EP1580156A1 - Elevator comprising V-belt-like transmission means, particularly comprising ribbed V-belts, as carrying and/or traction means - Google Patents

Abstract

Lift system comprises a drive (14) including a V-ribbed belt (13) for moving the lift car (12) and counter-weight (15). An independent claim is included for a belt as described above with a core made from polybenzoxazole.

Description

The invention relates to an elevator system and belt-like transmission means as in the claims Are defined

Elevator systems of this type usually have an elevator car up in an elevator shaft or free along a guide device is movable. To generate the Movement, the elevator system has a drive over Transmission means with the elevator car and a balance weight (also called counterweight) interacts.

A distinction is made between elevator systems involving steel cables round cross-section used as a means of transmission and recent elevator systems using flat belts as a means of transmission exhibit.

An example of a flat transmission elevator system is known from PCT patent application WO 99/43602. The elevator car according to this patent application is by moves a drive that sits on the balance weight and moves in solidarity with the weight.

The described system has the disadvantage that the as Transmission means did not use that with certain belts achievable other belt-like transmission means has optimal traction and that the energy input to the drive motor as well as the transmission of Signals from associated control and regulating devices over long, flexible cables must be made.

Another elevator system with toothed belt-like transmission means is from PCT patent application WO 99/43592 known. In the described and claimed arrangement the drive is integrated in the counterweight, and an im Elevator shaft fixed timing belt-like transmission means serves to transmit the driving force between counterweight and elevator shaft. Because the elevator car and the balance weight at one of said timing belt transmission means hang separate actual suspension, hang Drive and transmission means only the differential force between the counterweight and the weight of the elevator car.

This system has the same disadvantages as the described above and has the additional disadvantage, that for the drive function, a toothed belt and for the Tragfunktion another means are used. in the Comparison with a system in the drive and support function done through the same means is in this system Also a larger number of roles or pulleys required.

A different elevator system with toothed belt type Transfer agent is known from US Patent 5,191,920. In the elevator system shown is the timing belt-like Transmission means in the elevator shaft still. The drive unit is located on the elevator car or on the so-called Load handling attachments.

This system therefore has the same disadvantages as the in WO 99/43602. An additional disadvantage is here, that by the elevator drive the weight of the lifting device and thus the required drive power is increased.

The belts disclosed in the cited documents have certain disadvantages. Flat belts have in elevator facilities with in relation to the payload light elevator cabins insufficient traction. For timing belt exists the problem is that these are not on the drive pulley slip when the elevator car or the counterweight due to a control breakdown on its end position buffers rest. In addition, the centering of the belt on the Riemenpulleys not easy to realize. To have to if necessary special measures taken at the pulleys be to prevent the belt from the central Able to run out.

The object of the invention is thus seen in, a improved elevator system of the type mentioned above create which reduces the disadvantages of the known systems or avoids.

The solution to this problem is in the claims Are defined.

The elevator system according to the invention has an elevator car, a drive, belt-like transmission means, preferably a V-ribbed belt, and a counterweight on. Of the Drive is stationary and the transmission means participate the drive together to the elevator car through transmission to move a force.

Fig. 1A

ein erstes Aufzugssystem gemäss Erfindung, in stark vereinfachter und schematisierter Schnittdarstellung, mit einem Keilrippen-Riemen als Übertragungsmittel.

Fig. 1B

das erste Aufzugssystem, in stark vereinfachter und schematisierter Draufsicht, mit einem Keilrippen-Riemen als Übertragungsmittel.

Fig. 2

ein zweites Aufzugssystem, in stark vereinfachter und schematisierter Draufsicht, mit einem Keilrippen-Riemen als Übertragungsmittel.

Fig. 3

ein drittes Aufzugssystem, in stark vereinfachter und schematisierter Draufsicht, mit einem Keilrippen-Riemen als Übertragungsmittel.

Fig. 4

ein viertes Aufzugssystem, in stark vereinfachter und schematisierter Draufsicht, mit zwei Keilrippen-Riemen als Übertragungsmittel.

Fig. 5A

ein fünftes Aufzugssystem gemäss Erfindung, in stark vereinfachter und schematisierter Schnittdarstellung, mit einem Keilrippen-Riemen als Übertragungsmittel.

