Modular sheave unit

We claim: 1. A modular sheave unit configured for being arranged on a mandrel of an elevator sheave system, the modular sheave unit comprising: a bearing that includes an outer race, an inner race and a plurality of rolling elements therebetween, wherein the outer and inner races extend to opposite axial ends of the modular sheave and the rolling elements are respectively seated at axial distal and proximate sides of the outer and inner races; and an outer sleeve axially surrounding the outer race, the outer sleeve including an outer sleeve surface defining a belt receiving groove, the belt receiving groove having a belt seating portion located at an axial center portion of the outer sleeve, having an arcuate convex curvature forming a belt seat and opposing flanged side walls for centering and providing transition fit with a belt. 2. The modular sleeve unit of claim 1 , wherein: the inner race includes an inner race surface configured to be positioned against the mandrel. 3. The modular sheave unit of claim 1 , wherein: an inner sleeve axially surrounded by the inner race and configured to be disposed between the inner race and the mandrel. 4. The modular sheave unit of claim 3 , wherein: the outer sleeve is formed from one of aluminum, plastic, thermoplastic polyurethane and rubber; and the inner sleeve is formed from another of aluminum, plastic, thermoplastic polyurethane and rubber. 5. The modular sheave unit of claim 1 , wherein the outer sleeve is formed from one of aluminum, plastic, thermoplastic polyurethane and rubber. 6. The modular sheave unit of claim 1 , wherein the bearing is a ball bearing. 7. An elevator sheave system comprising: a plurality of modular sheave units arranged side by side along a mandrel; and each of the modular sheave units including: a bearing that includes an outer race, an inner race and a plurality of rolling elements therebetween, wherein the outer and inner races extend to opposite axial ends of the modular sheave and the rolling elements are respectively seated at axial distal and proximate sides of the outer and inner races; and an outer sleeve axially surrounding the outer race, the outer sleeve including an outer sleeve surface defining a belt receiving groove, the belt receiving groove having a belt seating portion located at an axial center portion of the outer sleeve, having an arcuate convex curvature forming a belt seat and opposing flanged side walls for centering and providing transition fit with a belt. 8. The system of claim 7 , wherein: an inner race includes the inner race surface positioned against the mandrel; and adjacent pairs of the modular sheave units are configured so that axially facing surfaces of the outer sleeve are spaced from one another. 9. The system of claim 7 , wherein: an inner sleeve axially surrounded by the inner race and disposed between the inner race and the mandrel; and adjacent pairs of the modular sheave units are configured so that axially facing surfaces the inner sleeve are pressed against one another. 10. The system of claim 9 , wherein: the outer sleeve is formed from one of aluminum, plastic, thermoplastic polyurethane and rubber; and the inner sleeve is formed from another of aluminum, plastic, thermoplastic polyurethane and rubber. 11. The system of claim 7 , wherein the outer sleeve is formed from one of aluminum, plastic, thermoplastic polyurethane and rubber. 12. The system of claim 7 , wherein the bearing is a ball bearing. 13. The system of claim 7 , including: fastening devices located on opposing ends of the mandrel to secure the plurality of modular sheave units to the mandrel. 14. A method of configuring a modular sheave unit, comprising: arranging, a plurality of modular sheave units, side by side along a mandrel, each of the modular sheave units including: a bearing that includes an outer race, an inner race and a plurality of rolling elements therebetween, wherein the outer and inner races extend to opposite axial ends of the modular sheave and the rolling elements and respectively seated at axial distal and proximate sides of the outer and inner races; and an outer sleeve axially surrounding the outer race, the outer sleeve including an outer sleeve surface defining a belt receiving groove, the belt receiving groove having a belt seating portion located at an axial center portion of the outer sleeve, having an arcuate convex curvature forming a belt seat and opposing flanged side walls for centering and providing transition fit with a belt. 15. The method of claim 14 , wherein: the inner race includes an inner race surface positioned against the mandrel; and adjacent pairs of the modular sheave units are configured so that axially facing surfaces of the outer sleeve of are spaced from one another. 16. The method of claim 14 , wherein: an inner sleeve axially surrounded by the inner race and disposed between the inner race and the mandrel; and adjacent pairs of the modular sheave units are configured so that axially facing surfaces of the inner sleeve are pressed against one another. 17. The method of claim 16 , wherein: adjacent pairs of the modular sheave units are arranged so that: axially facing surfaces of the inner sleeve are pressed against one another; and axially facing surfaces of the outer sleeve are spaced from one another. 18. The method of claim 14 , comprising: arranging a fastening device on opposing ends of the mandrel to secure the plurality of modular sheave units to the mandrel.