Electromagnetic pump

The invention claimed is: 1. An electromagnetic pump comprising: a piston that moves back and forth within a cylinder; an electromagnetic portion that moves the piston forward; and a spring that moves the piston backward, the piston including a discharge check valve built in the piston, wherein: the piston is formed with a hollow portion that opens in an inner peripheral portion of an end surface of the piston, and a spring receiving surface formed on an outer peripheral portion of the end surface to receive the spring; the discharge check valve is fixed through plastic deformation of the piston by inserting the discharge check valve into the hollow portion from an opening of the piston, and partially pressing a portion of the spring receiving surface of the piston on an inner peripheral side after the insertion to recess the spring receiving surface and elevate an inner peripheral surface of the piston surrounding the hollow portion causing portions of the inner peripheral surface of the piston to project inwardly towards a central axis of the piston, and the piston includes, on an outer peripheral surface of the piston, a distal-end portion that is formed continuously with the end surface of the spring receiving surface on an outer peripheral side and a sliding portion that is formed continuously with the distal-end portion and configured to enable sliding within the cylinder, and an outside diameter of the distal-end portion is smaller than that of the sliding portion. 2. The electromagnetic pump according to claim 1 , wherein a portion of the spring receiving surface on the outer peripheral side is a region against which the spring abuts, and a portion of the spring receiving surface on the inner peripheral side with respect to the region is the portion that is pressed when inserting the discharge check valve. 3. The electromagnetic pump according to claim 1 , wherein the piston is quenched except at an end portion of the piston having the end surface. 4. The electromagnetic pump according to claim 3 , wherein the quenching is high-frequency quenching. 5. The electromagnetic pump according to claim 1 , wherein the cylinder includes, on an inner peripheral side of the cylinder, a first inner wall that forms a pump chamber to accommodate the end surface of the piston and a second inner wall that is formed continuously with the first inner wall and over which the piston slides, and an inside diameter of the first inner wall is larger than that of the second inner wall. 6. The electromagnetic pump according to claim 1 , wherein: the piston is formed with a cylindrical space that communicates with a discharge port as the hollow portion; the discharge check valve includes a ball, an annular plug formed with a flow-in port for a working fluid, and a second spring that presses the ball against the flow-in port of the plug in a direction opposite to a flow-in direction of the working fluid, which are inserted into the hollow portion of the piston in the order of the second spring, the ball, and the plug; and the inner peripheral surface surrounding the hollow portion is elevated by the pressing to extend over the plug. 7. The electromagnetic pump according to claim 6 , wherein: the plug is formed with a tapered surface that becomes gradually larger in outside diameter from an end surface toward an outer peripheral surface, and inserted into the hollow portion with the tapered surface facing toward the opening; and the inner peripheral surface surrounding the hollow portion is elevated by the pressing to fill a gap between the inner peripheral surface and the tapered surface of the plug. 8. The electromagnetic pump according to claim 6 , wherein the plug is press-fitted into the hollow portion of the piston. 9. An electromagnetic pump comprising: a piston that moves back and forth within a cylinder; an electromagnetic portion that moves the piston forward; and a spring that moves the piston backward, the piston including a discharge check valve built in the piston, wherein: the piston is formed with a hollow portion that opens in an inner peripheral portion of an end surface of the piston, and a spring receiving surface formed on an outer peripheral portion of the end surface to receive the spring; the discharge check valve is fixed through plastic deformation of the piston by inserting the discharge check valve into the hollow portion from an opening of the piston, and partially pressing a portion of the spring receiving surface of the piston on an inner peripheral side after the insertion to recess the spring receiving surface and elevate an inner peripheral surface of the piston surrounding the hollow portion causing portions of the inner peripheral surface of the piston to project inwardly towards a central axis of the piston, and the cylinder includes, on an inner peripheral side of the cylinder, a first inner wall that forms a pump chamber to accommodate the end surface of the piston and a second inner wall that is formed continuously with the first inner wall and over which the piston slides, and an inside diameter of the first inner wall is larger than an inside diameter of the second inner wall. 10. The electromagnetic pump according to claim 9 , wherein a portion of the spring receiving surface on the outer peripheral side is a region against which the spring abuts, and a portion of the spring receiving surface on the inner peripheral side with respect to the region is the portion that is pressed when inserting the discharge check valve. 11. The electromagnetic pump according to claim 9 , wherein the piston is quenched except at an end portion of the piston having the end surface. 12. The electromagnetic pump according to claim 11 , wherein the quenching is high-frequency quenching. 13. The electromagnetic pump according to claim 9 , wherein: the piston is formed with a cylindrical space that communicates with a discharge port as the hollow portion; the discharge check valve includes a ball, an annular plug formed with a flow-in port for a working fluid, and a second spring that presses the ball against the flow-in port of the plug in a direction opposite to a flow-in direction of the working fluid, which are inserted into the hollow portion of the piston in the order of the second spring, the ball, and the plug; and the inner peripheral surface surrounding the hollow portion is elevated by the pressing to extend over the plug. 14. The electromagnetic pump according to claim 13 , wherein: the plug is formed with a tapered surface that becomes gradually larger in outside diameter from an end surface toward an outer peripheral surface, and inserted into the hollow portion with the tapered surface facing toward the opening; and the inner peripheral surface surrounding the hollow portion is elevated by the pressing to fill a gap between the inner peripheral surface and the tapered surface of the plug. 15. The electromagnetic pump according to claim 13 , wherein the plug is press-fitted into the hollow portion of the piston.