EP1799603A2 - Modular elevator car - Google Patents

Abstract

The invention relates to a lift cage which comprises a platform (1) which is provided with a plurality of platform sections (2, 3, 4). Said cage is characterised in that a front-sided and a rear-sided platform section (3, 4) are arranged on a central platform section (2). The platform sections comprise connection points (2.1, 3.1, 4.1) which are arranged on parallel, vertical planes, whereon said platform sections can be connected together by means of connection elements. In order to provide additional stabilisation for the cage platform, stable platform edge profiles (8) are connected to the uppersides of all platform sections. Subsystems of the lift cage can be premounted in the platform sections. The invention also relates to a method for installing a lift wherein a cage platform (1; 21) is prepared in at least two separate platform sections (2, 3, 4), and the platform sections (2, 3, 4) of the cage platform (1), which are delivered separately, are connected together by means of connection elements during mounting on the installation place.

Description

Elevator car and method for installing an elevator

The invention relates to an elevator car with a car platform, and a method for installing an elevator, which comprises an elevator car according to the invention.

A cabin platform forms the load-bearing basic structure of an elevator car. Their useful surface carries the passengers or objects to be demanded and is in a certain ratio to the payload for which the elevator car is designed. In addition, a cabin platform can take on different other functions, such as the inclusion of subsystems to control the movement of the elevator car, the inclusion of Turfuhrungen or the addition of components of the elevator control.

From DE 31 34 764 a platform for an elevator car is known, which is made of at least two platform sections made of sheet steel, these platform sections are connected to each other by welding. As advantages of this design, a simple production and compared to the cabin floor made of rolled profiles reduced weight are called.

A Kabinen¬ platform produced according to the teaching of DE 31 34 764 has some disadvantages. It teaches a symmetrical design of the cabin platform from two similar platform sections. Due to the similarity of the platform sections their suitability to take on different functions at different locations of the elevator car is severely limited. The platform sections are also fixedly connected to each other so that the cabin platform forms a relatively large unit after the manufacturing process. It is correspondingly difficult to transport the cabin platform within a building, to maneuver it through bottlenecks and to load it through manhole openings into the elevator shaft.

On the one hand, the object of the present invention is to provide an elevator car whose car platform in different sizes is likewise made of a plurality of platform sections, but which can assume different functions at different points of the elevator car. On the other hand, on the basis of the elevator car according to the invention, a rational method for installing an elevator should be defined in which the said transport problems do not occur.

The first object according to the invention is achieved by the elevator car comprising a car platform in which a front and a rear platform section are arranged at a central platform section.

An elevator car according to the invention has the advantage that the car platform does not consist of identical platform sections fixedly connected to one another, but rather that it is constructed from platform sections which have different shapes in order to be able to fulfill different functions occurring in a lift cage or to simplify their realization. The second object is achieved by a method according to the invention, in which a central and one front and one rear platform section are provided separately from each other in the factory delivery of a car platform, and in the case of assembly at the installation site of the elevator, the platform sections separated from each other the cabin platform are interconnected by means of connecting elements. Advantages of this method result in particular when transporting the cabin platform to the installation site and during its transport to the assembly position, for example in a lift shaft of a building.

During transport, the separately delivered platform sections can be packed more easily, and they require less transport space. They can be loaded and unloaded by the transport personnel without special aids, loaded inside a building and brought into a lift shaft via manhole openings, since they weigh less and are less bulky than a complete cabin platform. When mounting at the installation of the elevator, the platform sections can be brought with simple aids in Montagepo¬ position and connected there without great effort to each other to a cabin platform.

In the following, advantageous embodiments and further developments of the invention are described:

According to a preferred embodiment of the invention, the central platform sections of the cabin platform is designed as a lower transverse yoke of the elevator car, in which or on this transverse yoke a plurality of subsystems are mounted, which serve the function of generating the movement of the elevator car, or to control. These subsystems are preferably support rollers and deflection rollers, via which a flexible suspension element carries and drives the elevator car in the form of a cabin underrun, to accommodate cabin guide shoes, with which the lower part of the elevator car approaches

