A method for operating a pressure control device in a vehicle, in particular in a motor vehicle, wherein current is supplied by an energy source of the vehicle for operating the pressure control device, as a result of which the pressure control device carries out at least one pressure control function, for which at least two actuators of the pressure control device are actuated, wherein at least one current required at maximum for actuating the actuator is determined for each actuator and current budget management for actuating the actuators and/or for carrying out the pressure control functions is performed by the determined currents required at maximum. In addition, the invention relates to a pressure control device for carrying out the method.

A pump device for a brake system of a motor vehicle has a housing, a pressure piston which delimits a pressure chamber in the housing for producing hydraulic pressure mounted in the housing in a longitudinally displaceable manner, a return spring assigned to the pressure piston, a non-return valve which separates the pressure chamber from a pressure connection and only removes the separation when the hydraulic pressure in the pressure chamber is greater than in the pressure connection, and an electromagnetic actuator which includes an armature and an electrically energizable solenoid. The armature is arranged on the pressure piston and the solenoid in and/or on the housing. The pressure piston has an axial through-channel which opens out into the pressure chamber at one end and is assigned to the non-return valve at the other end.

A brake device for a vehicle may include: a housing block; a plurality of buildup valve mounting parts formed in the housing block and disposed in a first row region; a plurality of reduce valve mounting parts formed in the housing block, and disposed in a second row region formed under the buildup valve mounting parts; a wheel cylinder port formed in the housing block, disposed above the buildup valve mounting parts, and connected to a wheel cylinder; a master cylinder port formed in the housing block, disposed above the buildup valve mounting parts, and connected to a master cylinder; a pump port formed in the housing block, and disposed under the buildup valve mounting parts; and one or more damper units formed in the housing block, and disposed among the buildup valve mounting parts, the wheel cylinder port and the master cylinder port.

A brake device for a vehicle may include: a housing block; a plurality of buildup valve mounting parts formed in the housing block and disposed in a first row region; a plurality of reduce valve mounting parts formed in the housing block, and disposed in a second row region formed under the buildup valve mounting parts; a wheel cylinder port formed in the housing block, disposed above the buildup valve mounting parts, and connected to a wheel cylinder; a master cylinder port formed in the housing block, disposed above the buildup valve mounting parts, and connected to a master cylinder; a pump port formed in the housing block, and disposed under the buildup valve mounting parts; and one or more damper units formed in the housing block, and disposed among the buildup valve mounting parts, the wheel cylinder port and the master cylinder port.

This disclosure relates to a motor vehicle including a climate control system with an accumulator, and a corresponding method. An example motor vehicle includes a powertrain and a climate control system configured to meet a thermal conditioning demand. The climate control system includes an accumulator and a compressor driven by the powertrain. Further, a controller is in electronic communication with the climate control system, and the controller is configured to selectively command the climate control system to charge the accumulator when an amount of energy available to the compressor from the powertrain is in excess of an amount of energy required to meet the thermal conditioning demand.

A compressed air system for a motor vehicle with an air supply system includes an electric drive motor, which can be controlled for variable speed, an air compressor coupled to be driven by the electric drive motor, an electric power supply for supplying electric power to the electric drive motor, at least one air reservoir connected with the air compressor to receive air from the air compressor, an air utilization system connected to the air reservoir to receive air from the air reservoir, and a controller to control the speed of the electric drive motor. The controller controls the electric drive motor to determine its speed depending upon at least one of the following signals: a signal representing the activation status of an accelerator pedal of the vehicle, a signal representing the speed of the vehicle, a signal representing the temperature of the power supply, a signal representing the temperature of the electric drive motor, a signal representing the wetness level of the air compressed by the air compressor, a signal representing the load of the air compressor, a signal representing the running time of the air compressor, or a signal representing the status of the electric power supply.

An agricultural work vehicle having an air supply device includes: an air compressor for pressurizing air; an air tank for storing the air compressed by means of the air compressor; a pressure sensor for measuring the pressure of the air stored in the air tank or atmospheric pressure; a controller for stopping the operation of the air compressor when the measured pressure exceeds a first reference value; and an air pressure regulator for discharging, to the outside, the air inside an air pressure circuit system so as to reduce the pressure when the pressure of the air stored in the air tank exceeds a second reference value.

An agricultural work vehicle having an air supply device includes: an air compressor for pressurizing air; an air tank for storing the air compressed by means of the air compressor; a pressure sensor for measuring the pressure of the air stored in the air tank or atmospheric pressure; a controller for stopping the operation of the air compressor when the measured pressure exceeds a first reference value; and an air pressure regulator for discharging, to the outside, the air inside an air pressure circuit system so as to reduce the pressure when the pressure of the air stored in the air tank exceeds a second reference value.

A compressed air supply installation for operating a pneumatic installation, especially an air suspension installation of a vehicle, includes a compressed air supply unit, a compressed air port towards the pneumatic installation, a venting port towards the surroundings, a first pneumatic connection between the compressed air supply and the compressed air port, the first pneumatic connection having an air drier and a shut-off valve, and a second pneumatic connection between the compressed air port and the venting port. The shut-off valve is a pneumatically pilot-controlled check valve.

A compressed air supply installation for operating a pneumatic installation, especially an air suspension installation of a vehicle, includes a compressed air supply unit, a compressed air port towards the pneumatic installation, a venting port towards the surroundings, a first pneumatic connection between the compressed air supply and the compressed air port, the first pneumatic connection having an air drier and a shut-off valve, and a second pneumatic connection between the compressed air port and the venting port. The shut-off valve is a pneumatically pilot-controlled check valve.