EP1400479A2 - Driving gear for an elevator and method for installing the driving gear - Google Patents

Abstract

The drive has machine has a drive shaft (4), at least two spaced drive zones (3, 3') and components such as motor (1) and brake (2) and drives the cabin and counterweight through at least two drive zones. At least one component part of the drive machine (20) is mounted to the left or right of the two drive zones. The distance between the two drive zones amounts to at least the width of the rail foot of a cabin or counterweight guide rail (5) and maximum three times the width of the foot of a cabin guide rail. Independent claim describes method for mounting drive machine where at least one component is left or right of the two drive zones.

Description

The present invention relates to a drive machine for an elevator installation and a method for assembling a prime mover according to the definition of Claims.

• Raumbedarf: Die Antriebsmaschine belegt einen grossen Raum.
• Kräfteeinleitung: Die Auflagerkräfte müssen über massive Unterkonstruktionen in die Tragstruktur des Aufzuges eingeleitet werden.
• Montagehandhabung: Die Montage und im besonderen die Ausrichtung der Treibscheibenachse zur Laufrichtung der Trag- und Treibmittel ist aufwändig.

The document WO99 / 43593 shows a drive machine with two traction sheaves for belts. The traction sheaves are arranged in the outer regions of the cabin dimension, at least in the respective outer third of the cabin dimension corresponding to the orientation of the drive axis, or outside the cabin. The traction sheaves are arranged on both sides at the end of the drive machine.
The embodiment shown has several disadvantages:

• Space requirement: The drive machine occupies a large space.
• Force introduction: The support forces must be introduced into the supporting structure of the lift via massive substructures.
• Assembly handling: The assembly and in particular the alignment of the traction sheave axis to the running direction of the carrying and blowing agent is complex.

An object of the present invention is an engine and a method to provide for the same, which optimizes the power flow and thus the Demands on the connection construction keeps low as well as the space requirement for the Drive machine minimized. The prime mover should also have a flexible arrangement allow in the shaft. The carrier and propellant strand is to be divided into two strands.

This object is achieved by the invention according to the definition of independent Claims solved.

The invention relates to a drive machine for an elevator system with cabin and Counterweight and a shaft. Carrying and blowing agents connect the cabin with the Counterweight. The carrying and blowing agents are called blowing agents in the following. The Propellants are passed over the drive machine. The propellants are in the Drive machine driven by a drive shaft. The zones of the drive shaft which the force transferred to the propellant be called in the following Treibzonen. The Cab and the counterweight are by means of cabin guide rails, or Counterweight guide rails led.

The drive shaft has two spaced apart blowing zones. The blowing zones are adapted to the shape of the propellant. The number of propellants is symmetrical The two blowing zones are distributed, with each blowing zone accommodating at least one propellant offers.

According to the invention, at least one component of the drive machine, such as the motor or the brake, left or right of the two drive zones arranged. Of the Benefit of this arrangement is that the dimensions of the prime mover be reduced. The distance between the two blowing zones can thereby suitably be reduced to, for example, the propellant in the shortest possible distance left and right of the guide rails to arrange. This will reduce the space requirement of the Engine and the entire drive arrangement minimized. The small Dimensions of the drive machine allow a compact design. The compact Design allows further optimal introduction of the bearing forces in the Support structure which in turn allows simpler forms of substructures. The Assembly handling and the alignment of the drive machine is characterized by the compact Design, and therefore possible pre-assembly of the individual modules in one easy to install environment, greatly improved.

Fig. 1a

Prinzipskizze einer Erfindungsgemässen Antriebsmaschine mit links und rechts von Treibzonen angeordneten Lagern und Konsolen.

Fig. 1b

Prinzipskizze einer erfindungsgemässen Antriebsmaschine mit Zentralkonsole, Niveaueinstellung und mit links und rechts von Treibzonen angeordneten Lagern.

Fig. 1c

Prinzipskizze einer erfindungsgemässen Antriebsmaschine mit Zentrallager und mit links und rechts von Treibzonen angeordneten Konsolen.

