EP3201117A1 - Elevator system - Google Patents

Abstract

The present invention relates to an elevator system (100) having a car (110) that is movable in an elevator shaft (101), wherein the car (110) comprises a chassis element (120), wherein at least one rail (102a, 102b) is arranged in the elevator shaft (101), wherein the elevator system (101) comprises at least one linear motor (400) with in each case one primary part (410) and in each case one secondary part (300), wherein the primary part (410) of the at least one linear motor (400) is arranged on the at least one rail (102a, 102b), wherein the secondary part (300) of the at least one linear motor (300) is arranged on the chassis element (120), and wherein the secondary part (300) of the at least one linear motor (400) at least partially encloses the primary part (410) of the at least one linear motor (400).

Description

 elevator system

The present invention relates to an elevator system having a car which can be moved in an elevator shaft, wherein the car comprises a chassis element, wherein at least one rail is arranged in the elevator shaft and the elevator system comprises at least one linear motor each having a primary part and a respective secondary part.

State of the art

Linear motors are used to generate linear movements.

Conceptually, linear motors can be imagined as a one-level rotary motor. A linear motor comprises a primary part and a secondary part. Such a primary part is connected to a stator of a

Rotary motor comparable and can be formed, for example, as a current-carrying coil. Such a secondary part or

Reaction part is comparable to a rotor of a rotary motor and can be used, for example, as a magnet, e.g. a permanent magnet or a

Electromagnet, be formed.

Either the primary part or the secondary part is designed as a stationary element. The other element of the linear drive is designed to be movable and can be moved along the stationary element. In a long-stator linear drive, the primary part is stationary.

Linear drives can also be used as drives for elevator systems for moving cars in a hoistway. For example, the car in such cases via a suspension cable and a roller construction be associated with a counterweight. A movable element of the linear drive is arranged on the counterweight and a corresponding stationary element of the linear drive is arranged in the elevator shaft. However, such elevator systems have the same disadvantages as elevator systems in which a car can be moved by means of conventional traction sheave drives in an elevator shaft. Such cars, which are moved by means of suspension cables or which are suspended from suspension cables, come with structural cable lengths of about 500 m to constructive limits. Supporting cables may vibrate or move at such lengths, hitting the elevator shaft or building, which may cause problems for the static of the building. By using ropeless elevator systems with linear drive, these disadvantages can be overcome.

It is therefore desirable to have a simple construction, which also saves weight as far as possible, of a lift system driven by a linear drive. Disclosure of the invention

According to the invention, an elevator system and a drive for an elevator system with the features of the independent patent claims are proposed. Advantageous embodiments are the subject of the dependent claims and the following description.

An elevator system according to the invention has a car which can be moved in an elevator shaft. At least one (in particular vertically extending) rail is arranged in the elevator shaft. The car includes a chassis or a chassis element. In particular, the car comprises a car, on which the chassis element is arranged.

An inventive drive for moving the car in the hoistway is designed as a linear motor. The elevator system comprises at least one such linear motor. Such a linear motor comprises a primary part and a secondary part. This primary part corresponds in particular to a stator of a rotary motor. This secondary part or reaction part corresponds in particular to a rotor or rotor of a rotary motor.

The primary part of the at least one linear motor is arranged on the at least one rail and the secondary part of the at least one linear motor on the chassis element. The term "arranged" in this context means, on the one hand, that primary part and rail or secondary part and chassis element can be different elements. In this case, the primary part or the secondary part can be structurally attached or fastened to the rail or the chassis element. On the other hand, the term "arranged" should also be understood to mean that the primary part and the rail or that secondary part and chassis element are each designed as a single, non-separable element. The primary part and the rail (or the secondary part and the chassis element) are formed in this case as a one-piece construction. In this way, in particular the secondary part of the linear motor can be maximally integrated into the chassis element. In particular, different secondary parts of a plurality of different linear motors can be expediently arranged on the chassis element. Different primary parts of different linear motors can each be arranged on different rails of the elevator system. However, different primary parts of different linear motors can also be arranged on a rail. It should be noted that the following description is directed in particular to "one" or "the" linear motor and to "one" or to the "rail". The following explanations apply analogously for several such linear motors and multiple rails.

The secondary part of the at least one linear motor encloses or surrounds or surrounds or at least partially surrounds the primary part of the at least one linear motor. Individual elements of the secondary part are in particular arranged on the chassis element such that they are arranged around corresponding elements of the primary part.

