Claims
- 1. In a multi-cylinder hot gas engine the combination comprising:
- (a) equal V-shaped engine block having two banks of cylinders wherein the cylinders in each bank have parallel equal length axial centerlines and the planes containing such centerlines intersect along or near the axis of a single crankshaft mounted for rotation in said engine block;
- (b) a piston in each cylinder connected with the crankshaft for reciprocation in said cylinder, each cylinder having an expansion space above the piston and a compression space below the piston;
- (c) an annular regenerator means disposed around each cylinder;
- (d) annular heater head means including a plurality of working fluid passageways disposed above the cylinders for supplying heated working fluid to the expansion spaces of all of the cylinders;
- (e) combustor means centrally disposed in said annular heater head means for heating the working fluid in said plurality of working fluid passageways;
- (f) a plurality of arcuate, balanced-flow manifold means one for each cylinder, each manifold means having a first arcuate portion in fluid communication with the expansion space of the cylinder and with one end of a number of working fluid passageways and having a second arcuate portion in communication with the annular regenerator means of the same cylinder and with the other end of said number of working fluid passageways and wherein the working fluid passageways thus intercommunicating within each of the plurality of arcuate manifold means are equal in number for each cylinder.
- 2. The multi-cylinder hot gas engine combination according to claim 1, wherein the respective arcuate portions of each manifold means is appropriately proportioned and shaped along the elongated arcuate axis thereof to provide substantially equal pressure drops in the working fluid across all of the working fluid paths interconnecting between the expansion space and regenerator space of each cylinder, and wherein the pressure drops in working fluid across all such fluid paths in the annular heater head means are substantially equal.
- 3. A multi-cylinder hot gas engine combination according to claim 2, further including annular cooler means disposed around each cylinder immediately under the annular regenerator means thereof.
- 4. In a multi-cylinder hot gas engine combination according to claim 3, wherein the cylinders in each V-shaped engine block are arranged in multiples of four with the cooler of one cylinder being interconnected through a working fluid passageway to a compression space of the next adjacent cylinder.
- 5. A multi-cylinder hot gas engine combination according to claim 3, further including an annular preheater circumferentially surrounding the annular heater head means and combustor for supplying preheated combustion air to the combustor and withdrawing hot combustion gases which have been passed through said plurality of working fluid passageways and extracting residual heat in the hot combustion gases for preheating the intake air being supplyed to the combustor.
- 6. A multi-cylinder hot gas engine combination according to claim 5, wherein the first arcuate portion of the plurality of arcuate, balanced-flow manifold means form an outer concentric ring of manifolds communicating with the expansion spaces of the respective cylinders and the second arcuate portions form an inner concentric ring of manifolds communicating with the annular regenerator means of the respective cylinders and the intersections of the plane of the inner and outer manifold ring with the axial extensions of the cylinder axes define the points of a parallelogram.
- 7. In a multi-cylinder hot gas engine combination according to claim 6, wherein the cylinders in each V-shaped engine block are arranged in multiples of four with the cooler of one cylinder being interconnected through a working fluid passageway to compression space of the next adjacent cylinder.
- 8. In a double-acting, multi-cylinder hot gas engine, the improvement comprising a V-shaped engine block formed by two banks of cylinders with the cylinders in each bank having parallel, equal-length axes for connecting rods to pistons reciprocatingly movable therein and with the planes of the two banks containing the axes of the cylinders intersecting along or near the axis of a single crankshaft; annular regenerator means surrounding each cylinder and defining a regenerator space; a single annular heater head means including a plurality of annularly arrayed working fluid passageways; a combustor supported within said annular heater head means for flowing hot combustion gases past the working fluid passageways for heating the working fluid therein; balanced-flow manifold means for interconnecting the working fluid passageways in said heater head means between the expansion space the regenerator space of the respective cylinders, said manifold means comprising two concentric inner and outer rings of arcuately-shaped manifold chambers with the number of arcuate manifold chambers in each ring being equal to the number of cylinders, the respective manifold chambers in one of the concentric rings communicating with a respective expansion space of one of the cylinders, and the respective manifold chambers of the other concentric ring communicating with a respective regenerator space of each cylinder; the plurality of annularly arrayed working fluid passageways being arranged in a circle around the combustor with each working fluid passageway having one end thereof communicating thru a respective manifold chamber to the expansion space of one of the cylinders and the remaining end thereof communicating thru respective manifold chamber to the regenerator space of the same cylinder; and the number of working fluid passageways thus connected to the respective expansion and regenerator spaces of each cylinder being equal to the number of working fluid passageways respectively connected to the other cylinders in the multi-cylinder engine.