Fig. 1d

Prinzipskizze einer erfindungsgemässen Antriebsmaschine mit Zentrallager, Zentralkonsole und einer Niveaueinstellung mit einer Variante.

Fig. 1e

Prinzipskizze einer erfindungsgemässen Antriebsmaschine mit Zentrallager, Zentralkonsole und einer Variante einer Niveaueinstellung.

Fig. 2

eine perspektivische Ansicht eines Teils eines ersten Ausführungsbeispiels, der Anordnung einer getriebelosen Antriebsmaschine in 2:1-Aufhängung und in der vertikalen Projektion oberhalb des Gegengewichts gemäss Fig. 1d.

Fig. 3

eine Detailansicht eines ersten Ausführungsbeispieles der Antriebsmaschine gemäss Fig. 1d.

Fig. 4

eine schematische Draufsicht eines Teils des ersten Ausführungsbeispiels der Anordnung der Antriebsmaschine.

Fig. 5

eine schematische Ansicht eines Teils des ersten Ausführungsbeispiels der Anordnung der Antriebsmaschine in 2:1-Aufhängung.

Fig. 6

eine schematische Ansicht des Ausführungsbeispiels analog Fig. 4, mit der Anordnung der Antriebsmaschine in 2:1-Aufhängung auf einer Schachtdecke.

Fig. 7

eine schematische Ansicht eines weiteren Ausführungsbeispiels der Anordnung der Antriebsmaschine in 2:1-Aufhängung.

Fig. 8

eine schematische Ansicht eines weiteren Ausführungsbeispiels der Anordnung der Antriebsmaschine in 1:1-Aufhängung.

In the following, the invention will be explained in detail with reference to exemplary embodiments according to FIGS. 1 to 8 . Hereby show:

Fig. 1a

Schematic diagram of an inventive drive machine with left and right of blowing zones arranged bearings and brackets.

Fig. 1b

Schematic diagram of an inventive drive machine with central console, level adjustment and with left and right of blowing zones arranged bearings.

Fig. 1c

Schematic diagram of an inventive drive machine with central warehouse and with left and right of blowing zones arranged brackets.

Fig. 1d

Schematic diagram of an inventive drive machine with central warehouse, central console and a level adjustment with a variant.

Fig. 1e

Schematic diagram of an inventive drive machine with central warehouse, central console and a variant of a level adjustment.

Fig. 2

a perspective view of a portion of a first embodiment, the arrangement of a gearless drive machine in 2: 1 suspension and in the vertical projection above the counterweight according to FIG. 1d.

Fig. 3

a detailed view of a first embodiment of the drive machine according to FIG. 1d.

Fig. 4

a schematic plan view of a portion of the first embodiment of the arrangement of the prime mover.

Fig. 5

a schematic view of a portion of the first embodiment of the arrangement of the prime mover in 2: 1 suspension.

Fig. 6

a schematic view of the embodiment analogous to FIG. 4 , with the arrangement of the drive machine in 2: 1 suspension on a shaft ceiling.

Fig. 7

a schematic view of another embodiment of the arrangement of the prime mover in 2: 1 suspension.

Fig. 8

a schematic view of another embodiment of the arrangement of the prime mover in 1: 1 suspension.

As shown in FIGS. 1a to 1e and 2 to 4 , a drive machine 20 has a drive shaft 4 which is provided with two drive zones 3, 3 'spaced apart from each other at a distance D. A motor 1 and a brake 2 act on the drive shaft 4. The drive zones 3, 3 'drive propellant 19, 19', which as shown by way of example in FIGS. 5 to 8 drive a car 11 and a counterweight 12. The distance D is advantageously chosen as small as possible. It results, for example, from the intended arrangement of the blowing zones or the blowing means 19, 19 'on both sides of the car guide rail 5. The engine 1 and / or the brake 2 and / or other components such as speed sensors, evacuation aids or visual indicators are according to the invention left and / or right of the two blowing zones 3, 3 'arranged. By taking advantage of the possible arrangements of the components of the drive machine 20, the best combination can be determined. The benefit of this arrangement results from the fact that the space requirement for the drive machine 20 can be minimized according to the requirement of the system arrangement. The engine 20 is designed with a small overall length. This allows an extensive pre-assembly of the prime mover in a suitable working environment. This simplifies assembly and eliminates sources of error.

