LU90417A1 - Passenger detector test equipment - Google Patents

Abstract

Test equipment 10 for testing a passenger detector, comprising an internal structure 12 of rigid material, the said internal structure corresponding to a first element 16 with a shape similar to a pelvis, particularly the pelvis of a person having a given height, and a second element 18 and a third element 20, each of a shape similar to the upper part of a femur of said person, the said first, second and third elements being assembled together so as to simulate a portion of the skeleton of a seated person. The test equipment of the present invention furthermore comprises a coating 14 of elastic material which covers the said first, second and third elements of the internal structure 12 and has an external shape similar to the buttocks and thighs of the said person.<IMAGE>

Description

Test tool

Introduction

The present invention relates to a test tool used in particular for testing and calibrating passenger sensors of a vehicle protection system.

In order to protect the lives of passengers during a traffic accident, modern vehicles are most often fitted with a protection system comprising several airbags and seatbelt pretensioners, which are used to absorb the energy of a passenger released during the crash. It is clear that such systems are all the more effective as they are better adapted to the specific needs of each passenger, that is to say to the weight and / or the size of the passenger. This is why microprocessor-controlled protection systems have been perfected which allow several operating modes, namely which allow for example an adaptation of the moment and volume of deployment of the airbags, of the moment of unlocking of the seat belt after the shock, etc. depending on the passenger's stature and their position and orientation on the seat.

In order to allow the control microprocessor to decide the optimal operating mode for a certain passenger, it is therefore necessary to have a device for detecting the passenger's stature which determines the size and / or the weight of the passenger and which l 'indicates to the protection system control circuit. To this end, US-A-5,232,243 describes for example a device for detecting the weight of a passenger which comprises several individual force sensors arranged in a matrix in the cushion of the vehicle seat. The force sensors have a variable electrical resistance depending on the force applied and are known as FSR (force sensing resistor). The resistance of each sensor is measured individually and this information is processed in a microprocessor to determine the passenger's stature. By adding, for example, the forces corresponding to these resistance values, we obtain an indication of the total force exerted, that is to say, the weight of the passenger. In another embodiment, the information from the various force sensors is used to establish a pressure profile exerted by the passenger on the seat with the help of which the classification can be made.

In order to test and possibly calibrate such passenger classification systems, a force is applied to the seat containing the passenger sensor according to a pressure profile corresponding to a person of a certain class and it is checked whether the response of the classification system indicates the correct class.

Now the application of force is done by a human person who sits on the seat. However, it is clear that such a method is ineffective, takes a long time and leads to non-reproducible results.

Object of the invention The object of the present invention is to provide a test tool for testing a passenger sensor in a reproducible manner.

General description of the invention

According to the invention, this objective is achieved by a test tool for testing a passenger detector, comprising an internal structure of rigid material, said internal structure comprising a first element of a shape similar to the bony pelvis, in particular to the pelvis of 'a person with a stature resp. a given body size, and a second element and a third element, each of a shape similar to an upper part of a femur of said person, said first, second and third elements being assembled with each other so as to simulate a part of the skeleton of the person in a sitting position. The test tool according to the present invention further comprises a coating of elastic material, said coating of elastic material covering said first, said second and said third element of said internal structure and having an external shape similar to the buttocks and thighs of said person.

Pressed in a seat equipped with a passenger sensor with a total force which corresponds substantially to the weight of a person of given stature, such a tool allows, thanks to its advantageous combination of a rigid internal structure and a coating in appropriate material, to perfectly simulate the imprint of the buttocks and thighs of this person sitting in the seat. It should be noted, that the term stature is used in this description in a broad sense, that is to say meaning not only the size as the height of the body but also as the width of the body, that is to say ie the corpulence.

