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A hybrid system includes a hybrid module that is located between an engine and a transmission. The hybrid system includes an energy storage system for storing energy from and supplying energy to the hybrid module. An inverter transfers power between the energy storage system and the hybrid module. T

A hybrid system includes a hybrid module that is located between an engine and a transmission. The hybrid system includes an energy storage system for storing energy from and supplying energy to the hybrid module. An inverter transfers power between the energy storage system and the hybrid module. The hybrid system also includes a cooling system, a DC-DC converter, and a high voltage tap. The hybrid module is designed to recover energy, such as during braking, as well as power the vehicle. The hybrid module includes an electrical machine (eMachine) along with electrical and mechanical pumps for circulating fluid. A clutch provides the sole operative connection between the engine and the eMachine. The hybrid system further incorporates a power take off (PTO) unit that is configured to be powered by the engine and/or the eMachine.

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1. A hybrid system, comprising: a hybrid module including an eMachine having a generator mode in which the eMachine generates energy that is stored in an energy storage system, the eMachine having a motor mode in which the eMachine draws energy from the energy storage system to provide torque,a clut

1. A hybrid system, comprising: a hybrid module including an eMachine having a generator mode in which the eMachine generates energy that is stored in an energy storage system, the eMachine having a motor mode in which the eMachine draws energy from the energy storage system to provide torque,a clutch providing a connection for transferring torque between an engine and a torque converter of a transmission, the clutch having an engaged state where the torque is able to be transferred between the engine and the torque converter, the clutch having a disengaged state where the torque is unable to be transferred between the engine and the torque converter, andwherein the hybrid module includes a dedicated lubrication, communication, controller, and cooling system to minimize impact on other vehicular systems. 2. The hybrid system according to claim 1, further comprising: the engine;the transmission with a torque converter;the energy storage system; andwherein the hybrid module is coupled between the engine and the torque converter of the transmission. 3. The hybrid system according to claim 2, further comprising: the clutch forming a torque pathway between the engine and the torque converter of the transmission; andthe eMachine being located along the torque pathway between the clutch and the torque converter. 4. The hybrid system according to claim 1, wherein the eMachine and the clutch are oriented in a radial configuration. 5. The hybrid system according to claim 4, wherein the clutch is radially disposed inside the eMachine. 6. The hybrid system according to claim 1, wherein the clutch is a hydraulic type clutch. 7. The hybrid system according to claim 1, further comprising: a rotor hub configured to be mechanically connected to the torque converter, wherein the rotor hub and the torque converter are configured to rotate in unison together;a clutch hub configured to be mechanically connected to the engine; andthe clutch including clutch plates disposed between the rotor hub and the clutch hub to transfer torque between the engine and the torque converter when the clutch is in the engaged state. 8. The hybrid system according to claim 7, wherein the clutch includes: a piston configured to press against the clutch plates to frictionally engage the clutch plates when the clutch is in the engaged state, the piston having a spring recess; anda piston spring received in the spring recess to bias the piston to the disengaged state. 9. The hybrid system according to claim 7, further comprising: the rotor hub defining a piston cavity in which the piston is slidably disposed, the piston dividing the piston cavity into an activation chamber and a deactivation chamber; andthe piston having an offset section bumped out from the rest of the piston in which portions of the piston facing the activation chamber and the deactivation chamber have similar effective areas so that the clutch is centrifugally neutral. 10. The hybrid system according to claim 9, wherein the piston has a standoff disposed opposite of the piston spring to prevent bottoming out of the piston. 11. The hybrid system according to claim 9, further comprising: the clutch including a deactivation fluid passage that supplies fluid to the deactivation chamber; andthe rotor hub including a spillover gap proximal the deactivation fluid passage that allows excess fluid to spill over to prevent hydrostatic lock of the piston. 12. The hybrid system according to claim 7, further comprising: an input shaft mechanically connecting the clutch hub to the engine; andwherein the input shaft and the clutch hub are connected via a spline-type connection. 13. The hybrid system according to claim 12, further comprising: the clutch including a clamp member connected to the rotor hub for bracing the clutch plates; andthe clamp member having a stop member that extends to create an interference relationship with the clutch hub to prevent the clutch hub from falling out of the hybrid module when inverted. 14. The hybrid system according to claim 12, wherein the input shaft has splines and the engine and the input shaft are connected via the splines. 15. The hybrid system according to claim 14, further comprising: the engine includes a drive shaft; anda flywheel connected to the drive shaft. 