1a shows the arrangement of the motor 1 and a first bearing 28 on one side of the blowing zones 3, 3 'and the brake 2 and a second bearing 28' on the other side of the blowing zones 3, 3 '. Consoles 29, 29 'are mounted according to the arrangement of the bearings 28, 28' on the support structure of the elevator installation. This variant is advantageously used when the distance D between the blowing zones 3, 3 'is selected to be small, which is useful, for example, in the case of very small guide rail dimensions.

In contrast to FIG. 1 a, FIG. 1 b shows the use of a central console 22 which guides the bearing forces of the drive machine 20 centrally, essentially at one point into the supporting structure of the elevator installation. The central console 22 is perpendicular to the axis of the drive machine 20, in a plane of symmetry S of the two blowing zones 3, 3 'acting arranged. This allows a particularly cost-effective design of the adjacent construction. In addition, this arrangement allows the use of a level adjustment 27. The level adjustment 27 has to take on only small differential forces, resulting essentially from the weight forces of the drive itself, and inaccuracies of the propellant arrangement. The level adjustment 27 allows the alignment of the axis of the drive shaft 4 to the direction of the propellant 19, 19 'without any special effort. This orientation is, in particular, advantageous in the use of belts as propellants, as this significantly influences the wear and noise behavior. With inaccurate alignment of the prime mover, the wear of the propellant increases greatly, which leads to an early replacement of the propellant and consequently to high costs.
By way of example, in this Fig. 1b, the brake 2 and the motor 1 on one side of the blowing zones 3, 3 'are arranged. This arrangement is advantageous if the space on the opposite side of the blowing zones is otherwise occupied.

Fig. 1c shows the arrangement of a central bearing 21, which receives, by the existing in the propellant 19, 19 'tensile forces generated radial force of the drive shaft 4 at a central location. The central warehouse 21 is perpendicular to the axis of the prime mover, in a plane of symmetry S of the two blowing zones 3, 3 'acting arranged. At the motor end of the drive shaft 4, a support bearing 24 is arranged. It takes over the differential forces arising in the drive system. The differential forces arise essentially from the weight forces of the drive itself, and inaccuracies of the propellant arrangements. The support bearing 24 also ensures exact compliance with the air gap between the stator and the rotor of the engine 1. The drive machine 20 is secured by means of two brackets 29, 29 'on the support structure of the elevator system. This arrangement is particularly advantageous when the distance D between the blowing zones 3, 3 'leaves enough space for the arrangement of the central bearing 21 and the requirements for the alignment accuracy of the drive shaft are low.

Fig. 1d shows the arrangement of a central warehouse 21 and a central console 22, which leads the support forces of the drive machine 20 centrally, essentially at one point, in the support structure of the elevator installation. The central console 22 and the central warehouse 12 are perpendicular to the axis of the drive machine 20, in a plane of symmetry S of the two blowing zones 3, 3 'acting arranged. A level adjustment 27 is preferably arranged at the engine-side end of the engine. A support bearing 24 is arranged as shown in Fig. 1c . The arrangement of the drive machine 20 according to FIG. 1d is particularly advantageous since small dimensions of the drive machine 20 result, the forces are optimally introduced into the support structure of the elevator installation, the use of only two bearing points in the drive machine 20 a safe interpretation of Drive shaft 4 allows and the alignment of the axis of the drive shaft 4 to the direction of the propellant 19, 19 'is easy to carry out.

Fig. 1e shows another possible arrangement of a level adjustment 27. The level adjustment 27 is arranged directly on the bearing housing in this embodiment. It is identical in its effect to the embodiment shown under Fig. 1b, 1d . The person skilled in the art can define further embodiments which are best suited for a specific application.

The arrangements shown in FIGS. 1a to 1e can be combined in a suitable form by the person skilled in the art. The brake 2 can be arranged, for example, between the blowing zones 3, 3 '.

