squib 24 is accommodated in an inflator (not shown) of an airbag (not shown) stored in a steering wheel (not shown), and a small amount of explosive is arranged around the squib 24.
[0018]
The voltage supply path 22 between the booster circuit 20 and the squib 24 is composed of a lead wire, and is connected to the squib 24 by a steering connection (covering) cable 22a after leaving the airbag device 10.
[0019]
A G sensor (second acceleration detecting means) 32 is provided in the vicinity of the center position of the vehicle (not shown), and outputs a signal proportional to the acceleration (deceleration) generated in the traveling direction of the vehicle and sends it to the CPU 12.
[0020]
A safing sensor (first acceleration detecting means) 34 is provided in the airbag device 10. The safing sensor 34 is inserted upstream of the position where the squib 24 is disposed in the voltage supply path 22. The safing sensor 34 is composed of a reed switch, and a ferromagnetic lead is sealed in a glass tube with a gap at one end, and a coil is disposed around the encapsulated lead.
[0021]
The safing sensor 34 is turned off during normal driving of the vehicle to open the voltage supply path 22 and is turned on to close the voltage supply path 22 when acceleration (deceleration) of a predetermined value or more acts in the traveling direction of the vehicle. .
[0022]
In the voltage supply path 22, a first drive transistor (semiconductor switch) 36 is interposed between the squib 24 and the ground.
[0023]
The first drive transistor 36 is composed of an n-channel MOSFET, and its gate terminal is connected to the CPU 12 via an OR circuit 38 (described later), and its drain terminal is connected to the booster circuit 20 via the squib 24. The source terminal is grounded. The first drive transistor 36 is turned on when a high voltage (high level) operation signal is supplied to the gate terminal.
[0024]
Next, operations during normal vehicle operation will be described.
[0025]
When the acceleration (deceleration) acting on the vehicle is greater than or equal to a predetermined value from the output of the G sensor 32, the CPU 12 determines that a collision has occurred and outputs a high voltage (high level) operation signal to send it to the OR circuit 38. An output of an AND circuit 40 (described later) is input to the OR circuit 38. The output of the AND circuit 40 during normal vehicle operation outputs a low voltage (low level) operation signal.
[0026]
The OR circuit 38 receives a high voltage (high level) operation signal from the CPU 12 and outputs a high voltage (high level) operation signal, which is supplied to the gate terminal of the first drive transistor 36 to be conducted. At the same time, the safing sensor 34 is turned on to close the circuit.
[0027]
As a result, a current (approximately several A) flows from the backup capacitor of the booster circuit 20 to the squib 24, the squib 24 is energized and heated, ignites the enhancer (fire transfer agent), and burns the gas generating agent. The generated nitrogen gas enters the airbag from the inflator and inflates (deploys) the airbag to receive and protect the occupant's chest and head.
[0028]
Based on the above, the airbag disposal apparatus according to the present invention, more specifically, the airbag apparatus 10 including a disposal circuit will be described.
[0029]
The apparatus according to the present invention includes a disposal circuit 42 and a disposal tool (hereinafter referred to as “external tool”) separately from the CPU 12 that controls the normal deployment (inflation) of the airbag in order to discard the airbag when the vehicle is discarded. 44 was provided. The external tool 44 includes a tool power source 46 made of an AA type dry battery and the like, and a switch (discard command input means) 48. The voltage VP of the tool power supply 46 is set to about 12 V similarly to the battery voltage.
[0030]
The external tool 44 is connected to the discard dedicated circuit 42 through the discard dedicated connector 52. That is, when the airbag is discarded, the connector 17 on the CPU 12 side is removed, the external tool 44 is connected via the disposal dedicated connector 52, and the operating voltage VP is supplied from the tool power supply 46.
[0031]
Specifically, as shown by an imaginary line in the airbag device 10, the second voltage supply path 54 is wired in advance, and when the external tool 44 is connected via the disposal dedicated connector 52, the operating voltage VP is supplied to the upstream side of the squib 24 through the second voltage supply path 54 and the connection point 55.
[0032]
The discard exclusive circuit 42 includes a first comparator (op-amp. Comparison means) 60, a second comparator (op-amp. Comparison means) 62, and a third comparator (op-amp. Comparison means) 64.
[0033]
A reference voltage V1 (for example, 3V) obtained by dividing the voltage of a predetermined voltage source V (for example, 12V) by resistors R1 and R2 is input to the non-inverting input terminal of the first comparator 60, and the inverting input terminal has the inverting input terminal. Is input with the battery voltage VB.
