EP1641700A1

EP1641700A1 - Lift with a cable-driven cabin

Info

Publication number: EP1641700A1
Application number: EP04738611A
Authority: EP
Inventors: Günter Schmitt
Original assignee: SCHMITT AUFZUEGE GmbH
Current assignee: SCHMITT, GUENTER
Priority date: 2003-06-07
Filing date: 2004-06-04
Publication date: 2006-04-05
Anticipated expiration: 2024-06-04
Also published as: DE502004003892D1; JP4786532B2; CA2528319A1; AU2004247314A1; EP1641700B1; DE10325937A1; US7374022B2; ATE362893T1; DE10325937B4; CN1829652A; ES2287737T3; CA2528319C; AU2004247314B2; JP2006527149A; US20060254863A1; WO2004110914A1

Abstract

An elevator comprises a cable-driven car to which vertical guide rails are allocated. The cables are arranged on both sides of the car, each in a housing and acted upon by a common driving wheel.

Description

Elevator with a cable-driven cabin

description

The invention relates to an elevator with a cable-driven cabin, to which vertical guide rails are assigned.

An elevator is usually installed inside a vertical shaft that is part of or rigidly connected to a building structure so that it forms a unit with it. The shaft is made of concrete, metal, glass or a combination of these materials and is a heavy and expensive component. However, the shaft is imperative to protect the cables connected to the cabin from the weather, in particular from moisture, since moisture the friction between the ropes and the associated traction sheave is negatively affected. In order to avoid a complicated shaft in an elevator arranged outdoors, it is known from practice to move the elevator car directly or in conjunction with ropes with a ratio of 2: 1 in the vertical direction using a lifting piston. With such an elevator, however, the head is very limited and the speed of the car must not exceed 1 m / s. It is an object of the invention to provide an elevator of the type mentioned in the introduction, which can be operated outdoors with a simple structure and guaranteed safety.

According to the invention, the object is achieved in that the ropes are arranged in a housing on both sides of the cabin and acted upon by a common traction sheave.

Due to this measure, it is not necessary to install a shaft in order to protect the ropes from the weather, in particular moisture, when the elevator is operated outdoors. The accommodation of the ropes in the housing ensures reliable operation of the elevator.

The ropes on each side of the cabin are expediently coupled to the cabin on the one hand and to a counterweight on the other. This is accompanied by an even load on the ropes and a reduction in the power of the drive of the traction sheave, since the forces acting on each other cancel each other out. To achieve a compact design, the counterweight and the cabin are located on opposite sides of a vertical support holding the guide rail. The vertical beams arranged on both sides of the car represent the only essential static components of the elevator. They can be arranged, for example, in the area of the front of the car provided with a door and connected to a building. In addition, a free installation of the elevator is possible, in which the vertical beams, for example by means of tensioning rope. len are held. This type of installation of the vertical supports and thus of the elevator is possible, for example, when used in a tent construction or at a trade fair stand or the like, relatively unstable components.

In order to make the vertical supports both flexurally and kink-resistant and pressure-stable, each vertical support is preferably designed as a double-T support and arranged in the housing. The vertical beams can, for example, be fastened on at least one foundation in such a way that the entire elevator can be set up free-standing, that is to say without further supports.

For a space-saving implementation of the guidance of the ropes, the vertical supports are preferably provided at their upper ends with a bracket for mounting the traction sheave and a plurality of deflection sheaves for the ropes, the bracket extending like a bridge between the two vertical supports. The deflection sheaves are of course arranged in relation to the traction sheave in such a way that the ropes encompass them at angles of wrap that correspond to the relevant technical rules. A motor driving the traction sheave is expediently fastened to the console with the interposition of a transmission. If the motor is designed accordingly, the gearbox can be dispensed with, ie the drive can be “gearless”. In addition, the console carries control electronics. Of course, the control electronics, the motor and the gearbox below the are also possible Arrange the cabin stationary and guide the ropes to the cabin using appropriate pulleys.

The vertical supports are preferably fixed in a shaft pit with the end opposite the console. The shaft pit, for example concreted, on the one hand ensures that the vertical girders are securely fastened and on the other hand provides free space below the cabin in its lowest end position. For additional stiffening, the vertical beams are connected to one another by means of a plurality of cross beams spaced apart from one another.

