Abstract: A sheet eject device is provided for detecting whether a sheet eject tray is filled with ejected sheets. The sheet eject device includes an ejecting unit that ejects sheets onto the sheet eject tray; a counting unit that counts an accumulated eject number every time a sheet is ejected by the ejecting unit; a storing unit that stores a defined eject number threshold and a defined eject interval time; a fullness detecting unit that detects that the sheet eject tray is filled with ejected sheets when the accumulated eject number counted by the counting unit exceeds the defined eject number threshold; and a reset unit that resets the accumulated eject number counted by the counting unit when an eject interval time exceeds the defined eject interval time, the eject interval time extending from when one sheet is ejected until a next sheet is ejected by the ejecting unit.

Abstract: A sheet processing device comprising: a pressing unit that presses a fold line part of a folded sheet bundle; and a moving unit that moves a pressing position of the pressing unit in a fold direction of the folded sheet bundle, wherein the pressing unit includes a pair of pressing rollers that holds the folded sheet bundle therebetween, and the pair of pressing rollers changes an angle ? between a thickness direction of the folded sheet bundle and a line connecting the rotational centers of the pressing rollers in the middle of movement.

Abstract: A storage apparatus for one or more cleaning lances is provided. The storage apparatus can be utilized in connection with a driving apparatus that controls the cleaning movements of a cleaning lance with respect to certain industrial equipment such as a heat exchanger. The driving apparatus can be utilized to feed an additional length of the cleaning lance to the tubes of exchanger or to retract the cleaning lance from the tubes of the exchanger. The storing apparatus can be utilized to store the cleaning lance, regulate the distribution and movement of the cleaning lance, and prevent tangling or snagging of the cleaning lance during the cleaning process.

Abstract: There is provided an elevator group control system, in which even after an assigned car has been determined, the assigned car can be changed as necessary, and therefore comfortable service can be offered to a user. This group control system includes a call registration device by the use of which a user registers a hall destination call before getting into a car, a car position detection part for detecting the car position of each elevator, and a call registration storage part for storing, for each elevator, a hall destination call having been registered. When a hall destination call having the same contents as those of an already registered hall destination call stored in the call registration storage part is registered newly from the call registration device, if a non-assigned car has already arrived at the floor on which the call registration device is installed, the newly registered hall destination call is assigned to the non-assigned car.

Abstract: In order to increase safety, a computer-implemented method is proposed for determining the position of a lift cabin in a lift shaft with the aid of a coding device, in which method a section of a code band and/or of the bearing device is/are recorded with an optical detection device as a pixel image consisting of pixels, a reference marking analysis is carried out, the pixel image is processed, in particular is assigned to a detection grid, pixels of the pixel image are preferably combined with the aid of their color and/or position in order to be able to read out the barcode and/or 2D code of the marking, the barcode and/or 2D code is converted to a binary code, the binary code is decoded by means of an algorithm and is converted into a position indication and/or into information as to whether a bearing device has been detected.

Abstract: A safety system for a lift installation includes a safety helmet having an integrated person position indicator being a transmitter and/or receiver and an installation position indicator mounted in lift installation, especially in the lift shaft. The indicators cooperate to automatically determine potential risk situations for an engineer wearing the safety helmet such an approaching lift cage or an approaching counterweight. The safety system automatically triggers an appropriate safety function, for example, stopping of the lift cage.

Abstract: An exemplary elevator system includes a first mass that is moveable within a hoistway. A second mass is moveable within the hoistway. A plurality of elongated members couple the first mass to the second mass. At least one damper is positioned to selectively contact at least one of the elongated members if sway occurs. A sensor is associated with the damper. The sensor detects contact between the damper and the at least one of the elongated members. A controller adjusts at least one aspect of elevator system operation responsive to the detected contact.

Abstract: An exemplary elevator system includes an elevator car. A first governor sheave is supported on the elevator car for movement with the elevator car. The first governor sheave is supported for rotational movement relative to the elevator car responsive to movement of the elevator car. A first governor tripping mechanism is supported on the first governor sheave. The first governor tripping mechanism provides an indication to perform a first governor function for controlling the speed of the elevator car responsive to the elevator car moving at a speed above a first threshold speed. A second governor sheave is supported on the elevator car for movement with the elevator car and for rotational movement relative to the elevator car responsive to movement of the elevator car. A second governor tripping mechanism is supported on the second governor sheave.

Abstract: A composite lifting beam and methods are provided. Such a lifting beam includes at least one beam element. A plurality of plate elements are mounted to the at least one beam element and are spaced apart along a length of the at least one beam element. The plurality of plate elements provide a first connection arrangement for connecting the beam to a lifting apparatus, and a second connection arrangement for connecting the beam to a load.

