US20150051037A1 - Hydromechanical Transmission and Assemblies - Google Patents
Hydromechanical Transmission and Assemblies Download PDFInfo
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- US20150051037A1 US20150051037A1 US14/529,210 US201414529210A US2015051037A1 US 20150051037 A1 US20150051037 A1 US 20150051037A1 US 201414529210 A US201414529210 A US 201414529210A US 2015051037 A1 US2015051037 A1 US 2015051037A1
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- Prior art keywords
- hydraulic
- pump motor
- gear
- unit
- connecting plate
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16H—GEARING
- F16H47/00—Combinations of mechanical gearing with fluid clutches or fluid gearing
- F16H47/02—Combinations of mechanical gearing with fluid clutches or fluid gearing the fluid gearing being of the volumetric type
- F16H47/04—Combinations of mechanical gearing with fluid clutches or fluid gearing the fluid gearing being of the volumetric type the mechanical gearing being of the type with members having orbital motion
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16D—COUPLINGS FOR TRANSMITTING ROTATION; CLUTCHES; BRAKES
- F16D1/00—Couplings for rigidly connecting two coaxial shafts or other movable machine elements
- F16D1/06—Couplings for rigidly connecting two coaxial shafts or other movable machine elements for attachment of a member on a shaft or on a shaft-end
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16H—GEARING
- F16H61/00—Control functions within control units of change-speed- or reversing-gearings for conveying rotary motion ; Control of exclusively fluid gearing, friction gearing, gearings with endless flexible members or other particular types of gearing
- F16H61/38—Control of exclusively fluid gearing
- F16H61/40—Control of exclusively fluid gearing hydrostatic
- F16H61/44—Control of exclusively fluid gearing hydrostatic with more than one pump or motor in operation
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23P—METAL-WORKING NOT OTHERWISE PROVIDED FOR; COMBINED OPERATIONS; UNIVERSAL MACHINE TOOLS
- B23P15/00—Making specific metal objects by operations not covered by a single other subclass or a group in this subclass
- B23P15/14—Making specific metal objects by operations not covered by a single other subclass or a group in this subclass gear parts, e.g. gear wheels
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60Y—INDEXING SCHEME RELATING TO ASPECTS CROSS-CUTTING VEHICLE TECHNOLOGY
- B60Y2304/00—Optimising design; Manufacturing; Testing
- B60Y2304/07—Facilitating assembling or mounting
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16D—COUPLINGS FOR TRANSMITTING ROTATION; CLUTCHES; BRAKES
- F16D1/00—Couplings for rigidly connecting two coaxial shafts or other movable machine elements
- F16D1/10—Quick-acting couplings in which the parts are connected by simply bringing them together axially
- F16D2001/103—Quick-acting couplings in which the parts are connected by simply bringing them together axially the torque is transmitted via splined connections
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16H—GEARING
- F16H47/00—Combinations of mechanical gearing with fluid clutches or fluid gearing
- F16H47/02—Combinations of mechanical gearing with fluid clutches or fluid gearing the fluid gearing being of the volumetric type
- F16H47/04—Combinations of mechanical gearing with fluid clutches or fluid gearing the fluid gearing being of the volumetric type the mechanical gearing being of the type with members having orbital motion
- F16H2047/045—Combinations of mechanical gearing with fluid clutches or fluid gearing the fluid gearing being of the volumetric type the mechanical gearing being of the type with members having orbital motion the fluid gearing comprising a plurality of pumps or motors
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
- Y10T29/00—Metal working
- Y10T29/49—Method of mechanical manufacture
- Y10T29/49462—Gear making
- Y10T29/49464—Assembling of gear into force transmitting device
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
- Y10T403/00—Joints and connections
- Y10T403/70—Interfitted members
- Y10T403/7026—Longitudinally splined or fluted rod
Definitions
- This invention relates generally to a hydromechanical transmission, and more specifically to a hydromechanical powersplit transmission for a hydraulic hybrid vehicle, and to components and assemblies and methods that may be used with such transmissions and elsewhere.
- Hydromechanical transmissions including hydromechanical powersplit transmissions, are used in hydraulic hybrid vehicles.
- Such vehicles may include a vehicle prime mover such as an internal combustion engine, at least one hydraulic pump motor unit, a gear set such as a planetary gear set, and an output shaft connecting the planetary gear set to a drive shaft of the vehicle.
- the internal combustion engine and the hydraulic pump motor unit are connected to the gear set, and the gear set splits power from the internal combustion engine and from the hydraulic pump motor unit in a motoring mode to rotate the drive shaft and propel the vehicle.
- the pump motor unit may also be used in a pumping mode to capture energy under certain conditions such as braking the vehicle, and the captured energy may be stored in an energy storage device such as a hydraulic accumulator to power the hydraulic pump motor unit in the motoring mode.
- hydromechanical powersplit vehicle transmissions may be used in off-highway vehicle applications such as agricultural tractors and wheel loaders or in on-highway applications such as delivery trucks.
- the ability of the powersplit transmission to provide infinitely variable speed allows the engine to run at its optimum efficiency conditions, while transmission of most power through the mechanical power path rather than through the hydraulic power path may result in relatively high transmission efficiency when hydraulic power is limited or not being used.
- Smooth and seamless control with uninterrupted transfer of torque from the prime mover and/or the hydraulic pump motor unit to the vehicle drive shaft may result in good performance when compared to manual and automatic transmissions having discrete gear ratios, white elimination of a hydrodynamic torque converter may help achieve efficiency when compared to automatic transmissions.
- technical problems include difficulties with system complexity, efficiency, size, weight, flexibility, lubrication of components, sump oil fill levels and heat build-up, assembly, repair, transmission of forces and torque in relatively large weight vehicles, and parking lock requirements. More specifically, these technical problems include alignment with other components of a vehicle such as the prime mover engine and the differential, ease of assembly, ease of installation in a vehicle and removal from the vehicle, space availability of the vehicle, space requirements of the transmission and within the transmission, weight of the transmission, smooth operation, transmission control, ease of disassembly and repair, and flexibility to change for use in a variety of different vehicles and different applications.
- these technical problems include difficulty assembling and attaching and integrating the hydraulic components, including the hydraulic pump motor units and the controls and drive shafts for the hydraulic pump motor units and the hydraulic flow passages and ports for the hydraulic pump motor units, with the planetary gear set, including the drive gears and planetary gear set components, and assembling those components to the prime mover and differential of the vehicle.
- Further technical problems include lubrication of gear components, including size and complexity and efficiency of lubrication fluid pumps, and assembly and alignment of spline connections.
- Further technical problems include complexity of, and forces and stresses imposed on, parking lock mechanisms in relatively large weight vehicles.
- the present invention addresses the certain of the aforementioned technical problems and provides a hydromechanical vehicle transmission and assemblies for use in such transmissions and elsewhere.
- the transmission and assemblies according to the present invention may be used in a motor vehicle in place of a conventional manual or automatic transmission, connected directly to a conventional vehicle prime mover engine drive shaft and differential drive shaft, and situated between typical vehicle frame rails, while providing a configuration that is modular, compact, and capable of kinetic brake energy recovery, with good efficiency.
- the invention provides a hydromechanical transmission and assemblies that integrate hydraulic components with gear set components in an integral assembly. Still more specifically, the invention provides a connecting assembly for a hydromechanical transmission that includes a connecting plate having a hydraulic unit side and a gear unit side. Mechanical drive and hydraulic drive openings extend longitudinally through the connecting plate, and the connecting plate and hydraulic components and gear unit components are connected as an integral assembly. The connecting plate provides a hydraulic fluid manifold for the hydraulic components.
- At least one embodiment of the invention provides a hybrid vehicle hydromechanical or hydromechanical powersplit transmission including a hydraulic unit housing having a sealed internal chamber and a gear unit housing having a separate internal chamber sealed from the hydraulic unit housing internal chamber.
- the hydraulic unit housing may be connected to the gear unit housing in longitudinally aligned relationship.
- the hydraulic unit housing may have a prime mover input shaft opening at its input end and at least one and preferably two variable displacement hydraulic pump motor units with pump motor unit drive shafts disposed within the hydraulic unit housing interior chamber in laterally offset relation to the prime mover input shaft opening.
- the variable displacement hydraulic pump motor units and their pump motor unit drive shafts may be in circumferentially spaced relation and in axially spaced relation to one another.
- the gear unit housing may have an output drive shaft opening at its output end extending longitudinally from the gear unit housing interior chamber and a gear unit having gear unit components.
- An input shaft may be disposed in the input shaft opening, and an output shaft may be disposed in the output shaft opening.
- the input shaft and the hydraulic pump motor unit drive shaft(s) and the output shaft may each be drivingly connected to one of the gear components.
- the input shaft opening, input shaft, output shaft opening and output shaft may be substantially coaxial, so that the transmission may be connected to a conventional vehicle prime mover engine and a conventional vehicle drive wheel differential.
- the gear unit may include a planetary gear set having planetary gear components. Various different hydraulic components may be used with various different gear set components, to provide flexibility for use in a wide variety of applications and vehicles.
- At least one embodiment of the invention further provides a connecting plate intermediate the hydraulic unit housing and the gear unit housing.
- One side of the connecting plate may provide a wall of the hydraulic unit housing interior chamber, and the other side of the connecting plate may provide a wall of the gear unit housing interior chamber.
- the hydraulic pump motor units and the gear set may be mounted on and carried by the connecting plate.
- the connecting plate may also provide a hydraulic manifold having fluid flow passages in fluid communication with each pump motor unit, and the connecting plate may include bearings for supporting rotating shafts including the pump motor unit drive shafts.
- One type of fluid may be disposed within the hydraulic unit housing interior chamber to provide a hydraulic fluid reservoir, and a different type of fluid with a different fluid level may be disposed within the planetary gear unit housing interior chamber to provide gear lubrication.
- Components of the hydraulic unit extend into the gear unit and provide integral portions of the gear unit, while portions of the gear unit provide integral portions of the hydraulic unit.
- At least one embodiment of the invention further provides a motor vehicle having two laterally spaced apart longitudinally extending frame rails, and the hydromechanical powersplit transmission is disposed between the frame rails.
- the motor vehicle includes a drive shaft and a prime mover having a prime mover shaft, the drive shaft is axially aligned with and drivingly connected to the output shaft, and the prime mover shaft is axially aligned and drivingly connected to the input shaft.
- FIG. 1 is a schematic diagram of a wheeled land vehicle that includes a hydromechanical powersplit transmission according to a preferred embodiment of the present invention
- FIG. 2 is a more detailed enlarged view of a portion of the schematic diagram illustrated in FIG. 1 ;
- FIG. 3 is a perspective view of the hydromechanical powersplit transmission illustrated schematically in FIG. 1 , as viewed from the front driver side of the vehicle in which the transmission is installed;
- FIG. 4 is a perspective view of the transmission illustrated in FIG. 1 , similar to FIG. 3 but having a hydraulic unit housing removed from a central connecting plate;
- FIG. 5 is another perspective view of the transmission illustrated in FIG. 1 , as viewed from the rear driver side of the vehicle in which the transmission is installed, but having a planetary gear unit housing removed from the central connecting plate and having the planetary gear unit gears illustrated:
- FIG. 6 is a rear or output end view of the transmission illustrated in FIG. 1 ;
- FIG. 7 is a cross sectional view taken along plane 7 - 7 in FIG. 6 ;
- FIG. 8 is a cross sectional view taken along plane 8 - 8 in FIG. 6 ;
- FIG. 9 is a cross sectional view taken along plane 9 - 9 in FIG. 8 ;
- FIG. 10 is a cross sectional view taken along plane 10 - 10 in FIG. 6 ;
- FIG. 11 is a perspective view of a front planetary gear unit housing for the planetary gear unit of the transmission illustrated in FIG. 1 , as viewed from the rear driver side of the vehicle in which the transmission is installed, and with all associated components removed for clarity;
- FIG. 12 is a perspective view of a rear planetary gear unit housing for the planetary gear unit of the transmission illustrated in FIG. 1 , as viewed from the front passenger side of the vehicle in which the transmission is installed, and with all associated components removed for clarity;
- FIG. 13 is an enlarged perspective view of a lubricating liquid baffle or trough for the planetary gear unit of the transmission illustrated in FIG. 1 ;
- FIG. 14 is an exploded perspective view of a planetary gear and splash gear assembly for the planetary gear unit of the transmission illustrated in FIG. 1 , as viewed from the rear driver side of the vehicle in which the transmission is installed;
- FIG. 15 is a view similar to FIG. 14 , but showing the exploded components from FIG. 14 in an assembled condition;
- FIG. 16 is a cross sectional view of the planetary gear and splash gear assembly illustrated in FIGS. 14 and 16 , taken along reference view line 16 - 16 in FIG. 15 ;
- FIG. 17 is an elevation view of the rear planetary gear unit housing illustrated in FIG. 12 , with some associated components installed and other associated components removed for clarity, as viewed from the front of the vehicle in which the transmission is installed, illustrating a park pawl assembly for the transmission illustrated in FIG. 1 ;
- FIG. 13 is an enlarged view of a portion of the rear planetary gear housing shown in FIG. 17 , with a park pawl hub removed for clarity, illustrating the portion of the rear planetary gear housing and the park pawl assembly in cross section, and with the park pawl assembly in an engaged or locked position;
- FIG. 19 is a view similar to FIG. 18 , with the park pawl assembly in a disengaged or unlocked position;
- FIG. 20 is a cross sectional view taken along reference view line 20 - 20 in FIG. 17 , with the park pawl assembly in the engaged or locked position;
- FIG. 21 is a cross sectional view similar to FIG. 20 , with the park pawl assembly in the disengaged or unlocked position;
- FIG. 22 is an exploded perspective view illustrating a step in the method of assembling the transmission illustrated in FIG. 1 and a subassembly of the transmission, as viewed from the passenger side front of the vehicle in which the transmission is assembled;
- FIG. 23 is an exploded perspective view illustrating another step in the method of assembling the transmission illustrated in FIG. 1 and another subassembly of the transmission, as viewed from the passenger side front of the vehicle in which the transmission is assembled;
- FIG. 24 is an exploded perspective view illustrating another step in the method of assembling the transmission illustrated in FIG. 1 and another subassembly of the transmission, as viewed from the passenger side front of the vehicle in which the transmission is assembled:
- FIG. 25 is a perspective view illustrating another step in the method of assembling the transmission illustrated in FIG. 1 and another subassembly of the transmission, as viewed from the passenger side front of the vehicle in which the transmission is assembled;
- FIG. 26 is an exploded perspective view illustrating another step in the method of assembling the transmission illustrated in FIG. 1 and another subassembly of the transmission, as viewed from the driver side rear of the vehicle in which the transmission is assembled;
- FIG. 27 is an exploded perspective view illustrating another step in the method of assembling the transmission illustrated in FIG. 1 and another subassembly of the transmission, as viewed from the driver side rear of the vehicle in which the transmission is assembled;
- FIG. 28 is an exploded perspective view illustrating another step in the method of assembling the transmission illustrated in FIG. 1 and another subassembly of the transmission, as viewed from the passenger side rear of the vehicle in which the transmission is assembled;
- FIG. 29 is an exploded perspective view illustrating another step in the method of assembling the transmission illustrated in FIG. 1 and another subassembly of the transmission, as viewed from the driver side rear of the vehicle in which the transmission is assembled;
- FIG. 30 is an exploded perspective view illustrating another step in the method of assembling the transmission illustrated in FIG. 1 and another subassembly of the transmission, as viewed from the driver side rear of the vehicle in which the transmission is assembled;
- FIG. 31 is an exploded perspective view illustrating another step in the method of assembling the transmission illustrated in FIG. 1 and another subassembly of the transmission, as viewed from the driver side rear of the vehicle in which the transmission is assembled;
- FIG. 32 is an exploded perspective view illustrating another step in the method of assembling the transmission illustrated in FIG. 1 and another subassembly of the transmission, as viewed from the driver side rear of the vehicle in which the transmission is assembled;
- FIG. 33 is a diagrammatic flow chart, illustrating the steps of the method of assembling a transmission according to the present invention.
- FIG. 34 is a cross sectional side elevation view of the primary pump motor drive shaft and its associated drive gear for the transmission illustrated in FIG. 1 , illustrating a spline connection according to the present invention in a fully assembled configuration;
- FIG. 34 a is an enlarged view of a portion of FIG. 34 , illustrating the spline connection in a first partially assembled configuration
- FIG. 34 b is a view similar to FIG. 34 a, illustrating the spline connection in a second partially assembled configuration
- FIG. 35 is a cross sectional view of the primary pump motor unit drive gear illustrated in FIG. 34 ;
- FIG. 36 is a cross sectional view of the primary pump motor unit drive shaft illustrated in FIG. 34 ;
- FIG. 37 is a perspective view of the primary pump motor unit drive shaft and its associated drive gear illustrated in FIG. 34 , showing these components before they are assembled together;
- FIG. 38 is another perspective view of the primary pump motor unit drive shaft and its associated drive gear illustrated in FIG. 34 , showing these components in a fully assembled configuration.
- FIGS. 1-38 illustrate an object 10 having a compact hydromechanical powersplit transmission 11 according to a preferred embodiment of the present invention and a method of assembly 140 according to a preferred embodiment of the present invention.
- the object 10 can be any object that uses a transmission for transmitting energy or converting energy to rotational movement.
- the object 10 is a wheeled land vehicle such as an on-highway truck.
- the vehicle 10 includes a prime mover 13 , which in the preferred embodiment is a conventional internal combustion engine such as a gasoline or diesel or natural gas engine, and an engine drive shaft 14 .
- the vehicle 10 further includes drive wheels 15 , a differential 16 , and a differential drive shaft 17 .
- the vehicle 10 also includes frame rails 18 , which are longitudinally extending beams, which may be steel or other suitable structural material, to which the body (not shown), prime mover 13 , drive shaft 14 , vehicle suspension components (not shown), differential 16 and other components of the vehicle 10 are mounted in a conventional well know manner.
- frame rails 18 are longitudinally extending beams, which may be steel or other suitable structural material, to which the body (not shown), prime mover 13 , drive shaft 14 , vehicle suspension components (not shown), differential 16 and other components of the vehicle 10 are mounted in a conventional well know manner.
- the hydromechanical powersplit transmission 11 has a longitudinal axis 22 .
- the transmission 11 includes a hydraulic unit 23 , a gear unit or planetary gear unit 24 that is integral with the hydraulic unit 23 , and a connecting plate 25 disposed intermediate the hydraulic unit 23 and the gear unit 24 .
- the term integral means two or more functionally different cooperating devices that are assembled without externally exposed fluid or mechanical connections and used as a whole such that each device is an essential part to complete the other.
- the hydraulic unit 23 includes a hydraulic unit housing 26 having a vehicle prime mover input end 27 and an output end 28 .
- the gear unit 24 includes a gear unit housing or planetary gear unit housing 29 having an input end 30 and an output end 31 .
- the housings 26 and 29 include exterior surfaces 32 and 33 and interior surfaces 34 and 35 , respectively. Interior surfaces 34 and 35 cooperate with connecting plate 25 to define chambers 36 and 37 , respectively, that are sealed from one another and from the exterior surfaces 32 and 33 .
- the chambers 36 and 37 are in longitudinally aligned relationship to one another along longitudinal axis 22 .
- Various low pressure hydraulic connections through the chamber 36 are illustrated schematically in FIG. 1 with solid lines. It should be understood that these illustrated solid lines are not separate hydraulic conduits, but rather schematically illustrate hydraulic connections that occur between various components through the low pressure hydraulic fluid within chamber 36 .
- the hydraulic unit housing 26 includes a longitudinally extending prime mover input shaft or mechanical drive shaft 41 connected to engine drive shaft 14 through a suitable torsional vibration dampening coupling 14 a.
- Input shaft 41 ( FIGS. 1 and 7 ) extends through an input shaft opening 41 a at the input end 27 , longitudinally into and through the hydraulic unit housing interior chamber 36 .
- the input shaft 41 is rotatably connected to the prime mover 13 , so that the prime mover 13 drives the input shaft 41 and causes the input shaft 41 to rotate when the prime mover 13 is running.
- the term rotatably connected means that components rotate together or are drivingly connected.
- a primary hydraulic pump motor unit 42 and a secondary hydraulic pump motor unit 43 ( FIGS.
- the pump motor units 42 and 43 are longitudinally offset from one another, with the pump motor unit 43 including its barrel and pistons described below being closer to the connecting plate 25 and gear unit 24 than the pump motor unit 42 , to reduce the lateral dimension of the transmission 11 .
- the units 42 and 43 in the preferred embodiment are identical and are preferably bent axis, variable displacement, axial piston type pump motor units of the type disclosed in World Intellectual Property Organization publication number WO 2012/016240 A2, the disclosure of which is incorporated herein by reference.
- the size, displacement or type of the pump motor units 42 and 43 may be different from one another and/or may be different from that illustrated in the preferred embodiment.
- primary pump motor unit 42 may be a smaller displacement unit than secondary unit 43 .
- the detailed structure and operation of the pump motor units 42 and 43 as disclosed in the referenced publication are not repeated in detail herein.
- Primary pump motor unit 42 includes a barrel 42 a and pistons 42 b, and secondary pump motor unit 43 includes a barrel 43 a and pistons 43 b.
- the pump motor units 42 and 43 each operate in a pumping mode or in a motoring mode during the operation of the transmission 11 , as further described below.
- the primary pump motor unit 42 is drivingly connected to primary pump motor unit drive shaft 44 ( FIGS. 1 and 8 ), and the secondary pump motor unit 43 is drivingly connected to secondary pump motor unit drive shaft 45 ( FIGS. 1 and 9 ).
- the primary shaft 44 includes an integral annular head portion having sockets 44 a for its associated pistons 42 a, and the pistons 42 a and associated barrel 42 b provide a rotating group for the primary unit 42 .
- the secondary shaft 45 includes an integral annular head portion having sockets 45 a for its associated pistons 43 a, and the pistons 43 a and associated barrel 42 b provide a rotating group for the secondary unit 43 .
- the units 42 and/or 43 are driven by primary pump motor unit drive shaft 44 and secondary pump motor unit drive shaft 45 , respectively, to pump hydraulic fluid under pressure into a high pressure accumulator 46 ( FIG. 1 ) through a hydraulic line 47 to store energy.
- high pressure hydraulic fluid is supplied to the units 42 and/or 43 from high pressure accumulator 46 through hydraulic line 47 to rotate the shafts 44 and 45 to convert stored energy from accumulator 46 to rotational movement.
- the primary and secondary pump motor unit drive shafts 44 and 45 are also disposed in radially offset relation to the prime mover input shaft 41 and in circumferentially and longitudinally spaced relation relative to one another.
- the high pressure accumulator 46 may be mounted remotely to the vehicle frame rails 18 , or alternatively may be mounted directly to the transmission 11 .
