Multi-phase centrifugal supercharging air induction system
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02B-033/00
F02B-033/44
F04B-017/00
F01D-025/04
F01D-025/00
F16H-003/72
F16H-003/44
출원번호
US-0710797
(2004-08-03)
발명자
/ 주소
Jones,Daniel W.
Carlson,Michael A.
출원인 / 주소
Accessible Technologies, Inc.
대리인 / 주소
Hovey Williams LLP
인용정보
피인용 횟수 :
4인용 특허 :
29
초록▼
A multi-phase centrifugal supercharging system (10) configured for supplying compressed induction fluid to an engine (E) is disclosed. The air induction system (10) broadly includes a drive assembly (12) powered by the engine (E), a supercharging assembly (14) driven by the drive assembly (12) to co
A multi-phase centrifugal supercharging system (10) configured for supplying compressed induction fluid to an engine (E) is disclosed. The air induction system (10) broadly includes a drive assembly (12) powered by the engine (E), a supercharging assembly (14) driven by the drive assembly (12) to compress induction fluid, and an induction fluid flow control assembly (16) in communication with the supercharging assembly (14) to control operation of the supercharging assembly (14) and cooperating therewith to deliver the compressed induction fluid to the intake manifold (IM) of the engine (E). The supercharging assembly (14) includes a pair of centrifugal superchargers (28 and 30) that are phased by the control assembly (16) between multiple operating phases, including a series phase (172) and a parallel phase (176), to supply constant target boost to the intake (IM) over the entire rev range of the engine (E).
대표청구항▼
The invention claimed is: 1. A method of supplying compressed induction fluid to an intake manifold of an internal combustion engine of a powered land vehicle, wherein the engine includes a rotatable crankshaft and, when off idle, operates at variable rpm over a rev range, said method comprising th
The invention claimed is: 1. A method of supplying compressed induction fluid to an intake manifold of an internal combustion engine of a powered land vehicle, wherein the engine includes a rotatable crankshaft and, when off idle, operates at variable rpm over a rev range, said method comprising the steps of: (a) driving a first supercharger by the crankshaft to compress induction fluid; (b) driving a second supercharger by the crankshaft to compress induction fluid; (c) operating the superchargers at least partially in series so that at least some induction fluid that is compressed by the first supercharger is further compressed by the second supercharger and then supplied to the intake manifold of the engine; and (d) operating the superchargers at least partially in parallel so that at least a portion of induction fluid is compressed by the first supercharger and at least another portion of induction fluid is compressed by the second supercharger and the at least a portion and at least another portion of compressed induction fluid are supplied to the intake manifold of the engine without passing through the other supercharger, said driving steps of (a) and (b) each being performed so that both superchargers are continuously operated by the crankshaft at a substantially constant relative speed to the crankshaft speed during the operating steps of (c) and (d). 2. The method as claimed in claim 1, step (d) being performed after step (c) so that operation of the superchargers phases from at least partially in series to at least partially in parallel in response to a predetermined condition; and (e) switching operation of the superchargers to substantially fully parallel in response to a second predetermined condition so that at least a portion of induction fluid is compressed by the first supercharger and at least another portion of induction fluid is compressed by the second supercharger and the at least a portion and at least another portion of compressed induction fluid are supplied to the intake manifold of the engine without passing through the other supercharger wherein said at least a portion and said at least another portion of induction fluid comprise substantially all induction fluid supplied to the intake manifold of the engine. 3. The method as claimed in claim 1, steps (a) and (b) including the common step of intermeshing a common gear between the superchargers. 4. The method as claimed in claim 1, steps (a) and (b) including the common step of intermeshing a common gear between the superchargers, steps (a) and (b) further including the common steps of entraining an endless element around at least a portion of the crankshaft and driving the common gear at least in part with the endless element. 5. The method as claimed in claim 1, steps (c) and (d) each including the step of operating both superchargers so that each supercharger compresses at least some induction fluid that is supplied to the intake manifold of the engine whenever the crankshaft is rotating. 6. The method as claimed in claim 5, steps (c) and (d) each further including the step of delivering substantially all of the induction fluid compressed by the superchargers to the intake manifold. 