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Title:
HYDROSTATIC TRANSMISSION SYSTEM
Document Type and Number:
WIPO Patent Application WO/2020/099209
Kind Code:
A1
Abstract:
The present disclosure describes a hydrostatic transmission system that comprises a hydraulic pump and a hydraulic motor. First and second work lines interconnect the hydraulic pump and the hydraulic motor. The first work line is provided for transmission of a hydraulic fluid at a first pressure and the second work line is provided for transmission of the hydraulic fluid at a second pressure, the first and the second pressures being different. A drain line connects the hydraulic motor to a fluid reservoir. A loop flushing valve fluidly connects between the first and second work lines and the hydraulic motor. An impeller fluidly connects between the loop flushing valve and the hydraulic motor. The impeller couples to the drive shaft so as to convert at least some of the energy of the hydraulic fluid outgoing from the loop flushing valve into mechanical power acting on the drive shaft.

Inventors:
FRANZONI FEDERICA (IT)
NATALI FABIO (IT)
SASSI ALESSANDRO (IT)
Application Number:
PCT/EP2019/080379
Publication Date:
May 22, 2020
Filing Date:
November 06, 2019
Export Citation:
Click for automatic bibliography generation   Help
Assignee:
DANA MOTION SYS ITALIA SRL (IT)
International Classes:
F16H61/4104; F04C11/00; F15B21/14
Foreign References:
US20170198730A12017-07-13
US9759317B22017-09-12
US20040118623A12004-06-24
US20160281745A12016-09-29
DE19952167A12000-06-29
US9759317B22017-09-12
Attorney, Agent or Firm:
PFENNING, MEINIG & PARTNER MBB (DE)
Download PDF:
Claims:
Claims

1. A hydrostatic transmission system (10) comprising:

a hydraulic pump (12) coupled to a drive means (14);

a hydraulic motor (16) having a drive shaft (18) for coupling to a mechanically driven device;

a first and a second work lines (20, 22) interconnecting the hydraulic pump (12) and the hydraulic motor (16) wherein the first work line (20) is provided for transmission of a hydraulic fluid at a first pressure and the second work line (22) is provided for transmission of the hydraulic fluid at a second pressure, the first and the second pressures being different;

a drain line (24) connecting the hydraulic motor (16) to a fluid reservoir (26);

a loop flushing valve (28) fluidly connected between the first and second work lines (20, 22) and the hydraulic motor (16);

characterized in that it comprises

at least one impeller (30) fluidly connected between the loop flushing valve (28) and the hydraulic motor (16) wherein the at least one impeller (30) is coupled to the drive shaft (18) so as to convert at least some of the energy of the hydraulic fluid outgoing from the loop flushing valve (28) into mechanical power acting on the drive shaft (18).

2. The hydrostatic transmission system (10) of claim 1 wherein the at least one impeller (30) is provided on a cylinder block (75) wherein the drive shaft (18) is configured to jointly rotate with the cylinder block (75).

3. The hydrostatic transmission system (10) of claim 1 wherein the at least one impeller (30) is mounted to the drive shaft (18).

4. The hydrostatic transmission system (10) of claims 1, 2 or 3 wherein the at least one impeller (30) is bidirectionally rotatable, the at least one impeller (30) being rotatable in a first direction and in a second opposite direction.

5. The hydrostatic transmission system (10) of claims 1, 2 or 3 comprising a first impeller (30’) and a second impeller (30”) wherein the first impeller (30’) is rotatable in a first direction and the second impeller (30) is rotatable in a second direction.

6. The hydrostatic transmission system (10) of any one of preceding claims further comprising a booster line (36) for returning hydraulic fluid from the second and third relief lines (54, 56) to either the first work line (20) or the second work line (22), whichever work line (20, 22) having the lower pressure.

7. The hydrostatic transmission system (10) of claim 6 wherein a charge pump (38) is provided on the booster line (36).

8. The hydrostatic transmission system (10) of claim 7 wherein the charge pump (38) is coupled to the hydraulic pump (12), the charge pump (38) is configured to be driven by the drive means (14).