- FIG. 2 is an enlarged and more detailed schematic illustration of the portion of FIG. 1 illustrated by the dotted line box that surrounds the pump motor units 42 and 43 in FIG. 1 .
- the displacement of primary pump motor unit 42 is controlled by a displacement control mechanism including setting or control pistons 48 and 49 (also see FIG. 24 ).
- the displacement of secondary pump motor unit 43 is controlled by setting or control pistons 50 and 51 (also see FIG. 24 ).
- the primary pump motor unit control pistons 48 and 49 are set or controlled by electrohydraulic proportional control valve 52
- the secondary pump motor unit control pistons 48 and 49 are set or controlled by electrohydraulic proportional control valve 53 .
- An isolation valve 54 is arranged to block or open fluid communication between primary pump motor unit 42 high pressure outlet 91 and a high pressure isolation valve port 56 connected to hydraulic line 47 leading to high pressure accumulator 46 .
- An isolation valve 55 is arranged to block or open fluid communication between secondary pump motor unit 43 and high pressure isolation valve port 56 .
- the isolation valves 54 and 55 are closed or open in response to pilot signals from electrically operated isolation pilot signal valves 54 a and 55 a, respectively, and the valves 54 and 55 are disposed in a single housing 57 ( FIG. 10 ) that includes the high pressure fluid port 56 connected to high pressure line 47 leading to high pressure accumulator 46 .
- the isolation valve housing 57 further includes passages 56 a connecting the isolation valve high pressure port 56 with each of the isolation valves. As shown in FIG.
- a low pressure reservoir 53 is connected to pump motor units 42 and 43 through low pressure hydraulic line 59 and chamber 36 .
- a filtration and cooling pump 60 (also see FIG. 4 ) is driven by input shaft 41 and circulates hydraulic fluid from low pressure line 59 and chamber 36 through connections 32 a and 32 b to and from a hydraulic fluid filter (not shown) and a heat exchanger (not shown).
- pump 60 may be driven in any other suitable manner such as, for example, by a suitable gear set.
- a coupling 61 in the connecting plate 25 couples the prime mover input shaft 41 to a transfer shaft 62 , so that the input shaft 41 and transfer shaft 62 rotate together as a unit.
- coupling 61 may be in any other suitable location such as, for example, outside of and on either side of the connecting plate 25 .
- Coupling 25 is integral to the transfer shaft 62 in the preferred embodiment but may alternatively be integral to the shaft 41 or a separate component.
- the transfer shaft 62 extends longitudinally from connecting plate 25 into the planetary gear housing interior chamber 37 , so that the transfer shaft 62 may be considered a part of and/or an extension of input shaft 41 .
- the right end of the transfer shaft 62 is rotatably journaled or supported in a bearing 62 a in a blind bore in the left end of a planetary gear unit output drive shaft 63 at the output end 31 of the planetary gear unit housing 29 , so that the transfer shaft 62 is not drivingly coupled to the output drive shaft 63 but instead rotates relative to the output drive shaft 63 .
- the output drive shaft 63 extends from the planetary gear unit housing interior chamber 37 longitudinally through an output drive shaft opening 63 a in gear unit housing 29 and is connected to the differential drive shaft 17 by a coupling 64 .
- the gear unit or planetary gear unit 24 includes gear unit components 71 disposed within the gear unit housing interior chamber 37 .
- the gear unit components 71 are planetary gear components, and the components 71 include a sun gear 72 , a ring gear 73 , planet gears 74 and a planet carrier 75 .
- the prime mover 13 is drivingly connected to the planet carrier 75 .
- the primary pump motor unit 42 is drivingly connected to the sun gear 72 .
- the secondary pump motor unit 43 is drivingly connected to the ring gear 73 and to the drive wheels 15 .
- the planet carrier 75 is drivingly connected to transfer shaft 62 , preferably by a spline connection, so that transfer shaft 62 and input shaft 41 and engine drive shaft 14 and prime mover 13 are drivingly connected and rotate together.
- transfer shaft 62 and input shaft 41 and engine drive shaft 14 and prime mover 13 are drivingly connected and rotate together.
- one or more of the several spline connections illustrated herein may be replaced with any other suitable attachment device such as, for example, a key and slot arrangement or by a single piece construction.
- primary pump motor unit drive shaft 44 extends into planetary gear unit interior chamber 37 and carries a gear 76 through a spline connection.
- Gear 76 drives gear 77 , which drives sun gear 72 through a spline connection.
- secondary pump motor unit drive shaft 45 is drivingly connected to ring gear 73 and to output shaft 63 and differential drive shaft 17 and differential 16 and drive wheels 15 , so that these components rotate together.
- secondary pump motor unit drive shaft 45 extends into planetary gear unit interior chamber 37 and carries a gear 78 through a spline connection, and gear 78 meshes with gear 79 that is connected to ring gear 73 and to output shaft 63 .
- the primary pump motor shaft 44 extends longitudinally from the rotating axial piston group 42 a, 42 b of its associated primary pump motor unit 42 in interior chamber 36 of hydraulic unit 23 , through the connecting plate 25 , and into the interior chamber 37 of planetary gear unit 24 .
- the left end of the primary pump motor unit shaft 44 is supported by a tapered roller bearing 80 in the connecting plate 25 to accommodate radial and axial loads on the shaft 44
- the right end of the shaft 44 is supported by a roller bearing 81 in housing 29 of planetary gear unit 24 .
- the gear 76 that is carried by the primary pump motor unit shaft 44 is disposed intermediate the bearings 30 and 31 and adjacent the bearing 81 .
- the secondary pump motor shaft 45 extends longitudinally from the rotating axial piston group 43 a, 43 b of its associated secondary pump motor unit 43 in interior chamber 36 of hydraulic unit 23 , through the connecting plate 25 , and into the interior chamber 37 of planetary gear unit 24 .
- the left end of the secondary pump motor unit shaft 45 is supported by a tapered roller bearing 82 in the connecting plate 25 to accommodate radial and axial loads, and the right end of the shaft 45 is supported by a roller bearing 83 in a blind bore 83 a in housing 29 of planetary gear unit 24 .
- the gear 78 that is carried by the secondary pump motor unit shaft 45 is disposed intermediate the bearings 82 and 83 and adjacent the bearing 83 .
- This arrangement integrates the pump motor units 42 and 43 and their associated shafts 44 and 45 into the hydraulic unit 23 and the connecting plate 25 and the planetary gear unit 24 to provide an integral unit.
- the connecting plate 25 is of high strength cast iron and the hydraulic housing 26 and planetary gear unit housing 29 are of lower strength and lower weight aluminum casting.
- the material for the connecting plate 25 and housings 26 and 29 may alternatively be of other suitable materials.
- the connecting plate 25 provides a major structural element of the transmission 11
- a connecting assembly 84 includes the connecting plate 25 and the hydraulic components and gear set components that are assembled to and carried by the connecting plate 26 .
- the connecting plate 25 has a hydraulic unit side that includes a hydraulic unit wall 25 a that provides a wall of hydraulic unit sealed chamber 36 adjacent the output end 28 of the hydraulic unit 23 .
- the connecting plate 25 also has a planetary gear unit side that includes a planetary gear unit wall 25 b that provides a wall of planetary gear unit sealed chamber 37 adjacent the input end 30 of planetary gear unit 24 .
- a mechanical drive opening 85 ( FIG. 7 ) extends longitudinally through the connecting plate 25 from the hydraulic side 25 a to the gear set side 25 b, and a bearing 86 and seal 86 a are disposed in the opening 85 .
- the input mechanical drive shaft 41 (including its transfer shaft 62 ) extends longitudinally into the opening 35 and is supported by the bearing 86 a and sealed by the seal 86 b.
- a primary hydraulic drive opening 87 ( FIG. 8 ) extends longitudinally through the connecting plate 25 from the hydraulic side 25 a to the gear set side 25 b.
- the primary opening 87 is in laterally offset relation to the opening 85 and input shaft 41 , and the primary pump motor unit shaft bearing 80 and associated seal 80 a are disposed in the opening 87 .
- the primary pump motor unit 42 is secured to the connecting plate 25 on its hydraulic side 25 a and is longitudinally aligned with the opening 87 .
- the primary pump motor unit drive shaft 44 extends longitudinally through the opening 87 and is supported by the bearing 80 and sealed by the associated seal 80 a.
- a secondary hydraulic drive opening 88 ( FIG. 9 ) extends longitudinally through the connecting plate 25 from the hydraulic side 25 a to the gear set side 25 b.
- the secondary opening 88 is also in laterally offset relation to the opening 84 and input shaft 41 , and the secondary pump motor unit shaft bearing 82 and associated seal 82 a are disposed in the opening 88 .
- the secondary pump motor unit 43 is secured to the connecting plate 25 on its hydraulic side 25 a and is longitudinally aligned with the opening 88 .
- the secondary pump motor unit drive shaft 45 extends longitudinally through the opening 38 and is supported by the bearing 82 and sealed by seal 82 a.
- the connecting assembly 84 further includes the planetary gear set 71 , which is mounted on the gear set side 25 b of the connecting plate 26 .
- This configuration provides an input drive shaft 41 , 62 that extends longitudinally from end to end through the sealed chamber 36 of hydraulic unit 23 and through the connecting plate 25 , and primary and secondary pump motor units 42 and 43 that are each disposed in the sealed chamber 36 and are laterally offset from the drive shaft 41 , 62 and circumferentially and longitudinally spaced from one another.
- the connecting plate 25 of the connecting assembly 84 provides a hydraulic manifold and further includes fluid flow passages that include high pressure fluid flow passages 89 a and 89 b and pilot signal passages 90 .
- the high pressure fluid outlet side of each hydraulic pump motor unit 42 and 43 includes a high pressure fluid outlet or flow tube 91 ( FIGS. 1 and 8 ), 92 ( FIGS. 1 and 9 ); respectively, and the flow tubes 91 and 92 are further described in the above referenced publication.
- the passages 89 a and 89 b in the connecting plate 25 connect each of the isolation valves 54 , 55 with an associated one of the pump motor units, so that the flow tubes 91 and 92 are each connected in fluid communication to the isolation valves 54 and 55 .
- the valves 52 , 53 , 54 and 55 are secured to and mounted on the connecting plate 25 , and the pilot fluid passages 90 are in fluid communication with these valves.
- the connecting plate 25 is a component of a connecting assembly 84 and provides a mounting platform for the pump motor units 42 and 43 and for the valves 52 , 53 , 54 , and 55 ; provides support and bearings for the pump motor unit shafts 44 and 45 ; provides bearings for the transfer shaft 62 and support for the transfer shaft 62 and input shaft 41 ; provides a mounting platform for the planetary gear components 71 ; provides a wall for the hydraulic unit internal chamber 36 and for the planetary gear unit internal chamber 37 ; combines the hydraulic unit 23 and the planetary gear unit 24 into an integral unit; and provides a high pressure hydraulic manifold for the fluid connections between and among the high pressure accumulator 46 , valves 52 , 53 , 54 , and 55 , setting pistons 48 , 49 , 50 and 51 , and pump motor units 42 and 43 and their associated rotating piston groups and high pressure flow tubes 91 , 92 .
- the illustrated components in the hydraulic unit 23 may be replaced with different components and used with the gear unit 24 or with a different gear unit.
- the illustrated components in the gear unit 24 such as for example the planetary gear components 71 and drive gears, may be replaced with different components and used with the hydraulic unit 23 or with a different hydraulic unit. This enables the transmission 11 to be used in a wide variety of vehicles and applications.
- exterior surfaces 32 and 33 of housings 26 and 29 provides several connections used for the transmission 11 .
- exterior surfaces 32 and 33 provide liquid filter and cooler supply and return ports 32 a and 32 b, liquid sensor temperature port 32 c, auxiliary low pressure return port 32 d, park pawl position sensor connection 32 e, secondary pump motor unit speed sensor connection 32 f, primary pump motor unit speed sensor connection 32 g, primary and secondary pump motor unit displacement sensor 32 h and 32 i, and hydraulic unit low pressure sensor 32 j.
- the transmission 11 is installed in the vehicle 10 in the lateral space between the frame rails 18 and in the longitudinal space between the prime mover drive shaft 14 and the differential drive shaft 17 ( FIG. 1 ).
- the prime mover draft shaft 14 is connected through the torsional vibration dampening coupling 14 a to the input shaft 41 of the transmission 11 .
- the differential drive shaft 17 is connected to the output drive shaft 63 of the transmission 11 through the couplings 64 a and 64 b and shaft 64 c.
- the appropriate electrical connections are made between the control systems of the vehicle 10 and the electrical components of the transmission 11 , and the appropriate connections are made between the hydraulic components of the vehicle 10 (including the accumulators 46 and 47 ) and the transmission 11 .
- the prime mover drive shaft 14 hydraulic unit prime mover input shaft 41 , input opening 41 a, transfer shaft 62 , planetary gear unit output drive shaft 63 , output drive shaft opening 63 a, and differential drive shaft 17 are in axially aligned or coaxial relationship.
- All of the components of the hydraulic unit 23 including the pump motor units 42 and 43 , and all of the components of the connecting plate 25 including the hydraulic manifold high pressure port 56 and passages 89 and 90 and control valves 52 - 55 , and all of the components of the planetary gear unit 24 including the planetary gear components 71 and drive gears 76 , 78 and 79 , are disposed laterally between the frame rails 18 and longitudinally between the drive shafts 14 and 17 .
- the hydromechanical powersplit transmission 11 may be installed in the vehicle 10 in place of a conventional manual or automatic or variable transmission without substantial alteration of this space or the components of the vehicle 10 that define this space.
- the transmission 11 operates in various modes under a wide variety of conditions.
- the transmission 11 operates in various modes in response to vehicle operator accelerator pedal input to transmit power from the prime mover 13 and/or from stored energy in the high pressure accumulator 46 to the differential drive shaft 17 to propel the vehicle 10 .
- the transmission 11 operates in various modes in response to vehicle operator brake pedal input to capture energy from the vehicle 16 during braking of the vehicle 10 and to transmit the captured energy to the high pressure accumulator storage device 46 for later use.
- the transmission 11 operates in response to vehicle operator input to start the prime mover 13 using stored energy in the accumulator storage device 46 when the vehicle 10 is stationary.
- the displacement and pump or motor operating mode of pump motor units 42 and 43 may be changed and the isolation valves 54 and 55 may be opened or closed.
- the isolation valve 55 for the secondary pump motor unit 43 may act as a check valve, so that the isolation valve 55 opens when pressure in the outlet tube 92 exceeds the pressure in the high pressure accumulator 46 to allow pressure from unit 43 to charge accumulator 46 .
- the isolation valve 54 for the primary pump motor unit 42 may be generally opened when the vehicle 10 is moving, except closed when the secondary unit 43 is pumping during braking to prevent supply of fluid from the secondary unit 43 to the primary unit 42 .
- the isolation valve 54 for the primary unit 42 may be closed, to prevent unintended flow to the secondary unit 43 and unintended movement of the vehicle 10 .
- the transmission 11 may also be used to start the engine 13 , to eliminate the need for a conventional starter.
- hydraulic fluid from accumulator 46 is supplied to primary pump motor unit 42 and isolated from secondary pump motor unit 43 , so that unit 43 and its drive shaft 44 rotate to rotate gears 76 , 77 , 72 and 74 to rotate planet carrier 75 and transfer shaft 62 and input shaft 41 and drive shaft 14 to rotate and start prime mover engine 13 ( FIG. 1 ).
- the proportional control valves 52 and 53 adjust the displacement of the units 42 and 43 during both pumping and motoring modes. For example, when movement of vehicle 10 is initially started from a stopped position, fluid is supplied from accumulator 46 to secondary unit 43 and displacement of unit 43 is gradually increased to accelerate vehicle 10 . As speed of the vehicle 10 increases and displacement of unit 43 increases, fluid pressure from accumulator 46 decreases and less stored energy is available to unit 43 to continue to drive vehicle 10 . As the speed of the vehicle further increases, more power is transmitted mechanically directly from the engine 13 to driveshaft 17 through the planetary gearset 71 , while less power is transmitted by the hydraulic pump motor units. By reducing the hydraulic power transmitted at higher vehicle speeds, the overall transmission efficiency is increased.
- the displacements of pump motors 42 and 43 are steplessly adjusted to achieve a desired output shaft speed for a given input prime mover input shaft speed.
- the adjusting of displacement provides for an infinitely variable or stepless transmission ratio, which allows the prime mover 13 to be operated at its most efficient operating speed regardless of output shaft speed. Additionally, since there is no gear shifting, there is no interruption in power. Under this condition, displacement of units 42 and 43 may be set to zero, to minimize any drag or inefficiency caused by units 42 and 43 .
- secondary unit 43 is operated in a pumping mode and displacement of unit 43 is increased to pump more fluid into accumulator 46 and cause further braking resistance to the drive wheels 15 until the desired slower speed or stopped condition for the vehicle 10 is achieved.
- the sealed hydraulic unit chamber 36 is maintained at a positive pressure of at least about 2 bar and preferably in the range of about 2 bar to about 6 bar, to prevent cavitation in the pump motor units 42 and/or 43 during pumping, while the sealed gear unit chamber 37 is maintained at about atmospheric pressure. Because the pump motor units 42 and 43 are disposed in chamber 36 which is the low pressure reservoir, separate low pressure conduits and connections between the low pressure reservoir and the pump motor units 42 and 43 are not required.
- the transmission 11 provides a hydromechanical powersplit transmission that captures and stores energy as high pressure fluid in accumulator 46 during vehicle braking and that uses that stored energy to propel the vehicle 10 or to start engine 13 . Further, when the vehicle 10 is to be propelled when stored energy in accumulator 46 is depleted, a direct variable speed mechanical connection is provided from engine 14 , through hydraulic unit 23 but without pumping or motoring displacement of the units 42 and 43 , through the planetary gear set 71 and to the drive wheels 15 .
- the planetary gear unit housing 29 includes a front gear unit housing 29 a and a rear gear unit housing 29 b.
- the sealed interior chamber or sump 37 of the planetary gear unit 24 includes a front chamber or front sump 37 a and a rear chamber or rear sump 37 b.
- the primary hydraulic pump motor unit drive shaft 44 extends from the hydraulic side 25 a, through the connecting plate 25 , to the front chamber 37 a, where its associated gear 76 is drivingly connected to the sun gear 72 through gear 77 ( FIGS. 1 and 8 ).
- the planetary gear components 71 including sun gear 72 , ring gear 73 , planet gears 74 and planet carrier 75 and the gear 76 provide a first gear set all disposed within front chamber or sump 37 a.
- the mechanical or prime mover input shaft 41 with its transfer shaft 62 extends from the hydraulic side 25 a, through the connecting plate 25 , to the front sump 37 a, where the transfer shaft is drivingly connected to the planet carrier 75 ( FIGS. 1 and 7 ).
- the secondary hydraulic pump motor unit drive shaft 45 extends from the hydraulic side 25 a, through the connecting plate 25 , through the front sump 37 a, to the rear sump 37 b.
- gear 78 In the rear sump 37 b, the gear 78 is secured on the secondary pump motor unit drive shaft 45 and is drivingly connected to gear 79 ( FIGS. 1 and 9 ). Gear 79 in turn is connected to output drive shaft 63 in rear chamber 37 b and to ring gear 73 . Gears 78 and 79 provide a second gear set disposed in the rear sump 37 b.
- Gear unit front housing 29 a includes a longitudinally extending housing portion or wall 93 and a laterally extending generally planar housing portion or wall 94 .
- Housing portion 94 provides a wall that separates sumps 37 a and 37 b and provides a common or shared wall for each sump 37 a and 37 b.
- An output drive shaft opening 95 extends longitudinally through housing portion or wall 94 , and a bearing 96 in opening 95 supports output drive shaft 63 .
- Gear unit rear housing 29 b includes a longitudinally extending housing portion or wall 97 and a laterally extending generally planar housing portion or wall 98 .
- the output drive shaft opening 63 a extends longitudinally through housing portion or wail 98 , and a bearing 100 in opening 63 a supports output drive shaft 63 .
- the output shaft 63 and gears 79 and 78 and secondary pump motor unit drive shaft 45 are in a stationary condition and are not rotating, in this condition, the fluid level in the chambers or sumps 37 a and 37 b is approximately at a level indicated by dotted line 101 a in FIGS. 7-9 , which is above secondary pump motor unit gear 78 and below planetary gear components 71 .
- the fluid in planetary gear housing 29 within sumps 37 a and 37 b is a suitable gear lubricating oil.
- the fluid in sump 37 of planetary gear housing 29 can be a different fluid than in sump 36 of hydraulic unit housing 26 and can be at a different fluid pressure level. Further, as discussed in greater detail below, while the fluid level within the hydraulic unit housing 26 is substantially at the top of hydraulic unit sump 36 at level 101 b ( FIG.
- the fluid level within planetary gear unit sump 37 is at a different and lower level to avoid heat build-up that would occur if the fluid levels were the same and the planetary gear components 71 and gears in the planetary gear unit housing 37 were submerged in lubricating fluid.
- FIGS. 11 and 12 a rear facing generally planar surface 94 a of the front planetary gear housing 29 a is illustrated in FIG. 11 and a mating front facing generally planar surface 97 a of rear planetary gear housing 29 b is illustrated in FIG. 12 .
- the housings 29 a and 29 b and their respective mating surfaces 94 a and 97 a are illustrated in FIGS. 11 and 12 without any other components.
- a restricted size return opening or fluid passage 102 extends longitudinally through wall 94 at a location vertically below level 101 a to connect sumps 37 a and 37 b
- a larger size pump opening or fluid passage 103 extends longitudinally through wall 94 at a location vertically above level 101 a to connect sumps 37 a and 37 b.
- the surface 98 a includes a generally U-shaped longitudinally recessed pump channel 104 .
- surface 97 a provides a wall to close pump channel 104
- closed pump channel 104 extends between and establishes fluid communication between openings 102 and 103 .
- the front housing 29 a also includes an opening 118 a that may be used for mounting a speed sensor (not shown) for primary pump motor unit 42
- the rear housing 29 b also includes an opening 118 b that may be used for mounting a speed sensor (not shown) for secondary pump motor unit 43 .
- An oil fill hole 118 c is provided in the rear housing 29 b to fill the sumps 37 a and 37 b with lubricating oil.
- gear 78 As illustrated in FIG. 17 , rotation of gear 78 near the bottom of chamber or sump 37 b causes gear 78 to throw or pump fluid from return opening 102 ( FIG. 11 ) near the bottom of chamber or sump 37 b upward through channel 104 ( FIG. 12 ) to pump passage 103 .
- Passage 103 connects rear chamber or sump 37 b to front chamber or sump 37 a on the front side of housing 29 b. This oil from channel 104 flowing through passage 103 will then fall onto the primary gear 76 in front sump 37 a to increase oil splash lubrication in front sump 37 a.
- the output shaft 63 and gears 79 and 78 and secondary pump motor unit drive shaft 45 are rotating and this pumping from sump 37 b to sump 37 a through channel 104 occurs.
