A method for generating at least one installation operation for at least one on-going installation process of at an installation site includes obtaining site information of the at least one ongoing installation process at the installation site from a site control unit arranged at the installation site, obtaining site information gathered from one or more previous installation processes at one or more other installation sites from one or more external databases, defining at least one installation operation for the at least one ongoing installation process based on the site information of the at least one ongoing installation process and the site information gathered from the one or more previous installation processes, and generating at least one signal including an instruction to perform the at least one installation operation for the at least one ongoing installation process to the site control unit. A computing unit, an installation support system, and a computer program performing at least partly the method are disclosed.

A method for generating at least one installation operation for at least one on-going installation process of at an installation site includes obtaining site information of the at least one ongoing installation process at the installation site from a site control unit arranged at the installation site, obtaining site information gathered from one or more previous installation processes at one or more other installation sites from one or more external databases, defining at least one installation operation for the at least one ongoing installation process based on the site information of the at least one ongoing installation process and the site information gathered from the one or more previous installation processes, and generating at least one signal including an instruction to perform the at least one installation operation for the at least one ongoing installation process to the site control unit. A computing unit, an installation support system, and a computer program performing at least partly the method are disclosed.

A polygon compensation coupling system (30; 40; 60) comprises a first rotatable element (31; 41; 61), a second rotatable element (32; 42; 62a, 62b), and at least one linkage coupling the first rotatable element (31; 41; 61) with the second rotatable element (32; 42; 62a, 62b). The linkage comprises at least one first coupling element (34a; 44a; 64a) pivotably coupled to the first rotatable element (31; 41; 61) and at least one second coupling element (34b; 44b; 64b) pivotably coupled to the second rotatable element (32; 42; 62b). The first and second coupling elements (34a, 34b; 44a, 44b; 64a, 64b) are pivotably coupled to each other at a hinge point, the hinge point is configured to move along a compensation curve varying the coupling between the first rotatable element (34a; 44a; 64a) and the second rotatable element (32; 42; 62b).

A moving walkway pallet is composed of a series of plates of a plate belt arranged to circulate between two deflecting regions of the walkway. Each plate has a base body with a base surface to which a tread element can be attached. The plates are pivotally connected to each other along pivot axes (SA) extending across a width (B) of the plates. The pivot axis is located either in a plane containing the base surface or above the side of the plane, remote from the base body. The base body has a width base body cross-section having a geometric center of gravity arranged below the base surface.

A modernization method of an existing passenger transport system which is designed as an escalator or a moving walkway is disclosed. In the process, the modernization method can include generating a three-dimensional supporting framework model data set of the existing supporting framework, integrating the same into a digital double data set, producing the required components on the basis of the digital double data set, and installing said components into the existing framework.

In some embodiments, a stairway system may include a staircase having a plurality of steps and including a plurality of actuators. Each step may be coupled to one or more actuators and may be configured to move vertically in coordination with one or more other steps to provide a virtual platform to carry a user from a first elevation to a second elevation as the user moves. A control system may cause the virtual platform to move continuously along the staircase by progressively adjusting a sequential set of steps to a common elevation, such that a user can walk forward across a level platform formed from two or more steps while the virtual platform changes elevation carrying the user.

A variable speed moving walkway system has a plurality of walkway modules, each having at least one movable belt, wherein each of the plurality of walkway modules are positioned at least one of: immediately linearly adjacent or immediately laterally adjacent to another. The movable belt of each walkway module moves at a different speed from the belt of an immediately linearly adjacent and/or an immediately laterally adjacent walkway module. A transition between the walkway modules may include a stationary wedge and at least one rotational brush positioned in a gap formed between the stationary wedge and the at least one belt of each walkway module, and/or a transition T-bar positioned between the at least two walkway modules.

A variable speed moving walkway system has a plurality of walkway modules, each having at least one movable belt, wherein each of the plurality of walkway modules are positioned at least one of: immediately linearly adjacent or immediately laterally adjacent to another. The movable belt of each walkway module moves at a different speed from the belt of an immediately linearly adjacent and/or an immediately laterally adjacent walkway module. A transition between the walkway modules may include a stationary wedge and at least one rotational brush positioned in a gap formed between the stationary wedge and the at least one belt of each walkway module, and/or a transition T-bar positioned between the at least two walkway modules.

A moving walkway comprises at least one endless belt moving in a conveyance direction along a closed loop. The closed loop comprises a conveyance portion and a return portion extending between opposite turnaround portions. A plurality of pallets is drivingly coupled to the belt. Each of the pallets comprises at least one first roller and at least one second roller, the first and second rollers being spaced apart from each other in the conveyance direction. The moving walkway further comprises at least one first guide rail portion and at least one second guide rail portion. The at least one first guide rail portion is configured for guiding and supporting the first rollers in the conveyance portion and in the turnaround portions, and the at least one second guide rail portion is configured for guiding and supporting the second rollers in the conveyance portion.

The application relates to a method for modernizing an existing escalator or an existing moving walkway. The method can include removing all the electrical and mechanical parts from the existing framework of the existing escalator or of the existing moving walkway, the existing framework having two framework side parts and a base structure connecting said framework side parts, and the framework side parts being connected to each other by means of cross members disposed at a distance from the base structure; and replacing the existing cross members of the existing framework with new cross members, the two framework side parts of the existing framework being connected to each other in a mutually stabilising manner at least one point at a distance from the base structure of the framework, during replacement of the cross members.