The invention relates to an elevator. The elevator is particularly meant for transporting passengers and/or goods.
Elevators usually have a drive machine which drives the elevator car under control of an elevator control system. The drive machine typically comprises a motor and a rotatable drive member, such as a drive wheel, engaging an elevator roping which is connected to the car. Thus, the driving force is transmitted from the motor to the car via the drive member and the roping. Conventionally, elevators have a counterweight suspended by a rope section that is on one side of the rotatable drive member and the car by the rope section that is on the other side of the rotatable drive member. The counterweight provides tension for the rope section which does not suspend the car. There are also elevators which do not have a counterweight. These counterweightless elevators have the car suspended by the rope section that is on one side of the rotatable drive member, whereas on the opposite side the elevator comprises some sort of tightening arrangement for tightening the rope section on that side of the rotatable drive member. In these tightening arrangements, formation of loose rope in large scale is typically eliminated by connecting the rope on both sides of the rotatable drive member to the car with same ratio. Thereby, during upwards directed movement of the car also the rope section not suspending the car travels along with the car thereby not piling up anywhere in the hoistway. Furthermore, the tightness may be further increased with a tightening device. This may be needed for one or several of the following reasons. Firstly, by increasing the rope tension of the rope section not suspending the car it is possible to ensure that the rope rests against the rotatable drive member firmly for the whole length of contact between these components, in particular so that a normal force adequate for providing firm engagement between these components is provided. Secondly, in this way the rope tension of the rope section not suspending the car can be increased so as to ensure that the ropes do not jump away from their guide pulleys positioned along the route of the ropes. Furthermore, the rope length in many elevator arrangements changes slightly as a function of car position. The problems caused by this phenomenon can be eliminated by tightening the rope section not suspending the car. There are numerous different existing counterweightless elevators, for example elevators as disclosed in WO2004041699A1.
With existing counterweightless elevators, there have been difficulties to make the system such that the layout of the rope arrangement as well as the overall structure of the tightening arrangement are simple and compact. A drawback has been that the roping has needed a great number of ropes arranged in a complex layout. Also, in existing solutions, it has been difficult to design and dimension the tightening arrangement in a compact fashion yet such that it enables an adequate capacity of tightening. In particular, the range of movement of the movable tightening members has been designed and dimensioned long. A drawback has been that the space consumption of the tightening arrangement as well as the roping has made their space-efficient positioning difficult.
The object of the invention is, inter alia, to solve previously described drawbacks of known solutions and problems discussed later in the description of the invention. The object of the invention is to introduce a counterweightless elevator which is improved in simplicity and space-efficiency. In particular, the space-efficiency and simplicity of the hoisting function, including the roping and a tightening device effecting the roping, can be improved. Embodiments are presented, inter alia, where the layout of the bundle of ropes, forming the roping, is simple and compact. Embodiments are presented, inter alia, where the tightening capacity of the tightening arrangement need not be dimensioned as great as previously, yet maintaining good functionality in terms of transport capacity. Embodiments are presented, in particular, where these benefits are obtained with only small or minimal compromises in several other properties of the elevator.
It is brought forward a new counterweightless elevator comprising a hoistway, a car vertically movable in the hoistway, one or more suspension ropes, a rotatable drive member engaging said suspension rope(s) each of the suspension rope(s) having a first rope section on the first side of the drive member and a second rope section on the second side of the drive member, each rope section being connected to the car, said first rope section suspending the car; and a tightening device arranged to tighten the second rope section. Each of said rope(s) is belt-like and comprises a load bearing member or a plurality of load bearing members, which load bearing member(s) is/are made of composite material comprising reinforcing fibers embedded in a polymer matrix, which reinforcing fibers are carbon fibers. Due to this kind of overall cross sectional shape, structure and material selection of the hoisting rope, the simplicity of the roping containing said hoisting ropes can be facilitated, in particular because the number of ropes as well as the cross sectional space consumption of the rope bundle can be reduced. Importantly, due to this kind of overall cross sectional shape, internal structure and material selection of each rope, the tightening capacity of the tightening device can be reduced, most importantly due to an excellent capability to provide high longitudinal stiffness with compact structure. Thereby, a counterweightless elevator with good functionality in terms of transport capacity, space efficiency and simplicity, is obtained.
