JP2000326821A - Vehicle front body structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a vehicle front body structure such that detection of collisions can be effected precisely by means of the satellite sensor of an airbag device. SOLUTION: In this front body structure, the satellite sensor 30A of an airbag device is mounted on a vehicle front side member 48 formed of a difference thickness steel plate 52. In this case, the difference thickness steel plate 52 has a thin steel plate part 42a located at the front of the vehicle and formed to be longer at its lower side than at its upper side, and a thick steel plate part 52b located at the rear of the vehicle and formed to be longer at its upper side than at its lower side. The satellite sensor 30A is mounted on the thick steel plate part 52b of the difference thickness steel plate 52.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a front body structure of a vehicle equipped with a satellite sensor of an airbag device for protecting an occupant in the event of a vehicle collision.

[0002]

2. Description of the Related Art Conventionally, an airbag device is mounted on a vehicle to protect an occupant in the event of a vehicle collision. This airbag device includes a satellite sensor at the front of a front side member of a vehicle in order to detect a deceleration due to an offset collision at an early stage (see Japanese Patent Application Laid-Open No. 5-112195).

[0003]

The front side member of the vehicle is formed using a thick steel plate in order to reliably detect an impact by a satellite sensor. FIG. 8 is a side view of a conventional front side member (a front side member arranged on the right side of the vehicle) 100.
The front side member 100 is formed using a thick steel plate formed by a thick steel plate, that is, a thin steel plate portion 100a located on the front side of the vehicle and a thick steel plate portion 100b located on the rear side of the vehicle. It is a cylindrical member, and the thin steel plate portion 100a and the thick steel plate portion 100b are joined at a position perpendicular to the front-rear direction of the vehicle.

[0004] The satellite sensor 102 is mounted on the thin steel plate portion 100a. An extension member 104 is attached to a front portion of the thin steel plate portion 100a of the front side member 100, and a towing hook 108 is attached via a hook attachment member 106 provided on the front side member 100. I have.

However, according to the conventional front side member 100, since the strength of the portion of the front side member 100 to which the towing hook 108 is attached is high, the hook mounting member 106 and the towing hook 108 Is hard to collapse. Therefore, as shown in FIG. 9, the front side member 100 is not crushed sequentially from the front portion, but is bent at a portion having a low strength (portion indicated by a symbol A in the figure), and a high-speed ODB collision (in the case where the collision target is soft) is not performed. In some cases, it is not possible to accurately detect an impact when a “rule collision” occurs.

When a low-speed head-on collision occurs, FIG.
Since the thin steel plate portion 100a of the front side member 100 is crushed as shown in FIG.
In some cases, unnecessary impact was detected due to 02.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a vehicle front body structure capable of accurately detecting a collision by a satellite sensor of an airbag device.

[0008]

According to a first aspect of the present invention, there is provided a vehicle front body structure in which a satellite sensor of an airbag device is mounted on a front side member of a vehicle formed of a thick steel plate. So,
The differential thickness steel plate is located on the vehicle front side and has a thin steel plate portion formed with a longer lower surface side than the upper surface side, and has a longer upper surface side than the lower surface side located on the vehicle rear side. A long thick steel plate portion, wherein the satellite sensor is mounted on the thick steel plate portion of the differential thick steel plate.

According to the vehicle front body structure of the first aspect, the thin steel plate portion of the differential thickness steel plate is formed to have a longer length on the lower surface side than the upper surface side, and the satellite sensor is formed of the differential thickness steel plate. Because it is mounted on a thick steel plate, high-speed O
When a DB collision occurs, the front side members are sequentially crushed from the front, and the impact can be accurately detected by the satellite sensor. In addition, when a low-speed head-on collision occurs, the thin steel plate portion of the front side member is crushed but the thick steel plate portion is not crushed, thereby preventing the satellite sensor from detecting unnecessary impact in the case of a low-speed head-on collision. be able to.

[0010]

The first embodiment of the present invention will be described below with reference to the drawings. As shown in FIG. 1, the control device 2 of the airbag device includes an airbag device 3
6, which mainly includes a control circuit 20, satellite sensors 30A and 30B, a floor sensor 32, and a drive circuit.

