Combined power generation system using pressure difference

What is claimed is: 1. A combined power generation system performing pressure difference power generation, the combined power generation system comprising: a pressure difference power generation facility for generating electricity by using a pressure change of natural gas; a heating unit configured to heat the natural gas discharged from the pressure difference power generation facility; a gas turbine power generation facility comprising a compressor that takes in and compresses external air to produce compressed air, a combustor that mixes the compressed air and the natural gas discharged from the heating unit and burns the resulting fuel-and-gas mixture to produce a flue gas, a turbine provided with turbine blades rotated by the flue gas, and a generator connected to and rotated by the turbine to generate electricity; a supercritical fluid power generation facility for generating electricity by using a supercritical working fluid heated by the flue gas produced by the gas turbine power generation facility; a waste-heat recovery heat exchange facility configured such that heat exchange occurs between the flue gas produced by the gas turbine power generation facility and the working fluid to be used in the supercritical fluid power generation facility; a liquefied natural gas (LNG) heat exchange facility in which heat exchange occurs between the working fluid discharged from the supercritical fluid power generation facility and liquefied natural gas so that the working fluid is cooled and the liquefied natural gas is heated to be re-gasified into natural gas, the cooled working fluid flowing into the waste-heat recovery heat exchange facility to undergo heating and then flowing into the supercritical fluid power generation facility; and a working fluid heat exchanger for performing heat exchange between the working fluid having passed through the LNG heat exchange facility and the working fluid discharged from the supercritical fluid power generation facility, wherein the cooled working fluid from the LNG heat exchange facility flows into the waste-heat recovery heat exchange facility via first and second flow channels formed by a working fluid flow control valve, the cooled working fluid of the second flow channel being supplied to the waste-heat recovery heat exchange facility via the working fluid heat exchanger, such that the working fluid having passed through the LNG heat exchanger is supplied to the waste-heat recovery heat exchange facility via the working fluid flow control valve and the first flow channel and is supplied to the working fluid heat exchanger via the working fluid flow control valve and the second flow channel, wherein the combined power generation system further comprises a bypass channel having exactly two ports, the exactly two ports including an input port connected to the second flow channel of the working fluid flow control valve, between an output of the working fluid flow control valve and an input of the working fluid heat exchanger, the input of the working fluid heat exchanger provided on the second flow channel, and an output port connected to an input of the waste-heat recovery heat exchange facility, between an output of the working fluid heat exchanger and the input of the waste-heat recovery heat exchange facility, and wherein the bypass channel enables the working fluid cooled through the heat exchange performed in the LNG heat exchange facility to bypass the working fluid heat exchanger to maintain the working fluid flowing into the LNG heat exchange facility at a high temperature when an amount of the liquefied natural gas to be re-gasified increases, the combined power generation system further comprising an LNG storage facility for storing the liquefied natural gas to be introduced into the LNG heat exchange facility, wherein the LNG storage facility comprises an LNG heating facility configured to heat the stored liquefied natural gas for re-gasification of the liquefied natural gas, wherein the LNG heat exchange facility includes a first LNG path in which heat from the working fluid discharged from the supercritical fluid power generation facility is transferred to the liquefied natural gas supplied from the LNG storage facility and from which heated liquefied natural gas of the first LNG path is output to the pressure difference power generation facility, and wherein the LNG heating facility includes a second LNG path in which the liquefied natural gas supplied from the LNG storage facility via the LNG heat exchange facility is heated by sea water and from which the liquefied natural gas heated by the sea water is supplied to an input of the first LNG path. 2. The combined power generation system according to claim 1 , wherein the LNG heat exchange facility comprises a mediation fluid circulation unit through which circulates a mediation fluid for mediating heat exchange between the liquefied natural gas and the working fluid. 3. The combined power generation system according to claim 2 , further comprising a buffering unit configured to prevent explosions attributable to the mediation fluid. 4. The combined power generation system according to claim 1 , further comprising: an airflow channel configured to deliver a portion of the compressed air from the compressor to the turbine; and a fuel gas heater for performing heat exchange between compressed air from the airflow channel and natural gas flowing into the pressure difference power generation facility, thereby heating the natural gas. 5. The combined power generation system according to claim 4 , further comprising: a branch channel branching off from the airflow channel to allow the compressed air in the airflow channel to bypass the fuel gas heater; and an airflow control valve to regulate a flow rate of air flowing into the fuel gas heater. 6. The combined power generation system according to claim 4 , further comprising a cooling fan installed in the airflow channel to cool air having passed through the fuel gas heater. 7. The combined power generation system according to claim 4 , further comprising an air heat exchanger for performing heat exchange between the working fluid having passed through the LNG heat exchange facility and the compressed air having passed through the fuel gas heater. 8. The combined power generation system according to claim 1 , wherein the waste-heat recovery heat exchange facility comprises: a first waste-heat recovery heat exchange facility in which heat exchange occurs between the working fluid flowing in the first flow channel after passing through the LNG heat exchange facility and the flue gas produced by the gas turbine power generation facility; and a second waste-heat recovery heat exchange facility in which heat exchange occurs between the flue gas produced by the gas turbine power generation facility and a merged stream of the working fluid flowing in the second flow channel and the working fluid having passed through the first waste-heat recovery heat exchange facility, the merged stream of working fluid passing through the second waste-heat recovery heat exchange facility and flowing into the supercritical fluid power generation facility, and wherein the input of the waste-heat recovery heat exchange facility that is provided on the second flow channel includes the merged stream, such that the output port of the bypass channel is connected between the working fluid heat exchanger and the merged stream. 9. A combined power generation system performing pressure difference power generation, the combined power generation system comprising: a pressure difference power generation facility for generating electricity by using a pressure change of natural gas; a heating unit confi