Integration of a small scale liquefaction unit with an LNG plant to convert end flash gas and boil-off gas to incremental LNG

What is claimed is: 1. A method for retrofitting a main LNG plant having a capacity of at least 4 MTPA to expand the capacity of the main LNG plant and operating the expanded capacity plant, wherein the main LNG plant has design parameters including a winter design capacity, an average ambient temperature design capacity, a refrigeration horsepower requirement, a design production of end flash gas, a design production of boil off gas, a design feed flow rate and a design temperature of a gas stream exiting a main cryogenic heat exchanger and wherein the main LNG plant comprises a main cryogenic heat exchanger having a feed gas inlet and a gas outlet, a nitrogen rejection unit having an inlet in fluid communication with the gas outlet of the main cryogenic heat exchanger, an LNG outlet and an end flash gas outlet, an LNG storage unit having an LNG inlet in fluid communication with the LNG outlet of the nitrogen rejection unit, an LNG storage unit outlet and a boil off gas outlet, the method comprising: connecting a small-scale LNG plant having a capacity of less than 2 MTPA and having at least one inlet and an outlet to the end flash gas outlet of the nitrogen rejection unit of the main LNG plant such that an inlet of the small-scale LNG plant and the end flash gas outlet are in fluid communication; installing a first compressor having a first compressor inlet between the end flash gas outlet of the main LNG plant and the inlet of the small-scale LNG plant in fluid communication with the end flash gas outlet for increasing end flash gas pressure prior to being delivered to the inlet of the small-scale LNG plant; passing a natural gas feed stream at a feed flow rate above the design feed flow rate of the main LNG plant through the main cryogenic heat exchanger of the main LNG plant to produce a gas stream exiting the main cryogenic heat exchanger having a temperature between 5° C. and 30° C. higher than the design temperature; sending the gas stream exiting the main cryogenic heat exchanger to a nitrogen rejection unit to produce a nitrogen reduced LNG stream and an end flash gas stream; sending the nitrogen reduced LNG stream to an LNG storage unit; and compressing at least a portion of the end flash gas stream to produce a compressed end flash gas stream and sending the compressed end flash gas stream to the small scale LNG plant to be liquefied, thereby decreasing the refrigeration horsepower requirement such that the expanded capacity plant can be utilized at the winter design capacity above the average ambient temperature design capacity year-round. 2. The method of claim 1 , further comprising: connecting the small-scale LNG plant to the boil off gas outlet of the LNG storage unit of the main LNG plant such that one of the at least one inlet of the small-scale LNG plant and the boil off gas outlet are in fluid communication; and installing a second compressor between the boil off gas outlet of the main LNG plant and the inlet of the small-scale LNG plant in fluid communication with the boil off gas outlet for increasing boil off gas pressure prior to being delivered to the inlet of the small-scale LNG plant. 3. The method of claim 1 , further comprising: installing a temperature sensor between the gas outlet of the main cryogenic heat exchanger of the main LNG plant and the inlet to the nitrogen rejection unit of the main LNG plant capable of gathering temperature information on a gas stream exiting the main cryogenic heat exchanger of the main LNG plant. 4. The method of claim 3 , further comprising: installing a processor in communication with the temperature sensor for receiving the temperature information gathered by the temperature sensor and determining whether to activate a change in a feed gas flow rate to the main cryogenic heat exchanger of the main LNG plant; and connecting the processor to a flow control valve upstream of the feed gas inlet of the main cryogenic heat exchanger of the main LNG plant. 5. The method of claim 3 , further comprising: installing a processor in communication with the temperature sensor for receiving the temperature information gathered by the temperature sensor and determining whether to activate a change in a refrigerant circulation rate within the main cryogenic heat exchanger of the main LNG plant; and connecting the processor to a refrigerant control valve or a refrigerant compression control mechanism associated with the main cryogenic heat exchanger of the main LNG plant. 6. The method of claim 3 , further comprising: installing a processor in communication with the temperature sensor for receiving the temperature information gathered by the temperature sensor and determining whether to activate a change in a pressure at an outlet of a refrigerant compressor associated with the main cryogenic heat exchanger; and connecting the processor to a compressor outlet valve. 7. The method of claim 1 , further comprising: installing a pressure sensor at the first compressor inlet capable of gathering pressure information on a gas stream entering the first compressor. 8. The method of claim 7 , further comprising: installing a processor in communication with the pressure sensor for receiving the pressure information gathered by the pressure sensor and determining whether to activate a change in a feed gas flow rate to the main cryogenic heat exchanger of the main LNG plant; and connecting the processor to a flow control valve upstream of the feed gas inlet of the main cryogenic heat exchanger of the main LNG plant. 9. The method of claim 7 , further comprising: installing a processor in communication with the pressure sensor for receiving the pressure information gathered by the pressure sensor and determining whether to activate a change in a refrigerant circulation rate within the main cryogenic heat exchanger of the main LNG plant; and connecting the processor to a refrigerant control valve or a refrigerant compression control mechanism associated with the main cryogenic heat exchanger of the main LNG plant. 10. The method of claim 7 , further comprising: installing a processor in communication with the pressure sensor for receiving the pressure information gathered by the pressure sensor and determining whether to activate a change in a pressure at an outlet of a refrigerant compressor associated with the main cryogenic heat exchanger; and connecting the processor to a compressor outlet valve. 11. The method of claim 1 , wherein the design temperature of the gas stream exiting the main cryogenic heat exchanger is in a range of from −135° C. to −150° C. and the gas stream exiting the main cryogenic heat exchanger in step (a) has a temperature in a range of from −120° C. to −140° C. 12. The method of claim 1 , wherein prior to step (a), the natural gas stream is treated to remove acid gas and natural gas liquids. 13. The method of claim 1 , further comprising: monitoring the temperature of the gas stream exiting the main cryogenic heat exchanger with a temperature sensor and/or monitoring the pressure of the gas stream entering the first compressor with a pressure sensor; and controlling at least one process condition to result in maintaining the temperature of the gas stream exiting the main cryogenic heat exchanger at a temperature between 5° C. and 30° C. higher than the design temperature. 14. The method of claim 13 , wherein the at least one process condition is selected from the group consisting of feed gas flow rate to the main cryogenic heat exchanger of the main LNG plant, refrigerant circulation rate within the main cryogenic heat exchanger of the main LNG pla