In a further refined embodiment said load bearing member(s) is/are parallel with the longitudinal direction of the rope. Thereby, the load bearing members are oriented in the direction of the force when the rope is pulled, which increases the tensile stiffness and strength of the rope. Furthermore, it is preferred that said reinforcing fibers are parallel with the longitudinal direction of the load bearing member. In particular, the reinforcing fibers of the same load bearing member are preferably essentially untwisted in relation to each other. Thereby, the reinforcing fibers are oriented in the direction of the force when the load bearing member in question is pulled. This gives the load bearing members an excellent tensile stiffness and strength.
In a further refined embodiment said second rope section is connected to a movably mounted tightening member of the tightening device of the second rope section, which tightening member is movable to tighten the second rope section. The rope structure as defined, providing excellent longitudinal tensile stiffness reduces the need for the length of movement of the movable tightening member thereby enabling a tightening device of this kind which is simple and small in size. Thereby, simplicity and space-efficiency of the elevator can be improved.
In a further refined embodiment the tightening device is mounted on the car at the side thereof, or on the stationary hoistway structures beside the vertical projection of the car, in particular beside the path of the elevator car. This position is enabled by the particular rope structure and shape as defined, in a compact manner.
In a further refined embodiment the tightening device is mounted on the car at the side thereof, or on the stationary hoistway structures beside the vertical projection of the car, in particular beside the path of the elevator car, and the tightening member is movable along a vertical plane, which is parallel with the side wall plane of the car and/or hoistway inner wall plane to tighten the second rope section. The rope structure being as defined, and thereby compact in size, the elevator can be configured to be like this without excessively reducing space-efficiency of the elevator. Thus, the tightening device can be positioned to be in the same space with the car. The tightening member is preferably movable in particular by turning movement and/or by linear movement occurring along a plane, which is parallel with the side wall plane of the car and/or hoistway inner wall plane.
In a further refined embodiment the tightening member is between the vertical side wall plane of the car and the vertical hoistway inner wall plane.
In a further refined embodiment said first rope section, via which the car is suspended, is tensioned by the weight of the car, and guided to pass further to said tightening device of the second rope section and connected in a force transmitting manner to said movably mounted tightening member to pull the tightening member by effect of the rope tension of the first rope section such that the tightening member moves to tighten the second rope section. Thereby first rope section can is used to provide force for a tightening member of the tensioning device, without need for additional actuators.
In a further refined embodiment the end of the first rope section is connected in a force transmitting manner, e.g. fixed, to the movably mounted tightening member to pull the tightening member by effect of the rope tension of the first rope section such that the tightening member moves to tighten the second rope section. In this way, said connection is simply implemented and the end of the first rope section is at the same time provided.
In a further refined embodiment the tightening member is in the form of a tightening pulley around which the second rope section passes, the tightening member being movable in radial direction of the tightening pulley or around its axis, to tighten the second rope section. The ropes of the defined structure facilitate formation of a compact and simple rope bundle, with excellent tensile stiffness. Thereby, the tightening device of the pulley type can be provided good functionality in terms of space consumption of the rope bundle, load bearing capability and space consumption of the movable tightening pulley. Preferably, the plane of rotation of the tightening pulley is parallel with the side wall plane of the car and/or hoistway inner wall plane. Thereby, the radial size thereof is not strictly limited by the space consumption. In a first preferred type, the tightening member is in the form of a tightening pulley around which the second rope section passes is movable in radial direction of the tightening pulley to tighten the second rope section, the second rope section further passing to a rope fixing where the end of the second rope section is fixed, the end of the first rope section being connected in a force transmitting manner (e.g. fixed) to the movably mounted tightening pulley to pull the tightening pulley by effect of the rope tension of the first rope section such that the tightening pulley moves radially to tighten the second rope section. Hereby, a long range of movement is obtainable simply. In a second preferred type, the tightening member is in the form of a tightening pulley around which the second rope section passes against the rim of which the second rope section is fixed, the tightening pulley being movable around its axis to tighten the second rope section, the end of the first rope section being connected in a force transmitting manner to the movably mounted tightening pulley to pull the tightening pulley by effect of the rope tension of the first rope section such that the tightening pulley turns to tighten the second rope section. Hereby, a long range of movement is obtainable with minimal space consumption in radial direction. In this case, preferably the end of the first rope section is connected in a force transmitting manner to the movably mounted tightening pulley via a transmission pulley comprised in the tightening device, which transmission pulley is movable around its axis fixedly and coaxially with the tightening pulley, around which transmission pulley the second rope section passes and against the rim of which the first rope section is fixed. Then the first and second rope sections are arranged on their pulleys such that they pull the tightening pulley by effect of the rope tension to turn it in opposite turning directions, thereby working against each other, the tightening pulley preferably being larger in diameter than transmission pulley a leverage thereby existing between them. Leverage has the benefit of providing a desired level of tightening force, but also the effect of ensuring that tightening range of movement is adequate.