- the gear 78 stops rotating fluid returns from front sump 37 a to rear sump 37 b through passage 102 and the fluid level in sumps 37 a and 37 b returns to level 101 a.
- surface 98 a of rear housing portion 29 b also includes longitudinally extending ledges 105 and 106 .
- gear 78 When gear 78 rotates, gear 78 also splashes lubricating oil onto ledges 105 and 106 .
- Oil on ledge 105 flows into front sump 37 a through opening 105 a ( FIG. 11 ) and onto rear primary bearing 81 ( FIG. 8 ).
- Oil on ledge 106 is directed to the park pawl assembly 120 described below through a vertical hole at the right end of ledge 105 as viewed in FIG. 12 .
- lubricating oil from rear sump 37 b is pumped to front sump 37 a to reduce the fluid level in rear sump 37 b, and lubricating oil in the rear sump 37 b is distributed to the moving components and bearings within the sumps 37 a and 37 b .
- This pumping and distribution is accomplished using the secondary gear 78 and the openings and channels and ledges described above, to eliminate the need for a conventional lubrication pump and to minimize the size and weight and complexity of the transmission 11 .
- the front housing 29 a of the gear unit 24 also includes a secondary pump motor shaft opening 108 , and the secondary pump motor shaft 45 extends through opening 108 .
- the housing 29 a also includes a low pressure return line opening 109
- the housing 29 b includes a low pressure return line opening 110 .
- the opening 110 is used to optionally connect a low pressure accumulator to chamber 36 and is not used in the preferred embodiment illustrated in the drawings.
- a low pressure return tube 111 extends through and is sealed within openings 109 and 110 , to connect low pressure hydraulic reservoir or sump 36 through sump 37 a and 37 b to opening 110 .
- the walls 93 and 94 of the front or first housing 29 a define the front or first sump 37 a.
- the rear or second housing 29 b is connected to the first housing 29 a and includes walls 97 and 98 that cooperate with the common wall 94 of the first housing 29 a to define the rear or second sump 37 b.
- a first set of rotatable gears 71 is disposed in the first sump 37 a and has a stationary condition and a rotating condition.
- a second set of rotatable gears 78 , 79 is disposed in the second sump 37 b and has a stationary condition and a rotating condition.
- An input drive shaft 62 extends longitudinally into the first sump 37 a and is rotatably connected to the first set of rotatable gears.
- An output drive shaft 63 extends longitudinally out of the second sump 37 b and is rotatably connected to the second set of gears.
- the longitudinal axes 22 of the input and output drive shafts are substantially coaxial.
- a first hydraulic pump motor unit drive shaft 44 extends into the first sump 37 a and is driving connected with the first set of rotatable gears.
- a second hydraulic pump motor unit drive shaft 45 extends longitudinally from end to end through the first sump 37 a and into the second sump 37 b and is drivingly connected with the second set of rotatable gears.
- the first and second hydraulic pump motor unit drive shafts are supported by bearings in wails 25 , 94 and 98 . Openings 102 and 103 extend between and establish a fluid flow path between the first sump 37 a and the second sump 37 b, and the openings 102 and 103 extend to the channel 104 to pump lubricating liquid from the second sump 37 b to the first sump 37 a when the second set of gears is rotating.
- FIGS. 14 and 22 - 33 various steps in a method 140 of assembling and disassembling and repairing a transmission according to the present invention and various subassemblies or assemblies according to the present invention are illustrated.
- the method 140 and the assemblies provide a hydromechanical powersplit transmission 11 illustrated in the other Figures and described elsewhere in this description.
- the method 140 may be practiced in the step by step order described below, in a different order, or in a reverse order, and the steps may be combined or broken into sub-steps, to assemble and disassemble (in which case the term assemble will be understand to mean disassemble) and repair according to the present invention.
- the method of assembly 140 includes step 140 a illustrated in FIGS. 22 and 33 , which results in a connecting plate assembly 150 a illustrated in FIG. 23 .
- the method step 140 a includes providing a combination connecting and fluid manifold plate 25 as described above, a high pressure flow tube 91 for the primary pump motor unit 42 described above, and an identical high pressure flow tube 92 for the secondary pump motor unit 43 described above.
- the flow tubes 91 and 92 are assembled laterally into laterally extending portions of the high pressure passages 39 in the connecting plate 25 ( FIGS. 8 and 9 ). Once the flow tubes 91 and 92 are assembled in this manner at step 140 a, the assembly 150 a of the connecting plate 25 and the flow tubes 91 and 92 is provided as illustrated in FIG. 23 .
- the method of assembly 140 further includes step 140 b illustrated in FIGS. 23 and 33 , which results in a connecting plate assembly 150 b illustrated in FIG. 24 .
- the method step 140 b includes providing the connecting plate 25 and connecting plate assembly 150 a, the primary pump motor unit shaft 44 , the secondary pump motor shaft 45 , and the bearings 80 and 81 .
- the primary bearing 80 and primary shaft 44 are assembled longitudinally into primary opening 87
- the secondary bearing 81 and secondary shaft 45 are assembled longitudinally into secondary opening 88 .
- the method of assembly 140 further includes step 140 c illustrated in FIGS. 24 and 33 , which results in a connecting plate assembly 150 c illustrated in FIG. 25 .
- the method step 140 c includes providing the connecting plate 25 and connecting plate assembly 150 b, the primary pump motor unit rotating group pistons 42 a and barrel 42 b, the secondary pump motor unit rotating group pistons 42 a and barrel 42 b, and the setting or control pistons 48 - 52 .
- the primary pump motor unit rotating group pistons 42 a and barrel 42 b, the secondary pump motor unit rotating group pistons 42 a and barrel 42 b, and the setting or control pistons 48 - 52 are assembled longitudinally onto the connecting plate 25 and connecting plate assembly 150 b. Once the components are assembled in this manner at step 140 c, the assembly 150 c of the connecting plate 25 and these components is provided as illustrated in FIG. 25 .
- the method of assembly 140 further includes step 140 d illustrated in FIGS. 26 and 33 , which results in a connecting plate assembly 150 d illustrated in FIG. 27 .
- the method step 140 d includes providing the connecting plate 25 and connecting plate assembly 150 c and the hydraulic housing 26 .
- the housing 26 is assembled longitudinally onto the connecting plate 26 and connecting plate assembly 150 c, encapsulating the hydraulic pump motor units 42 , 43 and their rotating groups 42 a, 42 b, 43 a, 43 b and flow tubes 91 , 92 .
- the step 140 d includes sealing housing 26 against the hydraulic side 25 a of connecting plate 25 to provide the sealed chamber or sump 36 .
- Assembly bolts 151 pass longitudinally through aligned holes in connecting plate 25 and housing 26 , and nuts (not shown) are fastened to the ends of bolts 151 to secure housing 26 to connecting plate 26 .
- the bolts 151 provide temporary fastening of the connecting plate 25 and housing 26 during assembly of the gear unit 24 during subsequent steps of the method 140 .
- the method of assembly 140 further includes step 140 e illustrated in FIGS. 27 and 33 , which results in a connecting plate assembly 150 e illustrated in FIG. 28 .
- the method step 140 e includes providing the connecting plate 25 and connecting plate assembly 150 d and the transfer shaft 62 and associated bearing 86 and associated transfer shaft retainer 62 a.
- the transfer shaft 62 and bearing 86 and retainer 62 a are assembled longitudinally onto the connecting plate 25 and connecting plate assembly 150 d, and bolts 62 b secure the retainer 62 a in place.
- the valves 52 and 53 may also be secured to the connecting plate 25 .
- the method of assembly 140 further includes step 140 f illustrated in FIGS. 28 and 33 , which results in a connecting plate assembly 150 f illustrated in FIG. 29 .
- the method step 140 f includes providing the connecting plate 25 and connecting plate assembly 150 e and primary pump motor unit drive gear 76 and one piece integral gear 77 and sun gear 72 .
- the gear 76 is assembled longitudinally onto primary shaft 44
- the integral gear 77 and sun gear 72 is assembled longitudinally onto transfer shaft 62 .
- the method of assembly 140 further includes step 140 g illustrated in FIGS. 29 and 33 , which results in a connecting plate assembly 150 g illustrated in FIG. 30 .
- the method step 140 g includes providing the connecting plate 25 and connecting plate assembly 150 f and planetary components 71 , including planet gears 74 , planet carrier 75 and ring gear 73 , and associated splash gear 112 .
- the planet gears 74 and planet carrier 75 and ring gear 73 are assembled longitudinally onto the sun gear 72 and connecting plate 25 .
- the low pressure return tube 111 may also be assembled in the low pressure return opening 108 of connecting plate 25
- the assembly 150 g of the connecting plate 26 and these components is provided as illustrated in FIG. 30 .
- the method of assembly 140 further includes step 140 h illustrated in FIGS. 30 and 33 , which results in a connecting plate assembly 150 h illustrated in FIG. 31 .
- the method step 140 b includes providing the connecting plate 25 and connecting plate assembly 150 g, front planetary gear housing 29 a, and bearing 96 .
- the front planetary gear housing 29 a is assembled longitudinally onto the connecting plate 25 , encapsulating the gear set 71 , 72 , 73 .
- the step 140 h includes assembling the pump motor unit shaft 44 into bearing 81
- the step 140 h also includes sealing housing 29 a against the planetary gear side 25 b of connecting plate 25 to provide the sealed chamber or sump 37 a.
- the bearing 96 is assembled into opening 95 in housing 29 a.
- Assembly bolts 152 pass longitudinally through aligned holes in front planetary gear housing 29 a, connecting plate 25 and housing 26 , and nuts (not shown) are threaded to the ends of bolts 152 to secure housings 29 a and 26 to connecting plate 25 .
- nuts (not shown) are threaded to the ends of bolts 152 to secure housings 29 a and 26 to connecting plate 25 .
- the method of assembly 140 further includes step 140 i illustrated in FIGS. 31 and 33 , which results in a connecting plate assembly 150 i illustrated in FIG. 31 .
- the method step 140 i includes providing the connecting plate 25 and connecting plate assembly 150 h, output drive shaft 63 , bearing 63 a, gear 79 , park pawl hub 121 , and secondary pump motor unit drive gear 78 .
- the output drive shaft 63 and bearing 63 a are assembled longitudinally into drive shaft opening 95 in aligned relationship with transfer shaft 62 , and gears 79 and 121 are longitudinally assembled onto output drive shaft 63 .
- Secondary pump motor unit drive gear 78 is longitudinally assembled onto secondary pump motor unit drive shaft 45 .
- the method of assembly 140 further includes step 140 j illustrated in FIGS. 32 and 33 , which results in the completed transmission 11 illustrated in FIGS. 1-3 .
- the method step 140 j includes providing the connecting plate 25 and connecting plate assembly 150 i, rear planetary gear housing 29 b, and coupling 64 .
- the rear planetary gear housing 29 b is assembled longitudinally onto the front planetary gear housing 29 a and connecting plate 25 , encapsulating gear set 78 , 79 , 121 .
- the step 140 j includes assembling the pump motor unit shaft 45 into bearing 83 .
- the method step 140 j also includes sealing the rear planetary gear housing 29 b against the front planetary gear housing 29 a to provide the sealed chamber or sump 37 b ( FIG.
- Assembly bolts 153 pass longitudinally through aligned holes in rear planetary gear housing 29 b and are threaded into aligned threaded holes in the front planetary gear housing 29 a.
- the bolts 153 and this step secure the hydraulic unit housing 26 and the front gear unit housing 29 a and the rear gear unit housing 29 b and the connector plate 25 together.
- the temporary bolts used in step 140 d remain in place during step 140 h and hold the hydraulic unit housing 26 and connecting plate 25 together and in place to receive the bolts 153 .
- the coupling 64 is then longitudinally assembled onto output drive shaft 63 . Once the components are assembled in this manner at step 140 j, the assembly of the transmission 11 is complete.
- a hydraulic unit 23 and a planetary gear unit 24 are assembled using a central connecting plate 25 .
- the hydraulic components are assembled on the hydraulic side 25 a of the connecting plate 25
- a hydraulic unit housing 26 is assembled over the hydraulic components and in sealing engagement with the hydraulic side 25 a to provide a sealed chamber 36 that is pressurized during operation of the transmission 11 .
- the planetary gear components are assembled on the planetary gear side 25 b of the connecting plate 25
- planetary gear housings 29 a and 29 b are assembled over the planetary gear components to provide sealed chambers 37 a and 37 b that are isolated from chamber 36 .
- the transmission 11 is assembled onto the vehicle 10 in the position described above.
- the transmission 11 is removed from the vehicle 10 .
- the planetary gear unit housings 29 b and, if necessary, 29 a are removed to access the planetary gear unit components as illustrated in FIG. 5 . Since all planetary gear unit components are assembled onto the connecting plate 25 from the planetary gear unit side 25 b of the connecting plate 25 , all planetary gear unit components may be removed and repaired or replaced without opening the hydraulic unit 23 .
- the hydraulic unit housing 26 is removed to access the hydraulic unit components as illustrated in FIG. 4 .
- FIGS. 7 and 13 - 17 additional structure and features of the planetary gear set 71 , planet carrier 75 , planet gears 74 and lubrication system for the moving components within the front sump 37 a are illustrated, with FIG. 14 illustrating some of the structure in exploded format for clarity.
- the illustrated lubrication system is integral with the planet carrier 75 and planet gears 74 , and eliminates the need for a piston pump or gerotor pump or similar pump having higher energy consuming pumping parts to provide lubricating liquid under pressure to the moving components of the planetary gear set 71 and other moving components within the front sump 37 a.
- the invention provides a thin generally flat lateral splash gear 112 that is integral with the planetary gear set 71 and is carried by and rotates with planet carrier 75 about a longitudinal axis 71 a in the sump 37 a.
- the splash gear 112 includes laterally outwardly extending teeth 112 a, a central generally circular opening 112 b, and three spaced apart notches 112 c extending laterally outwardly from the opening 112 b.
- the notches 112 c each extend circumferentially through an angle of less than about 10 degrees and preferably less than about 5 degrees.
- the planet carrier 75 includes three planet gear shafts 113 , and the three planet gears 74 are each rotatably disposed on a bearing 74 a on one of the shafts 113 .
- the planet gear shafts 113 are each received in a planet shaft bore 114 that extends longitudinally into the planet carrier 75 and are stationary relative to the planet carrier 75 .
- Each of the planet gear shafts 113 includes a laterally extending cross bore 113 a, and laterally extending pins 115 extend into the planet carrier 75 and through the planet shaft cross bores 113 a to retain each planet gear shaft 113 and its associated planet gear 74 in place on the planet carrier 75 .
- Each planet gear shaft 113 further includes a radially outwardly facing lock groove 113 b on its generally cylindrical outer peripheral surface 113 g to retain the splash gear 112 on the planet carrier 75 in the manner further described below.
- the splash gear 112 is assembled in the longitudinal direction onto the radially outer peripheral surface 75 a of a circumferentially extending longitudinally projecting annular lip 75 b on a lateral end face or lateral wall 75 c of planet carrier 75 .
- the notches 112 c of the splash gear 112 are aligned with the shafts 113 so that the shafts 113 project longitudinally through the notches 112 c, and this position of the splash gear 112 is a partially assembled position.
- the splash gear 112 is then rotated about 5 to 10 degrees (clockwise as viewed in FIG. 14 ), so that the notches 112 c rotate a few degrees away from the shafts 113 .
- the planet carrier 75 further includes a longitudinally extending central opening 75 e.
- the central opening 75 e includes an internal spline connector 75 f.
- an external spline connector on the transfer shaft 62 mates to the internal spline connector 75 f of the planet carrier 75 .
- the planet carrier 75 and splash gear 112 are rotatably connected to the transfer shaft 62 and the input shaft 41 , so that these components rotate together under all operating conditions.
- Each planet gear shaft 113 also includes a central bore or lubricating liquid flow passage 113 c.
- Each flow passage 113 c extends into the shaft 113 from the lateral wall 75 c in the longitudinal direction to the left as viewed in the drawings.
- a lateral cross bore or radial passage 113 d extends radially from the central bore 113 c to the outer peripheral surface 113 g of each planet gear shaft 113 to provide lubricating liquid between each planet gear shaft 113 and an associated planet gear shaft bore 114 of the planet gear 74 and bearing 74 a that is disposed on the shaft 113 .
- the radial passage 113 d extends radially outward from the central bore 113 c in a direction away from the longitudinal axis 71 a.
- Each planet gear shaft 113 also includes a out away bevel portion 113 e at or near its end, adjacent the annular lip 75 b of the planet carrier 75 .
- the bevel portion 113 e extends radially from the outer peripheral surface 113 g of the shaft 113 and terminates at a longitudinally extending laterally inwardly facing wail 113 f that is substantially adjacent to and communicates with the central flow passage 113 c.
- the wall 113 f is radially outward from and substantially adjacent to the flow passages 113 c and provides a planet gear shaft lubricating liquid catch wail that catches lubricating liquid and directs the lubricating liquid to the flow passage 113 c.
- a further portion of the lubricating system in the chamber or sump 37 a is provided by a sheet metal baffle or trough 117 ( FIGS. 13 and 7 ).
- the baffle 117 includes a laterally extending wail 117 a and tabs 117 b, and the tabs 117 b fasten the trough 117 to planetary gear side 25 b of connecting plate 25 .
- the splash gear 112 rotates with the planet carrier 74 and lateral wall 74 c about axis 71 a.
- the teeth 112 a of the splash gear 112 rotate into and out of the lubricating oil in the lower portion of the front sump 37 a below the fluid level 101 a.
- this splashed lubricating liquid enters the space between the trough wall 117 b and the connecting plate gear side 25 b, and this oil flows by gravity to lubricate bearing 86 .
- Some of the splashed lubricating liquid engages and accumulates on the rotating lateral wall 75 c of the planet carrier 75 to at least partially coat the lateral wall 75 c with lubricating oil.
- this liquid is deposited in this manner on the lateral wall 75 c, the liquid begins to rotate with the lateral wall 75 c.
- the lubricating liquid immediately adjacent the wall 75 c will rotate substantially at the same rotational velocity as the wall 75 c, and the liquid farther away from the wall 75 c will rotate at a slightly lesser rotational velocity than the wall 75 c.
- the catch wall 75 g is substantially adjacent each flow passage 113 c and is at least partially radially outward from each flow passage 113 c.
- the lubricating liquid begins to accumulate at or flood the catch wall 75 g, and the thickness or depth of the lubricating liquid increases at the location of the catch wall 75 g.
- the accumulating lubricating liquid flows circumferentially along the rotating catch wall 75 g. This flow will be in a direction opposite the direction of rotation of the lateral wall 75 c and catch wall 75 g and toward and along the inwardly facing catch wall 113 f of each associated planet gear shaft 113 . A portion of this accumulating liquid then flows longitudinally through the passages 113 c and then radially through the passages 113 d to lubricate outer peripheral surfaces 113 g of planet gear shafts 113 and bearings 74 a and planet gears 74 .
- inwardly facing catch wall 113 f of each planet gear shaft 113 is generally laterally and circumferentially aligned with the inwardly facing catch wail 75 g so that the surfaces 75 g and 113 f provide a generally smooth generally annular catch wall.
- the catch wall 75 g extends longitudinally from the lateral wall 75 c in the opposite direction to the flow passages 113 c (that is, to the right as viewed in the drawings).
- the annular catch wall 75 g includes catch wall portions 75 h adjacent each of the flow passages 113 c, extending circumferentially in the direction of rotation of the lateral wall 75 c and catch wail 75 g. Lubricating liquid accumulating on each of these catch wall portions 75 h will flow to an adjacent flow passage 113 g, while lubricating liquid accumulating on the catch wall 75 g on the other side of a flow passage 113 g will flow to the next flow passage 113 g or will flood over the catch wall 75 g and contribute to the splash lubricating suspension or droplets.
- Each of the catch wall portions 75 h has a sufficient circumferential extent to catch lubricating oil to feed its adjacent flow passage 113 c.
- this circumferential extent is at least about 10 degrees.
- the catch wail portions 75 h are each generally semicircular and are joined to form the continuous annular catch wall 75 g.
- the term circumferential extending in relation to the catch wall portions 75 h describes both curved surfaces and straight surfaces, so that, for example, the catch wall portions 75 h could alternatively be straight wall portions.
- the catch wall portions 75 h in the preferred embodiment are joined together to provide the continuous catch wall 75 g, the catch wall portions 75 h could alternatively be separated from one another.
- the catch wail 75 g and its catch wall portions 75 h may extend perpendicular to the lateral wall 75 c (in which case they extend only in the longitudinal direction) or at another angle relative to the lateral wall 75 c (in which case they would extend in both the longitudinal and the lateral or radial direction).
- the lateral wall 75 c may be disposed in a plane that is perpendicular to the longitudinal axis 71 a (in which case it extends only in the lateral direction) or in a plane at another angle relative to the longitudinal axis 71 a (in which case it would extend in both the lateral and the longitudinal direction).
- lubricating oil from rear sump 37 b is pumped through channel 104 to front sump 37 a to reduce the fluid level in rear sump 37 b, and lubricating oil in the front sump or chamber 37 a is distributed to the moving components and bearings within the chamber 37 a.
- This distribution is accomplished using the splash gear 112 and the planet carrier 75 and lateral wall 74 c and catch walls 75 g, 75 h and 113 f and flow passages 113 c and 113 d and planet gear shafts 113 , to eliminate a need for a conventional lubrication pump and to minimize the size and weight and complexity of the transmission 11 .
- the lubricating system could alternatively secure a rotating splash gear and rotating lateral wall with catch walls to a different rotating planetary gear set component, such as for example a rotating ring gear, or could alternatively be used with other types of gear sets or in other applications.
- the transmission 11 further includes a park pawl assembly 120 .
- the park pawl assembly 120 locks the output drive shaft 63 (and the gears 79 and 73 and the ring gear 73 ) against rotation to prevent unwanted movement of the vehicle 10 such as when the vehicle 10 is parked. This is accomplished by the park pawl assembly 120 locking the drive shaft 63 to the stationary rear planetary housing 29 .
- the park pawl assembly 120 is moveable between an engaged or locked position illustrated in FIGS. 17 , 18 and 20 , and a disengaged or unlocked position illustrated in FIGS. 19 and 21 .
- the park pawl assembly 120 permits use of a relatively small assembly arranged in the sump 37 , to accommodate relatively large forces required to lock the transmission and drive wheels of relatively large weight vehicles and to transmit those relatively large forces to the housing 29 without over stressing the park pawl assembly 120 or the housing 29 .
- the park pawl assembly 120 includes a park hub 121 ( FIGS. 1 and 17 ) disposed in the rear interior chamber or sump 37 b between the front planetary gear housing 29 a and the lateral surface 98 a of the rear planetary gear housing 29 b.
- the hub 121 is secured to the output drive shall 63 by a spline connection.
