| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 156272400 | Involving magnetically susceptible lamina or incorporating into the work a particulate susceptor material having magnetic properties | 17 |
| 20080257488 | METHOD OF MANUFACTURING INDUCTOR - A method of manufacturing an inductor includes a lamination step, a division step, a firing step, and a plating step. In the lamination step, a laminate including an insulator, a coil body, and external electrodes is formed. That is, in the lamination step, insulating layers having wide filling conductors, insulating layers having narrow filling conductors, and conductor patterns having external electrode patterns are laminated. As a result, the conductor patterns form the coil body, and the wide filling conductors, the narrow filling conductors, and the external electrode patterns form the external electrodes. The narrow filling conductors have a width that is less than the widths of the wide filling conductors and the external electrode patterns, and recesses and projections are provided in the external electrodes. | 10-23-2008 |
| 20080302476 | METHOD TO BOND PLASTIC END CAPS TO POROUS FILTRATION BODIES - A bonding method for a filtration unit for bonding a polymeric end cap to a porous filter element body includes providing a polymeric end cap of a filtration unit, providing a porous filter element body and positioning a hot melt adhesive element and a metal element between the porous filter element body and the end cap. A pressure is applied between the porous filter element body and the end cap and an electromagnetic field is induced at the metal element. The hot melt adhesive is melted and flows between the end cap and the porous filter element body and a bond is formed between the porous filter element body and the end cap. | 12-11-2008 |
| 20090133822 | NANOPARTICULATE PREPARATION - The invention relates to nanoparticulate preparations containing at least one mixed metal oxide in the form of supramagnetic, nanoscale particles, methods for heating such a preparation, and methods for producing and dissolving adhesive compounds on the basis of said preparations. | 05-28-2009 |
| 20090294046 | ANISOTROPIC CONDUCTIVE FILM AND ADHESION METHOD THEREOF - The invention concerns an anisotropic conductive film used for adhering IC, e.g., LCD displays, etc. The conductive film is characterized by comprising a thermosetting adhesive, super-paramagnetic metal oxide nano-particles, and conductive particles, the super-paramagnetic metal oxide nano-particles and the conductive particles being dispersed in a thermosetting composition. With such a configuration in the invention, it is advantageous that low temperature curing is implemented by means of high frequencies and positions of particles can be controlled by means of a magnetic field in adhering IC, e.g., LCD displays, so that high connection reliability is achieved for connection electrodes of fine pitches. | 12-03-2009 |
| 20110094672 | METHOD AND DEVICE FOR SEALING - A method for sealing a first packaging material laminate, comprised of at least one layer of magnetizable particles and a sealable layer, to a second packaging laminate involves facing the sealable layer towards the second laminate, providing an alternating magnetic field to the laminates in a sealing zone, thereby generating magnetic hysteresis losses in the laminate having the magnetizable particles, which losses create heat substantially melting the sealable layer in the sealing zone, and applying a sealing pressure to the first and second laminate to cause the first and second laminate to be pressed together in the sealing zone, thereby sealing the laminates to each other. | 04-28-2011 |
| 20110120638 | Wide Sheet Magnetic Systems - A system and apparatus relating to connecting at least one first longitudinal periphery of at least one first magnetic sheet with at least one second longitudinal periphery of at least one second magnetic sheet by placing such first longitudinal periphery in adjacent relationship with such second longitudinal periphery; and connecting such first longitudinal periphery in adjacent relationship with such second longitudinal periphery; wherein such connecting step comprises the step of unitizing such at least one first magnetic sheet and such at least one second magnetic sheet into one unitary magnetic sheet. | 05-26-2011 |
| 20120234488 | MAGNETIC HOT MELT ADHESIVE AND METHODS OF MAKING AND USING THE SAME - One embodiment includes a magnetic particle-containing adhesive an adhesive including a polymer resin having a softening temperature; and magnetic particles dispersed within the polymer resin. | 09-20-2012 |
| 20120291948 | THERMOPLASTIC WELDING APPARATUS AND METHOD - A thermoplastic welding apparatus includes a thermoplastic welding tool, at least one tooling surface in the thermoplastic welding tool, a magnetic induction coil in the thermoplastic welding tool and generally encircling the at least one tooling surface and at least one smart susceptor in the thermoplastic welding tool at the at least one tooling surface. The magnetic induction coil is adapted to generate a magnetic flux field oriented generally parallel to a plane of the at least one smart susceptor. | 11-22-2012 |
