An infinitely variable transmission comprising an angular velocity input member ( 12 ), an angular velocity output member ( 14 ), two parallel stages ( 18, 20 ) of cyclic angular velocity generating devices ( 24, 30 ), a drive arrangement ( 16 ) for applying angular velocity from the input member (
An infinitely variable transmission comprising an angular velocity input member ( 12 ), an angular velocity output member ( 14 ), two parallel stages ( 18, 20 ) of cyclic angular velocity generating devices ( 24, 30 ), a drive arrangement ( 16 ) for applying angular velocity from the input member ( 12 ) to each of the angular velocity generating devices ( 24, 30 ), extraction devices ( 26, 32 ) which are each driven by a cyclic angular velocity generating device ( 24, 30 ) in each of the two stages ( 18, 20 ) means for varying the amplitude of the cyclic angular velocity produced by at least one of the stages ( 18, 20 ) and an arrangement ( 28, 34, 22 ) for summing and combining the pulsating angular velocity outputs from the extraction devices ( 26, 32 ).
대표청구항▼
1. An infinitely variable transmission comprisingan angular velocity input member [ 12 ],an angular velocity output member [ 14 ],two parallel stages [ 18 , 20 ] of cyclic angular velocity generating devices [ 24 , 30 ],a drive arrangement [ 16 ] for applying angular velocity from the input member [
1. An infinitely variable transmission comprisingan angular velocity input member [ 12 ],an angular velocity output member [ 14 ],two parallel stages [ 18 , 20 ] of cyclic angular velocity generating devices [ 24 , 30 ],a drive arrangement [ 16 ] for applying angular velocity from the input member [ 12 ] to each of the angular velocity generating devices [ 24 , 30 ],extraction devices [ 26 , 32 ] which are each driven by a cyclic angular velocity generating device [ 24 , 30 ] in each of the two stages [ 18 , 20 ] which extracts the absolute maximum angular velocity pulsations from the cyclic angular velocity output of the cyclic angular velocity generating device [ 24 , 30 ] which drives it,means for varying the amplitude of the cyclic angular velocity produced by at least one of the stages [ 18 , 20 ],an arrangement [ 28 , 34 , 22 ] for summing and combining the pulsating angular velocity outputs from the extraction devices [ 26 , 32 ] and applying a single non-pulsating output angular velocity to the output member [ 14 ],characterised in that:each of the cyclic angular velocity generating devices [ 24 , 30 ] includes two shafts which are coupled to each other by at least one universal joint,the drive means [ 16 ] includes a drive arrangement for driving the cyclic angular velocity generating devices [ 24 , 30 ] in each of the stages [ 18 , 20 ] in such a direction and fixed ratio of rotation relatively to the direction of rotation of the input member [ 12 ] so that each stage [ 18 , 20 ] produces the same number of angular velocity cycles per revolution of the input member [ 12 ],the amplitude varying means [ 126 , 128 ] is a control arrangement which interconnects one of the shafts of each of the cyclic angular velocity generating devices [ 24 , 30 ] in each of the stages [ 18 , 20 ] to those in the other stage [ 18 , 20 ] to enable the connected shafts in each stage to be concomitantly moved by the control arrangement in a predetermined angular relationship relatively to the connected shafts in the other stage [ 18 , 20 ] to enable the amplitudes of the cyclic angular velocities generated by the cyclic angular velocity generating devices [ 24 , 30 ] in that stage to be varied to correspond to the angular velocity amplitudes in the remaining stage [ 18 , 20 ], andmeans which is activated by the control arrangement for controlling the duration of each of the extract on device pulsations from at least one stage [ 18 , 20 ] in a predetermined relationship to the amplitudes of the cyclic angular velocities generated by the cyclic angular velocity generating devices [ 24 , 30 ], wherein the angular velocity generating stage [ 18 ] includes at least three cyclic angular velocity generating devices [ 24 ] and the angular velocity generating stage [ 20 ] two cyclic angular velocity generating devices [ 30 ]. 2. An infinitely variable transmission as claimed in claim 1 wherein the angular velocity generating devices in each stage [ 24 , 30 ] are rotationally phased 60° apart with reference to the input member [ 12 ]. 