16. The hybrid system according to claim 15, further comprising: an input drive disc connected to the flywheel; andthe input drive disc having the spline-type connection with the input shaft. 17. The hybrid system according to claim 15, further comprising: a flex plate connected to the flywheel;the flex plate having the spline-type connection with the input shaft; andthe flex plate being flexible to bend to minimize axial wear of the splines on the input shaft. 18. The hybrid system according to claim 15, further comprising: a damper connected to the flywheel;the damper having the spline-type connection with the input shaft; andthe damper being flexible to bend to minimize axial wear of the splines on the input shaft. 19. The hybrid system according to claim 18, further comprising: the transmission including a transmission damper; andthe transmission damper having a different stiffness that the damper connected to the flywheel. 20. The hybrid system according to claim 19, wherein the transmission damper is stiffer than the damper connected to the flywheel. 21. The hybrid system according to claim 12, further comprising: the hybrid modules includes a hybrid module housing; anda seal sealing between the hybrid module housing that the input shaft proximal the splines to prevent lubrication of the splines of the input shaft. 22. The hybrid system according to claim 14, further comprising: a stopper positioned to facilitate lubrication of the splines. 23. The hybrid system according to claim 1, wherein the hybrid system is self-sustaining unit to facilitate retrofitting to pre-existing vehicle designs. 24. The hybrid system according to claim 1, wherein the hybrid module further includes: a mechanical pump for circulating lubrication in the hybrid module; andan electric pump for circulating the lubrication in the hybrid module. 25. The hybrid system according to claim 24, wherein the electric pump supplements the operation of the mechanical pump to minimize the size of the mechanical pump. 26. The hybrid system according to claim 24, further comprising: the hybrid module includinga pump drive gear received around an input shaft for powering the mechanical pump,a snap ring holding the pump drive gear in place, anda key with a notched portion received under the snap ring to key the pump drive gear in place. 27. The hybrid system according to claim 1, further comprising: an adapter ring configured to secure to the torque converter; andthe adapter ring forming a spline-type connection with the hybrid module. 28. The hybrid system according to claim 27, wherein the adapter ring is configured to be bolted to standard bolt locations on the torque converter where the engine is traditionally connected. 29. The hybrid system according to claim 27, wherein the spline-type connection between the adapter ring and the hybrid module reduces any indexing issues during assembly. 30. The hybrid system according to claim 1, wherein the hybrid module includes a slinger blade for directing lubrication back into the hybrid module. 31. The hybrid system according to claim 30, wherein the hybrid module includes a dam structure with a window for retaining the lubrication from the slinger blade. 32. The hybrid system according to claim 1, wherein the hybrid module includes a resolver assembly. 33. The hybrid system according to claim 32, wherein the module includes shielding for shielding the resolver assembly for shielding the resolver assembly from electromagnetic noise. 34. The hybrid system according to claim 33, wherein the shielding includes a transmission facing shield disposed between the resolver assembly and the transmission. 35. The hybrid system according to claim 33, wherein the shielding includes an engine facing shield positioned between the resolver assembly and the engine. 36. The hybrid system according to claim 33, wherein the shielding includes an eMachine facing shield positioned between the resolver assembly and the eMachine. 37. The hybrid system according to claim 33, wherein hybrid module includes a stator terminal block located remotely from the resolver assembly to reduce the electromagnetic noise. 38. The hybrid system according to claim 37, wherein the hybrid module includes a hybrid housing having a stator access opening, anda stator connector access cover covering the stator access opening of the hybrid housing to facilitate access to the stator terminal block. 39. The hybrid system according to claim 2, wherein the transmission is an automatic transmission. 40. The hybrid system according to claim 2, wherein the transmission includes a power take off unit. 41. The hybrid system according to claim 40, wherein the power take off unit is powered in an electric power take off mode via the eMachine. 42. The hybrid system according to claim 40, wherein the power take off unit is powered in a mixed power mode via the eMachine and the engine. 43. The hybrid system according to claim 40, wherein the power take off unit is powered in an engine powered mode via the engine. 44. The hybrid system according to claim 2, wherein the engine is an internal combustion engine. 45. The hybrid system according to claim 2, wherein the energy storage system includes batteries. 46. The hybrid system according to claim 2, further comprising an inverter electrically connected between the transmission and the energy storage system. 47. The hybrid system according to claim 2, further comprising a DC-DC converter module to converts high voltage power supplied by the energy storage system to a lower voltage. 48. The hybrid system according to claim 47, further comprising an electrical accessory electrically connected to the DC-DC converter module. 49. The hybrid system according to claim 2, further comprising a voltage tap electrically connected to the energy storage system. 