In a further refined embodiment each of said rope(s) has at least one contoured side provided with elongated guide rib(s) and elongated guide groove(s) oriented in the longitudinal direction of the rope, said contoured side being fitted to pass against a contoured circumference of one or more rope wheels of the elevator, said circumference being provided with elongated guide rib(s) and elongated guide groove(s) so that said contoured circumference forms a counterpart for said contoured side(s) of the rope(s).
In a further refined embodiment the elevator comprises a plurality, preferably exactly two, of said ropes, which pass parallelly, at least substantially coplanar, and adjacent in width direction of the rope.
In a further refined embodiment each of said rope(s) has at least one contoured side provided with elongated guide rib(s) and elongated guide groove(s) oriented in the longitudinal direction of the rope, the contoured side of at least the first or the second rope section being fitted to pass against a contoured circumference of a rope wheel of the elevator, which circumference is provided with elongated guide rib(s) and elongated guide groove(s) so that said contoured circumference forms a counterpart for said contoured side(s) of the rope(s), and in that from said rope wheel said first or the second rope section passes downwards or upwards to the tightening device, in particular to a pulley thereof, turning around its longitudinal axis. Thereby, the rope section arriving to the tightening device can be turned to arrive thereto in an optimal attitude without problems or risks of rope wandering. In particular, the rope can in this way be guided to a rim of a pulley positioned in a compact manner, i.e. with its rotational plane parallel with the wall plane(s) of the car or the hoistway. This can be provided such that the rope section in question turns in the same particular space between said planes, whereby the rest of the ropes can be guided freely without compromising the optimality of the suspension arrangement in general. In this case, the compactness of the rope bundle is beneficial as it decreases the space requirements of the turning ropes, but also reduces problems with wandering as well. The turning angle may be 90 degrees, for instance. Preferably, the all the ropes turn in the defined manner maintaining their mutual positioning (parallel, at least substantially coplanar and adjacent in width direction), i.e. the whole rope bundle formed by said ropes turns around the longitudinal axis of the rope bundle.
In a further refined embodiment the elevator comprises one or more rope wheels having its plane of rotation parallel with the vertical side wall plane of the car and/or the vertical hoistway inner wall plane, which rope wheel is mounted on the car at the side thereof or separate from the car and positioned beside the vertical projection of the car, and around which rope wheel the rope turns such that the rope turns around an axis extending in width-direction of the rope.
In a further refined embodiment the first and/or second rope section passes to the tightening device turning around its longitudinal axis in the space between the vertical projection of the car and the vertical hoistway inner wall plane. Thereby, the ropes in the space limited by wall planes of the car and hoistway have portions which do not have their width direction parallel with said planes.
In one preferred embodiment, alternative to the embodiment with a tightening pulley, the tightening member is in the form of a tightening lever mounted turnably via a pivot, the first and the second rope section each being fixed on the tightening lever, to pull the tightening lever by effect of the rope tension of the respective rope section to turn it in opposite turning directions, the first rope section being preferably fixed at a smaller distance from the pivot than the second rope section, thereby a leverage existing between them.