7. The method as claimed in claim 1, step (c) including the step of operating the superchargers substantially fully in series so that substantially all induction fluid that is compressed by the first supercharger is further compressed by the second supercharger and then supplied to the intake manifold of the engine. 8. The method as claimed in claim 1; and (e) housing both superchargers substantially within a case. 9. The method as claimed in claim 1; and (c) intercommunicating the first and second superchargers and the intake manifold, step (e) including the steps of fluidly communicating the first and second superchargers with a serial passageway and disposing a first valve along the serial passageway for controlling the flow of induction fluid there through. 10. The method as claimed in claim 9, step (c) including the step of shifting the first valve into an open position wherein induction fluid is permitted to flow through said serial passageway. 11. The method as claimed in claim 9, step (d) including the step of shifting the first valve into a closed position wherein induction fluid is prevented from flowing through said serial passageway. 12. A method of supplying compressed induction fluid to an intake manifold of an internal combustion engine of a powered land vehicle, wherein the engine includes a rotatable crankshaft and, when off idle, operates at variable rpm over a rev range, said method comprising the steps of: (a) driving a first supercharger off of the crankshaft to compress induction fluid; (b) driving a second supercharger off of the crankshaft to compress induction fluid; (c) operating the superchargers at least partially in series so that at least some induction fluid that is compressed by the first supercharger is further compressed by the second supercharger and then supplied to the intake manifold of the engine; and (d) operating the superchargers at least partially in parallel so that at least a portion of induction fluid is compressed by the first supercharger and at least another portion of induction fluid is compressed by the second supercharger and the at least a portion and at least another portion of compressed induction fluid are supplied to the intake manifold of the engine without passing through the other supercharger, step (d) being performed after step (c) so that operation of the superchargers phases from at least partially in series to at least partially in parallel in response to a predetermined condition, said predetermined condition comprising the engine rpm being greater than about seventy percent of rev range. 13. A method of supplying compressed induction fluid to an intake manifold of an internal combustion engine of a powered land vehicle, wherein the engine includes a rotatable crankshaft and, when off idle, operates at variable rpm over a rev range, said method comprising the steps of: (a) driving a first supercharger off of the crankshaft to compress induction fluid; (b) driving a second supercharger off of the crankshaft to compress induction fluid; (c) operating the superchargers at least partially in series so that at least some induction fluid that is compressed by the first supercharger is further compressed by the second supercharger and then supplied to the intake manifold of the engine; and (d) operating the superchargers at least partially in parallel so that at least a portion of induction fluid is compressed by the first supercharger and at least another portion of induction fluid is compressed by the second supercharger and the at least a portion and at least another portion of compressed induction fluid are supplied to the intake manifold of the engine without passing through the other supercharger, step (d) being performed after step (c) so that operation of the superchargers phases from at least partially in series to at least partially in parallel in response to a predetermined condition; and (e) switching operation of the superchargers to substantially fully parallel in response to a second predetermined condition so that at least a portion of induction fluid is compressed by the first supercharger and at least another portion of induction fluid is compressed by the second supercharger and the at least a portion and at least another portion of compressed induction fluid are supplied to the intake manifold of the engine without passing through the other supercharger wherein said at least a portion and said at least another portion of induction fluid comprise substantially all induction fluid supplied to the intake manifold of the engine, said second predetermined condition comprising the engine rpm being about eighty percent of rev range or higher. 