Refrigerant compressor magnetic bearing

What is claimed is: 1. A refrigerant compressor comprising: an electric motor configured to rotationally drive an impeller via a shaft; a magnetic bearing assembly including an inner diameter within which the shaft is disposed, the magnetic bearing assembly having a lamination stack with coil apertures extending between opposing sides of the lamination stack, a continuous unitary insulation layer provided within the coil apertures and the opposing sides, and coils disposed within and extending between the coil apertures, wherein the insulation layer provides a coil aperture lining within each coil aperture and a wall formed entirely by the coil aperture lining within each coil aperture, wherein each wall bisects a respective coil aperture into first and second openings, and wherein the coils are disposed within and extend between the coil apertures; and a controller in communication with the magnetic bearing and configured to energize the coils and provide a magnetic field rotationally supporting the shaft. 2. The refrigerant compressor according to claim 1 , comprising a housing within which the electric motor and impeller are arranged, and a ring supporting the magnetic bearing assembly in the housing. 3. The refrigerant compressor according to claim 2 , wherein the lamination stack includes an outer diameter engaging the ring, and the insulation layer includes an outer periphery arranged radially inward of the outer diameter and beneath the coils. 4. The refrigerant compressor according to claim 1 , wherein the coil apertures include a gap facing radially inward providing a break at the inner diameter, and the insulation layer filling the gap with the coil aperture lining. 5. The refrigerant compressor according to claim 1 , comprising a refrigerant loop in fluid communication with the impeller, and wherein the lamination stack includes cooling holes extending between the opposing sides which are in fluid communication with the refrigerant loop. 6. A magnetic bearing assembly comprising: a lamination stack with coil apertures extending between opposing sides of the lamination stack; a continuous unitary insulation layer arranged on the opposing sides and within each of the coil apertures providing a coil aperture lining, and providing a wall formed entirely by the coil aperture lining within each of the coil apertures, wherein each wall bisects a respective coil apertures into first and second openings; and a coil portion disposed in each of the first and second openings, wherein coils are disposed within and extend between the coil apertures. 7. The magnetic bearing assembly according to claim 6 , wherein the insulation layer includes an outer periphery arranged radially inward of an outer diameter of the lamination stack and beneath the coils. 8. The magnetic bearing assembly according to claim 6 , wherein the coil apertures include a gap facing radially inward providing a break at an inner diameter of the lamination stack, and the insulation layer filling the gap with the coil aperture lining. 9. The magnetic bearing assembly according to claim 8 , wherein the wall extends from the gap radially outward to an opposite portion of the coil aperture lining. 10. The magnetic bearing assembly according to claim 7 , wherein cooling holes are circumferentially spaced about the lamination stack and extend between the opposing sides, the insulation including an outer periphery that extends radially to the cooling holes. 11. The magnetic bearing assembly according to claim 7 , comprising a ring engaging the outer diameter. 12. The magnetic bearing assembly according to claim 7 , wherein the coil apertures include a gap facing radially inward providing a break at an inner diameter of the lamination stack, and the wall terminates in a terminal end in proximity to the gap providing an opening in the insulation interconnecting the first and second openings. 13. A bearing stack comprising: magnetic layers laminated to one another providing an annular body having opposing sides, and including multiple coil apertures circumferentially spaced about the annular body and extending between the opposing sides; and a continuous unitary insulation layer arranged on the opposing sides and within the coil apertures, the continuous unitary insulation layer providing a coil aperture lining and a wall within each coil aperture, wherein each wall is formed entirely by the coil aperture lining and bisects a respective coil aperture into first and second openings. 14. The bearing stack according to claim 13 , wherein the coil apertures include a gap facing radially inward providing a break at an inner diameter of the annular body, and the insulation layer filling the gap with the coil aperture lining. 15. The bearing stack according to claim 14 , wherein the wall extends from the gap radially outward to an opposite portion of the coil aperture lining. 16. The bearing stack according to claim 13 , comprising cooling holes circumferentially spaced about the annular body and extending between the opposing sides, the insulation including an outer periphery that extends radially to the cooling holes. 17. The bearing stack according to claim 13 , wherein the coil apertures include a gap facing radially inward providing a break at an inner diameter of the lamination stack, and the wall terminates in a terminal end in proximity to the gap providing an opening in the insulation interconnecting the first and second openings.