The web of each vertical support is preferably aligned parallel to the cabin and carries the guide rail on the side facing the cabin. The guide rail is thus arranged within the U-shaped free space spanned by the flanges and the web of the vertical support. To prevent uncontrollable oscillating movements of the counterweight, according to a development of the invention, the flanges on the side of the vertical support opposite the guide rail have guide means for supporting the counterweight in the corresponding U-shaped recess in the vertical support. Due to the arrangement of the counterweight and the guide rail to the web of the vertical support, the vertical support is subjected to a compressive stress.

In order to achieve a relatively low-wear guiding of the counterweight, the guiding means are expediently designed as angle profiles fastened opposite to the flanges, on which are attached to the counterweight. Support the leadership roles. Here, for example, the tip of the angle profile points in the direction of the counterweight and the guide rollers are aligned such that their running surfaces roll over the entire surface of the legs of the angle profile.

The cross-sectionally T-shaped guide rail is preferably fixed to the web of the vertical support with the interposition of a holder profile in such a way that its foot runs parallel to the web of the vertical support and its web, which is guided between rollers on the cabin side, points in the direction of the cabin. Since both guide rails and rollers are located on both sides of the cabin, the cabin is mounted reliably, the mounting only permitting the cabin to move up and down.

To accomplish a relatively low-warp mounting of the guide rail, this can be fastened, for example, to the holding profile by means of clamping claws, and the holding profile can in turn be welded to the vertical support. According to a further embodiment of the invention, the rollers are mounted on a U-profile which is connected to a frame of the cabin via an angle bracket. Instead of an angle beam, a beam made of a U or flat profile can also be used, for example, and the U profile can be replaced by an angle profile, for example.

The frame is expediently composed of profiles which are U-shaped in cross section, the legs extending over the height of the cabin pointing in the direction of the respectively assigned vertical support and one leg of the profile is connected to one leg of the angle profile, the other leg of which holds the U-profile. Because of this relatively stiff construction, the rollers are always in contact with the associated guide rail.

In order to protect the coupling area between the cabin and the vertical supports or the associated guide rails from the weather, the cabin is preferably assigned a protective housing extending over its height on both sides, which covers the corresponding profiles of the frame and the one passage for the corresponding profile has associated leg of the angle leg, which projects through a slot of the housing accommodating the associated vertical support. The openings, namely the passage of the protective housing and the slot of the housing through which moisture could penetrate, are thus kept relatively small, nevertheless ensuring reliable storage of the cabin between the vertical supports. The passage is expediently formed between two protrusions of the protective housing, which protrude through the slot of the housing. The housing is thus nested with the protective housing in the area of the openings and the ingress of water is prevented. Preferably, the housing carries on both sides of the slot V-shaped sealing lips that rest on the projections of the protective housing. This prevents rain or snow, which strikes the protective housing or the housing, from getting into the interior of the same and there impairing the ropes or the guides. Expediently, a trigger of a safety device is assigned to the one guide rail of electrical cables and the other guide rail within the respective housing. The electrical cables preferably protrude through the slot in the housing and the passage of the protective housing into the interior of the cabin. Thus, the electrical cables, which serve on the one hand to supply energy to consumers within the cabin and on the other hand to control the elevator, and the trigger of the safety device, which acts on the two guide rails, as known from the prior art, are housed weather-protected inside the housing.

The traction sheave and the deflection sheaves are preferably covered by a hood. Of course, there is also a motor, gearbox and control devices under this hood, which are thus protected from the weather, so that the elevator is suitable for outdoor installation. The hood can be pivoted for maintenance work or have a flap or door.

According to a further advantageous embodiment of the invention, a wire rope is fastened on both sides of the cabin on the one hand to the respective counterweight and on the other hand to the cabin, the wire rope running below the associated vertical support and holding a deflection roller with a tensioning weight. To release the safety gear, i.e. an emergency braking device, a hoist is attached to the wire rope to either pull the cabin up or down when the drive brake is released. Since the cabin is both on an ascent and a descent downward trap can get caught, different procedures are required to release the safety gear. The cabin must be moved upwards after emergency braking during a downward journey. For this purpose, one end of a hoist is fastened to the section of the wire rope assigned to the counterweight, the other end of which, in contrast, is fixed further down in a shaft pit in which the deflection roller with the tensioning weight is located. When the hoist is loaded to tension it, the counterweight is moved downwards and consequently the cabin is moved upwards, so that the safety gear comes out of operative engagement. After emergency braking during an upward movement, it is necessary to move the cabin downwards, for which purpose one end of the hoist is fastened to the section of the wire rope assigned to the counterweight, the other end of which, in contrast, is fixed further above. The tensioning weight is fixed, for example, by fixing the deflection roller. Then, after releasing the drive brake of the elevator, the car is pulled down to disengage the safety device.

