The present invention relates to a passenger conveyor and in particular to a truss construction for a basically horizontally conveying passenger conveyor as e.g. a moving walkway.
Passenger conveyors are e.g. escalators or moving walkways. Escalators are passenger conveyors that typically carry passengers between landings at different levels in buildings, for example. Moving walkways are usually used to carry passengers along levels extending horizontally or with only slight inclination.
A passenger conveyor typically includes a truss construction, balustrades with movable handrails, tread members, e.g. plates, a drive system and a step chain for engaging and propelling the tread members. In an escalator the tread members typically have the form of steps, while they typically have the form of pallets in case of a moving walkway. The step chain travels in an endless way between turnaround sections located at an upstream landing and a down-stream landing, respectively. The truss construction supports the other components of the conveyor and rests on a basement. The truss construction includes truss sections on lateral sides of the tread members, each truss section generally extending in a vertical plane extending along the conveying direction. Each truss section has two end sections. The end sections at both lateral sides on a respective longitudinal side of the conveyor form a landing, respectively. The end sections of a same lateral side are connected by an inclined or—in case of a moving walkway—generally horizontal midsection. Typically, one of the landings, e.g. in case of an escalator usually the upper landing, houses the drive system or machine of the passenger conveyor positioned laterally between the truss sections.
In a common passenger conveyor the truss construction is usually entirely welded. I.e. all truss members are made of structural steel profiles connected by welded joints. The welding operation is either performed manually or automatically by means of welding robots. The required dimensional precision of the entire conveyor truss is achieved by manufacturing support means, i.e. welding tables, assembly and alignment fixtures. All additional components of the conveyor, such as a track system for guiding step chain rollers and/or step rollers, a machine, a balustrade or a handrail drive are attached to the truss by welding or bolting.
The assembly of such a conventional welded truss construction is complex and expensive. Welding the truss in the factory results in a large workpiece which is complicated to transport and to install on site. On-site welding during construction requires knowledge and experience and involves the particular problem of achieving the necessary precision when mounting the guide rails, as the typical tolerances for the truss are some millimeters, while the typical tolerances for the guide rails are some tenths of a millimeter. The use of welding robots is almost impossible in on-site welding.
In addition, such a common complex truss structure has a certain thickness or height in the vertical direction, which is disadvantageous for the implementation of a flat moving walkway as it requires providing a pit having a considerable depth in order to accommodate the truss structure under the floor level.
It is therefore desirable to provide a truss construction for a passenger conveyor providing a flat frame which can be produced and mounted easily with sufficiently high accuracy. In addition, it would be desirable to be able to integrate as much functionality as possible in such truss construction.
A section of a truss (“truss section”) according to an exemplary embodiment of the invention is configured to support at least one tread element in a passenger area of a passenger conveyor of the type conveying passengers by moving the at least one tread element in a longitudinal direction along the passenger area between a first landing and a second landing. The truss section comprises at least two longitudinal elements extending basically parallel to each other in the longitudinal direction; and at least one lateral connector connecting the at least two longitudinal elements, wherein each of the at least two longitudinal elements comprises at least one load-bearing portion having the configuration of a single wall profile.
As the longitudinal elements of such a truss-section comprise at least one load-bearing portion having the configuration of a single wall profile, these longitudinal elements may be formed as an extruded or roller-molded profile, in particular made of a light metal, as e.g. aluminum. Both longitudinal elements may be formed having an identical shape, so that both longitudinal elements may be produced in the same manufacturing process by extruding or roller-molding. Thus, truss-sections according to exemplary embodiments of the invention may be produced efficiently at low costs.
As the truss has the benefit to support over a small distance, it is intended to be placed directly on a rigid floor construction of a building and a light material, in particular Aluminum, may be used.
A truss for a passenger conveyor according to an exemplary embodiment of the invention is described in detail in the following with reference to the enclosed figures.
The figures and the following discussion describe particular embodiments of the invention so as to teach those skilled in the art how to produce and use the best modes of the invention. In order to teach the principle of the invention, several conventional aspects have been simplified or omitted. Those skilled in the art should understand that variations originating from these embodiments also fall within the scope of the invention. Those skilled in the art should understand that the features to be described below can be combined in various ways so as to form numerous variations of the invention. Therefore, the invention is not limited to the following particular embodiments and is merely defined by the appended claims and their equivalents.
