EP1737778A2

EP1737778A2 - Escalator or moving sidewalk

Info

Publication number: EP1737778A2
Application number: EP05716158A
Authority: EP
Inventors: Wolfgang Stein
Original assignee: ThyssenKrupp Fahrtreppen GmbH
Current assignee: ThyssenKrupp Fahrtreppen GmbH
Priority date: 2004-03-17
Filing date: 2005-03-17
Publication date: 2007-01-03
Also published as: US20080257682A1; WO2005090220A2; CN1953930A; US7703594B2; WO2005090220A3; DE202004004178U1

Abstract

The invention relates to an escalator or moving sidewalk having a frame for building a support structure between the entrance and the exit, said structure consisting at least partly of perforated plates, wherein the holes occupy a substantial part of the height of the frame, preferably up to half of the frame.

Description

Escalator or moving walk

description

The invention relates to an escalator or moving walk, according to the preamble of claim 1.

It has long been known that escalators and moving walks must have frames in order to ensure that the step or pallet belt is supported between the entrance and exit.

Corresponding chain rollers and step rollers typically run on separate rails, which are supported on a frame formed from profiles. In order to form the desired step pattern or to provide the desired pallet band, the rails must run at a predetermined height and be supported there securely and in particular also stiffly. If the rail deflected too much, the passenger would not only get a feeling of insecurity; it would also be feared that the asymmetrical load of the step or pallet belt would exceed the predetermined play, so that the step or pallet rubbed.

It is therefore important that the frames used are particularly stiff and that they do not bend beyond the specified tolerances, even in the event of the maximum permissible operating load of the escalator, but also, for example, of a self-supporting moving walk.

In order to provide the desired rigidity, combinations of T and U profiles which are welded to one another are typically used, which overall form an essentially U-shaped channel which is additionally stiffened by transverse struts. This construction has also proven itself with a larger unsupported length, for example also of 20 m or 30 m.

On the other hand, the use of such massive steel structures is expensive and complex and also requires highly trained supports at the entrance and exit. This is disadvantageous because it increases the cost of the structure in which the escalator or moving walk is to be used. For example, if an escalator extends between different storey levels in a department store, columns are typically not immediately attached adjacent to the escalator eye. Due to the high support weight, however, considerable forces have to be absorbed, so that the strength of the concrete slabs or at least the reinforcement may have to be reinforced.

Furthermore, there is of course the possibility of attaching support columns which extend through the escalator eye from bottom to top. However, such columns are not desirable for aesthetic reasons.

Furthermore, it has been known for about 15 years to use a beam made of a supported steel cable for an escalator frame. Such a solution was, for example, by the CNIM, 35 rue de Bassano, Paris, installed in Paris-Bercy Charenton in the early 1990s. However, this solution is aesthetically somewhat unsatisfactory, because the exposed steel cable makes a very technical impression, even if it helps to keep the weight of the frame low.

Another problem is the high cost of providing the support structure. Typically, the frames are prefabricated in pieces of 2 m or 3 m, for example, by welding the profiles in the factory. They are then brought to the desired location on site with cranes or lifting platforms or the like and welded to one another there. This solution is extremely time-consuming and personnel-intensive, requires heavy equipment and contributes significantly to the construction costs for the escalator.

Therefore, the invention has for its object to provide an escalator or moving walk according to the preamble of claim 1, which builds lighter without sacrificing rigidity, so that it can also be used for buildings with low resilience, but the manufacturing costs should still be reduced.

This object is achieved by claim 1. Advantageous further developments result from the subclaims.

The solution according to the invention provides for the use of perforated plates which build up the frame as a perforated plate frame. Even if the term perforated plate is used here, it goes without saying that this does not mean a perforated plate which is known per se, but rather a specially produced plate into which large holes are made, which alternately extend in different sizes, the largest holes, for example, definitely can take up half the height of a side panel, for example, can have a diameter of 50 cm.

Surprisingly, perforated plates of this type have the advantage that even with permanent vibration stress, such as that encountered when driving stairs occurs, the material fatigue is particularly low, even though a comparatively low weight with high strength can be manufactured inexpensively. Apparently, the spreading of vibrations is made more difficult by the unevenly arranged holes, so that the dreaded resonances are suppressed.

A perforated sheet according to the invention can be produced in any suitable manner.

