In a vehicle test system, a displacement degree computing unit computes degrees of six-degree-of-freedom displacements of each of second motion bases, which correspond to external forces of respective six degrees of freedom detected by a corresponding one of six-axis force sensors, on an assumption
In a vehicle test system, a displacement degree computing unit computes degrees of six-degree-of-freedom displacements of each of second motion bases, which correspond to external forces of respective six degrees of freedom detected by a corresponding one of six-axis force sensors, on an assumption that each of the second motion bases has a virtual mechanical impedance. A MB second target value generator generates final position and posture target values for each of the second motion bases based on the position and posture target values for each of the second motion bases and the degrees of six-degree-freedom displacements of each of the second motion bases.
대표청구항▼
1. A vehicle test system comprising: a test article installation vehicle body to which four axles corresponding to four wheels that are a left front wheel, a right front wheel, a left rear wheel and a right rear wheel are attached, and on which a test article is installed;a first motion base that su
1. A vehicle test system comprising: a test article installation vehicle body to which four axles corresponding to four wheels that are a left front wheel, a right front wheel, a left rear wheel and a right rear wheel are attached, and on which a test article is installed;a first motion base that supports the test article installation vehicle body, and that allows the test article installation vehicle body to make motions of six degrees of freedom; four electric motors that are connected to outer end portions of the respective axles to apply torques to the respective axles, the torques being external forces that are applied to the respective axles;four second motion bases that support the respective axles via the corresponding electric motors, and that allow the respective axles to make motions of six degrees of freedom, whereineach of the first motion base and the second motion bases includes a stationary base, a movable base disposed above the stationary base, and an actuator that is disposed between and connected to the stationary base and the movable base, and that allows the movable base to make motions of six degrees of freedom, andeach of the electric motors is disposed between an outer end portion of an axle and a corresponding movable base of the second motion bases, the electric motor being directly connected to the outer end portion of the axle and the corresponding movable base of the second motion bases;four external force detectors that individually detect the external forces, which are applied to the respective second motion bases from the test article installation vehicle body via the external forces applied by the four electric motors to respective axles;a first target value generator that generates target values of a position and a posture to be taken by each of the first motion base and the second motion bases, for each of the first motion base and the second motion bases;a displacement degree computing unit that computes a degree of displacement of each of the second motion bases, which corresponds to the external force detected by a corresponding one of the external force detectors,wherein the external forces applied to the respective second motion bases from the test article installation vehicle body via the external forces applied by the four electric motors to respective axles correspond to the target values of the position and the posture to be taken by each of the first motion base and the second motion bases, and each of the second motion bases has a virtual mechanical impedance for producing flexibility against the external force;a second target value generator that generates final position and posture target values for each of the second motion bases based on the position and posture target values for each of the second motion bases generated by the first target value generator and the degree of displacement of each of the second motion bases computed by the displacement degree computing unit; anda controller that controls the first motion base using the position and posture target values for the first motion base generated by the first target value generator, and controls the second motion bases using the final position and posture target values for the second motion bases generated by the second target value generatora second target value generator that generates final position and posture target values for each of the second motion bases based on the position and posture target values for each of the second motion bases generated by the first target value generator and the degree of displacement of each of the second motion bases computed by the displacement degree computing unit; anda controller that controls the first motion base using the position and posture target values for the first motion base generated by the first target value generator, and controls the second motion bases using the final position and posture target values for the second motion bases generated by the second target value generator. 2. The vehicle test system according to claim 1, wherein: each of the external force detectors is configured to detect external forces of respective six degrees of freedom applied to a corresponding one of the second motion bases from the test article installation vehicle body;the virtual mechanical impedance of each of the second motion bases is formed of virtual mechanical impedances of respective six degrees of freedom that correspond to the external forces of respective six degrees of freedom; andthe displacement degree computing unit is configured to compute degrees of six-degree-of-freedom displacements of the second motion bases, which correspond to the external forces of respective six degrees of freedom detected by the external force detectors. 3. The vehicle test system according to claim 2, wherein the virtual mechanical impedances of respective six degrees of freedom include a virtual spring and a virtual damper. 4. The vehicle test system according to claim 3, wherein the test article installation vehicle body is disposed on the movable base of the first motion base and fixed to the movable base of the first motion base. 5. The vehicle test system according to claim 2, wherein the test article installation vehicle body is disposed on the movable base of the first motion base and fixed to the movable base of the first motion base. 6. The vehicle test system according to claim 1, wherein the virtual mechanical impedances of respective six degrees of freedom include a virtual spring and a virtual damper. 7. The vehicle test system according to claim 6, wherein the test article installation vehicle body is disposed on the movable base of the first motion base and fixed to the movable base of the first motion base. 8. The vehicle test system according to claim 1, wherein the test article installation vehicle body is disposed on the movable base of the first motion base and fixed to the movable base of the first motion base.
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이 특허에 인용된 특허 (9)
Melz, Tobias; Matthias, Michael; Hanselka, Holger, Apparatus and method for the vibroacoustic inspection of a motor vehicles.
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