In a further refined embodiment the tightening device is mounted on the car or on the stationary hoistway structures.
In a preferred embodiment said first rope section is arranged to pass from the drive member to turn under rope wheel(s) mounted on the car, and to suspend the car via said rope wheel(s), and in that said second rope section is arranged to pass from the drive member to turn over rope wheel(s) mounted on the car, and further to the tightening device.
In a preferred embodiment the roping comprises exactly two of said ropes. Thus, the ropes are wide (as they are belt-like) and the number of ropes is small, which minimizes non-bearing clearances between adjacent ropes. Accordingly, the width of the individual ropes and the overall space required by the rope bundle is utilized very effectively for load bearing function. As a result, the wheels the ropes meet can be made compact in axial direction, but also the rope bundle arriving them consumes little space. Thus, they will fit well in a space between the car wall plane and the hoistway wall plane, even when this space is very slim. Having two ropes facilitates safety of the elevator as in this way it is not relied on only one rope.
In a preferred embodiment said load bearing member(s) is/are embedded in a common elastomeric coating. The ropes being belt-like, they provide an large surface area enabling efficient force transmission, e.g. by frictional engagement. This can be facilitated by elastomeric coating. In a preferred embodiment, the coating forms the contoured shape for the rope.
In a preferred embodiment said rope(s) each comprise a plurality of parallel load bearing members adjacent and spaced apart in the width direction of the belt-shaped rope.
In a preferred embodiment said the width/thickness ratio(s) of the rope is at least 4, preferably at least 8. Thereby, the bending resistance of the rope is small but the load bearing total cross sectional area can be made vast.
In a preferred embodiment said the width/thickness ratio(s) of said load bearing member(s) is/are at least 8, preferably more. Thereby, the bending resistance of the rope is small but the load bearing total cross sectional area is vast with minimal non-bearing areas.
In a further refined embodiment said load bearing member(s) has/have width larger than thickness as measured in width direction of the belt-like rope. In a yet further refined embodiment each of said rope(s) comprises a small number of load bearing parts, which is enabled by the great width. In one preferred embodiment, each of said rope(s) comprise(s) exactly one of said load bearing members. Thus, non-bearing cross sectional areas are minimized. Accordingly, the width of the rope is effectively utilized and size of the rope bundle minimized. In a preferred alternative embodiment, each of said rope(s) comprise exactly two of said load bearing members adjacent in width-direction of the rope. Thus, non-bearing areas between adjacent load bearing members are minimized, yet not having to rely on only one load bearing member. Said two load bearing members are parallel in length direction of the rope and placed on the same plane in width-direction of the rope.
In a preferred embodiment the of the elevator the thickness of each of said load bearing member(s) is from 0.8 mm to 1.5 mm, preferably from 1 mm to 1.2 mm as measured in thickness direction of the rope. In this way, the ropes as specified above, will have an optimal combination of properties with regard to compactness, traction abilities and tensile properties, which is especially important in case of an elevator where the ropes pass around a wheel is positioned in a slim space, in particular between the car wall plane and the hoistway inner wall plane as specified above. Preferably, the width of the of the single load bearing member or the total width of the two load bearing members of the same rope is from 20 mm to 30 mm. Preferably, the total width of the load bearing members of the two ropes is from 40 to 60 mm. This is the optimal combination of dimensions for obtaining an elevator with high maximum load and space efficiency.
In a further refined embodiment the load bearing member(s) of the rope cover(s) majority, preferably 70% or over, more preferably 75% or over, most preferably 80% or over, most preferably 85% or over, of the width of the rope. In this way at least majority of the width of the rope will be effectively utilized and the rope can be formed to be light and thin in the bending direction for reducing the bending resistance.
In a further refined embodiment the module of elasticity (E) of the polymer matrix is over 2 GPa, most preferably over 2.5 GPa, yet more preferably in the range 2.5-10 GPa, most preferably of all in the range 2.5-3.5 GPa. In this way a structure is achieved wherein the matrix essentially supports the reinforcing fibers, in particular from buckling. One advantage, among others, is a longer service life.
