1. Technical Field
The present disclosure is directed to tension members such as those used in elevator systems for suspension and/or driving of the elevator car and/or counterweight.
2. Description of the Related Art
Traction elevators are widely used. In general, a traction elevator system can include a car, a counterweight, one or more tension members interconnecting the car and counterweight, a traction sheave to move the tension member, and a motor-driven machine to rotate the traction sheave. The sheave is formed from cast iron.
In some elevators, the tension member is a rope formed from twisted steel wires. In other elevators, the tension member is a belt with the twisted wires retained in a polymer jacket. In any event, the transfer of the propulsive load between the sheave and the tension member requires coupling of shear forces along the contact length between the sheave and the tension member. With a belt as the tension member, if the shearing force exceeds the total pullout strength along the contact length, the jacket may crack, deform, or even separate from the belt.
In general, a conventional elevator tension member can include a plurality of steel wires of specific number, size and geometry for purposes of strength, cost of production, and/or durability. The polymer jacket used to retain the steel wires is usually made of polyurethane or other suitable polymer materials. However, as the tensile strength of steel is significantly higher than that of polyurethane, the polymer jacket may be susceptible to premature wear under the aforementioned shear forces, especially along the contact length between the steel wire and the iron sheave.
One way to address this issue is to reinforce the jacket with secondary tension members. For example, one elevator belt is known as including a plurality of planar steel cords encased in a polyurethane jacket, which is reinforced with a plurality of polymer cords distributed throughout the entire jacket. Moreover, each polymer cord is extending through the entire length of the belt. While effective in providing reinforcement to the elevator belt, the polymer cords may increase bending stiffness and may cause localized stress concentration, either of which may adversely affect the performance or service life of the elevator belt. Moreover, the polymer cords distributed throughout the entire jacket may increase the production cost and production time of the elevator belt.
Some power transmission belts, such as timing belts or serpentine belts in automobiles, includes interwoven reinforcement fibers encased in a polymer jacket. Such designs are labor intensive and consume more material, but are necessary for the strength of the belt due to the lack of stronger primary tension members (e.g. steel wires) in the power transmission belts.
In the present application, a tension member for an elevator system is disclosed. The tension member longitudinally extends along a longitudinal axis and includes a plurality of fibers formed into one or more primary strands or cords extending parallel to the longitudinal axis and a plurality of fibers formed into one or more secondary strands or cords extending along the longitudinal axis and through less than the full length of the belt. The secondary strands or cords have a tensile modulus greater than a tensile modulus of the jacket and less than a tensile modulus of the primary strands or cords. The tension member further includes a jacket at least substantially retaining the primary and secondary strands or cords.
Alternatively in this or other aspects of the invention, the tensile modulus of the secondary strands or cords is at least ten times the tensile modulus of the jacket.
Alternatively in this or other aspects of the invention, the tensile modulus of the primary strands or cords is about 10-100 times of the tensile modulus of the secondary strands or cords.
Alternatively in this or other aspects of the invention, the jacket is made of polyurethane and the primary strands or cords are made of steel.
Alternatively in this or other aspects of the invention, the secondary strands or cords are made of aramid, such as para-aramid.
Alternatively in this or other aspects of the invention, each and every primary strand or cord is positioned within a primary tension zone and each and every secondary tension strand or cord is positioned outside of the primary tension zone.
Alternatively in this or other aspects of the invention, the primary tension zone is defined by two imaginary planes parallel and equidistant to the longitudinal axis of the tension member.
Alternatively in this or other aspects of the invention, all of the primary strands or cords are coplanar.
Alternatively in this or other aspects of the invention, the secondary strands or cords are located on one side of the primary tension zone.
Alternatively in this or other aspects of the invention, the secondary strands or cords are located on both sides of the primary tension zone.
Alternatively in this or other aspects of the invention, the tension member is in frictional contact with a traction sheave of an elevator system. The elevator system may further include a driving machine to rotate the traction sheave.
Alternatively in this or other aspects of the invention, each of the secondary strands or cords is longer than the contact length between the tension member and traction sheave of the elevator system.
