Pressure control valve

The invention claimed is: 1. A pressure control valve ( 1 ), comprising: a pressure port (P); a consumer port (A); a tank port (T); a first spring (F 1 ); a piston (K) arranged in at least one working chamber (W, W 2 ), the piston (K) displaceable counter to a force of the first spring (F 1 ); and a second spring (F 2 ), wherein the second spring (F 2 ) acts on the piston (K) counter to the first spring (F 1 ), and wherein the first and second springs (F 1 , F 2 ) and area ratios of the pressure control valve ( 1 ) are designed such that the pressure port (P), in a non-pressurized condition, is connected to the consumer port (A) via an opening cross-section of the pressure control valve ( 1 ) between the pressure port (P) and the consumer port (A), and the tank port (T) is disconnected from the pressure port (P) and from the consumer port (A), the opening cross-section between the pressure port (P) and the consumer port (A) decreases upon attainment of a first limiting pressure at the consumer port (A) depending on the pressure at the pressure port (P), and the tank port (T) is disconnected from the pressure port (P) and from the consumer port (A), and upon attainment of a second limiting pressure at the consumer port (A), the consumer port (A) is connected to the tank port (T), and the pressure port (P) is disconnected from the consumer port (A) and from the tank port (T). 2. The pressure control valve ( 1 ) of claim 1 , wherein the piston (K) is configured to be acted upon by an external force (VS) that is counter to the first spring (F 1 ). 3. The pressure control valve ( 1 ) of claim 2 , wherein the external force (VS) is applied onto the piston (K) with a solenoid. 4. The pressure control valve ( 1 ) of claim 2 , wherein the external force (VS) is applied onto the piston (K) hydraulically. 5. The pressure control valve ( 1 ) of claim 1 , wherein the piston (K) comprises a first control surface (AC 1 ) and a second control surface (AC 2 ) that face opposite each other and are subjectable to the pressure acting at the consumer port (A), wherein the pressure acting on the first control surface (AC 1 ) is counter to the force of the second spring (F 2 ). 6. The pressure control valve ( 1 ) of claim 5 , wherein the first control surface (AC 1 ) is larger than the second control surface (AC 2 ). 7. The pressure control valve ( 1 ) of claim 1 , wherein the piston (K) comprises at least one bore hole (B 1 , B 2 ), the consumer port (A) connected to a differential control surface (DC) via the at least one bore hole (B 1 , B 2 ). 8. The pressure control valve ( 1 ) of claim 7 , wherein the piston (K) comprises a first control surface (AC 1 ) and a second control surface (AC 2 ) that face opposite each other and are subjectable to the pressure acting at the consumer port (A), wherein the pressure acting on the first control surface (AC 1 ) is counter to the force of the second spring (F 2 ), and the first control surface (AC 1 ) and the second control surface (AC 2 ) have the same cross-sectional area. 9. The pressure control valve ( 1 ) of claim 1 , wherein at least one pressure pocket (PT, AT, TT) is associated with the pressure port (P), the consumer port (A), and the tank port (T), the at least one pressure pocket (PT, AT, TT) arranged to bring the pressure, consumer and tanks pressure ports (P, A, T) into connection with the at least one working chamber (W, W 2 ) depending on the position of the piston (K), and the pressure pocket (AT) associated with the consumer port (A) is arranged between the pressure pocket (PT) associated with the pressure port (P) and the pressure pocket (TT) associated with the tank port (T). 10. A hydraulic system (HY) comprising the pressure control valve ( 1 ) of claim 1 , wherein a hydraulic actuator (AK, AK 1 , AK 2 , AK 3 , AK 4 , AK 5 ) is connected to the consumer port (A) of the pressure control valve ( 1 ), and the first limiting pressure at the consumer port (A) of the pressure control valve ( 1 ) corresponds to a pre-filling pressure of the actuator (AK). 11. The hydraulic system (HY) of claim 10 , further comprising a shut-off valve (VDC) connected to the pump port (P), the shut-off valve (VDC) configured for reducing a return flow of hydraulic fluid from the pump port (P) in the direction of a pressure supply of the hydraulic system (HY). 12. A motor vehicle transmission (G), comprising the hydraulic system (HY) of claim 10 , wherein the actuator (AK, AK 2 , AK 3 , AK 4 , AK 5 ) of the hydraulic system (HY) is provided for actuating at least one shift element (DK 1 , DK 2 , SE 1 , SE 2 , K 0 ) of the motor vehicle transmission (G). 13. The motor vehicle transmission (G) of claim 12 , further comprising an input shaft (GW 1 ), an output shaft (GW 2 ), and a gearshift section (GW) for actuating different transmission ratios between the input shaft (GW 1 ) and the output shaft (GW 2 ), wherein the at least one shift element (SE 1 , SE 2 ) is provided for establishing a force-fit connection in the gearshift section (GW). 14. The motor vehicle transmission (G) of claim 12 , wherein the at least one shift element (DK 1 , DK 2 ) is an integral part of a launch clutch of the motor vehicle transmission (G). 15. The motor vehicle transmission (G) of claim 12 , wherein the at least one shift element (DK 1 , DK 2 , SE 1 , SE 2 , K 0 ) is a multi-disk clutch.