14. A method of supplying compressed induction fluid to an intake manifold of an internal combustion engine of a powered land vehicle, wherein the engine includes a rotatable crankshaft and, when off idle, operates at variable rpm over a rev range, said method comprising the steps of: (a) driving a first supercharger off of the crankshaft to compress induction fluid; (b) driving a second supercharger off of the crankshaft to compress induction fluid; (c) operating the superchargers at least partially in series so that at least some induction fluid that is compressed by the first supercharger is further compressed by the second supercharger and then supplied to the intake manifold of the engine; and (d) operating the superchargers at least partially in parallel so that at least a portion of induction fluid is compressed by the first supercharger and at least another portion of induction fluid is compressed by the second supercharger and the at least a portion and at least another portion of compressed induction fluid are supplied to the intake manifold of the engine without passing through the other supercharger, (e) intercommunicating the first and second superchargers and the intake manifold, step (c) including the steps of fluidly communicating the first and second superchargers with a serial passageway and disposing a first valve along the serial passageway for controlling the flow of induction fluid there through, step (e) including the steps of fluidly communicating the first supercharger and the intake manifold with an additional passageway and disposing a second valve along the additional passageway for controlling the flow of induction fluid there through. 15. The method as claimed in claim 14, step (c) including the step of shifting the second valve into a closed position wherein induction fluid is prevented from flowing through said additional passageway. 16. The method as claimed in claim 14, step (d) including the step of shifting the second valve into an open position wherein induction fluid is permitted to flow through said additional passageway. 17. The method as claimed in claim 14, step (e) including the steps of fluidly communicating the second supercharger and the atmosphere with a parallel passageway and disposing a third valve along the parallel passageway for controlling the flow of induction fluid there through. 18. The method as claimed in claim 17, step (c) including the step of shifting the third valve into a closed position wherein induction fluid is prevented from flowing through said parallel passageway. 19. The method as claimed in claim 18, step (d) including the step of shifting the third valve into an open position wherein induction fluid is permitted to flow through the parallel passageway. 20. The method as claimed in claim 17, step (e) including the step of fluidly communicating the atmosphere, the first supercharger, and the parallel passageway with an inlet passageway and disposing a fourth valve along said inlet passageway for controlling the flow of induction fluid there through. 21. The method as claimed in claim 20; and (f) shifting the fourth valve into a partially closed position wherein at least some induction fluid is prevented from flowing through said inlet passageway. 22. A multiphase centrifugal supercharging air induction system for supplying compressed induction fluid to an intake manifold of an internal combustion engine wherein the engine includes a rotatable crankshaft, said induction system comprising: a first centrifugal supercharger drivingly connectable to the crankshaft and operable to compress induction fluid for the engine, said first supercharger including a first inlet, a spaced first outlet, and a first rotatable impeller fluidly between the first inlet and first outlet to compress induction fluid; a second centrifugal supercharger drivingly connectable to the crankshaft and operable to compress induction fluid for the engine, said second supercharger including a second inlet, a spaced second outlet, and a second rotatable impeller fluidly between the second inlet and second outlet to compress induction fluid; and an induction fluid flow control assembly fluidly intercommunicating the superchargers so that the superchargers cooperatively provide induction fluid to the engine in a number of operating phases, including a first phase in which at least some induction fluid from the first outlet is supplied to the second inlet and a second phase in which at least some induction fluid from the first and second outlets is supplied to the intake manifold without passing through the other supercharger, said first and second superchargers being drivingly connectable to the crankshaft wherein both of the impellers are rotated continuously by the crankshaft and at a substantially constant relative speed to the crankshaft speed during the operating phases of the superchargers. 23. The system as claimed in claim 22; and a drive assembly operable to drivingly connect the superchargers to the crankshaft. 24. The system as claimed in claim 23, said first and second impellers each being operable to compress induction fluid for the engine when rotated, said first and second superchargers including a transmission drivingly connecting the impellers to the drive assembly, said transmission cooperating with the drive assembly to maintain rotation of the impellers at the substantially constant speed relative to the rotation of the crankshaft. 25. The system as claimed in claim 24, said transmission including a plurality of intermeshing gears with at least one of said gears being common to both superchargers. 26. The system as claimed in claim 22, said induction fluid flow control assembly fluidly intercommunicating the superchargers so that in all operating phases both superchargers compress at least some induction fluid for the engine whenever the crankshaft is rotating. 