Among them, the satellite sensors 30A, 30A
B is provided at the front of the vehicle, and is a mechanical sensor for detecting whether or not an impact equal to or more than a predetermined reference value is applied to the vehicle. When a deceleration equal to or greater than a predetermined reference value is applied, an internal switch is turned on to output an ON signal. In addition, the floor sensor 32
Is a so-called acceleration sensor for measuring the impact applied to the vehicle and transmitted through the vehicle body. Specifically, it measures the deceleration applied to the vehicle in the front-rear direction as needed, and sends the measured value to a signal. Output as

The control circuit 20 includes a central processing unit (CPU)
22, an input / output circuit (I / O circuit) 24, a read only memory (ROM) 26, a random access memory 28, and the like. Each component is connected by a bus. Among them, the CPU 22 performs various processes of the operation control of the airbag device 36 according to a program or the like stored in the ROM 26. The RAM 28 is a memory for storing data obtained from signals from the satellite sensors 30A and 30B and the floor sensor 32, results calculated by the CPU 22 based on the data, and the like.
Further, the I / O circuit 24 includes the satellite sensors 30A and 30A.
B, input of signal from floor sensor 32, drive circuit 34
This is a circuit for outputting an operation signal or the like.

The drive circuit 34 is a circuit for energizing and igniting the squib 38 of the inflator in the airbag device 36 according to an operation signal from the control circuit 20. Further, the airbag device 36 includes a squib 3 which is an ignition device.
8, a gas generating agent (not shown) ignited by the squib 38, a bag (not shown) expanded by the generated gas, and the like.

Among these components, the control circuit 20, the floor sensor 32 and the drive circuit 34 correspond to the ECU shown in FIG.
(Electronic control unit) 44, which is mounted on a floor tunnel substantially in the center of the vehicle 46. The satellite sensor 30A is disposed on the front side member obliquely to the front right of the floor sensor 32 in the ECU 44, and the satellite sensor 30B is disposed on the front side member obliquely to the front left of the floor sensor 32. Has been established. Here, the front side member is the vehicle 4
6 is a rectangular cylindrical member extending in the front-rear direction, and is formed to be easily axially compressed in order to absorb a shock at the time of collision.

FIG. 3 is a side view of a front side member (front side member disposed on the right side of the vehicle) 48,
FIG. 4 is a perspective view of the front side member 48. The front side member arranged on the left side of the vehicle is
The description is omitted because it has a symmetrical shape with the front side member 48.

The front side member 48 is formed by welding a steel plate 50 having a uniform thickness disposed on the side surface of the vehicle and a differential steel plate 52 having a U-shape and disposed inside the vehicle. Is formed. Here, the difference thickness steel plate 52
The thin steel plate portion 52a is located on the front side of the vehicle and has a lower side longer than the upper side, and the upper side is longer on the rear side of the vehicle than the lower side. A thick steel plate portion 52b, and a connecting portion between the thin steel plate portion 52a and the thick steel plate portion 52b is formed in a step shape. Further, the satellite sensor 30A is mounted on the thick steel plate portion 52b.
The thin steel plate portion 52a of the front side member 48
An extension member 54 is attached to a front portion of the front side member 48, and a towing hook 58 is attached via a hook attachment member 56 provided on the front side member 48.

FIG. 5 is a diagram showing a deformed state of the front side member 48 when a high-speed ODB collision occurs on the vehicle 46. When a high-speed ODB collision occurs in the vehicle 46, since the strength of the upper surface side and the lower surface side of the front side member 48 is balanced, the thin steel plate portion 52a of the front side member 48 is crushed and the thick steel plate portion 52b is formed.
Crushed sequentially from the front. Therefore, the satellite sensor 30
A can accurately detect the impact of the collision, and a detection signal is input to the control circuit 20 via the I / O circuit 24. The control circuit 20 lowers a threshold value for comparing with a detection value of the floor sensor 32 to determine whether to activate the airbag device in response to the input of the ON signal input from the satellite sensor 30A. When the detected value of the floor sensor 32 exceeds the threshold value, the drive circuit 34 energizes the squib 38 of the airbag device 36 to operate the inflator and operate the airbag device 36.
Therefore, in the case of a high-speed ODB collision, the airbag device can be operated accurately.