So that users of the elevator or its drive parts are protected from cold and / or heat, the cabin and / or the area covered by the hood are expediently connected to a heating and / or air conditioning system for temperature control.

In order to enable users of the elevator installed in front of a building to make a comfortable transition from the cabin into the building, a balcony is advantageously provided on the level of a floor of each floor between a ner exterior door of the elevator and a building. The balconies also serve as roofing for the balconies underneath, although a roof can of course be provided above the balcony for the top floor. It is also possible to dimension the balconies in such a way that they can be used as a seat.

A plurality of balconies are preferably connected to one another by means of a scaffold. The scaffold is expediently free-standing or attached to the building and / or to the vertical supports. Alternatively, the balconies are arranged on the vertical beams.

It goes without saying that the features mentioned above and still to be explained below can be used not only in the respectively specified combination but also in other combinations. The scope of the present invention is defined only by the claims.

The invention is explained in more detail below using an exemplary embodiment with reference to the accompanying drawings. Show it:

1 is a sectional view of the elevator according to the invention,

2 is an enlarged view of a detail II of FIG. 1,

3 shows a front view of a drive unit of the elevator according to FIG. 2, 4 is a plan view of the illustration of FIG. 3,

Fig. 5 is a view of the detail II of FIG. 1 from below and

6 is a side view of the illustration of FIG .. 5

The elevator comprises a car 1 suitable for transporting several people, which is provided with a door 2 and which is reinforced by a frame 4 composed of profiles 3, the frame 4 being arranged in the region of the side of the car 1 having the door 2 , An outer door 52 and a balcony 53 are assigned to the elevator in front of each floor in order to ensure a comfortable transition from the car 1 into a building. The profiles 3 have a U-shaped cross-section, the profiles 3 extending over the height of the cabin 1 being aligned with their webs 5 in the direction of the cabin 1 and the legs 6 of the profiles 3 being perpendicular to the outer wall 7 of the cabin 1 , One of the legs 6 of the profile 3 is firmly connected to a leg 8 of an angle profile 9, the other leg 10 of which extends at a distance across the profile 3 and holds a U-profile 11 on the side facing away from the cabin 1. On the U-profile 11, rollers 13 cooperating with vertical guide rails 12 are mounted and one end of ropes 14 is attached, the other end of which is fixed to a counterweight 15. The guide rail 12, which is T-shaped in cross section, is arranged with the interposition of a holding profile 16 with a web 17 of a vertical beam 18 designed as a double-T beam connected, the foot 19 of the guide rail 12 running parallel to the web 17 of the vertical support 18 is fixed by means of claws 20 on the holding profile 16 welded to the vertical support 18. The web 21 of the guide rail 12 pointing in the direction of the cabin 1 is guided between the rollers 13 both with its parallel longitudinal sides and on the end face. Since this type of storage is present on both sides of the cabin 1, it only has degrees of freedom in the vertical direction.

On the side of the vertical support 18 opposite the guide rail 12, guide means 22 for mounting the counterweight 15 in the corresponding U-shaped recess 23 of the vertical support 18 are provided, the guide means 22 being attached to the opposite flanges 24 of the vertical support 18 and angle profiles 25 as well as on the counterweight 15 stored guide rollers 26 include. The tips of the angle profiles 25 fastened to the flanges 24 of the vertical support 18 with clamping claws 27 point in the direction of the counterweight 15 and are arranged in the middle thereof. The guide rollers 26 are aligned such that their running surfaces 28 roll on the associated legs 29 of the angle profile 25.

At the upper end of the two vertical supports 18, a bracket 30 is arranged on which a drive pulley 31 is mounted, which is driven by a motor 32 with the interposition of a gear 33. Starting from the counterweight 15, the cable 14 arranged on the left side of the cabin 1 runs over a first deflection pulley 34 over the traction sheave 31 and one below the traction sheave 31 and the first Deflection plate 34 arranged second deflection plate 35 to the U-profile 11 to which it is attached. Depending on the load capacity of the elevator, several ropes 14 can of course follow this course. In the present exemplary embodiment, three ropes 14 lying next to one another are provided. The ropes 14 on the right side of the cabin 1 are guided, starting from the assigned counterweight 15, to a third deflection sheave 36 and from there via the traction sheave 31 and a fourth deflection sheave 37 and a fifth deflection sheave 38 for attachment on the cabin side. The arrangement of all deflection sheaves 34, 35, 36, 37, 38 for the traction sheave 31 is selected such that the cables 14 enclose the traction sheave 31 evenly at a certain angle, on the one hand to prevent the cables 14 from slipping and on the other hand to ensure a uniform drive to ensure cabin 1.