Fig. 5B

das fünfte Aufzugssystem, in stark vereinfachter und schematisierter Draufsicht, mit einem Keilrippen-Riemen als Übertragungsmittel.

Fig. 5C

einen Motor, in stark vereinfachter und schematisierter Darstellung, der als Antrieb für das fünfte Aufzugssystem geeignet ist.

Fig. 6A

ein sechstes Aufzugssystem gemäss Erfindung, in stark vereinfachter und schematisierter Draufsicht, mit zwei Keilrippen-Riemen als Übertragungsmittel.

Fig. 6B

das sechste Aufzugssystem, in stark vereinfachter und schematisierter Schnittdarstellung, mit zwei Keilrippen-Riemen als Übertragungsmittel.

Fig. 6C

einen ersten Motor, in stark vereinfachter und schematisierter Darstellung, der als Antrieb für das sechste Aufzugssystem geeignet ist.

Fig. 6D

einen zweiten Motor, in stark vereinfachter und schematisierter Darstellung, der als Antrieb für das sechste Aufzugssystem geeignet ist.

Fig. 7A

ein siebtes Aufzugssystem gemäss Erfindung, in stark vereinfachter und schematisierter Draufsicht, mit zwei Keilrippen-Riemen als Übertragungsmittel.

Fig. 7B

das siebte Aufzugssystem, in stark vereinfachter und schematisierter Schnittdarstellung, mit zwei Keilrippen-Riemen als Übertragungsmittel.

Fig. 8

ein achtes Aufzugssystem gemäss Erfindung, in stark vereinfachter und schematisierter Schnittdarstellung, mit einem Keilrippen-Riemen als Treibmittel und einem getrennten Tragmittel.

Fig. 9

ein neuntes Aufzugssystem gemäss Erfindung, in stark vereinfachter und schematisierter Schnittdarstellung, mit einem Keilrippen-Riemen als Treibmittel und einem getrennten Tragmittel.

Fig. 10A

ein zehntes Aufzugssystem gemäss Erfindung, in stark vereinfachter und schematisierter Schnittdarstellung, mit zwei Keilrippen-Riemen als Übertragungsmittel.

Fig. 10B

das zehnte Aufzugssystem, in stark vereinfachter und schematisierter Draufsicht, mit zwei Keilrippen-Riemen als Übertragungsmittel.

Fig. 11

ein elftes Aufzugssystem, in stark vereinfachter und schematisierter Draufsicht.

Fig. 12

einen weiteren Motor, in stark vereinfachter und schematisierter Darstellung, der als Antrieb für verschiedene Aufzugssystem gemäss Erfindung geeignet ist.

Fig. 13

ein erfindungsgemässes Übertragungsmittel in Form eines Keilrippen-Riemens.

Fig. 14

einen weiteren Keilrippen-Riemen, gemäss Erfindung.

Fig. 15

einen weiteren Keilrippen-Riemen, gemäss Erfindung.

Fig. 16

einen weiteren erfindungsgemässen KeilrippenRiemen mit Zugschicht.

Fig. 17

ein erfindungsgemässes Übertragungsmittel in Form eines Flachriemens.

Fig. 18

ein Riemenpulley mit Bordscheiben.

In the following the invention will be described by means of embodiments and with reference to the drawing. Show it:

Fig. 1A

a first elevator system according to the invention, in a highly simplified and schematic sectional view, with a V-ribbed belt as a transmission means.

Fig. 1B

the first elevator system, in a highly simplified and schematic plan view, with a V-ribbed belt as a means of transmission.

Fig. 2

a second elevator system, in a highly simplified and schematized plan view, with a V-ribbed belt as a transmission means.

Fig. 3

a third elevator system, in a highly simplified and schematized plan view, with a V-ribbed belt as a means of transmission.

Fig. 4

a fourth elevator system, in a highly simplified and schematized plan view, with two V-ribbed belts as transmission means.

Fig. 5A

a fifth elevator system according to the invention, in a highly simplified and schematic sectional view, with a V-ribbed belt as a transmission means.

Fig. 5B

the fifth elevator system, in a highly simplified and schematized plan view, with a V-ribbed belt as a means of transmission.