3. An infinitely variable transmission as claimed in claim 2, wherein the stage [ 18 ] universal joint sets are rotated by the drive means [ 16 ] in a ratio of 1:1 relatively to and in the same direction of rotation as the input member [ 12 ] and the universal joint sets of the stage [ 20 ] are rotated in a ratio of 1:1.5 relatively to and in a direction opposite to the direction of rotation of the input member [ 12 ]. 4. An infinitely variable transmission as claimed in claim 2 wherein the angular velocity generating devices are each a universal joint set [ 24 30 ] which includes a universal shaft which carries at each of its ends a universal joint with one of the universal joints being driven by the drive means [ 16 ] with the other connected by a shaft [ 54 , 62 ] to an extraction device [ 26 , 32 ]. 5. An infinitely variable transmission as claimed in claim 4 wherein the universal shaft of each universal join t set [ 24 , 30 ] is telescopically variable in length. 6. An infinitely variable transmission as claimed in claim 4 wherein the yokes of the universal joints of the universal joint sets [ 24 , 30 ] which are attached to the universal shaft are fixed in each set at 90° to each other. 7. An infinitely variable transmission as claimed in claim 6 wherein the components of the drive arrangement [ 16 ] are located between and on two circular plates and the components of the transmission are located in a cylindrical housing [ 124 ] with the plates of the drive means [ 16 ] fixed to the housing wall with the remainder of the components being at least partially rotatable about the housing axis to vary the output amplitudes of the cyclic angular velocities of the universal joint sets [ 24 , 30 ] by varying the angular disposition of the universal shafts of the universal joint set [ 24 , 30 ] relatively to their universal joints. 8. An infinitely variable transmission as claimed in claim 7 wherein the extraction devices [ 26 , 32 ] are rotatably mounted between two circular plates [ 56 , 58 ] with the shafts [ 54 ] of the universal joint sets [ 24 ] passing slidably through the plates [ 56 , 58 ] and the extraction devices [ 26 ] between them. 9. An infinitely variable transmission as claimed in claim 7 wherein the plate [ 56 , 58 ] are each rotatably mounted coaxially in the housing [ 124 ] on a guide track on the inner wall of the housing [ 124 ]. 10. An infinitely variable transmission comprisingan angular velocity input member [ 12 ],an angular velocity output member [ 14 ],two parallel stages [ 18 , 20 ] of cyclic angular velocity generating devices [ 24 , 30 ],a drive arrangement [ 16 ] for applying angular velocity from the input member [ 12 ] to each of the angular velocity generating devices [ 24 , 30 ],extraction devices [ 26 , 32 ] which are each driven by a cyclic angular velocity generating device [ 24 , 30 ] in each of the two stages [ 18 , 20 ] which extracts the absolute maximum angular velocity pulsations from the cyclic angular velocity output of the cyclic angular velocity generating device [ 24 , 30 ] which drives it,means for varying the amplitude of the cyclic angular velocity produced by at least one of the stages [ 18 , 20 ],an arrangement [ 28 , 34 , 22 ] for summing an combining the pulsating angular velocity outputs from the extraction devices [ 26 , 32 ] and applying a single non-pulsating output angular velocity to the output member [ 14 ],characterised in that:each of the cyclic angular velocity generating devices [ 24 , 30 ] includes two shafts which are coupled to each other by at least one universal joint,the drive means [ 16 ] includes a drive arrangement for driving the cyclic angular velocity generating devices [ 24 , 30 ] in each of the stages [ 18 , 20 ] in such a direction and fixed ratio of rotation relatively to the direction of rotation of the input member [ 12 ] so that each stage [ 18 , 20 ] produces the same number of angular velocity cycles per revolution of the input member [ 12 ],the amplitude varying means [ 126 , 128 ] is a control arrangement which interconnects one of the shafts of each of the cyclic angular velocity generating devices [ 24 , 30 ] in each of the stages [ 18 , 20 ] to those in the other stage [ 18 , 20 ] to enable the connected shafts in each stage to be concomitantly moved by the control arrangement in a predetermined angular relationship relatively to the connected shafts in the other stage [ 18 , 20 ] to enable the amplitudes of the cyclic angular velocities generated by the cyclic angular velocity generating devices [ 24 , 30 ] in that stage to be varied to correspond to the angular velocity amplitudes in the remaining stage [ 18 , 20 ], andmeans which is activated by the control arrangement for