Guide rails is led to safety gear, which brakes the elevator car in an emergency, and a Schutzraumsi securing device to ensure a shelter above the elevator car. The concept of the cabin platform consisting of several platform sections makes it possible to equip the central platform section with the mentioned subsystems at the factory independently of the other sections, which substantially contributes to an improvement of the assembly quality and to a reduction of the installation effort at the installation location of the elevator ,

In accordance with a further preferred embodiment of the invention, the front platform section and the rear platform section are designed differently in order to be able to fulfill different functions. For example, a platform section associated with a door front can fulfill the function of accommodating a door sill in a recess, or having connection elements for fastening a safety bump below the door sill. A rear platform section can, for example, fulfill the functions of enabling the connection between the cabin platform and the cabin rear wall by means of integrated elements or of receiving and fixing connection boxes for the electrical installations of the elevator car. Significant advantages are provided by an embodiment of the invention in which at least two of the platform sections of the cabin platform have connection points arranged in parallel vertical planes, to which these platform sections are connected to one another by connecting elements, preferably with screw connections.

In this solution, the platform sections are automatically aligned when the connecting elements are tightened. In addition, with this arrangement of the connecting parts, the connecting elements are stressed primarily by the load occurring in the elevator operation and less by thrust, which reliably prevents the platform sections from shifting relative to one another under load.

After a weight and cost-saving embodiment of the invention, platform edge profiles are mounted over the two Seitenrandern of Kabinen¬ platform extending over the tops of the flanged platform sections and verbun¬ with these by connecting elements, the platform edge profiles are dimensioned so that they make a significant contribution to the stabilization and sustainability of the cabin platform. Advantageously, their material and their cross-section are selected so that they together and without the involvement of other components, the bending load, which exerts the cabin payload on the projecting from the central platform section 2 platform sections 3, 4, and thereby a deflection of less than 1% of Long experience of the platform sections. These properties of the platform edge profiles are preferably achieved in that they are made of steel or an aluminum alloy and have a cross-section, the posted his horizontal axis of gravity at least one flat moment of inertia of 50 cm ⁴ and / or a total height of at least 6 cm. Thanks to the stabilization of the cabin platform by acting as a connecting element between the cabin platform and the

Cabin side walls anyway required Plattformrandpro¬ file is achieved that the platform sections can be executed with simple shapes, the lowest possible manufacturing costs and minimal weight.

In accordance with a further advantageous embodiment of the invention, the platform edge profiles serving as stabilizing elements also form connecting elements with which the side walls of the elevator car are connected to the car platform.

This solution allows a stable connection between the side walls of the elevator car and the cabin platform, the combination of the two functions of the platform edge profiles resulting in a substantial simplification of the design of the cabin platform and thus considerable cost savings.

Outstanding flexibility with regard to the production of cabin platforms according to the invention is achieved in that the front and / or the rear platform section can be designed as a one-piece platform section or comprise a plurality of subsections.

Particularly inexpensive cabin platforms result with an embodiment in which the subsections of the cabin platform are designed as U-shaped folding profiles, each of which consists of a single piece of sheet metal. According to an economically particularly interesting embodiment of the method according to the invention for the installation of an elevator, subsystems of the substructures on or in the platform section designed as a lower transverse yoke are factory-set

Lift cabin mounted, the production or the Kontrol¬ le the movement of the elevator car serve (suspension rollers, Fuhrungsschuhe, etc.). This is particularly advantageous to implement in the inventive method, since the separate platform sections are not excessively difficult. The factory pre-assembly of the subsystems contributes significantly to an improvement in the assembly quality and to a reduction of the assembly work at the installation of the elevator at.

The term "factory" operation means any manufacturing or assembly operation that takes place prior to delivery and prior to assembly at the installation site of the elevator under factory conditions, d. H. for example in a suitable building and by means of particularly suitable aids and facilities.

According to a further embodiment of the method according to the invention, the front platform section (3, 23) and the rear platform section (4, 24) are designed differently so that they can fulfill different functions.

A particularly cost-saving further development of the method is that the cabin platform is produced according to a modular dimension concept, with the lengths of the front and rear platform sections as well the width of which is selected from a number of dimensions defined in the modular dimensioning concept.

Additional cost savings brings a development of the method, according to which the long-term carriers, which define the lengths of the respective platform sections, and the Quer¬ carriers, which define the width of the platform sections are made independently of each other and kept in stock and the pre-assembly of the platform sections factory only due a concrete contract with specified cabin dimensions by combination of prefabricated longitudinal and transverse beams with corresponding dimensions er¬ follows.

