Disclosed is a chassis component (1, 38) having a measuring device (9) for determining a relative position of two chassis components connected movably with one another. For example, a first chassis component is a joint (2) with at least one rotation axis (8) and a second chassis component is a structural component (3), the structural component (3) being mounted by means of the joint (2) so that it can pivot around the rotation axis (8) of the joint (2). The measuring device (9) has a signal emitter (13) and a sensor device (10, 28) with a signal receiver (21), where the sensor device (10, 28) is arranged on the structural component (3) and the signal emitter (13) is arranged on the joint (2). To improve an arrangement of the sensor device (10, 28) on the structural component (3), the sensor device (10, 28) extends through a through-opening (11).

A chassis component (1, 38, 40) has a joint inner portion (2) and a structural component (3), where the joint inner portion (2) is fitted and able to move in an articulated manner in a joint holder (4). A measuring device (5) is configured to determine a relative position of the joint inner portion (2) with respect to the structural component (3) and includes a first measuring element (6) and a second measuring element (7). The first measuring element (6) is on the structural component (3) and the second measuring element (7) is on the joint inner portion (2). In one example, the joint inner portion (2) extends out of the joint holder (4) and the second measuring element (7) is attached on a section (8) of the joint inner portion (2) which is outside the joint holder (4).

The present disclosure relates to a method of determining whether a frame of a work machine is approaching a tip over point. First and second loads upon respective first and second support arrangements of the frame are detected using respective first and second sensing means. Signals are generated indicative of the first and second loads and communicated to a controller. The controller is configured to generate an alert based upon the first and second loads when the first and/or second load signals indicate that the orientation of the work machine is approaching a tip over point.

A load monitoring system and techniques estimate a load on a vehicle, such as a trailer, bus, RV, or other vehicle. The system includes a sensor having a main body housing and an alignment feature. The main body housing contacts a first surface of a suspension component and the alignment feature contacts a second surface of the suspension component.

The present disclosure relates to a method of determining whether a frame of a work machine is approaching a tip over point. First and second loads upon respective first and second support arrangements of the frame are detected using respective first and second sensing means. Signals are generated indicative of the first and second loads and communicated to a controller. The controller is configured to generate an alert based upon the first and second loads when the first and/or second load signals indicate that the orientation of the work machine is approaching a tip over point.

A system may monitor a vibration isolating connection between a first part and a second part. The system may include a light source, an optical sensor mounted to receive light from the light source, and a processing unit for providing an output indicative of the deformation of the vibration isolating connection based on the output of the optical sensor.

A status tracking system for tracking a suspension system or a physical condition of the parts in a steering system in vehicles. The status tracking system includes a sensor unit connected with the body of the part, and a processor unit configured to connect with the sensor unit in a manner receiving the measurements made by the sensor unit as input. The processor unit is configured to obtain measurement information from the measurements it receives, generate status information by classifying the measurement information according to a reference value in a memory unit, and display the status information on a user interface.

A height sensor including a sensor body, a swing arm and a connecting rod. A first end of the swing arm is movably connected to the sensor body, and a second end of the swing arm is movably connected to the connecting rod. The swing arm is configured as a structure with an adjustable working length suitable for, and can be matched to, different chassis suspension structures, being highly versatile, with a low development cost and high development efficiency.

An orientationally flexible bump sensor is disclosed. The system includes at least one bump sensor mounted to a vehicle, the at least one bump sensor comprising at least two axes of measurement. A computer processor is configured to evaluate the at least two axes of measurement to determine which axis of the at least two axes of measurement has a highest magnitude vector and determine a gain value to cause the highest magnitude vector to be approximately 1 g. The computer processor will assign the gain value to the axis with the highest magnitude vector, such that the gain value is applied to each measurement generated by the axis with the highest magnitude vector.