Source: http://www.google.com/patents/US5287829?dq=5,381,459
Timestamp: 2017-03-30 02:00:56
Document Index: 751557164

Matched Legal Cases: ['art 12', 'art 12', 'art 12', 'art 12', 'arts 12', 'arts 12', 'art 12']

Patent US5287829 - Fluid actuators - Google PatentsSearch Images Maps Play YouTube News Gmail Drive More »Sign inPatentsA fluid actuator (10) including a chamber (14) in which a piston assembly (17) reciprocates. The piston assembly (17) includes a pair of spaced pistons (18, 19) which divide the chamber (14) into three sections (20, 21, 22) and a passageway (29) which supports a valve member (30). Reciprocating movement...http://www.google.com/patents/US5287829?utm_source=gb-gplus-sharePatent US5287829 - Fluid actuatorsAdvanced Patent SearchTry the new Google Patents, with machine-classified Google Scholar results, and Japanese and South Korean patents.Publication numberUS5287829 APublication typeGrantApplication numberUS 07/835,911PCT numberPCT/AU1990/000387Publication dateFeb 22, 1994Filing dateAug 28, 1990Priority dateAug 28, 1989Fee statusPaidAlso published asDE69027858D1, DE69027858T2, EP0489796A1, EP0489796A4, EP0489796B1, WO1991003630A1Publication number07835911, 835911, PCT/1990/387, PCT/AU/1990/000387, PCT/AU/1990/00387, PCT/AU/90/000387, PCT/AU/90/00387, PCT/AU1990/000387, PCT/AU1990/00387, PCT/AU1990000387, PCT/AU199000387, PCT/AU90/000387, PCT/AU90/00387, PCT/AU90000387, PCT/AU9000387, US 5287829 A, US 5287829A, US-A-5287829, US5287829 A, US5287829AInventorsNigel E. RoseOriginal AssigneeRose Nigel EExport CitationBiBTeX, EndNote, RefManPatent Citations (10), Referenced by (46), Classifications (24), Legal Events (7) External Links: USPTO, USPTO Assignment, EspacenetFluid actuators
US 5287829 AAbstract
A fluid actuator (10) including a chamber (14) in which a piston assembly (17) reciprocates. The piston assembly (17) includes a pair of spaced pistons (18, 19) which divide the chamber (14) into three sections (20, 21, 22) and a passageway (29) which supports a valve member (30). Reciprocating movement of the slide valve member (30) causes fluid to be directed to the chamber sections (20) and (22) and thereby corresponding reciprocating movement of the piston assembly (17). The actuator (10) may be applied to the control of any device such as valves of internal combustion engines, fuel injectors or comprise actuating means for the piston of an internal combustion engine.
1. A fluid actuator including a chamber, a piston assembly arranged for reciprocating movement within said chamber, said piston assembly including first and second spaced apart pistons dividing said chamber into a first chamber section between said first piston and said chamber, a second chamber section between said first and second pistons, and a third chamber section between said second piston and said chamber, passageway means in said piston assembly, fluid inlet means communicating with said second chamber section and valve means for controlling the flow of fluid through said passageway means, said valve means being operable to communicate fluid through said passageway means from said second to said first chamber sections so as to cause movement of said piston assembly in a first direction, and said valve means being further operable to communicate fluid through said passageway means from said second to said third chamber sections so as to cause said piston assembly to move in a direction opposite said first direction.
2. In combination, a fluid actuator as defined in claim 1 and a fuel injector having a reciprocal plunger, said piston assembly being coupled to said plunger and being adapted to reciprocate said plunger upon operation of said valve means.
3. A fluid actuator according to claim 1, wherein said piston assembly includes first, second and third port means communicating with said first, second and third chamber sections respectively and wherein said valve means controls communication between said port means and said passageway means.
4. A fluid actuator according to claim 3 wherein said piston assembly includes opposite portions extending beyond opposite ends of said chamber, vent port means in said opposite portions and adapted for communication with said passageway means, said valve means being adapted to control communication of said vent port means with said first and third port means whereby to control venting of said first and third chamber sections.
