EP3293135A1 - Suspension gainée à élément de traction pour un ascenseur avec différents câbles de suspension de charge et de fourniture de traction - Google Patents

Suspension gainée à élément de traction pour un ascenseur avec différents câbles de suspension de charge et de fourniture de traction Download PDF

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Publication number
EP3293135A1
EP3293135A1 EP16187686.7A EP16187686A EP3293135A1 EP 3293135 A1 EP3293135 A1 EP 3293135A1 EP 16187686 A EP16187686 A EP 16187686A EP 3293135 A1 EP3293135 A1 EP 3293135A1
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EP
European Patent Office
Prior art keywords
cords
type
strands
jacketed
suspension
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP16187686.7A
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German (de)
English (en)
Inventor
Andrea CAMBRUZZI
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Inventio AG
Original Assignee
Inventio AG
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Inventio AG filed Critical Inventio AG
Priority to EP16187686.7A priority Critical patent/EP3293135A1/fr
Publication of EP3293135A1 publication Critical patent/EP3293135A1/fr
Withdrawn legal-status Critical Current

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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B66HOISTING; LIFTING; HAULING
    • B66BELEVATORS; ESCALATORS OR MOVING WALKWAYS
    • B66B7/00Other common features of elevators
    • B66B7/06Arrangements of ropes or cables
    • B66B7/062Belts
    • DTEXTILES; PAPER
    • D07ROPES; CABLES OTHER THAN ELECTRIC
    • D07BROPES OR CABLES IN GENERAL
    • D07B1/00Constructional features of ropes or cables
    • D07B1/22Flat or flat-sided ropes; Sets of ropes consisting of a series of parallel ropes
    • DTEXTILES; PAPER
    • D07ROPES; CABLES OTHER THAN ELECTRIC
    • D07BROPES OR CABLES IN GENERAL
    • D07B2201/00Ropes or cables
    • D07B2201/10Rope or cable structures
    • D07B2201/1012Rope or cable structures characterised by their internal structure
    • D07B2201/1016Rope or cable structures characterised by their internal structure characterised by the use of different strands
    • DTEXTILES; PAPER
    • D07ROPES; CABLES OTHER THAN ELECTRIC
    • D07BROPES OR CABLES IN GENERAL
    • D07B2501/00Application field
    • D07B2501/20Application field related to ropes or cables
    • D07B2501/2007Elevators

