A lateral arm assembly and method of operation includes first and second articulating arms comprising first and second ends, the first ends of the articulating arms are mounted upon assembly to a support surface at separate lateral locations. The first ends each comprise separate pivoting mounting structures for forming a first pivotal connection with the first and second articulating arms. The lateral arm assembly also comprises a roller tube having spaced lateral ends supporting respective end brackets that provide a second pivotal connection to the second ends of the articulating arms. The roller tube supports a canopy coupled to a roller shaft, wherein one of the end brackets further supports a device that drives the roller shaft for furling and unfurling the canopy.

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.

An awning is disclosed. The awning comprises a case assembly comprising a housing, configured to be mounted to a dwelling, and a lead rail, a roller assembly mounted in the case assembly and including a roll tube rotatable relative to the case assembly, a lead rail assembly coupled to the lead rail, the lead rail assembly movable relative to the housing between an extended position and a retracted position, a canopy having a leading edge and a trailing edge, the leading edge being connected to the lead rail assembly and the trailing edge being connected to the roll tube, and a spring arm assembly connecting the housing of the case assembly to the lead rail, the spring arms including a first arm and a second arm pivotable relative to one another, the spring arm assembly allowing the lead rail assembly to move between the extended position and the retracted position.

A lateral arm assembly and method of operation includes first and second articulating arms comprising first and second ends, the first ends of the articulating arms are mounted upon assembly to a support surface at separate lateral locations. The first ends each comprise separate pivoting mounting structures for forming a first pivotal connection with the first and second articulating arms. The lateral arm assembly also comprises a roller tube having spaced lateral ends supporting respective end brackets that provide a second pivotal connection to the second ends of the articulating arms. The roller tube supports a canopy coupled to a roller shaft, wherein one of the end brackets further supports a device that drives the roller shaft for furling and unfurling the canopy.

An adjustable awning has no longitudinal linkage, which makes efficient use of space, can be assembled with a collapsible roof as a whole, increasing the function of the collapsible roof, and can be unfolded together with the collapsible roof, controlled by a mechanism inside the collapsible roof, and the control mechanism can be adjusted to select whether the awning is linked to the roof or not. The horizontal adjustable awning includes an internal control mechanism, a main transmission mechanism and a folding mechanism. The internal control mechanism includes a spring roller, a drive belt, a belt end block and a block snap; the main transmission mechanism includes a pulley, a filament rod, a shade cloth mechanism, a bearing housing, a rack and pinion mechanism and a gear housing; the folding mechanism includes two rotating pushers, two articulated sliders and a protective plate.

A roller awning, with lights, includes: a sheet; a shaft for winding/unwinding it; a structure supporting the shaft; a crosspiece for constraining an edge of the sheet; pairs of articulated arms for supporting and moving the crosspiece with respect to the support structure; and a plurality of LED lights fixed at least to the articulated arms. Articulation is obtained through disks fixed to cooperating ends of the arms, the disks being intercalated between them and being crossed by an articulation pin, forming an articulation joint with the discs. The pin being hollow and has its upper end opening into an upper cavity which is obtained in the upper disc of the joint and which also houses a printed circuit board. At least one LED is mounted thereon facing an axial cavity of the pin, within which, a light guide is housed opening at the lower end of the axial cavity.

An awning is disclosed. The awning comprises a case assembly comprising a housing, configured to be mounted to a dwelling, and a lead rail, a roller assembly mounted in the case assembly and including a roll tube rotatable relative to the case assembly, a lead rail assembly coupled to the lead rail, the lead rail assembly movable relative to the housing between an extended position and a retracted position, a canopy having a leading edge and a trailing edge, the leading edge being connected to the lead rail assembly and the trailing edge being connected to the roll tube, and a spring arm assembly connecting the housing of the case assembly to the lead rail, the spring arms including a first arm and a second arm pivotable relative to one another, the spring arm assembly allowing the lead rail assembly to move between the extended position and the retracted position.

A lateral arm assembly and method of operation includes a lateral arm awning assembly comprising a box cassette supporting a roll bar, A first end cap having a first end cap portion and a second end cap portion, the first end cap portion coupled to a first box end of the box cassette and the second end cap portion coupled to a first bar end of the roll bar, the second end cap portion removably couplable to the first end cap portion, and a second end cap coupled to a second box end of the box cassette, the first box end opposite the second box end, the second end cap spaced from the first end cap by the box cassette, the second end cap having a third end cap portion and a fourth end cap portion, the third end cap portion coupled to the second box end and the fourth end cap portion coupled to a second bar end of the roll bar, the first bar end opposite the second bar end, the fourth end cap portion removably couplable to the third end cap portion.

An awning arm assembly is provided that includes inner and outer arms. A joint is provided that has an axle, e.g., any structure about which rotation can be provided coupled with one of the inner arm and the outer arm and a hollow body disposed about the axle. The hollow-body is coupled with the other of the inner arm and the outer arm. The hollow body is coupled with the axle such that when the outer arm moves relative to the inner arm the angle between the hollow body and the axle (and thereby the inner and outer arms) is adjusted.

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.