- 9. The multi-cylinder hot gas engine combination according to claim 8, wherein the respective arcuate portions of each manifold means are appropriately proportioned and shaped along the elongated arcuate axis thereof to provide substantially equal pressure drops in the working fluid across all of the working fluid paths interconnecting between the expansion space and regenerator space associated with each cylinder, and wherein the pressure drops in working fluid across all of the fluid paths in the annular heater head means are substantially equal.
- 10. A multi-cylinder hot gas engine combination according to claim 9, further including annular cooler means disposed around each cylinder immediately under the annular regenerator means thereof.
- 11. In a multi-cylinder hot gas engine combination according to claim 10, wherein the cylinders in each V-shaped engine block are arranged in multiples of four with the cooler of one cylinder being interconnected through a working fluid passageway to a compression space of the next adjacent cylinder.
- 12. A multi-cylinder hot gas engine combination according to claim 10, further including an annular preheater circumferentially surrounding the annular heater head means and combustor for supplying preheated combustion air to the combustor and withdrawing hot combustion gases which have been passed through said plurality of working fluid passageways and extracting residual heat in the hot combustion gases for preheating the intake air being supplied to the combustor.
- 13. A multi-cylinder hot gas engine combination according to claim 12, wherein the first arcuate portion of the plurality of arcuate, balanced-flow manifold means form an outer concentric ring of manifolds communicating with the expansion spaces of the respective cylinders and the second arcuate portions form an inner concentric ring of manifolds communicating with the annular regenerator means of the respective cylinders.
- 14. In a multi-cylinder hot gas engine combination according to claim 13, wherein the cylinders in each V-shaped engine block are arranged in multiples of four with the cooler of one cylinder being interconnected through a working fluid passageway to a compression space of the next adjacent cylinder.
- 15. A multi-cylinder hot gas engine comprising in combination a plurality of cylinders disposed along paths forming two banks of cylinders having equal parallel axes and the planes of which form a V-shaped engine block extending from a single crankshaft, each cylinder containing a piston connected to said crankshaft in proper phase relation and dividing said cylinder into a high temperature space and a low temperature space with the low temperature space being nearer said single crankshaft; a plurality of annular regenerator-coolers each communicating between two cylinders and each disposed around a single cylinder; a plurality of working fluid passageways connecting said low temperature space of one cylinder to the cooler of the regenerator-cooler of an adjacent cylinder; a plurality of arcuately-shaped expansion space manifolds each positioned over the axial centerline of a respective cylinder or as near thereto as possible and communicating with the high temperature space of said cylinder; a plurality of arcuately-shaped regenerator manifolds one each positioned over the centerline of each of the cylinders or as near thereto as possible and communicating with the regenerator of the said cylinder; heater head means comprising a plurality of working fluid passageways disposed in a substantially uniform circular array above said cylinders and near the high temperature spaces thereof to define on top of the V-shaped engine blocks a combustion space; said working fluid passageways connecting said expansion space manifold of each cylinder to the associated regenerator manifold of the same cylinder; and a combustor unit mounted in said combustion space for uniformly heating the working fluid in all of the working fluid passageways of said heater head means.
- 16. The multi-cylinder hot gas engine according to claim 15, wherein the respective arcuate portions of each manifold means is appropriately proportioned and shaped along the elongated arcuate axis thereof to provide substantially equal pressure drops in the working fluid across all of the working fluid paths interconnected between the expansion space and the regenerator space provided for each cylinder, and wherein the pressure drops in working fluids across all of the fluid paths in the annular heater head means are substantially equal.
- 17. A multi-cylinder hot gas engine according to claim 16, wherein the arcuately-shaped expansion space manifolds are arranged in a first circular array within said heater head means and the arcuately-shaped regenerator manifolds form a second circular array within said heater head means concentrically arranged with respect to said first circular array.
- 18. A multi-cylinder hot gas engine according to claim 17, wherein the first circular array of arcuately-shaped expansion manifolds form the outer one of the concentric first and second circular arrays and wherein the axial extensions of the center axes of the cylinders intersect the planes of the concentrically-arrayed arcuately-shaped manifolds at points which define the corners of a parallelogram with two of the diagonally opposite points of the parallelogram substantially centered on two oppositely disposed manifolds within the outer first circular array of arcuately-shaped expansion manifolds and the remaining two diagonally opposite points substantially centered on the two oppositely disposed manifolds within the inner second circular array of arcuately-shaped regenerator manifolds.
- 19. A multi-cylinder hot gas engine according to claim 15, further including an annular preheater circumferentially surrounding the annular heater head means and combustor for supplying preheated combustion air to the combustor and withdrawing hot combustion gases which have been passed through said plurality of working fluid passageways and extracting residual heat in the hot combustion gases for preheating the intake combustion air being supplied to the combustor.
