This invention relates to an improved mounting assembly for the balustrade, and decking and skirt panel of a passenger conveyor.
Escalators, moving walkways, and other passenger conveyors commonly include a series of tread plates, a frame, a drive, a step chain and a pair of balustrade assemblies. In escalators, for example, the frame comprises a truss on both the left and right hand sides of the frame between which the steps are positioned. Each truss has two end sections forming landings, connected by an inclined midsection. Matching pairs of roller tracks are attached on the inside of each truss, i.e. the side of the truss facing the other truss. The upper landing usually houses the escalator drive between the trusses. The drive powers a pair of step chain sprockets, which in turn impart motion to the step chain to move the tread plates. The tread plates travel a closed loop as they are guided along the roller tracks running from one elevation to the other elevation, and back. For safety reasons, passenger handrails are provided, traveling in the same direction and speed as the tread plates. A balustrade assembly supports and guides a handrail on each side of the tread plates.
Each balustrade assembly includes a balustrade panel that extends up from a base to support the handrail. Externally, the base consists of outer and inner balustrade decking and a skirt panel. The outer decking encloses the mechanics on the side of the balustrade panel opposite the moving tread plates. The inner decking encloses the mechanics adjacent the moving tread plates. The inner decking also provides a transition section between the balustrade panel and the skirt panel. Internally, the base consists of a support structure that is attached to the frame and supports the balustrade panel and handrails.
The skirt panel lies in close proximity to, but out of contact with, the moving tread plates. The skirt panel is generally positioned in close proximity to the tread plates to decrease the likelihood that objects or body parts of passengers are pulled into and trapped in the gap between the stationary skirt panel and the moving tread plates. Also, to prevent pinching between the panel and the tread plates, the skirt panel is often a rigid panel. Skirt panels are typically assembled from structural members and sheet metal. Generally speaking, the sheet metal provides the surface in close proximity to the tread plates and the structural members add rigidity to the fabrication. The hardware necessary to locate and hold the skirt panel relative to the tread plates may depend upon and be incorporated into the structural members.
There is a continuing need to decrease material cost and complexity of balustrade assemblies without sacrificing structural requirements and to reduce the time and cost of installing and repairing such assemblies.
A passenger conveyor balustrade assembly includes a balustrade support, a decking panel, a skirt panel, and first and second flexible bands. The balustrade support is configured to be fixed to a frame of the passenger conveyor. The first flexible band connects a first side of the decking panel to the balustrade support such that the decking panel generally protrudes away from a balustrade panel projecting up from the balustrade support. The second flexible band connects a second side of the decking panel to a first side of the skirt panel and the second side of the decking panel and the first side of the skirt panel to the balustrade support such that the skirt panel is offset from and generally parallel to the balustrade panel.
Balustrade assembly 22 includes handrail 36, balustrade panel 38, decking 40, and skirt panel 42. Balustrade panels 38 protrude up through decking 40 on either side of steps 18 to support handrails 36. Decking 40 covers the underlying support structure of balustrade assemblies 22 (discussed in more detail below). Skirt panel 42 is connected on the inner side of balustrade panel 38 (i.e. side facing steps 18) to decking 40 and is arranged in close proximity to, but out of contact with, moving steps 18. On each side of steps 18, handrail 36 is driven either by escalator drive 14 or by an independent handrail drive (not shown) in the same direction and speed as steps 18. Handrails 36 enable the passenger(s) (not shown) to steady themselves while riding the escalator.
Balustrade assemblies of passenger conveyors include structural support for the balustrade panel and handrails. The rigid supports are connected to the conveyor frame and are commonly in the form of extruded aluminum channels. While the aluminum channels provide good weight to strength characteristics and multiple functions in a single shape (e.g. multiple channels for mounting various components in addition to balustrade panel), they also are expensive due to material costs and the complexity of manufacturing the relatively complex geometry. Embodiments of the present invention therefore provide a balustrade support that reduces material and manufacturing costs and that is also adjustable to vary the height of the balustrade panel and handrails in the passenger conveyor.