9. The hydrostatic transmission system (10) of any one of preceding claims 6 to 8 further comprising a line (41) extending from the return line (36), a first pressure relief valve (40) being provided on line (41) wherein the line (41) is connected between the booster line (36) and the loop flushing valve (28), the loop flushing valve (28) fluidly connecting the drain line (24) to the first pressure relief valve (40) at a second pool position (64).

10. The hydrostatic transmission system (10) of any one of preceding claims wherein the at least one impeller (30) is fluidly connected to the first work line (20) through the loop flushing valve (28), the loop flushing valve (28) being at a first spool position (62).

11. The hydrostatic transmission system (10) of any one of preceding claims wherein the at least one impeller (30) is fluidly connected to the second work line (22) through the loop flushing valve (28), the loop flushing valve (28) being at a third spool position (66).

12. The hydrostatic transmission system (10) of any one of preceding claims wherein the at least one impeller (30) is integrated in the hydraulic motor (16).

13. The hydrostatic transmission system (10) of any one of preceding claims wherein the hydraulic motor (16) is either of the bent axis type or of the swash plate type.

Description:
HYDROSTATIC TRANSMISSION SYSTEM

Technical Field

This disclosure relates to the field of hydraulic transmission systems and, particularly, to the field of hydraulic hydrostatic transmission systems, and more particularly, to the field of energy recovery in hydrostatic transmission systems.

Background

A hydraulic transmission system involves transmission of power through a pressurization of a hydraulic fluid in a closed loop system. The pressure is supplied by a hydraulic pump and is used to drive a hydraulic actuator. A hydrostatic transmission system generally has a variable displacement main pump that is connected with a hydraulic motor in a closed hydraulic circuit via a high pressure line and a low pressure line. Changing the displacement of the main pump changes the output rate that controls the rotational speed of the hydraulic motor. The hydraulic pump output can also be reversed thereby reversing the directional rotation of the hydraulic motor attached to the main pump. Both acceleration and deceleration of the transmission are controlled by varying the displacement of the hydraulic pump from its neutral position.

Under certain operating conditions a high amount of heat can be generated within the closed hydraulic circuit due to low leakage in the hydraulic pump and the hydraulic motor at low operating loads, thereby, resulting in a small amount of oil being exchanged between the closed hydraulic circuit and a fluid reservoir. Thus, when running hydrostatic transmissions at low pressure loads concurrently with high pump and/or motor speed, there is need to maintain a desired operating temperature of the hydraulic fluid in the closed hydraulic circuit.

Loop flushing valves are used conventionally for flushing of hydraulic fluid from the closed hydraulic circuit. The flushed hydraulic fluid is sent to the fluid reservoir and is replaced by means of a charge pump. The flushing valve that is connected to both the high pressure and low pressure line. The flushing valve is, generally, configured to select the lower pressure line of the two pressure lines in the closed hydraulic circuit.

The removal of hydraulic fluid through results in energy and system efficiency losses. As the hydraulic fluid in the closed circuit is pressurized, circuit flushing flow causes a frictional loss or waste of hydrostatic energy. This loss may require more power from an electric motor or an internal combustion engine.

US9759317 discloses a closed hydraulic circuit between a hydraulic pump and a hydraulic motor that are connected to one another via working lines. A flushing pump is provided in order to feed a pressure medium into the working lines. An output connection of a flushing valve is provided in order to discharge excess pressure medium from the working lines. At least one hydraulic consumer is provided to convert at least some of the volume flow discharged from the hydraulic circuit into mechanical power. The hydraulic consumer is connected downstream of the output connection. The hydraulic consumer may be a hydraulic motor connected in parallel to drive the flushing pump so that less energy is required for operating the flushing pump or the hydraulic pump.

The present disclosure is directed, at least in part, to improving or overcoming one or more aspects of the prior art system. In particular, there is a need for energy recovery from the loss of hydrostatic energy due to the circuit flushing flow.