Abstract: A system and method of packaging a bulk material is provided for scooping a quantity of the bulk material into a standard equipment bucket of an excavating or front loader equipment, covering the bucket with a single soft-sided container such that a bottom of the single soft-sided container spans and covers a mouth of the bucket, securing the single soft-sided container over the bucket to close the mouth of the bucket, and inverting the bucket such that the mouth of the bucket is oriented substantially downward to transfer the quantity of the bulk material from the bucket directly into the single soft-sided container.

Abstract: A movement device is configured for moving a payload. The movement device includes a first support, a second support, and an intermediate support. The intermediate support is operatively disposed between the first support and the second support. The intermediate support is jointed to the first support at two first joints and jointed to the second support at two second joints. The second support is configured for supporting the payload. The intermediate support is jointed to the second support at two second joints. The first joints are pivotable about a respective first axis of rotation such that the intermediate support moves relative to the first support. The second joints are pivotable about a respective first axis of rotation such that the second support moves relative to the intermediate support. Each of the first axes of rotation are in spaced and generally parallel relationship to one another.

Abstract: A method of lifting device collision avoidance is disclosed. In one embodiment, the method comprises determining a three dimensional position of a collision avoidance sensor unit coupled with a load line of a first lifting device, the determining performed by a first global navigation satellite system (GNSS) receiver coupled with a housing of the collision avoidance sensor unit, generating a geofence for the first lifting device based at least in part on the collision avoidance sensor unit position, monitoring for a collision related hazard indicated by encroachment between the first geofence and a second geofence associated with a second lifting device and initiating at least one collision hazard avoidance action in response to a monitored occurrence of the collision related hazard.

Abstract: A detector for an electromagnetic brake, for example used in an elevator system, that, by quantitative judgment, determines whether the brake force of the electromagnetic brake is appropriate. Load cells for detecting the recovery forces of brake springs are arranged between brake springs, which energize brake arms with brake shooes installed on them toward the side of brake wheel, and spring sheets, which hold brake springs in a compressive deformed state, and, at the same time, judgment part judges whether the brake force of electromagnetic brake 4 is outside a prescribed normal range based on the outputs of load cells. If the brake force of electromagnetic brake is outside the normal range, judgment part sends a signal, for example to a monitoring center.

Abstract: An apparatus with a wheel engagement mechanism for operation with a jack assembly for engaging and elevating two wheels of a multi-wheeled vehicle relative to the ground is provided. The apparatus includes a base, a support member connected to the base, and a wheel support assembly. The wheel support assembly includes wheel supports connected at the ends of the wheel support assembly that extend outward from the wheel support assembly for supporting two wheels of the vehicle. The apparatus also includes an actuation mechanism for selectively raising and selectively lowering the wheel support assembly to raise and lower the vehicle.

Abstract: A beverage carrying assembly with bottle opener provides a readily accessible bottle opener for opening pop-top bottles. The assembly includes a container having a bottom side and a perimeter wall extending upwardly from the bottom side. The container has an interior space configured to hold a plurality of bottles therein. A bottle opener is coupled to the perimeter wall. The bottle opener comprises a panel and an opening extending from a front side to a back side of the panel. The opening extends through the perimeter wall and has a size configured to receive a bottle cap therein. An upper lip and a lower lip are coupled to the opening and each of the upper and lower lips are configured for receiving a lower edge of the bottle cap such that the bottle cap is removed when upward force is applied to the lower edge of the bottle cap.

Abstract: A method and device for filling containers with a liquid product. The product is fed to the container by a filling valve and a filling nozzle. The product emerging from the filling nozzle is fed to a directing element. The directing element has a geometrical configuration such that an edge of the directing element runs along at a small distance from the inside walls of the container.

Abstract: A portable, insulated, opaque, hot beverage dispenser (40) with a sensor (50), such as a level sensor, and an electronic display (48) is provided with a portable thermoelectric recharging power source (50), a portable photovoltaic recharging source (54), or both, to provide recharging power to a rechargeable power supply (42) which, in turn, provides electrical power to the display (48), a display controller (44) and the sensor power to the level sensor. A thermoelectric generator is mounted within a funnel 51 with a cold side (158) in thermal communication with ambient air outside of the interior (64) of the container body (52) of the dispenser (40) and a hot side (160) in thermal communication with the interior air within the interior (64) is mounted within a funnel (51) fitted into the open top (66) of the container body (52).

Abstract: A bottle pouring dispenser featuring a dispenser housing having a lower end configured to be removably attached to and cover an open end of a bottle. The bottle pouring dispenser includes a valve providing one-way hydraulic communication from the bottle to a chamber defined within the dispenser housing. The dispenser housing has upper and lower chamber portions. A flavorant is disposed within the upper chamber portion in solid form and it is dissolvable in liquid so as to add flavoring to liquid flowing through the chamber. The flavorant is held spaced above a floor of the chamber, such that a lower portion of the chamber defines a drain volume beneath the flavorant for receiving liquid draining from about the flavorant. The bottle pouring dispenser further includes a pour spout extending from an upper end of the dispenser housing, for dispensing the flavored liquid from the chamber.