The perforated sheets according to the invention can be produced by cutting, for example laser cutting, but also any other sheet metal cutting techniques. The perforated sheet metal structure according to the invention enables a significantly reduced weight to be produced compared to the realization with welded U and T profiles; Surprisingly, with the same deflection of an escalator of 20 m in length, the weight of the frame is reduced to about half.

Surprisingly, with the solution according to the invention, the prefabricated longitudinal sections of side plates and bottom plates can be provided much more cheaply. Thanks to the greatly reduced wall thicknesses, the frame can be machined better on site, and the significantly reduced weight significantly reduces the load-bearing capacity of the floor slabs. The heavy equipment used for assembly can also be reduced, although the use of cranes may not be necessary.

Nevertheless, the solution according to the invention results in an extremely rigid support structure for the frame. The weld seams provided on the floor plate and side plates are preferably not provided at the same longitudinal extension point, but offset against one another, which additionally benefits the stiffening. It is also provided in an advantageous embodiment to weld small sheet metal ribs. When using a laser cutter and a laser welding device, such constructions can be realized inexpensively and automatically quickly from the factory, so that the production time is significantly reduced. On the other hand, this means that an escalator manufacturer with smaller storage capacities can work on prefabricated profiles and corresponding elements, which further reduces manufacturing costs.

Surprisingly, the material removal of the cut-out sheet metal circles for producing the large perforated sheet according to the invention results in essentially no weakening of the sheet used, however a significant weight reduction of, for example, 40%, depending on the definition of the hole cutouts. While bolt circles are preferred, it goes without saying that elliptical holes may also have advantages.

The cut-out bolt circles represent high-quality and reusable steel sheet, so that the solution according to the invention also does not entail any cost disadvantages in waste disposal.

The use of sheet metal for escalators and moving walks has long been known per se, for example for the balustrade side cover plates, but also for further cover plates and in some cases also for step guides.

Such known solutions, however, do not offer any real supporting function for the escalator or moving walk, much less a large-hole sheet metal structure, as is necessary according to the invention. .

It goes without saying that the precise design of the sheets according to the invention can be adapted to the requirements in a wide range. For structural reasons, it is advantageous if the perforated circles are offset from each other, so that the transitions between the holes practically each run obliquely to each other.

For example, a specific hole pattern can be specified, which then repeats itself. For example, the prefabricated sheet metal sections can have a length of one meter and a grid division of 4 units can be provided.

In an alternative modified embodiment of the escalator according to the invention, it is provided that the sheets cut to length in the grid dimension overlap one another, so that the adjustment area which is provided once per escalator or moving walk is associated with certain weight disadvantages over a length of less than 1 meter, At this critical point, however, no rigidity disadvantages are to be expected.

Typically, the upper run and the lower run of the step or pallet belt run clearly apart from each other. At the entrance and exit, the distance is determined by the diameter of the drive wheel or deflection wheel of the step or pallet chain.

The free space remaining between the strands allows additional cross struts to be used, as are known per se, and thus to further stiffen the sheet metal construction according to the invention. Such cross struts can consist of folded sheet metal, but can also be designed as profiles.

In an advantageous embodiment, it is also provided that the transfer arches are formed adjacent to the entrance and exit from perforated sheet metal. By limiting the longitudinal section in this area to, for example, 3 m or 4 m, a corresponding sheet with a width of, for example, 1.50 m can be prefabricated as a base, similar to the floor sheet, during which the course of the escalator or the Moving walkway extending side panels made of sheet metal with a width of about 1 m can be realized. Appropriate protruding areas can also be used to implement supports for the comb plates in such side plates for entry and exit.

According to the invention, it is provided that flat sheets are lasered. If required, the metal sheets can also be folded at the ends, for example by rolling. It goes without saying that the dimensioning of the sheets is adapted to the requirements in order to provide the desired strength.

According to the invention, it is particularly expedient if flat sheets are given the desired large-hole sheet metal structure by laser cutting and the connection to the sheets to be extended transversely here is achieved by laser welding. However, it goes without saying that any other welding techniques can also be used, particularly when used on site.

According to the invention, it is provided that the side plates are placed on the base plate and welded there, preferably in a continuous weld in prefabrication ex works. It goes without saying that any other suitable connection can also be used here, if appropriate also a riveted connection after a corresponding bending of one of the sheets.

Further advantages, details and features emerge from the following description of an exemplary embodiment with reference to the drawing.

