NL2030114B1 - A system comprising differential hydraulic cylinders and a hydraulic machine comprising the system - Google Patents

Abstract

A system for moving a tool such as a boom, dipper, bucket or hook of a hydraulic machine such as an excavator, crane or forklift and a hydraulic machine such as an excavator, crane or forklift comprising the system, said system comprising a first bidirectional hydraulic variable displacement pump, coupled for liquid flow, via a first flow line to a first differential hydraulic cylinder; a first generator; a hydraulic energy storage arrangement arranged, when said hydraulic energy storage arrangement is in a first operational mode, to be driven by said first generator for generating and storing hydraulic energy, and when said hydraulic energy storage arrangement is in a second operational mode, arranged for driving, together with said first generator, said first bidirectional hydraulic variable displacement pump; a third bidirectional hydraulic pump, a first bidirectional hydraulic motor and a first tank, wherein said third bidirectional hydraulic pump is arranged to be driven by said first bidirectional hydraulic motor for supplying liquid from said tank to said first flow line and/or adding liquid to said tank from said first flow line; a third flow line, wherein said third hydraulic pump is controlled such that a difference of a flow rate of said liquid in said third flow line and a flow rate of said liquid in said first flow line is within a predetermined range, preferably wherein said flow rates are equal.

Description

Title: A system comprising differential hydraulic cylinders and a hydraulic machine comprising the system

Description

According to a first aspect, the present disclosure relates to a system for moving a tool such as a boom, dipper, bucket or hook of a hydraulic machine such as an excavator, crane or forklift.

According to a second aspect, the present disclosure relates to a hydraulic machine such as an excavator, crane or forklift comprising a system according to the first aspect of the present disclosure.

A known hydraulic system for moving a tool such as a boom, dipper, bucket or hook of a hydraulic machine such as an excavator, crane or forklift comprises a diesel engine for driving a hydraulic pump that is arranged for operating a hydraulic cylinder. A drawback of this known system is that it can be improved as regards the energy efficiency.

An objective of the present disclosure is to provide a hydraulic system that has a relative high energy efficiency.

The objective is achieved in that the system according to the first aspect of the present disclosure comprises differential hydraulic cylinders for moving a tool such as a boom, dipper, bucket or hook of a hydraulic machine such as an excavator, crane or forklift.

The system further comprises a first bidirectional hydraulic variable displacement pump, coupled for liquid flow, via a first flow line of said system, to one of a piston rod side and a cylinder base side of a first differential hydraulic cylinder of said differential hydraulic cylinders for operating said first differential hydraulic cylinder. Within the context of the present disclosure operating such a hydraulic cylinder is to be understood as providing and removing a liquid, such as a hydraulic oil, from said hydraulic cylinder for moving a piston rod of the hydraulic cylinder relative to a housing of the hydraulic cylinder.

Within the context of the present disclosure, a bidirectional pump is to be understood as a pump that is arranged for pumping a liquid, such as a hydraulic fluid, from a first outlet port of the pump or a second outlet port of the pump while rotating in one direction.

Within the context of the present disclosure, a hydraulic variable displacement pump refers to a hydrostatic pump.

In addition, the system comprises a first generator coupled to said first bidirectional hydraulic variable displacement pump for driving said first bidirectional hydraulic variable displacement pump. The first generator may for instance be provided with an output axle that is mechanically coupled to the first bidirectional hydraulic variable displacement pump. It is noted that due to the provision of the bidirectional pump instead of a bi-rotational pump, there is no need for the first generator to be arranged for driving the output axle thereof in two directions. This is beneficial for realising a system having a relative low complexity and thereby being relatively robust.

A hydraulic energy storage arrangement of the system according to the present disclosure is coupled to said first generator and arranged, when said hydraulic energy storage arrangement is in a first operational mode, to be driven by said first generator for generating and storing hydraulic energy, and when said hydraulic energy storage arrangement is in a second operational mode, arranged for driving, together with said first generator, said first bidirectional hydraulic variable displacement pump. The first operational mode is beneficial for realising a relative high energy efficiency of the system for instance when the first generator is outputting more power than required for operating the differential hydraulic cylinder. In this instance the surplus of output power may be converted into hydraulic energy. The second operational mode is beneficial for increasing the power provided to the first bidirectional hydraulic variable displacement pump beyond a level that may be achieved by the first generator. This allows for a first generator having a relative low maximum power output.

