JP4000519B2 - Vehicle collision object discrimination device - Google Patents

Description

[0001]
[Technical field to which the invention belongs]
The present invention relates to a vehicle collision object discrimination device that discriminates the type of a collision object that collides with a vehicle.
[0002]
[Prior art]
When a pedestrian collides with a vehicle, the head or the like collides with a hood or windshield, resulting in serious injury. In particular, a pedestrian protection device that lifts the hood or deploys an air bag on the hood has been proposed because there is a structure such as an engine under the hood and the injury is large.
[0003]
In such a pedestrian protection device, it is determined whether or not the collision is for a pedestrian, including that the device operation narrows the driver's forward field of view, and this pedestrian protection device is only used when it is determined to be a pedestrian. There is a desire to operate.
[0004]
As such a pedestrian collision detection technique, a pedestrian determination technique for determining whether a person is a pedestrian based on a collision load detected by an acceleration sensor provided on a vehicle body (for example, a side member) or a deformation amount corresponding to the collision load has already been proposed. ing. For example, Patent Document 1 proposes to separate a pedestrian from other collision bodies using a collision impact force (that is, a collision load or a deformation amount corresponding to the collision load), its duration, and a vehicle speed. Patent Document 2 proposes to use the amount of deformation at the time of a collision, its change over time, and the vehicle speed. In both cases, it is estimated from the change in the waveform of the collision impact force that the leg will move away from the bumper immediately after the collision and the impact impact force (load and deformation) will decrease due to the pedestrian crashing phenomenon. ing.
[0005]
[Patent Document 1]
Japanese Patent Laid-Open No. 11-028994
[Patent Document 2]
JP 11-310095 A
[0006]
[Problems to be solved by the invention]
However, the present inventors have found that the peak value of the collision impact force described above and its temporal change differ depending on the collision position in the left-right direction despite the collision under the same conditions, and as a result, the collision occurs due to the variation in the left-right collision position. We found a phenomenon in which the accuracy of conventional pedestrian determination, which is based on the peak value of impact force and changes over time, is significantly reduced.
[0007]
According to the inventors' further investigation on this phenomenon, this is presumed to be due to the following reason. First, when a collision impact force is detected by an acceleration sensor fixed to a side member, the rigidity toward the rear in the foremost part of the vehicle body (hereinafter referred to as rear rigidity) is not uniform in each part in the left-right direction. As is well known, since the vehicle body has strength members called side members that extend in the front-rear direction at predetermined intervals in the left-right direction, there is little deformation on the vehicle body side due to a collision in the vicinity of this side member, The deformation on the vehicle body side increases as the distance from the side member increases. As a result, even in the case of a collision under the same conditions, the peak value of the collision impact force waveform that occurs in the vicinity of the side member is high, the attenuation is rapid, and the collision that occurs in a collision away from the side member The peak value of the impact force waveform is low, and the attenuation is gradual.
[0008]
Next, when a collision occurs in the vicinity of one of the side members, a large component of the collision impact force is applied to the side member near the collision position, and a small impact force is applied to the side member far from the collision position. Component force is transmitted. However, when the collision occurs at an intermediate position between the two side members (that is, the central portion in the left-right direction of the vehicle body), the ratio of the two collision impact forces transmitted to both the side members is substantially equal. That is, since the component ratio of the collision impact force transmitted to the side member changes depending on the collision position, the peak value of the collision impact force output from the acceleration sensor or its change over time (the time during which the collision impact force is equal to or greater than the predetermined value). In the conventional pedestrian discrimination method based on (1), a large accuracy drop occurs.
[0009]
In order to remedy this problem, it is conceivable to provide a large number of collision impact force detection sensors in each of the left and right parts of the bumper. However, this measure significantly increases the cost compared to providing the acceleration sensor on the side member. Is expected to. In other words, one or two acceleration sensors provided on the side member or the vehicle body are conventionally used for activating an airbag for protecting an occupant. Therefore, the acceleration sensor for protecting the occupant may be used. On the other hand, arranging a large number of sensors having the same collision impact force detection function on the bumper increases the cost significantly, and is not realistic in the vehicle manufacturing technology that demands cost reduction.