27. The system as claimed in claim 26, said induction fluid flow control assembly being operable to fluidly intercommunicate the superchargers with the intake manifold so that in all operating phases substantially all of the induction fluid compressed by each of the superchargers is delivered to the intake manifold. 28. The system as claimed in claim 22, said first phase including a series phase in which substantially all induction fluid from the first outlet is supplied to the second inlet. 29. The system as claimed in claim 28, said first phase further including a first transition phase, said induction fluid flow control assembly being configured to switch operation of the superchargers from the series phase to the first transition phase in response to a predetermined condition. 30. The system as claimed in claim 22, said second phase including a parallel phase in which substantially all induction fluid from the first and second outlets is supplied directly to the intake manifold. 31. The system as claimed in claim 30, said second phase further including a second transition phase, said induction fluid flow control assembly being configured to switch operation of the superchargers from the second transition phase to the parallel phase in response to a predetermined condition. 32. The system as claimed in claim 22; and a case presenting a compression chamber and a transmission chamber, said first and second superchargers being at least partially housed within said compression chamber. 33. The system as claimed in claim 22, said induction fluid flow control assembly including a passageway fluidly communicating said first outlet and said second inlet, said induction fluid flow control assembly further including a first valve disposed along said passageway for controlling the flow of induction fluid there through. 34. The system as claimed in claim 33, said first valve shiftable between an open position wherein induction fluid is permitted to flow through said passageway and a closed position wherein induction fluid is prevented from flowing through said passageway, said first valve shiftable into a plurality of intermediate positions between said open and closed positions wherein the quantity of induction fluid allowed to flow through the passageway varies from one intermediate position to another. 35. A multiphase centrifugal supercharging air induction system for supplying compressed induction fluid to an intake manifold of an internal combustion engine wherein the engine includes a rotatable crankshaft, said induction system comprising: a first centrifugal supercharger drivingly connectable to the crankshaft and operable to compress induction fluid for the engine, said first supercharger including a first inlet, a spaced first outlet, and a first impeller fluidly between the first inlet and first outlet to compress induction fluid; a second centrifugal supercharger drivingly connectable to the crankshaft and operable to compress induction fluid for the engine, said second supercharger including a second inlet, a spaced second outlet, and a second impeller fluidly between the second inlet and second outlet to compress induction fluid; and an induction fluid flow control assembly fluidly intercommunicating the superchargers so that the superchargers cooperatively provide induction fluid to the engine in a number of operating phases, including a first phase in which at least some induction fluid from the first outlet is supplied to the second inlet and a second phase in which at least some induction fluid from the first and second outlets is supplied to the intake manifold without passing through the other supercharger, a drive assembly operable to drivingly connect the superchargers to the crankshaft so that each of the superchargers operates continuously with rotation of the crankshaft, said first and second impellers being rotatable, each being operable to compress induction fluid for the engine when rotated, said first and second superchargers including a transmission drivingly connecting the impellers to the drive assembly, said transmission cooperating with the drive assembly to maintain rotation of the impellers at a substantially constant ratio relative to the rotation of the crankshaft, said transmission including a plurality of intermeshing gears with at least one of said gears being common to both superchargers, said transmission including a common rotatable transmission shaft coupled to said common gear, said drive assembly including an endless element entraining at least a portion of said common shaft and being operable to entrain at least a portion of the crankshaft. 