A door system with a deceleration mechanism may be adapted to control an opening of a door module that separates compartments of an aircraft and includes a door panel and a door frame. During the opening of the door module, the door panel performs a rotational movement 389 above a floor structure of the aircraft. The deceleration mechanism is operable in a normal operation mode and a deceleration mode and comprises a hinge, a wedge-shaped component that is rotatably attached to the hinge, and an activation device. The activation device is coupled to the wedge-shaped component and switches the deceleration mechanism from operating in the normal operation mode to operating in the deceleration mode when a difference in pressure between the compartments exceeds a predetermined threshold.

A clip release system for a vehicle door includes: a clip including a stem and a clamping portion configured to hold a window; a lock including at least one guide extending from the first axial surface to the second axial surface, the lock being disposed in the stem of the clip; a bolt that rotates between a first position and a second position, is inserted through the hole of the lock in an insertion direction, and biased to move out of the lock in a direction opposite the insertion direction, the bolt including a head at a first end of the bolt, a shaft extending to a second end of the bolt, and at least one locking tab disposed on a surface of the shaft and configured to pass through the at least one guide.

A clip release system for a vehicle door includes: a clip including a stem and a clamping portion configured to hold a window; a lock including at least one guide extending from the first axial surface to the second axial surface, the lock being disposed in the stem of the clip; a bolt that rotates between a first position and a second position, is inserted through the hole of the lock in an insertion direction, and biased to move out of the lock in a direction opposite the insertion direction, the bolt including a head at a first end of the bolt, a shaft extending to a second end of the bolt, and at least one locking tab disposed on a surface of the shaft and configured to pass through the at least one guide.

A door operator includes: a controller; a sensor operatively connected to the controller, the sensor configured to detect an undesirable condition and communicate a signal to the controller when the undesirable condition is detected; and a door operatively connected to the controller, the controller is configured to cause the door to move from a closed position to a non-closed position when the controller receives the signal. In another aspect, the disclosure describes a method of operating a door. The method includes: detecting an undesirable condition with a sensor; communicating with a controller when the undesirable condition is detected by the sensor; and moving the door from a closed position to a non-closed position when the controller receives the signal.

A door operator includes: a controller; a sensor operatively connected to the controller, the sensor configured to detect an undesirable condition and communicate a signal to the controller when the undesirable condition is detected; and a door operatively connected to the controller, the controller is configured to cause the door to move from a closed position to a non-closed position when the controller receives the signal. In another aspect, the disclosure describes a method of operating a door. The method includes: detecting an undesirable condition with a sensor; communicating with a controller when the undesirable condition is detected by the sensor; and moving the door from a closed position to a non-closed position when the controller receives the signal.

The present invention relates to a fire swing door operator system (100) comprising at least one swing door operator (1), a wall (200), a door frame (300), and at least one swing door leaf (400), wherein the door frame (300) is mounted in an opening in the wall, the at least one swing door leaf (400) is hingedly connected to the door frame (300), the wall (200) comprise a first wall section (201) at one side of the door frame (300) and a second wall section (202) at the other side of the door frame (300), the swing door operator (1) is mounted to the first wall section (201) and connected to the at least one swing door leaf (400) and arranged to move the at least one swing door leaf (400) between a closed and an open position.

The present invention relates to a fire swing door operator system (100) comprising at least one swing door operator (1), a wall (200), a door frame (300), and at least one swing door leaf (400), wherein the door frame (300) is mounted in an opening in the wall, the at least one swing door leaf (400) is hingedly connected to the door frame (300), the wall (200) comprise a first wall section (201) at one side of the door frame (300) and a second wall section (202) at the other side of the door frame (300), the swing door operator (1) is mounted to the first wall section (201) and connected to the at least one swing door leaf (400) and arranged to move the at least one swing door leaf (400) between a closed and an open position.

A system for controlling one or more motorized windows. The motorized windows each have a processor, a network device and wireless transmitters enabling connection via a network. The network is controlled by one or more mobile devices which receive user input. The mobile devices wirelessly connect to a local area network (LAN) via a hub. One or more hubs are connected via the LAN. The motorized windows are networked via a personal area network (PAN). The hubs convert the LAN protocol to the PAN protocol. Sensors send sensor data along with real time weather data to the processor. The processor uses this sensor data to update charts and schedules in memory, then sends commands to the controller based on these updated charts and schedules according to user defined and factory set parameters. The system includes both local and cloud-based control.

A system for controlling one or more motorized windows. The motorized windows each have a processor, a network device and wireless transmitters enabling connection via a network. The network is controlled by one or more mobile devices which receive user input. The mobile devices wirelessly connect to a local area network (LAN) via a hub. One or more hubs are connected via the LAN. The motorized windows are networked via a personal area network (PAN). The hubs convert the LAN protocol to the PAN protocol. Sensors send sensor data along with real time weather data to the processor. The processor uses this sensor data to update charts and schedules in memory, then sends commands to the controller based on these updated charts and schedules according to user defined and factory set parameters. The system includes both local and cloud-based control.

An intelligent door control system and method is provided. The intelligent door control method includes the following steps: receiving an ambient temperature inside and outside a door body of the intelligent door through a first sensor and a second sensor which are respectively installed inside and outside the door body of the intelligent door; comparing the ambient temperature inside the door with a preset first temperature threshold, and comparing the ambient temperature outside the door with a preset second temperature threshold; automatically controlling the intelligent door according to whether there is a living body inside the intelligent door, and comparison results of the ambient temperatures inside and outside the door body with the first and second temperature thresholds respectively.