초록 ▼

A single fluid valve device operable for setting an overall viscous damping level, magnetic damping strength, and low speed damping profile. A stationary, controllable magnetorheological fluid valve device comprising a first annular body having gap setting features and controllable passageways forme

A single fluid valve device operable for setting an overall viscous damping level, magnetic damping strength, and low speed damping profile. A stationary, controllable magnetorheological fluid valve device comprising a first annular body having gap setting features and controllable passageways formed within the fluid valve device, and a second body disposed adjacent to the first annular body, wherein the second body comprises a magnetic field generating means contained therein. A twin-tube damping device comprising an outer member containing an outer volume of magnetorheological fluid, an inner member containing an inner volume of magnetorheological fluid, a stationary, controllable fluid valve device disposed within the outer member, a piston rod mounted for movement with respect to the inner and outer members, a piston assembly attached to the piston rod and a pressurized volumetric compliance means.

대표청구항 ▼

A single fluid valve device operable for setting an overall viscous damping level, magnetic damping strength, and low speed damping profile. A stationary, controllable magnetorheological fluid valve device comprising a first annular body having gap setting features and controllable passageways forme

A single fluid valve device operable for setting an overall viscous damping level, magnetic damping strength, and low speed damping profile. A stationary, controllable magnetorheological fluid valve device comprising a first annular body having gap setting features and controllable passageways formed within the fluid valve device, and a second body disposed adjacent to the first annular body, wherein the second body comprises a magnetic field generating means contained therein. A twin-tube damping device comprising an outer member containing an outer volume of magnetorheological fluid, an inner member containing an inner volume of magnetorheological fluid, a stationary, controllable fluid valve device disposed within the outer member, a piston rod mounted for movement with respect to the inner and outer members, a piston assembly attached to the piston rod and a pressurized volumetric compliance means. ater tank, connected to the heat waste outlet that outputs hot water; a heat exchanger, in thermal conductive communication with the anode gas supply, the anode gas supply being controlled in temperature and pressure responsive thereto; and a pump, provided between the water tank and the heat exchanger. 2. The generating system for a fuel cell according to claim 1, wherein the heat exchanger includes a plurality of water routes surrounding the anode gas supply, the water routes being in fluid communication with the water tank, so as to enable the hot water to flow around the anode gas supply through the water routes. 3. The generating system for a fuel cell according to claim 1, wherein the anode gas supply is filled with metal hydride. 4. The generating system for a fuel cell according to claim 1, further comprising: a radiator provided between the heat exchanger and the coolant inlet of the fuel cell for facilitating temperature reduction of the water leaving the heat exchanger. 5. A heat waste recirculation and cooling system for use in a generating system for a fuel cell, comprising: a water tank, for connection to a heat waste outlet of the fuel cell that outputs hot water; a heat exchanger, in thermal conductive communication with an anode gas supply, the anode gas supply being controlled in temperature and pressure responsive thereto; and a pump, provided between the water tank and the heat exchanger. 6. The heat waste recirculation and cooling system according to claim 5, wherein the heat exchanger includes a plurality of water routes surrounding the anode gas supply, the water routes being in fluid communication with the water tank, so as to enable the hot water to flow around the anode gas supply through the water routes. 7. The heat waste recirculation and cooling system according to claim 5, wherein the anode gas supply is filled with metal hydride. 8. The heat waste recirculation and cooling system according to claim 5, further comprising: a radiator provided between the heat exchanger and the coolant inlet of the fuel cell for facilitating temperature reduction of the water leaving the heat exchanger.