36. A multiphase centrifugal supercharging air induction system for supplying compressed induction fluid to an intake manifold of an internal combustion engine wherein the engine includes a rotatable crankshaft, said induction system comprising: a first centrifugal supercharger drivingly connectable to the crankshaft and operable to compress induction fluid for the engine, said first supercharger including a first inlet, a spaced first outlet, and a first impeller fluidly between the first inlet and first outlet to compress induction fluid; a second centrifugal supercharger drivingly connectable to the crankshaft and operable to compress induction fluid for the engine, said second supercharger including a second inlet, a spaced second outlet, and a second impeller fluidly between the second inlet and second outlet to compress induction fluid; and an induction fluid flow control assembly fluidly intercommunicating the superchargers so that the superchargers cooperatively provide induction fluid to the engine in a number of operating phases, including a first phase in which at least some induction fluid from the first outlet is supplied to the second inlet and a second phase in which at least some induction fluid from the first and second outlets is supplied to the intake manifold without passing through the other supercharger, said first phase including a series phase in which substantially all induction fluid from the first outlet is supplied to the second inlet, said first phase further including a first transition phase, said induction fluid flow control assembly being configured to switch operation of the superchargers from the series phase to the first transition phase in response to a predetermined condition, said predetermined condition being the relative rotational speed of the crankshaft measured in engine rpm relative to the maximum rotational speed of the crankshaft, said relative rotational speed being between about sixty and about seventy percent of the maximum rotational speed. 37. A multiphase centrifugal supercharging air induction system for supplying compressed induction fluid to an intake manifold of an internal combustion engine wherein the engine includes a rotatable crankshaft, said induction system comprising: a first centrifugal supercharger drivingly connectable to the crankshaft and operable to compress induction fluid for the engine, said first supercharger including a first inlet, a spaced first outlet, and a first impeller fluidly between the first inlet and first outlet to compress induction fluid; a second centrifugal supercharger drivingly connectable to the crankshaft and operable to compress induction fluid for the engine, said second supercharger including a second inlet, a spaced second outlet, and a second impeller fluidly between the second inlet and second outlet to compress induction fluid; and an induction fluid flow control assembly fluidly intercommunicating the superchargers so that the superchargers cooperatively provide induction fluid to the engine in a number of operating phases, including a first phase in which at least some induction fluid from the first outlet is supplied to the second inlet and a second phase in which at least some induction fluid from the first and second outlets is supplied to the intake manifold without passing through the other supercharger, said second phase including a parallel phase in which substantially all induction fluid from the first and second outlets is supplied directly to the intake manifold, said second phase further including a second transition phase, said induction fluid flow control assembly being configured to switch operation of the superchargers from the second transition phase to the parallel phase in response to a predetermined condition, said predetermined condition being the relative rotational speed of the crankshaft measured in engine rpm relative to the maximum rotational speed of the crankshaft, said relative rotational speed being about eighty percent of the maximum rotational speed. 38. A multiphase centrifugal supercharging air induction system for supplying compressed induction fluid to an intake manifold of an internal combustion engine wherein the engine includes a rotatable crankshaft, said induction system comprising: a first centrifugal supercharger drivingly connectable to the crankshaft and operable to compress induction fluid for the engine, said first supercharger including a first inlet, a spaced first outlet, and a first impeller fluidly between the first inlet and first outlet to compress induction fluid; a second centrifugal supercharger drivingly connectable to the crankshaft and operable to compress induction fluid for the engine, said second supercharger including a second inlet, a spaced second outlet, and a second impeller fluidly between the second inlet and second outlet to compress induction fluid; and an induction fluid flow control assembly fluidly intercommunicating the superchargers so that the superchargers cooperatively provide induction fluid to the engine in a number of operating phases, including a first phase in which at least some induction fluid from the first outlet is supplied to the second inlet and a second phase in which at least some induction fluid from the first and second outlets is supplied to the intake manifold without passing through the other supercharger, said induction fluid flow control assembly including a passageway fluidly communicating said first outlet and said second inlet, said induction fluid flow control assembly further including a first valve disposed along said passageway for controlling the flow of induction fluid there through, said induction fluid flow control assembly including an additional passageway in fluid communication with said first outlet and operable to be in fluid communication with the intake manifold, said induction fluid flow control assembly further including a second valve disposed along said additional passageway downstream of said first-mentioned passageway for controlling the flow of induction fluid through said additional passageway. 