- a pawl 122 is disposed on a pawl shaft 123 for rotational movement about the longitudinal axis or pivot axis of the shaft 123 between the locked position illustrated in FIGS. 17 , 13 and 20 and the unlocked position illustrated in FIGS. 19 and 21 .
- the hub 121 and pawl 122 are each preferably of a suitable steel material that is case hardened, for example by carburizing, to a suitable hardness, for example about Rockwell C60.
- the pawl shaft 123 and its pivot axis extend longitudinally parallel to the output drive shaft 63 .
- the pawl shaft 123 is secured to housings 29 a and 29 b by the opposite ends of the shaft 123 being received in a bore 123 a in housing 29 a and in a bore 123 b in housing 29 b ( FIGS. 11 and 12 ).
- the pawl 122 is generally flat or planar in the lateral direction and includes a pawl arm 124 , a pawl locking finger 125 and a pawl actuating finger or pawl locking surface 126 laterally opposite the pawl locking finger 125 .
- the pawl 122 including the locking finger 124 and the locking surface 126 , are moved along a park pawl path between locked and unlocked positions by a park pawl actuator 127 .
- the park pawl path is a rotational path about the park pawl pivot axis.
- the park pawl actuator 127 is a generally cylindrical plunger.
- a cam face or cam surface 128 is provided on the outer peripheral cylindrical surface of one side of the actuator 127 to engage the park pawl locking surface 126 , and the remainder of the actuator 127 retains its cylindrical shape.
- the park pawl actuator 127 slides in a substantially straight line park pawl actuator path along the longitudinal axis 127 a of the actuator 127 within a generally cylindrical bushing 129 , which is fit into a bore in housing 29 b and retained within the bore by a threaded cap or plug 130 .
- the bore is preferably generally cylindrical.
- the substantially straight line path of the park pawl actuator 127 is substantially perpendicular to the pivot axis of the park pawl 122 and is perpendicular to the direction of movement of the park pawl locking finger 125 and locking surface 126 as the locking finger 125 and locking surface 126 move between their locked and unlocked positions.
- the cylindrical bushing 129 has an axial extent that is longer than the axial extent of the park pawl actuator 127 . This permits the park pawl actuator 127 to slide within the bushing 129 during the entire travel of the park pawl actuator 127 between its locked position ( FIG. 18 ) and its unlocked position ( FIG. 19 ). Also, the portion of the cylindrical bushing 129 circumferentially aligned with the cam surface 128 of the park pawl actuator 127 is cut away, to allow the pawl actuating finger 126 to extend through the cut away portion of the bushing 129 and engage the cam surface 128 .
- the cut away portion of the bushing 129 is in the shape of a slot that extends longitudinally slightly more than half the length of the bushing 129 from the bottom of the bushing 129 and that extends circumferentially an amount sufficient to accommodate the width of the actuator finger 126 that extends through the cut away portion to engage the cam surface 128 .
- a cross pin 131 at the bottom of the bore orients the bushing 129 and retains it against rotational movement in the bore.
- the pin 131 also provides a stop for the park pawl actuator 127 when the cam is pushing the pawl 122 downwardly into its locked position.
- the cylindrical shape of the park pawl actuator 127 and bushing 129 aids machining of the cam surface 123 .
- cylindrical shape of the park pawl actuator 127 and bushing 129 and bore radially opposite the cam face 123 provides curved surfaces that spread lateral loads transmitted by the pawl 122 laterally against the cam face 128 of the park pawl actuator 127 and against the housing 29 b over a relatively large area of the housing 29 b and bushing 129 to reduce stress.
- the park pawl 127 is free floating with the bushing 129 and bore in which the bushing 129 is disposed.
- a locking spring 132 pushes or biases the free floating park pawl actuator 127 toward the locked position illustrated in FIGS. 17 , 18 and 20 .
- the cam face 128 of park pawl actuator 127 in the locked position engages or acts against the park pawl locking surface 126 to lock the pawl locking finger 125 of the pawl 122 against the hub 121 between adjacent teeth and against one tooth of the hub 121 . This locks the hub 121 and output drive shaft 64 against the housing 29 b and prevents rotation of the output drive shaft 64 and drive wheels 15 .
- the cam face or cam surface 123 of the actuator 127 includes a radially outer portion 128 a that is radially outward from the longitudinal axis 127 a.
- the radially outer portion 123 a extends in the longitudinal direction and provides a positive lock to engage the locking surface 126 when the actuator 127 and pawl 122 are in their locked position, to prevent release of the pawl locking finger 125 even with large loads imposed on the locking finger 125 such as may occur if the vehicle 10 is parked on a hill.
- the portion 128 a may be slightly fiat relative to the generally cylindrical outer peripheral surface of the actuator 127 or may be coextensive with the generally cylindrical outer peripheral surface.
- the cam face 128 also includes a generally flat radially inner portion 128 b that is radially inward toward the longitudinal axis 127 a relative to the surface 128 a.
- the surface 128 b extends in the longitudinal direction and engages the pawl locking surface 126 when the pawl 122 and actuator 127 are in their unlocked positions.
- the cam face 128 further includes an inclined portion or ramp that extends longitudinally and radially relative to the axis 127 a between the outer portion 128 a and the inner portion 128 b.
- the locking surface 126 engages the inclined surface as the actuator 127 and the park pawl 122 move between their locked and unlocked positions.
- the outer peripheral surface of the generally cylindrical park pawl actuator 127 circumferentially spaced from the cam surface 128 provides an actuator curved surface 128 c.
- the cam surface 123 is laterally intermediate the pawl locking ringer 125 and the actuator curved surface 128 c, whereby forces transmitted by the locking finger 125 through the locking surface 126 against the cam surface 128 are transmitted to the actuator curved surface 128 c and against the curved surface of the bushing 129 and against the curved surface of the bore in the housing 29 b in which the bushing 129 and actuator 127 are disposed.
- a release arm 133 and a release lever 134 are secured to a release shaft 135 , and the components 133 , 134 and 135 rotate or pivot together as a unit about the longitudinal axis or release arm pivot axis 135 a of the release shaft 135 .
- the release arm pivot axis and the park pawl pivot axis and the path of the park pawl actuator 127 are substantially perpendicular to one another.
- This rotation of the release lever 134 rotates the shaft 135 and the release arm 133 about the pivot axis 135 a, so that the release arm 133 positively lifts the park pawl actuator 127 upward along its substantially straight line movement path 127 a in the bushing 129 against the bias of the spring 132 , to allow release of the pawl locking finger 125 from the hub 121 .
- a second spring biases the pawl 122 and locking finger 125 away from the hub 121 and against the cam face 128 , to release the locking finger 125 from hub 121 and prevent unintentional engagement.
- the inclined ramp intermediate the portions 128 a and 128 b smoothly guides the pawl locking surface 126 about the pawl pivot axis 135 a of the pawl shaft 135 as the park pawl 122 moves to its unlocked position.
- the release lever 134 is preferably secured to a cable (not shown) that is operated by the driver of the vehicle 10 or by an actuator (not shown) to rotate the release lever 134 .
- the release lever 134 is rotated to rotate the release arm 133 in the opposite direction from the unlocked position to the locked position, the spring 132 biases the park pawl actuator 127 downward as viewed in the drawings.
- the inclined portion of the cam face 128 engages the pawl locking surface 126 and rotates a locking finger 125 of the pawl 122 against the hub 121 . If the locking finger 125 engages a tooth of hub 121 rather than entering a space between adjacent teeth, the action of spring 132 retains the locking finger 125 biased against the tooth until the hub 121 rotates a slight amount such as by slight movement of the vehicle 10 . When this slight movement occurs, the locking finger 125 will then move into the space between adjacent teeth to lock the hub 121 against movement. When the locking finger 125 is seated in the space between adjacent teeth of the hub 121 , the radially outer portion 128 a of the cam face 128 engages the locking surface 126 and positively locks the park pawl 122 in its locked position.
- the hub 121 includes several teeth on its outer peripheral surface, and the profile of each tooth is involute.
- the profile of the oppositely facing surfaces of the pawl locking finger 125 that engage the teeth is substantially flat.
- the park pawl assembly 120 When the park pawl assembly 120 is in its unlocked position and the park pawl actuator 127 is moved to allow spring 132 to urge the finger 125 toward its locked position, the involute profile of the teeth and the substantially flat profile of the finger 125 prevent the finger 125 from fully entering the space between the teeth and locking against a tooth of the hub 121 until the vehicle has slowed to an acceptable slow speed, for example one mile per hour or less, or has stopped.
- the park pawl assembly 120 therefore includes the park pawl 122 , the park pawl actuator 127 , and the release arm 133 .
- the park pawl actuator 127 is a generally cylindrical plunger and moves with its cam surface 123 along a substantially straight line path from an unlocked position to a locked position by operation of the locking spring 132 in response to rotational movement of the release arm 133 to its locked position.
- This substantially straight line movement of the actuator 127 is substantially perpendicular to the direction of movement of the locking surface 126 and locking finger 125 of the park pawl 122 and causes movement of the park pawl 122 to its locked position.
- the release arm 133 rotates about its pivot axis back to its unlocked position, and this rotational movement of the release arm 133 causes substantially straight line movement of the park pawl actuator 127 against the bias of the locking spring 132 back to its unlocked position, to return the park pawl 122 to its unlocked position.
- the gears and shafts described above are preferably secured together using a spline connection 160 illustrated in FIGS. 34-33 .
- the spline connection 160 is illustrated in FIGS. 34-38 as applied to the connection between the primary pump motor unit drive shaft 44 and the primary pump motor unit drive gear 76 .
- the same spline connection 160 is also used between the secondary pump motor unit drive shaft 45 and its associated drive gear 78 and between other shaft and gear connections illustrated in the drawings.
- the spline connection 160 may be used in other applications to drivingly connect two components such as a shaft and a member arranged on the shaft.
- the spline connection 160 includes an internal spline connector 161 on the gear 76 and a mating external spline connector 162 on the shaft 44 .
- the primary gear 76 includes external gear teeth 163 and a longitudinally extending bore 164 .
- the bore 164 provides an internal spline connector, and the internal spline connector 164 extends longitudinally from end to end through the gear 76 for a longitudinal extent 165 .
- the internal spline connector 164 includes a spline portion 166 having a longitudinal extent 167 .
- the longitudinal extent 167 of the spline portion 166 is at least about 30% of the longitudinal extent 165 of the internal spline connector 164 and is preferably between about 50% and about 80 percent of the longitudinal extent 165 of the internal spline connector 164 . In the preferred embodiment illustrated in FIG. 35 , the longitudinal extent 167 of the spline portion 166 is about 60% of the longitudinal extent 165 of the internal spline connector 167 .
- the internal spline connector 164 also includes a pilot and centering portion 168 having a substantially cylindrical generally smooth surface substantially adjacent the spline portion 166 .
- the pilot and centering portion 168 has a longitudinal extent 169 .
- the longitudinal extent 169 of the pilot and centering portion 168 is at least about 10% of the longitudinal extent 165 of the internal spline connector 164 and is preferably between about 20% and about 60% of the longitudinal extent 165 of the internal spline connector 164 . In the preferred embodiment illustrated in FIG. 35 , the longitudinal extent 169 of the pilot and centering portion 168 is about 40% of the longitudinal extent of the 165 of the internal spline connector 164 .
- the pilot and centering portion 168 has an internal diameter 170 that is substantially greater than the internal diameter 171 of the crests of the teeth of the splines of the spline portion 166 .
- the solid lines indicated in FIG. 35 for the spline portion 166 illustrate the crests of the splines, and the dotted lines indicated in FIG. 35 for the spline portion 166 illustrate the roots of the splines.
- the external spline connector 162 of the shaft 44 is an external surface 172 of the shaft 44 that is at least partially radially aligned with the internal spline connector portion 161 of the gear 76 when the gear 76 is partially or fully assembled on the shaft 44 .
- the external spline connector 162 has a longitudinal extent 173
- the external spline connector 162 includes a spline portion 174 and a substantially smooth generally cylindrical centering portion 175 longitudinally substantially adjacent the spline portion 174 .
- the spline portion 174 has a longitudinal extent 176 that is greater than about 40% of the longitudinal extent 173 and is preferably between about 60% and about 100% of the longitudinal extent 173 .
- the longitudinal extent 176 is about 80% of the longitudinal extent 173 .
- the centering portion 175 has a longitudinal extent 177 that is less than about 50% of the longitudinal extent 173 and is preferably between about 30% and 0% of the longitudinal extent 173 . In the preferred embodiment, the longitudinal extent 177 is about 20% of the longitudinal extent 173 .
- the solid lines indicated in FIG. 36 for the spline portion 174 indicate the crests of the splines, and the dotted lines indicated in FIG. 36 for the spline portion 174 indicate the roots of the splines. Only the roots of the splines of the spline portion 174 are illustrated in FIGS.
- the generally smooth portion 163 is longitudinally substantially adjacent its spline portion 188 on one side of the spline portion 163
- the generally smooth portion 175 is substantially adjacent its spline portion 174 on the opposite side of the spline portion 174 .
- FIG. 37 illustrates the gear 76 and shaft 44 , and the infernal and external spline connectors 161 and 162 , in a disassembled configuration.
- the smooth pilot and centering portion 168 of the infernal spline connector 161 is moved longitudinally onto and over the spline portion 174 of the external spline connector 162 of the shaft 44 , to a first partially assembled position or configuration illustrated in FIG. 34 a.
- the centering portion 168 of the internal spline connector 161 lightly engages and centers and guides the shaft 44 and its external spline connector 162 to longitudinally and circumferentially align the spline portions 166 and 174 .
- the pilot and centering portion 168 aligns the longitudinal axis of the gear 76 relative to the longitudinal axis of the shaft 44 so that these axes are substantially coaxial.
- the gear 76 can be rotated relative to the shaft 44 while the smooth pilot and centering portion 168 is in radial alignment with the spline portion 174 as illustrated in FIG. 34 a, to circumferentially align splines of the internal spline portion 166 with the splines of the external spline portion 174 .
- the smooth pilot and centering portion 168 has a diameter only slightly larger than the diameter of the crests of the spline portion 174 , for example with a minimal clearance fit between the portions 168 and 174 , to assist in aligning the portions 163 and 174 without binding during assembly.
- Suitable stops may be provided to lock the gear 76 against longitudinal movement relative to the shaft 44 after assembly to the position illustrated in FIG. 34 , although such stops may not be required in the assembly illustrated in the drawings.
- the spline connection 161 includes an internal spline connector 161 and an external spline connector 162 .
- At least one of the spline connectors 161 or 162 include a spline portion and a smooth centering portion.
- the smooth centering portion of one of the spline connectors 161 or 162 cooperates with the spline portion of the other spline connector to align the connectors 161 and 162 while permitting rotating movement between the spline connectors 161 and 162 .
- the smooth centering portion of the one spline connector moves into registry with the smooth centering portion of the other spline connector to continue to maintain alignment and reduce relative movement between the spline connectors.
Abstract
A motor vehicle 10 includes a hydromechanical powersplit transmission 11, a prime mover 13, an engine drive shaft 14, drive wheels 15, a differential 16, a differential drive shaft 17, and frame rails 18. The transmission 11 includes a connecting plate 25 having a hydraulic side 25 a with a pressurized hydraulic chamber 36 filled with hydraulic fluid and a gear set side 25 b with an atmospheric pressure gear side chamber 37 partially filled with lubricating oil. The connecting plate 25 provides a hydraulic manifold. A prime mover input shaft 41, 62 extends through the hydraulic chamber 36 and connecting plate 25 and is drivingly connected to one of the planetary gear components 71. Hydraulic pump motor units 42, 43 include hydraulic pump motor unit drive shafts 44, 45 that extend through connecting plate 25 and are drivingly connected to planetary gear components 71.
Description
- The present patent application is a continuation of PCT/US2013/023048, filed on Jan. 25, 2013 which claims the benefit of U.S. Provisional Patent Application Ser. No. 61/641,467 filed May 2, 2012, the disclosures of which are incorporated herein by reference in entirety.
- The present patent application also cross references related patent applications filed of even date herewith by the assignee of the present patent application and titled “Hydromechanical Transmission With Double Sump Gear Unit Housing,” and “Method of Assembly for Hydromechanical Transmission.”
- This invention relates generally to a hydromechanical transmission, and more specifically to a hydromechanical powersplit transmission for a hydraulic hybrid vehicle, and to components and assemblies and methods that may be used with such transmissions and elsewhere.
- Hydromechanical transmissions, including hydromechanical powersplit transmissions, are used in hydraulic hybrid vehicles. Such vehicles may include a vehicle prime mover such as an internal combustion engine, at least one hydraulic pump motor unit, a gear set such as a planetary gear set, and an output shaft connecting the planetary gear set to a drive shaft of the vehicle. The internal combustion engine and the hydraulic pump motor unit are connected to the gear set, and the gear set splits power from the internal combustion engine and from the hydraulic pump motor unit in a motoring mode to rotate the drive shaft and propel the vehicle. The pump motor unit may also be used in a pumping mode to capture energy under certain conditions such as braking the vehicle, and the captured energy may be stored in an energy storage device such as a hydraulic accumulator to power the hydraulic pump motor unit in the motoring mode.
- Various prior art configurations for hydromechanical powersplit vehicle transmissions may be used in off-highway vehicle applications such as agricultural tractors and wheel loaders or in on-highway applications such as delivery trucks. The ability of the powersplit transmission to provide infinitely variable speed allows the engine to run at its optimum efficiency conditions, while transmission of most power through the mechanical power path rather than through the hydraulic power path may result in relatively high transmission efficiency when hydraulic power is limited or not being used. Smooth and seamless control with uninterrupted transfer of torque from the prime mover and/or the hydraulic pump motor unit to the vehicle drive shaft may result in good performance when compared to manual and automatic transmissions having discrete gear ratios, white elimination of a hydrodynamic torque converter may help achieve efficiency when compared to automatic transmissions.
- In transmissions of this type, and in hydromechanical components and assemblies and methods for use in such transmissions and elsewhere, technical problems include difficulties with system complexity, efficiency, size, weight, flexibility, lubrication of components, sump oil fill levels and heat build-up, assembly, repair, transmission of forces and torque in relatively large weight vehicles, and parking lock requirements. More specifically, these technical problems include alignment with other components of a vehicle such as the prime mover engine and the differential, ease of assembly, ease of installation in a vehicle and removal from the vehicle, space availability of the vehicle, space requirements of the transmission and within the transmission, weight of the transmission, smooth operation, transmission control, ease of disassembly and repair, and flexibility to change for use in a variety of different vehicles and different applications. Still more specifically, these technical problems include difficulty assembling and attaching and integrating the hydraulic components, including the hydraulic pump motor units and the controls and drive shafts for the hydraulic pump motor units and the hydraulic flow passages and ports for the hydraulic pump motor units, with the planetary gear set, including the drive gears and planetary gear set components, and assembling those components to the prime mover and differential of the vehicle. Further technical problems include lubrication of gear components, including size and complexity and efficiency of lubrication fluid pumps, and assembly and alignment of spline connections. Further technical problems include complexity of, and forces and stresses imposed on, parking lock mechanisms in relatively large weight vehicles.
- The present invention addresses the certain of the aforementioned technical problems and provides a hydromechanical vehicle transmission and assemblies for use in such transmissions and elsewhere. The transmission and assemblies according to the present invention may be used in a motor vehicle in place of a conventional manual or automatic transmission, connected directly to a conventional vehicle prime mover engine drive shaft and differential drive shaft, and situated between typical vehicle frame rails, while providing a configuration that is modular, compact, and capable of kinetic brake energy recovery, with good efficiency.
- Still more specifically, the invention provides a hydromechanical transmission and assemblies that integrate hydraulic components with gear set components in an integral assembly. Still more specifically, the invention provides a connecting assembly for a hydromechanical transmission that includes a connecting plate having a hydraulic unit side and a gear unit side. Mechanical drive and hydraulic drive openings extend longitudinally through the connecting plate, and the connecting plate and hydraulic components and gear unit components are connected as an integral assembly. The connecting plate provides a hydraulic fluid manifold for the hydraulic components.
- At least one embodiment of the invention provides a hybrid vehicle hydromechanical or hydromechanical powersplit transmission including a hydraulic unit housing having a sealed internal chamber and a gear unit housing having a separate internal chamber sealed from the hydraulic unit housing internal chamber. The hydraulic unit housing may be connected to the gear unit housing in longitudinally aligned relationship. The hydraulic unit housing may have a prime mover input shaft opening at its input end and at least one and preferably two variable displacement hydraulic pump motor units with pump motor unit drive shafts disposed within the hydraulic unit housing interior chamber in laterally offset relation to the prime mover input shaft opening. The variable displacement hydraulic pump motor units and their pump motor unit drive shafts may be in circumferentially spaced relation and in axially spaced relation to one another. The gear unit housing may have an output drive shaft opening at its output end extending longitudinally from the gear unit housing interior chamber and a gear unit having gear unit components. An input shaft may be disposed in the input shaft opening, and an output shaft may be disposed in the output shaft opening. The input shaft and the hydraulic pump motor unit drive shaft(s) and the output shaft may each be drivingly connected to one of the gear components. The input shaft opening, input shaft, output shaft opening and output shaft may be substantially coaxial, so that the transmission may be connected to a conventional vehicle prime mover engine and a conventional vehicle drive wheel differential. The gear unit may include a planetary gear set having planetary gear components. Various different hydraulic components may be used with various different gear set components, to provide flexibility for use in a wide variety of applications and vehicles.
- At feast one embodiment of the invention further provides a connecting plate intermediate the hydraulic unit housing and the gear unit housing. One side of the connecting plate may provide a wall of the hydraulic unit housing interior chamber, and the other side of the connecting plate may provide a wall of the gear unit housing interior chamber. The hydraulic pump motor units and the gear set may be mounted on and carried by the connecting plate. The connecting plate may also provide a hydraulic manifold having fluid flow passages in fluid communication with each pump motor unit, and the connecting plate may include bearings for supporting rotating shafts including the pump motor unit drive shafts. One type of fluid may be disposed within the hydraulic unit housing interior chamber to provide a hydraulic fluid reservoir, and a different type of fluid with a different fluid level may be disposed within the planetary gear unit housing interior chamber to provide gear lubrication. Components of the hydraulic unit extend into the gear unit and provide integral portions of the gear unit, while portions of the gear unit provide integral portions of the hydraulic unit.
- At least one embodiment of the invention further provides a motor vehicle having two laterally spaced apart longitudinally extending frame rails, and the hydromechanical powersplit transmission is disposed between the frame rails. The motor vehicle includes a drive shaft and a prime mover having a prime mover shaft, the drive shaft is axially aligned with and drivingly connected to the output shaft, and the prime mover shaft is axially aligned and drivingly connected to the input shaft.
- The invention further provides the combinations set out in the accompanying claims. This Summary is not intended to identify key features or essential features of the claimed subject matter, and these and other features of the invention are more fully described and particularly pointed out in the description and claims set out below. The following description and claims and the annexed drawings set forth in detail certain illustrative embodiments of the invention, and these embodiments indicate but a few of the various ways in which the principles of the invention may be used.
