Hydraulic energy recovery system

Abstract

A hydraulic energy recovery system (101) has an output drive unit (103), which can be actuated by a driver (102), and by which a hydraulic motor-pump unit (104) can be driven. In at least one energy feed position, the motor-pump unit supplies an energy storage device (106) and/or working hydraulics (107) with fluid. In a recuperation position, the motor-pump unit discharges fluid under pressure from the energy storage device (106) at least to the working hydraulics (107) and/or is used to actuate the output drive unit (103).

Claims

1. A hydraulic energy recovery system, comprising: a driver; a first output drive coupled to and actuated by said driver; a hydraulic motor-pump coupled to and driven by said first output drive, said motor-pump being in fluid communication with an energy storage and working hydraulics, supplying at least one of said energy storage or said working hydraulics with fluid in an energy feed position and discharging fluid under pressure from said energy storage at least one of to actuate said working hydraulics or to actuate said first output drive in a recuperation position; a hydraulic supply pump coupled to and driven by a second output drive, said second output drive being parallel to said motor-pump, said supply pump having an output side being in fluid communication with and supplying said working hydraulics, said supply pump being connected in fluid communication on said output side to a supply connection of said motor-pump; a supply line extending from said motor-pump joining a pressure line of said supply pump to said working hydraulics; and a priority valve connected to said supply line.

2. A hydraulic energy recovery system according to claim 1 wherein said priority valve comprises a 2/2-way switching valve.

3. A hydraulic energy recovery system according to claim 1 wherein said supply pump comprises a load sensing pump controllable by said working hydraulics.

4. A hydraulic energy recovery system according to claim 1 wherein said supply pump and said motor-pump are connected such that when a delivery volume of said sump pump is larger than a displacement of said motor-pump a higher output pressure of said sump pump or said motor-pump is present at said working hydraulics.

5. A hydraulic energy recovery system according to claim 1 wherein said motor-pump and supply pump form a hydraulic transformer feeding more energy into said energy storage as compared to feeding solely by said motor-pump.

6. A hydraulic energy recovery system according to claim 1 wherein a pressure sensor is connected to said pressure line and records pressure values for a central control.

7. A hydraulic energy recovery system according to claim 1 wherein said motor-pump unit and said energy storage are connected by supply lines to form a secondary hydraulic branch.

8. A hydraulic energy recovery system according to claim 7 wherein said secondary branch operates as a pump that supplies fluid pressure to said working hydraulics and to any other hydraulic consumers connected thereto, with energy for the fluid pressure originating from at least one of said first output drive or said energy storage; and said secondary branch operates as a motor that boosts at least one of said driver, said supply pump or connected units.

9. A hydraulic energy recovery system according to claim 1 wherein said motor-pump is operable in a four-quadrant operating mode and is electrically controllable by a central control.

10. A hydraulic energy recovery system according to claim 1 wherein a constant pressure valve is connected in a supply line extending from said motor-pump to said energy storage and comprises a 2/2-way switching valve.

11. A hydraulic energy recovery system according to claim 10 wherein a pressure sensor is connected to said supply line between said constant pressure valve and said energy storage and records pressure values for a central control.

12. A hydraulic energy recovery system according to claim 1 wherein said energy storage comprises a hydraulic accumulator.

13. A hydraulic energy recovery system according to claim 12 wherein said hydraulic accumulator is a bladder accumulator or a diaphragm accumulator.

14. A hydraulic energy recovery system according to claim 1 wherein said motor-pump is operable as a hydraulic transformer between said working hydraulics and said energy storage.

15. A hydraulic energy recovery system, comprising: a driver; a first output drive coupled to and actuated by said driver; a hydraulic motor-pump coupled to and driven by said first output drive, said motor-pump being in fluid communication with an energy storage and working hydraulics, supplying at least one of said energy storage or said working hydraulics with fluid in an energy feed position and discharging fluid under pressure from said energy storage at least one of to actuate said working hydraulics or to actuate said first output drive in a recuperation position; and a hydraulic supply pump coupled to and driven by a second output drive, said second output drive being parallel to said motor-pump, said supply pump having an output side being in fluid communication with and supplying said working hydraulics, said supply pump being connected in fluid communication on said output side to a supply connection of said motor-pump, said supply pump being a load sensing pump controllable by said working hydraulics.

