Heat exchanger with refrigerant storage volume

The invention claimed is: 1. A heat exchanger comprising: a microchannel coil, the microchannel coil includes flattened tubes fluidly connected to a header, and fins between the flattened tubes, the flattened tubes include multiple channels fluidly connected with the header to pass a working fluid through the multiple channels of the flattened tubes and through the header, the flattened tubes and fins are constructed and arranged to pass a heat exchange fluid through the microchannel coil externally of the flattened tubes and fins so as to have a heat exchange relationship with the working fluid, the microchannel coil includes a first fluid port fluidly connected with the header, and a second fluid port fluidly connected with the header, in a cooling mode, the first fluid port receives the working fluid, and the second fluid port exits the working fluid after the working fluid has passed through the flattened tubes and the header, in a mode other than the cooling mode, the second fluid port receives the working fluid, and the first fluid port exits the working fluid after the working fluid has passed through the flattened tubes and header; a volume fluidly connected with the first fluid port; and a flow control device fluidly connected with the volume, the volume being disposed between the flow control device and the first fluid port, wherein, in the cooling mode, the flow control device is in an open state and the volume is constructed and arranged to pass the working fluid through the volume and to the first fluid port into the header fluidly connected with the first fluid port, and in the mode other than the cooling mode, the flow control device is in a closed state and the volume is constructed and arranged to receive the working fluid from the first fluid port, and to store the working fluid. 2. The heat exchanger of claim 1 , wherein the microchannel coil includes a condensing section, the first fluid port is fluidly connected to an inlet of the condensing section. 3. The heat exchanger of any of claim 1 , wherein the microchannel coil includes a sub-cooling section, the second fluid port is fluidly connected to an outlet of the sub-cooling section. 4. The heat exchanger of claim 1 , wherein the volume includes a capacity to receive a substantial amount of an operating charge of the working fluid designed for a cooling system in which the heat exchanger is implemented. 5. The heat exchanger of claim 1 , further comprising a fan assembled with the microchannel coil to draw the heat exchange fluid over the microchannel coil. 6. The heat exchanger of claim 5 , wherein the volume is disposed within a perimeter defined by an arrangement of the microchannel coil, the fan, and another coil. 7. A method of operating a cooling system comprising: compressing a working fluid with a compressor; directing the working fluid to a first heat exchanger according to claim 1 to condense the working fluid; directing the working fluid from the first heat exchanger to an expansion device to expand the working fluid; directing the working fluid from the expansion device to a second heat exchanger; and returning the working fluid to the compressor, the step of directing the working fluid from the compressor to the first heat exchanger includes directing the working fluid through a volume prior to the working fluid flowing into a microchannel coil of the first heat exchanger. 8. The method of claim 7 , further comprising storing the working fluid, the step of storing includes directing the working fluid into the first heat exchanger, directing the working fluid from the microchannel coil and out of a fluid port; and directing the working fluid into a volume, and storing the working fluid in the volume. 9. The method of claim 8 , wherein the step of storing the working fluid is during a pump down operation. 10. A cooling system comprising: a compressor to compress a working fluid; a first heat exchanger to condense the working fluid, the first heat exchanger is fluidly connected with the compressor to receive the working fluid compressed by the compressor; an expansion device to expand the working fluid, the expansion device is fluidly connected with the first heat exchanger to receive the working fluid condensed by the first heat exchanger; and a second heat exchanger to evaporate the working fluid, the second heat exchanger is fluidly connected with the expansion device to receive the working fluid expanded by the expansion device, the first heat exchanger including: a microchannel coil, the microchannel coil includes flattened tubes fluidly connected to a header, and fins between the flattened tubes, the flattened tubes include multiple channels fluidly connected with the header to pass a working fluid through the multiple channels of the flattened tubes and through the header, the flattened tubes and fins are constructed and arranged to pass a heat exchange fluid through the microchannel coil externally of the flattened tubes and fins so as to have a heat exchange relationship with the working fluid, the microchannel coil includes a first fluid port fluidly connected with the header, and a second fluid port fluidly connected with the header, in a cooling mode, the first fluid port receives the working fluid, and the second fluid port exits the working fluid after the working fluid has passed through the flattened tubes and the header, in a mode other than the cooling mode, the second fluid port receives the working fluid, and the first fluid port exits the working fluid after the working fluid has passed through the flattened tubes and header; a volume fluidly connected with the first fluid port; and a flow control device fluidly connected with the volume, the volume being disposed between the flow control device and the first fluid port, wherein, in the cooling mode, the flow control device is in an open state and the volume is constructed and arranged to pass the working fluid through the volume and to the first fluid port into the header, and in the mode other than the cooling mode, the flow control device is in a closed state and the volume is constructed and arranged to receive the working fluid from the first fluid port, and to store the working fluid. 11. The cooling system of claim 10 , wherein the cooling system is a water chiller. 12. The cooling system of claim 10 , wherein the microchannel coil includes a condensing section, the first fluid port is fluidly connected to an inlet of the condensing section. 13. The cooling system of claim 10 , wherein the microchannel coil includes a sub-cooling section, the second fluid port is fluidly connected to an outlet of the sub-cooling section. 14. The cooling system of claim 10 , wherein the volume includes a capacity to receive a substantial amount of an operating charge of the working fluid designed for the cooling system. 15. The cooling system of claim 10 , further comprising a fan assembled with the microchannel coil to draw the heat exchange fluid over the microchannel coil. 16. The cooling system of claim 15 , wherein the volume is disposed within a perimeter defined by an arrangement of the microchannel coil, the fan, and another coil included with the first heat exchanger.