A form fill seal apparatus for forming and filling a plurality of bags with a product having a tube formation assembly forming a tubular film, a bag forming assembly configured to form transverse seals and to cut the tubular film to form bags. A product delivery system is provided to deliver product from a positive displacement pump to a product delivery tube. A control system is structurally configured to direct the positive displacement pump to operate in two different modes, a first, continuous operating mode and a second, dosing operating mode. A method of filling is likewise disclosed.

The present disclosure relates to an oral pouched snuff product comprising a filling material and a saliva-permeable pouch enclosing the filling material, the oral pouched snuff product having a longitudinal direction and a transverse direction perpendicular to said longitudinal direction, the saliva-permeable pouch comprising a first elongated seal and a second elongated seal, each of said first and second elongated seals having a seal length extending along the transverse direction of the product and a seal width extending along the longitudinal direction of the product, wherein the seal width of said at least one elongated seal being equal to or less than 2 mm, such as within the range of from 0.1 mm to 2 mm or from 0.1 mm to 1 mm or from 0.1 mm to 0.5 mm. There is also provided a container having a base and a detachable lid together providing an interior container space in which a plurality of these oral pouched snuff products is contained.

A packaging unit for producing sealed packages from a tube fed along a first direction and comprising one pair of jaws, which grip the tube along transverse sections, defining respective second directions crosswise to the first direction; sealing means, which seal transverse sections to form sealed packages; separating means for separating packages from the tube along transverse sections and comprising one knife movably supported by one jaw; driving means moving the knife with respect to the jaw along a plane crosswise to the first direction and between a resting position, in which a cutting edge of the knife is spaced from the tube and is aligned with the respective second direction defined by the transverse section to be cut, and an operating position, in which the knife has completely cut the tube at the transverse section; driving means move the cutting edge obliquely with respect to the second direction when said driving means move the knife from the resting position to the operating position; cutting edge contacts the transverse section along a cutting surface parallel to the second direction and increasing as the knife moves from the resting position to the operating position.

A lighting device for a vehicle, comprising a housing, an illuminant arranged in the housing and comprising a light panel for the passage of light generable by the illuminant, wherein a frame is provided, which is molded onto the light panel at least on the edge side in an at least sectionally circumferential fashion using a plastic injection molding process, and wherein the frame is joined to a connection portion of the housing by means of a plastic welded seam. The invention further relates to a method for producing a lighting device.

Methods and materials to fabricate laminated devices are disclosed, particularly the laminates where the interlayer is deposited by 3d printing (or also called additive manufacturing process). In particular, emphasis is placed on the fabrication of electrooptical devices, including electrochromic, thermochromic and liquid crystal devices. In the electrochromic devices at least the electrolytic interlayer or optionally some of the other layers are deposited by this process, and for the other two the interlayer contains thermochromic and the liquid crystalline material respectively. In one embodiment printing is used to form both an interlayer and a sealant located at the perimeter of the interlayer. Laminated glass and plastic objects using this invention have many applications including their use in windows for building and transportation.

Methods and materials to fabricate laminated devices are disclosed, particularly the laminates where the interlayer is deposited by 3d printing (or also called additive manufacturing process). In particular, emphasis is placed on the fabrication of electrooptical devices, including electrochromic, thermochromic and liquid crystal devices. In the electrochromic devices at least the electrolytic interlayer or optionally some of the other layers are deposited by this process, and for the other two the interlayer contains thermochromic and the liquid crystalline material respectively. In one embodiment printing is used to form both an interlayer and a sealant located at the perimeter of the interlayer. Laminated glass and plastic objects using this invention have many applications including their use in windows for building and transportation.

Intravascular inflatable medical devices and their methods of manufacture and use. The inflatable medical devices may include a conduit that includes an inflatable wall, with the inflatable wall defining a lumen therein. The inflatable wall may include an outer layer and an inner layer, and optionally an intermediate layer between the inner and layers. Intermediate layers may include one or more couplings between the outer and inner layers, and may include radial connectors extending between the outer layer and the inner layer.

A cryogenic storage tank including a first metallic end piece having a first structured connection area on its outer surface, a second metallic end piece having a second structured connection area on its outer surface, a hollow body extending between the first structured connection area and the second structured area. The hollow body is formed of a fiber reinforced polymer-based composite, a first metallic clamp having a third structured connection area and a second metallic clamp having a fourth structured connection area. The hollow body is arranged between and in intimate contact with the first structured connection area of the first metallic end piece and with the third structured connection area of the first metallic clamp and is arranged between and in intimate contact with the second structured connection area of the second metallic end piece and with the fourth structured connection area of the second metallic clamp.

A polarizable compact is provided with high productivity, which makes a polarizing sheet resistant to the occurrence of color unevenness and voids and also resistant to the occurrence of variations in polarization degree accompanying thermal shrinkage and the like of a protective layer (protective film). A polarizable compact is used for glasses, and a method of manufacturing the same. An injection-molded portion made of a transparent plastic material is thermally bonded to the concave surface side of a polarizing sheet having a predetermined curvature radius. The polarizing sheet has a polarizer layer held between first and second protective layers respectively serving as a convex surface side and a concave surface side. Both the first and second protective layers are formed from transparent films by a casting method with retardation (Re)≤50 nm. The transparent films for the first and second protective layers are respectively formed from an acylcellulose-based film and a polyamide-based film.

A polarizable compact is provided with high productivity, which makes a polarizing sheet resistant to the occurrence of color unevenness and voids and also resistant to the occurrence of variations in polarization degree accompanying thermal shrinkage and the like of a protective layer (protective film). A polarizable compact is used for glasses, and a method of manufacturing the same. An injection-molded portion made of a transparent plastic material is thermally bonded to the concave surface side of a polarizing sheet having a predetermined curvature radius. The polarizing sheet has a polarizer layer held between first and second protective layers respectively serving as a convex surface side and a concave surface side. Both the first and second protective layers are formed from transparent films by a casting method with retardation (Re)≤50 nm. The transparent films for the first and second protective layers are respectively formed from an acylcellulose-based film and a polyamide-based film.