The linear motor is designed in particular as a long-stator linear motor. Primary and secondary interact with each other, causing the car is moved. In particular, the primary part comprises at least one (current-carrying) coil, in particular at least one copper coil. In particular, the secondary part comprises at least one magnet, for example at least one permanent magnet and / or at least one electromagnet. The current flow through such a current-carrying coil in particular controls the movement of the car in the elevator shaft.

ADVANTAGES OF THE INVENTION According to the invention, the elements of the linear motor are arranged on the rail and on the car or on the chassis element itself. The rail and the chassis element are in any case already present in the elevator shaft and provided for moving the car. According to the invention, the rail and the chassis element additionally act as a holder for the linear motor. In particular, the chassis element acts as a suspension of the car. The car is manufactured especially in lightweight construction. Thus, the loads that act on this suspension of the car can be kept as low as possible. The car includes in particular a cabin. The chassis element is further arranged in particular on the cabin.

In particular, a safety device or safety device for preventing fall of the car is arranged on the chassis element. This safety device is triggered, for example, by a speed limiter when a speed of the car exceeds a limit. Such a speed limiter is designed in particular as an electronic system. The speed limiter in particular evaluates sensor data to determine the speed of the car. If the speed of the car exceeds the limit value, the speed limiter actuates actuators to trigger the safety device or the safety gear.

According to the invention, it is not necessary to arrange elements of the linear motor on other elements of the elevator system than the rail and the car or the chassis element. The elevator system is designed in particular as a machine room-less elevator system. Large, heavy and expensive drives, such as traction sheave drives, can be saved by the invention. A space requirement or space requirements and a weight load of the drive and the entire elevator system can be reduced.

The elevator system is designed, in particular, without counterweights and, in particular, without carrying cables. By the invention, these elements of an elevator system can be saved. The car is accordingly particularly ropeless, so in particular without ropes, proceed. Through this ropeless Procedures of the car result in considerable advantage over cars, which are moved by means of suspension cables. Such cars, which are moved by means of suspension cables or are suspended from suspension ropes, come with structural cable lengths of about 500 m to constructive limits: suspension cables can get in such lengths in vibration or in motion, where they are connected to the elevator shaft or to the Buildings hit, which can lead to problems for the statics of the building. By using a linear motor and the ropeless method of the car, these disadvantages can be overcome. The car can thus be easily moved over building heights of over 500 m.

Existing conventional elevator systems can be retrofitted in a simple and uncomplicated way. Rail and chassis element are in any case already present in a conventional elevator shaft. The secondary part can be easily arranged or attached to the chassis element, the primary part in a simple manner to the rail. New elevator systems which do not already exist can be constructed or manufactured in a simple way according to the invention. Rails with integrated primary part and chassis elements with integrated secondary element can be manufactured by convenient manufacturing processes as one-piece constructions.

According to an advantageous embodiment of the invention, the secondary part of the at least one linear motor comprises a U-shaped support member, for example a U-profile. In particular, the secondary part is fastened to the chassis element via this U-shaped carrier element. This support element comprises in particular two legs arranged parallel to one another and a support structure arranged perpendicular to these legs. In particular, the secondary part is attached to this support structure on the chassis element or integrally connected thereto. By this U-shape of the support member, the secondary part can at least partially enclose the primary part. The primary part is in particular arranged on the rail such that it projects at least partially into this U-shaped support element. Furthermore, in particular, the primary part is arranged on the rail in such a way that it is arranged at least partially between the two legs arranged parallel to one another.

Preferably, the secondary part comprises two magnetic elements arranged parallel to one another. These magnetic elements are arranged in particular on the secondary part such that they each extend next to the primary part. The primary part is thus at least partially enclosed or surrounded by these magnetic elements of the secondary part.

More preferably, the two magnetic elements are arranged on the U-shaped support member of the secondary part. In particular, each of the two magnetic elements is arranged on one of the two mutually parallel legs of the support element, in particular on the respective inner sides of the legs. Preferably, the two magnetic elements each comprise at least two magnets arranged in the longitudinal direction of the support element (or in the longitudinal direction of the elevator shaft). In particular, these magnets are each designed as permanent magnets and / or electromagnets. Such a magnetic element is thus in particular an arrangement of a plurality of individual magnets.