16. A hydraulic energy recovery system according to claim 1 wherein a supply line extends from said motor-pump joining a pressure line of said supply pump to said working hydraulics; and a priority valve is connected to said supply line; and said priority valve comprises a 2/2-way switching valve.

17. A hydraulic energy recovery system according to claim 15 wherein said supply pump and said motor-pump are connected such that when a delivery volume of said sump pump is larger than a displacement of said motor-pump a higher output pressure of said sump pump or said motor-pump is present at said working hydraulics.

18. A hydraulic energy recovery system according to claim 15 wherein said motor-pump and supply pump form a hydraulic transformer feeding more energy into said energy storage as compared to feeding solely by said motor-pump.

19. A hydraulic energy recovery system according to claim 15 wherein a pressure sensor is connected to said pressure line and records pressure values for a central control.

20. A hydraulic energy recovery system according to claim 15 wherein said motor-pump unit and said energy storage are connected by supply lines to form a secondary hydraulic branch.

21. A hydraulic energy recovery system according to claim 20 wherein said secondary branch operates as a pump that supplies fluid pressure to said working hydraulics and to any other hydraulic consumers connected thereto, with energy for the fluid pressure originating from at least one of said first output drive or said energy storage; and said secondary branch operates as a motor that boosts at least one of said driver, said supply pump or connected units.

22. A hydraulic energy recovery system according to claim 15 wherein said motor-pump is operable in a four-quadrant operating mode and is electrically controllable by a central control.

23. A hydraulic energy recovery system according to claim 15 wherein a constant pressure valve is connected in a supply line extending from said motor-pump to said energy storage and comprises a 2/2-way switching valve.

24. A hydraulic energy recovery system according to claim 23 wherein a pressure sensor is connected to said supply line between said constant pressure valve and said energy storage and records pressure values for a central control.

25. A hydraulic energy recovery system according to claim 15 wherein said energy storage comprises a hydraulic accumulator.

26. A hydraulic energy recovery system according to claim 25 wherein said hydraulic accumulator is a bladder accumulator or a diaphragm accumulator.

27. A hydraulic energy recovery system according to claim 15 wherein said motor-pump is operable as a hydraulic transformer between said working hydraulics and said energy storage.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Referring to the drawings that form a part of this disclosure:

(2) FIG. 1 is a highly schematic, simplified circuit diagram of a hydraulic energy recovery system according to a first exemplary embodiment of the invention; and

(3) FIG. 2 is a circuit diagram of an energy recovery system according to a second exemplary embodiment of the invention, equipped with additional components.

DETAILED DESCRIPTION OF THE INVENTION

(4) FIGS. 1 and 2 show energy recovery systems 101, 201 according to exemplary embodiments of the invention. An output drive unit 103, 203, in particular, in the form of a shaft, may be actuated by a drive unit 102, 202. The output drive unit 103, 203 in this case, as is shown, may be driven directly or indirectly by a gear unit or drive gears (not shown). A hydraulic motor-pump unit 104, 204 is connected to the output drive unit 103, 203. The rotational energy of the shaft 103, 203 is converted to hydraulic energy by the motor-pump unit 104, 204.

(5) The motor-pump unit 104, 204 may be operated in a 4-quadrant operating mode in multiple positions depending on the swivel angle. The swivel angle in this case is adjusted electrically by a central control unit (CPU) 205, cf. FIG. 2. In this way, in at least one energy feed position, the motor-pump unit 104, 204 supplies an energy storage device 106, 206 and/or working hydraulics 107, 207 with fluid. In a recuperation position, fluid under pressure is retrieved from the energy storage device 106, 206 and conducted to the working hydraulics 107, 207 or is converted into mechanical energy of the output drive unit 103, 203.

(6) The energy storage device 106, 206 in this case is formed by a hydraulic accumulator in the form of a bladder accumulator. The hydraulic accumulator 106, 206 is connected to the motor-pump unit 104, 204 via an accumulator supply line 108, 208. The working hydraulics 107, 207 are, in turn, connected to the motor-pump unit 104, 204 via an oppositely facing working hydraulics supply line 109, 209. The working hydraulics 107, 207 may be an arbitrary hydraulic consumer.

