Title of Invention

"SHEAVE FOR USE IN AN ELEVATOR SYSTEM"

Abstract An elevator sheave (20) includes a belt guiding surface (26) having a surface profile along at least a portion of the belt guiding surface. The surface profile preferably is defined by an nth order polynomial equation where n is a number greater than 2. In one example, the reference point (40) is a central point along the width of the belt guiding surface (26). In one example, a central portion (42) of the surface profile preferably is aligned to be generally parallel with the central axis (34) of the sheave body. Some examples have curvilinear side portions (44, 46) between the central portion (42) and the edges (28, 30) of the sheave. Other examples also include second side portions (48, 50) that have linear profiles. FIG. 1
Full Text 1. Field of the Invention
This invention generally relates to elevator sheaves and more particularly, to a unique belt guiding surface configuration on an elevator sheave.
2. Description of the Related Art
Elevator systems are widely known and used. Typical arrangements include an elevator cab that moves between landings in a building, for example to transport passengers or cargo to different levels in the building. A load bearing member, such as a rope or a belt typically supports the weight of the cab as it moves through the hoistway.
As the cab moves through the hoistway, the load bearing member typically moves over at least one sheave. In some instances the sheave is a drive sheave, which is coupled to a motorized mechanism for moving the elevator cab as desired. In other instances, sheaves are passive and move responsive to movement of the load bearing member.
While elevator sheaves have been in use for a long time, there is a need for an improvement in their design to maximize the longevity of the elevator system components, such as the load bearing member. For example, flat belts typically are subjected to overload stresses as the belt moves over the sheave. Additionally, because the elevator sheave axis is typically not perfectly aligned with the supporting mechanism axis, there is a tendency for the belt to move sideways along the sheave as the sheave rotates. While crowned sheave surfaces have been used to improve belt-tracking behavior, they have the associated drawback of introducing an overload in at least some of the cords in the central region of the bell. Coated steel belts in which a plurality of steel cords arc imbedded in a polymer coating are particularly subject to such strain because those belts are designed to be axially very stiff. The cords are not uniformly stressed, resulting in uneven loading. Additionally, conventional crown designs do not adequately accommodate tracking behavior under all circumstances.
There is a need for an improved elevator sheave design that optimizes tracking performance of the load bearing member and reduces overall stress on the load bearing member. This invention addresses that need while avoiding the shortcomings and drawbacks of the prior art.
SUMMARY OF THE INVENTION
An exemplary disclosed sheave for use in an elevator system has a belt guiding surface that maximizes tracking capabilities while minimizing stress induced on the load bearing member.
An example sheave includes a sheave body that has a central axis about which the sheave rotates. A belt guiding surface includes a surface profile extending along at least a portion of the belt guiding surface. The surface profile preferably is defined by an equation that approximates an nlh degree polynomial, of a distance from a selected reference point on the belt guiding surface, where n is a number greater than 2.
In one example, the belt guiding surface includes a central portion that is aligned parallel with the central axis of the sheave. Side portions on either side of the central portion preferably are defined by an equation that approximates an nth degree polynomial of a distance from a selected reference point on the belt guiding surface, where n is any number. The latter example is particularly useful for embodiments where the width of the load bearing member or belt is greater than one-half of the width of the belt guiding surface.
In another example, first side portions on either side of the central portion are defined by an nth degree polynomial. Second side portions extend from the first side portions toward outer edges of the sheave. The second side portions in this example have a linear profile. Accordingly, a sheave designed according to this example provides three distinct zones on each side of a plane of symmetry through a center of the sheave.
The various features and advantages of this invention will become apparent to those skilled in the art from the following detailed description of the currently preferred embodimenis. The drawings that accompany the detailed description can be briefly descnbed as follows.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 diagrammatically illustrates an elevator sheave assembly designed according to an embodiment of this invention.
Figure 2 is a partial cross sectional illustration of the embodiment of Figure 1. Figure 3 illustrates selected features of an embodiment of this invention. Figure 4 schematically illustrates another example embodiment.
Figure I diagrammatically illustrates an elevator sheave assembly 20 where a sheave body 22 cooperates with a load beanng member 24. The load bearing member 24 in one example ,s a coated steel belt. The term, "belt" as used in this descnption should not be construed in its stnctest sense. An assembly designed according to this invention may accommodate flat belts, coated steel belts, or other synthetic core belts used in elevator systems. The term "belt." therefore, should be construed in a generic sense to include a variety of configurations of load beanng members useful in an elevator system.