Brief Summary of the Invention

The present disclosure describes a hydrostatic transmission system that comprises a hydraulic pump coupled to a drive means; a hydraulic motor having a drive shaft for coupling to a mechanically driven device; a first and a second work lines interconnecting the hydraulic pump and the hydraulic motor wherein the first work line is provided for transmission of a hydraulic fluid at a first pressure and the second work line is provided for transmission of the hydraulic fluid at a second pressure, the first and the second pressures being different; a drain line connecting the hydraulic motor to a fluid reservoir; a loop flushing valve fluidly connected between the first and second work lines and the hydraulic motor; characterized in that it comprises at least one impeller fluidly connected between the loop flushing valve and the hydraulic motor wherein the at least one turbine is coupled to the drive shaft so as to convert at least some of the energy of the hydraulic fluid outgoing from the loop flushing valve into mechanical power acting on the drive shaft.

The hydraulic transmission system enables the recovery of energy due to circuit flushing flow through the impeller.

Brief Description of the Drawings The foregoing and other features and advantages of the present disclosure will be more fully understood from the following description of various embodiments, when read together with the accompanying drawings, in which:

Fig. 1 is a hydrostatic transmission system, in a first embodiment, according to the present disclosure;

Fig. 2 is the hydrostatic transmission system of Fig. 1 in a first operation configuration;

Fig. 3 is the hydrostatic transmission system of Fig. 1 in a second operation configuration;

Fig. 4 is a hydrostatic transmission system, in a second embodiment, according to the present disclosure;

Fig. 5 is a hydrostatic transmission system, in a third embodiment, according to the present disclosure;

Fig. 6 is an isometric view of a turbine provided on a drive shaft of a motor with a bent axis piston according to the present disclosure;

Fig. 7 is a sectional view of a turbine provided on a shaft of a motor according to the present disclosure;

Fig. 8 is an isometric view of fluid lines from a flushing valve fluidly connected to a turbine provided on a shaft of a motor according to the present disclosure;

Fig. 9 is an enlarged view of the fluid lines fluidly connected to the turbine of Fig. 8; and

Fig. 10 is an isometric view of a turbine coupled to a drive shaft of a motor with a swash plate according to the present disclosure.

Detailed Description

This disclosure generally relates to a hydrostatic transmission system that provides for recovery of energy that may be lost during a flushing flow.

Fig. 1 illustrates a hydrostatic transmission system 10 in a first embodiment. The hydrostatic transmission system 10 comprises a hydraulic pump 12. The hydraulic pump 12 is coupled to a drive means 14. The hydraulic pump 12 is driven by the drive means 14. In an embodiment, the drive means 14 is an electric motor. In an alternative embodiment, the drive means 14 is a conventional engine. The hydraulic pump 12 is coupled to the drive shaft 11 of the drive means 14.

The hydrostatic transmission system 10 comprises a hydraulic motor 16. The hydraulic motor 16 has a drive shaft 18 for coupling to a mechanically driven device (not shown). The hydraulic motor 16 is fluidly coupled to and driven by the hydraulic pump 12.

The hydrostatic transmission system 10 comprises a first work line 20 and a second work line 22. The first and second work lines 20, 22 interconnect the hydraulic pump 12 and the hydraulic motor 16. First and second work lines 20, 22 are fluidly connected through the hydraulic pump 12 and the hydraulic motor 16. Hydraulic fluid in the first and second work lines 20, 22 enable the transmission of energy from the hydraulic pump 12 to the hydraulic motor 16. The first work line 20 is provided for transmission of a hydraulic fluid at a first pressure. The second work line 22 is provided for transmission of the hydraulic fluid at a second pressure. The first and the second pressures are different.