[0010]
SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and is a vehicle pedestrian discrimination direction and a vehicle pedestrian capable of accurately discriminating a pedestrian regardless of a change in the impact impact force waveform caused by a vehicle body lateral collision position. The purpose is to realize the discriminating apparatus while suppressing an increase in cost.
[0011]
[Means for Solving the Problems]
The collision object discriminating device for a vehicle according to the present invention is installed in a vehicle body and has a collision impact caused by a collision of the collision object with the vehicle body. Power An impact detection element to detect, Each has a different impact impact range The type of the collision object Separately Any of the allocated areas Impact force value Determine if the file belongs for Having a discrimination criterion, and input from the impact force detection element Impact impact force A collision object type determination element for determining the area by comparing the determination object with the determination criterion, and outputting the type of the collision object assigned to the determined area as a determination result; ,car A collision part detection element that is mounted on both sides and detects a collision position of the collision body in the left-right direction of the vehicle body, and a determination reference change element that changes the determination reference based on the detected collision position. In the vehicle collision object determination device, the collision object type determination element compares the collision impact force with a predetermined collision impact force value as the determination reference, and the impact force detection element is a pair of vehicle bodies. A pair of acceleration sensors individually fixed to the front end portion of the side member, and the discrimination reference changing element is configured such that when the collision position is a lateral end portion of the vehicle body front portion, the collision position is the vehicle body The predetermined collision impact force value as the discriminating reference is increased as compared with the case where the front portion is the central portion in the left-right direction. It is characterized by that.
[0012]
In other words, the present invention compensates for the variation in the collision impact force due to the change in the collision position in the left-right direction by changing the discrimination criterion for each collision position, so the collision impact force due to the change in the collision position in the left-right direction. Despite this variation, it is possible to determine the collision object type based on the collision impact force.
[0013]
The impact force detection element may be provided in any part of the vehicle body as long as it can detect a collision impact force. However, preferably, the impact force detection element is also used in the operation of a conventional occupant protection device when provided near each side member. Therefore, it is particularly suitable in terms of simplification of the configuration.
[0014]
The collision object type discrimination element compares the input electric quantity related to the collision impact force with the discrimination criterion which is preferably the threshold value. In addition to the peak value of the impact impact force, the time when the impact impact force is greater than the predetermined threshold, etc., the deceleration as the integral value of the impact impact force, the impact energy as the double integral value of the impact impact force, etc. The following parameters can be adopted.
[0015]
In addition, although it changes according to the vehicle speed, a predetermined band component of the collision impact force can also be adopted. More specifically, a waveform of a collision impact force between a collision object and a vehicle at a predetermined vehicle speed has a frequency component having a correlation with the rigidity, mass, and collision position in the left-right direction of the collision object. Therefore, if the vehicle speed and the collision position can be specified, the rigidity and mass of the collision object can be estimated, and thereby the type of the collision object can be specified. For example, the body of a pedestrian is relatively soft, the rigid body is very hard, and the waveform of the impact impact force that is generated is different, so the type of collision object is determined based on the generated frequency component and rising waveform at the time of collision Can do. However, even in this frequency discrimination, the technique of the present invention that removes changes in the frequency and rising waveform due to the collision position of the collision object is particularly important. For example, as a discrimination criterion, a threshold value for the magnitude of the collision impact force and a threshold value for the decay time can be adopted. At this time, only a predetermined frequency component of the collision impact force is extracted and used in the present invention. The amount of electricity can be used, and the band to be extracted can be changed based on the vehicle speed or the collision position. Naturally, one area classified according to the discrimination criterion is an area corresponding to a collision with a pedestrian.