Alternatively in this or other aspects of the invention, the elevator system includes a driving machine to rotate the traction sheave.
Alternatively in this or other aspects of the invention, the tension member extends between an elevator car and a counterweight
A method of forming an elevator tension member extending along a longitudinal axis is also disclosed. In a general embodiment, the method includes the steps of arranging a plurality of primary strands or cords along the longitudinal axis; arranging a plurality of secondary strands or cords along the longitudinal axis; and at least substantially retaining the primary and secondary strands or cords in a jacket. The secondary strands or cords are shorter than the primary strands or cords and extending less than the full length of the belt, and the secondary strands or cords have a tensile modulus greater than a tensile modulus of the jacket and less than a tensile modulus of the primary strands or cords.
Alternatively in this or other aspects of the invention, the secondary strands or cords are retained in the jacket before the primary strands or cords.
Alternatively in this or other aspects of the invention, the primary strands or cords are retained in the jacket before the secondary strands or cords.
Alternatively in this or other aspects of the invention, the primary strands or cords are retained in a first portion of the jacket and the secondary strands or cords are retained in a second portion of the jacket before the first and second portions of the jacket are fused together to form the tension member.
Finally, an elevator system is disclosed as including a traction sheave and a tension member engaging said traction sheave along a distance. The tension member longitudinally extends along a longitudinal axis and includes a plurality of fibers formed into one or more primary strands or cords extending parallel to the longitudinal axis, a plurality of fibers formed into one or more secondary strands or cords extending parallel to the longitudinal axis, and a jacket at least substantially retaining the primary and secondary strands or cords. The secondary strands or cords have a tensile modulus greater than a tensile modulus of the jacket and less than a tensile modulus of the primary strands or cords. The primary strands or cords have a length substantially greater than said distance and said secondary strands or cords have a length approximately equal to said distance.
Other advantages and features of the disclosed elevator tension member and method of making thereof will be described in greater detail below. It will also be noted here and elsewhere that the device or method disclosed herein may be suitably modified to be used in a wide variety of applications by one of ordinary skill in the art without undue experimentation.
For a more complete understanding of the disclosed device and method, reference should be made to the embodiments illustrated in greater detail in the accompanying drawings, wherein:
It should be understood that the drawings are not necessarily to scale and that the disclosed embodiments are sometimes illustrated diagrammatically and in partial views. In certain instances, details which are not necessary for an understanding of the disclosed device or method which render other details difficult to perceive may have been omitted. It should be understood, of course, that this disclosure is not limited to the particular embodiments illustrated herein.
Turning to
The phrase “substantially retained” means that the jacket 24 has sufficient engagement with the strands or cords (23, 26) such that the strands or cords (23, 26) do not pull out of, detach from, and/or cut through the jacket 24 during the application on the tension member 16 of a load that can be encountered during use in the elevator system 10. In other words, the strands or cords (23, 26) remain at their original positions relative to the jacket 24 during use in an elevator system 10. The jacket 24 could completely encase/envelop the strands or cords (23, 26) (such as shown in
Still referring to
The jacket 24 may be formed of any suitable material, including a single material, multiple materials, two or more layers using the same or dissimilar materials, and/or a film. In one arrangement, the jacket 24 could be a polymer, such as an elastomer like a thermoplastic polyurethane material applied to the primary strands or cords 23 using, for example, an extrusion or a mold wheel process. Other materials may also be used to make the jacket 24, provided that strength and durability of such materials are sufficient to meet the required functions of the tension member, including traction, wear, transmission of traction loads to the one or more primary strands cords 23 and resistance to environmental factors. The jacket 24 may also contain a fire retardant composition. In addition, the composite tensile properties of the secondary cords or fibers and the jacket are expected to be enhanced over the properties of an unsupported jacket. In this manner, jacket materials with insufficient properties to meet all belt properties, but with other desirable properties, such as damping or fire retardancy, can be made to provide sufficient properties for use in an elevator belt.