In a mode of operation, the hydraulic fluid in the first work line 20 is transmitted at a first pressure and the hydraulic fluid in the second work line 22 is transmitted at a second pressure. The first pressure is at a higher value relative to the second pressure. In another mode of operation, the hydraulic fluid in the first work line 20 is transmitted at a second pressure and the hydraulic fluid in the second work line 22 is transmitted at a first pressure. The first pressure is at a higher value relative to the second pressure. The different modes of operation both drive the hydraulic motor 16. In the first mode of operation the drive shaft 18 is driven in a first direction and in the second mode of operation the drive shaft 18 is driven in a second direction.

The hydrostatic transmission system 10 comprises a fluid reservoir 26. A drain line 24 connects the hydraulic motor 16 to the fluid reservoir 26. Hydraulic fluid used to cool the hydraulic motor 16 flows to the fluid reservoir 26 through the drain line 24.

The hydrostatic transmission system 10 comprises a loop flushing valve 28. The loop flushing valve 28 is fluidly connected between the first and second work lines 20, 22 and the hydraulic motor 16. The loop flushing valve 28 alternatively fluidly connects the hydraulic motor 16 to the first and second work lines 20, 22. The loop flushing valve 28 is fluidly connected to the hydraulic motor 16 either through the first flushing line 72 or the second flushing line 74.

The loop flushing valve 28 is separately fluidly connected to the first and second work lines 20, 22. The loop flushing valve 28 is fluidly connected to the first work line 20 through a line 68. The loop flushing valve 28 is fluidly connected to the second work line 22 through a line 70. The loop flushing valve 28 comprises three spool positions 62, 64, 66.

In an embodiment, each spool position of the loop flushing valve 28 has four ports. At the first spool position 62, the loop flushing valve 28 fluidly connects the second flushing line 74 to the first work line 20 through line 68 and fluidly disconnects the first flushing line 72 from the second work line 22. At the second spool position 64, the loop flushing valve 28 fluidly disconnects the second flushing line 74 from the first work line 20 and fluidly disconnects the first flushing line 72 from the second work line 22. At the third spool position 66, the loop flushing valve 28 fluidly disconnects the second flushing line 74 from the first work line 20 and fluidly connects the first flushing line 72 to the second work line 22 through line 70.

The hydrostatic transmission system 10 comprises at least one impeller 30. The at least one impeller 30 is fluidly connected to the loop flushing valve 28 and to the hydraulic motor 16. The at least one impeller 30 is fluidly connected between the loop flushing valve 28 and the hydraulic motor 16. Hydraulic fluid from the loop flushing valve 28 flows to the impeller 30 through either the first or the second flushing lines 72, 74. The flow of hydraulic fluid acts on the impeller 30. The direction of force from the flow of the hydraulic fluid acting on the impeller 30 is dependent on the flow of hydraulic fluid either through the first flushing line 72 or the second flushing line 74. The direction of force from the flow of the hydraulic fluid acting on the impeller 30 is dependent on the spool position 62, 66 of the loop flushing valve 28.

The at least one impeller 30 is bidirectionally rotatable. The impeller 30 is rotatable in a first direction. Alternatively, the impeller 30 is rotatable in a second direction. The first direction being opposite to the second direction.

Hydraulic fluid from the impeller 30 flows to the hydraulic motor 16 through a motor line 76. The impeller 30 is fluidly connected to the motor line 76 through the impeller line 32. Hydraulic fluid from the impeller 30 passes through impeller line 32 and the motor line 76 to the hydraulic motor 16.

The at least one impeller 30 is mounted to the drive shaft 18 so as to convert at least some of the energy of the hydraulic fluid outgoing from the loop flushing valve 28 into mechanical power acting on the drive shaft 18. In an embodiment, the at least one impeller 30 is incorporated in the hydraulic motor 16. In an alternative embodiment, the at least one impeller 30 is positioned external to the hydraulic motor 16.