Fig. 2 and Fig. 3 show an exemplary detail of the arrangement shown in Figure 1d. The drive machine 20 shown has a drive shaft 4 with two spaced drive zones 3, 3 '. In this example, the distance D of the two blowing zones is 100 to 250 mm. This allows the arrangement of today usual guide rail profiles, which have a rail foot width of 50 to 140 mm. The drive shaft 4 is mounted in a bearing housing 7. A central console 22 is integrated in the bearing housing 7. The central console 22 is arranged in a, perpendicular to the drive axis and in a defined by the two drive zones, symmetry plane S between the two drive zones 3, 3 '. The drive shaft 4 is mounted in the bearing housing 7 by means of a between the drive zones 3, 3 'arranged central warehouse 21. The central warehouse 21 is also arranged acting in the plane of symmetry S. The central warehouse 21 receives the propelling means 19, 19 'resulting bearing forces and directs them via the bearing housing 7, the central console 22 and an intermediate piece in the support structure of the elevator system. The blowing zones 3,3 'are incorporated directly into the drive shaft 4. Alternatively, the blowing zones 3, 3 'can also be applied to the drive shaft 4 by means of separate elements, for example in the form of disks. The drive shaft 4, or the drive zones 3, 3 ', is connected to a motor 1 and a brake 2 forces, preferably in one piece and gearless, connected, and thus enables the driving of the blowing agent 19, 19' by means of the blowing zones 3, 3 '. The blowing zones 3, 3 'are likewise integrally integrated into the drive shaft 4 in the embodiment shown. This is advantageous in the use of belts as blowing agents, since these blowing agents allow small deflection or driving radii. The arrangement of the central warehouse 21 between the blowing zones 3, 3 ', the space available there is used efficiently and the external dimensions are reduced. Reducing the number of bearings reduces costs. The quality of the drive machine 20 is substantially increased by this arrangement, as overdefung the shaft bearing deleted by the reduction of the bearings.

Advantageously, the brake 2 and the engine 1 are left as shown in the examples and on the right of the two blowing zones 3, 3 '. The engine 1 and the brake 2 are connected through the bearing housing 7 forces. The generated by the engine 1 Drive torques, and / or the brake torque generated by the brake 2 are in the bearing housing 7 and the central console 22 in the support structure of the elevator system initiated. The illustrated arrangement of the blowing zones 3, 3 'between the brake 2 and the Engine 1 allows, together with the efficient connection of brake 2, engine 1 and bearing housing 7 a particularly space-saving design. In addition, the Accessibility to the brake 2 and the motor 1 ensured in an ideal manner.

At the motor end of the drive shaft 4, a support bearing 24 is arranged. The Support bearing 24 takes over the differential forces arising in the drive system. The Differential forces arise essentially from the weight forces of the drive itself, and inaccuracies of the propellant arrangements. The support bearing 24 ensures In addition, an exact compliance with the air gap between the stator and the rotor of the Motors 1. The support bearing 24 directed the differential forces in the housing of the engine and the Bearing housing 7. The resulting support forces are from a level adjustment 27th taken and introduced into the support structure of the elevator system. The Level adjustment 27 also serves to precisely and easily level out the Axle of the drive shaft 4 to the propellant 19, 19 '. This orientation is in special in the use of belt as a propellant advantageous because thereby the Wear and noise behavior is significantly influenced.

Alternatively, as shown in Fig. 1e , the level setting 27 may be arranged horizontally, for example.

The bearing housing 7 shown in Figs. 2 and 3 encloses the drive shaft 4 with the blowing zones 3, 3 'partially. This forms a direct protection of the blowing zones 3, 3 'from accidental contact and risk of entrapment by assembly or service personnel, but also prevents the damage of the blowing zone or the propellant by falling objects. At the same time, the bearing housing thereby gains the required strength to take over the forces and moments from the engine 1 and the brake 2.