5. A fluid actuator according to claim 4 wherein said passageway means comprise a passageway extending longitudinally of said piston assembly and wherein said valve means is slidable in said passageway.
6. A fluid actuator according to claim 5 wherein said valve means includes a plurality of lands, said lands being adapted to open and close said port means to control communication thereof with said passageway.
7. A fluid actuator according to claim 6 wherein said lands are separated by annular grooves defining fluid paths in said passageway.
8. A fluid actuator according to claim 4 wherein movement of said valve means in said first direction opens communication between said first and second port means via said passageway means, and opens communication between said third port means and vent port means via said passageway means to cause said movement of said piston assembly in said first direction.
9. A fluid actuator according to claim 8 wherein movement of said valve means in said opposite direction opens communication between said second and third port means via said passageway means, and opens communication between said first port means and vent port means via said passageway means to cause movement of said piston assembly in said opposite direction.
10. A fluid actuator according to claim 4 and including further chamber sections communicating with the respective said vent port means and isolating vented fluid.
11. A fluid actuator according to claim 1 and including biasing means for opposing movement of said piston assembly in said first direction.
12. A fluid actuator according to claim 11 wherein said biasing means acts on said second piston.
13. A fluid actuator according to claim 12 wherein said biasing means comprising spring means disposed between said second piston and wall means at the other end of said chamber.
14. In combination a fluid actuator as defined in claim 1 and a valve of an internal combustion engine, said piston assembly being coupled to said engine valve and wherein movement of said operation of said valve means is adapted to cause opening and closing movement of said valve.
15. The combination of claim 14 wherein said engine valve includes a valve stem, said piston assembly being secured to or formed integrally with said stem and said passageway being disposed within said stem.
16. An internal combustion engine comprising a piston reciprocable in a cylinder and a fluid actuator as defined in claim 1, said piston assembly of said actuator being coupled to said engine piston and wherein operation of said valve means causes reciprocation of said piston assembly and said engine piston.
17. An internal combustion engine according to claim 16 wherein said valve means is operated by cam means, rotation of said cam means causing reciprocation of said valve means and said piston assembly.
18. An internal combustion engine according to claim 16, wherein operation of said valve means causes said engine piston to undergo a compression stroke and a fuel intake stroke, respectively.
19. An internal combustion engine according to claim 18, wherein said fluid actuator includes fluid outlet means, said valve means controlling fluid communication between said fluid outlet means and said first and third chamber sections, said fluid outlet means receiving fluid from said first and third chamber sections on movement of said piston assembly in opposite directions.
20. An internal combustion engine according to claim 19, wherein said fluid outlet means are connected to a high pressure fluid gallery via non-return valve means for supplying fluid to a load.
21. An internal combustion engine according to claim 20, wherein said fluid actuator includes secondary valve means, said secondary valve means venting fluid from said third chamber section in the event of misfiring in said engine cylinder in an advanced position of said engine piston so as to permit said piston assembly of said fluid actuator and said piston of said engine to retract from said advanced position.
22. An internal combustion engine according to claim 17, wherein said cam means are mounted on a rotating shaft and there being provided means for selectively engaging said cam means with said shaft so as to allow rotation of said cam means with said shaft.
23. An internal combustion engine according to claim 17, wherein said cam means are mounted for movement towards and away from said valve means so as to vary the compression ratio of said engine while maintaining the stroke of said engine piston.
24. An internal combustion engine according to claim 17, and including crank means between said cam means and said valve means and means for varying the position of said crank means relative to said valve means to vary the stroke of said engine piston and compression ratio of said engine.
This invention relates to fluid actuators which in one particular aspect are applicable to the control of various mechanisms in internal combustion engines, for example exhaust and inlet valves or fuel injectors and which in a further aspect are applicable to the extraction of power from reciprocating pistons of internal combustion engines. The actuators of the invention however may be applied to other situations for example as servomechanisms or for accurate control of movement.