FIG. 6 is a view showing a deformed state of the front side member 48 when a low-speed head-on collision occurs in the vehicle 46. When a low-speed collision occurs in the vehicle 46, the thin steel plate portion 52a of the front side member 48 is crushed, but the thick steel plate portion 52b is not crushed. Therefore, since the satellite sensor 30A does not detect unnecessary impact and does not lower the threshold value for determining whether to activate the airbag device, the airbag device 36 can be used in a low-speed head-on collision. Actuation can be prevented.

Next, a satellite sensor mounting structure for an airbag device according to a second embodiment of the present invention will be described. The front side member 60 according to the second embodiment
In the first embodiment, the connecting portion between the thin steel plate portion 52a and the thick steel plate portion 52b of the thick steel plate 52 of the front side member 48 of the first embodiment is changed to the shape shown in FIG. That is, also in the front side member 60, the length of the thin steel plate portion 52a is formed longer on the lower surface side than that of the upper steel plate portion.
b has a longer upper surface side than the lower surface side.

Therefore, also in this front side member 60, when a high-speed ODB collision occurs in the vehicle 46, the thin steel plate portion 52a of the front side member 48 is crushed and the thin steel plate portion 52b is sequentially crushed from the front portion. Therefore, the impact of the collision can be accurately detected by the satellite sensor 30A. When a low-speed head-on collision occurs in the vehicle 46, the thin steel plate portion 52a of the front side member 48 is crushed, but the thick steel plate portion 52b is not crushed. Therefore, unnecessary impact is not detected by the satellite sensor 30A.

[0021]

According to the present invention, the thickness of the thin steel plate portion of the differential thickness steel plate is longer than that of the upper surface side, and the satellite sensor is mounted on the thick steel plate portion of the differential thickness steel plate. Therefore, when a high-speed ODB collision occurs, the front side members are sequentially crushed from the front and the impact can be accurately detected by the satellite sensor. In addition, when a low-speed head-on collision occurs, the thin steel plate part of the front side member is crushed but the thick steel plate part is not crushed, thereby preventing the satellite sensor from detecting unnecessary impact in the case of a low-speed head-on collision. be able to.

[Brief description of the drawings]

FIG. 1 is a block configuration diagram of a control device of an airbag device according to a first embodiment.

FIG. 2 is a diagram for explaining a vehicle mounting position of the satellite sensor according to the first embodiment.

FIG. 3 is a side view of the front side member on which the satellite sensor according to the first embodiment is mounted.

FIG. 4 is a perspective view of a front side member on which the satellite sensor according to the first embodiment is mounted.

FIG. 5 is a diagram showing a deformed state of the front side member according to the first embodiment.

FIG. 6 is a diagram showing a deformed state of the front side member according to the first embodiment.

FIG. 7 is a side view of a front side member on which a satellite sensor according to a second embodiment is mounted.

FIG. 8 is a side view of a CFC side member on which a conventional satellite sensor is mounted.

FIG. 9 is a view showing a deformed state of a conventional front side member.

FIG. 10 is a view showing a deformed state of a conventional front side member.

[Explanation of symbols]

2 ... Control device for airbag device, 20 ... Control circuit, 30
A, 30B: satellite sensor, 32: floor sensor,
34 drive circuit, 36 airbag device, 44 EC
U, 46: Vehicle, 48: Front side member, 52:
Different thickness steel plate.

Claims (1)

[Claims] 1. A front body structure of a vehicle in which a satellite sensor of an airbag device is mounted on a front side member of a vehicle formed of a thick steel plate, wherein the thick steel plate is located on a front side of the vehicle and has an upper surface. A thin steel plate portion having a longer lower surface side than the lower steel plate portion and a thicker steel plate portion located on the vehicle rear side and having a longer upper surface side than the lower surface side; A front body structure of a vehicle, wherein a sensor is mounted on a thick steel plate portion of the thick steel plate.