The passenger conveyor 15 comprises a truss 10 for supporting tread members, which are not shown in
An outer end portion of the truss 10 forming a landing portion is provided with a drawer mechanism 19 providing easy access to a maintenance space (not shown), which is provided below the truss 10.
The structure of the truss 10 and the drawer mechanism 19 will be described in more detail with respect to the following figures.
The exemplary embodiment of a truss 10 for a passenger conveyor 15, as it is shown in the enclosed figures, comprises a drive landing section 2, at least one mid section 3 and a return landing section 4. Said sections 2, 3, 4 are arranged adjacent to each other in the longitudinal direction of the truss 10. Although only one mid section 3 is shown in
Each of the sections 2, 3, 4 comprises two longitudinal truss elements 5a, 5b extending basically parallel to each other in the longitudinal direction. Lateral connectors 6, 7 extend laterally, in particular orthogonally, to the longitudinal direction between the longitudinal elements 5a, 5b such as to connect the longitudinal elements 5a, 5b with each other. The ends of the lateral connectors 6, 7 are respectively connected between the longitudinal elements 5a, 5b forming a rigid framework comprising the two longitudinal elements 5a, 5b and a plurality of lateral connectors 6, 7.
On each end of the truss sections 2, 3, 4 in the longitudinal direction a respective end connector 7 is arranged such that it connects to both of two adjacent longitudinal sections 2, 3, 4, so that the end connector 7 aligns and fixes two adjacent truss sections 2, 3, 4 to each other. Each end connector 7 thereby connects a total of four longitudinal elements 5a, 5b with each other, forming a chain of truss sections 2, 3, 4 extending in the longitudinal direction of the truss 10. The end connectors 7 are shared by each two adjacent truss sections 2, 3, 4.
A floor plate 12 providing a lateral connector element of the conveyor 15 is attached to the inner parts 1a, 1b. A comb portion 11 and a ramp portion 13 are attached to the floor plate 12 and also attached to the inner parts 1a, 1b. However, the floor plate 12 may also be formed integrally with a comb portion 11 and/or a ramp portion 13. The inner parts 1a, 1b are sliding or rolling along the tracks of the outer remaining profile 1c, 1d, so that the floor plate 12 is also moveable with respect to the fixed portion of the truss 10 and the floor. This design provides a drawer mechanism 19 allowing an easy access to the entire inner space provided in and/or below the landing, so that the motor (not shown) and all additional devices for driving the conveyor 15, which are housed in a maintenance space below the truss 10, can be easily accessed and maintained by opening the drawer mechanism 19.
The fixed outer part 1c, 1d comprises a least on stopper element 1f, which is configured for stopping the opening and/or closing movement of the inner part 1a, 1b, and at least one fixture 1e for fixing the moveable inner part 1a, 1b in at least one of its open and closed positions.
All additional components, as e.g. plates, skirts etc., can be mounted to the truss 10 directly, in particular to the longitudinal elements 5a, 5b. Threads may be formed directly in the longitudinal elements 5a, 5b for mounting the additional components, which may be designed in a way so that screw, bolt, pin, nut etc. connections can be used which may even be visible for the passenger. In contrast to a classical truss arrangement, additional small light (LED) elements can be simply placed on or within the truss 10.
Guide tracks 55, 56, 57 for guiding the tread plates (not shown) are formed integral with longitudinal elements 5a, 5b of the truss 10, as will be discussed in more detail below with respect to
The comb portion 11, the floor plate 12 and the ramp portion 13 are connected to the moveable inner part 1a in order to move together with said moveable inner part 1a.
A number of support elements 21 are provided for supporting the comb portion 11, the floor plate 12 and/or the ramp portion 13. In the embodiment shown in
The support members 21 may be rotatable around their axes or provided with rollers, which are not shown in the figures, in order to reduce the friction between the support members 21 and the comb portion 11, the floor plate 12 and the ramp portion 13, respectively. Additional base rollers 28 are provide at a lower side of the ramp portion 13 supporting the ramp portion 13 in the floor and minimizing the friction between the ramp portion 13 and the floor when the ramp portion 13 is moved against the floor.