The engine 20 is secured by means of vibration isolations 23, 26. This allows a substantial decoupling of vibration of the engine 20 of the Support structure of the elevator installation. The noise in the elevator system and / or in the Buildings are reduced.

For easy design of the central storage is in the illustrated embodiment of Inner diameter of the central bearing 21 greater than the diameter of the blowing zone 3, 3 ' selected.

Due to the construction form shown is a cost and space optimal drive form offered. In particular, the assembly and alignment of the prime mover easy and fast. The design of the drive components is simplified because the load of the drive shaft 4 and the bearing housing 7 by the achieved 2-point bearing is ideally defined.

2 shows a perspective view of an exemplary embodiment of an arrangement of a gearless drive machine 20. The drive machine 20 is mounted on a traverse 8 which is arranged substantially horizontally in the shaft 10. The traverse 8 is, for example, an elongated square of proven materials such as steel. In this first embodiment, the cross member 8 is attached to counterweight guides 9, 9 'and to a cabin guide 5 of the first wall. Advantageously, the traverse is attached to the counterweight guides 9, 9 'via two end regions and to a cabin guide via a central region. The attachment of the cross member 8 to these three guides takes place in the three attachment areas eg. Via screw. The embodiment shown results in an optimal utilization of the space and allows the cost-optimal extensive preparation of the mounting unit in the factory or a corresponding environment.

A control and / or a converter 6 of the elevator installation is, as shown in FIG. 2 , fastened in the vicinity of the drive machine, advantageously also on the cross member 8. This attachment is, if necessary, vibration isolated. The prime mover can thus be delivered and assembled together with the associated inverter with prefabricated cabling. Any positional changes that may result from construction contraction have no effect and the entire unit can be provided at particularly low cost. If appropriate, the controller and / or inverter can be supported in addition to the wall.

On the drive machine 20 is advantageously, as shown in Fig. 3 , a leveling scale 25 is arranged. The leveling scale 25 is designed for example as a spirit level, which indicates the horizontal position of the drive machine 20. The leveling scale 25 allows easy control of the proper leveling and accordingly allows a rapid correction of the orientation of the engine 20.

The application of the prime mover 20 shown by way of example is universally possible for many plant types. The arrangement shown in FIG. 2 refers to an elevator without a separate machine room. However, the application is not limited to machine room-less elevator systems. If there is an engine room, for example, the drive, as shown in Fig. 6 , also attach to the shaft ceiling.

With the options shown can be the arrangement of the prime mover For example, in modernizations to predetermined manhole conditions flexible adapt which flexibility allows the use of standard parts and avoids expensive special solutions.

In the following, various arrangement options are shown by way of example.

4 and 5 show a preferred application of the inventive drive machine as used for example in new plants. The figures show the triangular arrangement of guides 5, 5 ', 9, 9' of an elevator installation. The elevator installation is, for example, arranged in a largely vertical shaft 10. The shaft 10 has, for example, a rectangular cross section with four walls. In the shaft largely vertically arranged cabin guides 5, 5 'and counterweight guides 9, 9' are attached. Two car guides carry a car 11 and two counterweight guides carry a counterweight 12. The guides are attached to nearest walls. The two counterweight guides 9, 9 'and a first cabin guide 5 are fixed to a first wall. The second cabin guide 5 'is attached to a second wall. The second wall is opposite the first wall. The first cabin guide 5 is arranged substantially centrally between the two counterweight guides 9, 9 '. The guides are made of proven materials such as steel. The attachment of the guides on the walls takes place, for example, via screw. With knowledge of the present invention, other shaft geometries with square, oval or round cross-section can be realized.

The two counterweight guides 9, 9 'and in each case one of the two cabin guides 5, 5 'span a largely horizontal triangle T in the shaft 10. The horizontal one Connecting between the two counterweight guides forms a first side of the Triangle T. The horizontal links between a counterweight guide and a cabin guide form second and third sides of the triangle T. Advantageously The horizontal connecting the cabin guides H cuts the horizontal Connecting the counterweight guides largely centered, so that the triangle T is largely isosceles.