Advantageously, the secondary part of the at least one linear motor is formed at least partially from aluminum and / or a fiber composite material, in particular from carbon fiber reinforced plastic (carbon fiber reinforced plastic, CFRP). In particular, the secondary part is thus made of a Lightweight material formed. The secondary part is manufactured especially in lightweight construction. The weight of the linear motor, in particular the secondary part of the linear motor can thus be kept as low as possible. Loads that act on the suspension of the car are kept as low as possible. In particular, the car and / or the chassis element are also made of such a lightweight material.

In particular, the U-shaped support member of the secondary part is formed from such a lightweight material. In this case, it is convenient not to place the magnetic elements of the secondary part directly on the support member but to place a ferromagnetic material (e.g., steel) or a layer of such a ferromagnetic material between the support member and the magnetic member. Such a ferromagnetic material is usually needed for a sufficient magnetic flux. Such a ferromagnetic material, in particular steel, is usually associated with a high weight load for the car. Due to the construction of the U-shaped support member of the lightweight material and the relatively thin layer of ferromagnetic material, this weight load can be kept as low as possible.

In particular, the secondary part, more particularly the U-shaped support element is manufactured by the manufacturing process of the extrusion. The lightweight material is pressed or pulled in this manufacturing process through a shaping opening. In this way, the U-shaped support member can be made as a U-shaped profile in an appropriate length in a cost effective and simple manner. In particular, the chassis element is manufactured with integrated secondary part or with integrated U-shaped support member by the manufacturing process of the extrusion. Preferably, the elevator system comprises at least two linear motors each having a primary part and a respective secondary part. The secondary parts of two linear motors are preferably arranged (directly) next to one another. In particular, the U-shaped support elements of these juxtaposed secondary parts (directly) are arranged side by side. In particular, two immediately adjacent U-shaped support elements of two secondary parts form a W-shaped (or double U-shaped) element. In particular, a bending moment can be absorbed particularly well by such a W-shaped element.

The primary parts of these two (immediately) arranged side by side

Linear motors are arranged in particular on a rail next to each other. Alternatively, these two primary parts can also be arranged on two different rails, which are arranged next to one another.

Advantageously, the juxtaposed secondary parts have a common center bar. In particular, the two U-shaped support elements arranged directly next to one another, which form a W-shaped element, are connected to one another via such a common central web or a common connecting element. Such a common center bar is formed in particular as a common leg of the two juxtaposed U-shaped support members.

Such a central web is formed in particular of ferromagnetic material (eg steel). In particular, in each case a magnetic element of the two juxtaposed secondary parts of the two linear motors is arranged on the two side surfaces of the central web. This ferromagnetic material is used in particular for the magnetic flux of these two magnetic elements. Thus, ferromagnetic material can be saved and a weight load can be kept as low as possible. According to a first preferred embodiment of the invention, the Chassislemenet is designed as a frame member which surrounds the cabin of the car at least partially or surrounds. The frame element does not necessarily have to be self-contained, but may in particular also contain openings, for example on an upper and / or underside of the car. The frame element can also be designed to be self-contained and completely surround or surround the cabin. In particular, the Chassislemenet is designed as a catch frame of the car.

Advantageously, the secondary part of the at least one linear motor is arranged on a vertical side part or on a vertically extending side part of the frame element. This vertical side part of the frame element is arranged in particular on a vertical side surface of the cabin. As vertical side surfaces are those vertically extending surfaces of the cabin to understand, which are adjacent to a front of the cabin, so an area of the cabin with a car door. The secondary part of the linear motor is accordingly arranged in particular on one of the vertical side surfaces of the cabin or of the car.

The elevator system preferably comprises two linear motors each having a primary part and a respective secondary part. The secondary parts of the two linear motors are preferably arranged on opposite vertical side parts of the frame element. Thus, in each case a secondary part of one of the two linear motors is arranged in each case on each of the two vertical side surfaces of the car or the car. In particular, two rails are arranged in the elevator shaft in this case. In each case, in each case a primary part of one of the two linear motors is arranged on each of these two rails. The elevator system may also include more than two linear motors. In this case, a plurality of secondary parts can each be arranged on the vertical side parts of the frame element. In particular, secondary parts can also be arranged directly adjacent to one another on the vertical side parts and form a W-shaped element as described above.

