This invention generally relates to load bearing assemblies for elevator systems. More particularly, this invention relates to an arrangement for readily detecting localized strain in an elevator load bearing assembly.
Elevator systems typically include a cab and counterweight that are coupled together using an elongated load bearing member. Typical load bearing members include steel ropes and, more recently, synthetic ropes and multi-element ropes such as polymer coated reinforced belts. The increasing use of elevators in high-rise buildings has given rise to the need for an increasing use of the polymer coated reinforced belts because of their weight-to-strength ratios compared to steel roping arrangements.
Inspecting a load bearing member in an elevator system has been accomplished in several ways. With conventional steel roping, a manual, visual inspection of the rope allows the technician to determine when particular strands of the steel rope are frayed, broken or otherwise worn. This inspection method is limited, however, to the exterior portions of the rope and does not provide any indication of the condition of interior strands of the rope. Additionally, this inspection method is somewhat difficult and time consuming and does not always permit complete inspection of the entire length of the load bearing arrangement.
There are similar limitations on using visual inspection techniques on newer ropes. For example, the polymer coated reinforced belts do not permit visual inspection because of the coating that is typically applied over the cords, which are made up of strands of polymer material. Several advances have been proposed for facilitating inspection of such load bearing arrangements. One example is shown in U.S. Pat. No. 5,834,942 where a voltage detection unit is included in the load bearing member. By measuring an electrical voltage across that unit, a determination is made regarding the condition of the load bearing member. This proposal is limited, however, in that it does not provide any information regarding locations of strain along the length of the load bearing member. Moreover, there is no way of guaranteeing that a loss of conductivity through the voltage detection unit is directly correlated to strain or damage to the load bearing member. Another shortcoming of such an arrangement is that there is no qualitative information regarding degradation of the load bearing member over time.
There is a need for improved arrangements and methods for determining the condition of load bearing members in elevator assemblies. This invention provides a unique solution to that problem.
In general terms, this invention is a load bearing member assembly for use in an elevator system. The inventive arrangement includes a first material that forms a portion of the load bearing member. An element of a second material is associated with the load bearing member assembly. The second material has a material characteristic that distinguishes the second material from the first material. The element of second material is arranged relative to the remainder of the load bearing assembly such that it has a configuration that is repeated along the length of the load bearing member. Detecting the configuration of the element provides an indication of local strain on identifiable portions of the load bearing assembly.
One example arrangement includes a plurality of fibers of a first material that are arranged into a plurality of strands. At least one filament of a second material that has a characteristic that distinguishes it from the first material is associated with the plurality of strands. The filament of second material has a configuration that is repeated at consistent intervals along the length of the load bearing member when the load bearing member is in a first condition. The configuration of the filament of second material changes along a portion of the load bearing member responsive to a strain on that portion of the load bearing member. Therefore, changes in the configuration of the filament of second material provides an indication of the condition of the load bearing member at specific locations.
A method of this invention for assembling a load bearing member for use in an elevator system includes winding a plurality of fibers of a first material together to form a plurality of strands. An element of a second material, which has a different characteristic than the first material, is arranged relative to the strands such that the element of second material has a repeated configuration along the length of the load bearing member. The configuration of the element of second material changes along a portion of the length of the load bearing member responsive to strain on that portion of the load bearing member.
In one example, the method of assembling a load bearing member includes placing a filament of second material at the center of one of the strands and winding the strands together to form a cord. The winding pattern of the strand containing the second material filament provides the repeated configuration of the filament.
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 embodiment. The drawings that accompany the detailed description can be briefly described as follows.
The load bearing member assembly 26 may take a variety of forms. One example is a flat belt containing polymer reinforced strands. Other examples include flat, coated steel belts; synthetic ropes; and multi-element ropes. This invention is not limited to “belts” in the strictest sense. A flat belt is used as one example of a load bearing member designed according to this invention. Therefore, any reference to a “belt” within this description is not intended to be limiting in any sense.