According to a particularly advantageous embodiment of the inventive method, the platform sections of the cabin platform are individually packaged and / or transported in a separate state to the installation site prior to installation at the installation of the elevator.

This generally facilitates the handling of the cabin platform, the packaging is simplified and the separate platform sections can be loaded with simpler or no auxiliary means and in smaller vehicles during transport to the installation site.

Two exemplary embodiments of the invention are explained below with reference to the accompanying drawings.

Show it:

Fig. 1 is a perspective exploded view of a first embodiment of the cabin platform of an elevator car according to the invention.

Fig. 2 is a side view of the cabin platform according to FIG. 1 in an exploded view.

3 shows a side view of a second embodiment of the cabin platform of an elevator cabin according to the invention.

Fig. 4 is a view of the cabin platform according to FIG. 3 in the longitudinal direction and a section through the cabin platform.

Fig. 1 shows in the form of a perspective exploded view of the structure with all the essential components of a first embodiment of the cabin platform 1 of an elevator car according to the invention. 2 shows the cabin platform 1 according to FIG. 1 in mounted state, in a side view.

The cabin platform 1 comprises a plurality of platform sections 2, 3, 4, which are made of sheet steel and steel plates, wherein each of a front and a back Plattform¬ section 3, 4 are arranged on a central platform section 2 net. On the lying in a common plane

Top sides of the platform sections is a Kabinenbodenplat¬ 9 fixed, which is preferably designed as a composite plate. Honeycomb sandwich panels made of aluminum or plastics or wood fiber boards with metal composite layers on both sides are preferably suitable as cabin floor panels. The central platform section 2 is designed as a lower transverse yoke of the elevator car, which is integrated into the cabin platform. It gives it the required stability, while saving the space that is claimed in conventional elevator cabins by a transverse yoke below the cabin platform, which is not integrated into it.

The central platform section 2 forming a lower transverse yoke has, among other things, attachment points 2.5, 2.6 for cabin guide shoes or for safety gears. There may also be safety buffers attached to this cross bar. In addition, in the transverse yoke forming central platform section 2 supporting and deflection rollers 11 are integrated, via which carries a flexible support means the elevator car and moves. In the present case, the support and Um¬ guide rollers 11 extending in the circumferential direction grooves and ribs, which cooperate with ribs and grooves of serving as a support means V-ribbed belt.

In addition, a protective space protection device 12 may be integrated into the central platform section 2 forming the lower transverse yoke. This ensures by lateral extension of a locking bar 12.1, which cooperates with a stop fixedly mounted in the elevator shaft, that, for example, during a inspection trip a safety distance between the car roof and the shaft head, or between the cabin floor and the bottom of the elevator shaft, can not be fallen below.

The platform sections 2, 3, 4 have connection points 2.1, 3.1, 4.1 lying in parallel verti cal planes, on each of which two of the platform sections are connected by means of links. are elements connected to each other 10. There are preferably applied releasable fasteners such as screw connections. However, the connection of the platform sections, which takes place only during assembly at the installation location of the elevator installation, can also be realized with non-detachable connection elements, for example with rivets.

In this connection concept, the platform sections to be connected in each case are roughly aligned with each other during assembly of the cabin platform at the installation site of the elevator. These are then pressed together with the help of Verbmdungselemente in the field of vertical Verbindungs¬, whereby the platform sections align themselves independently. The precise mutual alignment is supported by the simultaneous attachment of Plattformrandprofllen, which are described nach¬ standing.

All platform sections 2, 3, 4 comprise at least two longitudinal carriers 2.2, 3.2, 4.2 and at least one cross member 2.3, 3.3, 4.3 each. The cross member 2.3 is part of the central platform section 2, which forms a lower transverse yoke of the elevator car which is integrated into the cabin platform 1. The cross member 3.3 serves as a carrier of a door sill profile 7 (shown only in Fig. 2) and supports 13 for a safety gap, and an upper part of the cross member 4.3 is formed so that a rear cabin wall (not shown) can be fixed to it.

