KR20030014488A - Sensor for air back unit capable of testing car bump and acceleration - Google Patents

Abstract

PURPOSE: A combined sensor of an airbag is provided to sense a collision and measure acceleration together without influence of electromagnetic waves. CONSTITUTION: A combined sensor(100) has a housing(10); a guide member(20); an elastic member(30); a slider member(40); a first sparking line(50); second sparking lines(60) and a light receiving sensor(70). The housing is installed to a vehicle. The guide member is installed to an inner surface of the housing. The elastic member is installed to one side of the guide member. The slider member is combined with the elastic member to slide with the guide member. The slider member slides to return elasticity of the elastic member when the vehicle collides to a specific thing. The slider member returns to a starting site when collision impact is disappeared. The first sparking line is installed to an upper side of a fixed member(13). The fixed member is installed to a lower surface of the housing. Second sparking lines are installed to the upper side of the slider member to make a spark by approaching to an anode sparking line when the slider member moves. The light receiving sensor is installed to the inner surface of the housing. The light receiving sensor senses and transmits sparks to a receiving part of an airbag unit. Therefore, size of the airbag unit is small and electromagnetic waves are not influenced.

Description

Integrated sensor for airbags that can measure vehicle collision detection and acceleration {SENSOR FOR AIR BACK UNIT CAPABLE OF TESTING CAR BUMP AND ACCELERATION}

The present invention relates to an integrated sensor for an airbag capable of measuring both a collision detection and an acceleration amount of a vehicle. More particularly, the size of an airbag unit may be increased by detecting an impact of the vehicle and an acceleration according to the integrated sensor. The present invention relates to an integrated sensor for an airbag that can be implemented small and detects collision and acceleration by detecting the sparks of the first and second ignition lines without being affected by electromagnetic waves.

In general, an airbag system mounted on a vehicle is a device that minimizes injuries by inflating the airbag momentarily between the driver and the steering wheel or between the passenger and the instrument panel of the passenger seat when the vehicle crashes.

In these airbags, two types of airbags, called the SRS airbag system, which are equipped with a three-point belt and a system that uses a large airbag for the driver who is mounted on the steering wheel and do not have seat belts. There is this.

As a way to inflate the airbag, a predetermined bead is advanced in the event of a vehicle crash and pressurizes the piezoelectric sensor to generate a signal. Inflate the airbag.

However, since the piezoelectric sensor may be subjected to electromagnetic interference, there is an inherent possibility of opening the airbag due to electromagnetic interference. In addition, since there is a function of the collision sensor and no function of the acceleration sensor to use a separate acceleration sensor, there is a problem that the parts cost and development cost is increased according to this, and the size of the airbag unit is increased due to the increase of the required space of the airbag unit. .

The present invention has been made to solve the problems described above, and can detect a collision and acceleration of the vehicle without the influence of electromagnetic waves, collision detection and acceleration of the vehicle that can reduce the size of the airbag unique The object is to provide an integrated sensor for airbags that can measure the weight together.

1 is a plan view schematically showing an integrated sensor for an airbag capable of measuring a collision detection and an acceleration amount of a vehicle according to a preferred embodiment of the present invention.

2 is a side cross-sectional view of FIG.

3 is an operation showing the operating state of the collision sensor of Figure 1 during a vehicle crash.

<Explanation of symbols for the main parts of the drawings>

10.Housing 20 ... Guide member

30 ... elastic member 40 ... slider member

50 ... Ignition line 60 ... Ignition line 2

60 ... Receiving Sensor

In order to achieve the above object, an integrated sensor for an airbag capable of simultaneously measuring a collision detection and an acceleration amount of a vehicle of the present invention includes a housing mounted at a predetermined position of the vehicle; A guide member installed on an inner surface of the housing along a longitudinal direction of the housing; An elastic member installed at one side of the guide member; It is coupled to the elastic member so as to be slid along the guide member, the vehicle is slid in a direction to overcome the elastic force of the elastic member when the vehicle collides with a predetermined object, the elasticity when the impact amount of the vehicle is extinguished A slider member returned to the initial position by the elastic force of the member; A first ignition line installed on an upper side of the fixing member installed on the lower surface of the housing;

A plurality of second ignition lines disposed above the slider member and generating sparks in proximity to the anode ignition line when the slider member is moved; And a light receiving sensor installed on an inner surface of the upper side housing of the anode ignition wire and detecting the spark and transferring the spark to a receiver of an airbag unit installed in the vehicle.

In the present invention, the housing is characterized in that the vehicle is installed on the front side.

In the present invention, the elastic member is characterized in that the spring.

In the present invention, the first ignition line is characterized in that the anode ignition line.

In the present invention, the second ignition line is characterized in that the cathode ignition line.

In the present invention, the first ignition line and the second ignition line is characterized in that the tip portion is formed in a direction facing each other.

In the present invention, the second ignition line is characterized in that provided with at least two or more.

Hereinafter, an integrated sensor for an airbag capable of measuring a collision detection and an acceleration amount of a vehicle according to an exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various forms, and only the present embodiments are intended to complete the disclosure of the present invention and to those skilled in the art to fully understand the scope of the invention. It is provided to inform you.

1 is a plan view schematically illustrating an integrated sensor for an airbag capable of measuring both a collision detection and an acceleration amount of a vehicle according to a preferred embodiment of the present invention, FIG. 2 is a side cross-sectional view of FIG. 1, and FIG. 1 is an operation diagram showing an operating state of the collision sensor of FIG.