In a further refined embodiment, individual reinforcing fibers are homogeneously distributed in said polymer matrix. Preferably, over 50% of the cross-sectional square area of the load-bearing part consists of said reinforcing fiber. Preferably, the load-bearing part(s) cover(s) over proportion 50% of the cross-section of the rope. Thereby, a high tensile stiffness can be facilitated.
Preferably, said first rope section and a second rope section are connected to the car with same suspension ratio. Preferably, the elevator comprises a drive machine comprising said rotatable drive member and a power source, such as an electric motor, for rotating the drive member. Preferably, the rotatable drive member is positioned in the hoistway. The elevator as describe anywhere above is preferably, but not necessarily, installed inside a building. The car is preferably arranged to serve two or more landings. The car preferably responds to calls from landing and/or destination commands from inside the car so as to serve persons on the landing(s) and/or inside the elevator car. Preferably, the car has an interior space suitable for receiving a passenger or passengers, and the car can be provided with a door for forming a closed interior space.
In the following, the present invention will be described in more detail by way of example and with reference to the attached drawings, in which
In the elevator shown in
In the illustrated embodiment the first rope section 2a and the second rope section 2b are connected to the car 1 with same (suspension) ratio, in this case with ratio 2:1 as these sections 2a and 2b of rope 2 are connected each to car 1 via only one set of rope wheels 10,12. The first rope section 2a on the first side of the drive member 3 passes from the drive member 3 to the car 1 forming a first rope loop, which suspends the car 1 via rope wheels 10 mounted on the car 1. The second rope section 2b on the second side of the drive member 3 passes to the car 1 forming a second rope loop, which is suspended by the car 1 via rope wheels 12 mounted on the car 1. The first rope loop suspending the car is formed between upper rope wheels 3,11 mounted at the upper end of the path of the car 1 and the second rope loop is formed between lower rope wheels 13,14 mounted at the lower end of the path of the car 1. In this embodiment, the rotational planes of all the rope wheels 2,10,12,13,14 and 11 are substantially coplanar, whereby each rope 2 passes along a plane without substantial twisting. The rope passes around all the rope wheels 2,10,12,13,14 and 11 turning around an axis extending in width-direction of the rope 2. For clarity in
In the elevator shown in
In the illustrated embodiment the first rope section 2a′ and the second rope section 2b′ are connected to the car 1 with same (suspension) ratio, in this case with ratio 2:1, as rope sections 2a′ and 2b′ of rope 2′ are connected each to car 1 via only one set of rope wheels 10′,12′. The first rope section 2a′ on the first side of the drive member 3′ passes from the drive member 3′ to the car 1 forming a first rope loop, which suspends the car 1 via rope wheels 10′ mounted on the car 1. The second rope section 2b′ on the second side of the drive member 3′ passes to the car 1 forming a second rope loop, which is suspended by the car 1 via rope wheels 12′ mounted on the car 1. The first rope loop suspending the car is formed between upper rope wheels 3′,11′ mounted at the upper end of the path of the car 1 and the second rope loop between the lower rope wheels 13′,14′ mounted at the lower end of the path of the car 1.
In this embodiment, the rotatable drive member 3′, as well as the power source 9′, is positioned beside the vertical projection of the car 1, so as to enable extending the path of the car 1 as far as possible towards shaft end in a space efficient manner. Particularly preferably, the rotatable drive member 3′ is positioned in the hoistway space which is between a hoistway wall and the vertical projection of the car. For this purpose, the rotatable drive member 3′, as well as the power source 9′ (e.g. electric motor), have rotational plane which is parallel with the side wall plane of the car 1 (i.e. the plane coplanar with the planar side wall of the car 1) and/or hoistway inner wall plane. The rope wheels 10′,13′ where the rope 2 is guided from the rotatable drive member 3′ have each an axis of the rotation which is orthogonal with respect to the axis of rotation of the rotatable drive member 3′. Therefore, the ropes 2 pass downwards to these rope wheels each rope 2 turning around its longitudinal axis an angle of 90 degrees.