Abstract: A fluid dispenser comprising a fluid container and a metering unit is disclosed. The container comprises a fluid level sensor and the dispenser comprises a control unit configured to determine a parameter value representative for an amount of fluid in the container after refill on basis of a signal from the sensor. The sensor can for example be configured to generate a signal at a predefined fluid level (B, C), while the control unit is configured to calculate a fluid level on basis of an input value indicative of the fluid level (A) after refill, and a dispense value indicative of amounts of fluid dispensed since the latest refill. The control unit can be configured to compare the signalled predefined fluid level (B, C) with the calculated fluid level to generate a correction factor.

Abstract: The device comprises a connecting pipe (18) having an inlet (18A) capable to be connected to the feed and an outlet (18B) capable to be connected to the storage vat (10), as well as a retaining chamber (20) which branches off from the connecting pipe (18) and which is equipped with a sampling valve (24). The connecting pipe comprises a charging valve (22), located between the retaining chamber and the outlet of the connecting pipe. After the product originating from the feed has been conveyed to the retaining chamber (20), and a sample of the product mixture present in the retaining chamber (20) has been taken to ascertain information relative to the nature of this mixture, and if the ascertained information corresponds to expected information, a charging valve (22) is opened to have the outlet of the connecting pipe (18) communicate with the vat (10).

Abstract: A fueling device includes a fuel passage-forming member and a flap valve mechanism. The flap valve mechanism includes an opening-forming member attached to one end of the fuel passage-forming member and an opening-closing mechanism to open and close a filler inlet of the opening-forming member. The fuel passage-forming member includes a pipe body containing a resin inner layer in a pipe shape made of a first resin material and a resin outer made of a second resin material, and a welding end formed on an opening end of the pipe body. The opening-forming member includes a cover member that covers the opening end of the pipe body and a welded end formed on an opening end of the cover member and welded to the welding end. The cover member is made of a third resin material welded to either one of the first resin material and the second resin material.

Abstract: A system for offloading a fluid from an offshore structure comprises an annular conduit support structure disposed about the offshore structure. The support structure is fixably coupled to the offshore structure. In addition, the system comprises an annular reel disposed about the offshore structure and rotatably coupled to the support structure. The reel includes a conduit fairlead configured to move relative to the support structure. Further, the system comprises a flexible conduit having a fluid inlet end and a fluid outlet end. The flexible conduit includes a first portion wrapped around the conduit support structure and a second portion extending from the conduit support structure through the fairlead.

Abstract: A micro electro-mechanical system (MEMS) microphone is provided. The MEMS microphone is configured to operate at a predetermined range of frequencies. The MEMS microphone has a tensioned membrane preset at a tension amount selected to cause the MEMS microphone to operate at a predetermined sensitivity level that is above a threshold sensitivity level. The tension amount is controlled based on a temperature applied to the tensioned membrane during a fabrication process. At least a portion of the tensioned membrane is sandwiched between a first conductive layer and a second conductive layer configured to equalize stress of the tensioned membrane.

Abstract: A micro electro mechanical device includes: a semiconductor layer; a source/drain region formed on both sides of a channel region within the semiconductor layer; a gate insulating film formed on the semiconductor layer; a cavity formed on the gate insulating film; and a gate electrode formed on the cavity, the gate electrode being movable so as to contact with the gate insulating film. In the device, a pressure applied on the gate electrode is detected by a contact area of the gate electrode and the gate insulating film.

Abstract: A MEMS package structure is disclosed. The MEMS package structure includes a first glass substrate on a micro-electromechanical systems (MEMS) structure, a sealant adhered between the first glass substrate and the MEMS structure; and a first moisture barrier on the sidewalls of the first glass substrate, the sealant, and the MEMS structure.

Abstract: Methods and systems for a reversible top/bottom MEMS package may comprise a base substrate comprising metal traces, an opening through the base substrate, a die coupled to a first surface of the substrate and positioned over the opening, a frame member coupled to the first surface of the substrate wherein the die is positioned interior of the frame member, a cover substrate coupled to the frame member, and conductive plating on the frame member that electrically couples the base substrate to the cover substrate, wherein the conductive plating is exposed. The conductive plating may couple a ground plane in the base substrate to a ground plane in the cover substrate. The conductive plating may be exposed at an outer surface of the frame member and/or at an inner perimeter of the frame member. Conductive vias within the frame member may be coupled to the metal traces in the base substrate.