Conventional internal combustion engines usually also include reciprocating pistons which are coupled to a crank shaft via piston rods, however, this form of mechanical connection has limitations resulting in limitation of transmission of usable energy from the piston to the crank shaft caused by changes of the lever arm at the crank shaft from zero at the start of the stroke through a maximum at approximately half stroke to zero at the end of the stroke. Further disadvantages arise because of side thrust friction losses causing cylinder and piston wear induced by thrust angles of the connecting rods relative to the cylinder bore centre line during rotation of the crank shaft. Lack of flexibility in the control of the rate of expansion of the gases of combustion also occurs due to utilization of a rotating crank shaft rigidly attached to the reciprocating pistons by connecting rods consequently leading to a considerable loss in the recovery of usable energy from the gases of combustion.
In its applicability to the extraction of usable energy from the reciprocating pistons of internal combustion engines the present invention provides an actuator which permits greater recovery of usable energy, reduces side thrust friction losses and consequent rates of cylinder tear and provides a degree of flexibility to control the rate of expansion of the gases of combustion.
With the above and other objects in view the present invention provides a fluid actuator including a chamber, a piston assembly arranged for reciprocating movement within said chamber, said piston assembly including first and second spaced apart pistons dividing said chamber into at least a first chamber section between said first piston and said chamber and a second chamber section between said first and second pistons, passageway means in said piston assembly, fluid inlet means communicating with said second chamber section and valve means for controlling the flow of fluid through said passageway means, said valve means be operable to communicate through said passageway means said first and second chamber sections so as to cause movement of said piston assembly in a first direction, said valve means being further operable to vent fluid from said first chamber section whereby to permit said piston assembly to move in a direction opposite said first direction.
Preferably, said piston assembly defines between said second piston and said chamber a third chamber section, and said valve means is operable to communicate through said passageway means said second and third chamber sections so as to cause said piston assembly to move in said direction opposite said first direction.
Most preferably, said piston assembly includes first, second and third port means communicating with said first, second and third chamber sections respectively and said valve means controls communication between said port means and said passageway means. The piston assembly suitably includes opposite portions extending beyond opposite ends of said chamber, and vent port means in said opposite portions and adapted for communication with said passageway means, said valve means being adapted to control communication of said vent port means with said first and third port means whereby to control venting of said first and third chamber sections.
Means are suitably provided for reciprocating said valve means such that movement of said valve means in said first direction opens communication between said first and second port means and said passageway, and opens communication between said third port means and vent port means through said passageway, to cause said movement of said piston assembly in said first direction.
Preferably, movement of said valve means in said opposite direction opens communication between said second and third port means and said passageway and opens communication between said first port means and vent port means through said passageway to cause movement of said piston assembly in said opposite direction.
The actuator may also include further chamber sections communicating with the respective said vent port means and isolating vented fluid.
In a further form, the actuator includes biasing means for opposing movement of said piston assembly in said first direction. Suitably, said biasing means acts on said second piston and comprises spring means disposed between said second piston and wall means at the other end of said chamber.
The present invention also provides the combination of a fluid actuator as described above and a valve of an internal combustion engine, said piston assembly of said actuator being coupled to said engine valve and wherein movement of said operation of said valve means is adapted to cause opening and closing movement of said valve. Suitably, said engine valve includes a valve stem, said piston assembly being secured to or formed integrally with said stem and said passageway being disposed within said stem.
In a further form the present invention provides an internal combustion engine comprising a piston arranged for reciprocation in a cylinder and a fluid actuator as described above, said piston assembly of said actuator being coupled to said engine piston and wherein operation of said valve means causes reciprocation of said piston assembly and said engine piston.
Preferably, said valve means is operated by cam means, rotation of said cam means causing reciprocation of said valve means and said piston assembly.
Means may also be provide for varying the stroke of said engine piston or compression ratio of said engine by selectively repositioning the cam means.
FIGS. 13 to 15 illustrate in sectional view alternate forms of housings for the actuator;
FIGS. 16A and 16B are a sectional views showing alternative arrangements for mounting the actuator in the head of an engine;
FIGS. 19 to 23 illustrate the cycle of operate on of the actuator as applied to fuel injectors;
FIGS. 24 and 25 illustrate in cut-away and part-sectional view respectively an alternative actuator/injector combination;
FIG. 26 is a partly cut away view showing a modification to the actuator and injector combination of FIGS. 19 and 20.