The belt 24 is received upon a belt guiding surface 26 that extends between edges 28 and 30 on the illustrated sheave. The raised edges 28 and 30 are not included in another example sheave. The belt rides along the surface 26 as the sheave rotates about a central axis 34. The belt guiding surface preferably includes a surface profile along at least a portion of the width of the belt guiding surface. The surface profile preferably provides an at least partially crowned surface along which the belt ndes on the sheave. As can be appreciated from Figure 2. the belt guiding surface 26 includes a surface profile that extends in an axial direction and is at least partially convex as seen in a radial cross section of the sheave 22.
In one example, the surface profile is approximated by a higher order polynomial equation. This equation may be expressed as y=|xn| where n is a number greater than 2. y is along an axis perpendicular to the sheave ax.s of rotation 34 and x is a distance measured from a reference point 40 on the belt guiding surface 26 in a direction parallel to the sheave axis of rotation. In the illustrated example, the reference point 40 is at a central location along the width of the belt guiding surface 26.
The example surface profiles maximize the tracking behavior of the belt 24 on the belt guiding surface 26 while minimizing the stresses on the belt caused by the shape of the profile. The example surface profiles enhance tracking robustness because they maintain adequate spacing between the edges on a belt and the sides of the sheave.
In examples as shown in Figure 3, where the width w of the belt 24 ,s greater than one-half the width c of the belt guid.ng surface 26. the surface profile preferably includes a fiat central portion 42. A distance between each point along the central port.on 42 and the central axis 34 is equal in the illustrated example. In other words, the example central portion 42 preferably is aligned entirely parallel with the central ax.s 34 of the sheave 22.
Side portions 44 and 46 of the surface profile preferably extend between the central portion 42 and the edges 28 and 30 of the belt guiding surface, respectively. Each of the side portions 44 and 46 preferably is approximated by the equation y = xn where n is any number
In the example of Figure 3, n = 2. In one example, the surface 26 has various sections with different n values. In another example, the surface 26 has portions with different n values on each side of the center of the surface 26 such that the surface 26 is asymmetric about the center.
A crown design as shown in Figure 3 preferably is flat along the section of the top of the crown that cannot be accessed by the trailing edge of the belt 24. The width of the central portion 42 preferably is equal to the difference between the width w of the belt 24 and the width c of the belt guiding surface 26. The distance f indicated in Figure 3 preferably is equal to w-c/2. Therefore, whenever there is spacing between the edges of the belt 24 and the edges 28 and 30 of the sheave, respectively, neither belt edge will be on the flat central portion 42.
Figure 4 illustrates another example where the belt guiding surface 26 has a central portion 42 that is aligned parallel with the sheave axis of rotation 34. First side portions 44 and 46 extend away from opposite sides of the central portion 42. In this example, the first side portions 44 and 46 have a profile described by an nth order polynomial, where n is any number. In one particular example, n is greater than 2. In this example, the first side portions 44 and 46 do not extend all the way toward ends 28 and 30 of the sheave.
Second side portions 48 and 50 extend between the first side portions 46 and 44, respectively, and the edges of the belt guiding surface 26. In this example, the second side portions 48 and 50 have a surface profile that is linear. In the illustrated example, the belt guiding surface 26 is symmetrical about a plane through a center of the sheave (i.e.. a vertical plane extending into the page).
In examples as shown in Figure 4, the second side portions 50 and 48 preferably are linear. Having a linear profile section near the edges of the belt guiding surface 26 maintains the tracking efficiency of an arrangement having a curved surface extending between the central portion and the edges of the belt guiding surface 26. Having a linear profile, however, reduces the effect of the curved surface that would tend to compromise the service life of the belt without limiting the tracking efficiency of the most outward portions of the belt guiding surface 26. This is accomplished, in part, because the loads on the portions of the belt nding over the outermost portions of the belt guiding surface 26 carry significantly lower loads than the portions of the belt nding over the central portion 42 and the more central areas of the first side portions 44 and 46.
In the figures, transitions between portions of the guiding surfaces 26 are somewhat exaggerated for illustration. In an example sheave, the guiding surface is machined from a
single piece of matenal and presents a continuous, uninterrupted surface across the entire sheave.
The preceding description is exemplary rather than limiting in nature. Variations and modifications to what has been disclosed above may become apparent to those skilled in the art that do not necessarily depart from the essence of this invention. The scope of legal protection given to this invention can only be determined by studying the following claims.