Definitions

  • the present invention relates to a jacketed suspension traction member for an elevator.
  • Elevators typically comprise a cabin and, in most cases, a counterweight which may be displaced for example within an elevator hoistway to different levels in order to transport persons or items for example to various levels within a building.
  • the cabin and/or the counterweight are supported by a suspension traction member arrangement comprising one or generally more suspension traction members.
  • the suspension traction member is typically an elongate member such as a rope or a belt.
  • the suspension traction member may carry heavy loads in a tension direction and may be bent in a direction transverse to the tension direction. Accordingly, the suspension traction member may suspend the loads of the cabin and/or the counterweight.
  • the cabin and/or the counterweight are generally displaced throughout the elevator hoistway by displacing the suspension traction member suspending these movable components.
  • the suspension traction members are wound around a traction sheave being driven into rotation by a drive engine such that due to traction between the traction sheave and the traction suspension member, the latter may be displaced.
  • suspension traction members in an elevator installation have to provide two different functions, i.e. a suspension function and a traction function.
  • suspension is related to balanced forces in the elevator installation, while traction has to compensate for an unbalance in the elevator installation.
  • the suspension traction member such as a rope or a belt generally comprises a plurality of cords.
  • Each of the cords may comprise a multiplicity of strands.
  • a strand may be a thin elongate fibre or wire.
  • the strands may be made for example with a metal such as steel.
  • modern types of strands may also comprise other materials.
  • strands may be made with heavily loadable fibres such as carbon fibres, glass fibres, aramid fibres, etc.
  • the cords and their strands are embedded into a jacket material.
  • Such jacket material is typically an elastic or at least bendable material which jackets, i.e. fully encloses, the embedded cords.
  • the jacket on the one hand, may help in providing a required traction between the suspension traction member and a traction surface of for example the driven traction sheave and/or of a pulley.
  • the jacket may protect the embedded cords against for example mechanical damaging and/or corrosion.
  • an amount of wire or fibre material in the strands of the cords is generally set considering a sum of both the suspension function and the traction function. Typically, upon such setting, an additional relative safety factor is taken into account. Moreover, the cords and their strands should have a good adhesion to the enclosing jacket material in order to be able to fulfil the traction function.
  • the strands are typically provided in a twisted configuration. Furthermore, the strands are typically placed near to a neutral axis of the suspension traction member's cross section in order to provide better bending flexibility. However, in such configuration, a longitudinal stiffness of the suspension traction member is reduced.
  • a jacketed suspension traction member for an elevator at least partly overcoming the above mentioned deficiencies.
  • a jacketed suspension traction member which may be optimised for fulfilling both, a suspension function and a traction function, while preferably allowing both, enhanced longitudinal stiffness as well as very good bending flexibility.
  • an elevator arrangement comprising such jacketed suspension traction member.
  • a jacketed suspension traction member (STM) for an elevator comprises a first type of cords comprising mainly load suspending strands and a second type of cords comprising mainly traction providing strands. Furthermore, the STM comprises a common jacket made from a bendable jacket material jacketing both the first and second types of cords.
  • an elevator arrangement comprising an elevator cabin, a drive engine driving a traction sheave and a jacketed suspension traction member according to an embodiment of the above first aspect, the jacketed suspension traction member suspending the elevator cabin and being wound around the traction sheave.
  • suspension traction members of a modem traction-type elevator have to fulfil two different functions, i.e. a suspension function and a traction function.
  • a single type of cords is generally comprised in a common jacket.
  • each of the cords has same structural and/or functional characteristics. Accordingly, the cords have to be adapted for fulfilling both functional requirements.
  • the jacket may comprise an elastic or at least elastically bendable material, preferably a plastic such as polyurethane (PU).
  • the first and second types of cords may significantly differ in their structural and/or functional characteristics. Such differences may result, inter alia, from different physical characteristics of the strands comprised in the cords, from different amounts of strands in each of the cords, from different positional arrangements of strands in the cords and of the cords in the STM, etc.
  • the first type of cords comprises strands which are configured such as to be mainly load suspending.
  • the strands of the first type of cords are specifically adapted for fulfilling the suspension function of the STM, i.e. for carrying the load of the elevator cabin and/or the counterweight to be suspended by the STM.
  • the strands of these first type cords may be specifically configured and arranged such as to provide a maximum of load bearing capacity and of longitudinal stiffness while at the same time allowing substantial bending flexibility.
  • the second type of cords comprises strands which are specifically configured for mainly providing for the traction capability of the STM.
  • the strands of the second type of cords are specifically adapted for fulfilling the traction function of the suspension traction medium, i.e. for enabling that the STM suspending the cabin and/or the counterweight being displaced upon rotating the traction sheave driven by the drive engine due to traction forces acting between the traction sheave and the STM.
  • the STM proposed herein comprises two different types of cords wherein each type of cords may be optimised for fulfilling only one of these two functional requirements, i.e. for fulfilling either the suspension function or the traction function.
  • each type of cords may be optimised for fulfilling only one of these two functional requirements, i.e. for fulfilling either the suspension function or the traction function.