The displacement of the hydraulic flow from the loop flushing valve 28 acts on the impeller 30. The force acting on the impeller 30 may be used to assist in the rotation of the drive shaft 18. The spool position may be selected such that the force acting on the impeller 30 is directed along the same rotational direction as the direction of rotation of the drive shaft 18. Alternatively, the force acting on the impeller 30 may be used to impede the rotation of the drive shaft 18. With reference to Fig. 2, the impeller 30 may be selectively fluidly connected to the second work line 22 through the loop flushing valve 28. The loop flushing valve 28 is at the third spool position 66. The impeller 30 is fluidly connected to second work line 22 through first flushing line 72 and line 70. The impeller 30 is fluidly disconnected from the first work line 20. In this first operational configuration, hydraulic fluid flows from the second work line 22 to the at least one impeller 30.

With reference to Fig. 3, the at least one impeller 30 may be selectively fluidly connected to the first work line 20 through the loop flushing valve 28. The loop flushing valve 28 is at the first spool position 62. The impeller 30 is fluidly connected to first work line 20 through second flushing line 74 and line 68. The impeller 30 is fluidly disconnected from the second work line 22. In this second operational configuration, hydraulic fluid flows from the first work line 20 to the at least one impeller 30. In an embodiment, the impeller 30 is a turbine.

With reference to Figs. 2 and 3, the hydrostatic transmission system 10 further comprises a booster line 36 connecting the fluid reservoir 26 to the first work line 20 and / or the second work line 22 for return of hydraulic fluid from the fluid reservoir 26. Hydraulic fluid from the fluid reservoir 26 is returned to the first work line 20 and / or the second work line 22 through the return line 36. The booster line 36 is connected to the first work line 20 through line 42 and connected to the second work line 22 through line 44. A first check valve 46 is positioned on line 42 to prevent flow of hydraulic fluid from the first work line 20 to the booster line 36 and a second check valve 48 is positioned on line 44 to prevent flow of hydraulic fluid from the second work line 22 to the return line 36.

The hydrostatic transmission system 10 further comprises a charge pump 38 fluidly connected to the booster line 36. The charge pump 38 is coupled to the hydraulic pump 12. The charge pump 38 is configured to be driven by the drive means 14. The charge pump 38 is driven by the drive shaft 11 of the drive means 14. Charge pump 38 pumps fluid from the fluid reservoir 26 to the first work line 20 and / or the second work line 22.

A line 41 extends from the booster line 36. A first pressure relief valve 40 is provided on the line 41. The first pressure relief valve 40 permits flow of hydraulic fluid from the booster line 36 to the fluid reservoir 26 at a predetermined pressure value. Line 41 is connected to the booster line 36 at a position between the charge pump 38 and the respective connections to lines 42, 44. In an embodiment, the line 41 is connected between the booster line 36 and the fluid reservoir 26.

The hydrostatic transmission system 10 further comprises a relief sub-circuit 50 configured to set the maximum pressure in either the first work line 20 or the second work line 22. The relief sub-circuit 50 comprises a first relief line 52 being connected to the first work line 20 though a second relief line 54 and being connected to the second work line 22 through a third relief line 56.

The first relief line 52 is configured convey hydraulic fluid from the second and third relief lines 54, 56 to either the first work line 20 or the second work line 22 whichever work line 20, 22 having the lower pressure. . A second pressure valve 58 positioned on the second relief line 54 to permit flow of hydraulic fluid from the first work line 20 to the first relief line 52 at a predetermined pressure value. A third pressure relief valve 60 is positioned on the third relief line 56 to permit flow of hydraulic fluid from the second work line 22 to the first relief line 52 at a predetermined pressure value.

Fig. 4 illustrates a hydrostatic transmission system 10 in a second embodiment. In the second embodiment, there are two impellers 30’, 30”. All other features hydrostatic transmission system 10 are present as in the first embodiment. The first impeller 30’ is rotatable in a first direction. The second impeller 30” is rotatable in a second direction. The first direction being opposite to the second direction. In an embodiment, the first impeller 30’ and the second impeller 30” are both bidirectionally rotatable. In an alternative embodiment, the first impeller 30’ and the second impeller 30” are both unidirectionally rotatable.