Fig. 5C

a motor, in a very simplified and schematic representation, which is suitable as a drive for the fifth elevator system.

Fig. 6A

a sixth elevator system according to the invention, in a highly simplified and schematic plan view, with two V-ribbed belts as a transmission means.

Fig. 6B

the sixth elevator system, in a very simplified and schematic sectional view, with two V-ribbed belts as transmission means.

Fig. 6C

a first motor, in a highly simplified and schematic representation, which is suitable as a drive for the sixth elevator system.

Fig. 6D

a second motor, in a highly simplified and schematic representation, which is suitable as a drive for the sixth elevator system.

Fig. 7A

a seventh elevator system according to the invention, in a highly simplified and schematic plan view, with two V-ribbed belts as a transmission means.

Fig. 7B

the seventh elevator system, in a very simplified and schematic sectional view, with two V-ribbed belts as a means of transmission.

Fig. 8

an eighth elevator system according to the invention, in a highly simplified and schematic sectional view, with a V-ribbed belt as a propellant and a separate support means.

Fig. 9

a ninth elevator system according to the invention, in a highly simplified and schematic sectional view, with a V-ribbed belt as a propellant and a separate support means.

Fig. 10A

a tenth elevator system according to the invention, in a highly simplified and schematic sectional view, with two V-ribbed belts as a transmission means.

Fig. 10B

the tenth elevator system, in a highly simplified and schematized plan view, with two V-ribbed belts as a means of transmission.

Fig. 11

an eleventh elevator system, in a highly simplified and schematized plan view.

Fig. 12

another engine, in a highly simplified and schematic representation, which is suitable as a drive for various elevator system according to the invention.

Fig. 13

an inventive transmission means in the form of a V-ribbed belt.

Fig. 14

another V-ribbed belt, according to the invention.

Fig. 15

another V-ribbed belt, according to the invention.

Fig. 16

a further inventive V-ribbed belt with tension layer.

Fig. 17

an inventive transmission means in the form of a flat belt.

Fig. 18

a belt pulley with flanged wheels.

Detailed description

In the following embodiments are preferably so-called V-ribbed belts - also called V-ribbed belts - for use. Such a V-ribbed belt can advantageously as frictional (adhesive) support and / or Drive element (transmission means) for a Elevator cab be used with counterweight. Of the V-ribbed belt allows, with similar running characteristics like a flat belt, a higher one by its shape Cable force ratio. In the case of a belt pulley driven belt means a high rope force ratio, that the tensile force in running on the belt pulley (pulled) run of the belt can be much higher than in the same time running from Riemenpulley strand. In the Application of a V-ribbed belt as transmission means for an elevator car with counterweight has this advantage It also makes a very light elevator car can interact with a much heavier counterweight without the transmission means on the Antriebspulley slips.

As shown in Figs. 13 to 15, the V-ribbed belt 13 a plurality of longitudinally arranged in parallel wedge-shaped grooves 5 and V-ribs 6 on. This wedge-shaped Grooves 5 and V-ribs 6 allow by their Wedge effect a rope force ratio of more than 2 at one Wrap angle of 180 degrees.

It is another advantage of the V-ribbed belt 13 that he himself on the driving or leading pulleys self centered. Preferably, the V-ribbed belt 13 on the back (i.e., on the side that is not wedge-shaped Grooves 5 or V-ribs 6) with a guide rib 2, as shown in FIG. This leadership rib 2 has the task, in a counter-bending of the V-ribbed belt, d. H. if this is a pulley with against the pulley straightened belt backside reveals the V-ribbed belt in a guide groove provided in the tread of the pulley respectively.

For the inventive application, it is advantageous if the wedge-shaped grooves 5 of the V-ribbed belt 13 a Groove angle b of 80 degrees to 100 degrees. Preferably the groove angle b is about 90 degrees. This groove angle b is much larger than conventional V-ribbed belts. Achieved by the larger groove angle b a reduction of the running noise. The self-centering Property as well as one (defined above) increased rope power ratio remain but.

In a further embodiment, the V-ribbed belt is 13 on the back, as shown in Fig. 13, with a Layer 4 provided, preferably good sliding properties Has. This layer 4 may be, for example, a fabric layer be. Facilitated in multi-suspended elevator systems this is the assembly.