Indeed, the rigid internal structure, for example of hard plastic or metal, of a shape similar to the skeleton of a person of the given stature causes a distribution of the forces applied on the same places as in the case of a person human. The shape of the first element of the internal structure, which is similar to the bone basin of a human person, allows for example to find in the imprint of the tool a concentration of forces which is located in the same regions as that caused by a person's ischia. It is clear that the distribution of forces is all the more exact as the shape of the internal structure is more biofidel. In addition, by choosing a suitable material for the coating of elastic material, we manage to perfectly imitate the elasticity and / or hardness of human muscle tissue. Like human flesh, elastic material deforms itself under the action of the pressure exerted by the tool on the seat, so that the pressure profile generated by the tool perfectly matches that of a being human. Such a match cannot be acquired by a rigid object. It follows that the test tool according to the present invention represents, at least on its lower part directed towards the seat, an ideal reproduction of the buttocks and thighs of a person seated of the given stature, not only from the point of view of the shape but also from the point of view of the structure of the material.

Using a positioning device, such as a mechanical robot, such a test tool can be placed very precisely and in a well-defined position on a seat comprising a passenger sensor. The robot can then apply force to the test tool in order to press it into the seat with a total force which corresponds substantially to the weight of a person of the given stature. The force to be applied by the robot must for example correspond to the difference of the weight of a person of the given stature and the weight of the tool itself. In this way it becomes possible to execute series of tests under well defined conditions and therefore perfectly reproducible. The test tool can therefore be used in temperature or aging tests, for which it is essential to reproduce exactly the same conditions of weight and pressure profile on a large number of individual tests. In addition, the tool is well suited to testing the detector in different seats and for different equipment.

It should be noted that the force to be applied by the robot can be distributed over several regions of the tool in order to simulate a specific sitting position. Indeed, only part of the pressure exerted by a person on a seat is exerted by the buttocks of the person. Another part of the force, variable according to the position of the legs, is for example exerted by the thighs. By applying a greater part of the force on the "thighs", one can for example simulate a position in which the person's legs are raised towards the front of the vehicle and consequently do not carry their own weight.

In a preferred embodiment of the test tool, the internal structure further comprises a fourth element having a first and a second end, said fourth element having a shape similar to a lower part of a backbone of said person, said fourth element being assembled with the first end to said first, second and third elements so as to simulate a part of the skeleton of the person in a seated position. A tool presenting this simulated "backbone" has an improved degree of biofidelity compared to the first execution and therefore makes it possible to acquire a better distribution of the forces on the seat. Part of the force to be applied can then be transmitted directly to the fourth element of the internal structure, thus simulating the part of the weight exerted by the thorax on the spine of the human being.

The fourth element is preferably executed so as to exit towards the top of the coating so that the second end of the fourth element is accessible outside of said coating. The second end then preferably carries a coupling element, which makes it possible to couple the tool to a handling arm of the mechanical robot. By this execution, the positioning and positioning of the tool on the seat are clearly facilitated. The coupling is advantageously carried out as a loading platform and then makes it possible to easily apply part of the pressing force directly to said fourth element.

In a very simple and economical execution of the test tool, said first, second and third elements are rigidly assembled to each other. The angle between the "thighs" and the "pelvis" of the internal structure being non-variable, the number of sitting positions that can be simulated with such a tool is obviously reduced. The variation in the distribution of the force applied by the robot nevertheless makes it possible to simulate several different positions, so that such a tool is largely sufficient for tests of online production. If it is desired to carry out more sophisticated tests, said first, second and third elements are advantageously assembled together with the aid of joints. In this way, more varied position simulations become possible, such as a position with a seat back that is tilted sharply towards the rear or a position of a passenger leaning towards the front of the car.

The elastic material of the coating preferably comprises silicone. Silicone exists in a wide range of different hardnesses and by varying the ratio between silicone and silicone oil, the desired consistency can be adjusted. It follows that silicone is well suited to simulate the properties of the skin and muscle tissue of a human being. In addition, the silicone is easy to handle. The test tool is for example produced by suspending the internal structure in a mold having an appropriate internal shape and by pouring the silicone into the mold.

