Vapor compression desalination system for seawater

The invention claimed is: 1. A vapor compression desalination system for seawater, comprising: a plurality of evaporators that are fluidly connected in series, with a number of evaporators being from 3 to 12, wherein each evaporator comprises a tube with a tube inlet and a tube outlet, wherein at least a portion of the tube is located in an interior of the evaporator, a saline water inlet to deliver a saline water to the interior of the evaporator, wherein the saline water is contacted with the tube thereby forming water condensate inside the tube and concurrently forming vapor and brine in the interior of the evaporator, a vapor outlet to reject the vapor from the interior of the evaporator, a brine outlet to reject the brine from the interior of the evaporator, and a vapor line that fluidly connects the vapor outlet to the tube inlet of a subsequent evaporator or a compressor; a saline water line that is fluidly connected to the saline water inlet of at least one evaporator, wherein the saline water line delivers the saline water to the saline water inlet; a distillate line that is fluidly connected to the tube outlet of at least one evaporator, wherein the distillate line delivers the water condensate to a downstream unit; a primary compressor that is fluidly connected to the vapor outlet of a last evaporator in the series and the tube inlet of a first evaporator in the series, wherein the primary compressor compresses a vapor from the interior of the last evaporator and delivers the vapor to the tube of the first evaporator; and a secondary compressor that is fluidly connected to the vapor outlet of the first evaporator and/or the vapor outlet of at least one intermediate evaporator in the series and the tube inlet of the first evaporator, wherein the secondary compressor compresses a vapor from the interior of the first evaporator and/or the at least one intermediate evaporator and delivers the vapor to the tube of the first evaporator, wherein the secondary compressor is a positive displacement reciprocating compressor or a positive displacement rotary compressor. 2. The vapor compression desalination system of claim 1 , wherein the secondary compressor is fluidly connected to the vapor outlet of the first evaporator and the vapor outlet of the at least one intermediate evaporator and the tube inlet of the first evaporator. 3. The vapor compression desalination system of claim 1 , wherein the secondary compressor is fluidly connected to the vapor outlet of the first evaporator and the tube inlet of the first evaporator. 4. The vapor compression desalination system of claim 1 , wherein the secondary compressor is fluidly connected to the vapor outlet of an intermediate evaporator and the tube inlet of the first evaporator. 5. The vapor compression desalination system of claim 1 , wherein the primary compressor and the secondary compressor are fluidly connected to the tube inlet of the first evaporator in parallel. 6. The vapor compression desalination system of claim 1 , wherein a pressure ratio of the secondary compressor is in the range of 1.1 to 3. 7. The vapor compression desalination system of claim 1 , further comprising: a brine line that is fluidly connected to the brine outlet of at least one evaporator, wherein the brine line discharges the brine. 8. The vapor compression desalination system of claim 1 , wherein the evaporators are fluidly connected in series with a parallel feed configuration. 9. The vapor compression desalination system of claim 1 , wherein the evaporators are fluidly connected in series with a parallel/cross feed configuration. 10. The vapor compression desalination system of claim 1 , wherein the evaporators are fluidly connected in series with a forward feed configuration. 11. The vapor compression desalination system of claim 1 , further comprising: a first heat exchanger that is located on the distillate line and the saline water line, wherein the first heat exchanger transfers heat from the water condensate to the saline water.