The present disclosure relates to a measuring device (42, 43) for measuring forces and/or torques between a motorized vehicle (1) and a trailer or attachment which is towed or pushed thereby, wherein the measuring device (42, 43) has at least three sensor elements (22, 34) which are arranged on a carrier (20, 31), transversely with respect to a virtual longitudinal axis of the motorized vehicle (1) and spaced apart from one another, wherein the measuring device (42, 43) is arranged in a coupling region between the motorized vehicle (1) and the pulled or pushed trailer or attachment, and wherein, in order to transmit their measured values, the sensor elements (22, 34) are connected to an evaluation device (40), which is configured to convert these measured values into signals for force displays and/or torque displays according to magnitude and direction.

A measuring device (60) is configured for measuring forces or torques between a motorized vehicle (1) and a trailer or attachment which is towed or pushed thereby. The measuring device (60) has at least three sensor elements (79, 80) arranged on a carrier (71), transversely with respect to a virtual longitudinal axis of the motorized vehicle (1) and spaced apart from one another. The measuring device (60) is arranged in a coupling region between the motorized vehicle (1) and the pulled or pushed trailer or attachment. In order to transmit their measured values, the sensor elements (79, 80) are connected to an evaluation device (40), which is configured to convert these measured values into signals for force displays and/or torque displays according to magnitude and direction.

A carrier mountable to a vehicle for carrying a conventional broadcast spreader features a mounting bar for coupling to the vehicle in a mounted condition and a holder arranged at an end of the mounting bar for supporting the spreader. The holder has a first portion which is in fixed relation to the mounting bar and a second portion which is pivotally coupled to the first portion so as to be movable from a storage position to a lowered position where a front end of the second portion is arranged at the ground. The holder includes a first receptacle for receiving a lower portion of the spreader and a pair of channels, one of which is supported on the second portion so as to be movable therewith and another one which is supported in fixed position on the first portion, which collectively form an enclosure for receiving the leg of the spreader in the storage position.

A carrier mountable to a vehicle for carrying a conventional broadcast spreader features a mounting bar for coupling to the vehicle in a mounted condition and a holder arranged at an end of the mounting bar for supporting the spreader. The holder has a first portion which is in fixed relation to the mounting bar and a second portion which is pivotally coupled to the first portion so as to be movable from a storage position to a lowered position where a front end of the second portion is arranged at the ground. The holder includes a first receptacle for receiving a lower portion of the spreader and a pair of channels, one of which is supported on the second portion so as to be movable therewith and another one which is supported in fixed position on the first portion, which collectively form an enclosure for receiving the leg of the spreader in the storage position.

Contemplated are cost reduction and enhanced readiness of parts management related to right and left fenders. A work vehicle includes right and left fenders (16) each having a vertical plate member (18) covering an inner face of a traveling device from an inner side of a vehicle body and a top plate member (19) covering an upper portion of the traveling device (5) from above, wherein the top plate member (19) is configured to be front-rear symmetric, and each of the vertical plate member (18) and the top plate member (19) is configured to act as a right-left interchangeable member.

Provided is an articulated bus including a front vehicle including a steering wheel and a rear wheel positioned on a rear side of the steering wheel in a front-rear direction of a vehicle, a rear vehicle disposed on a rear side of the front vehicle in the front-rear direction of the vehicle and mounted with an engine, an articulating portion that swingably connects the front vehicle and the rear vehicle to each other, and a hybrid system including an electric generator that functions as an electric motor and a generator, and an HV battery that stores electric energy generated by the electric generator and supplies electric energy to the electric generator, in which the HV battery is disposed on a roof of the front vehicle.

A system a first mobile body configured to support a turbine engine and an auxiliary skid communicatively and fluidly coupled to the turbine engine. The auxiliary skid includes one or more interconnects configured to support a turbine engine component. The system also includes a second mobile body configured to support a generator. The first and second mobile bodies are configured to align a removable coupling between the turbine engine and the generator.

A system a first mobile body configured to support a turbine engine and an auxiliary skid communicatively and fluidly coupled to the turbine engine. The auxiliary skid includes one or more interconnects configured to support a turbine engine component. The system also includes a second mobile body configured to support a generator. The first and second mobile bodies are configured to align a removable coupling between the turbine engine and the generator.

A computing system for an autonomous engine module stores a self-driving capability and is configured to determine, by communication between an autonomous engine module in which the computing system resides and other autonomous engine modules, and responsive to a user request for use of an autonomous engine module, at least one suitable autonomous engine module use candidate. The computing system may also generate a notification directed to the user including information relating to the at least one suitable autonomous engine module use candidate. The computing system may also receive a selection by the user of an autonomous engine module use candidate. The computing system may also, using the self-driving capability, autonomously drive the autonomous engine module to a designated pickup location responsive to selection by the user of the autonomous engine module as the autonomous engine module use candidate.

The disclosure relates to a device of a vehicle, in particular a tractor, having a hydraulic activation unit for controlling the operation of a towed implement on the vehicle, comprising at least one position detection unit with at least one camera, position detection marks, and an evaluation unit and a data-transmitting connection to a control unit which is assigned to the hydraulic activation unit. Furthermore, a method is proposed, wherein by means of such a position detection unit the position of the towed implement can be determined, and the position can be adjusted according to requirements by suitable operation of the hydraulic activation unit.