Insulated bearing

The invention claimed is: 1. An insulated bearing, comprising a pair of bearing rings arranged concentrically to each other and rolling elements arranged to be rotatable between the pair of bearing rings, a bearing ring of the bearing rings having an insulating layer formed thereon, wherein the bearing ring, having the insulating layer formed thereon, has two annular grooves that are formed on respective end surfaces of the bearing ring, the annular grooves each having an arc-shaped cross section, at least a surface from a non-raceway surface side circumferential surface to one of the annular grooves of the bearing ring is covered by the insulating layer, a distance between a groove bottom of each of the two annular grooves of the bearing ring in an axial width direction is less than a distance between raceway surface side end surfaces of the bearing ring in the axial width direction, the raceway surface side end surfaces respectively connected to the two annular grooves and respectively formed as a part of the end surfaces, and for each of the end surfaces of the bearing ring: the end surface includes a non-raceway surface side end surface, a respective one of the raceway surface side end surfaces, and the annular groove, formed on the end surface between the non-raceway surface side circumferential surface and the respective one of the raceway surface side end surfaces, and the annular groove and the non-raceway surface side end surface are connected to each other via an inclined surface, and the inclined surface includes a thinnest portion of the insulating layer from the non-raceway surface side circumferential surface to the annular groove. 2. The insulated bearing according to claim 1 , wherein: an axial width between the non-raceway surface side end surfaces is larger than an axial width between the raceway surface side end surfaces, and a thickness of the insulating layer formed on the annular grooves is thicker than a thickness of the insulating layer formed on the non-raceway surface side end surfaces. 3. The insulated bearing according to claim 2 , wherein: for each of the end surfaces of the bearing ring, having the insulating layer formed thereon, a cross-sectional shape of the annular groove, formed on the end surface, and the inclined surface is a composite arc obtained by compounding two single arcs, the single arcs being connected to each other. 4. An insulated bearing, comprising a pair of bearing rings arranged concentrically to each other and rolling elements arranged to be rotatable between the pair of bearing rings, a bearing ring of the bearing rings having an insulating layer formed thereon, wherein the bearing ring, having the insulating layer formed thereon by spraying, has two annular grooves that are formed on respective end surfaces of the bearing ring, the annular grooves each having an arc-shaped cross section, at least a surface from a non-raceway surface side circumferential surface to one of the annular grooves of the bearing ring is covered by the insulating layer, a distance between a groove bottom of each of the two annular grooves of the bearing ring in an axial width direction is less than a distance between raceway surface side end surfaces of the bearing ring in the axial width direction, the raceway surface side end surfaces respectively connected to the two annular grooves and respectively formed as a part of the end surfaces, and for each of the end surfaces of the bearing ring: the end surface includes a non-raceway surface side end surface, a respective one of the raceway surface side end surfaces, and the annular groove, formed on the end surface between the non-raceway surface side circumferential surface and the respective one of the raceway surface side end surfaces, and the annular groove and the non-raceway surface side end surface are connected to each other via only an inclined surface, and for each of the end surfaces of the bearing ring, having the insulating layer formed thereon, a cross-sectional shape of the annular groove, formed on the end surface, and the inclined surface is a composite arc obtained by compounding two single arcs, the single arcs being connected to each other. 5. The insulated bearing according to claim 4 , wherein: an axial width between the non-raceway surface side end surfaces is larger than an axial width between the raceway surface side end surfaces. 6. The insulated bearing according to claim 4 , wherein: the single arcs of the composite arc have a tangent line in common with each other at a joining point of the single arcs. 7. The insulated bearing according to claim 4 , wherein: the insulating layer is a ceramic thermal sprayed layer. 8. The insulated bearing according to claim 4 , wherein: a second bearing ring of the bearing rings has a second insulating layer formed thereon, wherein the second bearing ring, having the second insulating layer formed thereon, has two second annular grooves that are formed on respective second end surfaces of the second bearing ring, the second annular grooves each having an arc-shaped cross section, at least a surface from a non-raceway surface side circumferential surface to one of the second annular grooves of the second bearing ring is covered by the second insulating layer, and a distance between a groove bottom of each of the two second annular grooves of the bearing ring in the axial width direction is less than a distance between second raceway surface side end surfaces of the bearing ring in the axial width direction, the second raceway surface side end surfaces respectively connected to the two second annular grooves and respectively formed as a part of the second end surfaces. 9. The insulated bearing according to claim 4 , wherein: a distance, in the axial width direction, between the non-raceway surface side end surfaces of the end surfaces of the bearing ring is equal to a distance between the raceway surface side end surfaces of the bearing ring in the axial width direction. 10. The insulated bearing according to claim 4 , wherein: the insulating layer does not cover the raceway surface side end surfaces of the bearing ring.