An elevator car is provided and includes a car frame which translates along a guide rail during ascents or descents, a safety disposed along the car frame to selectively engage with the guide rail to selectively permit vertical elevator car movement, an electronic safety actuator (ESA) and a control system. The ESA actuates the safety and includes an ESA body secured to the car frame with horizontal maneuverability and defining a groove through which the guide rail translates during the vertical elevator car movement, a magnetic guide operably disposed within the groove to exert magnetic force on the guide rail and a sensor disposed within the groove to sense horizontal distance between the guide rail and corresponding portions of the ESA body. The control system controls the magnetic guide to exert a magnetic force in accordance with reading of the sensor to maneuver the ESA body horizontally.

An elevator car of an elevator system includes a car body and a car frame supportive of the car body. The car frame includes two opposing side frames, each side frame formed from a plurality of side frame segments, including two upright members and one or more upright braces connecting the two upright members, adjacent side frame segments secured to each other via a joint. A method of installation of an elevator car of an elevator system includes positioning a first side frame segment of a plurality of side frame segments adjacent to second side frame segment of the plurality of side frame segments, and securing the first side frame segment to the second side frame segment via a splice joint thereby constructing a car frame of the elevator car. One or more car bodies are installed into the car frame.

A monitoring apparatus includes: a monitoring camera to monitor a situation of a specific area; a recorder to record monitoring information output from the monitoring camera; a video transmission device to transmit the monitoring information recorded in the recorder to the outside; a determination unit to calculate, based on the monitoring information output from the monitoring camera, the number of people present in the specific area and a degree of positional imbalance of the people; and an adjustment unit to adjust, based on the number of people and the degree of positional imbalance calculated by the determination unit, at least one of a recording density to be used when the recorder records the monitoring information or a communication frequency to be used when the video transmission device transmits the monitoring information.

A monitoring apparatus includes: a monitoring camera to monitor a situation of a specific area; a recorder to record monitoring information output from the monitoring camera; a video transmission device to transmit the monitoring information recorded in the recorder to the outside; a determination unit to calculate, based on the monitoring information output from the monitoring camera, the number of people present in the specific area and a degree of positional imbalance of the people; and an adjustment unit to adjust, based on the number of people and the degree of positional imbalance calculated by the determination unit, at least one of a recording density to be used when the recorder records the monitoring information or a communication frequency to be used when the video transmission device transmits the monitoring information.

A safety exit assembly for an elevator car and an elevator system. The safety exit assembly includes: a door panel, which is configured to open and close a safety exit of the elevator car, and which has an upper surface and a lower surface; a moving assembly, which includes a guide block provided on a lower surface of the door panel, and a guide rail which guides the door panel to move downward and translate through a cooperation with the guide block; a drive assembly, which drives the door panel to reciprocate along the guide rail; and a locking assembly, which includes an unlocking element provided on an upper surface of the door panel; wherein the unlocking element is electrically connected to the drive assembly, and an unlocking action of the unlocking element triggers the drive assembly to drive the door panel to move until the safety exit is opened.

A top extensible section and an operating method thereof, an elevator car assembly, and an elevator system. The top extensible section is installed above a top plate of the elevator car when in use. The top extensible section includes a top wall and a plurality of side walls, and has an unfolded state and a folded state; in the unfolded state, the top wall and the plurality of side walls of the top extensible section define an expansion space which communicates with an inner space of the elevator car to provide an additional top space; and in the folded state, the top wall of the top extensible section is lowered to be substantially flush with the top plate of the elevator car, and the plurality of side walls are folded to provide an operating space on the plurality of side walls.

The invention relates to a method for transporting construction material and/or equipment into and inside a building under construction, wherein the building under construction comprises plurality of vertically displaced floors, the method comprising providing a control system configured to automatically operate one or more transporting devices, including at least an elevator; providing a storage at the construction site of the building; and transporting into the storage at the construction site of the building under construction plurality of transport containers containing construction material and/or equipment; storing said transport containers in the storage; and delivering transport containers belonging to said plurality of transport containers from said storage to different destination floors, the delivering comprising obtaining an order to deliver a transport container, the order identifying the transport container to be delivered; and retrieving the transport container identified in the order from the storage; and moving said transport container at least horizontally to a container loading floor of the building under construction; and loading said transport container on the load receiving unit for being moved to its destination floor; and obtaining the destination floor information indicating the destination floor of said container; and moving the load receiving unit vertically in the elevator shaft to the destination floor of said transport container; and unloading said transport container from the load receiving unit to the destination floor of said transport container. The invention also relates to a method for constructing a building and an arrangement for transporting construction material, which implement the method for transporting construction material and/or equipment into and inside a building under construction.

Techniques are described for an elevator apparatus that includes a cabin apparatus and a hoistway apparatus. In an embodiment, the cabin head apparatus of the cabin apparatus extends parallel to a cross-section of the hoistway apparatus. The air pressure in the part of the hoistway is maintained to be different from the air pressure inside the cabin apparatus and may cause the cabin apparatus to ascend or to stay steady within the hoistway apparatus. The cabin head apparatus is partially load-bearing for the cabin apparatus and any load. In an embodiment, the air pressure difference is maintained by seal(s) that are peripherally coupled to the cabin apparatus, generating an airtight connection of the cabin apparatus with an inner periphery of a cross section of the hoistway apparatus. The seals substantially prevent the air in the top portion of the hoistway apparatus from entering the bottom portion and vice versa.

An elevator panel assembly comprises a detachable panel (4), for covering a front surface of an elevator car panel (2b), and a separation member (7). The separation member (7) comprises a head portion (7a) received against a back surface of the detachable panel (4). The detachable panel (4) is magnetically attachable to the elevator car panel (2b) and comprises a through hole (9) which is smaller than the head portion (7a) of the separation member (7) and arranged to sit directly over the head portion (7a). The separation member (7) is configured so that a tool inserted through the through hole (9) engages with the head portion to apply a mechanical force, causing the head portion (7a) to push against the back surface of the detachable panel (4).

An elevator air filtration system having an elevator car, an outdoor intake HEPA air filtration system that creates HEPA filtered air at a desired temperature, humidity and quantity of filtered outdoor air, and a retractable hose system that delivers the HEPA filtered air to the elevator car.