- Embodiments of this invention will now be described in further detail with reference to the accompanying drawings, in which:
-
FIG. 1 is a schematic diagram of a wheeled land vehicle that includes a hydromechanical powersplit transmission according to a preferred embodiment of the present invention; -
FIG. 2 is a more detailed enlarged view of a portion of the schematic diagram illustrated inFIG. 1 ; -
FIG. 3 is a perspective view of the hydromechanical powersplit transmission illustrated schematically inFIG. 1 , as viewed from the front driver side of the vehicle in which the transmission is installed; -
FIG. 4 is a perspective view of the transmission illustrated inFIG. 1 , similar toFIG. 3 but having a hydraulic unit housing removed from a central connecting plate; -
FIG. 5 is another perspective view of the transmission illustrated inFIG. 1 , as viewed from the rear driver side of the vehicle in which the transmission is installed, but having a planetary gear unit housing removed from the central connecting plate and having the planetary gear unit gears illustrated: -
FIG. 6 is a rear or output end view of the transmission illustrated inFIG. 1 ; -
FIG. 7 is a cross sectional view taken along plane 7-7 inFIG. 6 ; -
FIG. 8 is a cross sectional view taken along plane 8-8 inFIG. 6 ; -
FIG. 9 is a cross sectional view taken along plane 9-9 inFIG. 8 ; -
FIG. 10 is a cross sectional view taken along plane 10-10 inFIG. 6 ; -
FIG. 11 is a perspective view of a front planetary gear unit housing for the planetary gear unit of the transmission illustrated inFIG. 1 , as viewed from the rear driver side of the vehicle in which the transmission is installed, and with all associated components removed for clarity; -
FIG. 12 is a perspective view of a rear planetary gear unit housing for the planetary gear unit of the transmission illustrated inFIG. 1 , as viewed from the front passenger side of the vehicle in which the transmission is installed, and with all associated components removed for clarity; -
FIG. 13 is an enlarged perspective view of a lubricating liquid baffle or trough for the planetary gear unit of the transmission illustrated inFIG. 1 ; -
FIG. 14 is an exploded perspective view of a planetary gear and splash gear assembly for the planetary gear unit of the transmission illustrated inFIG. 1 , as viewed from the rear driver side of the vehicle in which the transmission is installed; -
FIG. 15 is a view similar toFIG. 14 , but showing the exploded components fromFIG. 14 in an assembled condition; -
FIG. 16 is a cross sectional view of the planetary gear and splash gear assembly illustrated inFIGS. 14 and 16 , taken along reference view line 16-16 inFIG. 15 ; -
FIG. 17 is an elevation view of the rear planetary gear unit housing illustrated inFIG. 12 , with some associated components installed and other associated components removed for clarity, as viewed from the front of the vehicle in which the transmission is installed, illustrating a park pawl assembly for the transmission illustrated inFIG. 1 ; -
FIG. 13 is an enlarged view of a portion of the rear planetary gear housing shown inFIG. 17 , with a park pawl hub removed for clarity, illustrating the portion of the rear planetary gear housing and the park pawl assembly in cross section, and with the park pawl assembly in an engaged or locked position; -
FIG. 19 is a view similar toFIG. 18 , with the park pawl assembly in a disengaged or unlocked position; -
FIG. 20 is a cross sectional view taken along reference view line 20-20 inFIG. 17 , with the park pawl assembly in the engaged or locked position; -
FIG. 21 is a cross sectional view similar toFIG. 20 , with the park pawl assembly in the disengaged or unlocked position; -
FIG. 22 is an exploded perspective view illustrating a step in the method of assembling the transmission illustrated inFIG. 1 and a subassembly of the transmission, as viewed from the passenger side front of the vehicle in which the transmission is assembled; -
FIG. 23 is an exploded perspective view illustrating another step in the method of assembling the transmission illustrated inFIG. 1 and another subassembly of the transmission, as viewed from the passenger side front of the vehicle in which the transmission is assembled; -
FIG. 24 is an exploded perspective view illustrating another step in the method of assembling the transmission illustrated inFIG. 1 and another subassembly of the transmission, as viewed from the passenger side front of the vehicle in which the transmission is assembled: -
FIG. 25 is a perspective view illustrating another step in the method of assembling the transmission illustrated inFIG. 1 and another subassembly of the transmission, as viewed from the passenger side front of the vehicle in which the transmission is assembled; -
FIG. 26 is an exploded perspective view illustrating another step in the method of assembling the transmission illustrated inFIG. 1 and another subassembly of the transmission, as viewed from the driver side rear of the vehicle in which the transmission is assembled; -
FIG. 27 is an exploded perspective view illustrating another step in the method of assembling the transmission illustrated inFIG. 1 and another subassembly of the transmission, as viewed from the driver side rear of the vehicle in which the transmission is assembled; -
FIG. 28 is an exploded perspective view illustrating another step in the method of assembling the transmission illustrated inFIG. 1 and another subassembly of the transmission, as viewed from the passenger side rear of the vehicle in which the transmission is assembled; -
FIG. 29 is an exploded perspective view illustrating another step in the method of assembling the transmission illustrated inFIG. 1 and another subassembly of the transmission, as viewed from the driver side rear of the vehicle in which the transmission is assembled; -
FIG. 30 is an exploded perspective view illustrating another step in the method of assembling the transmission illustrated inFIG. 1 and another subassembly of the transmission, as viewed from the driver side rear of the vehicle in which the transmission is assembled; -
FIG. 31 is an exploded perspective view illustrating another step in the method of assembling the transmission illustrated inFIG. 1 and another subassembly of the transmission, as viewed from the driver side rear of the vehicle in which the transmission is assembled; -
FIG. 32 is an exploded perspective view illustrating another step in the method of assembling the transmission illustrated inFIG. 1 and another subassembly of the transmission, as viewed from the driver side rear of the vehicle in which the transmission is assembled; -
FIG. 33 is a diagrammatic flow chart, illustrating the steps of the method of assembling a transmission according to the present invention; -
FIG. 34 is a cross sectional side elevation view of the primary pump motor drive shaft and its associated drive gear for the transmission illustrated inFIG. 1 , illustrating a spline connection according to the present invention in a fully assembled configuration; -
FIG. 34 a is an enlarged view of a portion ofFIG. 34 , illustrating the spline connection in a first partially assembled configuration; -
FIG. 34 b is a view similar toFIG. 34 a, illustrating the spline connection in a second partially assembled configuration; -
FIG. 35 is a cross sectional view of the primary pump motor unit drive gear illustrated inFIG. 34 ; -
FIG. 36 is a cross sectional view of the primary pump motor unit drive shaft illustrated inFIG. 34 ; -
FIG. 37 is a perspective view of the primary pump motor unit drive shaft and its associated drive gear illustrated inFIG. 34 , showing these components before they are assembled together; -
FIG. 38 is another perspective view of the primary pump motor unit drive shaft and its associated drive gear illustrated inFIG. 34 , showing these components in a fully assembled configuration. - Referring now to the drawings in greater detail,
FIGS. 1-38 illustrate anobject 10 having a compacthydromechanical powersplit transmission 11 according to a preferred embodiment of the present invention and a method ofassembly 140 according to a preferred embodiment of the present invention. - Headings are provided in the description below to assist the reader. However descriptions under all headings relate to the descriptions under each individual heading, so that the complete description below is to be used to understand the description under each individual heading.
- The
object 10 can be any object that uses a transmission for transmitting energy or converting energy to rotational movement. In the preferred embodiment described below, theobject 10 is a wheeled land vehicle such as an on-highway truck. Thevehicle 10 includes aprime mover 13, which in the preferred embodiment is a conventional internal combustion engine such as a gasoline or diesel or natural gas engine, and anengine drive shaft 14. Thevehicle 10 further includesdrive wheels 15, a differential 16, and adifferential drive shaft 17. Thevehicle 10 also includes frame rails 18, which are longitudinally extending beams, which may be steel or other suitable structural material, to which the body (not shown),prime mover 13,drive shaft 14, vehicle suspension components (not shown), differential 16 and other components of thevehicle 10 are mounted in a conventional well know manner. - As best shown in
FIGS. 1 , 3, and 7, thehydromechanical powersplit transmission 11 has alongitudinal axis 22. Thetransmission 11 includes ahydraulic unit 23, a gear unit orplanetary gear unit 24 that is integral with thehydraulic unit 23, and a connectingplate 25 disposed intermediate thehydraulic unit 23 and thegear unit 24. As used herein, the term integral means two or more functionally different cooperating devices that are assembled without externally exposed fluid or mechanical connections and used as a whole such that each device is an essential part to complete the other. Thehydraulic unit 23 includes ahydraulic unit housing 26 having a vehicle primemover input end 27 and anoutput end 28. Thegear unit 24 includes a gear unit housing or planetarygear unit housing 29 having aninput end 30 and anoutput end 31. Thehousings interior surfaces plate 25 to definechambers chambers longitudinal axis 22. Various low pressure hydraulic connections through thechamber 36 are illustrated schematically inFIG. 1 with solid lines. It should be understood that these illustrated solid lines are not separate hydraulic conduits, but rather schematically illustrate hydraulic connections that occur between various components through the low pressure hydraulic fluid withinchamber 36. - The
hydraulic unit housing 26 includes a longitudinally extending prime mover input shaft ormechanical drive shaft 41 connected toengine drive shaft 14 through a suitable torsionalvibration dampening coupling 14 a. Input shaft 41 (FIGS. 1 and 7 ) extends through an input shaft opening 41 a at theinput end 27, longitudinally into and through the hydraulic unit housinginterior chamber 36. Theinput shaft 41 is rotatably connected to theprime mover 13, so that theprime mover 13 drives theinput shaft 41 and causes theinput shaft 41 to rotate when theprime mover 13 is running. The term rotatably connected means that components rotate together or are drivingly connected. A primary hydraulicpump motor unit 42 and a secondary hydraulic pump motor unit 43 (FIGS. 1 , 3 and 9) are disposed within thechamber 36 in laterally offset spaced relation to theinput shaft 41 and in circumferentially spaced relation to one another. This laterally offset relationship of theunits input shaft 41, as further described below, allows theinput shaft 41 to extend longitudinally through the hydraulic unit housinginterior chamber 36 and into connectingplate 25 without interruption. Further, as illustrated inFIGS. 4 and 8 , thepump motor units pump motor unit 43 including its barrel and pistons described below being closer to the connectingplate 25 andgear unit 24 than thepump motor unit 42, to reduce the lateral dimension of thetransmission 11. Theunits pump motor units pump motor unit 42 may be a smaller displacement unit thansecondary unit 43. For brevity, the detailed structure and operation of thepump motor units pump motor unit 42 includes abarrel 42 a andpistons 42 b, and secondarypump motor unit 43 includes abarrel 43 a andpistons 43 b. Thepump motor units transmission 11, as further described below. The primarypump motor unit 42 is drivingly connected to primary pump motor unit drive shaft 44 (FIGS. 1 and 8 ), and the secondarypump motor unit 43 is drivingly connected to secondary pump motor unit drive shaft 45 (FIGS. 1 and 9 ). Theprimary shaft 44 includes an integral annular headportion having sockets 44 a for its associatedpistons 42 a, and thepistons 42 a and associatedbarrel 42 b provide a rotating group for theprimary unit 42. Thesecondary shaft 45 includes an integral annular headportion having sockets 45 a for its associatedpistons 43 a, and thepistons 43 a and associatedbarrel 42 b provide a rotating group for thesecondary unit 43. During the pumping mode, theunits 42 and/or 43 are driven by primary pump motorunit drive shaft 44 and secondary pump motorunit drive shaft 45, respectively, to pump hydraulic fluid under pressure into a high pressure accumulator 46 (FIG. 1 ) through ahydraulic line 47 to store energy. During the motoring mode, high pressure hydraulic fluid is supplied to theunits 42 and/or 43 fromhigh pressure accumulator 46 throughhydraulic line 47 to rotate theshafts accumulator 46 to rotational movement. The primary and secondary pump motorunit drive shafts mover input shaft 41 and in circumferentially and longitudinally spaced relation relative to one another. Thehigh pressure accumulator 46 may be mounted remotely to the vehicle frame rails 18, or alternatively may be mounted directly to thetransmission 11. -
FIG. 2 is an enlarged and more detailed schematic illustration of the portion ofFIG. 1 illustrated by the dotted line box that surrounds thepump motor units FIG. 1 . As illustrated schematically inFIG. 2 and as shown and described in detail in the above referenced publication, the displacement of primarypump motor unit 42 is controlled by a displacement control mechanism including setting orcontrol pistons 48 and 49 (also seeFIG. 24 ). Similarly, the displacement of secondarypump motor unit 43 is controlled by setting orcontrol pistons 50 and 51 (also seeFIG. 24 ). The primary pump motorunit control pistons proportional control valve 52, and the secondary pump motorunit control pistons proportional control valve 53. Anisolation valve 54 is arranged to block or open fluid communication between primarypump motor unit 42high pressure outlet 91 and a high pressureisolation valve port 56 connected tohydraulic line 47 leading tohigh pressure accumulator 46. Anisolation valve 55 is arranged to block or open fluid communication between secondarypump motor unit 43 and high pressureisolation valve port 56. Theisolation valves pilot signal valves valves FIG. 10 ) that includes the highpressure fluid port 56 connected tohigh pressure line 47 leading tohigh pressure accumulator 46. Theisolation valve housing 57 further includespassages 56 a connecting the isolation valvehigh pressure port 56 with each of the isolation valves. As shown inFIG. 1 , alow pressure reservoir 53 is connected to pumpmotor units hydraulic line 59 andchamber 36. A filtration and cooling pump 60 (also seeFIG. 4 ) is driven byinput shaft 41 and circulates hydraulic fluid fromlow pressure line 59 andchamber 36 throughconnections - As best illustrated in
FIGS. 1 and 7 , acoupling 61 in the connectingplate 25 couples the primemover input shaft 41 to atransfer shaft 62, so that theinput shaft 41 andtransfer shaft 62 rotate together as a unit. Alternatively, coupling 61 may be in any other suitable location such as, for example, outside of and on either side of the connectingplate 25.Coupling 25 is integral to thetransfer shaft 62 in the preferred embodiment but may alternatively be integral to theshaft 41 or a separate component. Thetransfer shaft 62 extends longitudinally from connectingplate 25 into the planetary gear housinginterior chamber 37, so that thetransfer shaft 62 may be considered a part of and/or an extension ofinput shaft 41. The right end of thetransfer shaft 62 is rotatably journaled or supported in a bearing 62 a in a blind bore in the left end of a planetary gear unitoutput drive shaft 63 at theoutput end 31 of the planetarygear unit housing 29, so that thetransfer shaft 62 is not drivingly coupled to theoutput drive shaft 63 but instead rotates relative to theoutput drive shaft 63. Theoutput drive shaft 63 extends from the planetary gear unit housinginterior chamber 37 longitudinally through an output drive shaft opening 63 a ingear unit housing 29 and is connected to thedifferential drive shaft 17 by acoupling 64. - As illustrated schematically in
FIG. 1 and described in more detail below, the gear unit orplanetary gear unit 24 includesgear unit components 71 disposed within the gear unit housinginterior chamber 37. Thegear unit components 71 are planetary gear components, and thecomponents 71 include asun gear 72, aring gear 73, planet gears 74 and aplanet carrier 75. Theprime mover 13 is drivingly connected to theplanet carrier 75. The primarypump motor unit 42 is drivingly connected to thesun gear 72. The secondarypump motor unit 43 is drivingly connected to thering gear 73 and to thedrive wheels 15. - More specifically, as illustrated in
FIGS. 1 and 7 , theplanet carrier 75 is drivingly connected to transfershaft 62, preferably by a spline connection, so thattransfer shaft 62 andinput shaft 41 andengine drive shaft 14 andprime mover 13 are drivingly connected and rotate together. Alternatively, one or more of the several spline connections illustrated herein may be replaced with any other suitable attachment device such as, for example, a key and slot arrangement or by a single piece construction. As illustrated inFIGS. 1 and 8 , primary pump motorunit drive shaft 44 extends into planetary gear unitinterior chamber 37 and carries agear 76 through a spline connection.Gear 76drives gear 77, which drivessun gear 72 through a spline connection. As illustrated inFIGS. 1 and 9 , secondary pump motorunit drive shaft 45 is drivingly connected to ringgear 73 and tooutput shaft 63 anddifferential drive shaft 17 and differential 16 and drivewheels 15, so that these components rotate together. Specifically, secondary pump motorunit drive shaft 45 extends into planetary gear unitinterior chamber 37 and carries agear 78 through a spline connection, andgear 78 meshes withgear 79 that is connected to ringgear 73 and tooutput shaft 63. - Referring to
FIGS. 1 and 3 , the primarypump motor shaft 44 extends longitudinally from the rotatingaxial piston group pump motor unit 42 ininterior chamber 36 ofhydraulic unit 23, through the connectingplate 25, and into theinterior chamber 37 ofplanetary gear unit 24. The left end of the primary pumpmotor unit shaft 44 is supported by a taperedroller bearing 80 in the connectingplate 25 to accommodate radial and axial loads on theshaft 44, and the right end of theshaft 44 is supported by aroller bearing 81 inhousing 29 ofplanetary gear unit 24. Thegear 76 that is carried by the primary pumpmotor unit shaft 44 is disposed intermediate thebearings bearing 81. Similarly, as shown inFIGS. 1 and 9 , the secondarypump motor shaft 45 extends longitudinally from the rotatingaxial piston group pump motor unit 43 ininterior chamber 36 ofhydraulic unit 23, through the connectingplate 25, and into theinterior chamber 37 ofplanetary gear unit 24. The left end of the secondary pumpmotor unit shaft 45 is supported by a taperedroller bearing 82 in the connectingplate 25 to accommodate radial and axial loads, and the right end of theshaft 45 is supported by aroller bearing 83 in ablind bore 83 a inhousing 29 ofplanetary gear unit 24. Thegear 78 that is carried by the secondary pumpmotor unit shaft 45 is disposed intermediate thebearings bearing 83. This arrangement integrates thepump motor units shafts hydraulic unit 23 and the connectingplate 25 and theplanetary gear unit 24 to provide an integral unit. By supporting the ends of theshafts plate 25 and planetarygear unit housing 29 and with the associated gears 76 and 78, respectively, disposed on theshafts transmission 11. - Referring now to
FIGS. 1-2 and 7-9 to further describe the connectingplate 25, the connectingplate 25 is of high strength cast iron and thehydraulic housing 26 and planetarygear unit housing 29 are of lower strength and lower weight aluminum casting. The material for the connectingplate 25 andhousings plate 25 provides a major structural element of thetransmission 11, and a connectingassembly 84 includes the connectingplate 25 and the hydraulic components and gear set components that are assembled to and carried by the connectingplate 26. The connectingplate 25 has a hydraulic unit side that includes ahydraulic unit wall 25 a that provides a wall of hydraulic unit sealedchamber 36 adjacent theoutput end 28 of thehydraulic unit 23. The connectingplate 25 also has a planetary gear unit side that includes a planetarygear unit wall 25 b that provides a wall of planetary gear unit sealedchamber 37 adjacent theinput end 30 ofplanetary gear unit 24. A mechanical drive opening 85 (FIG. 7 ) extends longitudinally through the connectingplate 25 from thehydraulic side 25 a to the gear setside 25 b, and abearing 86 and seal 86 a are disposed in theopening 85. The input mechanical drive shaft 41 (including its transfer shaft 62) extends longitudinally into theopening 35 and is supported by the bearing 86 a and sealed by the seal 86 b. A primary hydraulic drive opening 87 (FIG. 8 ) extends longitudinally through the connectingplate 25 from thehydraulic side 25 a to the gear setside 25 b. Theprimary opening 87 is in laterally offset relation to theopening 85 andinput shaft 41, and the primary pump motor unit shaft bearing 80 and associatedseal 80 a are disposed in theopening 87. The primarypump motor unit 42 is secured to the connectingplate 25 on itshydraulic side 25 a and is longitudinally aligned with theopening 87. The primary pump motorunit drive shaft 44 extends longitudinally through theopening 87 and is supported by thebearing 80 and sealed by the associatedseal 80 a. A secondary hydraulic drive opening 88 (FIG. 9 ) extends longitudinally through the connectingplate 25 from thehydraulic side 25 a to the gear setside 25 b. Thesecondary opening 88 is also in laterally offset relation to theopening 84 andinput shaft 41, and the secondary pump motor unit shaft bearing 82 and associatedseal 82 a are disposed in theopening 88. The secondarypump motor unit 43 is secured to the connectingplate 25 on itshydraulic side 25 a and is longitudinally aligned with theopening 88. The secondary pump motorunit drive shaft 45 extends longitudinally through the opening 38 and is supported by thebearing 82 and sealed byseal 82 a. The connectingassembly 84 further includes the planetary gear set 71, which is mounted on the gear setside 25 b of the connectingplate 26. This configuration provides aninput drive shaft chamber 36 ofhydraulic unit 23 and through the connectingplate 25, and primary and secondarypump motor units chamber 36 and are laterally offset from thedrive shaft - The connecting
plate 25 of the connectingassembly 84 provides a hydraulic manifold and further includes fluid flow passages that include high pressurefluid flow passages pilot signal passages 90. The high pressure fluid outlet side of each hydraulicpump motor unit FIGS. 1 and 8 ), 92 (FIGS. 1 and 9 ); respectively, and theflow tubes passages plate 25 connect each of theisolation valves flow tubes isolation valves valves plate 25, and thepilot fluid passages 90 are in fluid communication with these valves. - In this manner, the connecting
plate 25 is a component of a connectingassembly 84 and provides a mounting platform for thepump motor units valves motor unit shafts transfer shaft 62 and support for thetransfer shaft 62 andinput shaft 41; provides a mounting platform for theplanetary gear components 71; provides a wall for the hydraulic unitinternal chamber 36 and for the planetary gear unitinternal chamber 37; combines thehydraulic unit 23 and theplanetary gear unit 24 into an integral unit; and provides a high pressure hydraulic manifold for the fluid connections between and among thehigh pressure accumulator 46,valves pistons motor units pressure flow tubes hydraulic unit 23, such as for example thepump motor units gear unit 24 or with a different gear unit. Similarly, the illustrated components in thegear unit 24, such as for example theplanetary gear components 71 and drive gears, may be replaced with different components and used with thehydraulic unit 23 or with a different hydraulic unit. This enables thetransmission 11 to be used in a wide variety of vehicles and applications. - As best illustrated in
FIG. 3 , the exterior surfaces 32 and 33 ofhousings transmission 11. For example, exterior surfaces 32 and 33 provide liquid filter and cooler supply and returnports sensor temperature port 32 c, auxiliary lowpressure return port 32 d, park pawlposition sensor connection 32 e, secondary pump motor unitspeed sensor connection 32 f, primary pump motor unitspeed sensor connection 32 g, primary and secondary pump motorunit displacement sensor low pressure sensor 32 j. - Once the