Advantageously, the two blowing zones 3, 3 'of the drive machine 20 are symmetrical, left and right of a horizontal connecting H of the car guides 5, 5 ' arranged.

The largely horizontally arranged in the shaft drive machine 20 moves over at least two propellant 19, 19 'interconnected cabin and counterweight in the shaft. The propellants have two ends 18, 18 '. The propellant is a rope and / or a belt of any nature. The load bearing areas of the propellant are usually made of metal such as steel and / or plastic such as aramid. The rope can a single or multiple rope, also the rope can be an outside protective cover Plastic have. The belt can be flat and smooth or unstructured on the outside For example, in V-ribs or structured as a toothed belt. The power transmission takes place according to the embodiment of the propellant via friction or positive locking. The Driving zones 3, 3 'of the drive shaft 4 are designed according to the propellant. According to the invention, at least two blowing agents are used. The single ones In case of need, blowing zones can also be provided with a plurality of blowing agents.

• In den Ausführungsformen gemäss Fig. 5, 6 und 7 sind ein oder beide Enden 18, 18' des Treibmittels an der Schachtwand/Schachtdecke und/oder an der Kabinenführung und/oder an der Traverse befestigt.
• In der Ausführungsform gemäss Fig. 8 ist ein erstes Ende 18 des Treibmittels an der Kabine 11 befestigt und ein zweites Ende 18 des Treibmittels ist am Gegengewicht 12 befestigt.

Each of the ends of the propellant is fixed either to a shaft wall / shaft cover and / or to a cabin guide and / or to a counterweight guide and / or to a crossbeam 8 and / or to the cabin and / or to the counterweight. Advantageously, the ends of the propellant are fixed via elastic intermediate elements for damping structure-borne noise. The intermediate elements are, for example, spring elements which prevent the transmission of vibrations perceived as unpleasant from the propellant into the shaft wall / shaft cover and / or cabin guide and / or counterweight guide and / or traverse and / or cabin and / or counterweight. Several exemplary embodiments of fixations of the ends of the propellant are possible:

• In the embodiments according to FIGS. 5, 6 and 7 , one or both ends 18, 18 'of the propellant are fastened to the shaft wall / shaft cover and / or to the cabin guide and / or to the crossbeam.
• In the embodiment of FIG. 8 , a first end 18 of the propellant is attached to the cabin 11 and a second end 18 of the propellant is attached to the counterweight 12.

According to the embodiments, two blowing zones move at least two Propellant via stiction. With knowledge of the present invention, the Those skilled in the art also use other drive methods than shown in the examples. So the skilled person can use a drive machine with more than two drive zones.

Also, the skilled person can use a drive pinion, which driving pinion in positive engagement with a toothed belt as a propellant.

The assembly process is characterized by the illustrated engine and in particular by the characterizing arrangement of a central console 22 between the blowing zones, in the axis of symmetry of the resultant power train of the propellant 19, 19 'and the Arrangement of a level adjustment 27 at the motor end of the drive machine 20th greatly simplified. The orientation of the drive axle to the traction axis of the propellant can by the provided level adjustment 27 simple, fast and accurate become. Otherwise usual elaborate methods such as placing underlay pieces, wedges, etc. can be omitted.

With knowledge of the present invention, the elevator expert can set the Change shapes and arrangements as you like. For example, he can use the central console Run 22 separately from the bearing housing 7.

Claims (20)

