Reversing valve

The invention claimed is: 1. A reversing valve, comprising: a valve body having a single internal cavity therein and an input port, output port and first and second reversing ports, wherein the input port, the output port and the first and second reversing ports are all in fluid communication with the single internal cavity; a baffle located within the single internal cavity, wherein: the baffle is configured to divide the single internal cavity into flow paths and rotate around a pivot point within the single internal cavity, wherein ends of the baffle contact interior walls of the single internal cavity when the baffle rotates about the pivot point in a clockwise direction, thereby isolating the input port and first reversing port and volume of the single internal cavity there-between, from the output port and second reversing port and different volume of the single internal cavity there-between; and the ends of the baffle contact different interior walls of the interior walls of the single internal cavity when the baffle rotates about the pivot point in a counter-clock wise direction, thereby isolating the input port and the second reversing port and second volume of the single internal cavity there-between from the output port and the first reversing port and second different volume of the single internal cavity there-between; and at least one electromagnet coupled to the valve body; wherein, responsive to a voltage being applied to the electromagnet, the electromagnet rotates the baffle in a first direction; wherein the pivot point is connected to a torsion spring concentric to the pivot point, and wherein the torsion spring is configured to rotate the baffle in a direction opposite the first direction; and wherein the input and output ports are located opposite one another on the valve body and the first and second reversing ports are located opposite one another on the valve body. 2. The reversing valve of claim 1 , wherein one or more of the interior walls of the single internal cavity includes a recess, each recess configured such that a portion of a major surface of the baffle near one of the ends of the baffle can contact the recess and thereby stop the baffle rotation in the clockwise direction or counter-clock wise direction and form a fluid seal between the baffle and the interior wall. 3. The reversing valve of claim 1 , wherein a gap distance between outer edges of the baffle and the interior walls is about ⅛ inch or less. 4. The reversing valve of claim 1 , wherein at least an outer edge of the baffle is covered with a pliable material that contacts the interior walls. 5. The reversing valve of claim 1 , wherein the single internal cavity of the valve body is covered with a pliable material. 6. The reversing valve of claim 1 , wherein the baffle is substantially composed of a ferromagnetic material. 7. The reversing valve of claim 1 , wherein the baffle is substantially composed of a non-ferromagnetic material and further includes a ferromagnetic material attached thereto. 8. The reversing valve of claim 1 , wherein the pivot point is substantially offset from the center of the single internal cavity along a central axis along the input port and the output port. 9. The reversing valve of claim 1 , where the electromagnet is a first electromagnet, and further including a second electromagnet coupled to the valve body and configured to rotate the baffle in the direction opposite the first direction when the voltage is applied to the second electromagnet and the voltage is not applied to the first electromagnet. 10. The reversing valve of claim 1 , further including a plurality of electromagnets each coupled to the valve body, wherein a first set of the electromagnets are configured to rotate the baffle in the first direction when the voltage is applied to the first set of the electromagnets and the voltage is not applied to a second set of the electromagnets, and the second set of the electromagnets arc configured to rotate the baffle in the direction opposite the first direction when the voltage is applied to the second set of the electromagnets and the voltage is not applied to the first set electromagnets. 11. The reversing valve of claim 10 , wherein the first set of electromagnets includes the electromagnet and a second electromagnet diagonally opposed to the electromagnet, and, the second set of electromagnets includes a third electromagnet and a fourth electromagnet diagonally opposed to the third electromagnet. 12. The reversing valve of claim 1 , wherein the input port is configured to be coupled to a refrigerant discharge line from a compressor, the output port is configured to be coupled to a refrigerant suction line of the compressor, and the first and second reversing ports are configured to be coupled to an indoor heat exchange coil and an outdoor heat exchange coil, respectively. 13. A heat pump system, comprising: an indoor heat exchanger; an outdoor heat exchanger; a compressor configured to compress a refrigerant and configured to transfer the refrigerant to a discharge line of the system and to receive the refrigerant from a suction line of the system; the reversing valve of claim 1 , wherein the input port is coupled to the discharge line, the output port is coupled to the suction line, the first reversing port is coupled to a first transfer line connected to the outdoor heat exchanger, and the second reversing port is coupled to a second transfer line connected the indoor heat exchanger. 14. The heat pump system of claim 13 , wherein the input and output ports are located on opposing side of the valve body and the first and the second reversing ports are located on different opposing sides of the valve body. 15. The heat pump system of claim 14 , wherein, portions of the discharge line and suction line in proximity to the valve bisect the valve along an axis that is perpendicular to another axis along which the first and second transfer lines in proximity to the valve, bisect the valve. 16. A method of manufacturing a reversing valve, comprising: providing a valve body having a single internal cavity therein and an input port, output port and first and second reversing ports, wherein the input port, the output port and the first and second reversing ports are all in fluid communication with the single internal cavity, wherein the input and output ports are located opposite one another on the valve body and the first and second reversing ports are located opposite one another on the valve body; providing a baffle configured to fit within the single internal cavity, such that: the baffle is configured to divide the single internal cavity into flow paths and rotate around a pivot point within the single internal cavity, wherein ends of the baffle both contact interior walls of the single internal cavity when the baffle rotates about the pivot point in a clockwise direction, thereby isolating the input port and first reversing port and volume of the single internal cavity there-between, from the output port and second reversing port and different volume of the single internal cavity there-between; and the ends of the baffle contact different interior walls of the single internal cavity when the baffle rotates about the pivot point in a counter-clockwise direction, thereby isolating the input port and the second reversing port and second volume of the single internal cavity there-between from the output port and the first reversing port and second different volume of the single internal cavity there-between; coupling at least one electromagnet to the valve bod