The ramp portion 13 and the truss 10 are respectively provided with locking members 24, 26, which are configured to engage with each other when the drawer mechanism 19 is positioned in its closed position in order to secure the ramp portion 13 in said closed position. In the engaged state the locking members 24, 26 in particular prevent the ramp portion 13 from lifting from the support members 21 even when a shock like load, which e.g. may be caused by a jumping passenger, is applied.
The mid section 3 shown in
Each of the longitudinal elements 5a, 5b may be formed as an extruded or roller-molded profile 5a, 5b made of a light metal, in particular aluminum. Both longitudinal elements 5a, 5b may be formed having an identical shape, so that both longitudinal elements 5a, 5b may be produced in the same manufacturing process of extruding or roller-molding. In order to form a mid section 3 of the truss 10, the longitudinal elements 5a, 5b are arranged in a mirrored orientation with respect to a virtual mirror plane A located in the middle between the two longitudinal elements 5a, 5b.
The longitudinal elements 5a, 5b have a genus of zero, i.e. in a cross-section which is oriented perpendicularly to the longitudinal direction of the longitudinal elements 5a, 5b, there are no closed curves or spaces. Such a structure considerably facilitates the production of the longitudinal elements 5a, 5b by in means of extrusion and/or roller molding as it is complicated to form structures comprising closes curves and/or spaces in a sectional view by means of extrusion or roller-molding and therefore usually additional steps, as e.g. fusing or welding, are necessary form forming said closed structures.
Each of the longitudinal elements 5a, 5b comprises a lower, basically horizontally oriented portion lower 51, a basically vertically extending middle portion 53 and an upper portion 52. The middle portion 53 is respectively connected with the upper portion 52 and the lower portion 51 by oblique intermediate portions 59a, 59b. All these portions 51, 52, 53 are essentially flat, extend in a longitudinal plane and provide a combination of load-bearing portions 51, 52, 53 having the configuration of a single wall profile.
The load-bearing portions 51, 52, 53 include a substantially vertically extending medium portion 53 and a substantially horizontally extending lower foot portion 51, a lower part of the medium portion 53 being connected to the foot portion 51, any of the medium portion 53 and/or the foot portion 51 having the configuration of a single wall profile.
The medium portion 53 faces towards the passenger area 30 and the foot portion 51 extends from the medium portion 53 towards a side facing the passenger area 30 as well as towards an opposite side facing away from the passenger area 30.
On the side facing the opposing longitudinal element 5a, 5b, i.e. on the inner side of the truss 10, each of the lower portions 51 is formed with an engagement portion 58 configured to be engaged with an engaging element 65 of a lateral connector 6, which will be described in more detail below.
A first track 57 providing a return line for the chain rollers (not shown) of the conveyor 15 is formed on an upper surface of the lower portion 51 adjacent to an engagement portion 58 and an engaging element 65.
On the outer side of the lower portion 51, i. e. the side facing away from the opposing longitudinal element 5a, 5b, a cover element receiving slot 70 is formed, which is configured for receiving an end portion 74 of an outer cover element 72 to be fixed to the outside of the truss 10.
A recess 71 is formed adjacent to the cover element receiving slot 70 for receiving at least one first magnetic element 68a in order to additionally fix the outer cover element 72 which may be made from magnetic material, in particular sheet metal.
The basically vertically extending middle portion 53 of the longitudinal element 5a, 5b comprises a protrusion 53a on the inner side, i. e. the side facing the opposing longitudinal element 5a, 5b. A groove 53b, which is configured for receiving a portion of a second connector element 62 of a lateral connector 6, is formed on the (inner) side of the protrusion 53a facing the opposing longitudinal element 5a, 5b. A second track 55 for guiding the chain rollers (not shown) of the conveyor 15 along the passenger line is formed on the upper surface of the protrusion 53a. A third track 56 for guiding pallet rollers of the conveyor 15 along the passenger line, is formed on an upper surface of the middle portion 53.
Thus, the entire track system 55, 56, 57 of the conveyor 15 including the passenger lines 56, 57 as well as the return line 55 is provided by the profiled bar-like elements forming the longitudinal elements 5a, 5b. As a result, it is not necessary to produce and install additional tracks for guiding the rollers of the conveyor 15, and the efforts and costs for producing and installing the conveyor system are considerably reduced.
