Patent application number | Description | Published |
20090199597 | Systems and methods for collapsing air lines in nanostructured optical fibers - Systems and methods of collapsing the air lines in the air line-containing region of a nanostructure optical fiber are disclosed. One method includes initiating irradiation of a portion of the nanostructure optical fiber from essentially opposite directions with at least first and second laser beams having substantially equal power and essentially the same mid-infrared wavelength. The method includes continuing the irradiation for an irradiation time t | 08-13-2009 |
20100129031 | Optical Ferrule Assemblies and Methods of Making the Same - Disclosed are multifiber ferrule assemblies and methods for manufacturing the same. In one embodiment, a finished multifiber ferrule can be provided with a front end having a first front surface that extends beyond a second front surface, thereby inhibiting interaction with a laser beam during processing. A plurality of optical fibers can be fixed within respective optical fiber bores and extend from respective optical fiber bore openings to a position beyond the first front surface. The plurality of optical fibers can be processed by cutting and polishing with a laser beam for providing each optical fiber with a final polished end surface located beyond the first front surface. In further embodiments, an offset structure is positioned with respect to a finished multifiber ferrule after cutting and polishing the optical fibers. | 05-27-2010 |
20100303416 | Laser-Shaped Optical Fibers Along with Optical Assemblies and Methods Therefor - Disclosed are optical assemblies such as field-installable connectors having a laser-shaped optical fiber along with methods for laser-shaping the optical fiber. The field-installable connector includes a ferrule having front and rear opposed faces and at least one fiber bore defined longitudinally therethrough, a stub optical fiber having a distal end with a laser-shaped end face is disposed within the at least one fiber bore of the ferrule and extends a predetermined distance beyond the rear face of the ferrule, and an alignment feature operable for aligning the stub optical fiber with the field optical fiber. One method of laser-shaping the optical fiber includes rotating the optical fiber and sweeping a beam of a laser across the optical fiber and then essentially stopping the rotation of the optical fiber and sweeping the beam through the optical fiber to cut the same with a tapered and angled end face. Other methods may include shifting the laser relative to the optical fiber to create a “pencil-tip” end on the optical fiber. | 12-02-2010 |
20120093465 | OPTICAL FERRULE ASSEMBLIES AND METHODS OF MAKING THE SAME - Disclosed are multifiber ferrule assemblies and methods for manufacturing the same. In one embodiment, a finished multifiber ferrule can be provided with a front end having a first front surface that extends beyond a second front surface, thereby inhibiting interaction with a laser beam during processing. A plurality of optical fibers can be fixed within respective optical fiber bores and extend from respective optical fiber bore openings to a position beyond the first front surface. The plurality of optical fibers can be processed by cutting and polishing with a laser beam for providing each optical fiber with a final polished end surface located beyond the first front surface. In further embodiments, an offset structure is positioned with respect to a finished multifiber ferrule after cutting and polishing the optical fibers. | 04-19-2012 |
20140099060 | OPTICAL FIBER CONNECTORS AND METHODS OF FORMING OPTICAL FIBER CONNECTORS - An optical fiber connector includes a fiber alignment body including a continuous optical fiber guide channel extending therethrough. The continuous optical fiber guide channel has a lead-in channel portion, a lead-out channel portion and a turn portion that connects the lead-in channel portion and the lead-out channel portion. The fiber alignment body has a reflective surface formed of metal that receives light traveling from an optical fiber located within the lead-in channel portion of the continuous optical fiber channel and reflects the light into the lead-out channel portion of the continuous optical fiber channel. | 04-10-2014 |
Patent application number | Description | Published |
20090041412 | Laser erosion processes for fiber optic ferrules - A method for processing fiber optic ferrules, the method comprising: providing a fiber optic ferrule defining an endface portion and a pedestal portion about one or more protruding optical fibers; mechanically polishing the one or more protruding optical fibers substantially flush with the pedestal portion; and non-mechanically eroding the pedestal portion about the one or more protruding optical fibers to a depth of at least the end face portion such that the one or more optical fibers remain protruding from the endface portion. Non-mechanically eroding may include laser erosion or chemical erosion. | 02-12-2009 |
20100126665 | LASER-BASED METHODS OF STRIPPING FIBER OPTIC CABLES - Laser-based methods of stripping different types of fiber optic cables ( | 05-27-2010 |