39. The system as claimed in claim 38, said second valve shiftable between an open position wherein induction fluid is permitted to flow through said additional passageway and a closed position wherein induction fluid is prevented from flowing through said additional passageway. 40. The system as claimed in claim 38, said induction fluid flow control assembly including a second additional passageway in fluid communication with said second inlet, said induction fluid flow control assembly further including a third valve disposed along said second additional passageway upstream of said first-mentioned passageway for controlling the flow of induction fluid through said second additional passageway. 41. The system as claimed in claim 40, said third valve shiftable between an open position wherein induction fluid is permitted to flow through said second additional passageway and a closed position wherein induction fluid is prevented from flowing through said second additional passageway. 42. The system as claimed in claim 40; and a case presenting a compression chamber and a transmission chamber, said first and second superchargers and said induction fluid flow control assembly being at least partially housed within said compression chamber, said compression chamber presenting a case inlet in fluid communication with the atmosphere. 43. The system as claimed in claim 42, said induction fluid flow control assembly including a third additional passageway fluidly communicating the case inlet with said first inlet and fluidly communicating the case inlet with said second additional passageway, said induction fluid flow control assembly further including a fourth valve disposed along said third additional passageway for controlling the flow of induction fluid there through. 44. The system as claimed in claim 43, said fourth valve shiftable between an open position wherein induction fluid is permitted to flow through said third additional passageway and a partially closed position wherein at least some induction fluid is prevented from flowing through said third additional passageway. 45. In a powered land vehicle including an internal combustion engine having an intake manifold and a rotatable crankshaft, an improved air induction system comprising: a first centrifugal supercharger drivingly connected to the crankshaft for compressing induction fluid for the engine, said first supercharger including a first inlet, a spaced first outlet, and a first rotatable impeller fluidly between the first inlet and first outlet to compress induction fluid; a second centrifugal supercharger drivingly connected to the crankshaft for compressing induction fluid for the engine, said second supercharger including a second inlet, a spaced second outlet, and a second rotatable impeller fluidly between the second inlet and second outlet to compress induction fluid; and an induction fluid flow control assembly fluidly intercommunicating the superchargers so that the superchargers cooperatively provide induction fluid to the engine in a number of operating phases, including a first phase in which at least some induction fluid from the first outlet is supplied to the second inlet and a second phase in which at least some induction fluid from the first and second outlets is supplied to the intake manifold without passing through the other supercharger, said first and second superchargers being drivingly connected to the crankshaft wherein both of the impellers are rotated continuously by the crankshaft and at a substantially constant relative speed to the crankshaft speed during the operating phases of the superchargers. 46. In a powered vehicle as claimed in claim 45; and a drive assembly drivingly connecting the superchargers to the crankshaft. 47. In a powered vehicle as claimed in claim 46, said first and second impellers being rotatable to compress induction fluid for the engine when rotated, said first and second superchargers including a transmission drivingly connecting the impellers to the drive assembly, said transmission cooperating with the drive assembly to maintain rotation of the impellers at the substantially constant speed relative to the rotation of the crankshaft. 48. In a powered vehicle as claimed in claim 47, said transmission including a plurality of intermeshing gears with at least one of said gears being common to both superchargers. 49. In a powered vehicle as claimed in claim 45, said induction fluid flow control assembly fluidly intercommunicating the superchargers so that in all operating phases both superchargers compress at least some induction fluid for the engine whenever the crankshaft is rotating. 50. In a powered vehicle as claimed in claim 49, said induction fluid flow control assembly being operable to fluidly intercommunicate the superchargers with the intake manifold so that in all operating phases substantially all of the induction fluid compressed by each of the superchargers is delivered to the intake manifold. 51. In a powered vehicle as claimed in claim 45, said first phase including a series phase in which substantially all induction fluid from the first outlet is supplied to the second inlet. 