FIG. 27 illustrates the actuator of the present invention associated with a piston of an internal combustion engine;
FIGS. 28 illustrates a pair of cylinders of an internal combustion engine showing the pistons at opposite ends of their strokes;
FIG. 29 illustrates the pair of cylinders of FIG. 28 at the middle of the reciprocating strokes of the pistons.
FIG. 30 illustrates a pair of cylinders of an internal combustion engine supplying fluid to a high pressure gallery;
FIG. 31 illustrates a preferred auxiliary valving arrangement for overcoming misfiring in a cylinder and engaging idle cylinders;
FIG. 32 illustrates in elevational view details of an alternative drainage port arrangement in the area A of FIG. 31;
FIG. 33 is a sectional view along lines B--B of FIG. 32
FIG. 34 illustrates in perspective view an arrangement for controlling the compression ratio of the cylinder of FIG. 28;
FIG. 35 illustrate in perspective view an arrangement for controlling the stroke of the piston of the engine; and
FIG. 36 illustrates an alternative arrangement for controlling the engine compression ratio.
Referring to the drawings and firstly to FIG. 1 there is illustrated a fluid actuator 10 according to the present invention adapted for the control of a valve 11 of an internal combustion engine, for example an inlet or exhaust valve. The actuator 10 includes a housing 12 of generally cylindrical form which is mounted to the head 13 of an engine and which includes a cylindrical chamber 14 defined between an end wall 15 of the housing 12 and intermediate annular wall 16.
Arranged for reciprocation within the chamber 14 is a piston assembly 17 which includes a pair of spaced apart annular pistons 18 and 19 which separate the chamber 14 into three chamber sections 20, 21 and 22. The valve 11 includes a valve stem 23 which is secured to the piston assembly 17 for movement therewith. Alternatively the piston assembly 17 may be formed integrally with the valve stem 23. An inlet port 24 is provided in the wall of the housing 12 for the supply of hydraulic fluid to the chamber section 21.
The piston assembly 17 includes a series of ports 25, 26 and 27 provided in its annular shaft 28 to communicate with the respective chamber sections 20, 21 and 22 and through the stem 23 with a longitudinally extending internal bore 29 formed within the shaft 28 or stem 23 of the valve 11. Supported for reciprocation within the bore 29 is a slide valve member 30 which includes spaced lands 31, 32 and 33 separated by annular grooves 34 and 35 which define passageways for hydraulic fluid. Discharge ports 36 are provided at the upper end of the piston assembly 17 to communicate with the bore 29 whilst at the lower end of the bore 29 a spring 37 is provided to urge the valve 33 to an upper position. Further discharge ports 38 are also provided in the shaft 28 at the lower end of the piston assembly 17 to communicate through the stem 23 with the bore 29. The ports 38 preferably extend in a non-radial direction outwardly from the bore 29 so that liquid discharging therefrom causes an off centre force to be applied to the valve stem 23 and rotation of the valve 11 so as to ensure even wearing on the valve seat.
The lower part of the housing 12 beneath the wall 16 forms a drainage chamber 39 which vents through drainage ports 40. Further drainage ports 41 communicate with the bore 29 in the region of the spring 37 to vent this portion of the bore 29.
Optionally, a return spring 42 acting between a flange 43 secured to the valve stem 23 and the end wall 15 of the housing 12 may be provided to normally hold the valve 11 in a closed position. Operation of the slide valve member 30 may be controlled by a solenoid 44 which has its armature connected to, or integral with the valve member 30, or alternatively a conventional rotational cam and cam shaft acting directly or indirectly on the valve member 30.
