Integrated hybrid thermostatic expansion valve and method for providing uniform cooling of heat generating devices

What is claimed is: 1. A valve assembly for supplying a refrigerant flowrate to at least one cold plate in a vapor compression system, comprising: a housing having a bifurcated passageway having a first flow path and a second flow path, an intermediate passage, a first orifice between the intermediate passage and the second flow path of the bifurcated passageway, a first annular volume oriented with the first flow path in the bifurcated passageway, and a second annular volume oriented with the intermediate passage; an expansion valve in the housing and positioned within the first annular volume and second annular volume; an electrically-actuated valve in the housing and positioned between the second flow path of the bifurcated passageway and the intermediate passage; and wherein the first orifice and the electrically-actuated valve are sized such that the refrigerant flowrate through the intermediate passage is 1.5 to 3 times more than the flowrate through the first flow path in the bifurcated passageway. 2. The valve assembly of claim 1 , wherein the first orifice and the electrically-actuated valve are sized such that the refrigerant flowrate through intermediate passage is 1.9 times more than the flowrate through the second flow path in the bifurcated passageway. 3. The valve assembly of claim 1 , wherein the expansion valve is a feedback-controlled expansion valve operatively arranged so that an expandable bulb thereof is located directly within an exit refrigerant stream of the at least one cold plate. 4. The valve assembly of claim 3 , wherein the feedback-controlled expansion valve is a thermal expansion valve and the expandable bulb is a temperature-sensitive feedback expandable bulb located directly within the exit refrigerant stream of the at least one cold plate. 5. The valve assembly of claim 1 , wherein the electrically-actuated valve operates in one of only a full-open position and only a full-closed position. 6. The valve assembly of claim 5 , wherein the electrically-actuated valve is selected from the group consisting of a solenoid valve, a rapidly-actuating gate valve, and a butterfly valve. 7. The valve assembly of claim 1 , wherein the expansion valve is a thermostatic expansion valve, and the electrically-actuated valve is configured to remain closed during low heat loads so that liquid refrigerant flows only through the first flow path in the bifurcated passageway. 8. The valve assembly of claim 1 , wherein a partial boss is arranged in a cavity between the electrically-actuated valve and the first orifice to ensure that the first orifice ingests a liquid portion of two-phase refrigerant flow from the electrically-actuated valve. 9. The valve assembly of claim 8 , wherein the two-phase refrigerant flow expands through the intermediate passage and into the second annular volume to a first port fluidly connected to the second annular volume. 10. The valve assembly of claim 1 , further comprising: the expansion valve having a needle, needle seat, and a plurality of holes for fluidly connecting the first annular volume and the second annular volume; wherein the needle and needle seat define a second orifice; an expandable bulb in contact with the needle; and wherein a movement of the expandable bulb moves the needle from the needle seat to create a space in the second orifice for expanded refrigerant to pass through the second orifice and to discharge from the plurality of holes into the second annular volume. 11. The valve assembly of claim 10 , wherein the expanded refrigerant from the second annular volume enters a first port in fluid connection with the second annular volume. 12. The valve assembly of claim 11 , further comprising: a second port in the housing to receive superheated vapor refrigerant from at least one cold plate; and wherein the expandable bulb is a temperature-sensitive feedback expandable bulb located in the housing and positioned adjacent the second port such that the superheated vapor refrigerant flows over the temperature-sensing element. 13. The valve assembly of claim 12 , wherein the temperature-sensitive feedback expandable bulb is positioned adjacent the needle and, in response to the superheated vapor, axially moves the needle from the needle seat so that the expanded refrigerant in the first annular volume passes through the second orifice and discharges from the plurality of holes into the second annular volume. 14. The valve assembly of claim 1 , wherein the expansion valve is a thermal expansion valve having a superheat adjustment module to allow for the adjustment of superheat during operation of the thermal expansion valve, and the housing has a partial hexagonal shape configured to interface with a hexagonal portion of superheat adjustment module of the thermostatic expansion valve in order to prevent the thermal expansion valve from rotating within the housing and to allow for adjustment of the thermostatic expansion valve during vapor compression system operation without having to remove the thermal expansion valve.