The example load bearing member assembly 26 shown in
A load bearing member assembly designed according to this invention includes an element of a second material that has at least one characteristic that distinguishes it from the first material. The element of second material is associated with the remainder of the load bearing member such that the element has a configuration that is repeated at regular intervals along a length of the load bearing member. Example configurations include an internal property such as crystalline structure or an external property such as a physical arrangement relative to the load bearing member.
Localized strain in the load bearing member causes an alteration in the configuration of the second material element. Because the second material has at least one characteristic that distinguishes it from the first material, such alteration is readily measurable. The technique for measuring the alteration of the second material element depends upon the nature of the distinguishing characteristic. Changes in the configuration of the second material element can be correlated to a loss of strength or other alteration in the condition of the load bearing member.
Having a second material with a distinguishing characteristic and a repeated configuration along the length of the load bearing member provides a reliable source of information regarding localized strain on the load bearing member. A variety of distinguishing characteristics may be used. Some of the characteristics may be a physical characteristic of the second material. Example characteristics include density, magnetic absorption properties, wavelength absorption properties and crystalline structure. The chosen distinguishing characteristic will dictate the method of observing the geometry or configuration of the second material element. For example, when density is the distinguishing characteristic, x-ray technology may be used to obtain an image of the configuration of the second material element at discrete portions along the length of the load bearing member assembly. Known techniques can be used to observe the configuration of the second material element to obtain the desired information based upon the distinguishing characteristic used in a specific embodiment. Those skilled in the art who have the benefit of this description will be able to choose from among the possible materials, material characteristics and observation techniques to obtain the results provided by this invention.
There are a variety of ways to incorporate the second material element into the load bearing member assembly. One example includes integrating the second material element into the assembly of the load bearing member. In this example, the second material element is a filament 38 at the center of one of the strands. When the strands are wound together (in a helical arrangement, for example) the filament 38 has a resulting geometric pattern that is consistent with the lay length of the strands along the load bearing member. Observing the configuration of the filament 38 along the length of the load bearing member provides an indication of the structural condition of the load bearing member.
One example method of assembling a load bearing member 26 designed according to this invention includes placing the filament 38 at the center of a strand 32. In other words, a plurality of fibers 36 of the first material are placed in a position to surround the filament 38. Once that strand is assembled, it is then wound with other strands, each of which are made up of a plurality of fibers 36 of the first material. The winding together of the strands not only forms a cord but also establishes the configuration of the filament 38 that is repeated along the length of the load bearing member 26. A typical arrangement provides a helical geometry with a repeated period along the length of the load bearing member 26. The period of the filament 38 geometry in this example preferably corresponds directly to the lay length of one or more of the strands of the cord.
Obtaining an image such as that shown in
Because different patterns may be chosen the particular distinguishing characteristic and its relationship to the remainder of the load bearing member assembly preferably is chosen to optimize detection. The detectable element of second material may be incorporated into the load bearing member at any stage of assembly and may be used to provide an indication in a variety of ways.
The selection of the second material will depend, in part, on the first material used for making the load bearing member. A variety of commercially available materials can be used as the first or structural material. The structural material of the load bearing member may be, for example, a metal, multiple metals, metallic alloys or a metal matrix composite. Other possibilities include polymeric materials or any combination of polymeric and metallic materials. Example polymeric materials include PBO, which is sold under the trade name Zylon; liquid crystal polymers such as a polyester-polyarylate, which is sold under the trade name Vectran; p-type aramids such as those sold under the trade names Kevlar, Technora and Twaron; or an ultra-high molecular weight polyethylene, an example of which is sold under the trade name Spectra; and nylon.
The material selected for the detectable element 38 may be any one of the materials mentioned above. Given this description, those skilled in the art will be able to select appropriate materials to meet the needs of their particular situation or to accommodate their chosen detection techniques.
