Linear compressor

What is claimed is: 1. A linear compressor, comprising: a casing extending between a first end portion and a second end portion, the casing having a cylinder assembly positioned at the second end portion of the casing, the cylinder assembly defining a chamber; a piston slidably received within the chamber of the cylinder assembly; a driving coil mounted to the casing; an inner back iron assembly positioned in the driving coil, the inner back iron assembly having an outer surface; a magnet mounted to the inner back iron assembly at the outer surface of the inner back iron assembly such that the magnet faces the driving coil; and a machined spring comprising a first cylindrical portion mounted to the casing at the first end portion of the casing; a second cylindrical portion positioned within and fixed to the inner back iron assembly; a first helical portion extending between and coupling the first and second cylindrical portions together; a third cylindrical portion mounted to the casing at the second end portion of the casing; and a second helical portion extending between and coupling the second and third cylindrical portions together, a piston flex mount positioned in the machined spring, the piston flex mount coupled to the machined spring at the second cylindrical portion of the machined spring; and a flexible coupling extending between the piston flex mount and the piston, wherein a magnetic field of the driving coil engages the magnet in order to move the inner back iron assembly in the driving coil and the piston within the chamber of the cylinder assembly during operation of the driving coil. 2. The linear compressor of claim 1 , wherein the first, second and third cylindrical portions and the first and second helical portions of the machined spring are positioned coaxially relative to one another. 3. The linear compressor of claim 1 , wherein the first, second and third cylindrical portions and the first and second helical portions of the machined spring are continuous with one another. 4. The linear compressor of claim 1 , wherein the inner back iron assembly comprises an outer cylinder defining the outer surface of the inner back iron assembly and an inner surface positioned opposite the outer surface, the outer cylinder comprising a plurality of ferromagnetic laminations circumferentially distributed and mounted to one another, the inner back iron assembly also comprising a sleeve positioned on the inner surface of the outer cylinder, the sleeve extending between the inner surface of outer cylinder and the second cylindrical portion of the machined spring. 5. The linear compressor of claim 3 , wherein a first interference fit between the sleeve and the outer cylinder fixes the sleeve to the outer cylinder at the inner surface of the outer cylinder, wherein a second interference fit between the sleeve and the second cylindrical portion of the machined spring fixes the sleeve to the second cylindrical portion of the machined spring. 6. The linear compressor of claim 1 , wherein the piston flex mount defines an axial passage for directing a flow of fluid though the piston flex mount, wherein the piston defines an axial opening for directing the flow of fluid though the piston into the chamber of the cylinder assembly. 7. The linear compressor of claim 1 , wherein the first helical portion of the machined spring includes a first pair of helices that are separate from each other and the second helical portion of the machined spring includes a second pair of helices that are separate from each other, each helix of the first pair of helices extending between the first and second cylindrical portions, each helix of the second pair of helices extending between the second and third cylindrical portions. 8. The linear compressor of claim 7 , wherein the first and second pair of helices are oppositely wound. 9. The linear compressor of claim 1 , wherein the third cylindrical portion of the machined spring is threaded to the casing. 10. The linear compressor of claim 9 , wherein the first cylindrical portion of the machined spring is mounted to the casing with fasteners. 11. The linear compressor of claim 1 , wherein: the first, second and third cylindrical portions and the first and second helical portions of the machined spring are positioned coaxially relative to one another and are continuous with one another; the inner back iron assembly comprises an outer cylinder defining the outer surface of the inner back iron assembly and an inner surface positioned opposite the outer surface, the outer cylinder comprising a plurality of ferromagnetic laminations circumferentially distributed and mounted to one another, the inner back iron assembly also comprising a sleeve positioned on the inner surface of the outer cylinder, the sleeve extending between the inner surface of outer cylinder and the second cylindrical portion of the machined spring; a first interference fit between the sleeve and the outer cylinder fixes the sleeve to the outer cylinder at the inner surface of the outer cylinder, wherein a second interference fit between the sleeve and the second cylindrical portion of the machined spring fixes the sleeve to the second cylindrical portion of the machined spring; and the piston flex mount defines an axial passage for directing a flow of fluid though the piston flex mount, wherein the piston defines an axial opening for directing the flow of fluid though the piston into the chamber of the cylinder assembly. 12. A linear compressor defining a radial direction, a circumferential direction and an axial direction, the linear compressor comprising: a casing extending between a first end portion and a second end portion along the axial direction, the casing having a cylinder assembly positioned at the second end portion of the casing, the cylinder assembly defining a chamber; a piston received within the chamber of the cylinder assembly such that the piston is slidable along a first axis within the chamber of the cylinder assembly; a machined spring extending between the first and second end portions of the casing; an inner back iron assembly extending about the machined spring along the circumferential direction, the inner back iron assembly fixed to the machined spring at a middle portion of the machined spring; a driving coil extending about the inner back iron assembly along the circumferential direction, the driving coil operable to move the inner back iron assembly along a second axis during operation of the driving coil, the first and second axes being substantially parallel to the axial direction; a magnet mounted to the inner back iron assembly such that the magnet is spaced apart from the driving coil by an air gap along the radial direction; a piston flex mount positioned in the machine spring, the piston flex mount coupled to the machined spring at the middle portion of the machined spring; and a flexible coupling extending between the piston flex mount and the piston along the axial direction, wherein a magnetic field of the driving coil engages the magnet in order to move the inner back iron assembly along the second axis during operation of the driving coil. 13. The linear compressor of claim 12 , wherein the inner back iron assembly comprises an outer cylinder defining the outer surface of the inner back iron assembly and an inner surface positioned opposite the outer surface, the outer cylinder comprising a plurality of ferromagnetic laminations distributed along the circumferential direction and mounted to one another, the inner back iron assembly also comprising a sleeve positioned on the inner surface of the out