20120269488 | METHODS FOR PREPARATION AND DISPOSING OF AN OPTICAL FIBER(S) INTO A BLIND HOLE(S) AND RELATED ASSEMBLIES AND METHODS OF MAKING SAME - Methods for preparation and disposing of an optical fiber(s) into a blind hole(s) and related assemblies and methods of making same are disclosed. In one embodiment, a method for processing an optical fiber(s) is provided. The method includes processing an end portion(s) of the optical fiber(s) with a laser. The end portion(s) of the optical fiber(s) is disposed in a blind hole(s). The blind hole(s) may be disposed in a holding structure. The optical fiber(s) is attached to the holding structure. A fixture is also disclosed and may be used for retaining the optical fiber(s) in a channel(s) disposed in the fixture during preparation and/or disposing of the optical fiber(s) in the blind hole(s). An assembly prepared in accordance with the methods provided herein is also disclosed. In one embodiment, the assembly could include a holding structure assembly for an array of the optical fibers. | 10-25-2012 |
20130336618 | OPTICAL FIBER AND COMPOSITE INORGANIC FERRULE ASSEMBLIES AND METHODS - A pre-terminated optical fiber assembly with a ferrule having front and rear opposed faces and at least one fiber bore defined longitudinally therethrough includes a glass optical fiber is disposed within the at least one fiber bore with the fiber fused to the ferrule at a location at least 1 mm deep inside the bore. A method for fusing is also disclosed. The ferrule 14 is desirably composed of an inorganic composite material, the composite comprising a material gradient from at least 75% by volume of a first inorganic material to at least 75% by volume of second inorganic material in the radially inward direction, where the first inorganic material has a fracture toughness of at least 1 MPa•m | 12-19-2013 |
20130343709 | FERRULE ASSEMBLIES EMPLOYING MECHANICAL INTERFACES FOR OPTICAL FIBERS, AND RELATED COMPONENTS AND METHODS - Embodiments disclosed herein include ferrule assemblies employing mechanical interfaces for optical fibers and related component and methods. The ferrule assemblies may be used in fiber optic connectors to precisely position the optical fiber relative to the ferrule to facilitate an optical connection with another optical device. In certain embodiments disclosed herein, the ferrule assemblies include a ferrule that includes an inner surface forming a ferrule bore. Each of the ferrules may also include an end portion of an optical fiber disposed in the ferrule bore. The inner surface of the ferrule bore abuts against an outer surface of the optical fiber to form a mechanical interface. In this manner, the mechanical interface secures the optical fiber within the ferrule bore and precisely positioned relative to the ferrule. This mechanical interface may eliminate the need for epoxy or other means to secure the optical fiber within the ferrule bore. | 12-26-2013 |
20130343710 | SIMULTANEOUS THERMAL FORMING OF FERRULE AND OPTICAL FIBER IN A FERRULE ASSEMBLY TO THERMALLY FORM AN OPTICAL SURFACE IN THE FERRULE ASSEMBLY, AND RELATED FIBER OPTIC COMPONENTS, FIBER CONNECTORS, ASSEMBLIES, AND METHODS - Simultaneous thermal forming of a ferrule and optical fiber as part of a ferrule assembly to thermally form an optical surface in the ferrule assembly. Related fiber optic components, connectors, assemblies, and methods are disclosed. In certain embodiments, the ferrule assembly is comprised of a ferrule and an optical fiber having an end portion extending from an end face of the ferrule. The ferrule may be made from a material or material composition having the same or similar thermal energy absorption characteristics as the optical fiber disposed in the ferrule. Thus, when the end face of the ferrule and an end portion of an optical fiber are simultaneously exposed to a wavelength(s) of a laser beam emitted by a laser, at least a portion of the end face of the ferrule and end portion of the optical fiber are both thermally formed together to form an optical surface. | 12-26-2013 |
20140105545 | GRADED COMPOSITION FOR OPTICAL WAVEGUIDE FERRULE - A ferrule for optical waveguides includes an exterior and an interior of the ferrule. The interior of the ferrule has a bore defined therein that is configured to receive an optical waveguide. Material of the ferrule is such that the material changes from the interior to the exterior of the ferrule, where the thermal expansion coefficient of the material transitions from less than 30×10−7/° C. at the interior of the ferrule to greater than 70×10−7/° C. at the exterior of the ferrule. The thermal expansion coefficient of the material may change by way of discrete layers in the material between the interior and exterior of the ferrule. | 04-17-2014 |