In use and as shown in FIGS. 2 to 6 the piston assembly 17 when the valve 11 is seated is moved to a raised position under the influence of hydraulic fluid supplied through the port 24 passing into the port 26 through the annular groove 34 to the chamber section 22 to act between the piston 19 and wall 16. In this position also the slide valve member 30 is held in a raised position. Fluid in the chamber section 20 communicates through the ports 25, annular groove 35 and ports 36 to drain. So as to open the valve 11, the slide valve member 30 is advanced by the solenoid 44 (or a cam) as shown initially in FIG. 3 so that the land 32 blocks the passage of fluid from the inlet 24 to the chamber section 22. At the same time, fluid communication from the port 24 is opened through the ports 26, groove 35 and port 25 to the upper section 20 of the chamber 14, with the land 33 blocking its passage to the vent ports 36, whilst the lower chamber section 22 is vented through the ports 27, groove 34 and port 38 to the drainage chamber 39 and through port 40 to drain. The fluid in the chamber section 20 acting between the piston 18 and housing end wall 15 causes downward movement of the piston assembly 17 and thus opening movement of the valve 11. At the same time the slide valve member 30 is moved downwardly at the same rate by the solenoid 44 as shown in FIG. 4. It will be seen that during this motion the return spring 37 for the valve member 30 and return spring 42 for the valve 11 (if used) will be compressed.
When the valve 11 approaches a fully opened position, the valve member 30 is stopped in its movement as shown in FIG. 5 so that the land 32 blocks communication of the port 26 with the chamber section 20 and at the same time the land 31 blocks communication of the chamber section 22 with the drainage chamber 39. The chamber section 20, however, is opened to vent through the ports 25, passage 35 and ports 36, whilst the chamber 21 communicates through the ports 26, and passage 34 to the chamber section 22.
As fluid is supplied to the chamber section 22 through ports 26, passageway 34 and ports 27 whilst being vented from the chamber 20 through ports 25, passageway 35 and ports 36, the piston assembly 17 raises upwardly thereby moving the valve 11 again towards a closed position. At the same time, the slide valve member 30 is also retracted as shown in FIG. 6 so that the valve 11 and slide valve member 30 move upwards at the same rate until the valve 11 is closed and the slide valve member 30 moved to the position of FIG. 2. The piston assembly 12 is thus slaved to reciprocating movement of the slide valve member 30.
The inlet port 24 is preferably fitted with a non-return valve so as to preclude the possibility of valve bounce in the event of engine overspeed or the operation of an engine with excessively low hydraulic pressure supply. In most cases, hydraulic fluid to the inlet port 24 is supplied as the existing lubrication oil in an engine pressurised by a conventional oil pump. To increase pressure in the hydraulic supply however, the normal oil pump may be replaced by a pump with increased capacity or an auxiliary pump may be provided for direct supply of fluid sometimes other than lubrication oil to the inlet port 24. The housing 12 for assembly and disassembly purposes is preferably formed into at least two parts separable or joinable at the position 12' by an connection arrangement known in the art.
The housing 12 as shown in FIG. 1 may also be constructed in any of the forms shown in FIGS. 13 to 15. In FIG. 13, the housing 12 includes a top part 12a and a bottom part 12b defining the annular wall 16, the part 12a having an internal shoulder 48 against which the part 12b abuts. Preferably the parts 12a and 12b are pressed and held together by any suitable mounting means or clamp securing the housing to the engine head 13. In FIG. 14, the housing 12 is in one part however the annular wall 16 is of washer-shaped form and held against the shoulder 48 by a circlip 49 or like connector. In FIG. 15, the housing 12 is again in two parts 12a and 12b with the annular wall 16 in this embodiment being a separate washer like part held against the shoulder 48 by the housing part 12b.
In the embodiment of FIGS. 16A and 16B, the actuator is arranged within the head 13 of a engine and like parts of the actuator of FIG. 1 have been given like numerals in FIGS. 16 and 17. The housing 12 in both instance may be split longitudinally to facilitate assembly and disassembly of the unit and its placement within the head 13. In FIG. 16A, the housing 12 is placed into the head 13 from the lower side being located within a stepped bore 13' within the head 13 to mate therewith and be held in place by a circlip 13". In the arrangement of FIG. 16B, the housing 12 is inserted into the bore 13' from the top side of the head 13 to be again held in position by the circlip 13". In either case the housing 12 may be split as at 12' and 12" to facilitate assembly.