[0016]
In the present invention, The collision object type discrimination element is a collision impact Power , Predetermined impact impact force By value It is compared with a certain discrimination criterion. That is, in this mode, the type of the collision object is determined by comparing the magnitude of the collision impact force in the collision impact force waveform with a determination criterion that is a threshold value corresponding to the collision impact force value of a predetermined magnitude. To do. Thereby, as described above, the type of the collision object can be easily and accurately determined.
[0017]
In the present invention, The impact force detection element includes a pair of side members. Front edge A pair of acceleration sensors individually fixed to Have Thereby, as described above, this pair of acceleration sensors can be shared with an acceleration sensor (also referred to as a G sensor) for operating an occupant protection device, and the device configuration can be simplified.
[0018]
In a preferred aspect, the collision site detecting element is a pair of resistors that are fixed to the bumper at predetermined intervals and extend in the left-right direction, and are in electrical contact with each other at the collision position where the collision object collides. And a calculation circuit that determines the collision position based on a potential change between the resistance plates. According to this aspect, the collision position can be detected with high accuracy by a simple device. Since this collision site detection element has already been described in detail in the prior application of the present applicant, detailed description thereof will be omitted in this specification.
[0019]
In a preferred aspect, the collision site detection element determines the collision position based on a difference between output waveforms of the pair of acceleration sensors. That is, due to the change in the collision site, the waveform of the collision impact force detected by the two acceleration sensors individually fixed in the vicinity of the pair of side members differs for the two reasons already described. This is based on the impact impact force waveform output by these two acceleration sensors or a function thereof (for example, deceleration as an integral value, impact energy as a double integral value, amplitude (peak to peak), predetermined frequency component, etc.). This means that the collision position in the left-right direction can be determined on the basis of this. For example, the difference in the magnitude of the collision impact force has a strong correlation with the fluctuation of the collision position in the left-right direction, and the output signal waveform of the left acceleration sensor is relatively larger than that on the right side. Conversely, the fact that the output signal waveform of the right acceleration sensor is relatively larger than that of the left side indicates that the collision is on the right side, and the difference in the magnitude of the output signal waveforms of both acceleration sensors is small. This means that the collision position is the central portion in the left-right direction. Further, the rigidity of the vehicle between the collision site and the acceleration sensor has a correlation with the attenuation of the high frequency component of the collision impact force detected by the acceleration sensor. For example, when the magnitude of the high frequency component (or the predetermined band component corresponding to the vehicle speed) in the output signal waveform of the left acceleration sensor is relatively larger than that on the right side, this indicates that the collision is on the left side. A small difference in the magnitude of the high frequency component (or the predetermined band component corresponding to the vehicle speed) in the output signal waveform of the acceleration sensor means that the collision position is in the center in the left-right direction.
[0020]
In a preferred embodiment, the collision object type determination element sets the determination criterion for the magnitude of the collision impact force higher when the collision position is close to the impact force detection element than when the collision position is separated. That is, as described above, the closer the collision position in the left-right direction is, the larger the magnitude of the detected collision impact force is, so the influence is reduced by increasing the threshold value. It should be noted that changing the threshold value as the discrimination criterion is substantially the same as changing the collision impact force compared with this threshold value. In the collision object type determination based on the collision impact force, a threshold value for the time and frequency of the collision impact force can be employed in addition to the determination based on the magnitude of the collision impact force.
[0021]
In a preferred aspect, the collision object type determination element sets a collision object determination criterion for the magnitude of the collision impact force higher than when the collision position is in the vicinity of the side member and away from the side member. As a result, as described above, it is possible to satisfactorily compensate for the change in the magnitude of the detected collision impact force due to the shift of the collision position in the left-right direction from the side member.
[0022]
In a preferred embodiment, the car Speed It has a vehicle speed sensor to detect, and the collision object type determination element sets the collision object determination reference high when the vehicle speed is high, and lowers the collision object determination reference when the vehicle speed is low. Thereby, the determination accuracy can be further improved.
[0023]
In a preferred aspect, the collision object type determination element calculates a deceleration that is an integral value of the acceleration, and a relationship between the acceleration, the deceleration, and the collision object determination criterion. In addition, Substituting the detected acceleration and deceleration to determine the collision object discrimination criterion. Thereby, the determination accuracy can be further improved.