transmission 11 is assembled in the configuration illustrated in the drawings and described above, thetransmission 11 is installed in thevehicle 10 in the lateral space between the frame rails 18 and in the longitudinal space between the primemover drive shaft 14 and the differential drive shaft 17 (FIG. 1 ). The primemover draft shaft 14 is connected through the torsionalvibration dampening coupling 14 a to theinput shaft 41 of thetransmission 11. Thedifferential drive shaft 17 is connected to theoutput drive shaft 63 of thetransmission 11 through thecouplings shaft 64 c. The appropriate electrical connections are made between the control systems of thevehicle 10 and the electrical components of thetransmission 11, and the appropriate connections are made between the hydraulic components of the vehicle 10 (including theaccumulators 46 and 47) and thetransmission 11. In this installed configuration, the primemover drive shaft 14, hydraulic unit primemover input shaft 41, input opening 41 a,transfer shaft 62, planetary gear unitoutput drive shaft 63, output drive shaft opening 63 a, anddifferential drive shaft 17 are in axially aligned or coaxial relationship. All of the components of thehydraulic unit 23 including thepump motor units plate 25 including the hydraulic manifoldhigh pressure port 56 andpassages planetary gear unit 24 including theplanetary gear components 71 and drive gears 76, 78 and 79, are disposed laterally between the frame rails 18 and longitudinally between thedrive shafts hydromechanical powersplit transmission 11 may be installed in thevehicle 10 in place of a conventional manual or automatic or variable transmission without substantial alteration of this space or the components of thevehicle 10 that define this space. - Turning now the operation of the
transmission 11, thetransmission 11 operates in various modes under a wide variety of conditions. For example, thetransmission 11 operates in various modes in response to vehicle operator accelerator pedal input to transmit power from theprime mover 13 and/or from stored energy in thehigh pressure accumulator 46 to thedifferential drive shaft 17 to propel thevehicle 10. Further, thetransmission 11 operates in various modes in response to vehicle operator brake pedal input to capture energy from thevehicle 16 during braking of thevehicle 10 and to transmit the captured energy to the high pressureaccumulator storage device 46 for later use. Still further, thetransmission 11 operates in response to vehicle operator input to start theprime mover 13 using stored energy in theaccumulator storage device 46 when thevehicle 10 is stationary. - To select among a virtually infinite array of the above described operating modes of the
transmission 11, the displacement and pump or motor operating mode ofpump motor units isolation valves secondary unit 43 is to be used in a pumping mode during braking to charge theaccumulator 46, an input provided to thepilot valve 55 a may allow theisolation valve 55 to close. In this mode of operation, theisolation valve 55 for the secondarypump motor unit 43 may act as a check valve, so that theisolation valve 55 opens when pressure in theoutlet tube 92 exceeds the pressure in thehigh pressure accumulator 46 to allow pressure fromunit 43 to chargeaccumulator 46. Theisolation valve 54 for the primarypump motor unit 42 may be generally opened when thevehicle 10 is moving, except closed when thesecondary unit 43 is pumping during braking to prevent supply of fluid from thesecondary unit 43 to theprimary unit 42. - When the
vehicle 10 is stationary, theisolation valve 54 for theprimary unit 42 may be closed, to prevent unintended flow to thesecondary unit 43 and unintended movement of thevehicle 10. Thetransmission 11 may also be used to start theengine 13, to eliminate the need for a conventional starter. For this mode, hydraulic fluid fromaccumulator 46 is supplied to primarypump motor unit 42 and isolated from secondarypump motor unit 43, so thatunit 43 and itsdrive shaft 44 rotate to rotategears planet carrier 75 andtransfer shaft 62 andinput shaft 41 and driveshaft 14 to rotate and start prime mover engine 13 (FIG. 1 ). - Further, the
proportional control valves units vehicle 10 is initially started from a stopped position, fluid is supplied fromaccumulator 46 tosecondary unit 43 and displacement ofunit 43 is gradually increased to acceleratevehicle 10. As speed of thevehicle 10 increases and displacement ofunit 43 increases, fluid pressure fromaccumulator 46 decreases and less stored energy is available tounit 43 to continue to drivevehicle 10. As the speed of the vehicle further increases, more power is transmitted mechanically directly from theengine 13 to driveshaft 17 through theplanetary gearset 71, while less power is transmitted by the hydraulic pump motor units. By reducing the hydraulic power transmitted at higher vehicle speeds, the overall transmission efficiency is increased. Additionally, the displacements ofpump motors prime mover 13 to be operated at its most efficient operating speed regardless of output shaft speed. Additionally, since there is no gear shifting, there is no interruption in power. Under this condition, displacement ofunits units vehicle 10 is to brake,secondary unit 43 is operated in a pumping mode and displacement ofunit 43 is increased to pump more fluid intoaccumulator 46 and cause further braking resistance to thedrive wheels 15 until the desired slower speed or stopped condition for thevehicle 10 is achieved. During operation of thetransmission 11, the sealedhydraulic unit chamber 36 is maintained at a positive pressure of at least about 2 bar and preferably in the range of about 2 bar to about 6 bar, to prevent cavitation in thepump motor units 42 and/or 43 during pumping, while the sealedgear unit chamber 37 is maintained at about atmospheric pressure. Because thepump motor units chamber 36 which is the low pressure reservoir, separate low pressure conduits and connections between the low pressure reservoir and thepump motor units - In this manner, the
transmission 11 provides a hydromechanical powersplit transmission that captures and stores energy as high pressure fluid inaccumulator 46 during vehicle braking and that uses that stored energy to propel thevehicle 10 or to startengine 13. Further, when thevehicle 10 is to be propelled when stored energy inaccumulator 46 is depleted, a direct variable speed mechanical connection is provided fromengine 14, throughhydraulic unit 23 but without pumping or motoring displacement of theunits drive wheels 15. - Referring now to FIGS. 1 and 7-9, the planetary
gear unit housing 29 includes a frontgear unit housing 29 a and a reargear unit housing 29 b. The sealed interior chamber orsump 37 of theplanetary gear unit 24 includes a front chamber orfront sump 37 a and a rear chamber orrear sump 37 b. The primary hydraulic pump motorunit drive shaft 44 extends from thehydraulic side 25 a, through the connectingplate 25, to thefront chamber 37 a, where its associatedgear 76 is drivingly connected to thesun gear 72 through gear 77 (FIGS. 1 and 8 ). Theplanetary gear components 71, includingsun gear 72,ring gear 73, planet gears 74 andplanet carrier 75 and thegear 76 provide a first gear set all disposed within front chamber orsump 37 a. The mechanical or primemover input shaft 41 with itstransfer shaft 62 extends from thehydraulic side 25 a, through the connectingplate 25, to thefront sump 37 a, where the transfer shaft is drivingly connected to the planet carrier 75 (FIGS. 1 and 7 ). The secondary hydraulic pump motorunit drive shaft 45 extends from thehydraulic side 25 a, through the connectingplate 25, through thefront sump 37 a, to therear sump 37 b. In therear sump 37 b, thegear 78 is secured on the secondary pump motorunit drive shaft 45 and is drivingly connected to gear 79 (FIGS. 1 and 9 ).Gear 79 in turn is connected tooutput drive shaft 63 inrear chamber 37 b and to ringgear 73.Gears rear sump 37 b. - Gear unit
front housing 29 a includes a longitudinally extending housing portion orwall 93 and a laterally extending generally planar housing portion orwall 94.Housing portion 94 provides a wall that separatessumps sump wall 94, and abearing 96 in opening 95 supportsoutput drive shaft 63. Gear unitrear housing 29 b includes a longitudinally extending housing portion orwall 97 and a laterally extending generally planar housing portion orwall 98. The output drive shaft opening 63 a extends longitudinally through housing portion orwail 98, and abearing 100 in opening 63 a supportsoutput drive shaft 63. - When the
motor vehicle 10 is not moving, theoutput shaft 63 and gears 79 and 78 and secondary pump motorunit drive shaft 45 are in a stationary condition and are not rotating, in this condition, the fluid level in the chambers orsumps dotted line 101 a inFIGS. 7-9 , which is above secondary pumpmotor unit gear 78 and belowplanetary gear components 71. The fluid inplanetary gear housing 29 withinsumps planetary gear unit 24 is sealed from the interior chamber orsump 36 ofhydraulic unit 23, the fluid insump 37 ofplanetary gear housing 29 can be a different fluid than insump 36 ofhydraulic unit housing 26 and can be at a different fluid pressure level. Further, as discussed in greater detail below, while the fluid level within thehydraulic unit housing 26 is substantially at the top ofhydraulic unit sump 36 atlevel 101 b (FIG. 8 ) to permitsump 36 to provide a hydraulic fluid reservoir and to permit exchange and flow of hydraulic fluid from a motoring one ofpump motor units gear unit sump 37 is at a different and lower level to avoid heat build-up that would occur if the fluid levels were the same and theplanetary gear components 71 and gears in the planetarygear unit housing 37 were submerged in lubricating fluid. - Referring now to
FIGS. 11 and 12 , a rear facing generallyplanar surface 94 a of the frontplanetary gear housing 29 a is illustrated inFIG. 11 and a mating front facing generallyplanar surface 97 a of rearplanetary gear housing 29 b is illustrated inFIG. 12 . For clarity, thehousings FIGS. 11 and 12 without any other components. A restricted size return opening orfluid passage 102 extends longitudinally throughwall 94 at a location vertically belowlevel 101 a to connectsumps fluid passage 103 extends longitudinally throughwall 94 at a location vertically abovelevel 101 a to connectsumps surface 98 a includes a generally U-shaped longitudinally recessedpump channel 104. Whenhousings FIGS. 7-9 , therear facing surface 94 a ofhousing 29 a engages thefront facing surface 97 a ofhousing 29 b. In this assembled configuration, surface 97 a provides a wall to closepump channel 104, andclosed pump channel 104 extends between and establishes fluid communication betweenopenings front housing 29 a also includes anopening 118 a that may be used for mounting a speed sensor (not shown) for primarypump motor unit 42, and therear housing 29 b also includes anopening 118 b that may be used for mounting a speed sensor (not shown) for secondarypump motor unit 43. Anoil fill hole 118 c is provided in therear housing 29 b to fill thesumps - As illustrated in
FIG. 17 , rotation ofgear 78 near the bottom of chamber orsump 37 b causesgear 78 to throw or pump fluid from return opening 102 (FIG. 11 ) near the bottom of chamber orsump 37 b upward through channel 104 (FIG. 12 ) to pumppassage 103.Passage 103 connects rear chamber orsump 37 b to front chamber orsump 37 a on the front side ofhousing 29 b. This oil fromchannel 104 flowing throughpassage 103 will then fall onto theprimary gear 76 infront sump 37 a to increase oil splash lubrication infront sump 37 a. Fluid flows faster fromrear sump 37 b tofront sump 37 a throughpassage 103 than it can return fromfront sump 37 a torear sump 37 b throughpassage 102, and this results in the fluid level insump 37 b being substantially at the level of the bottom ofgear 78 when thegear 78 is rotating. This prevents thegear 78 from rotating at high speeds or for long periods of time submerged in oil, and prevents heat build-up that would otherwise occur if thegear 78 were to run submerged in oil. When thevehicle 10 is moving, theoutput shaft 63 and gears 79 and 78 and secondary pump motorunit drive shaft 45 are rotating and this pumping fromsump 37 b tosump 37 a throughchannel 104 occurs. When thevehicle 10 stops moving and thegear 78 stops rotating, fluid returns fromfront sump 37 a torear sump 37 b throughpassage 102 and the fluid level insumps - As illustrated in
FIGS. 12 and 17 ,surface 98 a ofrear housing portion 29 b also includes longitudinally extendingledges gear 78 rotates,gear 78 also splashes lubricating oil ontoledges ledge 105 flows intofront sump 37 a throughopening 105 a (FIG. 11 ) and onto rear primary bearing 81 (FIG. 8 ). Oil onledge 106 is directed to thepark pawl assembly 120 described below through a vertical hole at the right end ofledge 105 as viewed inFIG. 12 . Accordingly, lubricating oil fromrear sump 37 b is pumped tofront sump 37 a to reduce the fluid level inrear sump 37 b, and lubricating oil in therear sump 37 b is distributed to the moving components and bearings within thesumps secondary gear 78 and the openings and channels and ledges described above, to eliminate the need for a conventional lubrication pump and to minimize the size and weight and complexity of thetransmission 11. - As illustrated in
FIGS. 9 and 11 , thefront housing 29 a of thegear unit 24 also includes a secondary pumpmotor shaft opening 108, and the secondarypump motor shaft 45 extends throughopening 108. As illustrated inFIGS. 8 , 11 and 12, thehousing 29 a also includes a low pressurereturn line opening 109, and thehousing 29 b includes a low pressurereturn line opening 110. Theopening 110 is used to optionally connect a low pressure accumulator tochamber 36 and is not used in the preferred embodiment illustrated in the drawings. A lowpressure return tube 111 extends through and is sealed withinopenings sump 36 throughsump opening 110. - Accordingly, the
walls first housing 29 a define the front orfirst sump 37 a. The rear orsecond housing 29 b is connected to thefirst housing 29 a and includeswalls common wall 94 of thefirst housing 29 a to define the rear orsecond sump 37 b. A first set of rotatable gears 71 is disposed in thefirst sump 37 a and has a stationary condition and a rotating condition. A second set of rotatable gears 78, 79 is disposed in thesecond sump 37 b and has a stationary condition and a rotating condition. Aninput drive shaft 62 extends longitudinally into thefirst sump 37 a and is rotatably connected to the first set of rotatable gears. Anoutput drive shaft 63 extends longitudinally out of thesecond sump 37 b and is rotatably connected to the second set of gears. Thelongitudinal axes 22 of the input and output drive shafts are substantially coaxial. A first hydraulic pump motorunit drive shaft 44 extends into thefirst sump 37 a and is driving connected with the first set of rotatable gears. A second hydraulic pump motorunit drive shaft 45 extends longitudinally from end to end through thefirst sump 37 a and into thesecond sump 37 b and is drivingly connected with the second set of rotatable gears. The first and second hydraulic pump motor unit drive shafts are supported by bearings in wails 25, 94 and 98.Openings first sump 37 a and thesecond sump 37 b, and theopenings channel 104 to pump lubricating liquid from thesecond sump 37 b to thefirst sump 37 a when the second set of gears is rotating. - Turning now to FIGS. 14 and 22-33, various steps in a
method 140 of assembling and disassembling and repairing a transmission according to the present invention and various subassemblies or assemblies according to the present invention are illustrated. Themethod 140 and the assemblies provide ahydromechanical powersplit transmission 11 illustrated in the other Figures and described elsewhere in this description. Themethod 140 may be practiced in the step by step order described below, in a different order, or in a reverse order, and the steps may be combined or broken into sub-steps, to assemble and disassemble (in which case the term assemble will be understand to mean disassemble) and repair according to the present invention. - The method of
assembly 140 includesstep 140 a illustrated inFIGS. 22 and 33 , which results in a connectingplate assembly 150 a illustrated inFIG. 23 . Themethod step 140 a includes providing a combination connecting andfluid manifold plate 25 as described above, a highpressure flow tube 91 for the primarypump motor unit 42 described above, and an identical highpressure flow tube 92 for the secondarypump motor unit 43 described above. Theflow tubes FIGS. 8 and 9 ). Once theflow tubes step 140 a, theassembly 150 a of the connectingplate 25 and theflow tubes FIG. 23 . - The method of
assembly 140 further includesstep 140 b illustrated inFIGS. 23 and 33 , which results in a connectingplate assembly 150 b illustrated inFIG. 24 . Themethod step 140 b includes providing the connectingplate 25 and connectingplate assembly 150 a, the primary pumpmotor unit shaft 44, the secondarypump motor shaft 45, and thebearings primary bearing 80 andprimary shaft 44 are assembled longitudinally intoprimary opening 87, and thesecondary bearing 81 andsecondary shaft 45 are assembled longitudinally intosecondary opening 88. Once the components are assembled in this manner atstep 140 b, theassembly 150 b of the connectingplate 25 and the primary shaft 44 (withpiston sockets 44 a) and secondary 45 (withpiston sockets 45 a) is provided as illustrated inFIG. 24 . - The method of
assembly 140 further includesstep 140 c illustrated inFIGS. 24 and 33 , which results in a connectingplate assembly 150 c illustrated inFIG. 25 . Themethod step 140 c includes providing the connectingplate 25 and connectingplate assembly 150 b, the primary pump motor unit rotatinggroup pistons 42 a andbarrel 42 b, the secondary pump motor unit rotatinggroup pistons 42 a andbarrel 42 b, and the setting or control pistons 48-52. The primary pump motor unit rotatinggroup pistons 42 a andbarrel 42 b, the secondary pump motor unit rotatinggroup pistons 42 a andbarrel 42 b, and the setting or control pistons 48-52 are assembled longitudinally onto the connectingplate 25 and connectingplate assembly 150 b. Once the components are assembled in this manner atstep 140 c, theassembly 150 c of the connectingplate 25 and these components is provided as illustrated inFIG. 25 . - The method of
assembly 140 further includesstep 140 d illustrated inFIGS. 26 and 33 , which results in a connectingplate assembly 150 d illustrated inFIG. 27 . Themethod step 140 d includes providing the connectingplate 25 and connectingplate assembly 150 c and thehydraulic housing 26. Thehousing 26 is assembled longitudinally onto the connectingplate 26 and connectingplate assembly 150 c, encapsulating the hydraulicpump motor units rotating groups flow tubes step 140 d includes sealinghousing 26 against thehydraulic side 25 a of connectingplate 25 to provide the sealed chamber orsump 36.Assembly bolts 151 pass longitudinally through aligned holes in connectingplate 25 andhousing 26, and nuts (not shown) are fastened to the ends ofbolts 151 to securehousing 26 to connectingplate 26. Thebolts 151 provide temporary fastening of the connectingplate 25 andhousing 26 during assembly of thegear unit 24 during subsequent steps of themethod 140. Once the components are assembled in this manner, theinput shaft 41 is assembled longitudinally into thehousing 26 and into theinput shaft opening 35 in connecting plate 25 (seeFIGS. 3 and 7 ) to completestep 140 d and provide theassembly 150 d of the connectingplate 25 and these components is provided as illustrated inFIG. 27 . - The method of
assembly 140 further includesstep 140 e illustrated inFIGS. 27 and 33 , which results in a connectingplate assembly 150 e illustrated inFIG. 28 . Themethod step 140 e includes providing the connectingplate 25 and connectingplate assembly 150 d and thetransfer shaft 62 and associatedbearing 86 and associatedtransfer shaft retainer 62 a. Thetransfer shaft 62 andbearing 86 andretainer 62 a are assembled longitudinally onto the connectingplate 25 and connectingplate assembly 150 d, and bolts 62 b secure theretainer 62 a in place. At this step, thevalves plate 25. Once the components are assembled in this manner atstep 140 e, theassembly 150 e of the connectingplate 25 and these components is provided as illustrated inFIG. 28 . - The method of
assembly 140 further includesstep 140 f illustrated inFIGS. 28 and 33 , which results in a connectingplate assembly 150 f illustrated inFIG. 29 . Themethod step 140 f includes providing the connectingplate 25 and connectingplate assembly 150 e and primary pump motorunit drive gear 76 and one pieceintegral gear 77 andsun gear 72. Thegear 76 is assembled longitudinally ontoprimary shaft 44, and theintegral gear 77 andsun gear 72 is assembled longitudinally ontotransfer shaft 62. Once the components are assembled in this manner atstep 140 f, theassembly 150 f of the connectingplate 25 and these components is provided as illustrated inFIG. 29 . - The method of
assembly 140 further includes step 140 g illustrated inFIGS. 29 and 33 , which results in a connectingplate assembly 150 g illustrated inFIG. 30 . Themethod step 140 g includes providing the connectingplate 25 and connectingplate assembly 150 f andplanetary components 71, including planet gears 74,planet carrier 75 andring gear 73, and associatedsplash gear 112. The planet gears 74 andplanet carrier 75 andring gear 73 are assembled longitudinally onto thesun gear 72 and connectingplate 25. At this step, the lowpressure return tube 111 may also be assembled in the low pressure return opening 108 of connectingplate 25 Once the components are assembled in this manner atstep 140 g, theassembly 150 g of the connectingplate 26 and these components is provided as illustrated inFIG. 30 . - The method of
assembly 140 further includesstep 140 h illustrated inFIGS. 30 and 33 , which results in a connectingplate assembly 150 h illustrated inFIG. 31 . Themethod step 140 b includes providing the connectingplate 25 and connectingplate assembly 150 g, frontplanetary gear housing 29 a, andbearing 96. The frontplanetary gear housing 29 a is assembled longitudinally onto the connectingplate 25, encapsulating the gear set 71, 72, 73. Thestep 140 h includes assembling the pumpmotor unit shaft 44 into bearing 81 Thestep 140 h also includes sealinghousing 29 a against theplanetary gear side 25 b of connectingplate 25 to provide the sealed chamber orsump 37 a. Thebearing 96 is assembled into opening 95 inhousing 29 a.Assembly bolts 152 pass longitudinally through aligned holes in frontplanetary gear housing 29 a, connectingplate 25 andhousing 26, and nuts (not shown) are threaded to the ends ofbolts 152 to securehousings plate 25. Once thebolts 152 are assembled and tightened, thebolts 151 are no longer needed. However, thebolts 151 are left in place and are prevented from falling out by thehousing 29 a covering thebolts 151. Once the components are assembled in this manner atstep 140 h, the assembly 160 h of the connectingplate 25 and these components is provided as illustrated inFIG. 31 . - The method of
assembly 140 further includesstep 140 i illustrated inFIGS. 31 and 33 , which results in a connectingplate assembly 150 i illustrated inFIG. 31 . Themethod step 140 i includes providing the connectingplate 25 and connectingplate assembly 150 h,output drive shaft 63, bearing 63 a,gear 79,park pawl hub 121, and secondary pump motorunit drive gear 78. Theoutput drive shaft 63 and bearing 63 a are assembled longitudinally into drive shaft opening 95 in aligned relationship withtransfer shaft 62, and gears 79 and 121 are longitudinally assembled ontooutput drive shaft 63. Secondary pump motorunit drive gear 78 is longitudinally assembled onto secondary pump motorunit drive shaft 45. Once the components are assembled in this manner atstep 140 i, theassembly 150 i of the connectingplate 25 and these components is provided as illustrated inFIG. 32 . - The method of
assembly 140 further includesstep 140 j illustrated inFIGS. 32 and 33 , which results in the completedtransmission 11 illustrated inFIGS. 1-3 . Themethod step 140 j includes providing the connectingplate 25 and connectingplate assembly 150 i, rearplanetary gear housing 29 b, andcoupling 64. The rearplanetary gear housing 29 b is assembled longitudinally onto the frontplanetary gear housing 29 a and connectingplate 25, encapsulating gear set 78, 79, 121. Thestep 140 j includes assembling the pumpmotor unit shaft 45 intobearing 83. Themethod step 140 j also includes sealing the rearplanetary gear housing 29 b against the frontplanetary gear housing 29 a to provide the sealed chamber orsump 37 b (FIG. 7 ) and to provide the channel 102 (FIGS. 12 and 17 ).Assembly bolts 153 pass longitudinally through aligned holes in rearplanetary gear housing 29 b and are threaded into aligned threaded holes in the frontplanetary gear housing 29 a. Thebolts 153 and this step secure thehydraulic unit housing 26 and the frontgear unit housing 29 a and the reargear unit housing 29 b and theconnector plate 25 together. The temporary bolts used instep 140 d remain in place duringstep 140 h and hold thehydraulic unit housing 26 and connectingplate 25 together and in place to receive thebolts 153. Thecoupling 64 is then longitudinally assembled ontooutput drive shaft 63. Once the components are assembled in this manner atstep 140 j, the assembly of thetransmission 11 is complete. - Using the