The system may further comprise a third bidirectional hydraulic pump, a first bidirectional hydraulic motor and a first tank, wherein said first bidirectional hydraulic variable displacement pump is coupled for liquid flow via said first flow line to said one of said piston rod side and said cylinder base side of said first differential cylinder via said first bidirectional hydraulic motor, wherein said third bidirectional hydraulic pump is arranged to be driven by said first bidirectional hydraulic motor for supplying liquid from said first tank to said first flow line and/or adding liquid to said first tank from said first flow line. This allows for setting a flow rate of liquid in said first flow line to a predetermined range or value for moving the piston rod relative to the piston housing.

It is pointed out that due to the presence of a piston rod at only one side of a piston element that is movable inside the cylinder housing for moving said piston rod, an effective surface of the piston element at the side of the piston rod is smaller than an effective surface of the piston element at the side of the cylinder base.

By providing the third bidirectional hydraulic pump, the first bidirectional hydraulic motor and the first tank the velocities of moving the piston rod in and out the cylinder housing may be adapted.

In an embodiment, the system according to the first aspect may comprise a third flow line that couples said first bidirectional hydraulic variable displacement pump for liquid flow to the other of said piston rod side and said cylinder base side of said first differential hydraulic cylinder, wherein said third hydraulic pump is controlled such that a difference of a flow rate of said liquid in said third flow line and a flow rate of said liquid in said first flow line is within a predetermined range, preferably wherein said flow rates are equal.

In an embodiment, the system according to the first aspect of the present disclosure comprises: - a second bidirectional hydraulic variable displacement pump coupled for liquid flow, via a second flow line of said system, to one of a piston rod side and a cylinder base side of a second differential hydraulic cylinder of said differential hydraulic cylinders for operating said second differential hydraulic cylinder;

wherein said first generator is further coupled to said second bidirectional hydraulic variable displacement pump for driving said second bidirectional hydraulic variable displacement pump and wherein said hydraulic energy storage arrangement is arranged, when said hydraulic energy storage arrangement is in said second operational mode, for driving, together with said first generator, said first and second bidirectional hydraulic variable displacement pumps.

The system may further comprise a fourth bidirectional hydraulic pump, a second bidirectional hydraulic motor and a second tank, wherein said second bidirectional hydraulic variable displacement pump is coupled for liquid flow via said second flow line to said one of said piston rod side and said cylinder base side of said second differential cylinder via said second bidirectional hydraulic motor, wherein said fourth bidirectional hydraulic pump is arranged to be driven by said second bidirectional hydraulic motor for supplying liquid from said second tank to said second flow line and/or adding liquid to said second tank from said second flow line.

In an embodiment, the system according to the first aspect may comprise a fourth flow line that couples said second bidirectional hydraulic variable displacement pump for liquid flow to the other of said piston rod side and said cylinder base side of said second differential hydraulic cylinder, wherein said fourth bidirectional hydraulic pump is controlled such that a difference of a flow rate of said liquid in said fourth flow line and a flow rate of said liquid in said second flow line is within a predetermined range, preferably wherein said flow rates are equal.

It is advantageous, if said first and/or second bidirectional hydraulic variable displacement pumps are coupled to said hydraulic energy storage arrangement and wherein said hydraulic energy storage arrangement is further arranged, when said hydraulic energy storage arrangement is in a third operational mode, to be driven by said first and/or second bidirectional hydraulic variable displacement pumps for generating and storing hydraulic energy. The third operational mode is beneficial for realising a relative high energy efficiency of the system.

It is beneficial if one of said third hydraulic pump and said first bidirectional hydraulic motor has a variable displacement. This is beneficial for setting a flow rate of liquid in said first flow line to a predetermined range or value for moving the piston rod relative to the piston housing.

It is beneficial if one of said fourth bidirectional hydraulic pump and 5 said second bidirectional hydraulic motor has a variable displacement. This is beneficial for setting a flow rate of liquid in said second flow line to a predetermined range or value for moving the piston rod relative to the piston housing.

In an embodiment of the system according to the first aspect, said first bidirectional hydraulic variable displacement pump is coupled for liquid flow, by said first flow line, with said piston rod side of said first differential hydraulic cylinder via said first bidirectional hydraulic motor. This is beneficial for realizing a system that is intended for use in an application wherein the tool exerts a relative large force on the piston rod when the piston rod is moved away from the cylinder base.