[0034]
A reference voltage V2 (for example, 10V) obtained by dividing a voltage of a predetermined voltage source V (for example, 12V) by resistors R3 and R4 is input to the non-inverting input terminal of the second comparator 62, and the inverting input terminal thereof is also input to the inverting input terminal. Is input with the operating voltage VP.
[0035]
The reference voltage V3 (for example, 5V) obtained by dividing the voltage of the voltage source V by resistors R4 and R5 is input to the inverting input terminal of the third comparator 64, and the operating voltage VP is input to the non-inverting input terminal. Is done.
[0036]
Here, the first comparator 60 determines whether or not the battery voltage VB is within the reference voltage V1, that is, detects whether or not the battery power supply 14 has been removed. The second and third comparators 62 and 64 constitute a window comparator and determine whether or not the operating voltage VP replacing the battery voltage VB is within a predetermined range (for example, 5V to 10V).
[0037]
The output of the first comparator 60 is input to the AND circuit 40, and the outputs of the second and third comparators 62 and 64 are connected at a connection point 66, and the output is input to the AND circuit 40.
[0038]
Further, the output between the switch 48 and the ground is sent to the disposal dedicated circuit 42 and input to the inverter 70. The output of the inverter 70 is also input to the AND circuit 40.
[0039]
The output of the AND circuit 40 is input to the OR circuit 38 described above, and is connected to the gate terminal of the second drive transistor 74 via the second inverter 72. The second drive transistor 74 is composed of a p-channel type MOSFET, and its source terminal is connected downstream of the connection point 55 of the second voltage supply path 54 and its drain terminal is connected to the voltage described above via the connection point 76. Connected to the supply path 22.
[0040]
Next, the operation when the airbag is discarded will be described.
[0041]
First, the connector 17 is removed by the operator (scrap car dealer), and the battery power source 14 is disconnected from the airbag device 10. Next, the external tool 44 is connected to the airbag device 10 via the disposal dedicated connector 52.
[0042]
In the discard circuit 42, the first to third comparators compare the reference voltage with the input voltage, and output a high voltage (high level) or low voltage (low level) comparison signal accordingly.
[0043]
The first comparator 60 outputs a high voltage (high level) comparison signal when the battery voltage VB is less than the reference voltage (3 V), in other words, when the battery power supply 14 is removed.
[0044]
When the tool voltage VP is within a predetermined range (5V to 10V), in other words, the second and third comparators 62 and 64 are sufficient as the operating voltage at the time of disposal instead of the battery power supply 14. When a high output is provided, a high voltage (high level) comparison signal is output.
[0045]
These comparison outputs are input to the AND circuit 40. At this time, when the operator retreats from the vehicle and turns on the switch 48 of the external tool 44 at a position away from the vehicle, a low voltage (low level) signal is input to the airbag device 10 and inverted by the inverter 70. A high voltage (high level) signal is input to the AND circuit 40.
[0046]
Therefore, the AND circuit 40 outputs a high voltage (high level) signal. The output is input to the OR circuit 38 on the one hand, and the OR circuit 38 outputs a high voltage (high level) signal and sends it to the gate terminal of the first drive transistor 36 to make it conductive.
[0047]
On the other hand, the output of the AND circuit 40 is input to the second inverter 72. The second inverter 72 inverts the input and outputs a low voltage (low level) signal, which is sent to the gate terminal of the second drive transistor 74 to conduct.
[0048]
Accordingly, current flows from the booster circuit 20 to the second drive transistor 74, the squib 24, and the first drive transistor 36, bypassing the safety sensor 34, and the squib 24 is ignited to expand (inflate) the airbag.
[0049]
Since this embodiment is configured as described above, the airbag can be discarded easily and reliably, and the possibility of human error can be reduced.
[0050]
In other words, it is configured to ignite when the operator turns on the switch, so that the intention of disposal can be confirmed, and the operation power is supplied, so even when the battery power of the vehicle is discharged, etc. Can be ignited.
[0051]
In addition, since an external tool is connected via the exclusive connector for disposal and ignition is performed only by turning on the switch, the possibility of human error can be reduced.
