Suspension system for vehicles and method for fitting vehicle parts with suspension

What is claimed is: 1. A suspension system for a vehicle seat, comprising: at least a first and a second part, the two parts being mounted to one another via at least one arm such that the two parts are oscillatorily movable and spring-loaded with respect to one another; a closed hydropneumatic circuit comprising: a hydraulic medium circulating in a flow direction in the closed hydropneumatic circuit; at least one control element that is connected to at least one of the two parts, the at least one control element having the hydraulic medium in a first hydraulic volume and having an action surface that is configured to move in at least one direction, which causes the two parts to move with respect to one another, wherein the first hydraulic volume of the at least one control element and the action surface are operably connected; and at least one first hydropneumatic spring having a gaseous medium in a gas volume at a gas pressure and having the hydraulic medium in a second hydraulic volume at a hydraulic pressure; and wherein a change in the gas pressure of the at least one first hydropneumatic spring causes a change in the hydraulic pressure of the hydraulic medium, which changes a force acting on the action surface of the at least one control element. 2. The suspension system according to claim 1 , wherein the action surface arranged in the at least one control element is arranged facing the hydraulic medium and is movable in two opposing movement directions by means of oscillatory movements of the two parts with respect to one another, wherein a movement of the action surface in the direction towards the hydraulic medium increases the hydraulic pressure. 3. The suspension system according to claim 1 , wherein the movement direction of the at least one control element is arranged parallel, perpendicular and/or at an angle to a direction of the oscillatory movements of the two parts. 4. The suspension system according to claim 1 , wherein the closed hydropneumatic circuit further comprises: an adjustable volume flow regulation component, arranged downstream from the at least one control element and upstream from the at least one first hydropneumatic spring in the flow direction of said closed hydropneumatic circuit, for regulating a volume flow of the hydraulic medium of the closed hydropneumatic circuit, and/or a hydraulic pump arranged downstream from the at least one first hydropneumatic spring and upstream from the at least one control element in the flow direction. 5. The suspension system according to claim 4 , wherein the volume flow regulation component is adjustable dependent on acceleration and/or speed values calculable from a sensor and based on the oscillatory movements of the two parts with respect to one another. 6. The suspension system according to claim 1 , wherein the hydraulic pressure is changeable by way of a level regulation device arranged in the hydropneumatic circuit, the level regulation device comprising a first throttle valve, arranged between the at least one control element and a hydraulic pump, and a second hydropneumatic spring connected in series therewith, a non-return valve connected in series and a second throttle valve connected in parallel with the non-return valve being arranged between the first throttle valve and the second hydropneumatic spring. 7. The suspension system according to claim 4 , wherein the volume flow regulation component is formed by at least one of a servo-hydraulic valve, a proportional valve, an electrorheological valve, and a magnetorheological valve. 8. The suspension system according to claim 1 , wherein the at least one control element is formed by at least one of a single-action or dual-action hydraulic cylinder, a membrane actuator, and a bellows actuator. 9. The suspension system according to claim 1 , wherein the gaseous medium of the at least one first hydropneumatic spring is nitrogen and the hydraulic medium of the closed hydropneumatic circuit is oil. 10. The suspension system according to claim 6 , wherein the gaseous medium of the first spring and a gaseous medium of the second spring are nitrogen. 11. A method for moving parts of a hydropneumatic suspension for a vehicle seat comprising: circulating a hydraulic medium in a flow direction in a closed hydropneumatic circuit having at least one first hydropneumatics spring, at least one control element, and an adjustable volume flow regulation component arranged downstream from the at least one control element and upstream from the at least one first hydropneumatics spring in the flow direction; providing a gaseous medium in a gas volume at a gas pressure in the at least one first hydropneumatics spring and providing the hydraulic medium in a hydraulic volume at a hydraulic pressure; providing an action surface in the at least one control element that is connected to a first part and a second part, which are connected via at least one arm such that the two parts are oscillatorily movable and spring-loaded with respect to one another; changing the gas pressure of the gaseous medium in the at least one first hydropneumatics spring, which changes the hydraulic pressure of the hydraulic medium; regulating, by the adjustable volume flow regulation component, a volume flow of the hydraulic medium; changing, by the change of the hydraulic pressure of the hydraulic medium, a force generated on the action surface of the at least one control element to move the action surface in at least one direction and to move the two parts with respect to each other. 12. The method according to claim 11 , wherein the volume flow of the hydraulic medium of the closed hydropneumatic circuit is driven by means of a hydraulic pump, arranged downstream from the at least one first hydropneumatics spring and upstream from the at least one control element in the flow direction of the closed hydropneumatic circuit, in an on state of the hydraulic pump. 13. The method according to claim 11 , wherein the volume flow of the hydraulic medium is kept constant by means of the volume flow regulation component in an off state of a hydraulic pump, and passive suspension is thus provided. 14. The method according to claim 11 , wherein the volume flow of the hydraulic medium is adjusted by means of the volume flow regulation component dependent on acceleration and/or speed values, calculable from a sensor and based on the oscillatory movements of the two parts with respect to one another, in an off state of a hydraulic pump, and semi-active suspension is thus provided. 15. The method according to claim 11 , wherein the volume flow of the hydraulic medium is adjusted by means of the volume flow regulation component dependent on acceleration and/or speed values, calculable from a sensor and based on the oscillatory movements of the two parts with respect to one another, in an on state of a hydraulic pump, and fully-active suspension is thus provided. 16. The method according to claim 12 , wherein the volume flow of the hydraulic medium is adjusted to a minimum value by means of the volume flow regulation component in the on state of the pump, and seat height adjustment is thus provided.