In an embodiment of the system according to the first aspect, said first bidirectional hydraulic variable displacement pump is coupled for liquid flow, by said first flow line, with said cylinder base rod side of said first differential hydraulic cylinder via said first bidirectional hydraulic motor. This is beneficial for realizing a system that is intended for use in an application wherein the tool exerts a relative large force on the piston rod when the piston rod is moved towards the cylinder base.

In an embodiment of the system according to the first aspect, said third hydraulic pump is arranged for supplying liquid from said first tank in a section of said first flow line between said first bidirectional hydraulic motor and said first bidirectional hydraulic variable displacement pump and/or wherein said third hydraulic pump is arranged for adding liquid to said first tank from said section of said first flow line.

It is advantageous if, said system further comprises a fifth hydraulic pump, wherein said fifth hydraulic pump is arranged for maintaining a pressure of said liquid in said first flow line within a predetermined range, by supplying liquid from said first tank or a further tank of said system to said first flow line.

In this regard, it is beneficial if said fifth hydraulic pump has a variable displacement and/or is unidirectional.

In an embodiment of the system according to the first aspect, said fifth hydraulic pump is arranged for maintaining a pressure in said first flow line in a range of 20 to 30 barg, preferably 25 barg.

In this regard, it is beneficial if the fifth hydraulic pump is arranged for further maintaining a pressure in said second, third and/or fourth flow line in a range of 20 to 30 barg, preferably 25 barg.

In a yet further embodiment of the system according to the present disclosure, the fifth hydraulic pump is arranged for maintaining a pressure in all flow lines for hydraulic fluid in a range of 20 to 30 barg, preferably 25 barg.

It is beneficial if, said system further comprises a load detector for detecting a load factor of said first generator and a control unit, communicatively coupled to said load detector, wherein said control unit is arranged for bringing said hydraulic energy storage arrangement in said first operational mode or said second operational mode taking into account a load factor detected by said load detector.

Preferably, said system further comprises a storage unit arranged for storing hydraulic energy generated, when in said first operational mode or third operational mode, by said hydraulic energy storage arrangement and supplying hydraulic energy, when said hydraulic energy storage arrangement is in said second operational mode.

Preferably, said hydraulic energy storage arrangement comprises said storage unit.

Preferably, said storage unit is arranged for operating at a maximum pressure in the range 275 barg — 400 barg, more preferable 330 barg. In other words, the storage unit is arranged for receiving and maintaining a liquid at a pressure in the range of 275 barg — 400 barg, more preferably 330 barg.

In a practical embodiment of the system according to the first aspect of the present disclosure, said storage unit comprises at least one of a hydraulic piston accumulator, a hydraulic bladder accumulator and a hydraulic diaphragm accumulator.

A hydraulic piston accumulator is beneficial for realizing a system having a relative large storage capacity. In addition, a hydraulic piston accumulator is advantageous for providing a relative large power output for operating the first bidirectional hydraulic variable displacement pump.

A hydraulic bladder accumulator is beneficial for realising a relative fast response time for storing hydraulic energy and for providing hydraulic energy for operating the first bidirectional hydraulic variable displacement pump. Preferably, a bladder of the hydraulic bladder accumulator is filled with a fluid, such as nitrogen, at a pressure in the range of 125 barg — 175 barg, more preferable 145 barg.

In this regard, it is beneficial if said hydraulic energy storage arrangement is in said first operational mode when the first generator is outputting more power than required for operating the differential hydraulic cylinder and a ratio of an actual charge of the storage unit and a maximum charge capacity of the storage unit is lower than a predetermined amount, preferably lower than 0.9, more preferably lower than 0.75. In other words, when the amount of hydraulic energy stored in the storage unit drops below the predetermined amount while the first generator is outputting more power than required, the storage unit is charged by the hydraulic energy storage arrangement. Should the amount of hydraulic energy be larger than the predetermined amount, the hydraulic energy storage arrangement will not charge the storage unit.

It is advantageous if said first generator comprises an internal combustion engine, preferably a diesel engine.