A balustrade receiving slot 60, which is configured for receiving at least one balustrade panel 63 of a conveyors balustrade, is formed in an upper surface of the upper portion 52 of the longitudinal elements 5a, 5b. The balustrade panel 63 may be made of metal, glass, acrylic glass or any other suitable material.
Mounting the balustrade panels 63 be means of a slot 60, which is provided in an upper surface of the longitudinal elements 5a, 5b, facilitates the installation of the balustrade and reduces the costs for producing and installing the conveyor 15 even further.
A further recess 64 is provided in the upper portion 52 outside of to the balustrade receiving slot 60 in order to receive at least one second magnetic element 68b, which is configured to additionally fix the outer cover element 72.
Each of the longitudinal elements 5a, 5b further is formed comprising a decking skirt panel mounting area 54 extending obliquely from a position on the inner side of the upper portion 52 of the respective longitudinal element 5a, 5b adjacent to the slot 60 downward and to the opposing longitudinal element 5a, 5b.
A decking skirt panel 66 may be mounted and fixed to the decking skirt panel mounting area 54 by means of hooks 66a, 66b formed at the ends of the decking skirt panel 66 and wrapping around the decking skirt panel mounting area 54 when the decking skirt panel 66 is fixed to the longitudinal element 5a, 5b. Alternatively or additionally further magnetic elements (not shown) may be used for fixing the decking skirt panel 66 to the decking skirt panel mounting area 54.
Thus, longitudinal elements 5a, 5b according to exemplary embodiments of the invention not only save the efforts and costs for providing the tracks 55, 56, 57 for guiding the rollers of the conveyor system and mounting tracks to a conventional truss, but further allow to easily mount and fix the outer cover element 72 as well as the decking skirt panel 66.
Two respective longitudinal elements 5a, 5b opposing each other in lateral direction of the truss 10 are connected to each other by means of lateral connectors 6. Each of the connectors 6 comprises a first (lower) connector element 61 and a second (upper) connector element 62, which are arranged at different vertical positions, as it is shown in
The first (lower) connector element 61 comprises a middle portion 61a extending basically horizontally between the longitudinal elements 5a, 5b and engaging elements 65 which are provided at both lateral ends of the middle portion 61a and engage with the corresponding engaging portions 58 formed at the inner ends of the lower horizontal portions 51 of the longitudinal elements 5a, 5b.
The second (upper) connector element 62 comprises a middle connector portion 62a extending basically horizontally between the longitudinal elements 5a, 5b and adjacent oblique portions 62b, 62c connected to the lateral ends of the middle connector portion 62a and extending upwardly thereof.
In order to fix the second connector element 62 to the longitudinal elements 5a, 5b, the lateral outer ends of the second connector element 62 facing the longitudinal elements 5a, 5b are respectively provided with a nose 67 engaging with the groove 53b formed in the protrusion 53a of the middle portion 53 of respective longitudinal element 5a, 5b facing the second connector element 62.
In consequence, the two longitudinal elements 5a, 5b in combination with the first and second connector elements 61, 62 provide a rigid framework comprising the two longitudinal elements 5a, 5b and a plurality of lateral connectors 6 formed by the first and second connector elements 61, 62.
The structure of outer longitudinal elements 1c, 1d corresponds to the structure of the longitudinal elements 5a, 5b shown in
In the upper portions 52 of the outer longitudinal elements 1c, 1d side rollers 22 are provided for moveably supporting the moveable inner longitudinal element 1a, 1b which are connected to each other by the lateral connector element (floor plate) 12.
Handles 29 are respectively provide at the outside of the outer longitudinal elements 1c, 1d in order to facilitate their movement. A support element 21 is provided below the lateral connector element 12. Below the support element 21 base rollers 28 moveably supporting the ramp portion 13 are shown. Locking elements 26 are provided for locking moveable portions of the drawer mechanism 19, in particular the lateral connector element 12 in its closed position.
A number of optional features are set out in the following. These features may be realized in particular embodiments, alone or in combination with any of the other features:
In an embodiment the load-bearing portion has a substantially vertically extending body portion and a substantially horizontally extending foot portion, a lower part of the body portion being connected to the foot portion, any of the body portion and/or the foot portion having the configuration of a single wall profile. Such a configuration provides a rigid and very stable load-bearing portion which may be produced easily by extrusion or roller molding.
