Pressure compensator valve

The invention claimed is: 1. A valve usable as a pressure compensator in hydraulically actuated hoists, the valve comprising: a valve housing a control port, fluid inlet port and a fluid outlet port; a regulating piston longitudinally displaceably in the valve housing against biasing of an energy store between a first position connecting the fluid inlet port and the fluid outlet port in fluid communication and a second position blocking fluid communication of the fluid inlet port and the fluid outlet port by a control pressure existing at the control port; a first orifice in the regulating piston connecting the control port to a receiving space containing the energy store in fluid communication; and a second orifice in an intermediate part in the valve housing connecting the receiving space to a compensating chamber in fluid communication, the compensating chamber being connected in fluid communication to the fluid outlet port without being via a tank. 2. A valve according to claim 1 wherein the energy store is a compression spring. 3. A valve according to claim 1 wherein the second orifice is closable by a servo control blocker. 4. A valve according to claim 3 wherein the servo control blocker is actuated by a solenoid. 5. A valve according to claim 4 wherein the servo control blocker comprises a servo cone interacting with a valve seat on the intermediate part and being engaged by two blocker energy stores acting in and against a direction of action of the solenoid. 6. A valve according to claim 5 wherein the two blocker energy stores comprise compression springs. 7. A valve according to claim 5 wherein an actuating part of the solenoid is guided in a connecting part of the solenoid connecting the solenoid to the valve housing, the connecting part receiving one of the two blocker energy stores and being connected to the intermediate part. 8. A valve according to claim 7 wherein the intermediate part and the connecting part are stationarily mounted in the valve housing. 9. A valve according to claim 1 wherein the compensating chamber is at least partially in the intermediate part establishing a fluid communication connection to a collecting chamber as a further part of the compensating chamber, the compensating chamber being permanently connected in a fluid communication to the fluid outlet port in the valve housing via a fluid-conveying passageway. 10. A valve according to claim 1 wherein the regulating piston is hollow in the area adjacent the control port and in an area adjacent the energy store; and the first orifice is in a piece threaded in the regulating piston and comprises two cavities permanently connected to each other in fluid communication. 11. A valve according to claim 1 wherein the regulating piston comprises a stop part on a side of the regulating piston facing the intermediate part, the stop part being able to contact the valve housing and intermediate part in first and second stop positions, respectively, of the regulating piston. 12. A valve according to claim 11 wherein the control port extends in an axial direction into the valve housing; the fluid inlet port and the fluid outlet port extend in radial directions through the valve housing; and the regulating pistons and the valve housing define an annular space on an outer circumference of the regulating piston, the annular space completely transverses the fluid outlet port in the second stop position of the regulating piston. 13. A valve according to claim 1 wherein the first and second orifices are throttles. 14. A hydraulically activated hoist, comprising: a hydraulic power cylinder having first and second working chambers a pressure compensator valve including a valve housing a control port, fluid inlet port and a fluid outlet port, a regulating piston longitudinally displaceably in the valve housing against biasing of an energy store between a first position connecting the fluid inlet port and the fluid outlet port in fluid communication and a second position blocking fluid communication of the fluid inlet port and the fluid outlet port by a control pressure existing at the control port, a first orifice in the regulating piston connecting the control port to a receiving space containing the energy store in fluid communication, and a second orifice in an intermediate part in the valve housing connecting the receiving space to a compensating chamber in fluid communication, the compensating chamber being connected in fluid communication to the fluid outlet port without being via a tank, the control port being connected to the first working chamber in fluid communication; a pressure supply source connected in fluid communication to the fluid inlet port; and a pressure accumulator connected in fluid communication to the fluid outlet port. 15. A hydraulically actuated hoist according to claim 14 wherein the first working chamber is integrated into a fluid communication connection between the pressure compensator valve and the pressure accumulator via a first shut-off valve; and the second working chamber is connected in fluid communication to a return line to a tank via a second shut-off valve. 16. A hydraulically actuated hoist according to claim 14 wherein the regulating piston comprises a stop part on a side of the regulating piston facing the intermediate part, the stop part being able to contact the valve housing and intermediate part in first and second stop positions, respectively, of the regulating piston. 17. A hydraulically actuated hoist according to claim 16 wherein the control port extends in an axial direction into the valve housing; the fluid inlet port and the fluid outlet port extend in radial directions through the valve housing; and the regulating piston and the valve housing define an annular space on an outer circumference of the regulating piston, the annular space completely transverses the fluid outlet port in the second stop position of the regulating piston. 18. A valve usable as a pressure compensator in a hydraulically actuated hoist, the valve comprising: a valve housing a control port, a fluid inlet port, a fluid outlet port and a longitudinal axis; a regulating piston axially movable in the valve housing along the longitudinal axis against a biasing of an energy store between open positions connecting in fluid communication to the fluid inlet port and the fluid outlet port and a closed position blocking fluid communication between the fluid inlet port and the fluid outlet port by a control pressure existing at the control port; a receiving space in the regulating piston containing the energy store, the retaining space being in fluid communication with the control port; an intermediate part in the valve housing, the intermediate part having a compensating chamber connected in fluid communication to the receiving space and to the fluid outlet port; and a stop part on a side of the regulating piston facing the intermediate part, the stop part contacting the valve housing in the closed position and the intermediate part in a fully open position of the regulating position. 19. A valve according to claim 17 wherein the control port extends in an axial direction into the valve housing; the fluid inlet port and the fluid outlet port extend in radial directions through the valve housing; and the regulating piston and the valve housing define an annular space on an outer circumference of the regulating piston, the annular space completely transverses the fluid ou