Another V-ribbed belt 13 is shown in FIG. This V-ribbed belt has both wedge-shaped grooves 5 and Ribs 6, which are applied in the longitudinal direction, as well Transverse grooves 3. These transverse grooves 3 improve bending flexibility of the V-ribbed belt, so this with Collaborate belt pulleys with reduced diameter can.

It can also be seen in FIGS. 13, 14 and 15 that the transmission means (V-ribbed belt 13) contains tension members 1 oriented in the longitudinal direction, which consist of metallic strands (eg steel strands) or non-metallic strands (eg of manmade fibers) , Such tension members 1 impart the required tensile strength and / or longitudinal rigidity to the transfer means according to the invention.
A preferred embodiment of the transmission means comprises tension members 1 made of Zylon fibers. Zylon is a trade name of Toyobo Co. Ltd., Japan, and refers to manmade fibers of poly (p-phenylene-2,6-benzobisoxazole) (PBO). These fibers surpass those of steel strands and other known fibers in the properties which are decisive for the application according to the invention. The elongation and the meter weight of the transfer means can be reduced by the use of Zylon fibers, whereby the breaking force is higher at the same time.

Ideally, the tension members 1 should be in the V-ribbed belt be embedded in that adjacent fibers or strands do not touch. The ideal is a degree of filling, d. H. a ratio between the total cross section of all tension members and the cross-section of the belt, of at least 20% proved.

FIG. 16 shows an embodiment of the V-ribbed belt 13 which is likewise suitable as transmission means for elevator systems. Instead of the tension members of metallic or non-metallic strands mentioned in connection with FIGS. 13-15, a flat tension layer 51 forms the core of the V-ribbed belt 13. this tension layer 51 extends substantially over the entire belt length and the entire belt width. The tension layer 51 can consist of an unreinforced material layer, for example of a polyamide film, or be formed of a film reinforced with synthetic fibers. Such a reinforced film could, for example, contain the aforementioned Zylon fibers embedded in a suitable plastic matrix.
The tension layer 51 gives the flat belt the required tensile and creep resistance, but is also sufficiently flexible to withstand a sufficiently high number of bending operations when deflecting around a belt pulley.
The V-ribbed layer 53 can be made, for example, of polyurethane or of an NBR elastomer (nitrile butadiene rubber) and is connected over the whole or part of the surface, directly or via an intermediate layer, to the tension layer 51. The rear side of the V-ribbed belt has a cover layer 54 connected to the tension layer 51 like the V-ribbed layer, which is advantageously designed as a sliding covering. Intermediate layers (not shown) may be present between said major layers to provide the necessary adhesion between said layers and / or increase the flexibility of the transfer medium. This V-ribbed belt provided with a full-area tension layer can also have a guide rib as already described in connection with FIG. 15.

In Fig. 17, another applicable in elevator systems Transfer means shown, which is to solve the inventive task is. It is about one of several layers of different materials constructed flat belt 50. The flat belt contains in the core at least one flat tensile layer 51, for example consists of an unreinforced polyamide film, or from a plastic film that is in the plastic matrix reinforced chemical fibers is reinforced. This train layer 51 gives the flat belt the required tension and Creep resistance, but is also flexible enough to one sufficiently high number of bending operations when redirecting to be able to endure a belt pulley. The flat belt 50 also has an outer, front-side friction layer 55, for example, from an NBR elastomer (nitriles butadienes Rubber), as well as an outer, back cover layer 54, which, depending on the elevator system, as a friction or sliding coating is executed. Between the mentioned main layers For example, intermediate layers 56 may be present which have the required To convey adhesion between the mentioned layers and / or increase the flexibility of the flat belt. For the purpose of Optimization of the aforementioned rope force ratio are Friction layers with coefficients of friction of 0.5 to 0.7 compared Steel pulleys available, which are also very resistant to abrasion. The lateral guidance of the flat belt 50 is usually, as shown in Fig. 18, by at the pulleys 16th attached flanges 57 ensures, possibly in Combined with a crowning of the pulley treads.

