Abstract: Apparatuses with improved flammability properties and methods for altering the flammability properties of the apparatuses are provided. In certain embodiments, the apparatus comprises an occupant structure having an exterior portion and an interior portion defining an occupant space. The interior portion is formed, at least in part, of a composite material and a first nanoadditive fixed on a surface of the composite material proximate the occupant space. In one embodiment, the nanoadditive may comprise a continuous network of nanoscale fibers.

Abstract: The present invention reduces the burden of the network having heavier load, maintains the load balance among different networks, and improves the overall resource utilization efficiency and transmission qualities of the networks, by providing a network forwarding apparatus for selectively distributing the IP packets to be forwarded to the network having less traffic for transmission by monitoring in real-time the traffic in the different networks.

Abstract: A method and system for parsing a markup language document are disclosed in the invention. The method comprises: pre-splitting a body of the markup language document into plurality parts; scanning each of the plurality parts, wherein while each of the parts is scanned, the scanning of the part is stopped only when a specific mark is found, and then a stop point at which the scanning is stopped is recorded; splitting the body of the markup language document into a plurality of fragments using the respective stop points; parsing the plurality of fragments in parallel and producing parsing results for the respective fragments; and combining the parsing results for the respective fragments to form a parsing result for the markup language document. A parsing method that supports namespace is also provided.

Abstract: Methods and devices are provided for the continuous production of a network of nanotubes or other nanoscale fibers. The method includes making a suspension of nanoscale fibers dispersed in a liquid medium, optionally with surfactant and/or sonication, and filtering the suspension by moving a filter membrane through the suspension, such that the nanoscale fibers are deposited directly on the filter membrane as the fluid medium flows through the filter membrane, thereby forming a continuous membrane of the nanoscale fibers. The deposition of the nanoscale fibers can occur when and where the filter membrane moves into contact with a static, porous filter element or a dynamic, porous filter element. The filtering can be conducted within a magnetic field effective to align the nanoscale fibers, and/or with the aid of vacuum to pull water through the filter membrane, applied pressure to press water though the filter membrane, or a combination thereof.

Abstract: The present invention relates to a method and apparatus of lock transactions processing in a single or multi-core processor. An embodiment of the present invention is a processor with one or more processing cores, an address arbitrator, where one or more processing cores are configured to submit a lock transaction request to the address arbitrator corresponding to a specific instruction in response to the execution of the specific instruction. The lock transaction request includes a lock variable address asserted on an address bus. The processor further includes a lock controller for performing lock transaction processing in response to the lock transaction request, and notifying processing result to the processing core from which the lock transaction request was sent. The processor further includes a switching device, coupled to the address arbitrator and the lock controller, for identifying the lock transaction request and notifying the lock transaction request to the lock controller.

Abstract: A technique is provided for the fabrication of multi-walled carbon nanotube (MWNT) and carbon nanofiber (CNF) film materials. The method includes mixing a relatively small amount of single-walled nanotubes (SWNTs) with larger amounts of MWNTs and CNFs, which enables one to produce highly flexible SWNT materials—advantageously without the need for bonding agents and at significantly lower costs compared to flexible SWNT materials. The method exploits SWNTs tendency to entangle together to form flexible films, using a small amount of SWNTs to wrap around and entangle the larger diameter MWNTs and CNFs together to form flexible films with highly beneficial mechanical, electrical, and thermal properties at a fraction of the cost of SWNT materials.

Abstract: Electromagnetic interference (EMI) shielding structure and methods of making such structures are provided. In one case, a method is provided for making a lightweight composite structure for electromagnetic interference shielding, including the steps of providing a nanoscale fiber film which comprises a plurality of nanoscale fibers; and combining the nanoscale fiber film with one or more structural materials to form a composite material which is effective as an electromagnetic interference shielding structure. In another case, a method is provided for shielding a device which includes an electrical circuit from electromagnetic interference comprising the steps of providing a nanoscale fiber film which comprises a plurality of nanoscale fibers; and incorporating the nanoscale fiber film into an exterior portion of the device to shield an interior portion of the device from electromagnetic interference.

Abstract: An electro-machining apparatus using one or more carbon nanotubes as an electrode. The nanotubes can be the single-walled or multi-walled variety. The electrode can be used in numerous electro-machining processes, including electrical discharge machining (“EDM”), electron beam machining (“EBM”), and electro-chemical machining.

Abstract: The present invention reduces the burden of the network having heavier load, maintains the load balance among different networks, and improves the overall resource utilization efficiency and transmission qualities of the networks, by providing a network forwarding apparatus for selectively distributing the IP packets to be forwarded to the network having less traffic for transmission by monitoring in real-time the traffic in the different networks.

Abstract: Methods and devices are provided for the continuous production of a network of nanotubes or other nanoscale fibers. The method includes making a suspension of nanoscale fibers dispersed in a liquid medium, optionally with surfactant and/or sonication, and filtering the suspension by moving a filter membrane through the suspension, such that the nanoscale fibers are deposited directly on the filter membrane as the fluid medium flows through the filter membrane, thereby forming a continuous membrane of the nanoscale fibers. The deposition of the nanoscale fibers can occur when and where the filter membrane moves into contact with a static, porous filter element or a dynamic, porous filter element. The filtering can be conducted within a magnetic field effective to align the nanoscale fibers, and/or with the aid of vacuum to pull water through the filter membrane, applied pressure to press water though the filter membrane, or a combination thereof.

Abstract: Methods are provided for mechanically chopping nanotubes and other nanoscale fibrous materials. The method includes forming a macroscale article which include the nanoscale fibers, and then mechanically cutting the macroscale article into a finely divided form. In one embodiment, these steps are repeated. The nanoscale fibers may be carbon nanotubes, which optionally are aligned in the macroscale article. The macroscale article may be in the form of or include one or more buckypapers. In one embodiment, the macroscale article further includes a solid matrix material in which the nanoscale fibers are contained or dispersed. The forming step can include making a suspension of nanoscale fibers dispersed in a liquid medium and then solidifying the liquid medium to form the macroscale article. After the mechanical cutting step, the medium can be dissolved or melted to enable separation of the chopped nanoscale fibers from the medium.

Abstract: A system for in-situ and on-line monitoring of a preform layup process for liquid composite molding allows for gathering of permeability measurements of a fabric preform for use in a liquid composite molding process after situation of the preform within the mold wherein the molding process is to occur. The system uses a plurality of pressure sensors located within one of the mold sections of the liquid composite molding process mold. The sensors take pressure measurements which are processed to obtain a permeability profile of the preform. From such data, any local permeability variations that are caused from defects in the preform, deformation of the preform, or from mold misfit can be noted and acted upon before resin flow. The system is relatively simple to use and is easy to implement.

Abstract: A system for in-situ and on-line monitoring of a preform layup process for liquid composite molding allows for gathering of permeability measurements of a fabric preform for use in a liquid composite molding process after situation of the preform within the mold wherein the molding process is to occur. The system uses a plurality of pressure sensors located within one of the mold sections of the liquid composite molding process mold. The sensors take pressure measurements which are processed to obtain a permeability profile of the preform. From such data, any local permeability variations that are caused from defects in the preform, deformation of the preform, or from mold misfit can be noted and acted upon before resin flow. The system is relatively simple to use and is easy to implement.