[0024]
BEST MODE FOR CARRYING OUT THE INVENTION
Example 1
A preferred embodiment of a vehicle safety device using the vehicle collision object discrimination device of the present invention will be described below with reference to FIG.
[0025]
(overall structure)
The vehicle safety device includes an impact force detection sensor (impact force detection element) 1, a collision position detection sensor (collision site detection element) 2, a controller (a collision object type determination element, a determination reference change element) 3, and an occupant protection device 4. And the pedestrian protection device 5.
As shown in FIGS. 2 and 3, the impact force detection sensor 1 includes a right acceleration sensor 11 fixed to the right side member and a left acceleration sensor 12 fixed to the left side member. These impact force detection sensors 1 are generated in the bumper when a collision object collides with the bumper, and then the bumper force and the vehicle front-rear direction corresponding to the component force of the collision impact force transmitted through the side member to which the self is fixed. Detect acceleration. Of course, the fixed position of the acceleration sensor may be not only on the side member but also on a member (for example, a radiator support) that is directly connected to the side member.
[0026]
As shown in FIG. 2, the collision position detection sensor 2 is supported by the bumper with a small predetermined interval in the front-rear direction and extends in the left-right direction, and is electrically connected to each other at the collision position where the collision object collides. A pair of resistor plates in contact with each other and an arithmetic circuit for determining a collision position based on a potential change between these resistor plates are provided. In this embodiment, since this arithmetic circuit is included in a controller which will be described later, the collision position detection sensor 2 supplies the power supply voltage to the resistor plate pair, the resistor element or constant current source attached thereto, and the resistor plate. A voltage source to be supplied. Such a collision position detection sensor has already been described in detail in a prior application (for example, Japanese Patent Publication No. 2002-277908) filed by the present applicant, and therefore, detailed description thereof will be omitted in this specification. And It is also preferable to make the conductive plate by greatly reducing the specific resistance value of one of the resistance plates. For example, as disclosed in the above publication, a predetermined constant potential is applied to one end of the pair of resistor plates, and another constant potential is applied to the other end of the pair of resistor plates through a resistance element or a constant current source. When a potential change at the end of the resistance plate is detected, a potential change that changes in conjunction with the collision position can be obtained.
[0027]
The controller 3 converts a voltage proportional to the collision impact force input from the sensors 1 and 2 and a voltage corresponding to the collision position into digital signals, respectively, to obtain a collision impact force signal and a collision position signal. The collision type is determined by computing with a microcomputer.
[0028]
The occupant protection device 4 includes a normal occupant protection airbag device, and the pedestrian protection device 5 includes a pedestrian protection airbag mounted on a hood. It is good to adopt an up device.
[0029]
Hereinafter, the collision object type determination routine executed by the controller 3 will be described with reference to the flowchart shown in FIG. In addition, since the process which determines a collision position from the signal voltage output from the collision position detection sensor 2 by the controller 3 is disclosed by the said gazette, description shall be abbreviate | omitted. Of course, the collision position detection sensor 2 may be other than the type using the pair of resistance plates. For example, it is obvious that a number of pressure detection switches may be attached to the bumper at predetermined intervals.
[0030]
(Explanation of collision object type discrimination routine)
In FIG. 7, first, it is detected from the output change of the collision position detection sensor 2 whether or not a collision has occurred (S100). The collision position detection sensor 2 has a specific value for the output signal voltage to indicate the collision position when no collision occurs. When the collision occurs, the collision position detection sensor 2 has a value different from the specific value and corresponding to the collision position. In order to generate an output signal voltage, the presence or absence of a collision is detected together with the collision position.
[0031]
If a collision is detected, the impact force and the collision position are read from the right acceleration sensor 11, the left acceleration sensor 12, and the collision position detection sensor 2, respectively (S102), and the acceleration within a predetermined period after the collision is read from the two acceleration signals read. A peak value Gmax is calculated, and a threshold Gth is obtained based on the collision position (S104).