  • Such separate optimising of cord characteristics may allow for overall optimised characteristics of the jacketed STM.
  • each functional requirements being fulfilled mainly by only one of the two types of cords, an overall load bearing capacity and longitudinal stiffness may be improved while still allowing for very good bending flexibility.
  • the load suspending strands are comprised within the jacket with a lower adhesion to the jacket than the traction providing strands.
  • the load suspending strands may adhere to the material of the jacket only weakly whereas the traction providing strands may strongly adhere to the material of the jacket. Accordingly, upon applying longitudinal forces to the strands, the load suspending strands may be displaced relative to the jacket relatively easily whereas the traction providing strands may hardly be substantially displaced relative to the jacket. Accordingly, the load suspending strands may provide for the load bearing capacity of the suspension traction member without transferring significant forces to the jacket upon displacements relative thereto while the traction providing strands may provide for the traction capacity of the suspension traction member.
  • the cords of the first type are arranged within the jacket spaced apart from cords of the second type.
  • the cords of the first type of cords do not extend in direct contact or in direct neighbourhood to the cords of the second type of cords.
  • lateral distances between cords of the first type and closest neighbouring cords of the second type may be in a same order of magnitude as cross-sectional dimensions of the cords, i.e. may be in a range e.g. from a few millimetres to a few centimetres.
  • the locations of the cords of the first type may be set such as to fulfil a load suspension function of the STM in an optimised manner whereas the location of the cords of the second type may be set such as to fulfil a traction provision function in an optimised manner.
  • portions of the jacket material are interposed between each cord of the first type and each cord of the second type.
  • each of the cords of the first and second types is separately embedded in the jacket material, its lateral surfaces being preferably completely enclosed by the jacket material and being separated by intermediate jacket material from lateral surfaces of neighbouring cords.
  • the cords of the second type are arranged closer to a neutral axis of the suspension traction member than the cords of the first type.
  • the neutral axis of the suspension traction member may be understood as being an axis or plane within the cross section of the STM along which no longitudinal stresses or strains occur in case the STM is bent.
  • the neutral axis would be at a geometric centroid.
  • the STM and particularly its jacket are typically not isotropic but, for example, the jacket is provided with a profiled surface, its neutral axis usually does not exactly extend along the geometric centroid but relatively close to it.
  • cords of the second type of cords may be relatively close to the neutral axis of the STM.
  • the traction providing strands of such second type cords may be in good adhesion to the surrounding jacket material and no excessive longitudinal stresses or strains will be applied by the surrounding jacket material to the embedded second type cords upon bending of the STM.
  • the cords of the first type do not need very good adhesion to any surrounding jacket material as they shall not mainly provide traction capabilities to the STM. Accordingly, these first type cords may be arranged further apart from the neutral axis of the STM.
  • a sum of all cords of the first type has a larger cross section than a sum of all cords of the second type.
  • first type cords of an STM these first type cords shall preferably have a substantially larger overall cross section than a sum of all second type cords taken together.
  • Such specifically adapting the overall cross sections of each of the types of cords may take into account that the cords of the STM shall mainly provide for a load bearing capacity of balanced forces in the elevator installation whereas forces for compensating an unbalanced part of forces in the elevator arrangement typically play a minor role.
  • a sum of all cords of the first type may have at least double the cross section of all cords of the second type.
  • the sum of all cords of the first type may have at least triple the cross section of all cords of the second type.
  • the sum of all cords of the first type may preferably have at least 66%, preferably at least 75% or even more of the overall cross section of all cords comprised in the STM. Accordingly, due to the ability of distinguishing between the two types of cords for providing different functionalities, it may be taken into account that for example in a typical elevator, the suspension function requires roughly 75% of the cross section of all strands, but only 25% thereof are required for the traction function.
  • the cords of the first type may have a larger cross section than the cords of the second type.
  • each individual first type cord may have a larger cross section than each individual second type cord.
  • the large first type cords may be optimised for providing the suspension function due to their relatively large cross-section
  • the smaller second type cords may be optimised for providing the traction function due to their relatively small cross section and therefore increased ratio of lateral surface area to volume of the cords allowing for better adhesion to adjacent jacket material.
  • the traction providing strands may be provided with a twisted strand configuration.
  • the strands of the second type of cords may be optimised for providing for a maximum traction force transmission by being arranged in a twisted configuration.
  • each or at least most of the strands of the second type cords do not extend exactly parallel to an extension direction of the STM. Instead, these strands extend preferably slightly inclined to such extension direction, for example in an inclination angle of between 0.1° and 20°, preferably between 1° and 10°.
  • the strands of the second type cords do not extend unidirectional, i.e. all in a same direction.
  • small bundles of strands may be twisted with neighbouring bundles of strands. In such twisted configuration, an overall adhesion or friction between the strands forming the second type of cords and the enclosing jacket material may be increased due to the twisted structure of the strand configuration.
