An escalator or a moving walkway has two access regions, each with a comb plate, and a conveying region arranged between the access regions. The conveying region extends between the two comb plates of the access regions. At least one projection projects into the conveying region at at least one stationary part of the escalator or moving walkway. At least one monitoring sensor is arranged at least partly in the at least one projection.

A control system and a control method for controlling the start and stop of multiple passenger conveyors are provided. The control system includes a remote camera for capturing images of the corresponding external state of the passenger conveyor in real time; a remote controller for controlling and collecting the operation state of the passenger conveyor; a monitoring server connected with each remote camera and the remote controller through a data network. The monitoring server uses an artificial intelligence algorithm to analyze images captured by the remote camera to determine whether there are passengers on the passenger conveyor; when the monitoring server determines that there are passengers on the passenger conveyor, the passenger conveyor is grouped into a non-automatic start and stop group; when the monitoring server determines that there are no passengers on the passenger conveyor, the passenger conveyor is grouped into an automatic start and stop group.

A control system and a control method for controlling the start and stop of multiple passenger conveyors are provided. The control system includes a remote camera for capturing images of the corresponding external state of the passenger conveyor in real time; a remote controller for controlling and collecting the operation state of the passenger conveyor; a monitoring server connected with each remote camera and the remote controller through a data network. The monitoring server uses an artificial intelligence algorithm to analyze images captured by the remote camera to determine whether there are passengers on the passenger conveyor; when the monitoring server determines that there are passengers on the passenger conveyor, the passenger conveyor is grouped into a non-automatic start and stop group; when the monitoring server determines that there are no passengers on the passenger conveyor, the passenger conveyor is grouped into an automatic start and stop group.

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 passenger conveyor has a guardrail belt configured to run on a pair of right and left handrails in synchronization with footsteps; a camera provided at a platform of the handrail; and a control device configured to analyze an image obtained by photographing the platform with the camera, detect a passenger getting in from the platform, stop the footsteps or lower a running speed than a normal speed when detecting no passenger for a predetermined time, and move the running speed of the footsteps at the normal speed when detecting the passenger.

A passenger conveyor has a guardrail belt configured to run on a pair of right and left handrails in synchronization with footsteps; a camera provided at a platform of the handrail; and a control device configured to analyze an image obtained by photographing the platform with the camera, detect a passenger getting in from the platform, stop the footsteps or lower a running speed than a normal speed when detecting no passenger for a predetermined time, and move the running speed of the footsteps at the normal speed when detecting the passenger.

A control device adapted to be connected to a conveyor system having a drive motor, a motor control unit which provides a motor control signal to the drive motor and a motor speed sensor adapted to output a motor speed signal to the motor control unit. The control device comprises: a motor speed alteration unit adapted to intercept the motor control signal and to provide a modified motor control signal to the drive motor so as to cause the motor speed to increase or decrease by a speed change value from a first motor operating speed to a target motor operating speed; and a feedback unit adapted to intercept the motor speed signal and to provide a scaled motor speed signal to the motor control unit based on the intercepted motor speed signal, the scaled motor speed signal indicating to the motor control unit that the motor speed has not been increased or decreased from the first motor operating speed by the speed change value.

A system of hexagonal building units is provided herein. The building units may be configured in a honeycomb configuration. The building units may be configured for a variety of different uses, including any of the following: residential, commercial, entertainment, community, government, retail, parking, storage, and office space. An escalator or moving walkway is also provided herein. The escalator or moving walkway may contain multiple lanes operating at varying speeds and may have a circular, oval, curved or straight shape. The escalator or moving walkway may also include at least one lane having segments that operate at different speeds.

A plurality of steps are linked by endless step chains. Each of the steps includes: a step main body; first shafts that are disposed on the step main body; first step rollers that are disposed on the first shafts, and that are guided by the first guide rails; second shafts that are parallel to the first shafts; and second step rollers that are disposed on the second shafts, and that are guided by the second guide rails. The first shafts move along first pathways, and the second shafts move along second pathways. The second pathways are positioned inside the first pathways when viewed parallel to respective shaft axes of the first shafts. The step chains link each of the steps by joining the second shafts of each of the steps, and are disposed within a range of the step main body in an axial direction of the first shafts.

A plurality of steps are linked by endless step chains. Each of the steps includes: a step main body; first shafts that are disposed on the step main body; first step rollers that are disposed on the first shafts, and that are guided by the first guide rails; second shafts that are parallel to the first shafts; and second step rollers that are disposed on the second shafts, and that are guided by the second guide rails. The first shafts move along first pathways, and the second shafts move along second pathways. The second pathways are positioned inside the first pathways when viewed parallel to respective shaft axes of the first shafts. The step chains link each of the steps by joining the second shafts of each of the steps, and are disposed within a range of the step main body in an axial direction of the first shafts.