The first impeller 30’ and the second impeller 30” are independently connected to the loop flushing valve 28. The first impeller 30’ and the second impeller 30” are independently connected to the loop flushing valve 28 through either the first flushing line 72 or the second flushing line 74. The first and second impellers 30’, 30” are connected to the motor line 76 through either a first impeller line 32 or a second impeller line 34. Hydraulic fluid from the loop flushing valve 28 may pass through the first impeller 30’ or the second impeller 30” to the motor 16.

In an embodiment, the first impeller 30’ is connected to the loop flushing valve 28 through the first flushing line 72. The first impeller 30’ may be selectively fluidly connected to the second work line 22 through the loop flushing valve 28 when the loop flushing valve 28 is at the third spool position 66. The first impeller 30’ is fluidly connected to second work line 22 through first flushing line 72 and line 70. In this first operational configuration, hydraulic fluid flows from the second work line 22 to the first impeller 30’.

The second impeller 30” is connected to the loop flushing valve 28 through the second flushing line 74. The second impeller 30” may be selectively fluidly connected to the first work line 20 through the loop flushing valve 28 when the loop flushing valve 28 is at the first spool position 62. The second impeller 30” is fluidly connected to first work line 20 through second flushing line 74 and line 68. In this second operational configuration, hydraulic fluid flows from the first work line 20 to the second impeller 30”.

In an alternate embodiment, the first impeller 30’ is connected to the loop flushing valve 28 through the second flushing line 74. The first impeller 30’ is selectively connected to the first work line 20 through the loop flushing valve 28 at the first spool position 62. The second impeller 30” is connected to the loop flushing valve 28 through the first flushing line 72. The second impeller 30” is selectively connected to the second work line 22 through the loop flushing valve 28 at the third spool position 66.

In a further embodiment, the first impeller 30’ is fluidly connected to the motor line 76 through the first impeller line 32. The second impeller 30” is fluidly connected to the motor line 76 through the second impeller line 34. In an alternative further embodiment, the first impeller 30’ is fluidly connected to the motor line 76 through the second impeller line 34. The second impeller 30” is fluidly connected to the motor line 76 through the first impeller line 32.

Fig. 5 illustrates a hydrostatic transmission system 10 in a third embodiment. In the third embodiment, the each spool position of the loop flushing valve 28 has six ports. Line 41 connects the return line 36 to the loop flushing valve 28. The loop flushing valve 28 fluidly connects the first pressure relief valve 40 to the drain line 24 at the second pool position 64. All other features hydrostatic transmission system 10 are present as in either the first embodiment or the second embodiment.

At the first spool position 62, the loop flushing valve 28 fluidly connects the second flushing line 74 to line 41 and first work line 20. At the first spool position 62, the loop flushing valve 28 fluidly disconnects line 41 from the drain line 24 and fluidly disconnects the first flushing line 72 from the second work line 22.

At the second spool position 64, the loop flushing valve 28 fluidly connects line 41 to the drain line 24 through a third flushing line 75. At the second spool position 64, the loop flushing valve 28 fluidly disconnects the first flushing line 72 from the second work line 22 and fluidly disconnects the second flushing line 74 from the first work line 20.

At the third spool position 66, the loop flushing valve 28 fluidly connects the first flushing line 72 to second work line 22 and line 41. At the third spool position 66, loop flushing valve 28 fluidly disconnects the line 41 from the drain line 24 and fluidly disconnects the second flushing line 74 from the first work line 20. In this embodiment hydrostatic transmission system 10 allows energy recovery also from the hydraulic fluid discharged from the first pressure relief valve 40.

