A method for operating an electronically controllable air spring system having air springs includes ascertaining a vehicle velocity of a vehicle and performing a procedure of monitoring a loading procedure and/or a procedure of monitoring an unloading procedure if the vehicle velocity indicates that the vehicle is at a standstill. The method further includes suppressing a level control procedure via the air spring system for a determined time period if at least one pressure difference that is allocated to the air springs exceeds the respective loading pressure limit difference or undercuts the unloading pressure difference and/or a loading criterion or an unloading criterion are met.

A transportable fire training apparatus includes a trailer frame having a rear raised section at a rear end of the trailer frame and an unraised section at a middle portion of the trailer frame, a shell attached to the trailer frame and partitioned into a plurality of training rooms, a rear multi-axle wheel set disposed below, and attached to, the rear raised section of the trailer frame via an air ride suspension system that raises the trailer frame relative to the a rear multi-axle wheel set in response to pressurization of the air ride suspension system. The unraised section of the trailer frame rides substantially above the ground when the air ride suspension system is in a pressurized state and rests on the ground when the air ride suspension system is in an unpressurized state. A method for deploying and using the transportable fire training apparatus is also disclosed herein.

A hybrid passenger vehicle includes a chassis supported by at least one front wheel and at least one rear wheel, a body coupled to the chassis including at least one door, and a vehicle floor coupled to the chassis. The body defines an interior space configured to be occupied by at least one passenger when operating the vehicle, and the vehicle floor has a front end and a rear end. A rear wall is coupled to the rear end of the vehicle floor such that the rear wall defines a rearmost boundary of the vehicle floor. A rear suspension assembly is coupled to the chassis. The rear wall is arc-shaped, and the rear suspension assembly is located rearward of the rear wall.

Deployable step systems for accessing vehicle cargo spaces on vehicles equipped with a tailgate assembly having a door subassembly may include a bumper integrated step pad that is movable between a stowed position and a deployed position. In the stowed position, the step pad establishes a portion of the bumper, and in the deployed position, the step pad is rearward and vertically lowered relative to the bumper.

A system for adjusting a height of at least one part of a utility vehicle at at least one predetermined location, the utility vehicle having a position determination device and a height adjustment device to determine a position of the utility vehicle and to change a height of the at least one part of the utility vehicle above a ground surface, including: an interface to receive data that indicate a target height of the at least one part of the utility vehicle at the predetermined location; and a control unit that is couple-able to the position determination device and to the height adjustment device, and is configured, based on a determined position, to prompt the height adjustment device of the utility vehicle to adjust the height of the at least one part of the utility vehicle to the target height. Also described are a related utility vehicle and a method.

A hybrid passenger vehicle includes a chassis supported by at least one front wheel and at least one rear wheel, a body coupled to the chassis including at least one door, and a vehicle floor coupled to the chassis. The body defines an interior space configured to be occupied by at least one passenger when operating the vehicle, and the vehicle floor has a front end and a rear end. A rear wall is coupled to the rear end of the vehicle floor such that the rear wall defines a rearmost boundary of the vehicle floor. A rear suspension assembly is coupled to the chassis. The rear wall is arc-shaped, and the rear suspension assembly is located rearward of the rear wall.

A method for lowering a vehicle chassis to a required vertical position, the vehicle including only two sets of running gear, namely a front set of running gear and a rear set of running gear, each wheel of the sets of running gear being associated with a parking brake, the method including the following successive steps: when the chassis is in its high running position, actuating the parking brake only for all of the wheels of one of the two sets of running gear; lowering the chassis to its low position resting on the ground; and actuating the parking brake for all of the wheels of the other of the two sets of running gear.

A method for operating an electronically controllable air spring system having air springs includes ascertaining a vehicle velocity of a vehicle and performing a procedure of monitoring a loading procedure and/or a procedure of monitoring an unloading procedure if the vehicle velocity indicates that the vehicle is at a standstill. The method further includes suppressing a level control procedure via the air spring system for a determined time period if at least one pressure difference that is allocated to the air springs exceeds the respective loading pressure limit difference or undercuts the unloading pressure difference and/or a loading criterion or an unloading criterion are met.

An air suspension system of a commercial vehicle comprises an electronic control device with a level control valve device. A valve element is coupled to a drive element mechanically coupled to a vehicle wheel or axle. In a first relative position of the valve element and a counter valve element, a port for an air suspension bellow is blocked. In a second relative position, the port for the air suspension bellow is connected to a port for an aeration device. In a third relative position, the port for the air suspension bellow is connected to a port for a deaeration device. Control logic generates a control signal for an actuator which, when a level change is set by an operator, correspondingly changes the relative position of the valve element and the counter valve element or the relative position of the counter valve element and a valve housing.

Disclosed are a system and method for operating a vehicle kneeling system. A controller operates an actuator that compresses the vehicle suspension to lower the frame of the vehicle to a kneeled position. The controller verified that the transmission is set to park, and that a kneel switch is depressed, to operate the actuator. The controller continues to monitor these parameters, and when the controller detects loss of a signal, it deactivates the actuator which allows the suspension to return the vehicle to a ride height.