[0032]
More specifically, in this embodiment, when a peak value of an acceleration signal having a magnitude equal to or greater than a predetermined threshold level is detected, all acceleration signals read from these two acceleration sensors 11 and 12 within a predetermined period are detected. The largest peak value is held as the maximum acceleration value Gmax. In addition, a table indicating the relationship between the collision object type determination threshold (acceleration determination threshold) Gth for each collision position and the collision position is stored in advance, and the collision position X detected this time is substituted into this table. Then, a threshold value Gth that is preferably used at the collision position is determined.
[0033]
Next, it is determined whether or not the maximum acceleration value Gmax is larger than the threshold value Gth (S106). If it is large, it is determined as a heavy body (fixed object) (S108). (S110). The operation of the pedestrian protection device 5 is commanded only when it is determined as a pedestrian. Note that the operation control of the occupant protection device 4 using the acceleration sensors 11 and 12 is different from the above and is not the gist of the present invention, and thus the description thereof is omitted.
[0034]
(Changes in peak value of impact impact force depending on impact location)
Next, compensation for the change in the peak value of the collision impact force depending on the collision position by the execution of the collision object type determination routine will be described with reference to FIGS.
[0035]
FIG. 3 is a schematic diagram showing a case where a rigid body collides with the right front portion of the vehicle. FIG. 4 shows an output waveform (a) of the right acceleration sensor 11 and an output waveform (b) of the left acceleration sensor 12 at the time of the collision shown in FIG. FIG. 5 is a schematic diagram showing a case where the rigid body collides with the center of the vehicle. FIG. 6 shows an output waveform (a) of the right acceleration sensor 11 and an output waveform of the left acceleration sensor 12 at the time of the collision in FIG. b).
[0036]
When the rigid body (fixed object) collides with the right front part of the bumper (see FIG. 3), as can be seen from FIG. 4, the peak value of the acceleration (collision impact force) output from the right acceleration sensor 11 is the left acceleration sensor. Therefore, the peak value of the collision impact force (front-rear direction acceleration) output by the right acceleration sensor 11 is adopted as the maximum acceleration value Gmax. Preferably, the maximum acceleration value Gmax is determined as the maximum acceleration value Gmax among the peak values generated within a predetermined measurement period after first detecting a peak value exceeding a predetermined peak value determination threshold value. . The reason why the peak value occurs many times in this way is that the side member vibrates due to the collision, and the peak value at the third to fifth times is the largest compared to the initial peak value. In addition, in order to avoid the extension of the time required for pedestrian determination, the predetermined measurement period should not be set so long. Naturally, when a rigid body (fixed object) collides with the left front part of the bumper, the reverse is true.
[0037]
Next, when the rigid body (fixed object) collides with the central portion in the left-right direction of the bumper (see FIG. 5), as can be seen from FIG. 6, the peak value of the acceleration (collision impact force) output by the right acceleration sensor 11 is obtained. As compared with FIG. 4, the peak value output by the right acceleration sensor 11 is lower than that output by the left acceleration sensor 12. This is because, as described above, the collision impact force transmitted to the right side member is reduced by increasing the deformation amount of the bumper force and evenly distributing the collision impact force to the two side members. Therefore, a large value is adopted as the threshold value Gth in the collision examples of FIGS. 3 and 4, and a small value is adopted as the threshold value Gth in the collision examples of FIGS. 5 and 6.
[0038]
By doing so, it is possible to reduce the influence of the fluctuation of the peak value of the collision impact force due to the fluctuation of the collision position, and to accurately perform the collision object type discrimination based on the magnitude of the peak value. Note that the vehicle speed in FIGS. 4 and 6 is 15 km / h.
(Modification)
In the above embodiment, the collision object type is determined based on the magnitude of the peak value of the collision impact force. In addition or in addition, the collision is performed based on the acceleration change speed and the duration of the collision impact force exceeding a predetermined level. A value corresponding to energy may be calculated, and the mass and rigidity of the collision object may be determined by comparison with thresholds corresponding to the values, so as to determine whether the person is a pedestrian.
