Linear compressor with a coupling

What is claimed is: 1. A linear compressor, comprising: a driving coil; a mover positioned adjacent the driving coil, the driving coil operable to reciprocate the mover relative to the driving coil; a piston having a piston head and a cylindrical side wall, an inner surface of the cylindrical side wall defining a ball seat; and a coupling extending between the mover and the piston, the coupling comprising a flex mount extending between a first end portion and a second end portion, the flex mount connected to the mover away from the first end portion of the flex mount; a ball nose positioned at the first end portion of the flex mount, the ball nose contacting the piston at the ball seat of the piston; a post extending from the piston into the flex mount; and a spring coupled to the post and the flex mount such that the spring urges the ball nose against the ball seat of the piston. 2. The linear compressor of claim 1 , wherein the flex mount comprises a tubular wall between the mover and the piston, a channel within the tubular wall configured for directing refrigerant though the flex mount towards the piston head of the piston. 3. The linear compressor of claim 2 , wherein the mover is mounted to the flex mount such that the mover extends around the tubular wall. 4. The linear compressor of claim 3 , wherein the channel extends between the first and second end portions of the flex mount within the tubular wall such that the refrigerant is flowable from the first end portion of the flex mount to the second end portion of the flex mount through the channel. 5. The linear compressor of claim 4 , wherein the coupling further comprises a muffler positioned within the tubular wall. 6. The linear compressor of claim 1 , wherein the flex mount and the ball nose are constructed with one or more thermoplastics. 7. The linear compressor of claim 1 , wherein the flex mount is constructed of a thermoplastic impregnated with glass fibers. 8. The linear compressor of claim 1 , wherein the ball nose has a frusto-spherical surface positioned against the ball seat of the piston, and the ball seat is shaped complementary to the frusto-spherical surface of the ball nose. 9. The linear compressor of claim 1 , wherein the flex mount comprises a tubular wall between the mover and the piston, the cylindrical side wall of the piston extending around the tubular wall of the flex mount at the first end portion of the flex mount such that an annular gap is defined between the cylindrical side wall of the piston and the tubular wall of the flex mount, and oil is flowable through the annular gap to an interface between the ball nose and the ball seat of the piston. 10. The linear compressor of claim 1 , wherein the flex mount has an annular flange at the first end portion of the flex mount, the ball nose has an annular flange, and the annular flange of the ball nose is positioned concentrically with the annular flange of the flex mount. 11. The linear compressor of claim 10 , wherein a radial gap is defined between the annular flange of the ball nose and the annular flange of the flex mount such that the ball nose is radially movable relative to the flex mount. 12. The linear compressor of claim 10 , wherein the spring compresses the ball nose between the flex mount and the ball seat of the piston. 13. The linear compressor of claim 1 , wherein the coupling further comprises a pre-load ring positioned within the flex mount at the first end portion of the flex mount, a head of the post is positioned opposite the piston head of the piston about the pre-load ring, the post is threaded to the piston head of the piston and extends through the pre-load ring, and the spring is compressed between the head of the post and the pre-load ring. 14. A linear compressor, comprising: a driving coil; a mover positioned adjacent the driving coil, the driving coil operable to reciprocate the mover relative to the driving coil; a piston having a piston head and a cylindrical side wall, an inner surface of the cylindrical side wall defining a ball seat; and a coupling extending between the mover and the piston, the coupling comprising a flex mount extending between a first end portion and a second end portion, the flex mount connected to the mover away from the first end portion of the flex mount, the flex mount having an annular flange at the first end portion of the flex mount; a ball nose positioned at the first end portion of the flex mount, the ball nose having a frusto-spherical surface positioned against the ball seat of the piston, the ball seat shaped complementary to the frusto-spherical surface of the ball nose, the ball nose having an annular flange, the annular flange of the ball nose positioned concentrically with the annular flange of the flex mount; a post extending from the piston into the flex mount; and a spring coupled to the post and the flex mount such that the spring compresses the ball nose between the flex mount and the ball seat of the piston, and wherein a radial gap is defined between the annular flange of the ball nose and the annular flange of the flex mount such that the ball nose is radially movable relative to the flex mount. 15. The linear compressor of claim 14 , wherein the flex mount comprises a tubular wall between the mover and the piston, a channel within the tubular wall configured for directing refrigerant though the flex mount towards the piston head of the piston. 16. The linear compressor of claim 15 , wherein the mover is mounted to the flex mount such that the mover extends around the tubular wall. 17. The linear compressor of claim 16 , wherein the channel extends between the first and second end portions of the flex mount within the tubular wall such that the refrigerant is flowable from the first end portion of the flex mount to the second end portion of the flex mount through the channel. 18. The linear compressor of claim 17 , wherein the coupling further comprises a muffler positioned within the tubular wall. 19. The linear compressor of claim 14 , wherein the flex mount comprises a tubular wall between the mover and the piston, the cylindrical side wall of the piston extending around the tubular wall of the flex mount at the first end portion of the flex mount such that an annular gap is defined between the cylindrical side wall of the piston and the tubular wall of the flex mount, and oil is flowable through the annular gap to an interface between the ball nose and the ball seat of the piston.