FIGS. 24 and 25 illustrate an alternative form of actuator 82 coupled to a fuel injector 83, the actuator 82 in this instance being of the same form as that shown in FIG. 1 operating in double acting mode and in the same fashion as described in FIGS. 2 to 6. In the arrangement of FIG. 24, the slide valve member 84 is controlled by a solenoid 79 as described previously however alternatively and as shown in FIG. 25, the slide valve member 84 may be reciprocated by a rotatable cam 85 to cause opposite reciprocating movement of the piston assembly 86 of the actuator 82. So as to enable assembly and disassembly of the actuator 82, the chamber housing 87 is suitably split at 88 to enable the piston assembly 86 to be removed from the housing 87. The split 88 may be defined by a threaded connection or any other suitable sealed connection.
In the embodiment of FIGS. 24 and 25, the fluid vented from the actuator at 89 freely mixes with the lubrication fluid or oil of the engine. However, to isolate the actuator operating fluid, the actuator 82 may be modified as shown in FIG. 26 for use say in situations where the injector is located externally of the engine. In this instance two further chambers 90 and 91 are provided within the housing 87 to act as vent chambers for the collection of vented operating fluid. These chambers 90 and 91 are provided with respective outlet ports 92 and 93 which may be interconnected with a manifold and isolate the fluid returning to drain from cross contamination or loss when recycling. Again the housing 87 is split, in this instance at three positions 88, 88a and 88b to facilitate assembly and disassembly of the actuator.
The slide valve member 84 in the above embodiments and where a cam 85 is used to control its reciprocation may include an end cap or shim 94 which may be made of varying thickness for varying the clearance/stroke of the valve member 84. Alternatively, this of course can be achieved through variations of the profile of the cam 85.
Referring now to FIG. 27 there is illustrated an application of the actuator of the invention to the extraction of energy from a reciprocating piston. As shown schematically a piston 95 reciprocates in a cylinder 96 of an internal combustion engine which may comprise a spark ignition engine or a compression ignition engine and be operated either as a four cycle or two cycle engine and for this purpose incorporates means for the supply of fuel and the removal of exhaust products.
Mounted in line with the cylinder 96 but separated therefrom by a partition 97 is a housing 98 which defines a cylindrical operating chamber 99 and a vent chamber 100 separated by a wall 101. Mounted within the housing 98 is a piston assembly 102 which includes a hollow tubular piston rod or sleeve 103 having mounted thereon or formed integrally therewith a pair of pistons 104 and 105 which are arranged for reciprocation within the chamber 99 and divide the chamber 99 into a supply section 106 between the pistons 104 and 105 and opposite end sections 107 and 108 between the piston 104 and wall 101, and piston 105 and a further end wall 109 of the housing 98. The sleeve 103 includes a series of ports 110, 111, 112, 113 and 114 which communicate with the internal bore 115 thereof. The chamber 106 includes a port 116 for the supply of hydraulic fluid whilst a further port 117 communicates with the chamber 100 for venting fluid therefrom.
Located with in the bore 115 is a slide valve member 118 arranged for reciprocation within the bore 115 and including spaced lands 119, 120 and 121 separated by annular grooves 122 and 123. A return spring 124 is located within the bore 115 to engage the slide valve 118, the latter being centrally bored at 125 to define a vent terminating in a port 126 for venting the end of the bore 115 so as to permit spring operation.
The end of the slide valve 118 may be fitted with an end cap 127 which serves for clearance adjustment as a cam follower for engagement with a rotatable cam 128 on a cam shaft 129. The piston assembly 102 is coupled to the piston 95 for movement therewith.
In use and assuming the piston 95 is at the lower end of its stroke within the cylinder 96 as shown in FIG. 28 and that the engine of which the cylinder 96 is a part is a four cycle engine, the cam shaft 129 is rotated so that the cam 128 moves the slide valve member 118 within the bore 115 so that hydraulic fluid is supplied through the port 116 to pass into the chamber 106, port 112, groove 122 and port 111 into the chamber 108. This will cause the piston assembly 102 to be driven upwardly because the fluid acts between the piston 105 and end wall 109. At the same time fluid in the chamber 107 is vented through port 113, groove 123, port 114 and chamber 100 into the vent port 117. The piston 95 will thus be driven upwardly compressing the charge which has been supplied into the cylinder 96.