[0039]
More specifically, if the square value of the acceleration output from the acceleration sensor in the immediately preceding predetermined period is integrated, the vibration energy generated by the collision can be obtained, so this vibration energy is compared with a predetermined threshold, What is necessary is just to determine whether it is a collision.
(Example 2)
In the case of a pedestrian, since the walking speed is lower than that of the vehicle, the collision speed can be regarded as substantially equal to the own vehicle speed. Since the weight of the pedestrian can be limited within a certain range, the collision energy when the pedestrian collides from the vehicle speed of the own vehicle can be estimated within the range corresponding to the weight. In other words, the collision object can be identified with higher accuracy by changing the reference for the pedestrian with respect to the acceleration output from the acceleration sensor, that is, the threshold value according to the collision position and the vehicle speed. Since the collision energy increases as the host vehicle speed increases, the threshold value should be increased. When the host vehicle speed is low, the threshold value should be decreased.
[0040]
That is, the vehicle speed is also read in step S202 shown in FIG. 8, and in step S204, a map showing the relationship between the vehicle speed V stored in advance, the collision position X, and the collision object type determination threshold (acceleration determination threshold) Gth. A suitable threshold value Gth at the vehicle speed V is obtained by substituting the vehicle speed V and the collision position X, and the obtained threshold value Gth is compared with the maximum acceleration value Gmax (S206). Thereby, the determination accuracy can be further improved.
(Example 3)
Further, the threshold value (acceleration determination threshold) Gth for the collision object type determination is changed by the sum (namely, deceleration) ΔV of the speed change amount that is the value obtained by integrating the acceleration G for the immediately preceding predetermined period. Also good. That is, the absolute value of the sum (ie, deceleration) ΔV of the speed change amounts is very large if the collision body is a rigid body having a large mass (for example, a fixed object), and is small if the collision body is a pedestrian. More specifically, in a collision with a rigid body, the vehicle changes from the traveling vehicle speed value to the vehicle speed 0 in a very short deceleration time, and the acceleration vibrates within this deceleration time, so that the acceleration G is summed up by the speed change amount ( That is, the amount of electricity G / ΔV divided by ΔV is a large value, and in the case of a pedestrian, it is lightweight and flexible, so this amount of electricity G / ΔV is a small value.
[0041]
Therefore, by substituting ΔV into a table indicating the relationship between the sum of speed change amounts (ie, deceleration) ΔV stored in advance and the threshold value (acceleration determination threshold) Gth for collision object type determination determination, this decrease A threshold (acceleration determination threshold) Gth suitable for collision object type discrimination determination with respect to the speed ΔV is obtained, and the obtained threshold (acceleration judgment threshold) Gth for collision object type discrimination determination and the detected acceleration G are obtained. And a fixed object and a pedestrian may be distinguished.
[0042]
This control routine is shown in FIG. In this embodiment, the collision object type determination routine of the first embodiment shown in FIG. 7 is partially changed.
[0043]
In FIG. 9, first, it is detected from the output change of the collision position detection sensor 2 whether or not a collision has occurred (S100).
[0044]
If a collision is detected, the impact force and the collision position are read from the right acceleration sensor 11, the left acceleration sensor 12, and the collision position detection sensor 2, respectively, and the vehicle speed of the host vehicle is detected from a vehicle speed sensor (not shown) as described in the second embodiment. Is read (S202).