50. The hybrid system according to claim 1, wherein the hybrid module includes a low voltage connector,one ore more high voltage lines electrically connected to the eMachine, andthe low voltage connector being aligned with high voltage wires on a same side of the hybrid module to facilitate making connections. 51. The hybrid system according to claim 2, further comprising a transmission and hybrid control module for controlling the hybrid module and the transmission. 52. The hybrid system according to claim 1, wherein the hybrid module includes a radiator that cools the hybrid module, wherein the radiator for the hybrid module is separate from a radiator for the engine. 53. A hybrid system, comprising: a hybrid module including an eMachine having a generator mode in which the eMachine generates energy that is stored in an energy storage system, the eMachine having a motor mode in which the eMachine draws energy from the energy storage system to provide torque,a clutch providing a connection for transferring torque between an engine and a torque converter of a transmission, the clutch having an engaged state where the torque is able to be transferred between the engine and the torque converter, the clutch having a disengaged state where the torque is unable to be transferred between the engine and the torque converter,a rotor hub configured to be mechanically connected to the torque converter, wherein the rotor hub and the torque converter are configured to rotate in unison together,a clutch hub configured to be mechanically connected to the engine,the clutch including clutch plates disposed between the rotor hub and the clutch hub to transfer torque between the engine and the torque converter when the clutch is in the engaged state,the rotor hub defining a piston cavity in which the piston is slidably disposed, the piston dividing the piston cavity into an activation chamber and a deactivation chamber,the piston having an offset section bumped out from the rest of the piston in which portions of the piston facing the activation chamber and the deactivation chamber have similar effective areas so that the clutch is centrifugally neutral,the clutch including a deactivation fluid passage that supplies fluid to the deactivation chamber, andthe rotor hub including a spillover gap proximal the deactivation fluid passage that allows excess fluid to spill over to prevent hydrostatic lock of the piston. 54. A hybrid system, comprising: a hybrid module including an eMachine having a generator mode in which the eMachine generates energy that is stored in an energy storage system, the eMachine having a motor mode in which the eMachine draws energy from the energy storage system to provide torque,a clutch providing a connection for transferring torque between an engine and a torque converter of a transmission, the clutch having an engaged state where the torque is able to be transferred between the engine and the torque converter, the clutch having a disengaged state where the torque is unable to be transferred between the engine and the torque converter,a mechanical pump for circulating lubrication in the hybrid module,a pump drive gear received around an input shaft for powering the mechanical pump,a snap ring holding the pump drive gear in place, anda key with a notched portion received under the snap ring to key the pump drive gear in place. 55. A hybrid system, comprising: a hybrid module including an eMachine having a generator mode in which the eMachine generates energy that is stored in an energy storage system, the eMachine having a motor mode in which the eMachine draws energy from the energy storage system to provide torque, anda clutch providing a connection for transferring torque between an engine and a torque converter of a transmission, the clutch having an engaged state where the torque is able to be transferred between the engine and the torque converter, the clutch having a disengaged state where the torque is unable to be transferred between the engine and the torque converter;an adapter ring configured to secure to the torque converter; andthe adapter ring forming a spline-type connection with the hybrid module. 56. The hybrid system according to claim 55, wherein the adapter ring is configured to be bolted to standard bolt locations on the torque converter where the engine is traditionally connected. 57. The hybrid system according to claim 55, wherein the spline-type connection between the adapter ring and the hybrid module reduces any indexing issues during assembly. 58. A hybrid system, comprising: a hybrid module including an eMachine having a generator mode in which the eMachine generates energy that is stored in an energy storage system, the eMachine having a motor mode in which the eMachine draws energy from the energy storage system to provide torque, anda clutch providing a connection for transferring torque between an engine and a torque converter of a transmission, the clutch having an engaged state where the torque is able to be transferred between the engine and the torque converter, the clutch having a disengaged state where the torque is unable to be transferred between the engine and the torque converter; andwherein the hybrid module includes a slinger blade for directing lubrication back into the hybrid module. 59. The hybrid system according to claim 58, wherein the hybrid module includes a dam structure with a window for retaining the lubrication from the slinger blade. 