controlling the duration of each of the extraction device pulsations from at least one stage [ 18 , 20 ] in a predetermined relationship to the amplitudes of the cyclic angular velocities generated by the cyclic angular velocity generating devices [ 24 , 30 ],wherein the extraction devices [ 26 , 32 ] each include a boss [ 88 ] with which a shaft [ 54 , 62 ] of a universal joint set [ 24 , 30 ] is engaged, opposed clutch plates [ 82 , 90 ] with one of the clutch plates [ 90 ] being engaged with the boss [ 88 ] and the other with an output gear [ 78 ] with both clutch places being movable relatively to each other in the axial direction of the shafts [ 54 , 62 ] between a first position in which they are spaced from each other and a second position in which they are engaged with each other and means for causing movement of the clutch plates between their two positions of movement, in dependence on the angular position of rotation of the shafts [ 54 62 ] with which they are engaged, twice during each revolution of the shafts [ 54 , 62 ] and for adjustably varying the time period of engagement of the plates [ 82 , 90 ] to cause their output gear [ 78 ] to partially rotate twice during each cycle of rotation of the drive shafts [ 54 , 62 ] and so to extract an output gear [ 78 ] movement pulse from the global absolute maximum and minimum portions of each cycle of rotation of the drive shaft [ 54 , 62 ]. 11. An infinitely variable transmission as claimed in claim 10 wherein the clutch plate [ 82 , 90 ] movement causing means is a double lobed [ 104 ] cam arrangement [ 74 ] and two cam followers [ 96 ] which are carried by the extraction device boss [ 88 ] and the extraction device includes biasing means biasing the cam followers [ 96 ] onto the cam arrangement [ 74 ]. 12. An infinitely variable transmission as claimed in claim 11 wherein the cam arrangement [ 74 ] includes two annular rings [ 89 , 100 ] with one concentrically located within the other to be relatively rotatable about and clear of the shaft [ 54 , 62 ], two diametrically opposite raised cam lobes [ 104 ] which extend over a predetermined limited portion of the circumferential length of and project outwardly from the annular face of each of the rings on a common side of the rings [ 98 , 100 ], and a control arm [ 102 ] which project partially outwardly from at least one of the rings [ 98 , 100 ] form rotating the ring and the lobes [ 104 ] on it from a position in which both lobes [ 104 ] on the rings [ 98 , 100 ] overlap and are in radial register to a position in which the two pairs of lobe partially overlap each other to increase the circumferential length of the composite lobes. 13. An infinitely variable transmission as claimed in claim 10 wherein the clutch plates [ 82 , 90 ] are dog-tooth clutch plates and the extraction devices each include two synchronisation ring plate [ 84 , 86 ] with plates [ 84 , 86 ] each being associated with one of the clutch plates [ 82 , 90 ] and each synchronisation plate [ 84 , 86 ] includes a ring of radial teeth which face and mesh with those on the opposite synchronisation plate [ 84 , 86 ] with the synchronisation plates [ 84 , 86 ] being movable relatively to their associated clutch plates [ 82 , 90 ] towards and away from the remaining synchronisation plate [ 84 , 86 ] and means biasing the synchronisation plates [ 84 , 86 ] away from the faces of the clutch plates [ 82 , 90 ] so that when the clutch plates are moved towards each other the teeth on the synchronisation plates [ 84 86 ] first engage each other and, if necessary, fractionally rotate relatively to the other to ensure a clean mesh of the dog-teeth on the clutch plates [ 82 , 90 ] when brought into engagement. 14. An infinitely variable transmission as claimed in claim 10 wherein the clutch plates [ 82 , 90 ] are smooth faced metal plates and the extraction devices [ 26 , 32 ] each include means for electrically magnetising at least one of the plates [ 82 , 90 ] to cause the plates [ 82 , 90 ] to become magnetically coupled, and electrical switch means which is synchronised with the shaft [ 54 , 62 ] for switching electrical cu rrent to the clutch plate [ 82 , 90 ] magnetising mean twice for every revolution of the shaft [ 54 , 62 ] for predetermined time periods during each revolution of the shaft [ 54 , 62 ]. 15. An infinitely variable transmission as claimed in claim 10 wherein the clutch plate [ 82 , 90 ] movement causing means is an electrical device for moving at least one of the plates towards the other to become coupled and electrical switch means which is synchronised with the shaft [ 54 , 62 ] for switching electrical current to the clutch plate [ 82 , 90 ] moving means twice in predetermined time periods during each revolution of the shaft [ 54 , 62 ]. 