52. In a powered vehicle as claimed in claim 51, said first phase further including a first transition phase, said induction fluid flow control assembly being configured to switch operation of the superchargers from the series phase to the first transition phase in response to a predetermined condition. 53. In a powered vehicle as claimed in claim 45, said second phase including a parallel phase in which substantially all induction fluid from the first and second outlets is supplied directly to the intake manifold. 54. In a powered vehicle as claimed in claim 53, said second phase further including a second transition phase, said induction fluid flow control assembly being configured to switch operation of the superchargers from the second transition phase to the parallel phase in response to a predetermined condition. 55. In a powered vehicle as claimed in claim 54, said predetermined condition being the relative rotational speed of the crankshaft measured in engine rpm relative to the maximum rotational speed of the crankshaft, said relative rotational speed being about eighty percent of the maximum rotational speed. 56. In a powered vehicle as claimed in claim 45; and a case presenting a compression chamber and a transmission chamber, said first and second superchargers being at least partially housed within said compression chamber. 57. In a powered vehicle as claimed in claim 45, said induction fluid flow control assembly including a passageway fluidly communicating said first outlet and said second inlet, said induction fluid flow control assembly further including a first valve disposed along said passageway for controlling the flow of induction fluid there through. 58. In a powered vehicle as claimed in claim 57, said first valve shiftable between an open position wherein induction fluid is permitted to flow through said passageway and a closed position wherein induction fluid is prevented from flowing through said passageway, said first valve shiftable into a plurality of intermediate positions between said open and closed positions wherein the quantity of induction fluid allowed to flow through the passageway varies from one intermediate position to another. 59. In a powered land vehicle including an internal combustion engine having an intake manifold and a rotatable crankshaft, an improved air induction system comprising: a first centrifugal supercharger drivingly connected to the crankshaft for compressing induction fluid for the engine, said first supercharger including a first inlet, a spaced first outlet, and a first impeller fluidly between the first inlet and first outlet to compress induction fluid; a second centrifugal supercharger drivingly connected to the crankshaft for compressing induction fluid for the engine, said second supercharger including a second inlet, a spaced second outlet, and a second impeller fluidly between the second inlet and second outlet to compress induction fluid; and an induction fluid flow control assembly fluidly intercommunicating the superchargers so that the superchargers cooperatively provide induction fluid to the engine in a number of operating phases, including a first phase in which at least some induction fluid from the first outlet is supplied to the second inlet and a second phase in which at least some induction fluid from the first and second outlets is supplied to the intake manifold without passing through the other supercharger, a drive assembly drivingly connecting the superchargers to the crankshaft so that each of the superchargers operates continuously with rotation of the crankshaft, said first and second impellers being rotatable to compress induction fluid for the engine when rotated, said first and second superchargers including a transmission drivingly connecting the impellers to the drive assembly, said transmission cooperating with the drive assembly to maintain rotation of the impellers at a substantially constant ratio relative to the rotation of the crankshaft, said transmission including a plurality of intermeshing gears with at least one of said gears being common to both superchargers, said transmission including a common rotatable transmission shaft coupled to said common gear, said drive assembly including an endless element entraining at least a portion of said common shaft and at least a portion of the crankshaft. 60. In a powered land vehicle including an internal combustion engine having an intake manifold and a rotatable crankshaft, an improved air induction system comprising: a first centrifugal supercharger drivingly connected to the crankshaft for compressing induction fluid for the engine, said first supercharger including a first inlet, a spaced first outlet, and a first impeller fluidly between the first inlet and first outlet to compress induction fluid; a second centrifugal supercharger drivingly connected to the crankshaft for compressing induction fluid for the engine, said second supercharger including a second inlet, a spaced second outlet, and a second impeller fluidly between the second inlet and second outlet to compress induction fluid; and an induction fluid flow control assembly fluidly