In each case, the elevator works fine if the tightening device 4a,4b,4c;4a′,4b′,4c′ is mounted either on the car 1 at the side thereof, or separate from the car (e.g. on the stationary hoistway structures) to be positioned beside the vertical projection of the car 1 (in the illustrated case particularly beside the path of the elevator car 1). In each of the presented cases, the tightening member 5a,5b,5c;5a′,5b′,5c′ is movable along a plane, which is parallel with the side wall plane of the car and/or hoistway inner wall plane to tighten the second rope section 2b,2b′, whereby the tightening movement does not necessitate large hoistway space beside the path of the elevator car 1.
In the preferred embodiments, the movable tightening member 5a,5b,5c;5a′,5b′,5c′ connects the first rope section 2a,2a′ and the second rope section 2b,2b′ in a force transmitting manner to each other. In particular, said first rope section 2a,2a′ suspending the car is tensioned by the weight of the car 1, and guided to pass further to said tightening device 4a,4b,4c;4a′,4b′,4c′ of the second rope section 2b,2b′ and connected in a force transmitting manner to said a movably mounted tightening member to pull the tightening member 5a,5b,5c;5a′,5b′,5c′ by effect of the rope tension of the first rope section 2a,2a′ such that the tightening member 5a,5b,5c;5a′,5b′,5c′ moves to tighten the second rope section 2b. Thereby, tension caused by the car 1 can be utilized to tighten the second rope section 2b,2b′, i.e. to provide more tension for it. This is implemented in the preferred embodiments such that the end of the first rope section 2a,2a′ is connected in a force transmitting manner, e.g. fixed, to the movably mounted tightening member 5a,5b,5c;5a′,5b′,5c′ to pull the tightening member 5a,5b,5c;5a′,5b′,5c′ by effect of the rope tension of the first rope section 2a,2a′ such that the tightening member 5a,5b,5c;5a′,5b′,5c′ moves to tighten the second rope section 2b,2b′.
In the embodiments as illustrated, the tightening member 5a,5b,5c;5a′,5b′,5c′ is movable to tighten the second rope section 2b,2b′ along a vertical plane, which is parallel with the vertical side wall plane of the car and/or the vertical hoistway inner wall plane W, in particular between the vertical side wall plane of the car and/or the vertical hoistway inner wall plane W. For this reason it is important that the rope bundle is compact in the direction of the horizontal distance between these two planes. The aforementioned movement occurring along said plane, which is parallel with the side wall plane of the car and/or hoistway inner wall plane, is in particular turning movement and/or linear movement.
The embodiments as illustrated in
Likewise, the embodiments as illustrated in
Likewise, the embodiments as illustrated in
The elevator comprises preferably a plurality, most preferably exactly two (not more nor less) of said ropes 2,2′. These ropes 2,2′ pass around a number of wheels 3,5a,5b,10,11,12,13,14,3′,5a′,5b′,10′,11′,12′,13′,14′ of the elevator adjacent each other in width-direction of the rope 2,2′, parallelly and at least substantially coplanar, the wide sides of the belt-like ropes 2,2′ against the wheels in question, said wheels 3,5a,5b,10,11,12,13,14,3′,5a′,5b′,10′,11′,12′, 13′,14′ preferably including at the rotatable drive member in the form of a wheel 3,3′.
The load bearing members 7,7′ of each rope is/are embedded in a common elastomeric coating p, which is preferably of polymer, most preferably of polyurethane, which coating p forms the surface of the rope 2,2′. In this way, it provides the surface for contacting the wheels around which the rope 2,2′ passes, for example the drive wheel 3,3′. The coating p provides the rope protection and good frictional properties for force transmittance via the drive wheel 3,3′. The coating p can be also used for providing a contoured shape for the rope. For facilitating the formation of the load bearing member 7,7′ and for achieving constant properties in the longitudinal direction it is preferred that the structure of the load bearing member 7,7′ continues essentially the same for the whole length of the rope 2,2′. For the same reasons, the structure of the rope 2,2′ continues preferably essentially the same for the whole length of the rope 2,2′.