20140116995 | GRADIENT-INDEX (GRIN) LENS FABRICATION EMPLOYING LASER PULSE WIDTH DURATION CONTROL, AND RELATED COMPONENTS, SYSTEMS, AND METHODS - Gradient-index (GRIN) lens fabrication employing laser pulse width duration control, and related components, systems, and methods are disclosed. GRIN lenses can be fabricated from GRIN rods by controlling the pulse width emission duration of a laser beam emitted by a laser to laser cut the GRIN rod, as the GRIN rod is disposed in rotational relation to the laser beam. Controlling laser pulse width emission duration can prevent or reduce heat accumulation in the GRIN rod during GRIN lens fabrication. It is desired that the end faces of GRIN lenses are planar to facilitate light collimation, easy bonding or fusing of the GRIN lens to optical fibers to reduce optical losses, polishing to avoid spherical aberrations, and/or cleaning the end faces when disposed in a fiber optic connector, as non-limiting examples. | 05-01-2014 |
20140321812 | PRETERMINATED FIBER OPTIC CONNECTOR SUB-ASSEMBLIES, AND RELATED FIBER OPTIC CONNECTORS, CABLE ASSEMBLIES, AND METHODS - Embodiments disclosed herein include pre-terminated fiber optic connector sub-assemblies, and related fiber optic connectors, cables, and methods. In certain embodiments, an optical fiber stub is pre-installed in a ferrule bore of a ferrule of a fiber optic connector sub-assembly, to provide the pre-terminated fiber optic connector sub-assembly. The optical fiber stub can be pre-installed in the ferrule bore prior to termination of the fiber optic connector sub-assembly. Because the pre-terminated optical fiber stub disposed in the ferrule bore is not directly accessible through a ferrule body of the ferrule when a field optical fiber is disposed in the ferrule bore for fusion splicing, the ferrule has properties that allow thermal energy to be directed through the ferrule body into the ferrule bore. In this manner, the optical fiber stub pre-installed in the ferrule bore can be fusion spliced with the field optical fiber to terminate a fiber optic cable. | 10-30-2014 |
20140332510 | COATING REMOVAL SYSTEMS FOR OPTICAL FIBERS - Coating removal systems for optical fibers are disclosed. Related methods and optical fibers processed with these methods and coating removal systems are also disclosed. An optical fiber includes a glass fiber, having a cladding and core, surrounded by a protective coating which does not contribute to the optical performance of the optical fiber. By removing the coating at an end portion of the optical fiber, the end portion may be precisely positioned and secured to enable reliable optical communications. A laser beam may be directed at the protective coating to remove the protective coating by one or more ablating, melting, vaporizing, and/or thermal decomposing processes. The optical fiber may also be optionally cleaved. In this manner, the coating may be efficiently removed while retaining at least fifty percent of the tensile strength of the optical fiber. | 11-13-2014 |
20150219860 | METHODS OF SECURING ONE OR MORE OPTICAL FIBERS TO A FERRULE - A method of securing an optical fiber to a ferrule involves heating the ferrule to cause thermal expansion. A ferrule bore of the ferrule increases in diameter as a result of the thermal expansion, and an optical fiber is inserted into the ferrule bore. The ferrule is then cooled so that the ferrule bore decreases in diameter and forms a mechanical interface with the optical fiber. Finally, the optical fiber is fused to the ferrule by irradiating the optical fiber and the ferrule with laser energy. | 08-06-2015 |
20150219861 | OPTICAL CONNECTOR WITH ADHESIVE MATERIAL - An optical fiber connector includes a ferrule configured to receive an optical fiber. The ferrule has a fiber bore and a storage location interior to the ferrule and adjacent to the fiber bore. The storage location comprises a funnel-shaped portion that is directed toward the fiber bore. An adhesive material is positioned in the storage location of the ferrule. The adhesive material is a dry and solid material. | 08-06-2015 |
20150241638 | PRETERMINATED FIBER OPTIC CONNECTOR SUB-ASSEMBLIES, AND RELATED FIBER OPTIC CONNECTORS, CABLE ASSEMBLIES, AND METHODS - Embodiments disclosed herein include pre-terminated fiber optic connector sub-assemblies, and related fiber optic connectors, cables, and methods. In certain embodiments, an optical fiber stub is pre-installed in a ferrule bore of a ferrule of a fiber optic connector sub-assembly, to provide the pre-terminated fiber optic connector sub-assembly. The optical fiber stub can be pre-installed in the ferrule bore prior to termination of the fiber optic connector sub-assembly. Because the pre-terminated optical fiber stub disposed in the ferrule bore is not directly accessible through a ferrule body of the ferrule when a field optical fiber is disposed in the ferrule bore for fusion splicing, the ferrule has properties that allow thermal energy to be directed through the ferrule body into the ferrule bore. In this manner, the optical fiber stub pre-installed in the ferrule bore can be fusion spliced with the field optical fiber to terminate a fiber optic cable. | 08-27-2015 |