In order to simulate the structure of different types of human tissue, the coating may comprise several layers having different elasticities and / or hardnesses. This execution makes it possible, for example, to constitute a hardness gradient inside the coating and thus simulate the difference in hardness of a muscle tissue inside the tool and an outer layer of fat. It is also possible to compensate for a lack of biofidelity of the internal structure using a harder layer. In addition, a harder layer inside the coating increases the stability of the coating, which advantageously increases the service life of the test tool. It should be noted that the different layers can be made of different materials and that for example only the outer layer comprises a silicone layer.

In a very advantageous embodiment of the test tool, said coating also comprises an electrically conductive material. The test tool thus acquires a certain electrical capacity which can be used to simulate the electrical capacity of a person seated in a seat. It is clear that the capacity of the tool depends on the amount of the electrically conductive material and its distribution in the coating. By varying these parameters, the capacity of the tool can therefore be adjusted to a value that corresponds to that of a person sitting on the seat. The test tool can thus also be used to test the response of a capacitive position detection system integrated in the seat. This integration of the different test functions allows rapid testing of different detection systems during the production of car seats.

The electroconductive material comprises for example metallic conductors which are integrated in the elastic material. Alternatively, metal ions or powdered carbon can be integrated into the elastic material in order to make it conductive. In another embodiment, the electroconductive device comprises electroconductive silicone and / or electroconductive rubber. This execution has the advantage that the electroconductive silicone does not modify the consistency of the coating and therefore does not influence the response of the tool.

In order to integrate another test function into the test tool, it can include one or more force sensors which are arranged on the outer surface of the coating of elastic material. These force sensors allow you to measure the response of the seat, for example, when the tool is pressed into the seat using a mechanical robot. We therefore have a tool with which we can directly measure the forces that the seat exerts on a passenger and thus obtain an indication of the comfort of the seat. It should be noted that the force sensors can include variable resistors known as Force Sensing Resistors or any other kind of force sensor.

In a preferred embodiment of the invention, said tool further comprises a protective sheath made of exchangeable fabric, said sheath being arranged in intimate contact with said coating of elastic material. This protective sheath can, for example, include a kind of ieggins which protects the external surface of the coating against dirt. It should be noted that the protective sheath may include metal conductors to simulate the electrical capacity or else the force sensors necessary to test the comfort of the seat. In this case, the coating must not be modified by the integration of these functional elements. By clothing the basic tool of the sheath comprising the functional elements necessary for the other test functions, there is therefore a modular tool which can easily be adapted to its intended use.

It is clear, that in order to test the functioning of a classification system, we would like to have a set of test tools to test a passenger detector, the set comprising several tools having different dimensions to simulate pressure profiles of people of different statures. In order to test the different classes of such a classification system, for example, tools representing a man in the fiftieth percentile, a woman in the fifth percentile and a child aged 10 are needed.

Description with the aid of the figures Other particularities and characteristics of the invention will emerge from the detailed description of some advantageous embodiments presented below, by way of illustration, with reference to the appended drawings. These show:

Fig.1: A top view on an execution of a test tool;

Fig. 2: a side view of the tool in fig. 1.

Fig. 1 shows a view on an execution of a test tool 10 according to the present invention, FIG. 2 shows a side view. The tool mainly comprises an internal structure 12 of rigid material and a coating 14 of elastic material.

The internal structure has the function of simulating part of the human skeleton. It includes a pelvis simulator 16, two femur simulators 18 and 20 and preferably a spine simulator 22, attached to the pelvis simulator 16 so as to simulate a seated position of a person of the given stature. The various elements of the internal structure 12 are made of a rigid material, for example a hard plastic or a metal, and preferably have biofidel shapes, that is to say their shapes correspond exactly to the respective parts of the human skeleton that 'they simulate.