A first embodiment of an elevator system 10 according to the invention is shown in FIGS. 1A and 1B. Fig. 1A shows a section through the head end of the elevator shaft 11. The elevator car 12 as well as a counterweight 15 are moved via a V-ribbed belt transmission means 13 within the shaft 11. For this purpose, a stationary drive 14 is provided which acts on the V-ribbed belt transmission means 13 via a drive pulley 16.1. The drive 14 is mounted on a bracket 9 which is supported on or on one or more guide rails 18 of the elevator system. In another embodiment, the console 9 may be supported in or on the shaft wall. The V-ribbed belt transmission means 13 is fixed at its one end in the region of the bracket 9, leads from this fixed point down to a suspension pulley 16.2 of a counterweight 15, wraps around this suspension pulley 16.2, leads up to the Antriebspulley 16.1, wraps around this leads downwards a below the elevator car 12 attached to this first Umlenkpulley 16.3, from there horizontally below the elevator car 12 through to a second below the elevator car 12 attached to this Umlenkpulley 16.3 and then back up to a second, referred to as support structure 8 fixed point. Depending on the direction of rotation of the drive 14, the car 12 is moved up or down via the V-ribbed belt transmission means 13.
The guide plane 20 formed by the two car guide rails 18 is, as shown in FIG. 1B, opposite the strand of the V-ribbed belt transmission means 13 passing under the elevator car 12, ie opposite the transverse axis of the elevator car 12, at an angle a of 15 to 20 Degree twisted arranged. Thereby, the car guide rails can be placed outside the space occupied by the V-ribbed belt transmission means 13 and the belt pulley, whereby on the one hand the axis of the strand of the V-ribbed belt transmission means 13 passing under the elevator car 12 can be arranged below the car's center of gravity S. when it lies in the guide plane 20 formed by the car guide rails 18. In addition, the claimed shaft width is minimized.

With the arrangement of passing under the elevator car 12 Strand of the V-ribbed belt transmission means 13 below the car's center of gravity S between Elevator cab 12 and cab guide rails 18 occurring Executives in normal operation as low as possible held, and in that the center of gravity S in the Leadership level 20, managers are minimized, when catch brakes engage the car guide rails 18.

In the illustrated arrangement of the V-ribbed belt transmission means 13, the suspension pulley 16.2 and the underneath the elevator car 12 mounted Umlenkpulleys 16.3 results in a ratio of V-ribbed belt speed to cabin and counterweight speed of 2: 1 (2: 1 suspension). This is compared to a 1: 1 suspension the torque applied by the drive 14 half reduced.

As required by V-ribbed belt minimum radius Drive and Umlenkpulleys is much lower than at the steel wire suspension cables hitherto customary in elevator construction, There are several advantages. Thanks accordingly reduced Diameter of drive pulley 16.1, reduce the am Drive 14 required torque and thus the dimensions of the drive. Because of that, and thanks in theirs too Diameters reduced Umlenkpulleys 16.2 and 16.3, is the type shown in FIGS. 1 and 2 and the embodiment Arrangement of the elevator is relatively compact and can as shown be housed in the shaft 11. The small size of deflection pulley 16.3 attached to the cab 12 allows usually referred to as bottom block 17 substructure below the elevator car 12, in which these Umlenkpulleys 16.3 are built to run with small dimensions. Preferably, this lower bottle 17 with the Diverter pulleys 16.3 even integrated into the cabin floor become.

A cross-section through a similar embodiment is shown in FIG Fig. 2 shown. The elevator car 12 is accessed via a V-ribbed belt transmission means 13 within the shaft 11th emotional. For this purpose, a stationary drive 14 provided, the V-ribbed belt transmission means 13th drives. There are several pulleys provided to the V-ribbed belt transmission means 13 corresponding to to lead. In the embodiment shown, the drive 14 stationary above the upper end position of the counterweight 15 appropriate. The drive 14 is mounted on a bracket 9, on or on one or more guide rails 18 of the Elevator system 10 is supported. In the example shown the bottom block 17 is perpendicular to the side walls the elevator shaft 11 in the plane of the drawing. By the Arrangement of the V-ribbed Belt Transmission 13 below the car's center of gravity S, occur on the car guide rails 18 only low managers. in the the rest, this second embodiment is substantially similar the first embodiment. The car guide rails 18 are arranged eccentrically, i. the management level 20 is located between the car door 7 and the center of gravity S of the elevator car 12, which in the case shown on the Central axis of the V-ribbed belt transmission 13th lies. In the embodiment shown, the counterweight 15 with the Umlenkpulley 16.2 and the cabin 12 with the Umlenkpulleys 16.3 2: 1 suspended (2: 1 - suspension).