16. An infinitely variable transmission comprisingan angular velocity input member [ 12 ],an angular velocity output member [ 14 ],two parallel stages [ 18 , 20 ] of cyclic angular velocity generating devices [ 24 , 30 ],a drive arrangement [ 16 ] for applying angular velocity from the input member [ 12 ] to each of the angular velocity generating devices [ 24 , 30 ],extraction devices [ 26 , 32 ] which are each driven by a cyclic angular velocity generating device [ 24 , 30 ] in each of the two stages [ 18 , 20 ] which extracts the absolute maximum angular velocity pulsations from the cyclic angular velocity output of the cyclic angular velocity generating device [ 24 , 30 ] which drives it,means for varying the amplitude of the cyclic angular velocity produced by at least one of the stages [ 18 , 20 ],an arrangement [ 28 , 34 , 22 ] for summing and combining the pulsating angular velocity outputs from the extraction devices [ 26 , 32 ] and applying a single non-pulsating output angular velocity to the output member [ 14 ],characterised in that:each of the cyclic angular velocity generating devices [ 24 , 30 ] includes two shafts which are coupled to each other by at least one universal joint,the drive means [ 16 ] includes a drive arrangement for driving the cyclic angular velocity generating devices [ 24 , 30 ] in each of the stages [ 18 , 20 ] in such a direction and fixed ratio of rotation relatively to the direction of rotation of the input member [ 12 ] so that each stage [ 18 , 20 ] produces the same number of angular velocity cycles per revolution of the input member [ 12 ],the amplitude varying means [ 126 , 128 ] is a control arrangement which interconnects one of the shafts of each of the cyclic angular velocity generating devices [ 24 , 30 ] in each of the stages [ 18 , 20 ] to those in the other stage [ 18 , 20 ] to enable the connected shafts in each stage to be concomitantly moved by the control arrangement in a predetermined angular relationship relatively to the connected shafts in the other stage [ 18 , 20 ] to enable the amplitudes of the cyclic angular velocities generated by the cyclic angular velocity generating devices [ 24 , 30 ] in that stage to be varied to correspond to the angular velocity amplitudes in the remaining stage [ 18 , 20 ], andmeans which is activated by the control arrangement for controlling the duration of each of the extraction device pulsations from at least one stage [ 18 , 20 ] in a predetermined relationship to the amplitudes of the cyclic angular velocities generated by the cyclic angular velocity generating devices [ 24 , 30 ],wherein the cyclic angular velocity amplitude adjusting means includes a carrier [ 128 ] which is engaged with the shafts [ 54 ] of the universal joint sets [ 24 ] with the carrier [ 128 ] including a radially extending control pin [ 126 ] and the housing wall a helical guide slot through which the pin [ 126 ] projects to be movable from one end of the slot, at which the components of the universal joint sets [ 24 , 30 ] are in axial alignment and the angular velocity of the universal joint sets [ 24 , 30 ] is non-cyclic at the low end of the transmission ratio range, to the other end of the slot at which the carrier [ 128 ] has rotated the plates [ 82 , 90 ] to the maximum position of angular displacement of the unive rsal shafts of the universal joint sets [ 24 , 30 ] to achieve maximum cyclic angular velocity output amplitude at the high end of the transmission ratio range. 17. An infinitely variable transmission as claimed in claim 16 including a circumferential slot in the housing [ 142 ] wall through which the ends of the cam arms [ 102 ] of the extraction device [ 26 , 32 ] project and a suitable control arrangement on the outside of the housing [ 124 ] for moving the control pin [ 126 ] in its slot and causing concomitant movement of the cam arms [ 102 ] to vary the amplitude of the pulsed output angular velocities of the extraction devices [ 26 , 32 ] to compensate for cyclic angular velocity amplitude changes of the universal joints [ 24 , 30 ] as the control pin [ 126 ] is moved.
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이 특허에 인용된 특허 (2)
Schonberger Abram (4608 E. Linebaugh Tampa FL 33617), Continuously and infinitely variable mechanical power transmission.
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