An actuator comprising a linear electrical machine (LEM) having a stator with a stator bore and a translator axially movable within the stator bore and defining a magnetic circuit airgap therebetween, at least one fluid bearing journal formed on the translator, at least one fluid bearing providing a bearing gap adjacent the translator to allow the translator to move axially within the stator bore, a preload chamber for applying a preload force to the translator, wherein the preload chamber is defined by a side wall, a first end wall and a second end wall at least part of which is movable with the translator, and wherein the bearing gap and the magnetic circuit airgap are coaxial.

In a vehicle vibration device including a first shaft and a second shaft extending in a left-right direction at such a spacing that each of wheels of a vehicle to be inspected is sandwiched therebetween in a front-rear direction and a movement mechanism that moves the first shaft, the first shaft being moved in a front-rear and horizontal direction by the movement mechanism to excite the wheel to vibration in front-rear and up-down directions, a support member that supports the wheel from below is provided between the first shaft and the second shaft. As a result, a vibration force produced by a front-side shaft is effectively transmitted to the wheel over an entire vibration frequency range in a vibration test.

The present disclosure belongs to the technical field of tests of automobile wheels and automobile chassis suspension systems, and provides a simulated pavement rotary drum and automobile test equipment. A simulated cobblestone pavement, and a simulated impact pavement, so that a testing pavement at a test field is reproduced; an impact load caused by the track pavement, the cobblestone pavement, and the impact pavement can be applied to wheels and a chassis system; and a road simulation test of wheels and a suspension system of an automobile can be performed on bench test equipment. As verified, the simulated pavement rotary drum of the present disclosure can reproduce the simulated track pavement at the test field; and the consistency of radial impact loads is greater than 95% at the same speed and under the same vehicle load operating condition.

The present invention is intended to make it possible to automatically drive a test object without performing pre-learning for a running performance map for each vehicle. There is provided an automatic test object driving device that automatically drives a test vehicle based on a command vehicle speed, and that includes a driving actuator for performing driving operation of the test vehicle, and a driving control unit for controlling the driving actuator. The driving control unit includes a first accelerator map and a second accelerator map each of which indicates a relationship among a vehicle-speed-related value, an acceleration-related value, and an accelerator-depression-amount-related value. The driving control unit uses the first accelerator map to determine an accelerator depression amount corresponding to the command vehicle speed, and uses the second accelerator map to correct the accelerator depression amount by feeding back a vehicle speed and an acceleration of the test vehicle.

The present invention is to evaluate a steering function of a test piece which is a vehicle having an automatic steering function or a part thereof on a chassis dynamometer, and is a vehicle testing system that performs a running test of a test piece which is a vehicle having an automatic steering function or a part thereof. The vehicle testing system includes a chassis dynamometer for performing a running test of the test piece, and a steering reaction force inputting device that inputs a steering reaction force to a steering rack gear of the test piece with a tie rod being removed, in which the steering reaction force is input to the test piece traveling on the chassis dynamometer to evaluate the steering function of the test piece.

A chassis dynamometer for motorcycles with a combustion engine, having a mounting unit, at least one fastening unit, an operating unit, a control unit and a roller for recording the peripheral speed of a motorcycle rear wheel is disclosed. The chassis dynamometer has a flow unit a drive unit, a diffuser and an outflow unit arranged downstream of the diffuser in the direction of flow where the diffuser and outflow unit form a flow channel carrying gas in the operating state, wherein the diffuser can be driven by the drive unit, where the control unit controls the drive unit as a function of the peripheral speed of the roller in such a way that a speed of the gas emerging from the outflow unit in the operating state is substantially equal to the peripheral speed at least from a peripheral speed of 150 km/h.

A test apparatus for simulating road conditions for a motor vehicle. The test apparatus includes a platform, a pair of roller assemblies, and a driveshaft. The pair of roller assemblies are coupled to the platform. Each pair of roller assemblies being configured to receive a pair of wheels of the motor vehicle. The driveshaft is secured between the pair of roller assemblies and is configured to transmit rotary power from one of the pair of roller assemblies to the other of the pair of roller assemblies. An orientation of the platform is adjustable.

A vehicle inspection apparatus includes: an exciter roller (3) configured to apply vibration to a vehicle (6); a control device 5 configured to control the exciter roller (3); and a vibration setting unit (the control device (5)) configured to set a vibration that is input to a wheel (7) of the vehicle (6) when abnormal noise generated in the vehicle (6) is detected. The control device (5) provides a range of vibrations including the vibration set by the vibration setting unit and applies the range of vibrations to the vehicle (6).

A method for providing a visual aid to guide a driver when executing a test cycle includes controlling an electronic display to display a graph including a target trace indicating a target speed of a vehicle during the test cycle and a first visual indicator of an actual speed of the vehicle during the test cycle, scroll the target trace from a first side of the graph to a second side of the graph during a time-based portion of the test cycle to indicate the target vehicle speed with respect to an amount of time elapsed since a start of the test cycle, and scroll the target trace from the first side of the graph to the second side of the graph during a distance-based portion of the test cycle to indicate the target vehicle speed with respect to a distance travelled by the vehicle during the test cycle.

A mobile fixture configured to move a structure in a manufacturing environment may include a motorized base configured to move on a surface and a support system connected to the motorized base, the support system being configured to support the structure, the support system being configured to position the structure along at least one of an X-axis, a Y-axis, and a Z-axis, the support system being configured to position the structure about the Z-axis, and the support system being configured to provide free rotation of the structure about at least one of the X-axis and the Y-axis.