Patent application number | Description | Published |
20080281880 | METHOD FOR STORING DATA FOR RETRIEVAL AND TRANSFER - Provided is a method, system and program for storing data for later retrieval and for transfer within a storage hierarchy. A data storage subsystem stores both individual user files and also managed files, each managed file comprising an aggregation of multiple user files. After receiving user files from a client station, the subsystem stores user files in a retrieval storage pool to facilitate file retrieval. Criteria are subsequently applied to the user files stored in the retrieval storage pool to delete low or lower priority files from the retrieval storage pool. In addition, user files are aggregated in managed files for transfer to another location within the storage hierarchy. | 11-13-2008 |
20080281883 | SYSTEM AND PROGRAM FOR STORING DATA FOR RETRIEVAL AND TRANSFER - Provided is a method, system and program for storing data for later retrieval and for transfer within a storage hierarchy. A data storage subsystem stores both individual user files and also managed files, each managed file comprising an aggregation of multiple user files. After receiving user files from a client station, the subsystem stores user files in a retrieval storage pool to facilitate file retrieval. Criteria are subsequently applied to the user files stored in the retrieval storage pool to delete low or lower priority files from the retrieval storage pool. In addition, user files are aggregated in managed files for transfer to another location within the storage hierarchy. | 11-13-2008 |
20080294611 | HIERARCHICAL STORAGE MANAGEMENT USING DYNAMIC TABLES OF CONTENTS AND SETS OF TABLES OF CONTENTS - A system, apparatus, and process creates a table of contents (TOC), including one or more table of contents (TOC) entries, to manage data in a hierarchical storage management system. Each TOC entry contains metadata describing the contents and attributes of a data object within an image, which is an aggregation of multiple data objects into a single object for storage management purposes. The TOC is stored in a storage hierarchy, such as magnetic disk, for fast access of and efficient operation on the aggregated TOC entries. The system, apparatus, and process also provide for aggregating the TOC entries from one or more TOCs into a TOC set in the storage management server database. The TOC set may be manipulated and queried in order to find a particular data object or image referenced by a TOC entry. The TOC entries, TOCs, and TOC sets may be dynamically managed by the hierarchical data storage management system through implementation of a set of policy management constructs that define appropriate creation, retention, and movement of the objects within the database and storage hierarchy. | 11-27-2008 |
Patent application number | Description | Published |
20110062119 | UNDERWATER MARKING WITH A PLASMA ARC TORCH - A method of marking underwater with a plasma arc torch is provided. The method includes surrounding a plasma arc produced by the plasma arc torch with a flow of gas. The flow of gas may be directed around and/or along the body of the plasma arc torch with an air curtain attachment. Directing the flow of gas in this manner generates a protective air curtain which substantially surrounds the plasma arc. A current between 8 and 35 amperes may be used to mark the workpiece. Thereafter, the workpiece may be cut using the same plasma arc torch with a current between 30 and 750 amperes. The same nozzle and rate of flow of gas may be used for both the marking and cutting operations. Additionally, the workpiece may be kept underwater throughout the marking and cutting operations. | 03-17-2011 |
20110210100 | CONTROLLABLE CUT BY A PLASMA ARC TORCH - Embodiments of methods of controlling the shape of a cut on a workpiece using a plasma arc torch are provided. The methods may control the resultant cut angle and the shape of a top of the cut. The top of the cut can have either a sharp edge, or have a rounded lip. The radius of the rounded lip can be adjusted. The standoff distance defined between the nozzle of the plasma arc torch and the top surface of the workpiece contributes to defining the resultant cut angle and the shape of the top of the cut. In particular, increasing the standoff results in a greater radius and increases the cut angle and decreasing the standoff distance does the opposite. Additionally, the angle of inclination of the plasma arc torch can be used to compensate for a resultant cut angle so as to produce a desired cut angle. | 09-01-2011 |
20110210101 | PROCESSES FOR USING A PLASMA ARC TORCH TO OPERATE UPON AN INSULATION-COATED WORKPIECE - A process for using a plasma arc torch is provided that includes operating a power source of the plasma arc torch to initiate an electric arc between an electrode of the plasma arc torch and a nozzle of the plasma arc torch at a starting arc current. A flow of argon-containing gas can be provided through the nozzle while the arc exists between the electrode and the nozzle, and the power source operated to cause the arc to extend out from the nozzle to a coating of insulation on a workpiece. The arc may ionize at least part of the argon-containing gas so as to burn through the insulation of the workpiece and attach the arc to metal of the workpiece. Thereafter, the flow of argon-containing gas can be halted and a flow of a different gas can be provided while increasing the arc current above the starting arc current. | 09-01-2011 |
20120145680 | Method and plasma arc torch system for marking and cutting workpieces with the same set of consumables - A plasma arc torch both cutting and marking of metal workpieces includes a plasma nozzle having a plasma nozzle orifice through which an electric arc from an electrode and a stream of plasma gas are emitted toward a workpiece, and a liquid-injection shield cup that injects liquid tangentially inwardly to the arc and stream of plasma gas. A power supply is operable to selectively deliver electrical power to the electrode at either a low power level suitable for marking of a workpiece or a high power level suitable for workpiece cutting. The torch may be selectively operated to mark at the low power level, with a plasma marking gas being delivered to the plasma gas passage, or to cut at the high power level, with a plasma cutting gas being delivered to the plasma gas passage, and liquid being delivered to the liquid injection passage for both cutting and marking. | 06-14-2012 |
