Reserve tank

What is claimed is: 1. A reserve tank comprising: a gas-liquid separator that is shaped in a bottomed tubular form and is centered on a predetermined axis; a flow inlet portion that is formed at the gas-liquid separator and is configured to conduct coolant into an inside of the gas-liquid separator; a flow outlet portion that is formed at the gas-liquid separator and is configured to discharge the coolant from the inside of the gas-liquid separator; and a projection that is shaped in a tubular form and extends along the predetermined axis from a bottom wall at the inside of the gas-liquid separator, wherein: an annular flow passage is formed by a gap which is formed between an inner peripheral surface of the gas-liquid separator and an outer peripheral surface of the projection; an opening, which is formed at an inner surface of the gas-liquid separator and is communicated with the flow inlet portion, is defined as a flow inlet opening, and an opening, which is formed at the inner surface of the gas-liquid separator and is communicated with the flow outlet portion, is defined as a flow outlet opening; in an axial direction of the predetermined axis, the flow outlet opening is located on a bottom side of the flow inlet opening where the bottom wall of the gas-liquid separator is placed; in the axial direction of the predetermined axis, the flow inlet opening is located on the bottom side of a distal end portion of the projection where the bottom wall of the gas-liquid separator is placed; an inner space of the projection opens to an inner space of the gas-liquid separator at the distal end portion of the projection; a peripheral wall surface and a bottom of the projection, which are other than a distal end opening of the projection, are closed; the predetermined axis is defined as a first axis; the flow inlet portion is shaped in a tubular form and is centered on a second axis, which is perpendicular to the first axis; and the second axis is offset relative to the first axis in a direction which is perpendicular to both of the first axis and the second axis to form a swirl flow along an outer wall of the projection in the annular flow passage with the coolant discharged from the flow inlet opening of the flow inlet portion into the annular flow passage. 2. The reserve tank according to claim 1 , wherein a partition wall is formed at a portion of the annular flow passage, which is located on an upstream side of the flow inlet opening in a flow direction of the coolant that is swirled in the annular flow passage, to partition the annular flow passage. 3. The reserve tank according to claim 1 , wherein: a recess is formed at the bottom wall of the gas-liquid separator; and the flow outlet portion is formed to extend from the recess. 4. The reserve tank according to claim 3 , wherein the flow outlet portion is formed to extend from the recess along an outer surface of the bottom wall of the gas-liquid separator. 5. The reserve tank according to claim 3 , wherein the flow outlet portion is formed to extend from the recess toward an outer side of the gas-liquid separator. 6. The reserve tank according to claim 1 , wherein the flow outlet opening is formed at a portion of the bottom wall of the gas-liquid separator while the portion of the bottom wall forms an inner wall of the annular flow passage. 7. The reserve tank according to claim 1 , wherein: an inner diameter of the gas-liquid separator and an outer diameter of the projection satisfy the following equation: ( D−d )/2<13.9 [mm], where D denotes the inner diameter of the gas-liquid separator, and d denotes the outer diameter of the projection. 8. The reserve tank according to claim 7 , wherein: the inner diameter of the gas-liquid separator and the outer diameter of the projection satisfy the following equation: 2.1 [mm]<( D−d )/2, where D denotes the inner diameter of the gas-liquid separator, and d denotes the outer diameter of the projection. 9. The reserve tank according to claim 1 , wherein an outer diameter of the projection is larger than a passage width of the annular flow passage which is measured in a radial direction of the predetermined axis.