As shown in Figures 1 and 3, the integrated sensor 100 for the airbag capable of measuring the collision detection and the acceleration of the vehicle according to the present invention, the housing 10, and installed on the inner surface of the housing 10 The guide member 20, the elastic member 30 is installed on one side of the guide member 20, and one side is coupled to the elastic member 30, the slider member 40 sliding in the guide member 20 ), A first ignition line 50 coupled to the fixing member 13 installed on the lower surface of the housing 10, and a plurality of second ignition lines 60 provided above the slider member 40. And a light receiving sensor 60 installed at an upper side of the housing 10.

The housing 10 is installed at a predetermined position of the vehicle, preferably the front side, and a space 11 is formed therein. The space member 11 is provided with a guide member 20 along its longitudinal direction.

One side of the guide member 20 is provided with an elastic member 30, the elastic member 30 is made of a spring.

The slider member 40 is coupled to the elastic member 30.

One side of the slider member 40 is coupled to the elastic member 30 is installed to slide along the guide member 20. The guide member 20 is slid in a direction of overcoming the elastic member 30 by inertial force when the vehicle collides, and returns to the initial position by the elastic force of the elastic member 30 when the amount of impact due to the vehicle is extinguished. do.

Meanwhile, the fixing member 13 is installed on the lower surface of the housing 10, and the first ignition line 50 is installed above the fixing member 13. The installation position of the fixing member 13 is preferably located at a substantially center position in the longitudinal direction of the housing 10.

The first ignition line 50 is made of an anode ignition line having the properties of the anode.

A second ignition line 60 is installed above the slider member 40.

The second ignition line 60 is composed of a cathode ignition wire having a negative electrode property, and at least two or more.

Accordingly, as shown in FIG. 3, when the slider member 40 is slid, the second ignition line 60 is close to the first ignition line 50 to generate a spark 51. The spark 51 is detected by the light receiving sensor 70 to be described later. The first ignition line 50 and the second ignition line 60 may be bent in a direction facing each other to facilitate generation of the spark 51.

The light receiving sensor 70 is coupled to the upper housing 10 of the first ignition line 50 fixed to the housing 10. Therefore, the light receiving sensor 70 is easily installed to detect the generation of the spark 51 by the first ignition line 50 and the second ignition line 60, and the spark detection signal is not detected through the lead 61. Delivered to the airbag unit shown. Reference numeral 63 is a light receiving sensor 70 fixed portion, and 65 is a bracket.

The operation of the integrated sensor for an airbag capable of measuring the collision detection and the acceleration of the vehicle according to the present invention having the above configuration will be described.

The slider member 40 of the integrated sensor 100 for an airbag capable of measuring the collision detection and the acceleration amount of the vehicle according to the present invention is the elastic member 30 in the collision direction by the inertial force when the vehicle collides with a predetermined object. It is moved while overcoming the elastic force.

Accordingly, the first ignition line 50 fixed to the lower side of the housing 10 and the second ignition line 60 provided on the slider member 40 are close to each other to generate a spark 51. The first spark 51 generated due to this action is a collision signal of the vehicle, and the subsequent spark is recognized as a signal measuring acceleration.

This signal is sensed through the light receiving sensor 70 is transferred to the airbag unit by moving the lead 61 is to operate the airbag, by using a single sensor can simultaneously detect the collision and acceleration detection of the airbag unique The size is reduced, and the structure is operable without the influence of electromagnetic waves.

The integrated sensor for an airbag capable of measuring the collision detection and the acceleration of the vehicle according to the present invention as described above has the following effects.

First, as a single integrated sensor can detect the collision of the vehicle and the resulting acceleration, it is possible to reduce the size of the airbag unit.

Second, by detecting the collision detection and the acceleration through the detection of the spark of the first ignition line and the second ignition line, it is possible to detect the signal without being affected by the electromagnetic waves.

The present invention has been described above with reference to the embodiments shown in the drawings. However, the present invention is not limited thereto, and various modifications or other embodiments falling within the scope equivalent to the present invention are possible by those skilled in the art. Therefore, the true scope of protection of the present invention should be defined by the following claims.

Claims (7)

A housing mounted at a predetermined position of the vehicle; A guide member installed on an inner surface of the housing along a longitudinal direction of the housing; An elastic member installed at one side of the guide member; It is coupled to the elastic member so as to be slid along the guide member, the vehicle is slid in a direction to overcome the elastic force of the elastic member when the vehicle collides with a predetermined object, the elasticity when the impact amount of the vehicle is extinguished A slider member returned to the initial position by the elastic force of the member; A first ignition line installed on an upper side of the fixing member installed on the lower surface of the housing; A plurality of second ignition lines disposed above the slider member and generating sparks in proximity to the anode ignition line when the slider member is moved; And It is installed on the inner surface of the housing of the upper side of the anode ignition wire, and includes a light receiving sensor that detects the spark and transmits it to the receiving unit of the airbag unit installed in the vehicle, it is possible to measure the collision and acceleration amount of the vehicle together sensor. The method of claim 1, The housing is an integrated sensor for an airbag capable of measuring the collision detection and the acceleration of the vehicle, characterized in that the vehicle is installed on the front side. The method of claim 1, Wherein the elastic member is a spring, the integrated sensor for an airbag capable of measuring the collision detection and acceleration amount of the vehicle. The method of claim 1, The first ignition line is an anode ignition wire, the integrated sensor for an airbag capable of measuring the collision detection and the acceleration of the vehicle together. The method of claim 1, And the second ignition line is a cathode ignition line, wherein the collision detection and acceleration amount of the vehicle can be measured together. The method of claim 1, An integrated sensor for an airbag capable of measuring a collision detection and an acceleration amount of a vehicle, wherein the first and second ignition lines are bent in a direction facing each other. The method of claim 1, The second flashing line is provided with at least two or more, the integrated sensor for an air bag capable of measuring the collision detection and the acceleration amount of the vehicle.