A door operator for operating a door leaf of a door set includes a control unit, a drive unit and a user interface. The control unit detects that the door operator is in a first mode to receive a set of set-up parameters. In the first mode the control unit detects an external data storage, provides access to the external data storage, and automatically receives a set of set-up parameters from the external data storage. The door operator installs the set of set-up parameters in the control unit. The door operator controls the drive unit to operate the door leaf based on the set of set-up parameters.

The proposed solution in particular relates to a method for generating a haptic feedback on a vehicle part including an operating element that is accessible for a user for manual actuation, and in response to an electronically detected actuation of the operating element, a feedback haptically perceptible for the user is generated in that the vehicle part and the operating element is adjusted back and forth in a power-operated way or is put into vibration.

An example window operator assembly comprises a motor, communication circuitry, and processor circuitry. The communication circuitry being configured to provide a first type of wireless communications and a second type of wireless communication with a first wireless communication system and a second wireless communication system. And, the processor circuitry being configured to identify connection loss between the communication circuitry and the first wireless communication system, and in response, cause the communication circuitry to switch to the second wireless communication system and cause the window operator assembly to perform an action.

A garage door status monitoring and control system for a jackshaft operator may include a control module comprising a programmable platform configured to: receive a change-door-status command to change a position of a door; in response to the change-door-status command, generate and communicate a light or sound command to a wireless controller; delay a period of time after communicating the light or sound command to the wireless controller; and only after the delay, generate a door command corresponding to said change-door-status command to change the position of the door.

An example kiosk for accepting a portable electronic device from a client in exchange for payment, associated method and systems are described. The kiosk may include at least one display, an imaging chamber that includes at least one camera and one or more mirrors fixedly-arranged to capture images of a portable electronic device, at least one communication connection to a remote server and/or operator, and at least one computer. The computer may be configured to, in conjunction with the remote server and/or operator, capture one or more images of the portable electronic device in the imaging chamber while said at least one camera and said mirrors remain in unchanged positions. The computer may also transmit the captured images to the remote server and/or operator, receive an acceptance of the offered payment amount based upon an offered payment amount for the portable electronic device received from the remote server and/or operator, and provide for secure deposit of the portable device in the kiosk.

Disclosed herein is a system for facilitating management of a facility. Accordingly, the system may include a communication device configured for receiving at least one sensor data from at least one sensor corresponding to at least one door of the facility. Further, the communication device may be configured for transmitting at least one actuation data to at least one actuator corresponding to the at least one door. Further, the communication device may be configured for receiving at least one configuration data from a user device. Further, the system may include a processing device configured for analyzing the at least one sensor data to determine a current contextual data. Further, the processing device may be configured for comparing the current contextual data with the configuration data. Further, the processing device may be configured for generating the at least one actuation data based on the comparing.

A user interface unit for an automatic door drive comprises a display unit for outputting output information and a control element arrangement for capturing input information. The user interface unit, together with the door drive, is mountable in a first spatial position and in a second spatial position on a door that is drivable by the door drive. The control element arrangement comprises a first control element and a second control element, wherein the first control element is arranged in the first spatial position of the user interface unit on the same spatial side of the control element arrangement as the second control element in the second spatial position. The display unit is designed to display the displayed output information in the same spatial orientation in both the first spatial position and the second spatial position of the user interface unit. In addition, the user interface unit is designed to capture the same input information in the first spatial position with the first control element as with the second control element in the second spatial position.

A counterbalance system for an overhead door is disclosed. The system includes a torsion adjustment comprising a first portion and a second portion, the first and second portions being rotatable relative to one another in a first direction and not in a second direction opposite the first direction. The system also includes an anchor fixed to the first portion, a collar fixed to the second portion, the collar being selectively fixable to a shaft of the overhead door, and a spring coupled between the collar and the anchor. The spring supports at least a portion of the weight of the overhead door as the overhead door is raised and lowered. Rotating the first portion of the torsion calibration collar relative to the second portion of the torsion calibration collar increases torsion in the spring and therefore calibrates the spring to support a desired amount of the weight of the overhead door.

A smart delivery box and method for securing the delivery of packages. The method involves (a) ascertaining when a delivery vehicle has entered a geo-location associated with a delivery address of a package, (b) transmitting a delivery signal to a cloud computing service when the delivery vehicle is ascertained as entering the geo-location associated with the delivery address of the package, and configuring a door of a delivery box, located at the delivery address, to open for the delivery and receipt of the package, in response to an open command generated by the cloud computing service in reply to the delivery signal transmitted when the delivery vehicle entered the geo-location.

A method and apparatus relating to generating, by at least one motion sensor of a data acquisition device that is mounted to a door having a door closer, motion data indicative of motion as the door is moved from an open position to a closed position, generating, by at least one load cell of the data acquisition device, load data as the door is being opened, analyzing the motion data and load data by a central processing device, determining at least one adjustment to the door closer based on at least one of a duration the door was in each of a plurality of door movement zones, as determined using the motion data, and a force applied to open the door, as determined using the load data, and displaying at least one installation instruction corresponding with the at least one adjustment on a graphical user interface of the central processing device.