Cooling module, supercritical fluid power generation system including the same, and supercritical fluid supply method using the same

What is claimed is: 1. A cooling module comprising: a cooling source flow unit in which a cooling source supplied from an outside flows; a cooler unit configured to enable a gas-phase working fluid introduced through a working fluid inlet port to undergo a phase change into a liquid-phase working fluid by performing heat exchange with the cooling source flowing in the cooling source flow unit; a buffer unit provided under the cooler unit and configured to receive and store the liquid-phase working fluid cooled by the cooler unit and to supply the stored liquid-phase working fluid to the outside; a housing including a cooler unit housing of the cooler unit and a buffer unit housing of the buffer unit, the cooler unit and the buffer unit being integrally formed to constitute the housing; and an opening and closing unit made of an insulating material disposed between the cooler unit housing and the buffer unit housing, the opening and closing unit having a panel shape corresponding to the buffer unit housing and being configured to move horizontally through the housing in order to selectively open and close the buffer unit, wherein the cooling source flow unit comprises a cooler-side flow unit extending via the cooler unit and a buffer-side flow unit extending via the buffer unit, wherein a cooling source flowing in the cooler-side flow unit performs heat exchange with the working fluid introduced into the cooler unit, a cooling source flowing in the buffer-side flow unit performs heat exchange with the working fluid stored in the buffer unit, and the cooler-side flow unit and the buffer-side flow unit are connected to each other outside the cooler unit, wherein the cooling source flow unit branches into the cooler-side flow unit and the buffer-side flow unit, and wherein the cooling source flowing in the buffer-side flow unit first performs heat exchange with the working fluid stored in the buffer unit and then joins the cooling source flowing in the cooler-side flow unit at a junction located outside the cooler unit housing. 2. The cooling module according to claim 1 , wherein the buffer unit includes an upper part disposed below a lower part of the cooler unit, and wherein the lower part of the cooler unit structurally communicates with the upper part of the buffer unit, the structural communication between the cooler unit and the buffer unit enabling the buffer unit to receive the liquid-phase working fluid cooled by the cooler unit. 3. The cooling module according to claim 1 , wherein the opening and closing unit selectively opens and closes the buffer unit by moving between an open state and a closed state, and wherein, in the closed state, the panel shape of the opening and closing unit is further configured to insulate the buffer unit from the cooler unit in order to prevent evaporation of the stored liquid-phase working fluid in the buffer unit by the gas-phase working fluid in the cooler unit that is not yet in a cooled state. 4. The cooling module according to claim 1 , wherein the cooling source flow unit is configured to pass sequentially through the buffer unit and the cooler unit, and wherein the cooling source performs heat exchange with the working fluid stored in the buffer unit and then performs heat exchange with the working fluid introduced into the cooler unit. 5. The cooling module according to claim 1 , wherein the cooling source flow unit is configured such that the cooling source is introduced through one side of the cooler unit and is discharged through the one side of the cooler unit. 6. The cooling module according to claim 5 , wherein the cooling source flow unit has a U-shaped configuration including an upper flow unit and a lower flow unit, the upper and lower flow units each having a far end arranged at a midpoint of a path of the cooling source flow unit through the cooler unit, the U-shaped configuration further including a 180-degree bend that is disposed adjacent to another side of the cooler unit opposite to the one side and connects the far ends of the upper and lower flow units, wherein each of the upper and lower flow units extends from the one side of the cooler unit toward the other side of the cooler unit opposite to the one side, and wherein the cooling source that flows in the upper flow unit first performs heat exchange with the working fluid introduced through the working fluid inlet port, and the cooling source that flows in the lower flow unit then performs heat exchange with the working fluid that has performed heat exchange with the cooling source in the upper flow unit. 7. The cooling module according to claim 1 , wherein the buffer unit receives a liquid-phase working fluid from the outside. 8. The cooling module according to claim 1 , further comprising an auxiliary cooler unit having a refrigerant flow path, a portion of the refrigerant flow path located in each of the buffer unit and the cooler unit. 9. The cooling module according to claim 1 , wherein the buffer unit has an aspect ratio greater than 1. 10. The cooling module according to claim 1 , wherein the joining of the cooling source flowing in the buffer-side flow unit and the cooling source flowing in the cooler-side flow unit does not occur inside the cooler unit, and wherein the cooling source flowing in the buffer-side flow unit joins the cooling source flowing in the cooler-side flow unit at an inlet of the cooler unit. 11. The cooling module according to claim 1 , wherein the joining of the cooling source flowing in the buffer-side flow unit and the cooling source flowing in the cooler-side flow unit does not occur inside the cooler unit, and wherein the cooling source flowing in the buffer-side flow unit joins the cooling source flowing in the cooler-side flow unit at an outlet of the cooler unit. 12. The cooling module according to claim 1 , wherein the cooler unit includes an inlet communicating with the cooler-side flow unit and an outlet communicating with the cooler-side flow unit, wherein the buffer unit includes an inlet communicating with the buffer-side flow unit and an outlet communicating with the buffer-side flow unit, wherein the inlet of the buffer unit communicates with the branch of the cooling source flow unit, and wherein the outlet of the buffer unit communicates with the cooler-side flow unit outside the cooler unit, the outlet of the buffer unit communicating with the cooler-side flow unit at one of a first communication point occurring at the outlet of the cooler unit and a second communication point occurring between the branch of the cooling source flow unit and the inlet of the cooler unit. 13. A power generation system comprising: a cooling module comprising a cooling source flow unit in which a cooling source supplied from an outside flows, a cooler unit configured to enable a gas-phase working fluid introduced through a working fluid inlet port to undergo a phase change into a liquid-phase working fluid by performing heat exchange with the cooling source flowing in the cooling source flow unit, a buffer unit provided under the cooler unit and configured to receive and store the liquid-phase working fluid cooled by the cooler unit and to supply the stored liquid-phase working fluid to the outside; a housing including a cooler unit housing of the cooler unit and a buffer unit housing of the buffer unit, the cooler unit and the buffer unit being integrally formed to constitute the housing; and an opening and closing unit made of an insulating material disposed between the cooler unit housing and the buffer unit housing, the opening and closing unit having a panel shape corresponding