  • the traction providing strands of the second type cords may be relatively close to a surface of the jacket of the STM, i.e. close to a position where shear stresses due to traction have to be exchanged.
  • the load suspending strands may be provided with a non-twisted strand configuration.
  • the strands of the first type of cords may be optimised for providing for a maximum of load bearing capacity.
  • its load suspending strands may preferably not be arranged in a twisted strand configuration but in a non-twisted strand configuration.
  • the traction providing strands are preferably arranged unidirectional.
  • all strands comprised in a first type cord are arranged substantially in the extension direction of the STM, with angular deviations therefrom being for example smaller than 5°, preferably smaller than 1°. Due to the strands in the first type cords being preferably non-twisted, they may suspend heavy loads at high longitudinal stiffness.
  • an adhesion or friction between the load suspending strands of the first type cords and the embedding jacket material may be substantially lower than the adhesion or friction between the traction providing strands of the second type cords and the embedding jacket material.
  • the load suspending strands may ideally be left to freely glide in a longitudinal direction. In fact, suspension forces are generally not transmitted as a shear force but as a normal force (shape contact). Therefore, the load suspending strands may be placed also not in an extreme proximity of the neutral axis of the STM.
  • the load suspending strands of the first type cords may be coated with a friction reducing material such as PTFE.
  • the load suspending strands may easily glide with respect to each other and/or with respect to the enclosing jacket material. Accordingly, due to, inter-alia, reduced adhesion of the load suspending strands to the jacket material, the first type cords formed thereby may easily be displaced in a longitudinal direction with respect to the jacket.
  • PTFE polytetrafluoroethylene - Teflon®
  • an overall longitudinal stiffness of the STM may be increased by preferably unidirectional fibres forming the load suspending strands of the first type cords
  • the bending stiffness of the STM may be significantly decreased because a major part of the strands (i.e. for example those 75% of all strands formed by the load suspending strands) may move longitudinally within the jacket.
  • the load suspending strands may be enclosed in a sheath being interposed between the load suspending strands and the jacket material.
  • the load suspending strands of the first type cords may be arranged for example within a stiff polymer forming a sheath enclosing those strands.
  • Such sheath may be arranged intermediately between the load suspending strands enclosed thereby, on the one side, and the jacket material, on the other side. Accordingly, the load suspending strands may glide along an inner surface of the enclosing sheath upon, for example, the STM being bent. Thereby, a bending stiffness of the STM may be reduced.
  • the sheath may be made from a material having at least one of a higher stiffness and a lower friction coefficient with respect to the enclosed load suspending strands compared to the jacket material.
  • the material forming the sheath may differ from the jacket material. Particularly, the material forming the sheath may be stiffer than the jacket material. Alternatively or additionally, the material forming the sheath may show lower friction with the enclosed load suspending strands than the jacket material would show. Accordingly, due to the enclosing sheath, the load suspending strands may be held within the jacket with very low friction between both components thereby reducing the bending stiffness of the STM.
  • the load suspending strands may be made with another strand material than the traction providing strands.
  • the load suspending strands may be made with a material optimised for load suspension, i.e. having for example great longitudinal stiffness and/or load bearing capacity, whereas the traction providing strands may be made with a material optimised for providing sufficient force transmission between the STM and for example a traction surface of a traction sheave in order to provide sufficient traction functionality.
  • the load suspending strands may be made with carbon fibres.
  • carbon fibres typically have very small diameters in a range from a few micrometres to a few tens of micrometres, e.g. between 4 and 20 ⁇ m
  • carbon fibres typically have very smooth lateral surfaces enabling low friction with neighbouring material.
  • carbon fibres typically have a very low elastic modulus and are therefore very stiff in a longitudinal direction. Accordingly, bundles of carbon fibres forming load suspending strands may provide for high load bearing capacity and longitudinal stiffness as well as low friction with adjacent jacket material.
  • the traction providing strands of the second type cords may be provided with a different material.
  • such traction providing strands may be made with metal wires or metal fibres potentially showing higher friction with enclosing jacket material than, for example, carbon or glass fibres.
  • the jacketed suspension traction member proposed herein may be provided with various shapes, cross sections and/or contours.
  • the STM may be provided with a profiled surface having elongate grooves extending in a longitudinal direction of the STM.
  • An opposing surface of the STM may be non-profiled, i.e. even.
  • the profiled surface may be designed to cooperate with a mating profiled surface provided for example at a traction surface of the traction sheave or of a pulley.
  • the jacket of the STM may be completely non-profiled but the STM has for example a square shaped cross-section with opposing surfaces being even.
  • Fig. 1 shows a traction-type elevator 1 in which a suspension traction member 11 according to an embodiment of the present invention may be used.
  • the elevator 1 comprises a cabin 3 and a counterweight 5 which may be displaced vertically within an elevator shaft 7.
  • the cabin 3 and the counterweight 5 are suspended by a suspension traction member arrangement 9.
  • This suspension traction member arrangement 9 comprises one or more suspension traction members 11.
  • Such suspension traction members 11 may be for example ropes, belts, etc. in which cords are embedded in a jacket.
  • end portions of the suspension traction members 11 are fixed to supporting structures 12 of the elevator 1 at a top of the elevator shaft 7.
  • the suspension traction members 11 may be displaced using a drive engine 13 driving a traction sheave 15.