Patent application number | Description | Published |
20090000815 | CONFORMAL SHIELDING EMPLOYING SEGMENT BUILDUP - In one embodiment, a meta-module having circuitry for two or more modules is formed on a substrate, which is preferably a laminated substrate. The circuitry for the different modules is initially formed on the single meta-module. Each module will have one or more component areas in which the circuitry is formed. A metallic structure is formed on or in the substrate for each component area to be shielded. A single body, such as an overmold body, is then formed over all of the modules on the meta-module. At least a portion of the metallic structure for each component area to be shielded is then exposed through the body by a cutting, drilling, or like operation. Next, an electromagnetic shield material is applied to the exterior surface of the body of each of the component areas to be shielded and in contact with the exposed portion of the metallic structures. | 01-01-2009 |
20090000816 | CONFORMAL SHIELDING PROCESS USING FLUSH STRUCTURES - In one embodiment, a meta-module having circuitry for two or more modules is formed on a substrate, which is preferably a laminated substrate. The circuitry for the different modules is initially formed on the single meta-module. Each module will have one or more component areas in which the circuitry is formed. A metallic structure is formed on or in the substrate for each component area to be shielded. A single body, such as an overmold body, is then formed over all of the modules on the meta-module. At least a portion of the metallic structure for each component area to be shielded is then exposed through the body by a cutting, drilling, or like operation. Next, an electromagnetic shield material is applied to the exterior surface of the body of each of the component areas to be shielded and in contact with the exposed portion of the metallic structures. | 01-01-2009 |
20090002970 | CONFORMAL SHIELDING PROCESS USING PROCESS GASES - In one embodiment, a meta-module having circuitry for two or more modules is formed on a substrate, which is preferably a laminated substrate. The circuitry for the different modules is initially formed on the single meta-module. Each module will have one or more component areas in which the circuitry is formed. A metallic structure is formed on or in the substrate for each component area to be shielded. A single body, such as an overmold body, is then formed over all of the modules on the meta-module. At least a portion of the metallic structure for each component area to be shielded is then exposed through the body by a cutting, drilling, or like operation. Next, an electromagnetic shield material is applied to the exterior surface of the body of each of the component areas to be shielded and in contact with the exposed portion of the metallic structures. | 01-01-2009 |
20090025211 | ISOLATED CONFORMAL SHIELDING - In one embodiment, a meta-module having circuitry for two or more modules is formed on a substrate, which is preferably a laminated substrate. The circuitry for the different modules is initially formed on the single meta-module. Each module will have one or more component areas in which the circuitry is formed. A metallic structure is formed on or in the substrate for each component area to be shielded. A single body, such as an overmold body, is then formed over all of the modules on the meta-module. At least a portion of the metallic structure for each component area to be shielded is then exposed through the body by a cutting, drilling, or like operation. Next, an electromagnetic shield material is applied to the exterior surface of the body of each of the component areas to be shielded and in contact with the exposed portion of the metallic structures. | 01-29-2009 |
20100199492 | CONFORMAL SHIELDING EMPLOYING SEGMENT BUILDUP - A meta-module having circuitry for two or more modules is formed on a substrate, which is preferably a laminated substrate. The circuitry for the different modules is initially formed on the single meta-module. Each module will have one or more component areas in which the circuitry is formed. A metallic structure is formed on or in the substrate for each component area to be shielded. A single body, such as an overmold body, is then formed over all of the modules on the meta-module. At least a portion of the metallic structure for each component area to be shielded is then exposed through the body by a cutting, drilling, or like operation. Next, an electromagnetic shield material is applied to the exterior surface of the body of each of the component areas to be shielded and in contact with the exposed portion of the metallic structures. | 08-12-2010 |
20110225803 | CONFORMAL SHIELDING EMPLOYING SEGMENT BUILDUP - A meta-module having circuitry for two or more modules is formed on a substrate, which is preferably a laminated substrate. The circuitry for the different modules is initially formed on the single meta-module. Each module will have one or more component areas in which the circuitry is formed. A metallic structure is formed on or in the substrate for each component area to be shielded. A single body, such as an overmold body, is then formed over all of the modules on the meta-module. At least a portion of the metallic structure for each component area to be shielded is then exposed through the body by a cutting, drilling, or like operation. Next, an electromagnetic shield material is applied to the exterior surface of the body of each of the component areas to be shielded and in contact with the exposed portion of the metallic structures. | 09-22-2011 |
20110235282 | CONFORMAL SHIELDING PROCESS USING PROCESS GASES - In one embodiment, a meta-module having circuitry for two or more modules is formed on a substrate, which is preferably a laminated substrate. The circuitry for the different modules is initially formed on the single meta-module. Each module will have one or more component areas in which the circuitry is formed. A metallic structure is formed on or in the substrate for each component area to be shielded. A single body, such as an overmold body, is then formed over all of the modules on the meta-module. At least a portion of the metallic structure for each component area to be shielded is then exposed through the body by a cutting, drilling, or like operation. Next, an electromagnetic shield material is applied to the exterior surface of the body of each of the component areas to be shielded and in contact with the exposed portion of the metallic structures. | 09-29-2011 |