[0045]
Next, in step S304, an acceleration peak value Gmax within a predetermined period after the collision is calculated from the read two acceleration signals. Further, the two accelerations G read from the respective acceleration sensors 11 and 12 are respectively integrated for the predetermined period immediately before to obtain the sum (ie, deceleration) ΔV of the speed change amount separately for each acceleration sensor 11 and 12. The sum (ie, deceleration) ΔV of the speed change amounts of the acceleration sensor that selects the peak value of G (the peak value is larger) is selected. Further, the read collision position X is displayed on a map showing the relationship between the collision position X, the vehicle speed V, the sum of speed changes (ie, deceleration) ΔV and the threshold value (acceleration determination threshold) Gth for collision object type determination. And the vehicle speed V and the sum (namely, deceleration) ΔV of the speed change amount are substituted, and a suitable collision object type discrimination for the current collision position X, the vehicle speed V, and the sum (namely, deceleration) ΔV of the speed change amount is substituted. A determination threshold value (acceleration determination threshold) Gth is obtained.
[0046]
Next, the obtained threshold value (acceleration determination threshold) Gth for collision object type determination determination is compared with the acceleration peak value Gmax selected above (S306), and the acceleration peak value Gmax is equal to or greater than the threshold value Gth. If so, it is determined as a fixed object (S308), and if it is less than that, it is determined as a pedestrian (S310).
[0047]
(Relationship between X, ΔV, and threshold Gth)
FIG. 10 shows changes in acceleration G and the sum of speed change amounts (ie, deceleration) ΔV when a fixed object collides with the right front portion of the vehicle at a predetermined vehicle speed. FIG. 11 shows a pedestrian in the right front portion of the vehicle. Shows the change of the acceleration G and the sum (ie, deceleration) ΔV of the speed change amount when the vehicle collides at the same vehicle speed. The acceleration is a two-dimensional curve that starts from the origin coordinates (0, 0) on the G-ΔV plane by the longitudinal vibration of the side member in the front-rear direction, and finally returns to the origin coordinates. Therefore, if the threshold value Gth is set with respect to ΔV as shown in FIGS. 10 and 11, the fixed object and the pedestrian can be well separated.
[0048]
FIG. 12 shows changes in acceleration G and the sum of speed changes (ie, deceleration) ΔV when a fixed object collides with the center of the vehicle at the same vehicle speed. FIG. A change in acceleration G and the sum (ie, deceleration) ΔV of the amount of change in speed when the vehicle collides is shown. The acceleration is a two-dimensional curve that starts from the origin coordinates (0, 0) on the G-ΔV plane by the longitudinal vibration of the side member in the front-rear direction, and finally returns to the origin coordinates. At this time, if the threshold value Gth is set with respect to ΔV as shown in FIGS. 12 and 13, the fixed object and the pedestrian can be well separated.
[0049]
That is, if the threshold value Gth is changed at the collision position X as shown in FIGS. 10, 11 to 12, 13, the change in G with respect to ΔV due to the change in the collision position X can be compensated well. .
(The invention's effect)
The effect when the collision object is identified in the first embodiment and used for the operation of the occupant protection device will be described. In the conventional collision detection by acceleration detection, the output of the acceleration sensor immediately after the collision and the output when traveling on a rough road can be distinguished in a collision mode in which acceleration is unlikely to occur at the beginning of the collision when the utility pole collides near the center of the vehicle. There was a problem that the judgment was delayed because it was not connected. However, according to the present invention, by detecting the collision position at the same time as the collision with the sensor based on the contact load, it is possible to know the collision start time and the acceleration due to the collision is low. The rest can be distinguished at a quick stage.
[0050]
In addition, it is difficult to discriminate between a human pole and a power pole when the power pole collides with the center of the vehicle at a low speed and when a human collides with the side member at a high speed. In some cases, the above problem can be solved by increasing the threshold when the collision occurs with the side member by knowing the collision position.
[0051]
If the vehicle speed is added and discriminated as in the second and third embodiments, for example, the position where the vehicle collides with a vehicle, a power pole, etc. at a low speed and the case where it collides with a pedestrian at a high speed is accurate. It becomes possible to distinguish well.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration of an apparatus according to a first embodiment.
FIG. 2 is a perspective view showing the sensor arrangement of FIG. 1;
FIG. 3 is a schematic cross-sectional view showing a collision with a right front portion of a vehicle.