method 140 of assembly according to the present invention, ahydraulic unit 23 and aplanetary gear unit 24 are assembled using a central connectingplate 25. The hydraulic components are assembled on thehydraulic side 25 a of the connectingplate 25, and ahydraulic unit housing 26 is assembled over the hydraulic components and in sealing engagement with thehydraulic side 25 a to provide a sealedchamber 36 that is pressurized during operation of thetransmission 11. The planetary gear components are assembled on theplanetary gear side 25 b of the connectingplate 25, andplanetary gear housings chambers chamber 36. After assembly of thetransmission 11, thetransmission 11 is assembled onto thevehicle 10 in the position described above. - If it becomes necessary to repair the
transmission 11, thetransmission 11 is removed from thevehicle 10. For repairs to theplanetary gear unit 24, the planetarygear unit housings 29 b and, if necessary, 29 a, are removed to access the planetary gear unit components as illustrated inFIG. 5 . Since all planetary gear unit components are assembled onto the connectingplate 25 from the planetarygear unit side 25 b of the connectingplate 25, all planetary gear unit components may be removed and repaired or replaced without opening thehydraulic unit 23. For repairs to thehydraulic unit 23, thehydraulic unit housing 26 is removed to access the hydraulic unit components as illustrated inFIG. 4 . - Referring now to FIGS. 7 and 13-17, additional structure and features of the planetary gear set 71,
planet carrier 75, planet gears 74 and lubrication system for the moving components within thefront sump 37 a are illustrated, withFIG. 14 illustrating some of the structure in exploded format for clarity. The illustrated lubrication system is integral with theplanet carrier 75 and planet gears 74, and eliminates the need for a piston pump or gerotor pump or similar pump having higher energy consuming pumping parts to provide lubricating liquid under pressure to the moving components of the planetary gear set 71 and other moving components within thefront sump 37 a. To achieve this, the invention provides a thin generally flatlateral splash gear 112 that is integral with the planetary gear set 71 and is carried by and rotates withplanet carrier 75 about alongitudinal axis 71 a in thesump 37 a. Thesplash gear 112 includes laterally outwardly extendingteeth 112 a, a central generallycircular opening 112 b, and three spaced apartnotches 112 c extending laterally outwardly from theopening 112 b. Thenotches 112 c each extend circumferentially through an angle of less than about 10 degrees and preferably less than about 5 degrees. Theplanet carrier 75 includes threeplanet gear shafts 113, and the threeplanet gears 74 are each rotatably disposed on a bearing 74 a on one of theshafts 113. Theplanet gear shafts 113 are each received in a planet shaft bore 114 that extends longitudinally into theplanet carrier 75 and are stationary relative to theplanet carrier 75. Each of theplanet gear shafts 113 includes a laterally extendingcross bore 113 a, and laterally extendingpins 115 extend into theplanet carrier 75 and through the planet shaft cross bores 113 a to retain eachplanet gear shaft 113 and its associatedplanet gear 74 in place on theplanet carrier 75. Eachplanet gear shaft 113 further includes a radially outwardly facinglock groove 113 b on its generally cylindrical outerperipheral surface 113 g to retain thesplash gear 112 on theplanet carrier 75 in the manner further described below. - To assemble the
splash gear 112 onto theplanet carrier 75, thesplash gear 112 is assembled in the longitudinal direction onto the radially outerperipheral surface 75 a of a circumferentially extending longitudinally projectingannular lip 75 b on a lateral end face orlateral wall 75 c ofplanet carrier 75. Thenotches 112 c of thesplash gear 112 are aligned with theshafts 113 so that theshafts 113 project longitudinally through thenotches 112 c, and this position of thesplash gear 112 is a partially assembled position. Thesplash gear 112 is then rotated about 5 to 10 degrees (clockwise as viewed inFIG. 14 ), so that thenotches 112 c rotate a few degrees away from theshafts 113. This causes the inner peripheral surface orcentral opening 112 b of thesplash gear 112 to move into thelock grooves 113 b in theshafts 113. In this fully assembled position or configuration, thesplash gear 112 is held onto theplanet carrier 75 for rotation with theplanet carrier 75, by thesplash gear 112 engaging thelock grooves 113 b of theplanet gear shafts 113. Alock pin 116 is then pressed through ahole 112 d insplash gear 112 and into ahole 75 d inplanet carrier 75, to hold thesplash gear 112 against continued clockwise or counterclockwise rotation relative to theplanet carrier 75. - The
planet carrier 75 further includes a longitudinally extendingcentral opening 75 e. Thecentral opening 75 e includes aninternal spline connector 75 f. When theplanet carrier 75 is assembled onto the transfer drive shaft 62 (FIGS. 1 and 7 ), an external spline connector on thetransfer shaft 62 mates to theinternal spline connector 75 f of theplanet carrier 75. With this structure, theplanet carrier 75 andsplash gear 112 are rotatably connected to thetransfer shaft 62 and theinput shaft 41, so that these components rotate together under all operating conditions. - Each
planet gear shaft 113 also includes a central bore or lubricatingliquid flow passage 113 c. Eachflow passage 113 c extends into theshaft 113 from thelateral wall 75 c in the longitudinal direction to the left as viewed in the drawings. A lateral cross bore orradial passage 113 d (FIG. 16 ) extends radially from thecentral bore 113 c to the outerperipheral surface 113 g of eachplanet gear shaft 113 to provide lubricating liquid between eachplanet gear shaft 113 and an associated planet gear shaft bore 114 of theplanet gear 74 and bearing 74 a that is disposed on theshaft 113. Theradial passage 113 d extends radially outward from thecentral bore 113 c in a direction away from thelongitudinal axis 71 a. Eachplanet gear shaft 113 also includes a out awaybevel portion 113 e at or near its end, adjacent theannular lip 75 b of theplanet carrier 75. Thebevel portion 113 e extends radially from the outerperipheral surface 113 g of theshaft 113 and terminates at a longitudinally extending laterally inwardly facingwail 113 f that is substantially adjacent to and communicates with thecentral flow passage 113 c. As discussed more fully below, thewall 113 f is radially outward from and substantially adjacent to theflow passages 113 c and provides a planet gear shaft lubricating liquid catch wail that catches lubricating liquid and directs the lubricating liquid to theflow passage 113 c. A further portion of the lubricating system in the chamber orsump 37 a is provided by a sheet metal baffle or trough 117 (FIGS. 13 and 7 ). Thebaffle 117 includes a laterally extendingwail 117 a andtabs 117 b, and thetabs 117 b fasten thetrough 117 toplanetary gear side 25 b of connectingplate 25. - When the
planet carrier 74 and lateral wall 74 c are in a rotating condition aboutlongitudinal axis 71 a within the front sump 36 a, thesplash gear 112 rotates with theplanet carrier 74 and lateral wall 74 c aboutaxis 71 a. Theteeth 112 a of thesplash gear 112 rotate into and out of the lubricating oil in the lower portion of thefront sump 37 a below thefluid level 101 a. This splashes lubricating liquid within thefront sump 37 a and creates a lubricating liquid suspension or droplets within the upper portion of thesump 37 a above the lubricatingliquid level 101 a. Some of this splashed lubricating liquid enters the space between thetrough wall 117 b and the connectingplate gear side 25 b, and this oil flows by gravity to lubricatebearing 86. Some of the splashed lubricating liquid engages and accumulates on the rotatinglateral wall 75 c of theplanet carrier 75 to at least partially coat thelateral wall 75 c with lubricating oil. When this liquid is deposited in this manner on thelateral wall 75 c, the liquid begins to rotate with thelateral wall 75 c. The lubricating liquid immediately adjacent thewall 75 c will rotate substantially at the same rotational velocity as thewall 75 c, and the liquid farther away from thewall 75 c will rotate at a slightly lesser rotational velocity than thewall 75 c. - As this lubricating liquid on the
lateral wall 75 c rotates with thelateral wall 75 c, the liquid is acted upon by centrifugal force and moved by centrifugal force laterally or radially outwardly against an annular radially inwardly facingcatch wall 75 g of thelip 75 b. Thecatch wall 75 g is substantially adjacent eachflow passage 113 c and is at least partially radially outward from eachflow passage 113 c. The lubricating liquid begins to accumulate at or flood thecatch wall 75 g, and the thickness or depth of the lubricating liquid increases at the location of thecatch wall 75 g. Due to the centrifugal force acting on the lubricating liquid, coupled with the relative rotational movement between thelateral wail 75 c and the liquid and between thecatch wall 75 g and the liquid, the accumulating lubricating liquid flows circumferentially along therotating catch wall 75 g. This flow will be in a direction opposite the direction of rotation of thelateral wall 75 c and catchwall 75 g and toward and along the inwardly facingcatch wall 113 f of each associatedplanet gear shaft 113. A portion of this accumulating liquid then flows longitudinally through thepassages 113 c and then radially through thepassages 113 d to lubricate outerperipheral surfaces 113 g ofplanet gear shafts 113 andbearings 74 a and planet gears 74. To facilitate this flow of oil, inwardly facingcatch wall 113 f of eachplanet gear shaft 113 is generally laterally and circumferentially aligned with the inwardly facing catch wail 75 g so that thesurfaces catch wall 75 g extends longitudinally from thelateral wall 75 c in the opposite direction to theflow passages 113 c (that is, to the right as viewed in the drawings). As theplanet carrier 75 rotates aboutaxis 71 a, centrifugal force acting on eachplanet gear 74 urges eachplanet gear 74 radially outward away fromaxis 71 a. This unloads thebearings 74 a at the location of thepassages 113 d, to facilitate flow of lubricating liquid from thepassages 113 d to thebearings 74 a and to prevent theholes 113 d from damaging thebearings 74 a. - The
annular catch wall 75 g includescatch wall portions 75 h adjacent each of theflow passages 113 c, extending circumferentially in the direction of rotation of thelateral wall 75 c and catchwail 75 g. Lubricating liquid accumulating on each of thesecatch wall portions 75 h will flow to anadjacent flow passage 113 g, while lubricating liquid accumulating on thecatch wall 75 g on the other side of aflow passage 113 g will flow to thenext flow passage 113 g or will flood over thecatch wall 75 g and contribute to the splash lubricating suspension or droplets. Each of thecatch wall portions 75 h has a sufficient circumferential extent to catch lubricating oil to feed itsadjacent flow passage 113 c. In the preferred embodiment, this circumferential extent is at least about 10 degrees. Also, in the preferred embodiment, thecatch wail portions 75 h are each generally semicircular and are joined to form the continuousannular catch wall 75 g. As used herein, the term circumferential extending in relation to thecatch wall portions 75 h describes both curved surfaces and straight surfaces, so that, for example, thecatch wall portions 75 h could alternatively be straight wall portions. Also, while thecatch wall portions 75 h in the preferred embodiment are joined together to provide thecontinuous catch wall 75 g, thecatch wall portions 75 h could alternatively be separated from one another. Further, thecatch wail 75 g and itscatch wall portions 75 h may extend perpendicular to thelateral wall 75 c (in which case they extend only in the longitudinal direction) or at another angle relative to thelateral wall 75 c (in which case they would extend in both the longitudinal and the lateral or radial direction). Also, thelateral wall 75 c may be disposed in a plane that is perpendicular to thelongitudinal axis 71 a (in which case it extends only in the lateral direction) or in a plane at another angle relative to thelongitudinal axis 71 a (in which case it would extend in both the lateral and the longitudinal direction). - In this manner, lubricating oil from
rear sump 37 b is pumped throughchannel 104 tofront sump 37 a to reduce the fluid level inrear sump 37 b, and lubricating oil in the front sump orchamber 37 a is distributed to the moving components and bearings within thechamber 37 a. This distribution is accomplished using thesplash gear 112 and theplanet carrier 75 and lateral wall 74 c and catchwalls passages planet gear shafts 113, to eliminate a need for a conventional lubrication pump and to minimize the size and weight and complexity of thetransmission 11. The lubricating system could alternatively secure a rotating splash gear and rotating lateral wall with catch walls to a different rotating planetary gear set component, such as for example a rotating ring gear, or could alternatively be used with other types of gear sets or in other applications. - Referring now to FIGS. 1 and 17-21, the
transmission 11 further includes apark pawl assembly 120. Thepark pawl assembly 120 locks the output drive shaft 63 (and thegears vehicle 10 such as when thevehicle 10 is parked. This is accomplished by thepark pawl assembly 120 locking thedrive shaft 63 to the stationary rearplanetary housing 29. As described more fully below, thepark pawl assembly 120 is moveable between an engaged or locked position illustrated inFIGS. 17 , 18 and 20, and a disengaged or unlocked position illustrated inFIGS. 19 and 21 . Thepark pawl assembly 120 permits use of a relatively small assembly arranged in thesump 37, to accommodate relatively large forces required to lock the transmission and drive wheels of relatively large weight vehicles and to transmit those relatively large forces to thehousing 29 without over stressing thepark pawl assembly 120 or thehousing 29. - The
park pawl assembly 120 includes a park hub 121 (FIGS. 1 and 17 ) disposed in the rear interior chamber orsump 37 b between the frontplanetary gear housing 29 a and thelateral surface 98 a of the rearplanetary gear housing 29 b. Thehub 121 is secured to the output drive shall 63 by a spline connection. Apawl 122 is disposed on apawl shaft 123 for rotational movement about the longitudinal axis or pivot axis of theshaft 123 between the locked position illustrated inFIGS. 17 , 13 and 20 and the unlocked position illustrated inFIGS. 19 and 21 . Thehub 121 andpawl 122 are each preferably of a suitable steel material that is case hardened, for example by carburizing, to a suitable hardness, for example about Rockwell C60. Thepawl shaft 123 and its pivot axis, referred to as the park pawl pivot axis, extend longitudinally parallel to theoutput drive shaft 63. Thepawl shaft 123 is secured tohousings shaft 123 being received in abore 123 a inhousing 29 a and in abore 123 b inhousing 29 b (FIGS. 11 and 12 ). Thepawl 122 is generally flat or planar in the lateral direction and includes apawl arm 124, apawl locking finger 125 and a pawl actuating finger orpawl locking surface 126 laterally opposite thepawl locking finger 125. Thepawl 122, including the lockingfinger 124 and the lockingsurface 126, are moved along a park pawl path between locked and unlocked positions by apark pawl actuator 127. The park pawl path is a rotational path about the park pawl pivot axis. Thepark pawl actuator 127 is a generally cylindrical plunger. A cam face orcam surface 128 is provided on the outer peripheral cylindrical surface of one side of theactuator 127 to engage the parkpawl locking surface 126, and the remainder of theactuator 127 retains its cylindrical shape. Thepark pawl actuator 127 slides in a substantially straight line park pawl actuator path along thelongitudinal axis 127 a of theactuator 127 within a generallycylindrical bushing 129, which is fit into a bore inhousing 29 b and retained within the bore by a threaded cap or plug 130. The bore is preferably generally cylindrical. The substantially straight line path of thepark pawl actuator 127 is substantially perpendicular to the pivot axis of thepark pawl 122 and is perpendicular to the direction of movement of the parkpawl locking finger 125 and lockingsurface 126 as the lockingfinger 125 and lockingsurface 126 move between their locked and unlocked positions. - As shown in
FIGS. 18 and 19 , thecylindrical bushing 129 has an axial extent that is longer than the axial extent of thepark pawl actuator 127. This permits thepark pawl actuator 127 to slide within thebushing 129 during the entire travel of thepark pawl actuator 127 between its locked position (FIG. 18 ) and its unlocked position (FIG. 19 ). Also, the portion of thecylindrical bushing 129 circumferentially aligned with thecam surface 128 of thepark pawl actuator 127 is cut away, to allow thepawl actuating finger 126 to extend through the cut away portion of thebushing 129 and engage thecam surface 128. The cut away portion of thebushing 129 is in the shape of a slot that extends longitudinally slightly more than half the length of thebushing 129 from the bottom of thebushing 129 and that extends circumferentially an amount sufficient to accommodate the width of theactuator finger 126 that extends through the cut away portion to engage thecam surface 128. Across pin 131 at the bottom of the bore orients thebushing 129 and retains it against rotational movement in the bore. Thepin 131 also provides a stop for thepark pawl actuator 127 when the cam is pushing thepawl 122 downwardly into its locked position. The cylindrical shape of thepark pawl actuator 127 andbushing 129 aids machining of thecam surface 123. Further, the cylindrical shape of thepark pawl actuator 127 andbushing 129 and bore radially opposite thecam face 123 provides curved surfaces that spread lateral loads transmitted by thepawl 122 laterally against thecam face 128 of thepark pawl actuator 127 and against thehousing 29 b over a relatively large area of thehousing 29 b andbushing 129 to reduce stress. - The
park pawl 127 is free floating with thebushing 129 and bore in which thebushing 129 is disposed. A lockingspring 132 pushes or biases the free floatingpark pawl actuator 127 toward the locked position illustrated inFIGS. 17 , 18 and 20. Thecam face 128 ofpark pawl actuator 127 in the locked position engages or acts against the parkpawl locking surface 126 to lock thepawl locking finger 125 of thepawl 122 against thehub 121 between adjacent teeth and against one tooth of thehub 121. This locks thehub 121 andoutput drive shaft 64 against thehousing 29 b and prevents rotation of theoutput drive shaft 64 and drivewheels 15. The cam face orcam surface 123 of theactuator 127 includes a radiallyouter portion 128 a that is radially outward from thelongitudinal axis 127 a. The radiallyouter portion 123 a extends in the longitudinal direction and provides a positive lock to engage thelocking surface 126 when theactuator 127 andpawl 122 are in their locked position, to prevent release of thepawl locking finger 125 even with large loads imposed on the lockingfinger 125 such as may occur if thevehicle 10 is parked on a hill. Theportion 128 a may be slightly fiat relative to the generally cylindrical outer peripheral surface of theactuator 127 or may be coextensive with the generally cylindrical outer peripheral surface. Thecam face 128 also includes a generally flat radiallyinner portion 128 b that is radially inward toward thelongitudinal axis 127 a relative to thesurface 128 a. Thesurface 128 b extends in the longitudinal direction and engages thepawl locking surface 126 when thepawl 122 andactuator 127 are in their unlocked positions. Thecam face 128 further includes an inclined portion or ramp that extends longitudinally and radially relative to theaxis 127 a between theouter portion 128 a and theinner portion 128 b. The lockingsurface 126 engages the inclined surface as theactuator 127 and thepark pawl 122 move between their locked and unlocked positions. The outer peripheral surface of the generally cylindricalpark pawl actuator 127 circumferentially spaced from thecam surface 128 provides an actuatorcurved surface 128 c. Thecam surface 123 is laterally intermediate thepawl locking ringer 125 and the actuatorcurved surface 128 c, whereby forces transmitted by the lockingfinger 125 through the lockingsurface 126 against thecam surface 128 are transmitted to the actuatorcurved surface 128 c and against the curved surface of thebushing 129 and against the curved surface of the bore in thehousing 29 b in which thebushing 129 andactuator 127 are disposed. - A
release arm 133 and arelease lever 134 are secured to arelease shaft 135, and thecomponents arm pivot axis 135 a of therelease shaft 135. The release arm pivot axis and the park pawl pivot axis and the path of thepark pawl actuator 127 are substantially perpendicular to one another. To move thepark pawl assembly 120 from its locked position to its unlocked position against the bias of lockingspring 132 to release thepark pawl 122 from its locked position, therelease lever 134 is rotated about therelease pivot axis 135 a from its locked position illustrated inFIGS. 18 and 20 to its unlocked position illustrated inFIGS. 19 and 21 . This rotation of therelease lever 134 rotates theshaft 135 and therelease arm 133 about thepivot axis 135 a, so that therelease arm 133 positively lifts thepark pawl actuator 127 upward along its substantially straightline movement path 127 a in thebushing 129 against the bias of thespring 132, to allow release of thepawl locking finger 125 from thehub 121. A second spring (not shown) biases thepawl 122 and lockingfinger 125 away from thehub 121 and against thecam face 128, to release the lockingfinger 125 fromhub 121 and prevent unintentional engagement. The inclined ramp intermediate theportions pawl locking surface 126 about thepawl pivot axis 135 a of thepawl shaft 135 as thepark pawl 122 moves to its unlocked position. Therelease lever 134 is preferably secured to a cable (not shown) that is operated by the driver of thevehicle 10 or by an actuator (not shown) to rotate therelease lever 134. When therelease lever 134 is rotated to rotate therelease arm 133 in the opposite direction from the unlocked position to the locked position, thespring 132 biases thepark pawl actuator 127 downward as viewed in the drawings. As theactuator 127 moves downward, the inclined portion of thecam face 128 engages thepawl locking surface 126 and rotates a lockingfinger 125 of thepawl 122 against thehub 121. If the lockingfinger 125 engages a tooth ofhub 121 rather than entering a space between adjacent teeth, the action ofspring 132 retains the lockingfinger 125 biased against the tooth until thehub 121 rotates a slight amount such as by slight movement of thevehicle 10. When this slight movement occurs, the lockingfinger 125 will then move into the space between adjacent teeth to lock thehub 121 against movement. When the lockingfinger 125 is seated in the space between adjacent teeth of thehub 121, the radiallyouter portion 128 a of thecam face 128 engages the lockingsurface 126 and positively locks thepark pawl 122 in its locked position. - The
hub 121 includes several teeth on its outer peripheral surface, and the profile of each tooth is involute. The profile of the oppositely facing surfaces of thepawl locking finger 125 that engage the teeth is substantially flat. When thepark pawl assembly 120 is in its locked position with thefinger 125 engaging a tooth of thehub 121 and the vehicle is parked on a hill, the involute profile of the tooth acting against the substantially fiat profile of thefinger 125 urges thefinger 125 out of engagement with the tooth to assure unlocking. When thepark pawl assembly 120 is in its unlocked position and thepark pawl actuator 127 is moved to allowspring 132 to urge thefinger 125 toward its locked position, the involute profile of the teeth and the substantially flat profile of thefinger 125 prevent thefinger 125 from fully entering the space between the teeth and locking against a tooth of thehub 121 until the vehicle has slowed to an acceptable slow speed, for example one mile per hour or less, or has stopped. - The
park pawl assembly 120 therefore includes thepark pawl 122, thepark pawl actuator 127, and therelease arm 133. Thepark pawl actuator 127 is a generally cylindrical plunger and moves with itscam surface 123 along a substantially straight line path from an unlocked position to a locked position by operation of thelocking spring 132 in response to rotational movement of therelease arm 133 to its locked position. This substantially straight line movement of theactuator 127 is substantially perpendicular to the direction of movement of the lockingsurface 126 and lockingfinger 125 of thepark pawl 122 and causes movement of thepark pawl 122 to its locked position. Therelease arm 133 rotates about its pivot axis back to its unlocked position, and this rotational movement of therelease arm 133 causes substantially straight line movement of thepark pawl actuator 127 against the bias of thelocking spring 132 back to its unlocked position, to return thepark pawl 122 to its unlocked position. - The gears and shafts described above are preferably secured together using a
