Van De Vyver
Bart Van De Vyver, Geneva CH
Patent application number | Description | Published |
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20090039000 | DOSIMETER FOR PROGRAMMABLE MICROSCALE MANIPULATION OF FLUIDS - The present invention is directed generally to devices and methods for controlling fluid flow in meso-scale fluidic components in a programmable manner. Specifically, the present invention is directed to an apparatus and method for placing two microfluidic components in fluid communication at an arbitrary position and time, both of which are externally defined. The inventive apparatus uses electromagnetic radiation to perforate a material layer having selected adsorptive properties. The perforation of the material layer allows the fluid communication between microfluidic components allowing volumetric quantitation of fluids. Using the perforation of the material functionality such as metering and multiplexing are achieved on a microscale. This functionality is achieved through basic operations, like dosimeters filling, dosimeters purging, dosimeters extraction, dosimeters ventilation and channels routing. Accordingly, these operations are performed in microfluidic platforms and are characterized extensively, allowing the realization of complex assays in a miniaturized format, where dilutions of proteins and assay readout can be performed in an extremely small footprint. | 02-12-2009 |
Bart Van De Vyver, Geneve CH
Patent application number | Description | Published |
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20080289692 | DEVICES AND METHODS FOR PROGRAMMABLE MICROSCALE MANIPULATION OF FLUIDS - The present invention is directed generally to devices and methods for controlling fluid flow in meso-scale fluidic components in a programmable manner. Specifically, the present invention is directed to an apparatus and method for placing two microfluidic components in fluid communication at an arbitrary position and time, both of which are externally defined. The inventive apparatus uses electromagnetic radiation to perforate a material layer having selected adsorptive properties. The perforation of the material layer allows the fluid communication between microfluidic components. Other aspects of this invention include an apparatus and method to perform volumetric quantitation of fluids, an apparatus to program arbitrary connections between a set of input capillaries and a set of output capillaries, and a method to transport fluid in centripetal device from a larger to a smaller radius. In addition, the present invention also is directed to a method to determine the radial and polar position of a pickup in the reference frame of a rotating device. | 11-27-2008 |
David Van De Vyver, Lokeren BE
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20130090030 | COATED FIBRES, YARNS AND TEXTILES - A method of treatment for synthetic or natural fibre or yarn includes coating the fibre/yarn with a dispersion of carbon nanotubes in a coating composition which is cured by actinic radiation, such as UV, to provide a flexible conductive layer on the fibre/yarn. The liquid coating composition is sheared along the direction of a long axis of the yarn as it is applied to the yarn whereby the carbon nanotubes are substantially aligned prior to curing of the coating layer to provide improved longitudinal conductance. The method provides conductive fibre/yarn, from which anti-static textiles and fabrics can be formed, by treatment of conventional fibre/yarn and in a method with low energy consumption. The improved conductance allows thin or partial (e.g. stripe) coating layers to be used for yarns which provide good feel and handle, combined with good conductivity, for textiles formed from the yarns Coating compositions for use in the method are disclosed as are anti-static yarns, fibres fabrics and textiles resulting from the method. | 04-11-2013 |
Ivan Van De Vyver, Rochford GB
Patent application number | Description | Published |
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20100043460 | CHILLER AND REACTION BLOCKS - A reaction block is provided that utilizes a refrigerant gas for cooling that includes a plurality of reaction stations each defining a reaction chamber for receiving a reaction vessel and defining a gas conducting passageway for conducting the refrigerant gas through the reaction station in temperature transmitting relation thereto. The reaction block also includes a metering means in fluid communication with a respective one of the reaction stations and is configured to receive a liquid refrigerant and to deliver an amount of refrigerant gas to the gas conducting passageway of one of the reaction stations in order to cool the contents inside the reaction vessel located at that reaction station. The metering means is also configured so that the amount of the refrigerant gas delivered to the gas conducting passageway of one reaction station is independent of the amount of refrigerant gas delivered to another one of the reaction stations. | 02-25-2010 |