We claim:
1. A sheave (20) for use in an elevator system, comprising:
a sheave body having a central axis (34) and a crowned belt guiding surface (26) including a surface profile extending in an axial direction along at least a portion of the belt guiding surface, the surface profile defined as an nth degree polynomial of a distance from a selected reference point (40) on the belt guiding surface where n is a number greater than 2.
2. The sheave as claimed in claim 1, wherein the sheave (20) comprises a first edge of the surface profile spaced a first nominal distance from the central axis (34) and said reference point (40) is spaced a second distance from the central axis that is greater than the first distance.
3. The sheave as claimed in claim 2, wherein the sheave (20) comprises a central portion (42) of the surface profile having a width and an equal distance to the central axis (34) along the entire central portion.
4. The sheave as claimed in claim 1, wherein the sheave (20) comprises a central portion (42) of the surface profile that has a width and is aligned parallel to the central axis (34).
5. The sheave as claimed in claim 4, wherein the central portion (42) is entirely equally distant from the central axis (34).
6. The sheave as claimed in claim 4, wherein the sheave (20) comprises first side portions (46,44) on opposite sides of the central portion (42), said first side portions have a surface profile defined by the nth degree polynomial, and comprises second side portions (50,48) extending from the first side portions toward edges of the belt guiding surface (26), the second side portions having a linear profile.

7. An assembly for use in an elevator system, comprising;
a belt having a width; and
a sheave as claimed in claim 1 that supports the belt and is rotatable about a central axis (34) as the belt moves, the sheave (20) including a crowned belt guiding surface (26) having a width that extends between edges on opposite sides of the sheave, the entire belt guiding surface being a single piece of material that presents a continuous, uninterrupted surface, the belt guiding surface having a central portion that has a width across which the belt guiding surface is aligned parallel to the central axis so as to be, at least partially equidistant from the central axis, and side portions extending from the central portion (42) toward corresponding edges of the sheave that are curved relative to the central axis.
8. The assembly as claimed in claim 7, wherein the width of the central portion (42) of the belt guiding surface (26) is equal to approximately two times the difference between the belt width and one-half the width of the belt guiding surface.
9. The assembly as claimed in claim 7, wherein the central portion (42) extends in opposite directions from a center point on the belt guiding surface (26) and one-half of the central portion is on each side of the center point.

10. The assembly as claimed in claim 7, wherein the side portions of the belt guiding surface (26) each have a curvature defined by an nth order polynomial of a selected reference point (40) on the belt guiding surface.
11. The assembly as claimed in claim 7, wherein the entire central portion (42) is equally spaced from the central axis (34) and the distance between the central portion and the central axis is greater than the distance between the central axis and any point along the side portions.
12. The assembly as claimed in claim 7, wherein the belt width is greater than one-half the width of the belt guiding surface (26).

13. The assembly as claimed in claim 7, wherein the assembly comprises second side portions (50, 48) extending from the side portions toward the corresponding edges of the sheave (20), the second side portions having a surface profile that is linear.
14. A sheave (20) as claimed in claim 1 for use in an elevator system, comprising:
a sheave body have a central axis (34) and a crowned belt guiding surface (26) including a surface profile extending in an axial direction along at least a portion of the belt guiding surface, the surface profile having a central portion (42), first side portions (46, 44)extending away from opposite edges of the central portion toward corresponding edges of the sheave and second side portions (50, 48) extending away from the first side portions toward the corresponding edges of the sheave, the central portion having a width across which the surface profile has a parallel alignment with the sheave central axis, the first side portions having a curved profile and the second side portions have a linear profile.
15. The sheave as claimed in claim 14, wherein the entire central portion (42) is equally distant from the sheave (20) central axis (34).
16. The sheave as claimed in claim 14, wherein the first side portions (46, 44) have a surface profile defined as an nth degree polynomial of a distance from a selected reference point (40) on the belt guiding surface (26).
17. The sheave as claimed in claim 16, wherein n is a number greater than 2.