spline connection 160 illustrated inFIGS. 34-33 . Thespline connection 160 is illustrated inFIGS. 34-38 as applied to the connection between the primary pump motorunit drive shaft 44 and the primary pump motorunit drive gear 76. However, thesame spline connection 160 is also used between the secondary pump motorunit drive shaft 45 and its associateddrive gear 78 and between other shaft and gear connections illustrated in the drawings. Further, thespline connection 160 may be used in other applications to drivingly connect two components such as a shaft and a member arranged on the shaft. - The
spline connection 160 includes aninternal spline connector 161 on thegear 76 and a matingexternal spline connector 162 on theshaft 44. As best shown inFIG. 35 , theprimary gear 76 includesexternal gear teeth 163 and alongitudinally extending bore 164. Thebore 164 provides an internal spline connector, and theinternal spline connector 164 extends longitudinally from end to end through thegear 76 for alongitudinal extent 165. Theinternal spline connector 164 includes aspline portion 166 having alongitudinal extent 167. Thelongitudinal extent 167 of thespline portion 166 is at least about 30% of thelongitudinal extent 165 of theinternal spline connector 164 and is preferably between about 50% and about 80 percent of thelongitudinal extent 165 of theinternal spline connector 164. In the preferred embodiment illustrated inFIG. 35 , thelongitudinal extent 167 of thespline portion 166 is about 60% of thelongitudinal extent 165 of theinternal spline connector 167. Theinternal spline connector 164 also includes a pilot and centeringportion 168 having a substantially cylindrical generally smooth surface substantially adjacent thespline portion 166. The pilot and centeringportion 168 has alongitudinal extent 169. Thelongitudinal extent 169 of the pilot and centeringportion 168 is at least about 10% of thelongitudinal extent 165 of theinternal spline connector 164 and is preferably between about 20% and about 60% of thelongitudinal extent 165 of theinternal spline connector 164. In the preferred embodiment illustrated inFIG. 35 , thelongitudinal extent 169 of the pilot and centeringportion 168 is about 40% of the longitudinal extent of the 165 of theinternal spline connector 164. The pilot and centeringportion 168 has aninternal diameter 170 that is substantially greater than theinternal diameter 171 of the crests of the teeth of the splines of thespline portion 166. The solid lines indicated inFIG. 35 for thespline portion 166 illustrate the crests of the splines, and the dotted lines indicated inFIG. 35 for thespline portion 166 illustrate the roots of the splines. - As best shown in
FIGS. 34 , 35 and 36, theexternal spline connector 162 of theshaft 44 is anexternal surface 172 of theshaft 44 that is at least partially radially aligned with the internalspline connector portion 161 of thegear 76 when thegear 76 is partially or fully assembled on theshaft 44. Theexternal spline connector 162 has alongitudinal extent 173, and theexternal spline connector 162 includes aspline portion 174 and a substantially smooth generally cylindrical centeringportion 175 longitudinally substantially adjacent thespline portion 174. Thespline portion 174 has alongitudinal extent 176 that is greater than about 40% of thelongitudinal extent 173 and is preferably between about 60% and about 100% of thelongitudinal extent 173. In the preferred embodiment, thelongitudinal extent 176 is about 80% of thelongitudinal extent 173. The centeringportion 175 has alongitudinal extent 177 that is less than about 50% of thelongitudinal extent 173 and is preferably between about 30% and 0% of thelongitudinal extent 173. In the preferred embodiment, thelongitudinal extent 177 is about 20% of thelongitudinal extent 173. The solid lines indicated inFIG. 36 for thespline portion 174 indicate the crests of the splines, and the dotted lines indicated inFIG. 36 for thespline portion 174 indicate the roots of the splines. Only the roots of the splines of thespline portion 174 are illustrated inFIGS. 34 , 34 a and 34 b, to avoid overlapping lines on those Figures among thespline portion 174 and themating spline portion 166. As illustrated inFIGS. 34 a and 34 b and further described below, the generallysmooth portion 163 is longitudinally substantially adjacent its spline portion 188 on one side of thespline portion 163, while the generallysmooth portion 175 is substantially adjacent itsspline portion 174 on the opposite side of thespline portion 174. -
FIG. 37 illustrates thegear 76 andshaft 44, and the infernal andexternal spline connectors gear 76 onto theshaft 44, the smooth pilot and centeringportion 168 of theinfernal spline connector 161 is moved longitudinally onto and over thespline portion 174 of theexternal spline connector 162 of theshaft 44, to a first partially assembled position or configuration illustrated inFIG. 34 a. During this movement, the centeringportion 168 of theinternal spline connector 161 lightly engages and centers and guides theshaft 44 and itsexternal spline connector 162 to longitudinally and circumferentially align thespline portions portion 168 aligns the longitudinal axis of thegear 76 relative to the longitudinal axis of theshaft 44 so that these axes are substantially coaxial. Thegear 76 can be rotated relative to theshaft 44 while the smooth pilot and centeringportion 168 is in radial alignment with thespline portion 174 as illustrated inFIG. 34 a, to circumferentially align splines of theinternal spline portion 166 with the splines of theexternal spline portion 174. The smooth pilot and centeringportion 168 has a diameter only slightly larger than the diameter of the crests of thespline portion 174, for example with a minimal clearance fit between theportions portions - Continued movement of the
gear 76 onto theshaft 44 to a second partially assembled position or configuration illustrated inFIG. 34 b causes thespline portion 166 of theinternal spline connector 161 of thegear 76 to move longitudinally into meshing engagement with thespline portion 174 of theexternal spline connector 162 of theshaft 44. In this position, thespline portions portion 168 slides along the outside or crests of thespline portion 174 to continue to help maintain alignment during movement to this position. Continued movement of thegear 76 onto theshaft 44 to the fully assembled position illustrated inFIG. 34 causes the smooth pilot and centeringportion 164 of theinternal spline connector 161 of thegear 76 to move into radial alignment with the smooth centeringportion 175 of theexternal spline connector 162 of theshaft 44, with thesmooth portions spline connectors gear 76 against longitudinal movement relative to theshaft 44 after assembly to the position illustrated inFIG. 34 , although such stops may not be required in the assembly illustrated in the drawings. - In this manner, the
spline connection 161 includes aninternal spline connector 161 and anexternal spline connector 162. At least one of thespline connectors spline connectors connectors spline connectors - The principles, embodiments and operation of the present invention are described in detail herein with reference to the accompanying drawings but are not to be construed as being limited to the particular illustrative forms disclosed. It will thus become apparent to those skilled in the art that various modifications of the principles, embodiments and operation herein can be made without departing from the spirit or scope of the invention.
Claims (40)
1. A connecting assembly for a hydromechanical transmission, comprising,
a connecting plate having a hydraulic unit wall and a gear set unit wall,
a hydraulic unit housing which is connected to the hydraulic unit wail to provide a sealed hydraulic chamber which contains a hydraulic fluid,
a gear set unit housing which is connected to the gear set unit wall to provide a sealed gear set chamber,
first and second hydraulic pump motor units disposed in the sealed hydraulic chamber and arranged so that hydraulic fluid can flow between each of the pump motor units and the sealed hydraulic chamber so as to permit exchange of fluid between the pump motor units, and
a gear set disposed in the sealed gear set chamber.
2. A connecting assembly as set forth in claim 1 , wherein the connecting plate includes fluid flow passages, and the hydraulic pump motor unit includes a fluid outlet in fluid communication with one of the passages.
3. A connecting assembly as set forth in claim 1 , including a mechanical drive opening that extends longitudinally through the connecting plate from the sealed hydraulic chamber to the sealed gear set chamber, and a mechanical drive shaft extends longitudinally from end to end through the sealed hydraulic chamber and through the mechanical drive opening and into the sealed gear set chamber.
4. A connecting assembly as set forth in claim 1 including a hydraulic drive opening that extends longitudinally through the connecting plate from the sealed hydraulic chamber to the sealed gear set chamber, a hydraulic pump motor unit drive shaft drivingly connected to the hydraulic pump motor unit, and the hydraulic pump motor unit drive shaft extends longitudinally through the hydraulic drive opening.
5. A connecting assembly as set forth in claim 4 , in which the hydraulic drive openings are in laterally offset relation to the mechanical drive opening and are in circumferentially spaced relation to one another.
6. A connecting assembly as set forth in claim 1 , in which the gear set includes a plurality of gear components, the mechanical drive shaft is connected to one of the gear components, and each hydraulic pump motor unit drive shaft is connected to another of the gear components.
7. A connecting assembly for a hydromechanical transmission, comprising:
a connecting plate having a hydraulic unit wall and a gear set unit wall,
a hydraulic unit housing which is connected to the hydraulic unit wall to provide a sealed hydraulic chamber,
a gear set unit housing which is connected to the gear set unit wall to provide a seated gear set chamber,
a hydraulic pump motor unit disposed in the sealed hydraulic chamber, having a hydraulic pump motor unit drive shaft drivingly connected to it,
a gear set disposed in the sealed gear set chamber and including a plurality of gear components, the hydraulic pump motor unit drive shaft extending through a hydraulic drive opening in the connecting plate from the hydraulic unit housing chamber into the gear set unit housing chamber where it is connected to a first one of the gear components,
a mechanical drive shaft for connection to a prime mover, which extends from the prime mover into the hydraulic unit housing, extending without interruption through the hydraulic unit housing chamber and out of the chamber through a mechanical drive opening in the connecting plate into the gear set unit housing chamber where it is connected to a second one of the gear components, the mechanical drive shaft being offset laterally from the hydraulic pump motor unit drive shaft.
8. A connecting assembly as set forth in claim 7 , in which the connecting plate includes fluid flow passages, and the hydraulic pump motor unit includes a fluid outlet in fluid communication with one of the passages.
9. A connecting assembly as set forth in claim 7 , which includes a second hydraulic pump motor unit disposed in the sealed hydraulic chamber having a second hydraulic pump motor unit drive shaft drivingly connected to it, the second hydraulic pump motor unit drive shaft extends longitudinally through a second hydraulic drive opening in the connecting plate.
10. A hydromechanical transmission comprising a hydraulic unit having a hydraulic unit housing, a gear unit having a gear unit housing,
the hydraulic unit housing having a vehicle prime mover input end and an output end, the gear unit housing having an input end and a vehicle drive shaft output end, the hydraulic unit housing and the gear unit housing each having an exterior surface and an interior surface, each interior surface defining an interior chamber, each of the interior chambers being sealed from the other interior chamber,
the hydraulic unit housing having a longitudinally extending prime mover input shaft opening at its input end extending longitudinally into the hydraulic unit housing interior chamber, at least one variable displacement hydraulic pump motor unit disposed within the hydraulic unit housing interior chamber, a hydraulic pump motor unit drive shaft within the hydraulic unit housing interior chamber, the hydraulic pump motor unit drive shaft being drivingly connected to the hydraulic pump motor unit,
the gear unit housing having an output drive shaft opening at its output end extending longitudinally from the gear unit housing interior chamber, a gear unit disposed within the gear unit housing interior chamber, the gear unit having gear components,
the hydraulic pump motor unit drive shaft being drivingly connected to one of the gear components, and
the hydraulic unit housing output end being connected to the gear unit housing input end, with the hydraulic unit housing interior chamber and the gear unit interior chamber being in longitudinally aligned relationship to one another.
11. A hydromechanical transmission as set forth in claim 10 , wherein the hydraulic pump motor unit drive shaft extends from the hydraulic unit housing interior chamber to the gear unit housing interior chamber
12. A hydromechanical transmission as set forth in claim 10 , including a connecting plate having longitudinally opposite sides, the connecting plate is intermediate the hydraulic unit housing interior chamber and the gear unit interior chamber, one side of the connecting plate is adjacent the hydraulic unit output end, and the other side of the connecting plate is adjacent the gear unit input end.
13. A hydromechanical transmission as set forth in claim 12 , wherein the hydraulic unit housing includes another hydraulic pump motor unit and another hydraulic pump motor unit drive shaft connected to the other hydraulic pump motor unit, the other pump motor unit drive shaft extends from the hydraulic unit housing interior chamber to the gear unit housing interior chamber, each hydraulic pump motor unit and each hydraulic pump motor unit drive shaft is disposed in laterally offset relation to the input shaft opening, each hydraulic pump motor unit drive shaft is drivingly connected to one of the gear unit components, and the input shaft opening and output shaft opening are substantially axially aligned.
14. A hydromechanical transmission as set forth in claim 13 , wherein the transmission is a powersplit transmission, each hydraulic pump motor unit is in circumferentially spaced relation to the other, each hydraulic pump motor unit drive shaft is in circumferentially spaced in relation to the other, the gear unit is a planetary gear unit having planetary gear components including a sun gear and a ring gear and a planet gear carrier.
15. A hydromechanical transmission as set forth in claim 13 , wherein each hydraulic pump motor unit is in longitudinally spaced relation to the other.
16. A hydromechanical transmission as set forth in claim 13 , including a prime mover input shaft extending longitudinally through the prime mover input shaft opening, an output shaft extending longitudinally through the output shaft opening, one of the sides of the connecting plate provides a wall of the hydraulic unit housing interior chamber, the other of the sides of the connecting plate provides a wall of the gear unit housing interior chamber, and the connecting plate includes bearings for supporting the input shaft and each hydraulic pump motor unit drive shaft.
17. A hydromechanical transmission as set forth in claim 13 , wherein one side of the connecting plate provides a wall of the hydraulic unit housing interior chamber, another side of the connecting plate provides a wall of the gear unit interior chamber, and the hydraulic unit housing and the planetary gear unit housing are each removably attached to the connecting plate.
18. A hydromechanical transmission as set forth in claim 13 , wherein the connecting plate is a hydraulic manifold having fluid flow passages in fluid communication with the pump motor unit.
19. A hydromechanical transmission as set forth in claim 16 , wherein each pump motor unit is a bent axis variable displacement pump motor unit, the variable displacement pump motor units each include a pumping mode high pressure hydraulic fluid outlet and a displacement control mechanism, and different ones of the fluid flow passages in the connecting plate are in fluid communication with the pumping mode high pressure hydraulic fluid outlet and with the displacement control mechanism of each pump motor unit.
20. A hydromechanical transmission as set forth in claim 13 , including a displacement control valve associated with each pump motor unit, each displacement control valve is in fluid communication with the fluid flow passages that are in fluid communication with the displacement control mechanism.
21. A hydromechanical transmission as set forth in claim 20 , wherein each of the displacement control valves is mounted on the connecting plate.
22. A hydromechanical transmission as set forth in claim 13 , including an isolation valve associated with each pump motor unit, the isolation valves include a high pressure port, each isolation valve has a closed position isolating the high pressure port from its associated pump motor unit.
23. A hydromechanical transmission as set forth in claim 22 , wherein each isolation valve is mounted on the connecting plate.
24. A hydromechanical transmission as set forth in claim 23 , wherein the isolation valves are disposed in a single isolation valve housing, the isolation valve high pressure port is disposed in the isolation valve housing, the isolation valve housing includes passages connecting the isolation valve high pressure port with a connecting plate high pressure port and with each of the isolation valves.
25. A hydromechanical transmission as set forth in claim 22 , wherein the connecting plate includes passages connecting each of the isolation valves with an associated one of the pump motor units.
26. A hydromechanical transmission as set forth in claim 16 , wherein the input shaft is connected to the planet gear carrier, the first mentioned hydraulic pump motor unit drive shaft is connected to the sun gear, and the second mentioned hydraulic pump motor unit drive shaft and the output shaft are each connected to the ring gear.
27. A hydromechanical transmission as set forth in claim 16 , including a transfer shaft extending longitudinally intermediate the input shaft and the output shaft, the transfer shaft is drivingly connected to the input shaft and to one of the planetary gear components, the connecting plate includes a bearing supporting the transfer shaft, and the transfer shaft is axially aligned with the input shaft and with the output shaft.
28. A hydromechanical transmission as set forth in claim 26 , including a bearing rotatably supporting the transfer shaft within one end of the output shaft.
29. A hydromechanical transmission as set forth in claim 16 , wherein the connecting plate includes a bearing rotatably supporting each pump motor unit drive shaft.
30. A hydromechanical transmission as set forth in claim 29 , wherein the planetary gear unit housing includes a bearing rotatably supporting each pump motor unit drive shaft.
31. A hydromechanical transmission as set forth in claim 30 , including a gear fixed to each pump motor unit drive shaft intermediate the bearings, and the gear is rotatably connected to one of the planetary gear components.
32. A hydromechanical transmission as set forth in claim 16 , wherein the connecting plate includes bearings rotatably supporting each of the pump motor unit drive shafts and seals preventing fluid leakage between the pump motor unit drive shafts and the connecting plate, the planetary gear unit housing includes bearings rotatably supporting each pump motor unit drive shaft, a gear is fixed to each of the pump motor unit drive shafts intermediate the bearings, the gears are each rotatably connected to one of the planetary gear components, and the input shaft and the output shafts are substantially axially aligned.
33. A hydromechanical transmission as set forth in claim 32 , wherein the bearings in the connecting plate are radial and axial thrust bearings.
34. A hydromechanical transmission as set forth in claim 10 , including one type of fluid disposed within the hydraulic unit housing interior chamber and a different type of fluid disposed within the planetary gear unit housing interior chamber.
35. A hydromechanical transmission as set forth in claim 34 , wherein the hydraulic unit housing interior chamber is substantially completely filled with the one type of fluid and is at a positive pressure of at least about 2 bar, and the planetary gear unit housing is substantially less than half filled with the different type of fluid at about atmospheric pressure.
36. A hydromechanical transmission as set forth in claim 35 , wherein each of the hydraulic pump motor units is fully immersed in the one type of fluid within the hydraulic unit interior chamber.
37. A hydromechanical transmission as set forth in claim 36 , wherein the first mentioned hydraulic pump motor unit discharges fluid into the hydraulic unit housing interior chamber when in a motoring mode, and the other hydraulic pump motor unit inputs fluid from the first mentioned hydraulic pump motor unit through the hydraulic unit housing interior chamber when in a pumping mode.
38. A hydromechanical transmission as set forth in claim 10 , including a motor vehicle having two laterally spaced apart longitudinally extending frame rails, and the hydromechanical transmission is disposed between the frame rails.
39. A hydromechanical transmission as set forth in claim 38 , wherein the motor vehicle includes a vehicle drive shaft and a prime mover having a prime mover shaft, the output shaft opening is axially aligned with the vehicle drive shaft, and the input shaft opening is axially aligned with the prime mover shaft.
40. A hydromechanical transmission as set forth in claim 33 , wherein the motor vehicle includes a high pressure accumulator and the high pressure accumulator is connected with each hydraulic pump motor unit during various modes of operation of the motor vehicle.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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US14/529,210 US20150051037A1 (en) | 2012-05-02 | 2014-10-31 | Hydromechanical Transmission and Assemblies |
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US201261641467P | 2012-05-02 | 2012-05-02 | |
PCT/US2013/023048 WO2013165489A1 (en) | 2012-05-02 | 2013-01-25 | Hydromechanical transmission and assemblies |
US14/529,210 US20150051037A1 (en) | 2012-05-02 | 2014-10-31 | Hydromechanical Transmission and Assemblies |
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PCT/US2013/023048 Continuation WO2013165489A1 (en) | 2012-05-02 | 2013-01-25 | Hydromechanical transmission and assemblies |
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US14/529,249 Expired - Fee Related US9453566B2 (en) | 2012-05-02 | 2014-10-31 | Hydromechanical transmission with double sump gear unit housing |
US14/529,210 Abandoned US20150051037A1 (en) | 2012-05-02 | 2014-10-31 | Hydromechanical Transmission and Assemblies |
US14/529,229 Abandoned US20150047195A1 (en) | 2012-05-02 | 2014-10-31 | Method of Assembly for Hydromechanical Transmission |
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US14/529,249 Expired - Fee Related US9453566B2 (en) | 2012-05-02 | 2014-10-31 | Hydromechanical transmission with double sump gear unit housing |
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- 2014-10-31 US US14/529,229 patent/US20150047195A1/en not_active Abandoned
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US4446756A (en) * | 1979-12-15 | 1984-05-08 | Maschinenfabrik Augsburg-Nurnberg Aktiengesellschaft | Power divider gearbox with a planetary differential gear drive |
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US7213488B2 (en) * | 2004-01-14 | 2007-05-08 | Daniel Jeffrey K | Three way swivel divider gearbox for agricultural drive systems |
US20100051410A1 (en) * | 2008-08-29 | 2010-03-04 | Koji Iwaki | Traveling System Transmission Structure for Vehicle |
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US10927936B2 (en) * | 2014-08-04 | 2021-02-23 | Hydracharge Llc | Power conversion device |
Also Published As
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ES2610790T3 (en) | 2017-05-03 |
EP2844892B1 (en) | 2016-10-19 |
WO2013165492A1 (en) | 2013-11-07 |
WO2013165493A1 (en) | 2013-11-07 |
WO2013165491A1 (en) | 2013-11-07 |
US20150047195A1 (en) | 2015-02-19 |
US9453566B2 (en) | 2016-09-27 |
WO2013165490A1 (en) | 2013-11-07 |
WO2013165489A1 (en) | 2013-11-07 |
US20130294825A1 (en) | 2013-11-07 |
BR112014027447A2 (en) | 2017-06-27 |
EP2844892A1 (en) | 2015-03-11 |
US20150057120A1 (en) | 2015-02-26 |
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Owner name: PARKER-HANNIFIN CORPORATION, OHIO Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:KOVACH, JOSEPH;SIMON, MATTHEW;HORSFALL, STEPHAN;AND OTHERS;SIGNING DATES FROM 20141209 TO 20141218;REEL/FRAME:035321/0573 |
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STCB | Information on status: application discontinuation |
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