Reference numeral 8 designates two platform edge profiles which, when mounted on the installation site of the elevator, are attached to attachment points 2.4, 3.4, 4.4 of the platform. Sections 2, 3, 4 are connected to the latter and extend over the tops of all flanged platform sections. The said fastening points on the platform sections are arranged so that they lie in the assembled state of the cabin platform 1 in the side edge region and in a common horizontal plane. The platform edge profiles 8 are dimensioned such that they make a significant contribution to the stability of the entire cabin platform 1. Advantageously, their material and their cross-section are selected so that they together and without the involvement of other components, the bending load which exerts the cabin payload on the projecting from the central platform section 2 platform sections 3, 4, and thereby a deflection of less than 1% of Long experience the respective Plattformsekti¬ ones. These properties of the platform edge profiles 8 are preferably achieved in that they are made of steel or an aluminum alloy and have a cross section having at least a flat moment of inertia of 50 cm ⁴ and / or a total height of at least 6 cm with respect to its horizontal axis of gravity.

The platform edge profiles 8 on the one hand serve to stabilize the entire cabin platform 1, so that the requirements for the stability of the platform sections 2, 3, 4 can be correspondingly reduced. These can therefore be produced with less weight. In the present case, the platform sections 3 and 4 are made exclusively of sheet steel with a maximum thickness of 2.5 mm. On the other hand, the platform edge profiles 8 serve to connect the cabin sidewalls (not shown) to the cabin platform 1 and thereby form one of the cabins. visible from the outside, aesthetically demanding transition element between the cabin floor and the cabin side walls mentioned.

When mounted on the installation site of the elevator, the platform edge profiles 8 also serve to precisely and flush align the tops of the flanged platform sections 2, 3, 4 with the help of the connecting elements 14 between them and the platform sections.

In and / or on the front or rear platform sections 3, 4, cabin components such as a door sill profile 7, a holder 13 for a safety lug underneath the sill profile 7, a holding element 4.3.1 for the cabin pressure wall, limit switch, connection box for electrical systems, Schachtbeleuch¬ tung lamps etc. may be present. So that the front or rear platform sections 3, 4 can fulfill these functions, they have correspondingly different shapes.

The above-mentioned, in one of the platform sections 2, 3, 4 integrated or attached to these components and subsystems (Kabinenfuhrungsschuhe, safety gear, Sicherheits¬ buffer, support and pulleys, Schutzraumsicherungs- device, safety gap, limit switches, Anschlusskas¬ th, lamps, etc .) are preferably already factory pre-assembled and preferably wired in order to keep the assembly costs at the installation site of the elevator as low as possible and to optimize the assembly quality. An inventive, built up of several platform sections Cabin platform offers ideal conditions for this assembly concept, since on the one hand the individual platform sections to be transported and mounted in the assembly position are still relatively easy to manipulate, even with integrated subsystems, and on the other hand the still separate platform sections can be better packed, so that the components mentioned and Subsystems are sufficiently protected ge.

The longitudinal members 3.2, 4.2 defining the lengths L3, L4 of the respective platform sections 3, 4, and the cross members 2.3, 3.3, 4.3 defining the width B of the platform sections 2, 3, 4 are produced independently of each other and held in stock, the lengths L3 and L4 as well as the width B of the platform sections 2, 3 and 4 are selectable according to a modular dimensioning concept. The plant-side pre-assembly of the platform sections takes place only on the basis of a specific order with defined cabin dimensions by combining longitudinal and transverse beams with corresponding dimensions.

With this manufacturing and storage concept, the costs for production and storage of the cabin platforms can be kept extremely low, while an optimal Liefer¬ preparedness remains ensured.

3 shows a side view of a second embodiment of a cabin platform 21 of the elevator cabin according to the invention. 4 shows a view of this cabin platform 21 in its longitudinal direction A and a cross section through the cabin platform on the interface designated II-II in FIG. 3. This embodiment of a cabin platform 21 according to the invention also comprises a plurality of platform sections 22, 23, 24, one front and one rear platform section 23, 24 being arranged on a central platform section 22. The front-side and rear-side platform sections 23, 24 are preferably constructed from a plurality of subsections 23a, 23b, 24a, 24b. The subsections 23a, 23b, 24a, 24b of the front and rear platform sections 23, 24 are designed as substantially U-shaped abutment profiles and are each produced by parallel folding from a single sheet metal stucco. The vertically arranged legs of the U-shaped Abkantprofile act on the one hand as transverse reinforcements of the cabin platform, and on the other hand they form in vertical planes arranged connection points 22.1, 23.1, 24.1, to which the subsections are connected by means of connecting elements 30, and which also provide Verbindungs¬ between the central platform section 2 and the front and rear platform sections 23, 24, respectively. Short and long front and rear platform sections may also comprise only a single U-shaped folding profile.