[0052]
As described above, the airbag discarding apparatus according to this embodiment includes an explosion means (squibs 24 and 26) housed in an inflator of an airbag mounted on a vehicle, and a voltage source (battery power supply 14). ), A first acceleration detecting means (safing sensor 34) that is turned on in accordance with the acceleration acting on the vehicle, and a second acceleration detecting means for detecting the acceleration acting on the vehicle. (G sensor 32), a semiconductor switch (first and second drive transistors 36, 38) inserted in series with the initiation means in the voltage supply path, and an output of the second acceleration detection means An air bag control device (CPU 12) that outputs an operation signal to the semiconductor switch and inflates the air bag by energizing the initiation means ( The air bag device 10) provided with a waste circuit is provided with a connector (discard connector) 52 that can be exchanged with the connector 17 of the case 11 that accommodates the control device, and is fitted via the connector 52. An external tool (disposal-only tool) 44 connected to the control device and supplying a second voltage source tool power source 46), comparing the voltage of the voltage supply path 22 with a first reference value V1, with the voltage supply path for generating a first comparison output indicating that it no longer connected to the first voltage source, when the voltage supply path is connected to said second voltage source, said second voltage The source voltage VP is compared with the second reference value V2 and the third reference value V3, and the voltage of the second voltage source is within a predetermined range defined by the second and third reference values V2 and V3 . The second comparison that shows that Comparing means (first, second and third comparators 60, 62, 64) for generating a discharge command input means (switch 48) provided in the external tool for inputting an operator discard command, the voltage supply A second semiconductor switch (second drive transistor 74) interposed in the path, and an operation signal is output to the second semiconductor switch in response to the operator's discard command and the second comparison output; An energizing means (AND circuit 40, OR circuit 38, second inverter 72) for energizing the initiation means is provided.
[0054]
In the above description, the discard dedicated circuit 42 is composed of a discrete digital circuit, but may be composed of a microcomputer. Further, it may be constituted by an analog circuit.
[0055]
In the above description, the airbag mounted on the steering wheel is taken as an example, but the same applies to the airbag mounted on the passenger seat. Furthermore, although the airbag for collision from the vehicle traveling direction is taken as an example, it goes without saying that the present invention is equally applicable to the airbag for collision from the side of the vehicle.
[0056]
【The invention's effect】
According to the first aspect, the airbag can be discarded easily and reliably, and the possibility of human error can be reduced. In addition, the operating voltage necessary for disposal can be secured, and the airbag can be discarded more reliably.
[Brief description of the drawings]
FIG. 1 is a schematic diagram showing the overall configuration of an air bag disposal apparatus according to the present invention.
[Explanation of symbols]
10. Airbag device with waste circuit (airbag control device)
12 Microcomputer (CPU)
14 battery power source 17 connector 22 voltage supply path 24 squib 32 G sensor (second acceleration detecting means)
34 Safing sensor (first acceleration detecting means)
36 First drive transistor (semiconductor switch)
38 OR circuit (energization means)
40 AND circuit (energization means)
42 Dedicated circuit for disposal 44 Dedicated tool for disposal (external tool)
46 Tool power supply 48 Switch (Discard command input means)
52 Discard dedicated connector 54 Second voltage supply path 60 Comparator (comparison means)
62 Comparator (comparison means)
64 Comparator (comparison means)
70 Inverter 72 Inverter (energization means)
74 Second drive transistor (second semiconductor switch)

Claims (1)

Explosion means accommodated in an inflator of an air bag mounted on a vehicle, a voltage supply path connecting the explosion means to a first voltage source, and a first acceleration that is turned on in response to an acceleration acting on the vehicle Depending on the output of the detection means, the second acceleration detection means for detecting the acceleration acting on the vehicle, the semiconductor switch inserted in series with the initiation means in the voltage supply path, and the output of the second acceleration detection means Comprising a microcomputer that outputs an operation signal to the semiconductor switch, and includes an airbag control device that inflates the airbag by energizing the initiation means,
a. An external tool that includes a connector that is replaceable with a connector of a case that accommodates the control device, and is connected to the control device to supply a second voltage source when fitted through the connector;
b. Comparing the voltage of the voltage supply path with a first reference value and generating a first comparison output indicating that the voltage supply path is no longer connected to the first voltage source; the second when connected to a voltage source, the voltage of the second of said second voltage source, compared with the third reference value, the voltage is the second of said second voltage source, a third reference A comparison means for generating a second comparison output indicating that it is within a predetermined range defined by the value ;
c. Disposal command input means provided in the external tool for inputting an operator's discard command,
d. A second semiconductor switch interposed in the voltage supply path;
And e. Energization means for outputting an operation signal to the second semiconductor switch in response to the operator's disposal command and the second comparison output to energize the detonation means;
An air bag disposal apparatus comprising:

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