Fig. 3 shows a cross section through a further embodiment an elevator system 10. The drive 14 is on the counterweight rails 19 and on one of the car rails 18 supported. On the opposite side is the Fixed point of the V-ribbed belt transmission means 13 on the supported second cabin rail 18. Also in this Embodiment are cabin 12 and counterweight 15 2: 1 suspended. The diagonal course of the V-ribbed belt transmission means 13 allows one in terms of the Cabin center point S centric guided and centric Suspended cabin 12 with the in connection with FIG described advantages.

In another embodiment, shown in FIG is the drive 14 on the two counterweight rails 19 and supported on an elevator rail 18. On the opposite side is the benchmark for here too fixing ends of the V-ribbed belt transmission means 13 supported on the second car rail 18. The drive 14 is in communication with two drive pulleys 16.1. It are two strands of V-ribbed belt transmission means Provided 13.1 and 13.2, which are parallel to each other. Also in this embodiment, cabin 12 and counterweight 15 hung 2: 1. The division of the V-ribbed belt transmission means into two parallel strands 13.1 and 13.2 allows a centric leadership and a in Concerning the cabin center of gravity S centric suspension of Elevator car 12 with those described in connection with FIG Benefits.

A different arrangement 10 is shown in FIGS. 5A and 5B shown. The drive 14 is outside the cabin projection arranged above the upper end position of the counterweight 15. The drive can, as with the previous ones Embodiments, a synchronous or an asynchronous motor contain. Preferably, the drive 14 is on a Carrier placed on or on the guide rails 18 the car 12 and the guides 19 to the counterweight 15 rests. In this embodiment, cabin 12 and counterweight 15 Hung 1: 1. The V-ribbed belt transmission means 13 is half to the left and right of the elevator car 12th arranged. The first half 13.1 of the V-ribbed belt transmission means 13 leads from the counterweight 15 over the Antriebspulley 16.2 to one on the elevator car 12 in the Near the ground existing fixed point. The second half 13.2 of the V-ribbed belt transmission means 13 leads from Counterweight 15 via the Antriebspulley 16.1 along the Schachtdecke 21 over the cabin 12. There it is from a Umlenkpulley 16.4 deflected and a second at the Elevator cabin 12 near the ground existing fixed point guided. The two guide rails 18 are at the top End preferably joined together (e.g. Cross member 24) to the horizontally directed belt force catch. The V-ribbed belt transmission means 13 and the guiding plane 20 of the elevator car 12 is symmetrical to the axis with the cabin center of gravity S arranged. you Distance to this axis is small to the executives, on the one hand in normal operation, on the other hand when intervening a safety gear to keep low.

Details of a drive 14 are shown in FIG. 5C Part of a machine room-less elevator system according to Figs. 5A and 5B. The drive 14 includes a motor 40, by a shaft 45 with the Antriebspulley 16.1 connected is. The drive 14 shown is very compact. The V-ribbed belt 13, the drive Pulley 16.1 with 180 Degrees or at only 90 degrees, depending on which Direction of V-ribbed belts from drive pulley 16.1 should be carried away.

