Abstract: A taping head for taping a wire harness with tape of a tape roll includes a base body and a rotatable tape dispenser with a mouth and mandrel for receiving the tape roll. The tape dispenser is configured to rotate the tape roll and is mounted to the base body by means of a quick-release coupling.

Abstract: An applicator (1) comprising: a body (2) defining a chamber (14) for storing an adhesive composition, and an outlet (16) for delivering the adhesive composition stored in the chamber (14), a piston (4) mobile in translation relative to the body (2), a drive element (6) mobile in rotation relative to the body (2), and configured to be releasably engaged with a guide (100, 200, 300) external to the applicator (1), wherein rotating the drive element (6) relative to the body (2) causes the piston (4) to translate relative to the body (2) so as to reduce a volume of the chamber (14) and force the adhesive composition out of the applicator (1) through the outlet (16).

Abstract: Applicator for depositing a layer of adhesive or sealant composition on a target site of a biological and/or prosthetic tissue, the applicator including a body having an application face intended to be positioned facing the biological and/or prosthetic tissue, and having a first outlet opening provided in the application face, the first outlet opening being shaped as a slot for allowing the adhesive or sealant composition to flow out of the applicator and to form the layer of adhesive or sealant composition, a second inlet opening provided in the application face, adjacent the first outlet opening, for allowing pollutants or undesirable elements to be removed from the target site while depositing the layer of adhesive or sealant composition, wherein the first outlet opening has a first section and the second inlet opening has a second section, the second section being greater than the first section.

Abstract: Solar cells use as substrates glass (23) coated with a transparent conductive layer (21), able to collect the electric power generated by the solar cell. This layer (21), normally a TCO, have limited conductivity, implying the use of current collector lines applied in a complex manner. The conductivity of the conductive layer (21) is increased by the application of a structure, in particular a grid, of thin conductive lines (22) inserted in grooves on the glass surface (23) or directly applied on this, followed by a TCO layer coating (21). This highly conductive grid (22) collects the electricity from the TCO layer (21) and directs it to the periphery of the cell. Both glass substrates are sealed by a process employing a precursor of glass surrounding the entire perimeter of the substrate. The glass precursor is heated to its melting point, by a laser, completely sealing the two substrates of the module.

Abstract: A monolithic device comprises a substrate. An array of sensing elements is coupled to the substrate, and each sensing element includes a magnetoresistive sensor. An analog electric drive generator is coupled to the substrate, and the electric drive generator produces a sensor-biasing signal that biases the magnetoresistive sensors of the array. An analog multiplexer is coupled to the substrate, and outputs of the array are coupled to inputs of the multiplexer. An analog signal conditioning circuit is coupled to the substrate, wherein at least one output of the multiplexer is coupled to at least one input of the signal conditioning circuit. The monolithic device is fabricated using both complementary metal-oxide semiconductor (i.e., CMOS) technology and thin film technology. For example, the electric drive generator, the multiplexer, and the signal conditioning circuit may be fabricated with CMOS technology, while the magnetoresistive sensors of the array are fabricated with thin film technology.

Abstract: Solar cells use as substrates glass (23) coated with a transparent conductive layer (21), able to collect the electric power generated by the solar cell. This layer (21), normally a TCO, have limited conductivity, implying the use of current collector lines applied in a complex manner. The conductivity of the conductive layer (21) is increased by the application of a structure, in particular a grid, of thin conductive lines (22) inserted in grooves on the glass surface (23) or directly applied on this, followed by a TCO layer coating (21). This highly conductive grid (22) collects the electricity from the TCO layer (21) and directs it to the periphery of the cell. Both glass substrates are sealed by a process employing a precursor of glass surrounding the entire perimeter of the substrate. The glass precursor is heated to its melting point, by a laser, completely sealing the two substrates of the module.

Abstract: A monolithic device comprises a substrate. An array of sensing elements is coupled to the substrate, and each sensing element includes a magnetoresistive sensor. An analog electric drive generator is coupled to the substrate, and the electric drive generator produces a sensor-biasing signal that biases the magnetoresistive sensors of the array. An analog multiplexer is coupled to the substrate, and outputs of the array are coupled to inputs of the multiplexer. An analog signal conditioning circuit is coupled to the substrate, wherein at least one output of the multiplexer is coupled to at least one input of the signal conditioning circuit. The monolithic device is fabricated using both complementary metal-oxide semiconductor (i.e., CMOS) technology and thin film technology. For example, the electric drive generator, the multiplexer, and the signal conditioning circuit may be fabricated with CMOS technology, while the magnetoresistive sensors of the array are fabricated with thin film technology.

Abstract: Solar cells use as substrates glass (23) coated with a transparent conductive layer (21), able to collect the electric power generated by the solar cell. This layer (21), normally a TCO, have limited conductivity, implying the use of current collector lines applied in a complex manner. The conductivity of the conductive layer (21) is increased by the application of a structure, in particular a grid, of thin conductive lines (22) inserted in grooves on the glass surface (23) or directly applied on this, followed by a TCO layer coating (21). This highly conductive grid (22) collects the electricity from the TCO layer (21) and directs it to the periphery of the cell. Both glass substrates are sealed by a process employing a precursor of glass surrounding the entire perimeter of the substrate. The glass precursor is heated to its melting point, by a laser, completely sealing the two substrates of the module.

Abstract: This invention refers to a new method for optimizing the composition of cell culture media. This new method comprises two main stages. In the first stage, a functional enviromics map is built through the joint screening of cell functions and medium factors by the execution of a specific cell culture protocol and exometabolome assays protocol. The functional enviromics map consists of a data array of intensity values of elementary cellular functions against medium factors. In the second stage, optimized cell culture medium formulations are developed that either enhance or repress target elementary cellular functions from columns of the functional enviromics map.

Abstract: Free-standing anchoring devices are provided for use with lines such as cords and ropes. The anchoring devices include various combinations of clam and boat cleats in unitary parts. One exemplary embodiment includes a boat cleat, a clam cleat, and a post proximate to the clam cleat. Another includes two clam cleats between two posts. A variation of this embodiment adds a boat cleat to the underside of the part.