The central platform section 22 is like the first one

Embodiment designed as in the cabin platform 21 integrated lower cross yoke of the elevator car and made exclusively of sheet steel. This platform section 22 likewise has fastening points for cabin shoes and safety devices, such as the lower transverse yoke shown in FIG. However, these attachment points are not shown here to the representation of the particular simple structure of the platform sections should not be impaired.

The front and rear platform sections 23, 24 may be of different shapes to accommodate different functions and requirements or to allow different positions of the central platform section. They can for example be shaped (abgekan¬ tet) that they can receive a door sill profile 27, or that in their Blechkorper a fastening element 24b.1 is integrated for fixing the cabin pressure wall. Different dimensions of the cabin platform 21 are realized by adapting the lengths L 24, L 25 of the platform sections 23, 24 flanged to the central platform section 22 (transverse yoke) or their subsections 23a, 23b, 24a, 24b. Different widths B are achieved by using differently wide steel sheets for the production of the platform sections 22, 23, 24 or 22, 23a, 23b, 24a, 24b.

In this cabin platform 21, too, all the subsystems and components mentioned in connection with the first embodiment can be integrated into or attached to the platform sections 22, 23, 24, the installation or fitting of the subsystems being factory-assembled in the separate ones Platform sections.

As mentioned above, the platform sections 23, 24 flanged onto the central platform section 22, or their subsections 23a, 23b, 24a, 24b in this embodiment of the cabin platform, are each made from a single sheet metal part whose U-shaped configuration is characterized by einfa¬ ches parallel folding is generated. All platform sector NEN, or subsections have vertically oriented webs, which extend in the transverse direction of the cabin platform 21 and lend the cabin platform in the transverse direction sufficient Stabi¬ quality. In order to additionally fix the position of the free lower ends of the vertical webs, these can be connected to one another by way of example by means of an auxiliary profile 31. The installation of this auxiliary profile 31 takes place only at the installation of the elevator.

As can easily be seen from FIG. 3, the platform sections constructed from relatively thin sheet-metal sections folded off in the transverse direction do not provide sufficient bending stability in their longitudinal direction for a cabin platform. In the case of the embodiment of a cabin platform 21 described here, too, therefore, the stability of the cabin platform in the longitudinal direction required for elevator operation is ensured by two sufficiently stable platform edge profiles 28 with the top sides of all in a common plane during assembly at the installation location Platform sections 22, 23, 24 are connected.

In this embodiment too, the platform edge profiles 28 additionally serve as connecting elements between the cabin side walls (not shown) and the cabin platform 21. The platform edge profiles 28, which here have a rectangular cross-section, both with the platform sections 22, 23, 24 to be able to connect with the side walls, the platform edge profiles 28 are provided over their entire length with a plurality of T-shaped grooves 32. When installing the cabin platform 21 at the installation site, screw heads or nuts with suitable shape are inserted into introduced these T-shaped grooves 32 and bolted to the Plattform¬ sections and the side walls.

With the exception that in this second embodiment, the platform sections do not comprise cross members and therefore are not separately manufactured and held in stock, all the properties and advantages of the car platform mentioned in connection with the first embodiment apply Advantages of the method for installing an elevator also for the second embodiment described here.

Claims

claims

Elevator car with a car platform (1, 21) comprising a plurality of platform sections (2, 3, 4, 22, 23, 24), characterized in that on a central platform section (2, 22) a front and a rear side Platform section (3, 4, 23, 24) are arranged.

2. Elevator car according to claim 1, characterized in that the central platform sections (2; 22) of the cabin platform is designed as the lower cross [...] of the elevator car, or m which several subsystems are mounted, which are the production or the Control the movement of Auf¬ zugskabine serve.