Show it:

Figure 1 is a side view of part of an embodiment of an escalator according to the invention, namely a side plate.

FIG. 2 shows a side view of part of the embodiment according to FIG. 1, namely another side plate; 3 shows a section through the escalator according to the invention in the embodiment according to FIG. 1, along the line AA;

4 shows a section through the escalator according to the invention in the embodiment according to FIG. 1, along the line B-B; and

5 shows a section through the escalator according to the invention in the embodiment according to FIG. 2, along the line C-C.

The escalator 10 partially shown in FIG. 1 in the embodiment according to the invention has a perforated plate frame 12 which is essentially U-shaped. Fig. 1 shows a side view of the U, ie a view of one of the side legs.

The side legs are formed by side plates, of which a side plate 14 can be seen from FIG. 1, while the middle leg is formed by a bottom plate, as can be seen in the form of the bottom plate 18 from FIG. 3.

The side plate 14 shown in FIG. 1 is in the form of a side plate section which is intended for the lower entry or exit of the escalator.

Substantially more side plates are connected to the part of the side plate 14 which points obliquely upward, so that the entire side plates of the escalator are formed by the combination of the end side plates shown in FIGS. 1 and 2 and central side plates extending between them ,

It also goes without saying that, in the case of a moving walk, the side panels used for entry and exit are not bent - as shown in FIG. 1 - but run straight.

According to the invention, the side plate 14 has a large-hole plate structure 20. In the illustrated embodiment a hole cutout 22 extends over a height of almost 60% of the side plate 14, and more closely adjacent to the upper edge of the side plate 14.

At a distance from this and offset from the hole cutout 22, a somewhat smaller hole cutout 24 extends closer to the lower end of the side plate 14. Between the hole cutouts 22 and 24, hole transitions 26 are formed, the width, size and position as well as inclination of which can be adapted to the requirements in wide areas. The alignment of adjacent hole transitions is preferably different from one another.

In the illustrated embodiment, however, the hole cutouts 22 and 24 are not provided alternately at the bottom and top of the side plate. Rather, the hole cutout 22 is adjacent to a rather small hole cutout 28, which is likewise arranged at the upper end, a quite narrow hole transition 30 extending between the hole cutout 22 and the hole cutout 28. In the manner shown in FIG. 1, further hole cutouts 31, 32 and 33 extend in different distributions, hole transitions 34, 35 and 36 being formed between adjacent hole cutouts.

Hole cutouts or holes that are adjacent to one another are at least either not provided at the same height or do not have the same diameter. This arrangement by means of a stochastically distributed arrangement successfully achieves a low-resonance structure of the large perforated plate 20 according to the invention.

The perforated sheets are produced by cutting out corresponding circles 32 from the sheet which is initially completely present. The cutting can be done in any suitable manner, but preferably by laser cutting. The holes are preferably round, so that the introduction of force is evened out without a notch effect. The perforated plate structure 20 shown in FIG. 1 is additionally stiffened via further ribs. Ribs 37 and 39 are mentioned here as examples. The ribs 37 run through the hole transition 30 perpendicular to the main orientation of the side plate 14, almost up to the bottom plate 18, on the other hand, the ribs 39 run through the hole transition 35 and essentially also extend over the entire height of the side plate 14. The ribs extend depending on the inside, for example over a width of 5 cm. They are formed by sheet metal strips welded there.

The same applies to the ribs 38, which run on the base plate 18, as can be seen from FIG. 3.

In addition, cross struts 40 are provided approximately in the middle of the hole transitions 35 and extend between the two side legs of the U. Such cross struts can be seen, for example, from FIGS. 4 and 5.

A projecting portion 42 is provided on the top of the side panels 14 in a manner as shown in FIGS. 1 and 3. The comb plate of the escalator according to the invention can be stored at this point.

At the end, the frame according to the invention is closed with an L-profile 46, which extends between the two side walls 14.

A corresponding construction of a side plate section for the upper entry or exit can be seen in FIG.

The same reference numerals indicate the same parts here as in the other figures.

It can be seen that a projecting area 48 is also provided, which extends beyond the top web 22 and the configuration of which can be seen in FIG. 5. The side plates 14 according to the invention are connected by a bottom plate 18. The base plate 18 preferably also has hole cutouts 50 (not shown). Preferably, no cutouts are provided in the area of the ribs 38, that is to say quite far to the side, in order to ensure full support of the welded-on ribs 38.