Preferably, said hydraulic energy storage arrangement comprises a storage arrangement hydraulic displacement pump, preferably a storage arrangement bidirectional hydraulic displacement pump, arranged for generating said hydraulic energy that is to be stored by said storage unit.

According to the second aspect, the present disclosure relates to a hydraulic machine such as an excavator, crane or forklift comprising a system according to the first aspect of the present disclosure for moving a tool of said hydraulic machine.

Embodiments of the system according to the first aspect of the present disclosure presented previously correspond to or are similar to embodiments of the hydraulic machine according to the second aspect of the present disclosure.

Effects of the system according to the first aspect of the present disclosure presented previously correspond to or are similar to effects of the hydraulic machine according to the second aspect of the present disclosure.

It is advantageous if said hydraulic machine is a forklift a container handler. Preferably, said container handler is arranged for handling containers according to ISO 668.2020.

In this regard, it is beneficial if said forklift or container handler is provided with a system wherein said first and/or second bidirectional hydraulic variable displacement pumps are coupled to said hydraulic energy storage arrangement and wherein said hydraulic energy storage arrangement is further arranged, when said hydraulic energy storage arrangement is in a third operational mode, to be driven by said first and/or second bidirectional hydraulic variable displacement pumps for generating and storing hydraulic energy. This is attractive for recovering a part of the energy provided, by the first generator or provided by the first generator and the hydraulic energy storage arrangement together, during lifting a load such as a container when lowering the load.

The present disclosure will now be explained by means of a description of an embodiment of a system in accordance to the first aspect, and a hydraulic machine according to the second aspect, in which reference is made to the following schematic figures, in which:

Fig. 1 a schematic overview of a system according to the first aspect of the present disclosure is shown;

Fig. 2 elements of a system according to the first aspect of the present disclosure are shown;

Fig. 3 elements of another system according to the first aspect of the present disclosure are shown;

Fig. 4 elements of a further system according to the first aspect of the present disclosure are shown;

Fig. 5 elements of yet another system according to the first aspect of the present disclosure are shown;

Fig. 6 a hydraulic machine according to the second aspect of the present disclosure is shown.

The system 1 comprises multiple differential hydraulic cylinders 3, 5, 7, 9, for moving a tool such as a boom, dipper, bucket or hook of a hydraulic machine such as an excavator or a crane.

The system 1 further comprises a first bidirectional hydraulic variable displacement pump 11 for operating first differential hydraulic cylinders 3, 5 of the differential hydraulic cylinders 3, 5, 7, 9. The first bidirectional hydraulic variable displacement pump 11 is coupled, for liquid flow, via a first flow line 25 to a piston rod side 27 of the first differential hydraulic cylinder 3, 5 and via a third flow line 39 to a cylinder base side 37 of the first differential hydraulic cylinder 3, 5. Both the first flow line 25 and the third flow line 39 are coupled via a pilot operated check valve 34, wherein the pilot operated check valve 34 is pilot to open, to the respective cylinder base side 37 and the piston rod side 27 of the first differential hydraulic cylinder 3, 5, for blocking liquid flow from the first differential hydraulic cylinder 3, 5 back into the first flow line 25 and/or the third flow line 39. The valve 34 is further arranged for completely blocking the flow from the first flow line 25 and/or the third flow line 39 into the first differential hydraulic cylinder 3, 5, for example when the system 1 is not operational.

The system 1 furthermore comprises a second bidirectional hydraulic variable displacement pump 13 for operating second differential hydraulic cylinders 7,

9 of the differential hydraulic cylinders 3, 5, 7, 9. The second bidirectional hydraulic variable displacement pump 13 is coupled, for liquid flow, via a second flow line 31 and via a further pilot operated check valve (not shown), wherein the further pilot operated check valve is pilot to open, to a piston rod side of the second differential hydraulic cylinder 7, 9 and via a fourth flow line 40 and via the further check valve to a cylinder base side 37 of the second differential hydraulic cylinder 7, 9.

A first generator 15, which comprises an internal combustion engine, is coupled to the first bidirectional hydraulic variable displacement pump 11 and the second bidirectional hydraulic variable displacement pump 13 for driving the first bidirectional hydraulic variable displacement pump 11 and the second bidirectional hydraulic variable displacement pump 13.

