Plate-type heat pump air conditioner heat exchanger for a unitary heat pump air conditioner

Having described the invention, it is claimed: 1. A unitary heat pump air conditioner (Unitary HPAC), comprising: a plate-type HPAC heat exchanger having a plurality of plates stacked and hermetically sealed between an upstream end plate and a downstream end plate, defining: a first heat exchanger portion configured to receive a refrigerant flow and having a hot side coolant passageway for a hot side coolant flow having a lower temperature than the refrigerant flow, wherein said refrigerant flow is in non-contact thermal communication with the hot side coolant flow, whereby heat energy is transferred from the refrigerant flow to the hot side coolant flow; and a second heat exchanger portion is configured to receive a refrigerant flow exiting from said first heat exchanger portion and having a cold side coolant passageway for a cold side coolant flow having a higher temperature than the refrigerant flow exiting from said first heat exchanger portion, wherein the cold side coolant flow is in non-contact thermal communication with the refrigerant flow, whereby heat energy is transferred from the cold side coolant flow to the refrigerant flow; wherein said first and second heat exchanger portions define a single unitary structure having a continuous torturous refrigerant passageway in thermal contact with both the cold side coolant flow and the hot side coolant flow. 2. The Unitary HPAC of claim 1 , wherein said plate-type HPAC heat exchanger further includes: an internal heat exchanger portion configured to receive the refrigerant flow exiting from said first heat exchanger portion before being received by said second heat exchanger portion and a refrigerant flow from said second heat exchanger portion before exiting said second heat exchanger portion, wherein the temperature of the refrigerant flow exiting said first heat exchanger portion is higher than temperature of the refrigerant flow exiting from said second heat exchanger portion, and wherein the refrigerant flow from said first heat exchanger portion is in non-contact thermal communication with the refrigerant flow from the second heat exchanger portion, whereby heat energy is transferred from the refrigerant flow exiting from said first heat exchanger portion to the lower temperature refrigerant flow from said second heat exchanger portion. 3. The Unitary HPAC of claim 2 , wherein said internal heat exchanger portion is sandwiched between said first heat exchanger portion and said second heat exchanger portion, thereby forming a single unit integral plate-type HPAC heat exchanger. 4. The Unitary HPAC of claim 1 , wherein said first heat exchanger portion comprises: a hot side coolant inlet, a hot side coolant outlet, and a high pressure refrigerant inlet disposed on said upstream end plate, a hot side coolant passageway in fluid communication with said hot side coolant inlet and hot side coolant outlet; a first boundary plate spaced from said upstream end plate defining a high pressure refrigerant port; and a high pressure refrigerant passageway in fluid communication with said refrigerant inlet of said upstream plate and said high pressure refrigerant port of first boundary plate; wherein said hot side coolant passageway and said high pressure refrigerant passageway are in non-contact thermal communication. 5. The Unitary HPAC of claim 4 , wherein said second heat exchanger portion comprises: a cold side coolant inlet, a cold side coolant outlet, and a low pressure refrigerant outlet disposed on said downstream end plate, a cold side coolant passageway in fluid communication with said cold side coolant inlet and cold side coolant outlet; an elongated refrigerant expansion chamber extending in a direction toward said downstream end plate; and a low pressure refrigerant passageway in fluid communication with said refrigerant expansion chamber and said low pressure refrigerant outlet; wherein said cold side coolant passageway and said low pressure refrigerant passageway are in non-contact thermal communication. 6. A plate-type HPAC heat exchanger comprising: a first heat exchanger portion having an upstream end plate including a high pressure refrigerant inlet; a second heat exchanger portion having a downstream end plate including a low pressure refrigerant outlet; an internal heat exchanger having a first boundary plate and a second boundary plate, wherein said internal heat exchanger is integrally sandwiched between said first heat exchanger portion and said second heat exchanger portion; a refrigerant passageway extending from said high pressure refrigerant inlet to said low pressure refrigerant outlet, defining a high pressure refrigerant flow passageway through said first heat exchanger portion and a low pressure refrigerant flow passageway through said second heat exchanger portion; a hot side coolant passageway extending through the first heat exchanger portion in non-contact thermal communication with said high pressure refrigerant passageway; and a cold side coolant passageway extending through the second heat exchanger portion in non-contact thermal communication with said low pressure refrigerant passageway. 7. The plate-type HPAC heat exchanger of claim 6 , wherein said internal heat exchanger includes a high pressure refrigerant channel in hydraulic communication with said high pressure refrigerant passageway of first heat exchanger portion, and a low pressure refrigerant channel in hydraulic communication with said low pressure refrigerant outlet of second heat exchanger portion.