Directional flow control device

What is claimed is: 1. A directional flow control device, comprising: a housing, comprising an inlet end and a discharge end, the housing extending along a longitudinal axis between the inlet end and the discharge end, wherein the housing comprises: a shell, having a cavity, a front housing, received in the cavity of the shell and comprising a front pocket, and a rear housing, received in the cavity of the shell and comprising a rear pocket; stator magnets, extending circumferentially around the housing; and a flow deflector, received in the housing and positioned relative to the stator magnets, wherein the flow deflector has a front end and a rear end, the flow deflector is rotatable in the housing about a rotation axis parallel to the longitudinal axis, the flow deflector has a flow channel therethrough, the flow channel comprises an intake bore at the front end of the flow deflector and a discharge bore at the rear end of the flow deflector, the intake bore is coaxial with the rotation axis, the discharge bore is offset from the rotation axis, the flow deflector comprises rotor magnets, aligned with and facing the stator magnets, the front end of the flow deflector is positioned in the front pocket of the front housing, the rear end of the flow deflector is positioned in the rear pocket of the rear housing, the shell contains the stator magnets and the rotor magnets, and the stator magnets are energized to cause rotation of the flow deflector relative to the housing. 2. The directional flow control device of claim 1 , wherein: the flow deflector further comprises a hub, the hub is cylindrical, and the rotor magnets are arranged circumferentially around an outer perimeter of the hub. 3. The directional flow control device of claim 1 , wherein: the rotor magnets are arranged in a first array, extending circumferentially around an outer perimeter of the flow deflector, and in a second array, extending circumferentially around the outer perimeter of the flow deflector, and the first array is positioned closer to the front end of the flow deflector than the second array. 4. The directional flow control device of claim 1 , wherein: the flow deflector further comprises a hub, and the rotor magnets are embedded in the hub of the flow deflector. 5. The directional flow control device of claim 1 , wherein the rotor magnets are magnetized teeth. 6. The directional flow control device of claim 1 , wherein the flow deflector is rotatable within the housing without requiring a shaft connection between the flow deflector and the housing. 7. The directional flow control device of claim 1 , wherein the flow deflector is rotatable within the housing without requiring a gear drive to rotate the flow deflector. 8. The directional flow control device of claim 1 , further comprising a control module, and coil windings, wherein the stator magnets are energized by the coil windings, electrically connected to the control module. 9. The directional flow control device of claim 1 , wherein the discharge bore is rotatable relative to the housing between a first discharge position and a second discharge position. 10. The directional flow control device of claim 1 , wherein: the intake bore extends along an intake bore axis, and the discharge bore extends along a discharge bore axis, which has a fluid path change angle from 10° to 45° relative to the intake bore axis. 11. The directional flow control device of claim 1 , wherein: the front housing also comprises an inlet bore in flow communication with the intake bore, the rear housing also comprises a first outlet bore and a second outlet bore, and the flow deflector is rotatable relative to the housing to selectively couple the discharge bore in flow communication with the first outlet bore and is also rotatable to selectively couple the discharge bore in flow communication with the second outlet bore. 12. The directional flow control device of claim 11 , wherein: the flow deflector is rotatable relative to the housing to a first discharge position so that the discharge bore is in flow communication with the first outlet bore, the flow deflector is rotatable relative to the housing to a second discharge position so that the discharge bore is in flow communication with the second outlet bore, and the flow deflector is rotatable relative to the housing to a shut-off position so that the discharge bore is in flow communication with neither the first outlet bore nor the second outlet bore so that flow through the directional flow control device is stopped. 13. The directional flow control device of claim 1 , wherein the stator magnets circumferentially surround at least one of the front pocket or the rear pocket. 14. The directional flow control device of claim 1 , wherein the stator magnets are positioned between the front housing and the rear housing. 15. A directional flow control device, comprising: a housing, comprising: an inlet end, a discharge end, a shell that has a cavity, a front housing, received in the cavity of the shell and comprising an inlet bore, and a rear housing, received in the cavity of the shell and comprising a first outlet bore and a second outlet bore, wherein the front housing and the rear housing are aligned in the cavity along a longitudinal axis, extending between the inlet end and the discharge end; stator magnets, coupled to at least one of the front housing or the rear housing; a control module, coupled to the stator magnets to energize the stator magnets; and a flow deflector that comprises a hub, having a front end and a rear end, wherein the flow deflector further comprises rotor magnets, arranged around an outer perimeter of the hub, the flow deflector further comprises a flow channel therethrough, the flow channel has an intake bore at the front end of the hub and a discharge bore at the rear end of the hub, the flow deflector is positioned between the front housing and the rear housing such that the rotor magnets are aligned with the stator magnets, the intake bore is in flow communication with the inlet bores, the hub is rotatable relative to the front housing and the rear housing about a rotation axis, parallel to the longitudinal axis, the hub is configured to rotate about the rotation axis between a first discharge position and a second discharge position based on energization of the stator magnets by the control module, the discharge bore is in fluid communication with the first outlet bore when the hub is at the first discharge position, and the discharge bore is in fluid communication with the second outlet bore when the hub is at the second discharge position. 16. The directional flow control device of claim 15 , wherein the flow deflector is rotatable within the housing without requiring a shaft connection between the flow deflector and the housing. 17. The directional flow control device of claim 15 , wherein: the intake bore extends along an intake bore axis, and the discharge bore extends along a discharge bore axis, which has a fluid path change angle from 10° to 45° relative to the intake bore axis. 18. The directional flow control device of claim 15 , wherein the flow deflector is rotatable within the housing without using a gear to rotate the flow deflector. 19. A method of using a directional flow control device, the directional flow control device comprising a housing and a flow deflector, received in the housing, the flow deflector comprising a front end and