Fuel pump

The invention claimed is: 1. A fuel pump comprising: a columnar plunger; a pump body having a cylinder, one end portion of the plunger being inserted in an interior of the cylinder and another end portion of the plunger projecting externally from the cylinder, the plunger being located inside the cylinder to slide in a reciprocating manner along a central axis of the plunger; a groove circumferentially extending along an outer surface of the plunger, the groove being formed at the other end portion of the plunger that projects externally from the cylinder; an annular disk-shaped plate having an inner circumferential surface engaged with the groove; a cam configured to reciprocate the plunger in the interior of the cylinder; a lifter located between the one end portion of the plunger and the cam; and a coil spring located between the pump body and the plate, the coil spring pressing the plate towards the lifter, wherein: a side force that acts in a direction perpendicular to a sliding direction of the plunger is generated in the coil spring during compression of the coil spring; a direction opposite to the direction of the side force is defined as a counter-side force direction when viewed along a central axis of the coil spring; the plate includes a joint port that connects an outer peripheral surface of the plate to the inner circumferential surface of the plate, the joint port extending in a direction aligned with the counter-side force when viewed along the central axis of the coil spring; and the lifter has a projection portion located in an interior of the joint port of the plate. 2. The fuel pump according to claim 1 , wherein the lifter is restricted from rotating about the central axis of the plunger with respect to the pump body. 3. The fuel pump according to claim 1 , further comprising a recess, wherein: the projection and the recess are configured to restrict relative rotation of the plate; and the coil spring is formed on a contact surface where the plate and the coil spring are brought into contact. 4. A fuel pump comprising: a columnar plunger; a pump body having a cylinder, one end portion of the plunger being inserted in an interior of the cylinder and another end portion of the cylinder projecting externally from the cylinder, the plunger being located inside the cylinder to slide in a reciprocating manner along a central axis of the plunger; a groove circumferentially extending along an outer surface of the plunger, the groove being formed at the other end portion of the plunger that projects externally from the cylinder; an annular disk-shaped plate having an inner circumferential surface engaged with the groove; a cam configured to reciprocate the plunger in the interior of the cylinder; a lifter located between the one end portion of the plunger and the cam; and a coil spring located between the pump body and the plate, the coil spring pressing the plate towards the lifter, wherein: a side force that acts in a direction perpendicular to a sliding direction of the plunger is generated in the coil spring during compression of the coil spring; a direction opposite to the direction of the side force is defined as a counter-side force direction when viewed along a central axis of the coil spring; the plate includes, when viewed along the central axis of the coil spring, a radial gap between the inner circumferential surface of the plate and the groove, the radial gap being larger at a location generally aligned with the counter-side force than at other locations when a central axis of the plate and a central axis of the plunger are coincident; and the lifter has a projection portion located in an interior of the radial gap of the plate. 5. The fuel pump according to claim 4 , wherein: the lifter is installed in a state of being restricted from rotating about the central axis of the plunger with respect to the pump body; and the plate is restricted from rotating about the central axis of the plunger with respect to the lifter. 6. The fuel pump according to claim 5 , further comprising a recess, wherein: the projection and the recess are configured to restrict relative rotation of the lifter; and the plate is formed on a contact surface where the lifter and the plate are brought into contact.