To protect against weather influences, in particular against moisture, a hood 39 is arranged on the bracket 30, which spans all the drive parts 40 of the elevator. The hood 39 is connected on both sides of the cabin 1 to housings 41 in which the cables 14 run and the vertical supports 18 and the guide rails 12 and the counterweights 15 are received and which extend over the entire height of the vertical supports 18. In addition, protective housings extending on both sides over the height of the cabin 1 are provided for receiving the profiles 3 of the frame 4. For coupling the cabin 1 to the guide rail 12, the protective housing 42 has a passage 43 for the leg 8 of the angle profile 9 which is associated with the profile 3 of the frame 4 and which has a slot 44 extends through the housing 41. The passage 43 is formed between two projections 45 of the protective housing 42 and has an elliptical shape, the large diameter of which runs along the height of the cabin 1. The two projections 45 protrude through the slot 44 of the housing 41. For sealing purposes, sealing lips 46 are provided on both sides of the slot 44 of the housing 41 and bear against the projections 45 of the protective housing 42. Due to the elliptical shape of the passage 43, the sealing lips 46 are in mutual abutment above and below the passage 43 and otherwise follow the geometry of the projections 45, so that the penetration of water into both the housing 41 and the protective housing 42 is effectively prevented ,

In order to supply electrical devices within the cabin 1 with voltage and to control the elevator, electrical cables 47 are arranged in the housing 41 provided on the left side of the cabin 1. These electrical cables lead on the one hand to the console 30 and on the other hand through the slot 44 of the housing 41 and the passage 43 of the protective housing 42 into the cabin 1. On the right side of the cabin 1 there is a tensioning cable of a safety device 48 which is shown in FIG acts in a known manner on the guide rails 12.

To release the safety device 48 which interacts with the vertical supports 18, a wire cable 49 is fastened on both sides of the cabin 1, on the one hand to the respective counterweight 15 and, on the other hand, to the bottom of the cabin 1. The wire ropes 49 run below the assigned tikalträger 18 in a shaft pit and each hold a pulley 50 with a tension weight 51st

LIST OF REFERENCE NUMBERS

1st cabin 30th console

2. Door 31. traction sheave

3. Profile 32. Motor

4. Frame 33. Transmission

5. Bridge from 3 34. First deflection plate

6. leg of 3 35. second deflection pulley

7. outer wall of 1 36. third deflection plate

8. Leg of 9 37. fourth deflection plate

9. Angle profile 38. fifth deflection plate

10th leg of 9 39th hood

11. U-profile 40

12. Guide rail 41. Housing

13. Roll 42. Protective housing

Rope 43. Passage

15. Counterweight 44. slot

16. Holding profile 45. projection

17th bridge from 18 46th sealing lip

18. Vertical support 47. Electric cable

19. Foot of 12 48. Safety gear

20. Clamping claw 49. Wire rope

21st bridge of 12 50th pulley

22. Guide means 51. Tension weight

23. Recess of 18 52nd outer door

24. flange of 18 53. balcony

25. Angle profile

26. Leadership

27. Clamping claw

28. Tread

29 thigh of 25

Claims

claims

1. Elevator with a cable-driven car (1), the vertical guide rails (12) are assigned, characterized in that the cables (14) on both sides of the car (1) in a housing (41) and a common traction sheave (31) are applied.

2. Elevator according to claim 1, characterized in that the ropes (14) on each side of the car (1) on the one hand with the car (1) and on the other hand with a counterweight (15) are coupled.

3. Elevator according to claim 2, characterized in that the counterweight (15) and the cabin (1) are on opposite sides of a vertical support (18) holding the guide rail (12).

4. Elevator according to claim 3, characterized in that each vertical support (18) is designed as a double-T support and is arranged in the housing (41).

5. Elevator according to claim 3 or 4, characterized in that the vertical supports (18) at their upper ends with a bracket (30) for mounting the traction sheave (31) and a plurality of deflection sheaves (34, 35, 36, 37, 38) for the ropes (14) are provided, the console (30) extends like a bridge between the two vertical beams (18).