A hydraulic energy storage arrangement 2 is coupled to the first generator 15 as well to the first and second bidirectional hydraulic variable displacement pumps 11, 13. The hydraulic energy storage arrangement 2 comprises a storage arrangement bidirectional hydraulic displacement pump 17 arranged for generating the hydraulic energy that is to be stored by a storage unit 41 of the hydraulic energy storage arrangement 2. When the hydraulic energy storage arrangement 2 is in a first operational mode, the hydraulic energy storage arrangement 2 is driven by the first generator 15 for generating and storing hydraulic energy. When the hydraulic energy storage arrangement 2 is in a second operational mode, the hydraulic energy storage arrangement 2 is arranged for driving, together with the first generator 15, the first and second bidirectional hydraulic variable displacement pump 11,13. When the hydraulic energy storage arrangement 2 is in a third operational mode, the hydraulic energy storage arrangement 2 is driven by the first and/or second bidirectional hydraulic variable displacement pump 11, 13 for generating and storing hydraulic energy.

In the first and third operational mode, the generated hydraulic energy is stored in the storage unit 41 if a ratio of an actual charge of the storage unit 41 and a maximum charge capacity of the storage unit 41 is lower than 0.75. In case the hydraulic energy storage arrangement 2 is in the second operational mode, the stored hydraulic energy is supplied to the first and second bidirectional hydraulic variable displacement pumps 11,13.

The hydraulic energy storage arrangement 2 further comprises a first storage arrangement check valve 4 and a pilot operated storage arrangement check valve 18. The first storage arrangement check valve 4 is provided in a bypass flow line 6 such that a flow via said bypass first storage arrangement check valve 4 is blocked in a flow direction away from said storage unit 41 and allows a liquid flow. The pilot operated storage arrangement check valve 18 is provided in a flow line of the hydraulic energy storage arrangement 2 provided between the storage arrangement bidirectional hydraulic displacement pump 17 and the storage unit 41.

A load detector 43 is arranged for detecting a load factor of the first generator 15 and a control unit 35, communicatively coupled to the load detector 43, arranged for bringing the hydraulic energy storage arrangement 2 in the first operational mode or the second operational mode taking into account a load factor detected by the load detector 43.

The system 1 furthermore comprises a third bidirectional hydraulic pump 19, a first bidirectional hydraulic motor 21 and a first tank 23. The hydraulic motor 21 is coupled in the first flow line 25, wherein the third bidirectional hydraulic pump 19 is arranged to be driven by the first bidirectional hydraulic motor 21 for supplying liquid from the tank 23 in a section of the first flow line 25 between the first bidirectional hydraulic motor 21 and the first bidirectional hydraulic variable displacement pump 11 and/or adding liquid to the tank 23 from the section of the first flow line 25. The third hydraulic pump 19 is controlled such that a flow rate of the liquid in the third flow line 39 and a flow rate of the liquid in the first flow line 25 are preferably equal.

The system 1 additionally comprises a fifth hydraulic pump 29 and a further tank 33. The fifth hydraulic pump 29 has a variable displacement. Upstream from the first bidirectional hydraulic motor 21, the fifth hydraulic pump 29 is coupled via a check valve 36 to an upstream section of the first flow line 25. Downstream from the first bidirectional hydraulic motor 21, the fifth hydraulic pump 29 is coupled via a further check valve 38 to a downstream section of the first flow line 25. The fifth hydraulic pump 29 is furthermore coupled via a yet further check valve 40 to the third flow line 39. The fifth hydraulic pump 29 is arranged for maintaining a pressure of the liquid in the first flow line 25 and the third flow line 39 within a predetermined range of 20 to 30 barg, by supplying liquid from the further tank 33 to the first flow line 25 and the third flow line 39. In an embodiment of the system 1, the first tank 23 and the further tank 33 may be one and the same tank. In other words the further tank 33 may be a part of the first tank 23.

Fig. 2 and Fig. 3 disclose elements of different embodiments of the system 1 according to the first aspect of the present disclosure as described above, in which Fig. 2 discloses the third bidirectional hydraulic pump 19 with a variable displacement and Fig.3 discloses the first bidirectional hydraulic motor 21 with a variable displacement.