60. A hybrid system, comprising: a hybrid module including an eMachine having a generator mode in which the eMachine generates energy that is stored in an energy storage system, the eMachine having a motor mode in which the eMachine draws energy from the energy storage system to provide torque,a clutch providing a connection for transferring torque between an engine and a torque converter of a transmission, the clutch having an engaged state where the torque is able to be transferred between the engine and the torque converter, the clutch having a disengaged state where the torque is unable to be transferred between the engine and the torque converter,a resolver assembly, andshielding for shielding the resolver assembly for shielding the resolver assembly from electromagnetic noise. 61. The hybrid system according to claim 60, wherein the shielding includes a transmission facing shield disposed between the resolver assembly and the transmission. 62. The hybrid system according to claim 60, wherein the shielding includes an engine facing shield positioned between the resolver assembly and the engine. 63. The hybrid system according to claim 60, wherein the shielding includes an eMachine facing shield positioned between the resolver assembly and the eMachine. 64. The hybrid system according to claim 60, wherein hybrid module includes a stator terminal block located remotely from the resolver assembly to reduce the electromagnetic noise. 65. The hybrid system according to claim 64, wherein the hybrid module includes a hybrid housing having a stator access opening, anda stator connector access cover covering the stator access opening of the hybrid housing to facilitate access to the stator terminal block. 66. A hybrid system, comprising: a hybrid module including an eMachine having a generator mode in which the eMachine generates energy that is stored in an energy storage system, the eMachine having a motor mode in which the eMachine draws energy from the energy storage system to provide torque,a clutch providing a connection for transferring torque between an engine and a torque converter of a transmission, the clutch having an engaged state where the torque is able to be transferred between the engine and the torque converter, the clutch having a disengaged state where the torque is unable to be transferred between the engine and the torque converter, anda radiator that cools the hybrid module, wherein the radiator for the hybrid module is separate from a radiator for the engine. 67. A hybrid system, comprising: a hybrid module including an eMachine having a generator mode in which the eMachine generates energy that is stored in an energy storage system, the eMachine having a motor mode in which the eMachine draws energy from the energy storage system to provide torque,a clutch providing a connection for transferring torque between an engine and a torque converter of a transmission, the clutch having an engaged state where the torque is able to be transferred between the engine and the torque converter, the clutch having a disengaged state where the torque is unable to be transferred between the engine and the torque converter,a rotor hub configured to be mechanically connected to the torque converter, wherein the rotor hub and the torque converter are configured to rotate in unison together,a clutch hub configured to be mechanically connected to the engine,the clutch including clutch plates disposed between the rotor hub and the clutch hub to transfer torque between the engine and the torque converter when the clutch is in the engaged state,a piston configured to press against the clutch plates to frictionally engage the clutch plates when the clutch is in the engaged state, the piston having a spring recess,a piston spring received in the spring recess to bias the piston to the disengaged state,the rotor hub defining a piston cavity in which the piston is slidably disposed, the piston dividing the piston cavity into an activation chamber and a deactivation chamber, andthe piston having an offset section bumped out from the rest of the piston in which portions of the piston facing the activation chamber and the deactivation chamber have similar effective areas so that the clutch is centrifugally neutral. 68. The hybrid system according to claim 67, wherein the piston has a standoff disposed opposite of the piston spring to prevent bottoming out of the piston. 69. The hybrid system according to claim 67, further comprising: the clutch including a deactivation fluid passage that supplies fluid to the deactivation chamber; andthe rotor hub including a spillover gap proximal the deactivation fluid passage that allows excess fluid to spill over to prevent hydrostatic lock of the piston. 70. A hybrid system, comprising: a hybrid module including an eMachine having a generator mode in which the eMachine generates energy that is stored in an energy storage system, the eMachine having a motor mode in which the eMachine draws energy from the energy storage system to provide torque,a clutch providing a connection for transferring torque between an engine and a torque converter of a transmission, the clutch having an engaged state where the torque is able to be transferred between the engine and the torque converter, the clutch having a disengaged state where the torque is unable to be transferred between the engine and the torque converter,a rotor hub configured to be mechanically connected to the torque converter, wherein the rotor hub and the torque converter are configured to rotate in unison together,a clutch hub configured to be mechanically connected to the engine,the clutch including clutch plates disposed between the rotor hub and the clutch hub to transfer torque between the engine and the torque converter when the clutch is in the engaged state,an input shaft mechanically connecting the clutch hub to the engine, wherein the input shaft and the clutch hub are connected via a spline-type connection,the clutch including a clamp member connected to the rotor hub for bracing the clutch plates, andthe clamp member having a stop member that extends radially inward to overlap with the clutch hub to create an interference relationship with the clutch hub.