  • the STM 11 may be wound around a traction surface of the traction sheave 15 and may furthermore be wound around pulleys 16 attached to the cabin 3.
  • An operation of the drive engine 13 may be controlled by a control device 17.
  • the elevator 1 and particularly its suspension traction member(s) 11 may be configured and arranged in various other ways than those shown in Fig. 1 .
  • the suspension traction members 11 to be driven for example by the drive engine 13 may utilize metal cords or ropes to support a suspended load such as the cabin 3 and/or the counterweight 5 that is moved by the drive engine 13.
  • Fig. 2 shows an example of an STM 11 which is embodied with a belt 19.
  • the belt 19 comprises a plurality of cords 23 which are arranged parallel to and spaced from each other.
  • the cords 23 are enclosed in a jacket material 21 forming, inter alia, a jacket 25.
  • Such jacket 25 may mechanically couple neighbouring cords 23.
  • the jacket 25 may protect the cords 23 against for example mechanical damages and/or corrosion.
  • the jacket 25 may have a textured or profiled traction surface including longitudinal guiding grooves 27.
  • the cords 23 may typically conventionally consist of or comprise multiple strands formed by wires made from a metal such as steel.
  • the jacket material 21 may consist of or comprises a plastic or elastomeric material such as PU.
  • the conventional suspension traction member 11 shown in figure 2 comprises several cords 23 all having same structural and functional characteristics and all therefore contributing to both suspension functionalities as well as traction functionalities, it is proposed herein to separately address these differing functionalities by providing different types of cords within one and the same the jacket of an STM.
  • Embodiments of such modified jacketed STMs 31, 31' are shown in Figs. 3 and 4 .
  • Fig. 3 shows an embodiment of an STM 31 in which cords 33 of a first type of cords and cords 35 of the second type of cords are comprised within one and the same jacket 37.
  • Jacket material 38 of the jacket 37 encloses each of the first and second type cords 33, 35.
  • the first type cords 33 are adapted for mainly providing for the load bearing capacity of the STM 31.
  • the first type cords 33 comprise mainly load suspending strands 39.
  • a multiplicity of such load suspending strands 39 is shown in the enlarged visualisation in figure 3 in a side view (i.e. a view transverse to the viewing direction of the overall representation of figure 3 ).
  • the load suspending strands 39 are generally arranged unidirectional in a direction parallel to the longitudinal direction of the STM 31, i.e. in a non-twisted configuration.
  • the first type cords 33 may be comprised in a sheath 41 made from a relatively stiff plastic material such as PU elastomer with higher hardness. Within this sheath 41, the load suspending strands 39 of the first type cords 33 may easily glide in a longitudinal direction with respect to each other as well as with respect to the sheath 41. Accordingly, the load suspending strands 39 may be slidingly displaced in the longitudinal direction with respect to the enclosing jacket 37.
  • the load suspending strands 39 may be coated with a friction reducing material such as PTFE.
  • the load suspending strands 39 may make up a major portion, i.e. significantly more than 50%, preferably more than 70%, of a sum of all strands 39, 49 enclosed in the jacket 37. This fact and the fact that the strands 39 of the first type cords 33 preferably extend unidirectional may result in the first type cords 33 providing for a major portion of the entire load bearing capacity of the STM 31.
  • the first type cords 33 are arranged laterally distant to a neutral axis 43 of the STM 31.
  • the first type cords 33 are arranged in a core part of the STM 31, i.e. in a bulk portion being square in cross section and being arranged underneath a profiled surface 45 comprising longitudinal grooves 47.
  • the second type cords 35 are adapted for mainly providing for the traction capacity of the STM 31.
  • the second type cords 35 comprise mainly traction providing strands 49.
  • a multiplicity of such traction providing strands 49 is shown in the second enlarged visualisation in Fig. 3 in a side view.
  • the traction providing strands 49 are generally provided in a twisted configuration in which each of the strands 49 is arranged in an inclined direction with respect to the longitudinal direction of the STM 31. Accordingly, the traction providing strands 49 are not unidirectional but multidirectional.
  • the second type of cords 35 are provided with an increased adhesion or friction with respect to the jacket material 38 when compared to the adhesion or friction occurring between the load suspension strands 39 and the jacket material 38. Due to such increased adhesion or friction, shear stresses resulting from forces between a traction surface of for example a traction sheave and an abutting traction surface of the jacket 37 of the STM 31 may be effectively transmitted to the traction providing strands 49 of the second type cords 35.
  • the second type cords 35 may be arranged at or close to the neutral axis 43 of the STM 31.
  • the second type cords 35 are arranged in an upper portion of the jacket 37 at the profiled surface 45, i.e. in the longitudinal protrusions 48 between the longitudinal grooves 47.
  • the second type cords 35 are also arranged close to a traction surface of the STM 31 adapted for making contact with a traction surface of e.g. the traction sheave. Due to such configuration, the second type cords 35 may effectively transmit/absorb traction forces acting onto the STM 31.
  • Fig. 4 shows an alternative embodiment of an STM 31'.
  • the STM 31' is provided with a symmetrical profile on both opposing sides of a middle axis forming at the same time the neutral axis 43'.
  • the second type cords 35' are arranged parallel to each other and laterally apart from each other in the plane of this neutral axis 43'.
  • the first type cords 33' are symmetrically arranged at both sides on top and below of the second type cords 35'.
  • the first type cords 35' are provided with a half circle cross section.
  • the load suspending strands 39' of the first type cords 35' are enclosed by a sheath 41'. All first and second type cords 33', 35' are embedded in a jacket 37' made of jacket material 38' such as PU.
  • STMs 31, 31' as proposed herein may allow for less compromise between lifetime and longitudinal stiffness. Furthermore, such STMs may be especially suited in cases where longitudinal stiffness is a main design criterion such as in high-rise elevators.