- 20. A multi-cylinder hot gas engine according to claim 18, further including an annular preheater circumferentially surrounding the annular heater head means and combustor for supplying preheated combustion air to the combustor and withdrawing hot combustion gases which have been passed through said plurality of working fluid passageways and extracting residual heat in the hot combustion gases for preheating the intake combustion air being supplied to the combustor.
- 21. A multi-cylinder hot gas engine according to claim 15, further including a virtual balancing axis means formed to intersect the crankshaft at or near the center of action of any force imbalance acting on the crankshaft and being proportioned to eliminate any such force imbalance while simultaneously minimizing any residual turning moment, said balancing means comprising appropriately sized, imbalance-correcting, eccentric weights non-concentrically mounted for rotation on substantially diametrically opposite sides of the axis of rotation of said crankshaft and coupled thereto for rotation in a direction opposite the direction of rotation of the crankshaft, said eccentric weights being further disposed at preselected distances toward opposite ends of said crankshaft from said center of action.
- 22. A multi-cylinder hot gas engine according to clam 21, wherein the crankshaft initially has been partially balanced by the provision of eccentrically mounted weights secured to and rotating with the crankshaft in a known manner.
- 23. A multi-cylinder hot gas engine according to claim 21, wherein the counter-rotating residual imbalance correcting eccentric weights are disposed along the virtual balancing shaft axis at preselected distances away from the center of action of the imbalance force acting on the crankshaft in order to reduce to a minimum any residual turning moment.
- 24. A multi-cylinder hot gas engine according to claim 22, wherein the imbalance-correcting, eccentric weights are rotated at the same speed of rotation as the crankshaft but in a direction opposite the direction of crankshaft rotation and are disposed along the virtual balancing shaft axis a preselected distance away from the center of action of the imbalance force acting on the crankshaft in order to reduce to a minimum any residual turning moment.
- 25. A multi-cylinder hot gas engine according to claim 24, wherein the imbalance-correcting, eccentric weights are coupled to the crankshaft by separate sets of driving and driven gear wheels with the imbalance-correcting, eccentric weights being carried by to the driven gear wheels.
- 26. A multi-cylinder hot gas engine according to claim 25, wherein the driven rotating gear wheels carrying the imbalance-correcting, eccentric weights also serve to drive auxiliary equipment required in the running of the reciprocating piston and crankshaft machine on which the virtual balancing axis arrangement is formed.
- 27. The multi-cylinder hot gas engine recited in claim 23, wherein the imbalance-correcting eccentric weights are carried by the working members of auxiliary devices already required for the engine.
- 28. The multi-cylinder hot gas engine recited in claim 23, wherein the imbalance-correcting eccentric weights are provided by the working members of auxiliary devices already required for the engine.
- 29. A multi-cylinder hot gas engine according to claim 20, further including a virtual balancing axis means formed to intersect the crankshaft at or near the center of any force imbalance acting on the crankshaft and being proportioned to eliminate any such force imbalance while simultaneously minimizing any residual turning moment, said virtual balancing axis means comprising appropriately-sized, imbalance-correcting, eccentric weights, non-concentrically mounted for rotating on substantially diametrically opposite sides of the axis of rotation of the crankshaft and coupled thereto for rotation at the same speed but in a direction opposite that of said crankshaft, thereby creating a virtual balancing axis which passes through the center of rotation of the eccentric weights and through the center of action of the force imbalance acting on the crankshaft or as near thereto as possible.
- 30. A multi-cylinder hot gas engine according to claim 29, wherein the crankshaft initially has been partially balanced by the provision of eccentrically mounted weights secured to and rotating with the crankshaft in a known manner.
- 31. A multi-cylinder hot gas engine according to claim 30, wherein the imbalance-correcting, eccentric weights are rotated at the same speed of rotation as the crankshaft but in a direction opposite thereto and are disposed along the virtual balancing axis a preselected distance away from the center of action of the imbalance force acting on the crankshaft in order to reduce to a minimum any residual turning moment.
- 32. A multi-cylinder hot gas engine according to claim 31, wherein the imbalance-correcting, eccentric weights are coupled to the crankshaft by separate sets of driving and driven gear wheels with the imbalance-correcting, eccentric weights being carried by the driven gear wheels.
- 33. A multi-cylinder hot gas engine according to claim 32, wherein the driven gear wheels carrying the imbalance-correcting, eccentric weights also serve to drive auxiliary equipment required in the running of the piston and crankshaft machine on which the virtual balancing axis means is formed.
Government Interests
The Government of the United States of America has rights in this invention pursuant to Contract DEN3-32 awarded by the U.S. Department of Energy.
US Referenced Citations (5)