Documents:

7813-DELNP-2006-Abstract-(12-04-2010).pdf

7813-DELNP-2006-Abstract-(21-09-2010).pdf

7813-delnp-2006-abstract.pdf

7813-DELNP-2006-Claims-(12-04-2010).pdf

7813-DELNP-2006-Claims-(14-02-2011).pdf

7813-DELNP-2006-Claims-(21-09-2010).pdf

7813-delnp-2006-claims.pdf

7813-DELNP-2006-Correspondence-Others-(12-04-2010).pdf

7813-DELNP-2006-Correspondence-Others-(14-02-2011).pdf

7813-DELNP-2006-Correspondence-Others-(21-09-2010).pdf

7813-DELNP-2006-Correspondence-Others-(25-08-2010).pdf

7813-DELNP-2006-Correspondence-Others.pdf

7813-DELNP-2006-Description (Complete)-(12-04-2010).pdf

7813-DELNP-2006-Description (Complete)-(21-09-2010).pdf

7813-delnp-2006-description (complete).pdf

7813-DELNP-2006-Drawings-(12-04-2010).pdf

7813-DELNP-2006-Drawings-(21-09-2010).pdf

7813-delnp-2006-drawings.pdf

7813-DELNP-2006-Form-1-(12-04-2010).pdf

7813-DELNP-2006-Form-1-(21-09-2010).pdf

7813-delnp-2006-form-1.pdf

7813-delnp-2006-form-18.pdf

7813-DELNP-2006-Form-2-(21-09-2010).pdf

7813-delnp-2006-form-2.pdf

7813-DELNP-2006-Form-3-(25-08-2010).pdf

7813-DELNP-2006-Form-3.pdf

7813-delnp-2006-form-5.pdf

7813-DELNP-2006-GPA-(12-04-2010).pdf

7813-delnp-2006-pct-101.pdf

7813-delnp-2006-pct-220.pdf

7813-delnp-2006-pct-237.pdf

7813-delnp-2006-pct-search report.pdf


Patent Number 257640
Indian Patent Application Number 7813/DELNP/2006
PG Journal Number 43/2013
Publication Date 25-Oct-2013
Grant Date 22-Oct-2013
Date of Filing 21-Dec-2006
Name of Patentee OTIS ELEVATOR COMPANY
Applicant Address TEN FARM SPRINGS ROAD,FARMINGTON,CT 06032 USA
Inventors:
# Inventor's Name Inventor's Address
1 PRASAD DILIP 125 SOUTH STREET.APT. 289 VERNON,CT 06066 USA
2 CASSENTI BRICE N. 29 ARNOLD DRIVE,TOLLAND,CT 06084 USA
3 BARANDA PDERO S. QUINTA DO MARQUES,P-CASA 5 ALCABIDECHE PT PORTUGAL
4 VERONEST WILLIAM C. 342 FAIRFIELD AV.,HARTFORD CT 06114 USA.
5 PERRON WILLIAM C., 30 LAKEVIEW STREET,BURLINGTON CT 06013 USA
6 MELLO ARY O.JR., 6 PENFIELD PLACE,FARMINGTON,CT 06032 USA
7 STUCKY PAUL A., 1038 MELBOURNE AVENUE,STOCKTON,CA 95203 USA
8 PITTS JOHN T., 102 PARKVIEW DRIVE,AVON, CT 06001 USA.
9 WESSON JOHN P., 39 DONNELL ROAD,VERNON,CT 06066 USA.
10 THOMPSON MARK S., 151 OLD KENT ROAD,NORTH TOLLAND,CT 06084 USA.
PCT International Classification Number B66B9/02; B66B7/08; B66B11/06
PCT International Application Number PCT/US2004/025211
PCT International Filing date 2004-08-04
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 NA