Fig. 4 discloses elements of a yet further embodiment of system 1 according to the first aspect of the present disclosure, in which the first bidirectional hydraulic motor 21 is included in the third flow line 39, wherein the third bidirectional hydraulic pump 19 is arranged to be driven by the first bidirectional hydraulic motor 21 for supplying liquid from the tank 23 in a section of the third flow line 39 between the first bidirectional hydraulic motor 21 and the first bidirectional hydraulic variable displacement pump 11 and/or adding liquid to the tank 23 from the section of the third flow line 39, such that the flow rates in both flow lines 25, 39 are preferably equal. In this embodiment, the fifth hydraulic pump 29 is coupled via a check valve 36 to the first flow line 25. Upstream from the first bidirectional hydraulic motor 21, the fifth hydraulic pump 29 is coupled via a further check valve 38 to an upstream section of the third flow line 39. Downstream from the first bidirectional hydraulic motor 21, the fifth hydraulic pump 29 is coupled via a yet further check valve 40 to a downstream section of the third flow line 39.

The embodiments shown in Fig. 2, 3 and 4 described previously, can equivalently be applied to the part of system 1 comprising the second bidirectional hydraulic variable displacement pump 13, coupled via the second and fourth flow lines 31, 40 to the second differential hydraulic cylinders 7, 9.

Fig. 5 discloses elements of yet another system according to the first aspect of the present disclosure, wherein the system 1 comprises additional bidirectional hydraulic variable displacement pumps 12, 14 and 16 for operating an additional set of differential hydraulic cylinders. The first generator 15 and the hydraulic energy storage arrangement 2 are coupled to the bidirectional hydraulic variable displacement pumps 11, 12, 13, 14. When the hydraulic energy storage arrangement 2 is in a second operational mode, the hydraulic energy storage arrangement 2 is arranged for driving, together with the first generator 15, the bidirectional hydraulic variable displacement pump 11, 12, 13, 14. When the hydraulic energy storage arrangement 2 is in a third operational mode, the storage arrangement bidirectional hydraulic displacement pump 17 is driven by the one or more of the bidirectional hydraulic variable displacement pumps 11, 12, 13, 14 for generating hydraulic energy, which is stored in storage unit 41.

Fig. 6 discloses a forklift 101 comprising a moving a tool 105 and the system 1 according to the first aspect of the present disclosure for moving a tool 105 of the forklift and for recovering a part of the energy provided during lifting a load such as a container when lowering the load.

Claims (1)