Ignition of the charge within the cylinder 96 drives the piston 95 and the coupled piston assembly 102 downwardly from the top position as shown on the right hand side of FIG. 28, whilst at the same time the cam 128 has advanced the slide valve 118 thereby closing communication between the supply port 116 and chamber 108 and causing fluid in that chamber to be forced out upon downward movement of the piston 95 through the port 111, groove 122 and port 110 where it is directed to do useful work for example for driving an hydraulic motor and thence return to a reservoir to be stored for future use. At the same time communication is opened between the port 116 and chamber 107 so that hydraulic fluid is admitted thereto.
Movement of the slide valve member 118 again by the cam 128 as shown on the left hand side of FIG. 29 again causes fluid to be admitted to the chamber 108 so that the piston assembly 102 is displaced upwardly causing the piston 95 to rise in cylinder 96 thereby causing exhaust gases therein to be discharged through an exhaust valve of the cylinder 96 in conventional fashion. At the same time, the valve 118 opens communication between the chamber 107 and chamber 100 so that hydraulic fluid is forced from chamber 107 and through the outlet port 117 where again it may be directed to do useful work.
Movement of the cam 128 then causes movement of the slide valve 118 to be reversed so that again fluid is directed from the chamber 106 into the chamber 107 whilst chamber 108 is vented through the port 110. This causes the piston assembly 102 to retract as shown on the right hand side of FIG. 29 carrying with it the piston 95 which serves to draw in through the inlet valve of the cylinder 96 a fresh cylinder charge.
A plurality of cylinders 96 and associated actuators may be arranged as shown in FIG. 30 with the outlets ports 110 being connected via one way valves 130 to a high pressure gallery 131 for supplying hydraulic fluid for driving a pump or other load. The slide valve member 118 is provided with a bore 132 stepped at 133 and located within the bore 132 is a secondary slide valve member 134 which operates against a return spring 135 interposed between one end of the valve 134 and the step 133.
The slide valve member 134 normally reciprocates in unison with the slide valve member 118 under the influence of the cam 128. A port 137 is provided in the slide valve member 118 for communication with the bore 132 with communication of the port 137 with the bore 132 being controlled by the slide valve member 134. The slide valve member 134 is also centrally bored at 138, this bore comprising a fluid passageway normally venting the main spring chamber of the slide valve member 118 and also comprising a passageway for venting fluid from the chamber 108.
The slide valve member 134 as shown in FIGS. 32 may be provided with channels 139 for discharge of hydraulic fluid from the bore 138, these channels communicating with channels 140 formed in the lower end of the slide valve 118. Alternatively or additionally, the cam 128 may be formed with an annular groove 141 communicating with the bore 138 for discharge of hydraulic fluid.
In the event of a misfire, the non-return valve 130 associated with the misfiring cylinder 96 isolates the misfiring cylinder from the high pressure gallery 131. Fluid pressure however is maintained in the chamber section 108 with this pressure being insufficient to overcome the pressure in the gallery 31 and cause the valve 130 to open, and thus the piston 95 will be unable to return from its top position after having been moved to that position by the piston assembly 102. The cam 128 however will continue rotating so that the slide valve member 134 under the urging of the spring-135 opens the port 137 so that fluid may drain therefrom through the bore 138 and either through the groove 141 or ports 139 and 140. This will permit the piston 95 to return to a lower position for the next upward stroke.
In the arrangement described above, the piston 95 undergoes a conventional four stroke cycle however it may readily be adapted for undergoing a two stroke cycle by providing appropriate exhaust ports in the cylinder 96. Furthermore, rather than extracting the hydraulic discharge for performing work, the hydraulic discharge may be utilised for the supply of auxiliary power and operation of the pistons only whilst the power to do useful work is extracted from the discharge gases of combustion by their passage through for example a turbine. In this form, the engine will be working in a form equivalent to a free piston engine without the disadvantages associated therewith.