elevator system
with cab (11) and counterweight (12) in a shaft (10) and with a drive machine (20) which drives the cab (11) and the counterweight (12) via at least two propellants (3, 3 '), the prime mover (20) a drive shaft (4), at least two mutually spaced blowing zones (3, 3 ') and components such as a motor (1) and a brake (2) and the support and propellant means (19, 19') corresponding to the distance Blowing zones (3,3 ') are arranged,
characterized in that at least one component of the drive machine (20) on the left or right of the two drive zones (3,3 ') is arranged. Elevator installation according to claim 1,
characterized in that the distance (D) of the two blowing zones (3, 3 '), or the carrying and blowing means (19, 19'), to each other, at least the width of the rail foot of a car or counterweight guide rail (5 or 9) and a maximum of 3 times the width of the rail foot of a car guide rail (5) or that the distance (D) of the two blowing zones (3, 3 '), or the supporting and blowing means (19, 19'), to each other, 100 bis 250 millimeters. Elevator installation according to one of the preceding claims,
characterized in that a motor (1) to the left or right of the two blowing zones (3, 3 ') is arranged, and a brake (2) on the motor (1) opposite side of the two blowing zones is arranged, or
that the motor (1) and the brake (2) is arranged on the left or right of the two blowing zones, or
that at least the motor (1) or the brake (2) is arranged on the left or right of the two blowing zones. Elevator installation according to one of the preceding claims,
characterized in that the drive machine (20) arranged at a right angle to the axis of the drive machine and in a plane of symmetry (S) of the two blowing zones (3, 3 ') acting central console (22) . Elevator installation according to claim 4,
characterized in that on the drive machine (20) has a level adjustment (27) is mounted. Elevator installation according to one of claims 1 to 3,
characterized in that the drive machine (20) at least two left and right of the blowing zones (3, 3 ') arranged brackets (29, 29'). Elevator installation according to one of the preceding claims,
characterized in that the drive shaft (4) via at least one, perpendicular to the axis of the drive machine arranged and in the plane of symmetry (S) of the two blowing zones (3, 3 ') acting central warehouse (21) is mounted. Elevator installation according to claim 7,
characterized in that a support bearing (24) at the motor end of the drive shaft (4) is arranged. Elevator installation according to one of the preceding claims 1 to 6,
characterized in that the drive shaft (4) via at least two, left and right of the blowing zones (3, 3 ') arranged bearings (28, 28') is mounted. Elevator installation according to one of the preceding claims,
characterized in that the drive shaft (4) with the motor (1) and the brake (2) operatively connected and the prime mover (20) is gearless. Elevator installation according to one of claims 7 to 9,
characterized in that the brackets (29, 29 ') and the bearings (28, 28') and the central console (22) and the central warehouse (21) in a bearing housing (7) are integrated. Elevator installation according to one of the preceding claims,
characterized in that the motor (1), the brake (2) and a bearing housing (7), are operatively connected and the bearing housing (7) encloses the drive shaft (4) with the blowing zones (3, 3 ') by a majority. Elevator installation according to one of the preceding claims,
characterized in that the power transmission from the drive shaft to the propellant positively or frictionally takes place and / or that the propellant belt. Elevator installation according to one of the preceding claims,
characterized in that the attachment of the drive machine (20) to the, from a crossmember (8) or a shaft ceiling (10a) formed, support structure of the elevator system directly or by means of vibration isolation (23, 26). Elevator installation according to claim 14,
characterized in that a controller and / or an inverter (6) is attached to the cross member 8. Elevator installation according to claim 14 or 15,
characterized in that the traverse (8) is attached to a respective counterweight guide (9, 9 ') and to a cabin guide (5, 5'), or
that the cross member (8) is attached to each of a cage guide (5, 5 ') and to a counterweight guide (9, 9'). Elevator installation according to one of the preceding claims,
characterized in that the blowing zones (3, 3 ') to the left and right of a horizontal connecting ends (H) of the car guides (5, 5') are arranged. Elevator installation according to one of the preceding claims,
characterized in that at least two propellants (19, 19 ') move the car (11) and the counterweight (12),
that each propellant has two ends, and
that each of the ends of the propellant
either
on a shaft wall / shaft cover, or
at the counterweight leadership, or
at the cabin guide, or
at the traverse, or
at the counterweight, or
at the cabin
is fixed. Elevator installation according to one of the preceding claims,
characterized in that the drive machine (20) with a spirit level (25) is provided. Method for assembling a drive machine (20) of an elevator installation,
with a cabin (11) and a counterweight (12) in a shaft (10),
which drive machine (20) is provided with a drive shaft (4) with at least two spaced drive zones (3, 3 '),
characterized in that at least one component of the drive machine (20) is arranged on the left or right of the two drive zones.

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