CONCLUSIONS 1. A system (1) comprising hydraulic differential cylinders (3, 5, 7, 9) for moving a tool such as a mast, bucket, bucket or hook of a hydraulic machine such as an excavator or a crane, the system (1 ) comprising - a first bi-directional variable displacement hydraulic pump (11), coupled for fluid flow, through a first flow line (25) of the system (1), to one of a piston rod side (27) and a cylinder base side (37) of a first hydraulic differential cylinder (3, 5) of the hydraulic differential cylinders (3, 5, 7, 9) for operating the first hydraulic differential cylinder (3, 5); - a first generator (15) coupled to the first bidirectional variable displacement hydraulic pump (11, 13) for driving the first bidirectional variable displacement hydraulic pump (11, 13); - a hydraulic energy storage arrangement (2) coupled to the first generator (15) and arranged, when the hydraulic energy storage arrangement (2) is in a first operational mode, to be driven by the first generator (15) for the generation and storage of hydraulic energy, and when the hydraulic energy storage arrangement (2) is in a second operational mode, adapted to drive, together with the first generator (15), the first bi-directional variable displacement hydraulic pump (11 , 13); - a third bidirectional hydraulic pump (19), a first Dbidirectional hydraulic motor (21) and a first reservoir (23), the first bidirectional variable displacement hydraulic pump (11) being coupled for fluid flow through the first flow line (25) to the one of the piston rod side (27) and the cylinder base side (37) of the first differential cylinder (3, 5) through the first bidirectional hydraulic motor (21), the third bidirectional hydraulic pump (19) being arranged to be driven by the first bidirectional hydraulic motor (21) for supplying fluid from the reservoir (23) to the first flow line (25) and/or adding fluid to the reservoir (23) from the first flow line (25); - a third flow line (39) coupling the first bidirectional variable displacement hydraulic pump (11) for fluid flow to the other of the piston rod side (27) and the cylinder base side (37) of the first hydraulic differential cylinder (3, 5), wherein the third hydraulic pump (19) is controlled such that a difference between a flow rate of the liquid in the third flow line (39) and a flow rate of the liquid in the first flow line {25) is within a predetermined range, preferably wherein the flow rates are equal. The system (1) according to claim 1, wherein the system (1) further comprises: - a second bidirectional variable displacement hydraulic pump (13) coupled for fluid flow, via a second flow line (31) of the system (1), to one of a piston rod side and a cylinder base side of a second hydraulic differential cylinder {7, 9) of the hydraulic differential cylinders (3, 5, 7, 9) for operating the second hydraulic differential cylinder (7, 9); wherein the first generator (15) is further coupled to the second bidirectional variable displacement hydraulic pump (11, 13) for driving the second bidirectional variable displacement hydraulic pump (11, 13) and wherein the hydraulic energy storage arrangement (2 ) is arranged, when the hydraulic energy storage arrangement (2) is in the second operational mode, together with the first generator (15), to drive the first and second bidirectional variable displacement hydraulic pumps (11, 13). The system (1) according to claim 1 or 2, wherein the first and/or second bidirectional variable displacement hydraulic pumps (11, 13) are coupled to the hydraulic energy storage arrangement (2) and wherein the hydraulic energy storage arrangement ( 2) is further arranged, when the hydraulic energy storage arrangement (2) is in a third operational mode, to be driven by the first and/or second bidirectional variable displacement hydraulic pumps (11, 13) for generating and storing of hydraulic energy. The system (1) according to any one of the preceding claims, wherein one of the third hydraulic pump (19) and the first bidirectional hydraulic motor (21) has a variable displacement. The system (1) according to any of the preceding claims, wherein the first bi-directional variable displacement hydraulic pump (11) is coupled for fluid flow, through the first flow line (25), to the piston rod side (27) of the first hydraulic differential cylinder (3, 5) via the first bidirectional hydraulic motor (21). The system (1) according to any of the preceding claims, wherein the third hydraulic pump (19) is adapted to supply fluid from the reservoir (23) in a section of the first flow line (25) between the first bi-directional hydraulic motor (21) and the first bidirectional variable displacement hydraulic pump (11) and/or wherein the third hydraulic pump (19) is adapted to supply fluid to the reservoir (23) from the section of the first flow line (25) . The system (1) according to any of the preceding claims, wherein the system (1) further comprises a fifth hydraulic pump (29), the fifth hydraulic pump (29) being adapted to maintain a pressure of the fluid in the first flow line (25) within a predetermined range, by supplying liquid from the reservoir (23) or a further reservoir (33) of the system (1) to the first flow line (25). The system (1) according to claim 7, wherein the fifth hydraulic pump (29) has a variable displacement. The system (1) according to claim 7 or 8, wherein the fifth hydraulic pump (29) is adapted to maintain a pressure in the first flow line (25) in a range of 20 to 30 barg. The system (1) according to any of the preceding claims, wherein the system further comprises a load detector (43) for detecting a load factor of the first generator (15) and a control unit (35) communicatively coupled to the load detector ( 43), the control unit (35) being arranged to put the hydraulic energy storage arrangement (2) in the first operational mode or the second operational mode taking into account a load factor detected by the load detector (43). The system (1) according to any of the preceding claims, wherein the hydraulic energy storage arrangement (2) further comprises a storage unit (41) adapted to store hydraulic energy generated, when in the first operational mode, by the hydraulic energy storage arrangement (2) and supplying hydraulic energy, when the hydraulic energy storage arrangement (2) is in the second operational mode. The system (1) according to any of the preceding claims, wherein the first generator comprises an internal combustion engine. The system (1) according to any one of the preceding claims, wherein the hydraulic energy storage arrangement (2) comprises a storage arrangement hydraulic pump (17), preferably a storage system bi-directional hydraulic pump, adapted to generate energy generated by the storage arrangement. for hydraulic energy (2) to store hydraulic energy. A hydraulic machine (101) such as an excavator, crane, forklift or container handler, comprising a system (1) according to any one of the preceding claims for moving a tool of the hydraulic machine (101). The hydraulic machine (101) according to claim 14, comprising a system (1) according to claim 3 for recovering part of the energy supplied by the first generator or supplied by the first generator (15) and the storage arrangement for hydraulic energy (2) collectively, when lifting a load such as a container when lowering the load.