According to a second preferred embodiment of the invention, the Chassislemenet is designed as a backpack element, which is arranged on a rear side of the cabin. The back of the cabin is in particular a vertically extending surface of the cabin to understand, which is opposite to the front of the cabin, so the area of the cabin with the car door. The chassis element acts in particular as a suspension of the car, the suspension of the car is designed in this case, in particular as a backpack suspension.

Preferably, the elevator system comprises at least two linear motors each having a primary part and a respective secondary part. The secondary parts of the at least two linear motors are preferably arranged side by side on the backpack element. In particular, in this case a rail is arranged in the elevator shaft. In particular, the primary parts of the at least two linear motors are arranged next to one another on this rail. Alternatively, a plurality of rails may be arranged side by side. In particular, in each case a primary part of one of the at least two linear motors can be arranged on each of these multiple rails.

In particular, in this case, the U-shaped support elements of the secondary parts of the at least two linear motors are arranged side by side on the backpack element. In particular, two such U-shaped support elements of two secondary parts of two linear motors form a W-shaped element as described above. Such a chassis element, which is designed as a frame element or backpack element, is usually already present in the elevator system. For the linear motor, therefore, no additional elements need to be installed in the elevator system to which the linear motor is placed.

Advantageously, the at least one rail is designed as at least one guide rail. In particular, corresponding guide rollers are arranged on the car. Such guide rails are usually already present in the elevator system and arranged in close proximity to the chassis element. Thus, it is particularly appropriate to arrange the primary part of the linear motor on a guide rail. The rails thus act both as a drive and as a guide for the car. For the linear motor, therefore, no additional elements need to be installed in the elevator system to which the linear motor is placed.

It should be noted at this point that it is in principle also conceivable to form the linear motor as a short-stator linear motor. In this case, the primary part, in particular a current-carrying coil, is arranged on the chassis element and the secondary part on the rail.

Further advantages and embodiments of the invention will become apparent from the description and the accompanying drawings. It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination given, but also in other combinations or in isolation, without departing from the scope of the present invention. The invention is illustrated schematically with reference to an embodiment in the drawing and will be described in detail below with reference to the drawing. Figure description shows schematically a preferred embodiment of an elevator system according to the invention in a perspective view. shows a chassis element of a car according to a preferred embodiment of an elevator system according to the invention in a perspective view. Figure 3 shows schematically a secondary element of a preferred

 Embodiment of a drive according to the invention in a perspective view. schematically shows a preferred embodiment of an elevator system according to the invention in a plan view. schematically shows a preferred embodiment of an elevator system according to the invention in a perspective view. schematically shows a preferred embodiment of an elevator system according to the invention in a plan view.

Figure 7 shows schematically a preferred embodiment

Lift system according to the invention in a plan view. Identical reference numerals in the figures describe identical elements and are not explained separately each time. 1 shows a preferred embodiment of an elevator system according to the invention is shown schematically and designated 100. A car 110 is movable in an elevator shaft 101. The car 110 includes a car 111 and a chassis element 120. In Figure 1, the elevator system 100 is shown schematically with a first preferred embodiment 120 of such a chassis element. The chassis element 120 according to FIG. 1 is designed as a frame element or a catching frame of the car

110 formed. The frame member 120 outlines the cabin in this example

111 of the car 110.

A first vertical side portion 120a of the frame member 120 is disposed on a first vertical side surface purple of the cab 111. A second vertical side part 120b of the frame member 120 is disposed on a second vertical side surface 111b of the cab 111. These left and right vertical side surfaces purple and 111b adjoin a front side 111c of the cabin 111, that is to say an area of the cabin with a car door 112.

In the elevator shaft 101, a first rail 102a and a second rail 102b are further arranged. These first and second rails 102a and 102b are formed as guide rails for the car 110. The first vertical side portion 120a of the frame member 120 is disposed in close proximity to the first rail 102a, the second vertical side portion 120b of the frame member 120 is disposed in close proximity to the second rail 102b. For moving the car 110 in the hoistway 101, a preferred embodiment of a drive according to the invention is provided. The drive is designed as a linear motor, in particular as a long-stator linear motor. In the example of FIG. 1, the elevator system 100 comprises two such linear motors 400. A primary section 410 of a first linear motor 400 is arranged on the first rail 102a. A secondary part 300 of the first linear motor 400 is arranged on the first side part 120 a of the frame element 120. A primary part 410 of the second linear motor 400 is disposed on the second rail 102b. A secondary part 300 of the second linear motor 400 is arranged on the second side part 120 a of the frame element 120.