20150277048 | OPTICAL FIBERS HAVING COATINGS REMOVED THEREFROM AND RELATED METHODS - An optical fiber includes a glass fiber, having a cladding and core, surrounded by a polymer coating. Some of the coating is removed by a laser beam so that the optical fiber comprises a first lengthwise portion covered by the coating and a second lengthwise portion where the coating is not present on at least ninety-five (95) percent of an exterior surface of the second lengthwise portion. A microstructure of the polymer coating, adjacent to the second lengthwise portion on the first lengthwise portion, tapers at an angle such that a thickness of the polymer coating decreases toward the second lengthwise portion as a function of proximity to the second lengthwise portion. The optical fiber may also be optionally cleaved with the laser beam. | 10-01-2015 |
20150301292 | METHODS OF TERMINATING ONE OR MORE OPTICAL FIBERS - A method of terminating an optical fiber involves providing a ferrule having a front end, a rear end, a ferrule bore extending between the front and rear ends, and a bonding agent disposed in at least a portion of the ferrule bore. The method also involves applying energy to heat the bonding agent. An end section of an optical fiber is inserted into the ferrule bore and through the bonding agent when the bonding agent is heated. The end section of the optical fiber includes a primary coating prior to insertion into the ferrule bore. During insertion of the end section of the optical fiber through the bonding agent, the heated bonding agent thermally removes at least a portion of the primary coating during so that the optical fiber can be secured in the ferrule bore with the bonding agent. | 10-22-2015 |
20150309268 | OPTICAL FIBER AND COMPOSITE INORGANIC FERRULE ASSEMBLIES - A pre-terminated optical fiber assembly with a ferrule having front and rear opposed faces and at least one fiber bore defined longitudinally therethrough includes a glass optical fiber is disposed within the at least one fiber bore with the fiber fused to the ferrule at a location at least 1 mm deep inside the bore. A method for fusing is also disclosed. The ferrule | 10-29-2015 |
20160062054 | OPTICAL CONNECTOR WITH ADHESIVE MATERIAL - An optical fiber connector preloaded with an adhesive is provided. The optical connector includes a body having a passage with a first section extending inwardly from a first face of the body, a second section extending inwardly from a second face from the body, and a transition section located between the first section and the second section. The first section of the passage has a first width and the second section of the passage has a second width that is less than the first width. An adhesive composition is located within the transition section of the passage and is configured to bind an optical fiber to an inner surface of the second section following melting and solidification of the adhesive composition. | 03-03-2016 |
Patent application number | Description | Published |
20080304540 | SYSTEM AND METHOD FOR THERMAL ANALYSIS USING VARIABLE THERMAL RESISTANCE - A thermal measurement apparatus and method for performing heat flux differential scanning calorimetry (DSC) is disclosed. A variable thermal resistor is used to couple a measurement assembly to a heat sink in the thermal measurement apparatus, such that samples can be rapidly heated and rapidly cooled. The apparatus can be configured with a highly conductive sample assembly enclosure. The enclosure can include a high emissivity coating. In one embodiment, the enclosure extends along a longitudinal direction that is about the same as that of an infrared lamp assembly used to heat the enclosure, thereby increasing the efficiency of heating the sample enclosure. In one configuration, the variable thermal resistor comprises a gap whose gas composition can be varied during a sample measurement to independently optimize sample heating and cooling rates. | 12-11-2008 |
20080304542 | INFRARED HEATED DIFFERENTIAL SCANNING CALORIMETER - A heat flux differential scanning calorimeter (DSC) is disclosed. The DSC can be configured with a highly conductive sample assembly enclosure. The enclosure can include a high emissivity coating. In one embodiment, the enclosure extends along a longitudinal direction that is about the same as that of an infrared lamp assembly used to heat the enclosure, thereby increasing the efficiency of heating the sample enclosure. In one embodiment, a gas-filled thermal resistor is used to couple the measurement assembly to a heat sink, such that samples can be rapidly heated and rapidly cooled. | 12-11-2008 |
20100154439 | COOLING SYSTEM USING POSITIVE DISPLACEMENT CRYOGENIC LIQUID PUMP - A cooling system employs a single-acting positive displacement bellows pump to transfer a cryogenic liquid such as liquid nitrogen from a storage dewar to a heat exchanger coupled to a measurement chamber of an instrument, wherein cooling takes place by vaporizing the liquid. Preferably, the capacity of the pump is greater than the maximum cooling requirement of the instrument, wherein both vapor resulting from vaporizing of the cryogenic liquid circulated through the heat exchanger and liquid that does not vaporize when circulated through the heat exchanger are returned to the storage dewar, wherein the vapor is subsequently vented from the dewar. Preferably, with the aid of a weir in a return line, the level of liquid in the heat exchanger is maintained full and constant, and the cooling demands are automatically met without the need for other control of the flow rate or level of the liquid. Also, unlike conventional systems, liquid transfer from the dewar does not require dewar pressurization, so that the dewar may be refilled whenever necessary without interrupting the experiment in progress. | 06-24-2010 |