In an embodiment the body portion faces towards the passenger area and/or the foot portion extends from the body portion towards a side facing the passenger area as well as towards an opposite side facing away from the passenger area.
In an embodiment the truss section further comprises at least one outer cover element, which is attached to the load-bearing portion on a side facing away from the passenger area such that the load-bearing portion and the cover element define a compartment for the handrail return section of the passenger conveyor. This provides a compartment for the handrail return section of the passenger conveyor without the need for additional elements. Thus, truss comprising a handrail return section may be provided at low costs.
The cover element may be removable attached, in particularly clipped, to the load-bearing portion providing a convenient attachment of the cover element, which is easy to separate for replacement and/or maintenance.
In an embodiment the load-bearing portion has a genus of zero, i.e. there are no closed curves in a cross-section which is oriented perpendicularly to the longitudinal direction of the longitudinal elements. As it is complicated to form structures showing closes curves in a sectional view by means of extrusion or roller-molding and therefore usually additional steps as e.g. fusing or welding are necessary for forming said closed structures, a structure comprising no closed curves considerably facilitates the production of the longitudinal elements.
In an embodiment the truss section comprises at least one roller track which is configured for supporting the at least one tread element while moving in the passenger line and/or while moving in a return line of the passenger conveyor, respectively. The at least one roller track in particular may be formed integrally with the load-bearing portion. Such a configuration facilitates the production of the truss even further, as a separate production and installation of the roller track may be avoided.
In an embodiment the at least one load-bearing portion is formed by a profiled bar made of a lightweight material, in particular aluminum, which results in a low weight of the truss facilitating its transportation and installation.
In an embodiment the at least one load-bearing portion is an extruded or roller molded element, which may be produced efficiently at low costs.
In an embodiment the at least one lateral connector comprises at least two lateral elements extending basically parallel to each other, in particular in different vertical positions, providing a high stability of the lateral connector and, in consequence, of the truss.
In an embodiment the at least one longitudinal element comprises receiving means and/or fixing means for mounting balustrade elements and/or the at least on outer cover element to the truss section. Providing such receiving and/or fixing means facilitates the installation of the passenger conveyor and in particular the installation of the balustrade elements and/or the at least on outer cover element considerably.
In an embodiment the truss section comprises magnets for fixing the balustrade element and/or the at least one cover element. Using magnets the elements may be attached securely but removable.
Additionally or alternatively at least one slot may be formed in the at least one longitudinal element, the slot being configured for fixing at least one balustrade element and/or at least one cover element by means of clipping.
In an embodiment the truss section comprises an inner skirt panel which is formed integrally with the at least one load-bearing portion. This avoids the need of providing and installing an additional skirt panel and thus facilitates the installation of the truss, as well.
In an embodiment the truss sections are configured to be connected with a plurality of other truss modules arranged adjacent to each other in the longitudinal direction such as to form a truss providing a modular truss, which may be transported and installed easily.
In an embodiment a passenger conveyor of the type conveying passengers by moving at least one tread element in a longitudinal direction along a passenger area between a first landing and a second landing is provided, the passenger conveyor comprising a truss made up with a plurality of truss modules arranged adjacent to each other in the longitudinal direction, each of the truss modules comprising at least two longitudinal elements extending basically parallel to each other in the longitudinal direction; and a least one lateral connector connecting between the at least two longitudinal elements, wherein at least one of the truss modules has a configuration according to an exemplary embodiment of the invention.
This provides a passenger conveyor with a flat frame, which can be produced and mounted easily with sufficiently high accuracy. In addition, it is possible to integrate much functionality in such truss construction.
In an embodiment the passenger conveyor is a moving walkway configured for transporting passengers basically horizontally and/or parallel to a basement of the passenger area.
Moving walkways, which are configured to extend basically horizontally and/or parallel to a basement of the passenger area, are well suited to comprise a truss according to an exemplary embodiment of the invention, as the truss is supported by the basement over its entire lengths, which prevents the truss from bending, and therefore the truss section may be produced from a very light material.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/067013 | 8/7/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2016/020006 | 2/11/2016 | WO | A |
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International Search Report and Written Opinion for application PCT/EP2014/067013, dated Apr. 2, 2015, 9 pages. |
Number | Date | Country | |
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20170233224 A1 | Aug 2017 | US |