The internal structure 12 is coated with a coating 14 made of elastic material. This coating has at least in the lower part 24 of the tool an external shape similar to the buttocks and thighs of a person in a seated position. The coating may for example comprise silicone, the hardness of which is easily adjustable to the required values. It should be noted that the external shape is preferably that of the uncompressed buttocks and thighs. Thus the tool will deform just like human flesh under the action of the pressure exerted by the tool on a seat, so that the pressure profile generated by the tool corresponds perfectly to that of a human being.

It should be noted that the coating can comprise several layers 14 ^ 142, 143 having different consistencies in order to simulate a hardness gradient in the tool.

The spine simulator 22 is preferably executed so as to exit upwards from the cover 14 so that an upper end of the spine simulator 22 is accessible outside of said cover 14. This upper end then carries preferably a coupling element 26, which makes it possible to couple the tool 10 to a handling arm of a mechanical robot. By this execution, the positioning and positioning of the tool on the seat are clearly facilitated. The coupling 26 is advantageously executed as a load platform and then makes it possible to easily apply part of the pressing force directly to the spine simulator 22.

Other points of action of the pressure force can be found directly on the coating 14. Thus a part of the pressure force is preferably applied to the coating 14 in the regions 28 which are located above the bones of the pelvis, so as to transmit an appropriate part of the pressing force through these bones on the parts of the structure simulating a person's ischia. Finally, part of the pressing force is advantageously applied to the "thighs" of the tool, for example in a region 32 situated above the end of said femur simulator 18, 20. In this way, account can be taken of the weight of thighs and legs of a seated person.

Claims (14)

1. Test tool (10) for testing a passenger detector, comprising a) an internal structure (12) of rigid material, said internal structure comprising i) a first element (16) of a shape similar to the basin of a a person of a given stature, and ii) a second element (18) and a third element (20), each of a shape similar to an upper part of a femur of said person, said first (16), second (18) ) and third (20) elements being assembled together so as to simulate a seated position of said person, and b) a coating (14) of elastic material, said coating (14) of elastic material covering said first , said second and said third element of said internal structure and having an external shape similar to the buttocks and thighs of said person. 2. Tool according to claim 1, characterized in that the internal structure further comprises a fourth element (22) having a first and a second end, said fourth element (22) having a shape similar to a lower part of a thorn back of said person, said fourth member being assembled with the first end to said first, second and third members so as to simulate a sitting position of said person. 3. Tool according to claim 2, characterized in that said fourth element leaves said coating so that said second end of said fourth element is accessible outside of said coating, said second end carrying a coupling element (26). 4. Tool according to one of claims 1 to 3, characterized in that said first, second and third elements are rigidly assembled to each other. 5. Tool according to one of claims 1 to 3, characterized in that said first, second and third elements are assembled to each other using joints. 6. Tool according to one of claims 1 to 5, characterized in that the elastic material of the coating comprises silicone. 7. Tool according to one of claims 1 to 6, characterized in that the coating comprises several layers (14i, 142, M3) having different elasticities and / or hardnesses. 8. Tool according to one of claims 1 to 7, characterized in that said coating comprises an electrically conductive material. 9. Tool according to claim 8, characterized in that the electroconductive material comprises metallic conductors which are integrated in the elastic material. 10. Tool according to one of claims 8 to 9, characterized in that the electroconductive material comprises electroconductive silicone and / or electroconductive rubber. 11. Tool according to one of the preceding claims, characterized by at least one force sensor, said force sensor being disposed on the outer surface of the coating of elastic material. 12. Tool according to one of the preceding claims, characterized by a protective sheath of fabric, said sheath being arranged in intimate contact with said coating of elastic material. 13. Tool according to claim 12, characterized by metal conductors integrated in the fabric sheath. 14. Set of test tools for testing a passenger detector comprising several tools according to one of the preceding claims, the tools having different dimensions for simulating pressure profiles of people of different statures.