Vapor injection heat pump and control method

What is claimed: 1. A vapor injection heat pump, comprising: a compressor for compressing a refrigerant that includes at least a first input port, a second input port, and an output port; a first valve directing at least one of a first portion of the refrigerant output by said compressor to a first heat exchanger and a second portion of the refrigerant output by said compressor to a second heat exchanger dependent upon a mode of operation; a first expansion device receiving at least one of the first portion of the refrigerant directed through said first heat exchanger and the second portion of the refrigerant directed through said second heat exchanger; a vapor generator receiving a liquid and vapor refrigerant mix from said first expansion device and directing a vapor component of the liquid and vapor refrigerant mix to said first input port of said compressor and a liquid component of the liquid and vapor refrigerant mix to at least one of said second heat exchanger and a third heat exchanger, via controlling a second valve, dependent upon the mode of operation, wherein said second input port of said compressor receives an output refrigerant from at least one of said second heat exchanger and said third heat exchanger dependent upon the mode of operation; a second expansion device downstream of said vapor generator; a third expansion device upstream of said third heat exchanger; a third valve opening or closing flow of the refrigerant dependent upon the mode of operation, and a control module for controlling at least said first, second and third valves and said first, second and third expansion devices dependent upon the mode of operation. 2. The vapor injection heat pump of claim 1 , further comprising an accumulator upstream of said second input port of said compressor receiving the refrigerant output by at least one of said second heat exchanger and said third heat exchanger dependent upon the mode of operation and directing substantially the vapor component of the refrigerant output by at least one of said second heat exchanger and said third heat exchanger to said second input port of said compressor. 3. The vapor injection heat pump of claim 2 , wherein said first valve directs the refrigerant output by said compressor to said first heat exchanger, said control module operates said first expansion device in an open mode providing minimal refrigerant flow restriction and said second expansion device in an expansion mode lowering pressure and temperature of the refrigerant flow, said control module further closes said second valve and third expansion device, and opens said third valve, said second heat exchanger receives an expanded refrigerant flow out of said second expansion device and absorbs heat, and said third valve directs cooled refrigerant out of said second heat exchanger to said accumulator and eventually to said second input port of said compressor where the refrigerant is compressed to high-temperature, high-pressure vapor, in a deicing mode of operation. 4. The vapor injection heat pump of claim 2 , wherein said first heat exchanger is a refrigerant-to-coolant heat exchanger. 5. The vapor injection heat pump of claim 4 , further comprising a coolant loop including said first heat exchanger and a fourth air-to-coolant heat exchanger through which a coolant is pumped dependent upon the mode of operation. 6. The vapor injection heat pump of claim 5 , further comprising a refrigerant loop including said compressor, said first valve, said second heat exchanger, said first expansion device, said vapor generator, said second valve, said second expansion device, said third expansion device, said third valve, and said third heat exchanger. 7. The vapor injection heat pump of claim 6 , wherein said first valve directs the refrigerant output by said compressor to said second heat exchanger and said second valve directs the liquid component of the liquid and vapor refrigerant mix to said third heat exchanger, in a cooling mode of operation. 8. The vapor injection heat pump of claim 6 , wherein said first valve directs the refrigerant output by said compressor to said first heat exchanger, said second valve closes and said third valve opens to allow the liquid component of the liquid and vapor refrigerant mix to said second heat exchanger, and said pump pumps coolant through said first refrigerant-to-coolant heat exchanger and said fourth air-to-coolant heat exchanger within said coolant loop, in a heating mode of operation. 9. The vapor injection heat pump of claim 6 , wherein said first valve directs the refrigerant output by said compressor to said first heat exchanger, said second valve directs the liquid component of the liquid and vapor refrigerant mix first to said second heat exchanger, via said second expansion device, and then to said third heat exchanger, via said third expansion device, and said pump pumps coolant through said first refrigerant-to-coolant heat exchanger and said fourth air-to-coolant heat exchanger within said coolant loop, in a first reheating mode of operation. 10. The vapor injection heat pump of claim 6 , wherein said first valve directs the refrigerant output by said compressor to both said first heat exchanger and said second heat exchanger, said second valve directs the liquid component of the liquid and vapor refrigerant mix to said third heat exchanger, via said third expansion device, and said pump pumps coolant through said first refrigerant-to-coolant heat exchanger and said fourth air-to-coolant heat exchanger within said coolant loop, in a second reheating mode of operation. 11. The vapor injection heat pump of claim 6 , wherein said first valve directs the refrigerant output by said compressor to said first heat exchanger, said control module operates said first expansion device in an open mode providing minimal refrigerant flow restriction and said second expansion device in an expansion mode lowering pressure and temperature of the refrigerant flow, said control module further closes said second valve, said third expansion device, and opens said third valve, said second heat exchanger receives the expanded refrigerant flow and absorbs heat, and said third valve directs the cooled refrigerant out of said second heat exchanger to said accumulator and eventually to said second input port of said compressor where the refrigerant is compressed to high-temperature, high-pressure vapor, in a deicing mode of operation. 12. The vapor injection heat pump of claim 1 , further comprising a fourth valve between said vapor generator and said first input port of said compressor opening or closing the refrigerant flow into said first input port of said compressor. 13. The vapor injection heat pump of claim 1 , wherein said first, second, and third heat exchangers are air-to-refrigerant heat exchangers. 14. The vapor injection heat pump of claim 1 , wherein said first valve directs the refrigerant output by said compressor to said second heat exchanger, and said second valve directs the liquid component of the liquid and vapor refrigerant mix to said third heat exchanger, in a cooling mode of operation. 15. The vapor injection heat pump of claim 1 , wherein said first valve directs the refrigerant output by said compressor to said first heat exchanger, and said second valve closes and said third valve opens to allow the liquid component of the liquid and vapor refrigerant mix to said second heat exchanger via said second expansion device, in a heating mode of operation. 16. The vapor injection heat pump of claim 1 , wherein said first valve directs the refrigerant output b