Heat recovery system for an internal combustion engine

The invention claimed is: 1. A heat recovery system for an internal combustion engine comprising: a heat exchanger, flowed through by a fluidic heat carrier, for transferring the heat from a combustion exhaust gas of the internal combustion engine to the heat carrier, an expansion turbine, flowed through by the heat carrier, for converting the heat transferred to the heat carrier into mechanical work, a cyclically closed duct system for connecting the heat exchanger with the expansion turbine, at least one displacement pump for conveying the heat carrier through the duct system in a predetermined flow direction, a pump drive for driving the at least one displacement pump, an impermeable separating membrane providing a fluid-tight separation of the heat carrier from the pump drive, a bellows surrounding the at least one displacement pump, the bellows having a wall that forms the separating membrane, a hydraulic fluid at least partially filling the bellows, a valve having a starting position, in which the at least one displacement pump conveys the heat carrier through the duct system, and an idle position, in which the at least one displacement pump does not convey the heat carrier through the duct system, and a discharge duct fluidly connecting the bellows with a fluid reservoir, for discharging the hydraulic fluid from the bellows, wherein the valve is configured so that in the starting position the valve blocks the discharge duct, and in the idle position the valve frees the discharge duct in the direction of the fluid reservoir. 2. The heat recovery system according to claim 1 , further comprising a short circuit line fluidly connecting the feed with the discharge to hydraulically short circuit the at least one displacement pump, wherein the valve is configured so that: in the starting position the valve blocks the short circuit line, and in the idle position the valve frees the short circuit line in the direction of the feed. 3. The heat recovery system according to claim 1 , wherein the at least one displacement pump includes three displacement pumps each having a valve, which acts on the respective displacement pump. 4. The heat recovery system according to claim 1 , wherein the at least one displacement pump includes three displacement pumps having a shared valve, which acts on each displacement pump. 5. The heat recovery system according to claim 1 , wherein the pump drive is connected mechanically with the internal combustion engine. 6. The heat recovery system according to claim 1 , wherein the valve is a proportional valve with at least 3 different adjustable opening positions. 7. The heat recovery system according to claim 6 , further comprising a short circuit line fluidly connecting the feed with the discharge to hydraulically short circuit the at least one displacement pump, wherein the valve is configured so that: in the starting position the valve blocks the short circuit line, and in the idle position the valve frees the short circuit line in the direction of the feed. 8. The heat recovery system according to claim 1 , wherein the separating membrane is made of at least one of a metal and a plastic. 9. The heat recovery system according to claim 8 , wherein the at least one displacement pump includes three displacement pumps each having a valve, which acts on the respective displacement pump. 10. The heat recovery system according to claim 8 , wherein the at least one displacement pump includes three displacement pumps having a shared valve, which acts on each displacement pump. 11. The heat recovery system according to claim 1 , wherein the pump drive comprises a reciprocating piston movably supported in the hydraulic fluid, so that a stroke movement of the reciprocating piston unfolds the bellows hydromechanically by means of the hydraulic fluid. 12. The heat recovery system according to claim 11 , wherein the at least one displacement pump has a cylinder in fluid connection with the duct system, in which cylinder the reciprocating piston is mounted. 13. The heat recovery system according to claim 12 , wherein the at least one displacement pump comprises: a feed for aspirating the heat carrier, and a discharge for discharging the heat carrier, which connects the cylinder with the duct system. 14. The heat recovery system according to claim 13 , wherein the at least one displacement pump comprises: a feed valve for blocking the feed, and a discharge valve for blocking the discharge, wherein the feed valve and the discharge valve are spring-loaded check valves and respectively have a passage direction which corresponds to the flow direction. 15. A heat recovery system for an internal combustion engine comprising: a heat exchanger through which a fluidic heat carrier is flowable, the heat exchanger being configured to transfer heat from a combustion exhaust gas of the internal combustion engine to the heat carrier; an expansion turbine through which the heat carrier is flowable, the expansion turbine being configured to convert the heat transferred to the heat carrier by the heat exchanger into mechanical work; a cyclically closed duct system connecting the heat exchanger with the expansion turbine; at least one displacement pump configured to convey the heat carrier through the duct system in a predetermined flow direction; a pump drive configured to drive the at least one displacement pump; a bellows surrounding the pump drive, the bellows having a wall that forms an impermeable membrane providing a fluid-tight separation between the heat carrier and the pump drive; wherein the pump drive comprises a hydraulic fluid at least partially filling the bellows, and a reciprocating piston movably supported in the hydraulic fluid, so that a stroke movement of the reciprocating piston unfolds the bellows hydromechanically by means of the hydraulic fluid; a valve having a starting position, in which the at least one displacement pump conveys the heat carrier through the duct system, and an idle position, in which the at least one displacement pump does not convey the heat carrier through the duct system; and a discharge duct fluidly connecting the bellows with a fluid reservoir, for discharging the hydraulic fluid from the bellows, wherein the valve is configured so that in the starting position the valve blocks the discharge duct, and in the idle position the valve frees the discharge duct in the direction of the fluid reservoir.