The frame of the escalator according to the invention is extremely rigid both as a section and in a welded-together form and has a particularly low weight in relation to this. It goes without saying that the width and arrangement of the hole cutouts can be adapted to the requirements over a wide range. Likewise, manufacturing is not limited to laser cutting and laser welding; any other type of material separation and material addition can be used. The sheet thickness can also be varied over a wide range depending on the requirement profile in order to provide the desired strength.

Claims

claims

1. escalator or moving walk, with a frame for the formation of a supporting structure between entry and exit, characterized in that the frame (12) is at least partially constructed from perforated plate (20), the holes (hole cutouts) in particular on the side surfaces of the frame are provided and in particular occupy a substantial part of the frame height, preferably approximately half the frame height.

2. Escalator or moving walk according to claim 1, characterized in that the holes or cutouts are round, and in particular that their edges are free of straight sections.

3. Escalator or moving walk according to one of the preceding claims, characterized in that the holes or hole sections are circular, oval and / or ellipsoidal.

4. Escalator or moving walk according to one of the preceding claims, characterized in that the perforated plate frame (12) has two side plates (14) and a base plate (18) which are firmly connected or welded together to form a substantially U-shaped opening are.

5. Escalator or moving walk according to one of the preceding claims, characterized in that the side plates (14) are welded onto the base plate (18), in particular by laser welding.

6. Escalator or moving walk according to one of the preceding claims, characterized in that the side plates (14) form the same hole pattern and are in particular symmetrical to one another.

7. Escalator or moving walk according to one of the preceding claims, characterized in that the holes in the two side plates (14) are arranged so that mutually adjacent holes are offset from one another.

8. Escalator or moving walk according to one of the preceding claims, characterized in that the floor plate (18) has a slit pattern.

9. Escalator or moving walk according to one of the preceding claims, characterized in that on the base plate (18) ribs (38) are attached, in particular welded, which stiffen the base plate (18) against bending.

10. Escalator or moving walk according to one of the preceding claims, characterized in that the perforated pattern (20) of the perforated plates is produced by laser cutting.

11. Escalator or moving walk according to one of the preceding claims, characterized in that at the entrance and exit each end side panels and an end floor panel are formed, which are bent according to the course of the escalator (10).

12. Escalator or moving walk according to claim 11, characterized in that between the end side plates and the end bottom plate extend middle side plates and middle bottom plates, which are prefabricated in a predetermined length of 4 m, for example, or optionally in a predetermined Length that is greater than 4 m.

13. Escalator or moving walk according to one of the preceding claims, characterized in that each with the same hole pattern prefabricated floor (18) and side panels (14) in a predetermined length of 2 m to 6 m, preferably about 4 m, prefabricated and on site are joined, in particular welded.

14. Escalator or moving walk according to one of the preceding claims, characterized in that the perforated pattern of the perforated sheets is characterized by a ratio between sheet and air of less than 3: 1, in particular somewhat less than 2: 1.

15. Escalator or moving walk according to one of the preceding claims, characterized in that on side plates (14) inwardly facing profiles are attached, in particular welded, which serve to hold rails for the roles of the escalator steps or moving walkway pallets.

16. Escalator or moving walk according to one of the preceding claims, characterized in that the side plates (14), which extend perpendicular to the step or pallet band of the escalator or moving walk (10), are stiffened by welded-on ribs (36).

17. Escalator or moving walk according to claim 16, characterized in that the welded-on ribs (36) extend between the holes.

18. Escalator or moving walk according to one of the preceding claims, characterized in that the largest holes take up about 60% of the side panel height and the smallest holes in the side panel about 20% of the side panel height and small and large holes alternate.

19. Escalator or moving walk according to one of the preceding claims, characterized in that the side plates (14) and the base plate (18) are composed by longitudinal seams of plates of different thickness and / or strength, depending on the desired load capacity.

20. Escalator or moving walk according to one of the preceding claims, characterized in that the supporting structure has a cross frame which defines the predetermined width and in which the base plate (18) can be inserted, or to which the base plate (18) can be attached.

21. Escalator or moving walk according to one of the preceding claims, characterized in that the supporting structure stores receptacles for further structural parts, in which in particular the exact relative position between the right and the left side is fixed.