Heat exchanger

The invention claimed is: 1. A heat exchanger, comprising: a first plate having a pair of first-plate-side first communication holes; a pair of first-plate-side second communication holes; a pair of first-plate-side first protrusions, each of which surrounds a respective hole of the first-plate-side first communication holes; and a pair of first-plate-side second protrusions, each of which surrounds a respective hole of the first-plate-side second communication holes; a second plate having a pair of second-plate-side first communication holes; a pair of second-plate-side second communication holes; a pair of second-plate-side first protrusions, each of which surrounds a respective hole of the second-plate-side first communication holes; and a pair of second-plate-side second protrusions, each of which surrounds a respective hole of the second-plate-side second communication holes; a first spacer interposed between the first plate and the second plate; and a second spacer interposed between the first plate and the second plate, wherein the first plate and the second plate are alternately laminated to alternately form, between the first plate and the second plate, a first coolant flow path in which a first coolant flows and a second coolant flow path in which a second coolant flows, the first plate and the second plate being adjacent to each other; each of the pair of first-plate-side first protrusions overlaps with a respective protrusion of the pair of second-plate-side first protrusions within the second coolant flow path to form a first overlapped portion, such that the pair of first-plate-side first communication holes and the pair of second-plate-side first communication holes are opened to the first coolant flow path and are closed to the second coolant flow path; each of the pair of first-plate-side second protrusions overlaps with a respective protrusion of the pair of second-plate-side second protrusions within the first coolant flow path to form a second overlapped portion, such that the pair of first-plate-side second communication holes and the pair of second-plate-side second communication holes are closed to the first coolant flow path and are opened to the second coolant flow path; the first coolant has a higher pressure than the second coolant; the first coolant flow path is structured such that the first coolant flows into the first coolant flow path from one of the pair of first-plate-side first communication holes and one of the pair of second-plate-side first communication holes, and such that the first coolant which has passed through the first coolant flow path flows out of the other of the pair of first-plate-side first communication holes and the other of the pair of second-plate-side first communication holes; the second coolant flow path is structured such that the second coolant having a lower pressure than the first coolant flows into the second coolant flow path from one of the pair of first-plate-side second communication holes and one of the pair of second-plate-side second communication holes, and such that the second coolant which has passed through the second coolant flow path flows out of the other of the pair of first-plate-side second communication holes and the other of the pair of second-plate-side second communication holes; the first spacer is located around the first-plate-side first communication holes and the second-plate-side first communication holes, and the first spacer is located within the first coolant flow path, the second spacer is located around the first overlapped portion, and the second spacer is located within the second coolant flow path and reinforces the first overlapped portion to prevent buckling of the first overlapped portion, and the first spacer is located around the second overlapped portion within the first coolant flow path and reinforces the second overlapped portion to prevent buckling of the second overlapped portion. 2. The heat exchanger according to claim 1 , wherein the first spacer is structured to permit the first coolant to flow from the one of the pair of first-plate-side first communication holes and the one of the pair of second-plate-side first communication holes to the other of the pair of first-plate-side first communication holes and the other of the pair of second-plate-side first communication holes along the first coolant flow path. 3. The heat exchanger according to claim 1 , wherein an inner fin is disposed within the first coolant flow path, and the first spacer surrounds an outer periphery of the inner fin. 4. The heat exchanger according to claim 1 , wherein the first plate and the second plate each include an outer peripheral wall protruding toward the same direction of a laminating direction, and the outer peripheral wall is provided with a step portion, wherein the first plate and the second plate are located adjacent to each other and come into contact with each other at the step portion.