3. elevator car according to claim 2, characterized in that on or in the formed as a lower transverse yoke platform section (2; 22) at least one of the following subsystems of the elevator car is mounted:

- Support and deflection rollers (11), via which a flexible support means carries and drives the elevator car,

- cabin guide shoes, - safety gear

- Protection space protection device (12) to ensure a shelter above the elevator car.

4. elevator car according to one of claims 1 - 3, characterized in that the front-side platform section (3,

23) and the rear platform section (4, 24) are differently designed to different functions to be able to fulfill.

5. Elevator car according to one of claims 1 to 4, characterized in that at least two of the platform sections (2, 3, 4, 22, 23, 24) arranged in parallel vertical planes connecting points (2.1, 3.1, 4.1, 22.1, 23.1 , 24.1), to which these platform sections are connected to one another by means of connecting elements (10, 30).

β. Elevator car according to one of claims 1 - 5, characterized in that above the two side edges of the car platform (1; 21) platform edge profiles (8, 28) are mounted which extend over the upper sides of all platform sections (2, 3, 4) 22, 23, 24) and connected thereto by means of connection means (14, 34).

7. elevator car according to claim 6, characterized in that the cross section and the material of the Plattformrandpro¬ file (8, 28) are chosen so that this is the bending load, which the cabin payload to that of a central

Platform section (2, 22) cantilevered platform sections (3, 4, 23, 24) exercises, record and thereby undergo a deflection of less than 1% of the length of the platform sections.

8. elevator car according to claim 6 or 7, characterized gekenn¬ characterized in that the platform edge profiles (8, 28) made of steel or an aluminum alloy and have a cross-section, with respect to its horizontal axis of gravity at least one flat moment of inertia of 50 cm ⁴ and / or has a total height of at least 6 cm.

9. elevator car according to one of claims 6 - 8, characterized in that the platform edge profiles (8, 28) form a Verbmdungselement for fastening the side walls of the elevator car to the cabin platform (1, 21).

10. elevator car according to one of claims 1-9, characterized in that the front side and / or the rücksei¬ term platform section (3, 4; 23, 24) are designed as a one-piece platform section or a plurality of subsections (23a, 23b, 24a , 24b).

11. Elevator car according to claim 10, characterized in that the front and rear platform sections

(23, 24), or their subsections (23a, 23b, 24a, 24b) of the cabin platform (21) are designed as U-shaped Abkantprofile, each consisting of a single Blechstuck.

12. A method for installing an elevator comprising an elevator car with a cabin platform (1, 21) made up of several platform sections (2, 3, 4, 22, 23, 24), characterized

that in the factory delivery of a cabin platform (1; 21), respectively one central and one each front and one rear platform section (2, 3, 4, 23, 24) are provided separately from each other,

- That during assembly at the installation of the elevator, the separate platform sections (2, 3, 4, 22, 23, 24) of the cabin platform (1, 21) by means of connecting elements (10, 30) are interconnected.

13. The method according to claim 12, characterized in that at the factory on or in the form of a lower cross yoke platform section (2; 22) of at least one of the following subsystems of the elevator car is mounted:

- carrying and deflecting rollers (11), via which a flexible support means carries and drives the elevator car, - cabin guide shoes,

- Safety gear

- Protection space protection device (12) to ensure a shelter above the elevator car.

14. The method according to claim 12 or 13, characterized gekennzeich¬ net, that the front side platform section (3, 23) and the rear platform section (4, 24) are gestal¬ different, so that they can fulfill different functions.

15. The method according to any one of claims 12-14, characterized in that the platform sections (2, 3, 4, 22, 23, 24) of the cabin platform (1, 21) arranged in parallel verti¬ cal planes connecting points (2.1, 3.1 , 4.1, 22.1, 23.1, 24.1).

16. The method according to any one of claims 12-15, characterized in that the cabin platform (1; 21) is produced according to a modular dimensioning concept, wherein the lengths (L3, L4; L23, L24) of the front and the rear platform sections ( 3, 4; 23, 24) as well as their width (B) are selected from a number of dimensions defined in the modular dimensioning concept.

17. The method according to any one of claims 12-16, characterized in that prior to installation at the installation of the Elevator the platform sections (2, 3, 4, 22, 23, 24) of the cabin platform (1, 21) are individually packed and / or transported in ge-separated state to the installation site