Another embodiment is shown in Figs. 6A and 6B shown. The drive 14 is above the elevator shaft door 7 between the shaft inner wall 21 and the shaft outer wall 22 arranged. This is easily possible because of Diameter of the drive 14 is smaller than the shaft wall thickness D. The drive 14 may as in the other embodiments designed as a synchronous or asynchronous motor be. Advantageously, the drive is a small mass system, d. H. a drive with a low mass moment of inertia, used. The drive 14 is at the two ends depending provided with a Antriebspulley 16.1. Both the Antriebspulleys 16.1 and the drive 14 can on be attached to a common support 43. The system 10 is equipped with two counterweights 15, each depending on one side of the elevator car 12 are arranged. The V-ribbed belt transmission means 13 are symmetrical the left and right sides of the elevator car 12 are arranged. First runs of the V-ribbed belt transmission means 13 lead from the Antriebspulleys 16.1 to first on same height fixed deflection pulley 16.5, of these from down to both sides attached to the elevator car 12 Umlenkpulley 16.6, wrap around this and lead up to fixed points 25.1. Second runs of V-ribbed belt transfer means 13 lead from the drive pulleys 16.1 out to the second fixed at the same height Umlenkpulley 16.7, from these downwards to the Counterweights 15 attached deflection pulley 16.8, loop around these and lead up to fixed points 25.2. Above of the counterweight 15 in its uppermost position claimed Raums are on both sides of the elevator car 12 each a carrier 44 on the counterweight guide rails 19 and the cab guide rails 18, which supports 44, the deflection pulleys 16.5 and 16.7, as well as the fixed points 25.1 and 25.2 wear. The carriers 44 may communicate with the support 43 of the drive 14 form a U-shaped support structure. Horizontal and vertically acting forces are thus not on the shaft structure transfer. The car guide rails 18 and the Umlenkpulleys 16.6 attached to the elevator car 12 are in the direction of the cabin depth as close as possible to Cabin center S arranged to allow managers in the Normal operation as well as catching low remain.

Details of a first drive 14 are shown in FIG. 6C. the component of a machine room-less elevator system according to FIGS. 6A and 6B. The drive 14 includes a Engine 40 and one or two brakes 41. The two Antriebspulleys 16.1 are by support members 44 with the Support 43 connected. Insulated torque arms 42 are used the attachment of the motor 40 to the support 43. The shaft 45 is executed throughout. The drive shown has low rotating masses and is due to its low Size suitable for installation in the shaft wall.

Details of a second drive 14 are shown in FIG. 6D. the component of a machine room-less elevator system according to FIGS. 6A and 6B. The drive 14 shown has a split shaft 46, the two coupling elements 47 is provided. Otherwise, this drive corresponds to the in Fig. 6C shown drive. The maintenance of the drive 14 can take place from the shaft interior.

A development of the embodiment according to FIGS. 6A and Fig. 6B is shown in Figs. 7A and 7B. The embodiment differs in that two separate drives 14.1 and 14.2 are provided. The cabin 12 and the Counterweights 15 are suspended 2: 1. The side view in Figure 7B shows the always same direction bending of the V-ribbed belt transmission means 13, what's more premature Abrasion counteracts.

In the embodiments described so far, the Function of driving and the function of carrying respectively combined. That is why the term was also used Transmission means for describing the function of the V-ribbed belt used.

In the following embodiments, the function of the Carrying and the function of driving carried out separately. In other words, there are separate suspension and propellants.

Fig. 8 shows a first such embodiment. The cabin 12 and the counterweight 15 are with support means 33 in the form of ropes (e.g., steel ropes, aramid ropes), flat belts, Timing belt or chains connected together. A deflection pulley 31 is provided at the shaft head and can on the Guide rails (not shown) to be supported. Of the Drive 14 is located at the shaft bottom 32. means V-ribbed belt drive means 13, the drive 14 moves the Cab 12. The V-ribbed belt driving means 13 is at a End connected to the lower side of the counterweight 15. The necessary clamping force can, for example, by means of a Compression spring 34, or by a corresponding counterweight be generated.

The embodiment 30 shown in FIG. 9 corresponds to FIG Essentially the embodiment shown in Fig. 8. One Difference is that the drive 14 via a Reduction 35 features. This can be a smaller drive 14th be used. The drive 14 can via a V-belt or the like may be coupled to the reduction 35.