20100278209 | SIMULTANEOUS DIFFERENTIAL THERMAL ANALYSIS SYSTEM - A balance for a simultaneous differential thermal analysis instrument that combines gravimetric measurements with measurements that require propagation of electrical signals from the sample holder to an apparatus for recording the electrical signals. In one embodiment of the invention, conductive flat planar strip flexure pivots are used in a single-meter movement balance to mechanically and electrically couple the components of the balance mechanism to the apparatus that records the electrical signals. | 11-04-2010 |
20100278210 | SIMULTANEOUS DIFFERENTIAL THERMAL ANALYSIS SYSTEM - A balance for a simultaneous differential thermal analysis instrument that combines gravimetric measurements with measurements that require propagation of electrical signals from the sample holder to an apparatus for recording the electrical signals. In one embodiment of the present invention, conductive cross-flexure pivots are used in a parallel guided balance to mechanically and electrically couple the components of the balance mechanism to the apparatus that records the electrical signals. | 11-04-2010 |
20130208759 | Thermal Analysis Sample Holder - A sample holder for use in a scientific instrument requiring accurate and precise measurements of temperatures. The sample holder includes a ceramic sample cup diffusion bonded to a ceramic beam or to a ceramic adapter. A thermocouple is welded to the bottom of the sample cup. | 08-15-2013 |
20150253206 | QUASIADIABATIC DIFFERENTIAL SCANNING CALORIMETER - A method of operating a differential scanning calorimeter wherein errors in the heat flow rate measurement are reduced by operating the calorimeter in a quasiadiabatic mode and by employing a heat flow rate measurement algorithm that includes the leakage heat flow rate. The temperature of the DSC enclosure is controlled independently of the temperature of the measuring system, which allows the temperature difference between the sample and reference containers and the enclosure to be minimized, thus minimizing leakage heat flow. | 09-10-2015 |
Patent application number | Description | Published |
20090087008 | Sound Reproduction With Improved Low Frequency Characteristics - A sound reproduction system ( | 04-02-2009 |
20090136072 | Sound reproduction with improved performance characteristics - A sound reproduction system is disclosed in which a sound barrier defines a horn passageway having a first end and a second open end. A high frequency range driver is provided at the first end, and is mutually coupled with a lower driver to the horn passageway. The lower driver has an upper frequency end lower than a frequency of a first cancellation notch for the drivers. The lower driver is located at a position along the horn passageway at which the passageway has a preselected cross-sectional area which is no greater than an area of a round cross section having a circumference equal to one wavelength at the upper frequency end. | 05-28-2009 |
20090323996 | Horn-loaded acoustic source with custom amplitude distribution - A sound reproduction system is disclosed in which at least one driver is provided, along with a horn member in acoustic loading relationship to the driver. The horn member defines an internal passageway having a first end and a second open end, with the driver at the first end, producing a driver soundwave having an initial central axis and an initial amplitude distribution. A plurality of vanes are disposed in the internal passageway, at different angles from the central axis to deflect respective portions of the driver soundwave so as to alter the initial amplitude distribution. | 12-31-2009 |
20090323997 | Horn-loaded acoustic line source - A sound reproduction system is disclosed in which a sound enclosure defines a soundwave path having a first end, a second open end and at least one bend therebetween. At least one driver is provided at the first end for producing a driver soundwave that is confined by the sound enclosure for travel along the soundwave path. At least one baffle member is situated in the soundwave path, defining a reflective surface of preselected shape that reflects and constricts the soundwave therethrough. | 12-31-2009 |
20120328140 | Horn enclosure for combining sound output - A horn enclosure combines sound output emanating from a plurality of acoustic drivers. The horn enclosure includes a plurality of sound input plenums, a plurality of flow passageways, and a common sound output chamber. Each of the input plenums is coupled to an acoustic driver for receiving generated sound output from the associated driver. A plurality of partitions defining the plurality of flow passageways provides for a plurality of acoustic paths from each acoustic driver and through the input plenum. The common sound output chamber is in acoustic communication with each plenum through respective flow passageways and has a sound output opening for passage of the combined sound output. | 12-27-2012 |