The selection of materials, for example, will depend upon whether the chosen configuration (used for strain recognition) will be an external property such as the geometry or physical arrangement of the second material element or an internal property such as the crystalline structure or density of the material.
In one example, regions of higher local strain will be indicated by a local increase in the length or period 52. Comparing local lay length versus position for a fatigued cord with a baseline measurement when the cord is in a first, acceptable structural condition (i.e., has not been strained), provides an indicator of the amount of strain at a particular portion of the load bearing member. Another comparing factor may be a correlating factor determined by observing an unstrained belt and comparing that to an area that has been strained to a known condition. For example, a belt section having a loss of belt breaking strength as derived from known bending fatigue tests can be utilized to provide a sample of a load bearing member that may not be fit for continued operation. The corresponding element configuration within that section gives a visual indication of such a belt condition. That measurement can be used for comparisons to actual measurements on belts in service to discern a condition of the belt
In another example, the filament 38 is a ferromagnetic wire such as steel. In this example, magnetic detection techniques such as a known magnetic flux leakage technique can be utilized to detect each turn of the helical arrangement of the filament 38. Because such magnetic detection techniques are already used for belt inspection, this provides an advantage for this invention to be accommodated by current inspection machinery or devices.
In examples where the filament 38 is non-ferromagnetic, an eddy current nondestructive detection technique is usable to sense the lay-length periodicity (i.e., the configuration) of the filament 38. Eddy current detection techniques are known. Either the magnetic detection technique or the eddy current detection technique provides information regarding locations of the portions of the filament 38, which provides an indication of the lay length 52.
In another example, the coating 34 is optically transparent and optical imaging is used to determine the configuration of the filament 38. In one such example, the filament 38 is wound around the outside of a cord making it visible through the coating 34. Preferably a high resolution video system obtains an image of the filament, which is digitally processed to determine the configuration characteristic that is an indicator of belt strain. In arrangements where optical imaging is used, the distinguishing characteristic of the filament 38 may be a different color compared to the color of the fibers 36, for example.
This invention provides the ability to detect localized strain on individual portions of the load bearing member 26. As the polymer fibers becomes strained, a corresponding portion of the load bearing member 26 will typically be elongated. A corresponding elongation in the configuration of the filament 38 provides an indication of the structural condition of that portion of the load bearing member 26.
This invention provides a versatile way of determining the strength characteristics of the load bearing member to meet a variety of criteria depending on the needs of a particular situation.
The preceding description is exemplary rather than limiting in nature. Variations and modifications to the disclosed embodiments 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.
This application is a Continuation of U.S. Patent application Ser. No. 09/970,451, which was filed on Oct. 3, 2001, now abandoned.
Number | Name | Date | Kind |
---|---|---|---|
4602476 | Riggs et al. | Jul 1986 | A |
5015859 | Uejio | May 1991 | A |
5834942 | De Angelis | Nov 1998 | A |
5890564 | Olsen et al. | Apr 1999 | A |
5992574 | Olsen et al. | Nov 1999 | A |
6073728 | Olsen et al. | Jun 2000 | A |
6080982 | Cohen | Jun 2000 | A |
6247359 | DeAngelis | Jun 2001 | B1 |
6289742 | DeAngelis | Sep 2001 | B1 |
20030011483 | Lamb et al. | Jan 2003 | A1 |
Number | Date | Country |
---|---|---|
303677 | Feb 1918 | DE |
2 159995 | Jun 1973 | DE |
0 103 162 | Mar 1984 | EP |
2 410 077 | Jun 1979 | FR |
2676814 | Nov 1992 | FR |
2 152 088 | Jul 1985 | GB |
WO 0058706 | Oct 2000 | WO |
Number | Date | Country | |
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20030221917 A1 | Dec 2003 | US |
Number | Date | Country | |
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Parent | 09970451 | Oct 2001 | US |
Child | 10406562 | US |