Vehicular heat pump system and control method

The invention claimed is: 1. A method of controlling a vehicular heat pump system having multiple heat exchangers within an HVAC module, the vehicular heat pump system including a connection line directly interconnecting a compressor and an outside heat exchanger, the method comprising: selecting a mode in which the vehicular heat pump system will operate, based on at least one control parameter; controlling the direction of refrigerant flow in a refrigeration circuit of the vehicular heat pump system, based on the mode of operation, wherein the mode of operation is a cooling mode when the at least one control parameter is within a first range of temperatures, and the mode of operation is a heating mode when the at least one control parameter is within a second range of temperatures; adjusting a first isolation valve and a second isolation valve of the vehicular heat pump system to isolate one of a first inside heat exchanger and a second inside heat exchanger of the vehicular heat pump system from the refrigeration circuit, based on the mode of operation while still allowing refrigerant flow through the outside heat exchanger disposed along the refrigeration circuit regardless of the mode of operation; adjusting a first metering device and a second metering device of the vehicular heat pump system to isolate one of the first inside heat exchanger and the second inside heat exchanger from the refrigeration circuit, and to control expansion of the refrigerant, based on the mode of operation while still allowing refrigerant flow through the outside heat exchanger regardless of the mode of operation; and wherein the first inside heat exchanger and the second inside heat exchanger are located within the HVAC module, and are configured to selectively operate both in parallel and in series; and wherein controlling the direction of refrigerant flow in the refrigeration circuit of the vehicular heat pump system, based on the mode of operation, includes: controlling the direction of refrigerant flow such that the refrigerant flows in a first direction when the vehicular heat pump system is operating in the cooling mode, wherein, when the refrigerant flows in the first direction and the vehicular heat pump system is operating in the cooling mode, the refrigerant exits the compressor, flows through the connection line, and then enters the outside heat exchanger; controlling the direction of refrigerant flow such that the refrigerant flows in a second direction when the vehicular heat pump system is operating in the heating mode, wherein the second direction is opposite to the first direction, and when the refrigerant flows in the second direction and the vehicular heat pump system is operating in the heating mode, the refrigerant exits the outside heat exchanger, flows through the connection line, and then enters the compressor; and controlling the direction of refrigerant flow such that the refrigerant flows in the second direction when the vehicular heat pump system is operating in a dehumidification mode, wherein when the refrigerant flows in the second direction and the vehicular heat pump system is operating in the dehumidification mode, the refrigerant exits the outside heat exchanger, flows through the connection line, and then enters the compressor. 2. The method of claim 1 wherein the second inside heat exchanger is isolated from the refrigeration circuit when the vehicular heat pump system is operating in the cooling mode. 3. The method of claim 1 wherein the first inside heat exchanger is isolated from the refrigeration circuit when the vehicular heat pump system is operating in the heating mode. 4. The method of claim 1 wherein the at least one control parameter is ambient air temperature. 5. The method of claim 1 wherein the at least one control parameter is a desired temperature of a cabin of the vehicle. 6. A vehicular heat pump system comprising: a refrigeration circuit in which refrigerant is circulated, the refrigeration circuit having: an outside heat exchanger configured to selectively operate as a condenser or an evaporator; a first inside heat exchanger and a second inside heat exchanger each configured to selectively operate as a condenser or an evaporator; a compressor configured to compress the refrigerant; a connection line coupled between the outside heat exchanger and the compressor, wherein the connection line fluidly interconnects the outside heat exchanger and the compressor; at least two isolation valves configured to isolate one of the first inside heat exchanger and the second inside heat exchanger from the refrigeration circuit; at least two metering devices configured to control the flow and expansion of the refrigerant; and an HVAC module in which the first inside heat exchanger and the second inside heat exchanger are located; and at least one controller programmed to: select the mode in which the vehicular heat pump system will operate, based on at least one control parameter; control the direction of refrigerant flow in the refrigeration circuit of the vehicular heat pump system, based on the mode of operation so as to change the direction of refrigerant flow between a first direction and a second direction opposite the first direction, wherein, in the first direction, the refrigerant exits the compressor, flows through the connection line, and then enters the outside heat exchanger, and, in the second direction, the refrigerant exits the outside heat exchanger, flows through the connection line, and then enters the compressor; adjust the at least two isolation valves to isolate one of the first inside heat exchanger and the second inside heat exchanger from the refrigeration circuit, based on the mode of operation; and adjust the at least two metering devices to isolate one of the inside heat exchangers from receiving refrigerant from the other inside heat exchanger, and to control expansion of the refrigerant, based on the mode of operation; wherein the first inside heat exchanger and the second inside heat exchanger are configured to selectively operate in parallel and in series; and wherein the controller is programmed to control the direction of refrigerant flow in the refrigeration circuit such that: the refrigerant flows in the first direction when the vehicular heat pump system is operating in a cooling mode; the refrigerant flows in the second direction when the vehicular heat pump system is operating in a heating mode; and the refrigerant flows in the second direction when the vehicular heat pump system is operating in a dehumidification mode. 7. The vehicular heat pump system of claim 6 wherein the mode of operation is a cooling mode when the at least one control parameter is within a first range of temperatures. 8. The vehicular heat pump system of claim 7 wherein the connection line has a first end and a second end opposite the first end, the first end of the connection line is directly connected to the outside heat exchanger, the second end of the connection line is directly connected to the compressor, and the refrigerant is directed to flow from the compressor to the outside heat exchanger via the connection line when the vehicular heat pump system is operating in the cooling mode. 9. The vehicular heat pump system of claim 7 wherein the second inside heat exchanger is isolated from the refrigeration circuit when the vehicular heat pump system is operating in the cooling mode. 10. The vehicular heat pump system of claim 7 wherein the mode of operation is a heating mode when the at least one control parameter is within a second range of temperatures. 11. The vehicular heat pump system of claim 10 wherein the connection