intercommunicating the superchargers so that the superchargers cooperatively provide induction fluid to the engine in a number of operating phases, including a first phase in which at least some induction fluid from the first outlet is supplied to the second inlet and a second phase in which at least some induction fluid from the first and second outlets is supplied to the intake manifold without passing through the other supercharger, said first phase including a series phase in which substantially all induction fluid from the first outlet is supplied to the second inlet, said first phase further including a first transition phase, said induction fluid flow control assembly being configured to switch operation of the superchargers from the series phase to the first transition phase in response to a predetermined condition, said predetermined condition being the relative rotational speed of the crankshaft measured in engine rpm relative to the maximum rotational speed of the crankshaft, said relative rotational speed being between about sixty and about seventy percent of the maximum rotational speed. 61. In a powered land vehicle including an internal combustion engine having an intake manifold and a rotatable crankshaft, an improved air induction system comprising: a first centrifugal supercharger drivingly connected to the crankshaft for compressing induction fluid for the engine, said first supercharger including a first inlet, a spaced first outlet, and a first impeller fluidly between the first inlet and first outlet to compress induction fluid; a second centrifugal supercharger drivingly connected to the crankshaft for compressing induction fluid for the engine, said second supercharger including a second inlet, a spaced second outlet, and a second impeller fluidly between the second inlet and second outlet to compress induction fluid; and an induction fluid flow control assembly fluidly intercommunicating the superchargers so that the superchargers cooperatively provide induction fluid to the engine in a number of operating phases, including a first phase in which at least some induction fluid from the first outlet is supplied to the second inlet and a second phase in which at least some induction fluid from the first and second outlets is supplied to the intake manifold without passing through the other supercharger, said induction fluid flow control assembly including a passageway fluidly communicating said first outlet and said second inlet, said induction fluid flow control assembly further including a first valve disposed along said passageway for controlling the flow of induction fluid there through, said induction fluid flow control assembly including an additional passageway in fluid communication with said first outlet and the intake manifold, said induction fluid flow control assembly further including a second valve disposed along said additional passageway downstream of said first-mentioned passageway for controlling the flow of induction fluid through said additional passageway. 62. In a powered vehicle as claimed in claim 61, said second valve shiftable between an open position wherein induction fluid is permitted to flow through said additional passageway and a closed position wherein induction fluid is prevented from flowing through said additional passageway. 63. In a powered vehicle as claimed in claim 61, said induction fluid flow control assembly including a second additional passageway in fluid communication with said second inlet, said induction fluid flow control assembly further including a third valve disposed along said second additional passageway upstream of said first-mentioned passageway for controlling the flow of induction fluid through said second additional passageway. 64. In a powered vehicle as claimed in claim 63, said third valve shiftable between an open position wherein induction fluid is permitted to flow through said second additional passageway and a closed position wherein induction fluid is prevented from flowing through said second additional passageway. 65. In a powered vehicle as claimed in claim 63; and a case presenting a compression chamber and a transmission chamber, said first and second superchargers and said induction fluid flow control assembly being at least partially housed within said compression chamber, said compression chamber presenting a case inlet in fluid communication with the atmosphere. 66. In a powered vehicle as claimed in claim 65, said induction fluid flow control assembly including a third additional passageway fluidly communicating the case inlet with said first inlet and fluidly communicating the case inlet with said second additional passageway, said induction fluid flow control assembly further including a fourth valve disposed along said third additional passageway for controlling the flow of induction fluid there through. 67. In a powered vehicle as claimed in claim 66, said fourth valve shiftable between an open position wherein induction fluid is permitted to flow through said third additional passageway and a partially closed position wherein at least some induction fluid is prevented from flowing through said third additional passageway.
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