In FIG. 2, the chassis element 120 designed as a frame element is shown schematically in a perspective view according to FIG.

In FIG. 3, the secondary part 300 of a preferred embodiment of a drive 400 according to the invention according to FIG. 1 is shown schematically in a perspective view. The secondary part 300 comprises a U-shaped support element 310. The U-shaped support element 310 comprises two legs 311 and 312 arranged parallel to one another and a support structure 313 arranged perpendicularly to these legs. Via this support structure 313, the secondary part 310 can be attached to the chassis element 120 of the car 110 are attached.

This U-shaped support member 310 is formed in particular of a carbon fiber reinforced plastic (carbon fiber reinforced plastic, CFRP). Such a U-shaped support member 310 can be made in particular by the manufacturing process of the extrusion as a U-profile. On the inner sides of the two mutually parallel legs 311 and 312 is in each case a layer 320 of a ferromagnetic material, such as steel applied. On this layer 320, a magnetic element 330 is respectively arranged on the legs 311 and 312. The magnetic elements 330 are thus also arranged parallel to one another. Each magnet element 330 comprises in each case a plurality of magnets 331 arranged one above the other in the longitudinal direction of the support element 310, for example permanent magnets (shown in detail only for legs 311).

In FIG. 4, the elevator system 100 according to FIG. 1 is shown schematically in a plan view. As can be seen in FIG. 4, in each case the primary part 410 of one of the linear motors 400 is arranged on the first rail 102a and on the second rail 102b. The primary parts 410 are each formed as copper coils.

The magnetic elements 330 of the respective secondary parts 300 of the linear motors are arranged laterally next to these primary parts 410. Thus, the secondary part 300 of the linear motor 400 encloses the respective primary part 410 of the respective linear motor 400.

In FIG. 5, a further preferred embodiment of an elevator system according to the invention is shown schematically analogously to FIG. 1 and designated by 200. A driving basket 210 is movable in an elevator shaft 201. The car 210 includes a car 211 and a chassis member 220. FIG. 5 schematically shows the elevator system 200 with a second preferred embodiment 220 of such a chassis element. The chassis element 220 is designed as a backpack element. The backpack member 220 is disposed on a rear side 211d of the cabin 211. The rear side 211d of the car is a vertically extending surface of the car 211 facing a front side 211c of the car, that is, an area of the car 211 having a car door 212. In the elevator shaft 201, a rail 202 is further arranged. This rail 202 is formed as guide rails for the car 210. The backpack element 220 is disposed in close proximity to the rail 202.

For moving the car 210 in the elevator shaft 201, a preferred embodiment of a linear motor according to the invention is provided analogously to FIG. 1 or FIG. 3.

Also in the example of FIG. 5, the elevator system 200 comprises two such linear motors 400. A primary part 410 of a first linear motor 400 and a primary part 410 of a second linear motor 400 are arranged side by side on the rail 202. A secondary part 300 of the first linear motor 400 and a secondary part 300 of the second linear motor 400 are arranged side by side on the backpack element 220. In Figure 6, the elevator system 200 according to Figure 5 is shown schematically in a plan view. As can be seen in FIG. 6, the primary parts 410 of the first and the second linear motor 400 are arranged at a certain distance next to one another on the rail 202, and the secondary parts 300 of the first and second linear motor 400 are arranged next to each other on the backpack element 220 at a certain distance , In FIG. 7, the elevator system 200 according to FIG. 5 is shown schematically in a plan view, analogous to FIG. 6. In this example, the two secondary parts 300 of the two linear motors 400 are arranged directly next to each other on the backpack element 220 according to a preferred embodiment of the invention.

The two U-shaped support members 310 of the two linear motors 400 form a W-shaped or double U-shaped element 340. The adjacent legs of the two U-shaped support members 310 of the two linear motors 400 are in this example as a common leg or formed as a common center bar 341. In particular, this common central web 341 is made of ferromagnetic material, for example steel.