Handrail guides 58 are also connected to anchor brackets 52. Guides 58 may be formed from, for example, extruded high density polyethylene, and may each be several inches long. Thus, each of anchor brackets 52 will support one handrail guide 58. Guide 58 is formed with slot 58a to which second fastener 66 fastens anchor bracket 52. Guide 58 is itself generally T-shaped so as to telescopingly receive handrail 36.
Balustrade support 54 forms what has been previously referred to as a “balustrade support channel.” Balustrade support channels have commonly been relatively complex and expensive extruded aluminum members, which in a typical escalator assembly will be about thirteen feet long in the incline, and which provide full support for the glass balustrade panels 38. Balustrade support 54, on the other hand, includes support plates 60 and “L” bracket 62, both of which are relatively simple and inexpensive components. Support plates 60 may be, for example, aluminum plates adapted for the particular passenger conveyor in which they are installed. Plates 60 are relatively small and simple in design and therefore reduce material and manufacturing costs over more complex designs such as prior balustrade support channels. “L” bracket 62 may be an off-the-shelf steel angle iron that is cut and shaped to fit the intended application. “L” bracket 62 adds rigidity to balustrade support 54 without the complexity and cost of prior designs, including long extruded support channels.
In addition to simplifying the design and reducing the cost of supporting handrail 36 and balustrade panel 38, balustrade support 54 is also configured to adjust the height of panel 38 in escalator 10 (shown in
During operation of escalators, fasteners that are used to connect components may loosen due to vibrations generated by any number of systemic conditions. In the event such fasteners are located on the exterior of the escalator in proximity to passengers, there is a persistent safety risk that a loosened fastener may hitch or otherwise contact the passenger's clothing or body. Therefore, in order to increase passenger safety, improve aesthetics, and reduce installation complexity and costs, embodiments of the present invention provide balustrade assemblies in which the balustrade decking panel and skirt panel are attached to one another and to the balustrade support structure without fasteners.
In
Skirt panels in escalators and other passenger conveyors are attached to the frame of the escalator, and therefore remain fixed as the steps move therebetween. The gap between the steps and the skirt panel is kept very small to decrease the likelihood that objects are pulled into and trapped in this gap. Designing escalators with a very small gap between steps and skirt panels significantly increases installation and maintenance costs and complexity because the skirt panel needs to be positioned precisely with respect to the escalator steps at every installation. Embodiments of the present invention therefore provide a device that varies the position of the skirt panel relative to the moving steps in two directions by pushing against stationary components that are a part of, or otherwise connected to, the escalator frame.
Bracket 82 is adjustably connected to plate 80 extending away from steps 18 generally perpendicular to skirt panel 42. Bracket 82 includes first, second, third, and fourth walls 82a, 82b, 82c, 82d. First wall 82a extends away from steps 18 generally perpendicular to skirt panel 42. Second wall 82b (shown in
Post 84 is adjustably connected to plate 80 extending down from the bottom of plate 80 generally parallel to skirt panel 42. In
Embodiments of the present invention provide improved balustrade assemblies with several features including a balustrade support, a decking and skirt panel assembly, and a skirt panel positioning device. The balustrade support employs less material and less complex components than prior extruded aluminum balustrade support channels. The balustrade support is also adjustable to vary the height of a balustrade panel and handrail in a passenger conveyor. The balustrade decking and skirt panel assembly connects the decking and the skirt panel to one another and to the frame of a balustrade support structure. The skirt panel positioning device varies the position of a skirt panel relative to moving steps in two directions by pushing against stationary components that are a part of, or otherwise connected to, a passenger conveyor frame.
Although the present invention has been described with reference to preferred embodiments, workers skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the invention.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB09/05291 | 4/20/2009 | WO | 00 | 1/26/2012 |