A machine for processing containers is disclosed. The machine has a conveying device and at least one processing unit coupled to the conveying device to be carried along a processing path. The processing unit is provided with: a winding element, having an outer lateral surface designed to receive, and cause winding of, a portion of labelling material in a tubular configuration with opposite ends overlapped, and a top surface designed to support a bottom portion of a container to be processed; a sealing device including a sealing element having a functional surface adapted to cooperate with said portion wound about said winding body for performing a welding process of the overlapped ends, as the processing unit is carried along the path, to form a sleeve label; and a displacement device, operable to cause a relative displacement between the sleeve label and the container.

A lining drum which has a tubular body having open ends, an inlet for compressed air and an outlet for liner is disclosed. The lining drum has end pieces removably attached to the tubular body for closing the open ends of the tubular body, a rotatable shaft inside the tubular body and a crank for rotating the shaft. The end piece has a spring-loaded flange mounting, wherein bias of springs pushes the flange mounting towards the tubular body and a closed position of the flange mounting, and air pressure inside the lining drum pushes the flange mounting away from the tubular body and towards an open position of the flange mounting.

Microfluidic devices are provided for conducting fluid assays, for example biological assays, that have the ability to move fluids through multiple channels and pathways in a compact, efficient, and low cost manner. Discrete flow detection elements, preferably extremely short hollow flow elements, with length preferably less than 700 micron, preferably less than 500 micron, and internal diameter preferably of between about 50+/25 micron, are provided with capture agent, and are inserted into microfluidic channels by tweezer or vacuum pick-and-place motions at fixed positions in which they are efficiently exposed to fluids for conducting assays. Close-field electrostatic attraction is employed to define the position of the elements and enable ready withdrawal of the placing instruments. The microfluidic devices feature flow elements, channels, valves, and on-board pumps that are low cost to fabricate accurately, are minimally invasive to the fluid path and when implemented for the purpose, can produce multiplex assays on a single portable assay cartridge (chip) that have low coefficients of variation. Novel methods of construction, assembly and use of these features are presented, including co-valent bonding of selected regions of faces of surface-activatable bondable materials, such as PDMS to PDMS and PDMS to glass, while contiguous portions of one flexible sheet completes and seals flow channels, fixes the position of inserted analyte-detection elements in the channels, especially short hollow flow elements through which sample and reagent flow, and other portions form flexible valve membranes and diaphragms of pumps. A repeated make-and-break-contact manufacturing protocol prevents such bonding to interfere with moving the integral valve diaphragm portions from their valve seats defined by the opposed sheet member, which the flexible sheet material engages. Preparation of two subassemblies, each having a backing of relatively rigid material, followed by their assembly face-to-face in a permanent bond is shown. Hollow detection flow elements are shown fixed in channels, that provide by-pass flow paths of at least 50% of the flow capacity through the elements; in preferred implementations, as much as 100% or more. Metallized polyester film is shown to have numerous configurations and advantages in non-permanently bonded constructions. A method of preparing detection elements for an assay comprises batch coating detection elements, or hollow flow elements by mixing and picking and placing the elements in flow channels of a microfluidic device, capturing the flow elements by bonding two opposed layers while sealing the flow channels.

The present method relates to a manufacturing process of container labels with heat transfer technology, wherein alphanumeric codes are sequentially applied over, between and/or under the layers of specific inks and varnishes which protect said area of eventual friction and wear to which they are subject during transportation, handling and productive tests.

The present method relates to a manufacturing process of container labels with heat transfer technology, wherein alphanumeric codes are sequentially applied over, between and/or under the layers of specific inks and varnishes which protect said area of eventual friction and wear to which they are subject during transportation, handling and productive tests.

A pipe-liner system for lining a pipe and methods of use thereof. A continuous, eversible extended liner is formed from a pipe-liner attached to an extender-tube via a substantially leak-proof connection there between. Lengths of the extender-tube and the pipe-liner are each chosen so that the pipe-liner is caused to be accurately positioned within the pipe upon everting the extended liner into the pipe by a pressurized fluid. The pipe-liner is held against an interior surface of the pipe being lined by inserting an inflatable bladder into the extended liner and filling the bladder with pressurized fluid. When a resin in the pipe-liner has hardened, the bladder is removed and the extender-tube is detached from the pipe-liner.

A crown cap and closing device. The abstract of the disclosure is submitted herewith as required by 37 C.F.R. 1.72(b). As stated in 37 C.F.R. 1.72(b): A brief abstract of the technical disclosure in the specification must commence on a separate sheet, preferably following the claims, under the heading Abstract of the Disclosure. The purpose of the abstract is to enable the Patent and Trademark Office and the public generally to determine quickly from a cursory inspection the nature and gist of the technical disclosure. The abstract shall not be used for interpreting the scope of the claims. Therefore, any statements made relating to the abstract are not intended to limit the claims in any manner and should not be interpreted as limiting the claims in any manner.

A crown cap and closing device. The abstract of the disclosure is submitted herewith as required by 37 C.F.R. 1.72(b). As stated in 37 C.F.R. 1.72(b): A brief abstract of the technical disclosure in the specification must commence on a separate sheet, preferably following the claims, under the heading Abstract of the Disclosure. The purpose of the abstract is to enable the Patent and Trademark Office and the public generally to determine quickly from a cursory inspection the nature and gist of the technical disclosure. The abstract shall not be used for interpreting the scope of the claims. Therefore, any statements made relating to the abstract are not intended to limit the claims in any manner and should not be interpreted as limiting the claims in any manner.

A process for using a first labeling system that is a constituent of a block-form first container-handling includes, before switching between said labeling and non-labeling modes of a labeling unit thereof, providing a control signal to a control unit that controls the labeling machine, the control signal being indicative of a gap in container flow. the control signal occurs before the gap in container flow reaches a container inlet of the first labeling system.

A process for using a first labeling system that is a constituent of a block-form first container-handling includes, before switching between said labeling and non-labeling modes of a labeling unit thereof, providing a control signal to a control unit that controls the labeling machine, the control signal being indicative of a gap in container flow. the control signal occurs before the gap in container flow reaches a container inlet of the first labeling system.