FIGS. 10A and 10B show another embodiment of the invention Invention shown. The counterweight 15 is 1: 1 over one Supporting means 33 and several Umlenkpulleys 31 with the elevator car 12 connected. The support means 33 can either only on the left of the elevator car 12 (as shown) or on both sides the elevator car 12 (in dashed line) attached be. These compounds fulfill a purely load-bearing Function. The drive 14 is located above the counterweight 15 and is of a preferably on the guide rails 18, 19 fastened support 37 worn. The Counterweight 15 equals 100% of the cabin weight and one Part of the payload off. A V-ribbed belt 13 is at the top of Counterweight 15 directly attached (suspension 1: 1), over the Antriebspulley 16.1 deflected by 180 degrees and to the am Manhole bottom 32 located tension roller 38 out. The Tension pulley 38 redirects the V-ribbed belt 13 180 again Degree at which it moves up to the lower end of the Counterweight 15 out and attached there. The Tensioning roller 38 may be incorporated in a lever mechanism 39, the by means of spring or weight force the V-ribbed belt 13th stressed.

The embodiment according to FIGS. 10A and 10B can be considered modify, for example, by the V-ribbed belt 13th by suitable arrangement of pulleys leads to a so-called 2: 1 - Umhängung forms, over which the drive 14 counterweight 15 drives (as in connection with Fig. 1A described). This allows the required maximum torque of the drive be halved.

Another embodiment is shown in FIG. Of the Drive 14 is located in the example shown between the elevator car 12 and the wall of the shaft 11. The Elevator car 12 and the counterweight 15 are on common Guide rails 18 out. For this purpose point these rails have a special profile. It can either Drive pulleys 16.1 on both sides of the drive 14 or be provided only on one side of the drive 14. In Figure 12 shows a 1: 1 suspension. An execution with 2: 1 - suspension is possible if the V-ribbed belt 13, as shown for example in Fig. 1, below the elevator car 12 passed and on the other Cabin side be fixed in the shaft head.

Another compact drive 14 is shown in FIG. This drive 14 is characterized in that it has two Drive pulleys 16.1 has. The drive 14 comprises a motor 40, a brake 41 and a continuous Shaft 45. The two drive pulleys 16.1 each sit on one end of the shaft 45. The drive 14 is especially for the laterally above the cabin 12 lying installation designed.

In a further embodiment, the V-ribbed belt Teeth on, which are highly wear-resistant.

According to the invention, the stationary drive is either in housed in a machine room, or the drive is located in or on the hoistway.

Claims (9)

Elevator system (10) with a drive (14) which cooperates via at least two parallel arranged transmission means (13.1, 13.2) with an elevator car (12) and a counterweight (15) to the elevator car (12) and the counterweight (15) Transmitting a force, the elevator car (12) being guided on vertical car guide rails (18),
characterized in that arranged on the elevator car (12) is a group of along a common axis, with the transmission means (13.1, 13.2) cooperating Umlenkpulleys (16.3) and a cabin guide rail (18) in a between two Umlenkpulleys (16.3) lying gap protrudes. Elevator system according to claim 1, characterized in that the Umlenkpulleys (16.3) below the elevator car (12) are attached to this and the transmission means (13.1, 13.2) pass under the elevator car. Elevator system according to claim 2, characterized in that at least two deflecting pulleys (16.3) arranged along a common axis protrude a certain distance beyond a side wall of the elevator car (12) adjacent to a car guide rail (18), the common axis being parallel to said side wall and between two of the Umlenkpulleys (16.3) there is a gap. Elevator system according to claim 3, characterized in that the car guide rail (18) is arranged vertically and parallel to the adjacent car wall in the region of the intermediate space between two Umlenkpulleys (16.3), wherein the distance of the car guide rail (18) to the cabin wall is less than the distance, around which the deflection pulleys (16.3) protrude beyond the cabin wall. Elevator system according to claim 4, characterized in that on two sides of the elevator car (12), a car guide rail (18) projects into the intermediate space present between two deflecting pulleys (16.3). Elevator system according to one of claims 1 to 5, characterized in that the transmission means (13.1, 13.2) are belt-like transmission means. Elevator system according to claim 6, characterized in that the transmission means (13.1, 13.2) are V-ribbed belts. Elevator system according to claim 7, characterized in that the V-ribbed belts have wedge-shaped longitudinal ribs (5) and longitudinal grooves (6), wherein between two adjacent flanks of a longitudinal rib (5) or longitudinal groove (6) existing groove angle (b) between 80 ° and 100 ° lies. Elevator system according to one of claims 1 - 8, characterized in that the drive (14) is supported on a car guide rail (18) which projects into the interspace between two deflection pulleys (16.3).

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