Abstract: A method of controlling an air compressor of a vehicle. The absolute humidity is determined for atmospheric air entering the compressor as well as for the compressed air exiting the compressor. A liquid water mass formed or evaporated inside the compressor during a defined period of time is calculated. The above steps are repeated in order to calculate a cumulated liquid water mass inside the compressor. The compressor is stopped when the calculated cumulated liquid water mass has returned to zero and the control unit no longer receives a compressed air request.

Abstract: A system for a vehicle, having a fuel cell system and a compressed air system for supplying compressed air to a pneumatic device is provided. The fuel cell system includes: a fuel cell having an anode side and a cathode side, an outlet conduit connected to an outlet end of the cathode side, an air inlet conduit connected to an inlet end of the cathode side for supply of air to the cathode side of the fuel cell. An air compressor is disposed in the air inlet conduit, an air filter receives air from an ambient environment. Their filter is arranged at an inlet of the air inlet conduit. The compressed air system includes an electrically operable air compressor connectable to the pneumatic device in fluid communication with the compressor. An air inlet of the compressor is connected to the outlet conduit at a selected position, whereby the compressor receives exhaust air from the cathode side of the at least one fuel cell.

Abstract: A braking system, comprising an air reservoir, a first brake chamber, a first flow control device connected to the first brake chamber via a second fluid conduit, a second brake chamber, a second flow control device connected to the second brake chamber via a fourth fluid conduit, a third flow control device connected between the first flow control device and the first brake chamber, a parking brake sub-system configured to apply a parking brake when an air pressure falls below a threshold, and a control unit configured to control the third flow control device to maintain the pressure inside the first brake chamber, and each of the first flow control device and the second flow control device to allow air from the air reservoir arrangement to be discharged from the braking system, until the pressure provided by the air reservoir arrangement has fallen below the predefined parking brake threshold pressure.

Abstract: A safety park brake system of a vehicle is disclosed. The safety system comprises a pneumatic park brake, a park brake electronic unit, a controller, an air brake sub-system in air communication with the pneumatic park brake, and a compressor. The compressor is configured to provide pressurized air to the air brake sub-system through a discharge line arranged between the compressor and the air brake sub-system. The controller is configured to receive a park brake request, detect an error associated with a failure in the park brake electronic unit, and impede inflow of pressurized air into the air brake sub-system. The safety park-brake system is configured to control discharge of air from the air brake sub-system to thereby achieve a drop in air pressure. The pneumatic park brake is configured to automatically apply once the air pressure in the air brake sub-system drops below a predetermined threshold.

Abstract: A system for generating air pressure in a hybrid vehicle, comprising an engine-driven air compressor (C1) configured to be selectively operated by an ICE engine, an electrically-driven air compressor (C2) configured to be operated by an electric motor, wherein said electric motor is supplied from the electric network, at least one air reservoir configured to store pressurized air and being configured to be connected directly or indirectly to both an outlet of the engine-driven air compressor (C1) and an outlet of the electrically-driven air compressor (C2), at least one electronic control unit (3, 3?) configured to control at least the electrically-driven air compressor (C2) according at least to a selected drive mode of the vehicle, wherein the electrically-driven air compressor (C2) is downsized compared to the engine-driven compressor (C1), and corresponding control methods.

Abstract: A system for a vehicle, having a fuel cell system and a compressed air system for supplying compressed air to a pneumatic device. The fuel cell system includes at least one fuel cell having a cathode side, an air inlet conduit connected to an inlet end of the cathode side, an air compressor disposed in the air inlet conduit, an air filter arranged to receive air from an ambient environment. The air filter is arranged at an inlet of the air inlet conduit. A a fluid outlet conduit is connected between an outlet end of the cathode side and an inlet side of an expander, and an exhaust conduit is connected to an exhaust side of the expander. The compressed air system comprising: an electrically operable air compressor connectable to the pneumatic device. A controllable valve assembly fluidly connects an air inlet of the compressor to multiple fluid supply positions.

Abstract: Method for venting a pneumatic system of a vehicle, pneumatic system and vehicle Method for venting a pneumatic system (1) of a vehicle, the pneumatic system (1) comprising an air compressor (4), a pneumatic circuit (2), an air pressure management system (6) in communication with the air compressor (4) and the pneumatic circuit (2), and a control unit, the method comprising: —while pressure in the pneumatic circuit (1) is less than a cut-out pressure, supplying the pneumatic circuit (2) with compressed air from the air compressor (4) operated at an operating speed through the air pressure management system (6), —once pressure in the pneumatic circuit (2) reaches the cut-out pressure, lowering pressure in the pneumatic circuit (2) to a target pressure, the air compressor (4) being operated at at least one deflating speed lower than the operating speed, the deflating speed being non null, —after pressure in the pneumatic circuit (2) has reached the cut-out pressure, releasing compressed air in the air pressure

Abstract: A method of controlling an air compressor of a vehicle. The absolute humidity is determined for atmospheric air entering the compressor as well as for the compressed air exiting the compressor. A liquid water mass formed or evaporated inside the compressor during a defined period of time is calculated. The above steps are repeated in order to calculate a cumulated liquid water mass inside the compressor. The compressor is stopped when the calculated cumulated liquid water mass has returned to zero and the control unit no longer receives a compressed air request.

Abstract: Method for venting a pneumatic system of a vehicle, pneumatic system and vehicle Method for venting a pneumatic system (1) of a vehicle, the pneumatic system (1) comprising an air compressor (4), a pneumatic circuit (2), an air pressure management system (6) in communication with the air compressor (4) and the pneumatic circuit (2), and a control unit, the method comprising: —while pressure in the pneumatic circuit (1) is less than a cut-out pressure, supplying the pneumatic circuit (2) with compressed air from the air compressor (4) operated at an operating speed through the air pressure management system (6), —once pressure in the pneumatic circuit (2) reaches the cut-out pressure, lowering pressure in the pneumatic circuit (2) to a target pressure, the air compressor (4) being operated at at least one deflating speed lower than the operating speed, the deflating speed being non null, —after pressure in the pneumatic circuit (2) has reached the cut-out pressure, releasing compressed air in the air pressure

Abstract: A system for generating air pressure in a hybrid vehicle, comprising an engine-driven air compressor (C1) configured to be selectively operated by an ICE engine, an electrically—driven air compressor (C2) configured to be operated by an electric motor, wherein said electric motor is supplied from the electric network, at least one air reservoir configured to store pressurized air and being configured to be connected directly or indirectly to both an outlet of the engine-driven air compressor (C1) and an outlet of the electrically-driven air compressor (C2), at least one electronic control unit (3, 3?) configured to control at least the electrically-driven air compressor (C2) according at least to a selected drive mode of the vehicle, wherein the electrically-driven air compressor (C2) is downsized compared to the engine-driven compressor (C1), and corresponding control methods.