As mentioned, the ropes 2,2′ are belt-shaped. The width/thickness ratio of each rope 2,2′ is preferably at least 4, but preferably at least 8 or more. In this way a large cross-sectional area for the rope 2,2′ is achieved, such that the bending capacity is good around an axis extending in width direction of the rope, also with rigid materials of the load bearing member 7,7′. The load bearing member 7′ or a plurality of load bearing members 7 together cover most, preferably 80% or more, of the total width of the cross-section of the rope 2,2′ for essentially the whole length of the rope. Thus the supporting capacity of the rope 2,2′ with respect to its total lateral dimensions is good, and the rope does not need to be formed to be thick. This is preferably implemented with the composite as specified elsewhere in the application and this is particularly advantageous from the standpoint of, among other things, compactness of the rope bundle, total load bearing ability, service life and bending rigidity.
The two adjacent ropes 2 of
The ropes 2′ of
As mentioned earlier, it is preferable the load bearing member(s) 7,7′ have/has width (w,w′) larger than thickness (t,t′) thereof as measured in width-direction of the rope 2,2′. In particular, the width/thickness ratio(s) of each of said load bearing member(s) 7,7′ is/are at least 8, preferably more. In this way a large cross-sectional area for the load bearing member/members is achieved, without weakening the bending capacity around an axis extending in the width direction. So as to achieve an extremely compact and yet working solution for an elevator the thickness t,t′ of each of said load bearing member(s) 7,7′ is from 0.8 mm to 1.5 mm, preferably from 1 mm to 1.2 mm as measured in thickness direction of the rope 2,2′. The width w′ of the of the single load bearing member 7′ or the total width w+w of the two load bearing members 7 of the same rope 2,2′ is not more than 30 mm, preferably from 20 mm to 30 mm. In this way the rope 2,2′ is made very small in all directions and it will fit to very small space to bend in reasonable radius. The total width (w+w, w′) of the of the load bearing members 7,7′ of all the ropes 2,2′ of the rope bundle is 40-60 mm. In this way the total width of the rope bundle can be even smaller than what is achieved with metal ropes, yet the tensile strength and rigidity properties of the roping is at same level and the bending radius is not too great for producing torque in compact manner. There are two ropes, thus making the roping safer not relying on merely one larger rope. In this way, a redundant roping is obtained.
Each rope 2, 2′ presented in
In the embodiment of
The bending direction of the rope 2,2′ is around an axis that is in the width direction of the rope 2,2′ as well as in width direction of the load bearing members 7,7′ thereof (up or down in the
In the embodiments illustrated in
For the tightening device also different structures could be utilized than what is disclosed in the examples, where tension of the first rope section for tightening the second rope section is utilized. Such alternative solutions may include for instance a weight tightener, or a spring tightener. In case of a spring tightener, a spring is arranged to direct a tightening force to the second rope section, either acting via a rope wheel on the side of the second rope section or being the medium via which an end of the second rope section is fixed to a stationary structure or to the car, depending on which hoisting ratio is preferred for the elevator. In those cases, the first rope section need not be connected to the tightening device but may be fixed for example to a stationary structure or to the car, depending on which hoisting ratio is preferred for the elevator.
In this application, the term load bearing member refers to the part of the rope that is elongated in the longitudinal direction of the rope 2,2′, extending all the length thereof, and which part is able to bear without breaking a significant part of the load exerted on the rope in question in the longitudinal direction of the rope. Such load causes tension on the load bearing member in the longitudinal direction of the rope, which tension can be transmitted inside the load bearing member in question all the way from one end of the rope to the other end of the rope.
As described the ropes are preferably contoured, but this is not necessary. In particular, it is possible to alternatively form said rope(s) without grooves and ribs.
It is to be understood that the above description and the accompanying Figures are only intended to illustrate the present invention. It will be apparent to a person skilled in the art that the inventive concept can be implemented in various ways. The invention and its embodiments are not limited to the examples described above but may vary within the scope of the claims.
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13191600 | Nov 2013 | EP | regional |
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