In accordance with one aspect of this disclosure, the tension member 16 includes a plurality of secondary strands or cords 26 retained in the jacket 24. As illustrated in
One feature of the tension member 16 in some embodiments of this disclosure is that the secondary strands or cords 26 may have a tensile modulus greater than that of the jacket 24 and less than that of the primary strands or cords 23. In one non-limiting embodiment, the tensile modulus of the secondary strands or cords 26 is at least about ten times or even at least about 100 times of the tensile modulus of the jacket 24. In another non-limiting embodiment, the tensile modulus of the primary strands or cords 23 is from about 1.5 to about 3 times of the tensile modulus of the secondary strands or cords 26.
As a non-limiting example, the secondary strands or cords 26 may be made of an aromatic polyamide material, such as aramids. Aramids are generally prepared by the reaction between an amine group and a carboxylic acid halide group. Simple AB homopolymers may formed through the following reaction:
nNH2—Ar—COCl→—(NH—Ar—CO)n—+nHCl
The most well-known commercial aramids are Kevlar®, Twaron®, Nomex®, New Star®, Teijinconex® and X-fiper®, all of which are AABB-type polymers. Among those aramids, Nomex®, Teijinconex®, New Star and X-Fiper® contain predominantly the meta-linkage and are poly-metaphenylene isophtalamides (MPIA). On the other hand, Kevlar® and Twaron® are both p-phenylene terephtalamides (PPTA), the simplest form of the AABB-type para-polyaramide. PPTA is a product of p-phenylene diamine (PPD) and terephtaloyl dichloride (TDC or TCl). In one embodiment of the present application, the secondary cords are formed of Kevlar®. The tensile modulus of steel (exemplary material for the primary cords), Kevlar® (exemplary material for the secondary cords), and thermoplastic polyurethane (exemplary material for the jacket) are listed in Table 1 below.
Referring now to
In addition to the material and length of the secondary strands or cords 26 used in the tension member 16, the configuration (position and distribution) of the secondary strands or cords 26 within the jacket 24 may also contribute to the desirable features of the disclosed tension member 16.
Referring now to
Turning now to
It is to be understood that the cross-sectional profiles of the secondary strands or cords 26 illustrated in
Further, although the jacket 24 is illustrated in
Without wishing to be bound by any particular theory, it is contemplated by the inventors of the present application that the localization of the primary and secondary cords to distinct tension zones as disclosed herein, the tensile strength and/or the service life of the tension member 16 may be improved without the high cost, complex construction, relatively high bending stiffness, and/or localized stress concentration associated with known reinforcement structures, an insight heretofore unknown.
In addition, the tension member 16 disclosed in the present application includes secondary strands or cords 26 that are mechanically isolated from one another. In other words, the shear force exerted on each secondary strands or cord 26 is not transferred to adjacent secondary cords through interweaved structures as in automobile timing belts and serpentine belts. As a result of such a non-interference configuration, the tension member 16 according to this disclosure can be made with less material, through a simpler manufacturing process, and in a shorter period of time.
Referring now to
In one embodiment, the secondary cords are introduced into the thermoplastic polyurethane before the polyurethane is extruded onto the primary cords. In another embodiment, thermoplastic polyurethane is extruded onto the primary cords before the secondary cords are introduced to form the final tension member product. In yet another embodiment, thermoplastic polyurethane is extruded separately onto the primary and secondary cords before the two jacketed cords are thermally fused together. Other manufacturing method may also be used in light of this disclosure.
The tension member and method of making thereof disclosed herein may have a wide range of industrial, commercial or household applications. The tension cord may be conveniently installed in existing elevator systems without significant modifications thereto. Moreover, as discussed above, the tensile strength and/or the service life of the tension member 16 may be improved without the high cost, complex construction, bending stiffness, and/or localized stress concentration associated with known reinforcement structures.
While only certain embodiments have been set forth, alternative embodiments and various modifications will be apparent from the above descriptions to those skilled in the art. These and other alternatives are considered equivalents and within the spirit and scope of this disclosure.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US11/39896 | 6/10/2011 | WO | 00 | 10/23/2013 |