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  • Lift-Guide Devices, And Elevator Ropes And Cables (AREA)
EP16187686.7A 2016-09-07 2016-09-07 Suspension gainée à élément de traction pour un ascenseur avec différents câbles de suspension de charge et de fourniture de traction Withdrawn EP3293135A1 (fr)

Priority Applications (1)

Application Number Priority Date Filing Date Title
EP16187686.7A EP3293135A1 (fr) 2016-09-07 2016-09-07 Suspension gainée à élément de traction pour un ascenseur avec différents câbles de suspension de charge et de fourniture de traction

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
EP16187686.7A EP3293135A1 (fr) 2016-09-07 2016-09-07 Suspension gainée à élément de traction pour un ascenseur avec différents câbles de suspension de charge et de fourniture de traction

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EP3293135A1 true EP3293135A1 (fr) 2018-03-14

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EP16187686.7A Withdrawn EP3293135A1 (fr) 2016-09-07 2016-09-07 Suspension gainée à élément de traction pour un ascenseur avec différents câbles de suspension de charge et de fourniture de traction

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Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN201546108U (zh) * 2009-11-17 2010-08-11 房雪松 电梯专用钢带
US20120195733A1 (en) * 2009-09-11 2012-08-02 Sgl Carbon Se Cable, goods lift system, and method of making the cable
WO2012170031A1 (fr) * 2011-06-10 2012-12-13 Otis Elevator Company Elément de tension d'ascenseur
EP3015413A1 (fr) * 2014-11-03 2016-05-04 Kone Corporation Câble de hissage et appareil de levage

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20120195733A1 (en) * 2009-09-11 2012-08-02 Sgl Carbon Se Cable, goods lift system, and method of making the cable
CN201546108U (zh) * 2009-11-17 2010-08-11 房雪松 电梯专用钢带
WO2012170031A1 (fr) * 2011-06-10 2012-12-13 Otis Elevator Company Elément de tension d'ascenseur
EP3015413A1 (fr) * 2014-11-03 2016-05-04 Kone Corporation Câble de hissage et appareil de levage

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