A static mitigation end cap, for an architectural covering is provided. The covering may include a head rail having an end cap. The end cap may include housing extending along a longitudinal length of the head rail and defining a chamber. The end cap may include a printed circuit board received within the chamber and configured to control a motor assembly operatively connected to the at least one end cap. The end cap may include an actuation member slidably coupled with the end cap for selective engagement with the printed circuit board.

A battery-operated motorized roller shade that can be charged through an installation bracket. The roller shade comprises a roller tube, a motor and at least one battery disposed within the roller tube, and a motor head disposed at a terminal end of the roller tube having a motor head interface. The installation bracket comprises an installation bracket interface and an exterior wall comprising an installation bracket connector adapted to removably connect to and electrically interface with a power adapter. The motor head is adapted to removably attach to the installation bracket wherein the installation bracket provides electrical power to the at least one battery within the roller tube when the installation bracket is connected to the power adapter.

A battery-operated motorized roller shade that can be charged through an installation bracket. The roller shade comprises a roller tube, a motor and at least one battery disposed within the roller tube, and a motor head disposed at a terminal end of the roller tube having a motor head interface. The installation bracket comprises an installation bracket interface and an exterior wall comprising an installation bracket connector adapted to removably connect to and electrically interface with a power adapter. The motor head is adapted to removably attach to the installation bracket wherein the installation bracket provides electrical power to the at least one battery within the roller tube when the installation bracket is connected to the power adapter.

In one aspect, a mounting assembly for mounting an architectural covering to a support structure may include a bracket configured to be coupled to the support structure and a bracket adapter configured to be coupled to the bracket. In addition, the mounting assembly may include an end mount configured to be coupled to both an adjacent end of the covering and the bracket adapter. In accordance with aspects of the present subject matter, the various components of the mounting assembly may be configured or adapted to provide one or more advantages over known mounting assemblies.

A device for driving a closure component (9) in a building from a solar energy source (1), comprising at least one low-voltage alternating current electric motor (3) mechanically coupled to the closure component, a direct current electrical energy accumulator element (2), a solar energy source delivering a direct voltage. The electrical energy accumulator element has a nominal voltage lower than said effective electric voltage and greater than the direct voltage delivered by the solar energy source. A DC-DC charger (4) converts the output electrical energy from the solar energy source into electrical energy with an electric voltage for charging the electrical energy accumulator element. A DC-AC converter (5) converts the electrical energy with a direct output voltage of the electrical energy accumulator element into electrical energy with an alternating voltage that is able to power said electric motor.

A device for driving a closure component (9) in a building from a solar energy source (1), comprising at least one low-voltage alternating current electric motor (3) mechanically coupled to the closure component, a direct current electrical energy accumulator element (2), a solar energy source delivering a direct voltage. The electrical energy accumulator element has a nominal voltage lower than said effective electric voltage and greater than the direct voltage delivered by the solar energy source. A DC-DC charger (4) converts the output electrical energy from the solar energy source into electrical energy with an electric voltage for charging the electrical energy accumulator element. A DC-AC converter (5) converts the electrical energy with a direct output voltage of the electrical energy accumulator element into electrical energy with an alternating voltage that is able to power said electric motor.

Home-automation actuator (11) comprising a motor (16), a housing (17), a mechanical module for filtering vibrations (33; 33a; 33b; 33c), a module for absorbing vibrations (130) and a torque support (21), the mechanical module comprising a first end (35, 135) and a second end (39, 139), —the first end (35, 135) being connected to the housing (17), —the second end (39, 139) being connected to the torque support (21), the mechanical module providing the connection between the housing (17) and the torque support so as to rotate around a first axis (X) of the actuator, the absorption module translationally connecting the housing (17) to the torque support (21) allowing a rotational degree of freedom between the housing (17) and the torque support (21).

Home-automation actuator (11) comprising a motor (16), a housing (17), a mechanical module for filtering vibrations (33; 33a; 33b; 33c), a module for absorbing vibrations (130) and a torque support (21), the mechanical module comprising a first end (35, 135) and a second end (39, 139), —the first end (35, 135) being connected to the housing (17), —the second end (39, 139) being connected to the torque support (21), the mechanical module providing the connection between the housing (17) and the torque support so as to rotate around a first axis (X) of the actuator, the absorption module translationally connecting the housing (17) to the torque support (21) allowing a rotational degree of freedom between the housing (17) and the torque support (21).

An electromechanical actuator (11) for a closure, obscuring or solar protection installation (6) includes a motor assembly (16), including an electric motor (261) and a reduction gearbox (265), first and second (133) mechanical modules for filtering vibrations, and an output shaft (20), inserted at least partially in a casing (17), the electromechanical actuator (11) extends along a longitudinal axis (X), the first and the second mechanical modules (33, 133) being disposed on either side of the motor assembly (16) along the longitudinal axis (X) and each having a rigid transmission coupling, with at least a first degree of freedom perpendicularly to the longitudinal axis (X), allowing the motor assembly (16) to move along a plane perpendicular to the longitudinal axis (X), the electromechanical actuator also comprising at least one elastic module (130) that limits the movement of the motor assembly (16) along the perpendicular plane.

An electromechanical actuator (11) for a closure, obscuring or solar protection installation (6) includes a motor assembly (16), including an electric motor (261) and a reduction gearbox (265), first and second (133) mechanical modules for filtering vibrations, and an output shaft (20), inserted at least partially in a casing (17), the electromechanical actuator (11) extends along a longitudinal axis (X), the first and the second mechanical modules (33, 133) being disposed on either side of the motor assembly (16) along the longitudinal axis (X) and each having a rigid transmission coupling, with at least a first degree of freedom perpendicularly to the longitudinal axis (X), allowing the motor assembly (16) to move along a plane perpendicular to the longitudinal axis (X), the electromechanical actuator also comprising at least one elastic module (130) that limits the movement of the motor assembly (16) along the perpendicular plane.