A system and a method for a deployable awning that detects impending storms or other weather events and automatically deploys from a structure to extend out and cover vehicles to protect them from damage due to the storm or other weather event. In one embodiment, a method includes determining that an activating event has occurred. The activating event includes a storm or other weather event. Upon determining that the activating event has occurred, the method includes automatically deploying an awning from a stored configuration inside an awning housing to a deployed configuration such that the awning covers a coverage area of a ground surface adjacent to a location where the awning housing is mounted.

A method for configuring a motorized drive device for a solar protection home automation unit includes a step of triggering the rolling-up of a screen from an unrolled position, in which the screen is relaxed, towards a rolled-up position. This method further includes a step of measuring a magnitude of an electrical current passing through an electric motor using a measurement device, a step of determining a first maximum value of the measured magnitude, indicative of a position of breakage of the arms of a screening device, and a step of determining a lowered end-of-travel position of the screen. The lowered end-of-travel position of the screen corresponds to a measured-magnitude value lower than the first maximum value. The lowered end-of-travel position of the screen lies before the position of breakage of the arms of the screening device, in the direction of unrolling of the screen.

A method and device for preventing wind damage to a retractable awning comprises a processor that detects an oscillatory characteristic of movement signals received from an awning movement sensor, and generates an awning retraction signal if the oscillatory characteristic meets a predetermined retraction criterion. The sensor may comprise a gyroscopic sensor that detects angular movement of an awning portion and generates corresponding angular movement signals. The processor may detect predetermined angular movement signal events in the angular movement signals, calculate time elapsed between the events, and transmit a retraction signal when an angular movement signal characteristic relating to time elapsed between angular movement signal events meets at least one predetermined retraction criterion.

A method and device for halting the extension or retraction of a retractable awning comprises a sensor coupled to a processor that commands awning extension and retraction. The sensor senses a motion parameter, such as acceleration, which is associated with extension or retraction motion of a retractable awning and generates corresponding respective extension or retraction motion parameter signals. The processor calculates an acceleration rate of change and/or a tilt angle from the motion parameter signals received from the sensor, and halts awning extension or retraction by generating and sending a stop signal when the acceleration rate of change or tilt angle meets at least one predetermined criterion.

An awning adjustment device with variable speed and direction control serves to automatically open and close eclectic types of awnings by way of an elongated rod terminating at a hook. The hook detachably couples to an awning handle or crank mechanism. A motor powers the rod, so as to rotate the rod in variable speeds, directions, and durations. The rotational speed of the rod is either controlled by a user, or controlled by a rotation counter to variably increase or decrease the rotation of the rod, so as to prevent damaging the awning by rotating too fast. The control portion comprises a power on switch, a power off switch, a pause switch, a directional switch, and a speed switch. The motor operatively couples to at least one electrical power source through a power cord, or a battery to receive electrical power for operating the device.

An awning assembly and method of construction is disclosed herein. The awning assembly comprising a first main arm for coupling to a dwelling, a second main arm rotatably coupled to the first main arm at a first end and supportingly coupled to a roll bar at a second end, the roll bar coupled to a canopy, and a hard wire connection housed within the first main arm for coupling to a power source. The awning assembly further comprising a detachable attachment module coupled to the first end of the second main arm and functionally coupled to the hard wire connection, the detachable attachment module comprising a plurality of electrical components, the plurality of electrical components comprising at least one of a microphone, a heating element, an input/output port, an image capture device, a speaker, an illumination source, and a transceiver.

A protection device is provided, including a first fixed member, a second fixed member, a supporting member, a roller, an awning, an electromagnetic device, and a power supply unit. The supporting member connects to the first and second fixed members. The roller is movably disposed on the supporting member. The power supply unit provides electrical power to the electromagnetic device, so that the electromagnetic device attracts the roller, and the awning remains in a received state. When the power supply unit stops providing electrical power to the electromagnetic device, the roller moves along the supporting member, and the awning is expanded to cover the equipment.

A boat lift with hydraulically or mechanically actuated arms which self-installs a fitted three-dimensional boat cover on a powerboat. The control logic of the system allows for cover operation only when the lift is raised. A spring-tensioned roller keeps the cover tight and self-rolls the cover on the roller when the actuated arms are pivoted forward. The roller is hidden behind the boat in cover-on position. A slip clutch prevents the torsion spring from being over tightened. The forward position of the roller is adjusted by adjusting the hydraulic cylinder length. The rearward position of the roller is adjusted by limiting the retracted position of the hydraulic cylinder. A non-hydraulic embodiment actuates the cover when the lift is operated.

In an embodiment, a retractable awning comprises a slotted track; a webbing disposed in the slotted track; a cover attached to the webbing and disposed on the slotted track; a first roller disposed at a first end of the slotted track and connected to a first end of the webbing; a second roller disposed at a second opposite end of the slotted track and connected to a second end of the webbing; and a bracket, the bracket disposed over the first roller and comprising a guide roller which contacts the cover when the retractable awing is in a deployed position between the first roller and the first end of the slotted track.

Various embodiments of an awning roller assembly is provided. The structure provides an awning roller tube having a first end and a second end with a powered groove extending between the ends, in full or in part. The powered groove includes a plurality of tracks having at least one electrical conductor in each track. An accessory base is provided for connection with a plurality of powered accessories, including but not limited to, lights, fans or audio-video equipment. The accessory base provides electrical connection between the powered groove and the accessory to provide improved function in the outdoor living space beneath and around the awning.