| 20130075030 | LIQUID DISPENSER AND APPLICATION METHOD THEREOF - A liquid dispenser is used for a lens module. The lens module includes a lens barrel and a component received in the lens barrel. The liquid dispenser includes a magnetic support base and a needle. The magnetic support base defines at least one hole for receiving the lens module. The needle contains a magnetic glue. The needle dispenses the magnetic glue on the component, and the magnetic support base attracts the magnetic glue to flow towards an inner surface of the lens barrel by magnetic force. | 03-28-2013 |
| 20130087276 | MEDIUM SUPPORT MEMBER - A medium support member includes a table having a top surface; an overlay placed on the top surface of the table, the overlay having a top surface and a bottom surface and a plurality of through-holes; a spacer array provided between the top surface of the table and the bottom surface of the overlay to define a gap between the table and the overlay, and at least one vacuum passage communicating with said gap for creating an underpressure in the gap, wherein at least portions of the overlay and corresponding portions of the table are held together by magnetic attraction. | 04-11-2013 |
| 20140216644 | ELECTRICALLY CONDUCTIVE HEAT-ACTIVATED ADHESIVE COMPOUND - An adhesive film, which can be bonded when heat-activated, comprising a) a polymer-metal blend comprising at least one adhesive which can be bonded when heat-activated, and at least one metal component melting in the temperature range from 50° C. to 400° C., and b) at least one fibrous, electrically conductive filler, the filler being present at least partly in the form of a bound fiber network with the metal component. | 08-07-2014 |
| 20140299268 | Thermally Curable Bonding Film Adhesive with Uniform Thickness - An adhesive bonding film comprises at least one layer of thermally curable resin. The thermally curable resin includes embedded metal particles adapted to be excited to produce heat for curing the resin. | 10-09-2014 |
| 20140318702 | Magnetically guided catheters - A magnetically-guided catheter includes a tip positioning magnet in the distal electrode assembly configured to interact with externally applied magnetic fields for magnetically-guided movement. A magnetically-guided mapping catheter includes an electrically-conductive capsule in the form of a casing that includes a distal ablation surface and isolates the positioning magnet from bio-fluids to prevent corrosion. An open irrigation ablation catheter includes an isolated manifold that isolates the positioning magnet from contact with irrigation fluid to prevent corrosion. | 10-30-2014 |
| 20140332155 | Method for Connecting a Connector Coupling to a Fluid Line - A method for connecting a connector coupling to a fluid conducting line, wherein the line consists of plastic. A line end of the line is inserted in a receiving receptacle encompassing the circumference of the connector coupling. At least one metal element is disposed in or on the receiving receptacle. The metal element is heated by means of electromagnetic induction, and, as a result of this heating, at least the plastic regions of the line end melt, such that the line end is welded to the wall, or walls, of the receiving receptacle. | 11-13-2014 |
| 20150013894 | Metallic Bladders - A method and apparatus is presented. A method may comprise positioning a metallic bladder within a tool, the tool having a number of die liners that generate heat when exposed to a magnetic field; applying the magnetic field to the number of die liners to heat the metallic bladder; and pressurizing the metallic bladder. | 01-15-2015 |
| 20150107765 | UV-Curable Anisotropic Conductive Adhesive - Illustrative embodiments of anisotropic conductive adhesive (ACA) and associated methods are disclosed. In one illustrative embodiment, the ACA may comprise a binder curable using UV light and a plurality of particles suspended in the binder. Each of the plurality of particles may comprise a ferromagnetic material coated with a layer of electrically conductive material. The electrically conducting material may form electrically conductive and isolated parallel paths when the ACA is cured using UV light after being subjected to a magnetic field. | 04-23-2015 |
| 20150129124 | SURFACE ENHANCEMENT BY INCORPORATION OF MAGNETIC PARTICLES BY ELECTROMAGNETIC MOLDS, ROLLERS, COATING BLADES AND BRUSHES - A method for applying a magnetic element to a surface includes the steps of providing a magnetized surface capable of holding a magnetic element, providing a substrate having a surface to be modified by the addition of the magnetic element, bringing the magnetic element into contact with the surface of the substrate, eliminating the magnetism of the magnetized surface to create an un-magnetized surface, and withdrawing the un-magnetized surface from contact with the surface of the substrate, thereby leaving behind the magnetic element on the surface of the substrate. | 05-14-2015 |