Referring now to FIG. 34, there is illustrated an arrangement for varying the compression ratio in a cylinder In the embodiment illustrated, the cam shaft 129 carries cams 128 for operating slide valves members 118 through the extended stems 118', the cams 128 being rotatably supported via bearings 142 on the shaft 129 but which may be engaged for rotational movement with the shaft 129 by means of indexing clutch assemblies 143 such as a dog clutch which may be selectively engaged or disengaged by means of any suitable actuator such as an hydraulic ram or other device actuated by hydraulic pressure. As shown the shaft 129 is supported in bearings 144 in a frame 145, the latter being supported for adjustable movement in a vertical direction by means of, for example, a ram 146. Extension of the ram 146 will cause elevation of the frame 145 so as to cause raising of the piston assembly 102 and piston 95 within the cylinder 96 thereby resulting in a cylinder which has the same working stroke but a higher compression ratio when the piston 95 is reciprocated. Alternatively, retraction of the ram 146 will cause lowering of the compression ratio.
In the arrangement of FIG. 35, the cam shaft 129 is offset from operating stems 118' for the slide valves members 118 and again the cams 128 may be selectively engaged by the clutches 143. Reciprocatory movement of the slide valves 118 occurs via bell cranks 146, the latter being pivotally mounted at 147 on eccentrics 148. Rotation of the eccentrics will cause displacement of the pivotal mounts 147 of the bell cranks altering the ratios of leverage and thus the amount of movement transmitted to the valve stems 118' upon rotation of the cams 128. This arrangement thus permits selective alteration of the stroke and compression ratio of the piston 95 within the cylinder 96.
In FIG. 36, the shaft 129 is supported rotatably via bearings 149 and eccentrically on respective spaced eccentric members 150, the latter being mounted rotatably in the engine frame. Again indexing clutches 143 are employed to enable selective engagement of the cams 128 with the shaft 129. The eccentric members 150 are externally threaded at 151 and engaged by respective screw threaded spindles 152, the latter of which may be coupled via gearboxes 153 to a single adjustment shaft 154. Rotation of the shaft 154 will be transferred into rotation of the spindles 152 and thus rotation of the members 150 thereby altering the position of the shaft 129 relative to the valve stems 118'. This thereby serves to vary the stroke of the piston 95 and the compression ratio. In each of the above arrangements, selected cylinders may be isolated in the case of damage by simply disengaging the indexing 143 whilst continuing to operate the engine.
The cams 128 may alternatively be fixedly mounted to the shaft 129 or formed integrally with the shaft 129 so as to always rotate with the shaft and be carried in bearings about the shaft rigidly mounted to the engine frame. Alternatively, the shaft may be mounted as described in FIGS. 34, FIG. 35 or FIG. 36.
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EdwardsCRDM Divert ValveEP1174594A1 *Feb 23, 2001Jan 23, 2002International Truck and Engine CorporationHydraulically-assisted engine valve actuatorEP1253297A1 *Apr 25, 2001Oct 30, 2002International Engine Intellectual Property Company, LLC.Hydraulically-assisted engine valve actuatorWO2009004116A1 *Jul 2, 2008Jan 8, 2009Wärtsilä Finland OyHydraulic actuator* Cited by examinerClassifications U.S. Classification123/90.12, 251/63.5, 92/175, 239/585.1, 123/197.1, 251/30.04, 239/533.3International ClassificationF02M57/02, F01L9/02, B06B1/18, F02M59/10, F01L9/04, F02B3/06Cooperative ClassificationF02M57/025, F02B3/06, F02M59/105, F01L9/02, F01L9/04, B06B1/183European ClassificationF01L9/02, F01L9/04, B06B1/18B, F02M59/10C, F02M57/02C2Legal EventsDateCodeEventDescriptionAug 21, 1997FPAYFee paymentYear of fee payment: 4Sep 18, 2001REMIMaintenance fee reminder mailedFeb 22, 2002FPAYFee paymentYear of fee payment: 8Feb 22, 2002SULPSurcharge for late paymentYear of fee payment: 7Sep 7, 2005REMIMaintenance fee reminder mailedFeb 22, 2006SULPSurcharge for late paymentYear of fee payment: 11Feb 22, 2006FPAYFee paymentYear of fee payment: 12RotateOriginal ImageGoogle Home - Sitemap - USPTO Bulk Downloads - Privacy Policy - Terms of Service - About Google Patents - Send FeedbackData provided by IFI CLAIMS Patent Services