4 is a diagram showing an acceleration waveform in FIG. 3; FIG.
FIG. 5 is a schematic cross-sectional view showing a collision with a vehicle central portion.
6 is a diagram showing an acceleration waveform in FIG. 5. FIG.
FIG. 7 is a flowchart illustrating a pedestrian determination routine according to the first embodiment.
FIG. 8 is a flowchart illustrating a pedestrian determination routine according to the second embodiment.
FIG. 9 is a flowchart illustrating a pedestrian determination routine according to the third embodiment.
FIG. 10 is a diagram illustrating a relationship between acceleration G and a speed change amount.
FIG. 11 is a diagram illustrating a relationship between acceleration G and a speed change amount.
FIG. 12 is a diagram showing the relationship between acceleration G and speed change amount.
FIG. 13 is a diagram showing a relationship between acceleration G and a speed change amount.
[Explanation of symbols]
1 Impact force detection sensor (impact force detection element)
2 Collision position detection sensor (collision site detection element)
3 Controller (impact object type discriminating element, discrimination standard changing element)
4 Crew protection device
5 Pedestrian protection device

Claims (7)

An impact force detection element that is installed in the vehicle body and detects a collision impact force caused by a collision of a collision object with the vehicle body;
The impact force detection has a discrimination criterion for determining which of a plurality of areas each having a different impact impact force range and differently assigned types of impact bodies belong to the impact impact force value. The collision impact force input from an element is compared with the determination criterion to determine the area, and the collision object type determination element that outputs the type of the collision object assigned to the determined area as a determination result ;
A collision part detection element that is mounted on a vehicle and detects a collision position of the collision body in the left-right direction of the vehicle body;
A discrimination criterion changing element for changing the discrimination criterion based on the detected collision position;
In a vehicle collision object discrimination device comprising:
The collision object type determination element compares the collision impact force with a predetermined collision impact force value as the determination criterion,
The impact force detecting element has a pair of acceleration sensors individually fixed to front end portions of the pair of side members of the vehicle body,
When the collision position is the left and right end portion of the front portion of the vehicle body, the determination criterion changing element is more preferable than the case where the collision position is the central portion of the front portion of the vehicle body. A vehicle collision object discriminating apparatus characterized by increasing a predetermined collision impact force value . In the vehicle collision object discrimination device according to claim 1,
The collision site detection element is
A pair of resistance plates that are fixed to the bumper at a predetermined interval and extend in the left-right direction, and are in electrical contact with each other at the collision position where the collision object collides,
A vehicle collision object discriminating device comprising: an arithmetic circuit that determines the collision position based on a potential change between the resistance plates. In the vehicle collision object discrimination device according to claim 1,
The collision object type determination element sets the determination criterion for the magnitude of the collision impact force higher than that when the collision position is far away when the collision position is close to the impact force detection element. Body discrimination device. In the vehicle collision object discrimination device according to claim 1 ,
The vehicle according to claim 1, wherein the collision object type determination element sets a collision object determination reference for the magnitude of the collision impact force higher than when the collision position is in the vicinity of the side member and away from the side member. Collision object discrimination device. In the vehicle collision object discrimination device according to claim 1,
A vehicle speed sensor for detecting a vehicle speed,
The vehicle collision object determination device, wherein the collision object type determination element sets the collision object determination reference high when the vehicle speed is high, and lowers the collision object determination reference when the vehicle speed is low. In the collision object discriminating device for vehicles according to claim 3 ,
A vehicle speed sensor for detecting a vehicle speed,
The vehicle collision object determination device, wherein the collision object type determination element sets the collision object determination reference high when the vehicle speed is high, and lowers the collision object determination reference when the vehicle speed is low. In the vehicle collision object discrimination device according to claim 1,
The collision body type determining element calculates the deceleration is the integral value of the acceleration, said by substituting the acceleration and the deceleration and the acceleration and the deceleration relationship with the collision object determination reference A vehicle collision object discriminating apparatus for obtaining a collision object discrimination standard.

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