LIST OF REFERENCE NUMBERS

100 elevator system

 101 elevator shaft

 102a first rail, guide rail

 102b second rail, guide rail

 110 car

 111 cabin

purple first vertical side surface

 111b second vertical side surface

 111c front side

 112 cabin door

 120 chassis element, frame element

 120a first vertical side part

 120b second vertical side part

200 elevator system

 201 elevator shaft

210 car

211 cabin

 211c front

 211d rear side

 212 cabin door

 220 chassis element, backpack element

300 secondary part of the linear motor

 310 U-shaped carrying element

 311 thighs

 312 thighs

313 Carrying structure Layer of ferromagnetic material magnetic element

Magnet, permanent magnet

W-shaped element

common center bar

linear motor

 Primary part of the linear motor

Claims

claims

An elevator system (100, 200) having a car (110, 210) which can be moved in an elevator shaft (101, 201),

 wherein the car (110, 210) comprises a chassis element (120, 220),

- wherein in the elevator shaft (101, 201) at least one rail (102a, 102b, 202) is arranged,

 - wherein the elevator system (100, 200) comprises at least one linear motor (400) each having a primary part (410) and in each case a secondary part (300),

 wherein the primary part (410) of the at least one linear motor (400) is arranged on the at least one rail (102a, 102b, 202),

 - Wherein the secondary part (300) of the at least one linear motor (300) on the chassis element (120, 220) is arranged, and

 - Wherein the secondary part (300) of the at least one linear motor (400) the

Primary part (410) of the at least one linear motor (400) at least partially encloses.

2. elevator system (100, 200) according to claim 1, characterized in that the secondary part (300) of the at least one linear motor (400) has a U-shaped

Carrying element (310).

3. elevator system (100, 200) according to claim 1 or 2, characterized in that the secondary part (300) of the at least one linear motor (400) comprises two mutually parallel magnetic elements (330).

4. elevator system (100, 200) according to claim 2 and 3, characterized in that the two magnetic elements (300) on legs (311, 312) of the U-shaped support member (310) are arranged.

5. elevator system (100, 200) according to claim 3 or 4, characterized in that the two magnetic elements (330) each comprise at least two in the longitudinal direction of the U-shaped support member (310) arranged magnets (331).

6. elevator system (100) according to any one of the preceding claims, characterized in that the elevator system (200) comprises at least two linear motors (400) each having a primary part (410) and in each case a secondary part (300), wherein the secondary parts (300) of two of the at least two

Linear motors (400) are arranged side by side (340).

7. elevator system (100) according to claim 6, characterized in that the juxtaposed secondary parts (340) of the two of the at least two linear motors (400) have a common central web (341).

8. elevator system (100) according to any one of the preceding claims, characterized in that the chassis element (120) as a frame member

is formed, which surrounds a car (111) of the car (100) at least partially.

9. elevator system (100) according to claim 8, characterized in that the secondary part (300) of the at least one linear motor (400) on a vertical side part (120a, 120b) of the frame member (120) is arranged.

10. elevator system (100) according to claim 8 or 9, characterized in that the elevator system (100) comprises two linear motors (400) each having a primary part (410) and a respective secondary part (300), wherein the secondary parts (300) of the two Linear motors (400) on opposite vertical

Side parts (120a, 120b) of the frame member (120) are arranged.

11. elevator system (200) according to one of claims 1 to 7, characterized

in that the chassis element (220) is designed as a backpack element which is arranged at least partially on a rear side (211d) of a car (211) of the car (210).

12. elevator system (200) according to claim 11, characterized in that the elevator system (200) comprises at least two linear motors (400) each having a primary part (410) and in each case a secondary part (300), wherein the

Secondary parts (300) of the at least two linear motors (400) are arranged side by side on the backpack element (220) (340).

13. elevator system (100, 200) according to any one of the preceding claims, characterized in that the secondary part (300) of the at least one linear motor (400) at least partially made of aluminum and / or a

Fiber composite material, in particular made of carbon fiber reinforced plastic is formed.

14. Elevator system (100, 200) according to one of the preceding claims, characterized in that the at least one rail (102a, 102b, 202) as

at least one guide rail is formed.

15. Drive (400) for an elevator system (100, 200) for moving a car (110, 210) in an elevator shaft (101, 201),

 wherein the drive (400) is designed as a linear motor with a primary part (410) and a secondary part (300),

 - wherein the primary part (410) of the linear motor (400) can be arranged on a rail (102a, 102b, 202) in the elevator shaft (101, 201),

 - Wherein the secondary part (300) of the linear motor (400) on a

Chassis element (120, 220) of the car (110, 210) can be arranged and - Wherein the secondary part (300) of the linear motor (400), the primary part (410) of the linear motor (400) at least partially encloses.