The system includes a series of operable louvers mounted on a four-sided frame and connected on each side to the operating mechanism that allows for easy opening and closing of the louvers. Every part of the system that is exposing to the exterior of the building is separated from the interior part of the system by a low heat conductivity material as a thermal barrier. Each operable louver includes a four-sided main frame, at least one pane of glass and a coupling mechanism on each side that connects to the operating mechanism. The main frame acts as the thermal break as well as a system that absorbs the energy created when an outside object impacts the window from the outside. The system incorporates sealing devices between all moving parts to eliminate water and air infiltration. The operating system allows for easy opening and closing of the window by rotating each louver with the crank mechanism assisted by springs.

The present disclosure relates to methods of enriching root powder products, for example beetroot powder. In particular, the methods relates to increasing the nitrate content and/or reducing the sugar content of the root powder product. The disclosure also relates to root powder products with increased with at least 3% nitrate.

The invention relates to a slat (1) or a slatted roof (20) or a slatted window, comprising a light-permeable sheet-like covering element (2) having a longitudinal extent and width (b), wherein the width (b) is less than the longitudinal extent, and having an axis of rotation (5) which runs along the longitudinal extent of the slat (1) in order to pivot the slat (1) between a closed position and an open position. In order to allow a particularly flexible variation of the incoming sunlight entering a room (22) situated below the slatted roof (20) and in order to be able to set the desired temperature, climate control and brightness conditions in the room in a targeted manner, it is proposed that the slat (1) has at least one light-impermeable sheet-like shading element (6) having a longitudinal extent and a width (h), in which the shading element extends with the longitudinal extent thereof along the longitudinal extent of the covering element (2), that it is arranged with a first longitudinal side (6a) on the covering element (2) and projects with a second longitudinal side (6b), opposite the first longitudinal side (6a), from the covering element (2), wherein the at least one shading element (6) is arranged in the areal extent thereof at an angle () to the areal extent of the covering element (2). (FIG. 10).

The invention relates to a slat (1) or a slatted roof (20) or a slatted window, comprising a light-permeable sheet-like covering element (2) having a longitudinal extent and width (b), wherein the width (b) is less than the longitudinal extent, and having an axis of rotation (5) which runs along the longitudinal extent of the slat (1) in order to pivot the slat (1) between a closed position and an open position. In order to allow a particularly flexible variation of the incoming sunlight entering a room (22) situated below the slatted roof (20) and in order to be able to set the desired temperature, climate control and brightness conditions in the room in a targeted manner, it is proposed that the slat (1) has at least one light-impermeable sheet-like shading element (6) having a longitudinal extent and a width (h), in which the shading element extends with the longitudinal extent thereof along the longitudinal extent of the covering element (2), that it is arranged with a first longitudinal side (6a) on the covering element (2) and projects with a second longitudinal side (6b), opposite the first longitudinal side (6a), from the covering element (2), wherein the at least one shading element (6) is arranged in the areal extent thereof at an angle () to the areal extent of the covering element (2). (FIG. 10).

Embodiments of a panel-less shutter assembly comprise a series of parallel louvers mounted within a closed rectangular rail frame. Spring-loaded guides may be mounted between the rail frame and the window frame to self-center the assembly within the opening of the window frame. Carriers mounted on the ends of the louvers glide up and down within channels of the side rails to allow raising and lowering of the louvers. Spring-loaded channel slides may be coupled to the carriers. The channel slides have tabs that extend through slots in the side rails to maintain the positions of the louvers relative to the side rails. The tabs have a diagonal surface that engages the top edge of the slot to disengage the tab from the slot when a user raises the louvers. A method of using a panel-less shutter assembly is also disclosed.

The present disclosure relates to methods of enriching root powder products, for example beetroot powder. In particular, the methods relates to increasing the nitrate content and/or reducing the sugar content of the root powder product. The disclosure also relates to root powder products with increased with at least 3% nitrate.

A slat roof (1) comprising beams (2), a plurality of slats (3) arranged parallel to one another therebetween and slat shafts (4) by means of which the slats (3) are rotatably fixed to the respective beams (2), wherein at least one slat shaft (4) is hollow and wherein the slat roof (1) comprises at least one corresponding tensioning cable (5) which is inserted through said hollow slat shaft (4) and the ends of which are fixed to the respective beams (2). In addition, a method for adapting a slat roof.

A slat for use in a window frame having opposing walls may include a wing portion structured to block light, the wing portion having a first end in a longitudinal direction and a second end opposite to the first end; and a first pressure contact part provided at the first end and a second pressure contact portion provided at the second end, the first pressure contact part and the second pressure contact part being structured to press the wing portion against the opposing walls of the window frame to thereby hold the wing portion in place.

A venetian blind includes a frame unit, a slat unit, a transmission unit, and an operating unit. The slat unit includes multiple drive axles and a plurality of slats each connected co-rotatably to the drive axles. The transmission unit includes two transmission rollers, a plurality of constant-force coil springs that are linked together and that are coupled to the drive axles, and a belt that cooperates with the constant-force coil springs to form a loop trained on the transmission rollers. The operating unit includes an inner control member connected to the belt, and an outer control member operable to drive the inner control member to move so as to drive rotation of the drive axles via the constant-force coil springs to rotate the slats.

A venetian blind includes a frame unit, a slat unit, a transmission unit, and an operating unit. The slat unit includes multiple drive axles and a plurality of slats each connected co-rotatably to the drive axles. The transmission unit includes two transmission rollers, a plurality of constant-force coil springs that are linked together and that are coupled to the drive axles, and a belt that cooperates with the constant-force coil springs to form a loop trained on the transmission rollers. The operating unit includes an inner control member connected to the belt, and an outer control member operable to drive the inner control member to move so as to drive rotation of the drive axles via the constant-force coil springs to rotate the slats.