(7) In the expanded embodiment according to FIG. 2, a supply pump 210 is disposed on the output drive unit 203, which may be operated in parallel to the motor-pump unit 204. The supply pump 210, on the output side 211 thereof, supplies the working hydraulics 207 via a pressure line 212, and is also connected via this output side 211 in a fluid-conducting manner to a supply connection 213 of the motor-pump unit 204. The hydraulic supply pump 211 conveys fluid from a tank 214. The supply pump 210 in this case is implemented as a load sensing pump, which is controlled by a load signal 214 coming from the working hydraulics 207. The branch 216, which connects the tank 214 to the working hydraulics 207 via the supply pump 210, is also referred to as an open loop system.

(8) The supply line 209 coming from the motor-pump unit 204 joins pressure line 212 between the supply pump 210 and the working hydraulics 207. In this way, the working hydraulics 207 may be supplied with fluid by the supply pump 210 and the motor-pump unit 204. The two units 204, 210 are connected in such a way that in the case of a greater swivel angle of the supply pump 210 as compared to a swivel angle of the motor-pump unit 204, the higher output pressure of the supply pump 210 or the motor-pump unit 204 is present at the working hydraulics 207. This arrangement ensures a constantly high level of fluid pressure available at the working hydraulics 207.

(9) The supply pump 210 and the motor-pump unit 204 are interconnected to form a hydraulic transformer 217. The fluid conveyed from the tank 214 is conveyed by the supply pump 210 at a high pressure to motor-pump unit 204, which increases the fluid pressure once again. The fluid is then fed to the energy storage device 206 via the supply line 208. In this way, a higher pressure level can be generated in the energy storage device 206. This process is also called boosting the fluid pressure.

(10) To avoid a pressure drop at the working hydraulics 207 due to drainage in the direction of the motor-pump unit 204, a priority valve 218 is provided in the supply line 209 between motor-pump unit 204 and pressure line 212. This valve 218 has two switching positions and is accordingly designed as a 2/2-way switching valve. In one switching position, the priority valve 218 comprises a non-return valve 219, which blocks fluid flow in the direction of the motor-pump unit 204. In this switching position, all of the fluid of the supply pump 210 is passed on to the working hydraulics 207.

(11) To monitor the pressure level in the pressure line 212, a pressure sensor 220 may also be provided in the pressure line 212. The pressure sensor 220 is coupled to the central control unit 205.

(12) The motor-pump unit 204, the energy storage unit 206 and the supply lines 208, 209 form a secondary hydraulic branch 221, which is also referred to as a closed loop system. The secondary branch 221 functions, depending on the relative pressure in the working hydraulics 207 relative to the energy storage device 206, as a pump for supplying the working hydraulics 207 and any additional connected hydraulic consumers. For this purpose, it uses energy, which originates from the output drive unit 203 or from the energy storage device 206. Depending on the relative pressure between the working hydraulics 207 and the energy storage device 206, the secondary branch 221 acts as a motor for boosting the drive unit 202, the supply pump 210 and, if necessary, additional connected units.

(13) A constant pressure valve 222 in the supply line 208 between the motor-pump unit 204 and the energy storage device 206 is identical in design to the priority valve. In one switching position, the constant pressure valve 222 comprises a non-return valve 223, which opens in the direction of the energy storage device 206. The constant pressure valve 222 is designed as a 2/2-way switching valve. To monitor the pressure in the energy storage device 206, a pressure sensor 224 is connected to the supply line 208 between the constant pressure valve 222 and the energy storage unit 206 for the purpose of recording pressure values for the central control unit (CPU) 205.

(14) Hence, the motor-pump unit 204, the priority valve 218, the constant pressure valve 222 and the pressure sensors 220, 224 in the pressure line 212 and in the supply line 208 are connected to the central control unit (CPU).

(15) While various embodiments have been chosen to illustrate the invention, it will be understood by those skilled in the art that various changes and modifications can be made therein without departing from the scope of the invention as defined in the claims.