6. Elevator according to claim 5, characterized in that a motor (32) driving the traction sheave (31) is attached to the bracket (30) with the interposition of a gear (33).

7. Elevator according to claim 5 or 6, characterized in that the console (30) carries control electronics.

8. Elevator according to one of claims 3 to 7, characterized in that the vertical supports (18) are fastened with the end opposite the bracket (30) in a shaft pit.

9. Elevator according to one of claims 3 to 8, characterized in that the vertical beams (18) are connected to one another by means of a plurality of spaced-apart cross beams.

10. Elevator according to one of claims 3 to 9, characterized in that the web (17) of each vertical support

(18) is aligned parallel to the cabin (1) and carries the guide rail (12) on the side facing the cabin (1).

11. Elevator according to one of claims 3 to 10, characterized in that the flanges (24) on the opposite side of the guide rail (12) of the vertical support (18) have guide means (22) in order to To store the counterweight (15) in the corresponding U-shaped recess (23) of the vertical support (18).

12. Elevator according to claim 11, characterized in that the guide means (22) are formed as opposite to the flanges (24) attached angle profiles (25), on which are supported on the counterweight (15) guide rollers (26).

13. Elevator according to one of claims 1 to 10, characterized in that the cross-sectionally T-shaped guide rail (12) with the interposition of a holding profile (16) on the web (17) of the vertical support (18) is fixed such that its foot (19) runs parallel to the web (17) of the vertical support (18) and has its web (21) guided between cabin-side rollers (13) in the direction of the cabin (1).

14. Elevator according to claim 13, characterized in that the rollers (13) are mounted on a U-profile (11) which is connected via an angle profile (9) to a frame (4) of the car (1).

15. Elevator according to claim 14, characterized in that the frame (4) made of cross-sectionally U-shaped profiles

(3) is assembled, the profiles (3) extending over the height of the cabin (1) with their legs (6) pointing in the direction of the respectively assigned vertical support (18) and one leg (6) of the profile (3) with one leg (8) of the angle pro fils (9) is connected, the other leg (10) holding the U-profile (11).

16. Elevator according to one of claims 1 to 15, characterized in that the car (1) is assigned on both sides to a protective housing (42) extending over its height, which covers the corresponding profiles (3) of the frame (4) and the one Passage (43) for the corresponding leg (8) of the angle profile (9) associated with the profile (3), which extends through a slot (44) of the housing (41) receiving the associated vertical support (18).

17. Elevator according to claim 16, characterized in that the passage (43) is formed between two projections (45) of the protective housing (42) which protrude through the slot (44) of the housing (41).

18. Elevator according to claim 17, characterized in that the housing (41) on both sides of the slot (44) carries V-shaped sealing lips (46) which bear against the projections (45) of the protective housing (42).

19. Elevator according to one of claims 1 to 18, characterized in that within the respective housing

(41) a trigger of a safety device (48) is assigned to one guide rail (12), electrical cable (47) and the other guide rail (12).

20. Elevator according to claim 19, characterized in that the electrical cables (47) through the slot (44) of the housing (41) and the passage (43) of the protective housing

(42) protrude into the interior of the cabin (1).

21. Elevator according to one of claims 1 to 20, characterized in that the traction sheave (31) and the deflection sheaves (34, 35, 36, 37, 38) are covered by a hood (39).

22. Elevator according to one of claims 1 to 21, characterized in that on both sides of the car (1) a wire rope (49) on the one hand to the respective counterweight (15) and on the other to the car (1) is attached, wherein the wire rope (49) runs below the assigned vertical support (18) and holds a deflection roller (50) with a tensioning weight (51).

23. Elevator according to one of claims 1 to 23, characterized in that the cabin (1) and / or the area covered by the hood (39) are connected to a heating and / or air conditioning system for temperature control.

24. Elevator according to one of claims 1 to 23, characterized in that in the plane of a floor of each floor a balcony (53) between an outer door

(52) of the elevator and a building.

25. Elevator according to claim 24, characterized in that several balconies (53) are interconnected by means of a scaffold.

26. Elevator according to claim 25, characterized in that the scaffold is free-standing or attached to the building and / or to the vertical supports (18).

27. Elevator according to claim 24, characterized in that the balconies (53) are arranged on the vertical supports (18).