Fig. 6 illustrates the hydraulic motor 16 of a bent axis type incorporating a bi directional turbine 30. The turbine 30 is coupled to the drive shaft 18. Turbine 30 jointly rotates with the drive shaft 18. Turbine 30 is concentric with the drive shaft 18. Turbine 30 is coaxial with the drive shaft 18. The hydraulic motor 16 comprises a bent axis piston 90. In an embodiment, the turbine 30 is provided on a cylinder block 75. The turbine 30 is coupled to the drive shaft 18 though the cylinder block 75. The cylinder block 75 is concentric with the drive shaft 18. Cylinder block 75 is provided on the external surface of the drive shaft 18. Cylinder block 75 jointly rotates with the drive shaft 18. In an alternative embodiment, the turbine 30 is mounted on the drive shaft 18. The turbine 30 is positioned on the external surface of the drive shaft 18.

Turbine 30 comprises a series of channels 78. The longitudinal extension of the channels 78 are aligned with the longitudinal axis of the drive shaft 18. In an embodiment, the longitudinal axis of each channel 78 is substantially parallel to the longitudinal axis of the drive shaft 18. In an embodiment, the channels 78 are mutually radially spaced around the cylinder block 75. The channels 78 are externally positioned and are formed in the cylinder block 75. In an alternative embodiment, the channels 78 are mutually radially spaced around the drive shaft 18. The channels 78 are externally positioned and are formed in the drive shaft 18. The turbine 30 is connected to the drive shaft 18. Ledges 82 are interposed between the channels 78. Each ledge 82 separates adjacent channels 78. Each ledge 82 may have a ledge surface 84. Each ledge surface 84 extends axially in a direction substantially parallel to the longitudinal axis of the drive shaft 18. In an alternative embodiment, the ledge surface 84 may be linear. In an embodiment, the ledge surface 84 may have an hourglass shape.

Each channel 78 has an opening 86. The channels 78 communicates externally of the cylinder block 75 or the drive shaft 18 through the opening 86. The openings 86 are elongated along the length of the channel 78. Each opening 86 faces away from the drive shaft 18. Each opening 86 is directed externally relative to the cylinder block 75 or the drive shaft 18. A pair of ledge surfaces 84 are positioned on opposite sides of each opening 86. Each opening 86 is defined by the ledge surfaces 84 at the opposite sides. Each channel 78 has a first aperture 86 and a second aperture 88 at opposite ends.

The cylinder block 75 has an internal surface 90 in contact with the external surface of the drive shaft 18. The cylinder block 75is fixedly connected to the drive shaft 18 Each opening 86 faces away from the internal surface 90.

Fig. 7 is a sectional view of the turbine 30 coupled to the drive shaft 18

The turbine 30 is enclosed in a housing 92. The openings 86 are covered by a housing internal surface 94. The first flushing line 72 and the second flushing line 74 are provided in the housing 92. Throttle valves 98 are provided in the first flushing line 72 and the second flushing line 74 in order to increase the hydraulic fluid flow pressure towards the turbine 30. The motor line 76 may be a clearance between the housing 92 and the turbine 30.

The first flushing line 72 and the second flushing line 74 diverge towards the turbine 30. The first flushing line 72 and the second flushing line 74 are positioned so as to direct hydraulic fluid into the channels 78. The first flushing line 72 and the second flushing line 74 are positioned over the openings 82. The first flushing line 72 and the second flushing line 74 are positioned so as to direct hydraulic fluid at the openings 82.

Fig. 8 is an isometric view of fluid lines from a flushing valve fluidly connected to the turbine 30. The hydraulic fluid from the first flushing line 72 and the second flushing line 74 are directed tangentially relative to the cylindrical body 78. An aperture 96 is provided in the housing 92 for flow of hydraulic fluid to the motor line 76. Fig. 9 is an enlarged view of the fluid lines fluidly connected to the turbine 30.

Fig. 10 illustrates the hydraulic motor 16 of a swash plate type incorporating a bi directional turbine 30. The turbine 30 is coupled to a drive shaft 18. Turbine 30 jointly rotates with the drive shaft 18.

The turbine 30 is positioned on the external surface of the drive shaft 18. Turbine 30 is concentric with the drive shaft 18. Turbine 30 is coaxial with the drive shaft 18. The hydraulic motor 16 comprises a swash plate piston 100. In an embodiment, the turbine 30 is provided on a cylinder block 75. The turbine 30 is coupled to the drive shaft 18 though the cylinder block 75. The cylinder block 75 is concentric with the drive shaft 18. Cylinder block 75 is provided on the external surface of the drive shaft 18. Cylinder block 75 jointly rotates with the drive shaft 18. In an alternative embodiment, the turbine 30 is mounted on the drive shaft 18. The turbine 30 is positioned on the external surface of the drive shaft 18. Turbine 30 comprises a cylindrical body 76 having a series of channels 78. The longitudinal extension of the channels 78 are aligned with the longitudinal axis of the drive shaft 18. In an embodiment, the longitudinal axis of each channel 78 is substantially parallel to the longitudinal axis of the drive shaft 18. In an embodiment, the channels 78 are mutually radially spaced around the cylinder block 75. The channels 78 are externally positioned and are formed in the cylinder block 75. In an alternative embodiment, the channels 78 are mutually radially spaced around the drive shaft 18. The channels 78 are externally positioned and are formed in the drive shaft 18.

Ledges 82 are interposed between the channels 78. Each ledge 82 separates adjacent channels 78. Each ledge 82 may have a ledge surface 84. Each ledge surface 84 extends axially in a direction substantially parallel to the longitudinal axis of the drive shaft 18. The ledge surface 84 is linear.

Each channel 78 has an opening 86. The channels 78 communicates externally of the cylinder block 75 or the drive shaft 18 through the opening 86. The openings 86 are elongated along the length of the channel 78. Each opening 86 faces away from the drive shaft 18. Each opening 86 is directed externally relative to the cylinder block 75 or the drive shaft 18. A pair of ledge surfaces 84 are positioned on opposite sides of each opening 86. Each opening 86 is defined by the ledge surfaces 84 at the opposite sides. Each channel 78 has an aperture 88 and closed end 86.

The cylinder block 75 has an internal surface 90 in contact with the external surface of the drive shaft 18. The cylinder block 75 is fixedly connected to the drive shaft 18 Each opening 86 faces away from the internal surface 90.

The skilled person would appreciate that foregoing embodiments may be modified or combined to obtain the hydrostatic transmission system 10 of the present disclosure.

Industrial Applicability

This disclosure describes a hydrostatic transmission system 10 that enables energy recovery from hydraulic fluid removed from the system during the normal operation of the flushing valve. In addition, the hydrostatic transmission system 10 enables having a higher starting torque on the motor 16. Energy recovery is obtained by means of a turbine that is preferably integrated on the hydraulic motor.

Power, in the fluid, from the flushing valve is used to increase the power available or to reduce the power requested by sending the hydraulic fluid from the flushing valve to the turbine integrated on/coupled to the motor. The impeller 30 is provided directly in the motor 16 thereby enabling a further starting torque when the loop flushing valve 28 is actuated.

Further, the hydraulic fluid from the turbine passes through the motor to the drain line. The passage of the hydraulic fluid cools the hydraulic motor.

Accordingly, this disclosure includes all modifications and equivalents of the subject matter recited in the claims appended hereto as permitted by applicable law. Moreover, any combination of the above-described elements in all possible variations thereof is encompassed by the disclosure unless otherwise indicated herein.

Where technical features mentioned in any claim are followed by reference signs, the reference signs have been included for the sole purpose of increasing the intelligibility of the claims and accordingly, neither the reference signs nor their absence have any limiting effect on the technical features as described above or on the scope of any claim elements.

One skilled in the art will realise the disclosure may be embodied in other specific forms without departing from the disclosure or essential characteristics thereof. The foregoing embodiments are therefore to be considered in all respects illustrative rather than limiting of the disclosure described herein. Scope of the invention is thus indicated by the appended claims, rather than the foregoing description, and all changes that come within the meaning and range of equivalence of the claims are therefore intended to be embraced therein.