Abstract: The various embodiments described herein provide microelectromechanical systems (MEMS) sensor devices and methods of forming the same. In general, the embodiments provide MEMS sensor devices formed with two semiconductor die that are bonded together. Specifically, a sensor die includes at least one MEMS sensor fabricated thereon, such as MEMS gyroscope or MEMS accelerometer. A control-circuit die includes at least one integrated MEMS control circuit formed on an active area of the die. The control-circuit die is bonded to the sensor die with the active area and the integrated MEMS control circuits on the exterior side. The bonding defines and seals a cavity between the two die that encompasses the MEMS sensor and can be used to seal the MEMS sensor in a vacuum.

Abstract: An integrated MEMS device and its manufacturing method are provided. In the manufacturing method, the sacrificial layer is used to integrate the MEMS wafer and the circuit wafer. The advantage of the present invention comprises preventing films on the circuit wafer from being damaged during process. By the manufacturing method, a mechanically and thermally stable structure material, for example: monocrystalline silicon and polysilicon, can be used. The integrated MEMS device manufactured can also possess the merit of planar top-surface topography with high fill factor. The manufacturing method is especially suitable for manufacturing MEMS array device.

Abstract: MEMS devices, packaged MEMS devices, and methods of manufacture thereof are disclosed. In one embodiment, a microelectromechanical system (MEMS) device includes a first MEMS functional structure and a second MEMS functional structure. An interior region of the second MEMS functional structure has a pressure that is different than a pressure of an interior region of the first MEMS functional structure.

Abstract: Nano-structure includes a substrate and a non-oxidized portion of a metal layer (having an expansion coefficient, during oxidation, that is more than 1) on the substrate. An oxide layer is formed on the non-oxidized portion. A plurality of metal oxide nano-pillars is grown from the oxide layer. Each nano-pillar is grown through a plurality of pores defined in a template. A space is defined between adjacent nano-pillars. A continuous metal oxide cap layer is over the nano-pillars and over, but not in, the space between adjacent nano-pillars. The cap layer is formed from end portions of the nano-pillars that merge together over a template surface. The cap layer is in contact with all of the nano-pillars. The oxide layer, the nano-pillars, and the oxide cap layer are formed from anodization of portions of the metal layer.

Abstract: Antiproliferative compositions that include CLEFMA, as well as liposomal compositions containing said antiproliferative compositions, are disclosed. Also disclosed are methods of making and using the antiproliferative compositions and liposomal compositions.

Abstract: The present invention provides a system and method for diagnosing, monitoring, prognosing or staging Parkinson's disease using at least one sensor comprising carbon nanotubes coated with cyclodextrin or derivatives thereof or metal nanoparticles coated with various organic coatings in conjunction with a learning and pattern recognition algorithm.

Abstract: A system and method for creating three-dimensional nanostructures is disclosed. The system includes a substrate bonded to a carrier using a bonding agent. The bonding agent may be vaporizable or sublimable. The carrier may be a glass or glass-like substance. In some embodiments, the carrier may be permeable having one or a plurality of pores through which the bonding agent may escape when converted to a gaseous state with heat, pressure, light or other methods. A substrate is bonded to the carrier using the bonding agent. The substrate is then processed to form a membrane. This processing may include grinding, polishing, etching, patterning, or other steps. The processed membrane is then aligned and affixed to a receiving substrate, or a previously deposited membrane. Once properly attached, the bonding agent is then heated, depressurized or otherwise caused to sublime or vaporize, thereby releasing the processed membrane from the carrier.

Abstract: The present invention relates to an apparatus for generating hydrogen gas using a composition for generating hydrogen gas, which generates hydrogen gas (H2) from water (H2O) through spontaneous thermochemical reaction without supplying electricity using a composition for generating hydrogen gas which generates the hydrogen gas by spontaneous oxidation with water at room temperature.

Abstract: The invention relates to a process for parallel preparation of hydrogen and one or more carbonaceous products, in which hydrocarbons are introduced into a reaction space (R) and decomposed thermally to carbon and hydrogen in the presence of carbon-rich pellets (W). It is a feature of the invention that at least a portion of the thermal energy required for the hydrocarbon decomposition is introduced into the reaction space (R) by means of a gaseous heat carrier.

Abstract: A process for producing hydrogen from natural gas, said process comprises the steps of: (i) providing an autothermal heat exchanger packed-bed membrane reformer (APBMR) comprising: (a) an elongated external gas oxidation compartment comprising an inlet, an outlet and packed oxidation catalyst particles, said inlet and outlet being located each at one extremity of said external gas oxidation compartment; (b) an elongated internal gas steam-reforming compartment comprising an inlet, an outlet and packed steam-reforming catalyst particles, said inlet and outlet being located each at one extremity of said internal gas steam-reforming compartment; (c) one or more hydrogen-separating membrane(s) positioned in said steam-reforming compartment substantially parallel to the longitudinal axis of said steam-reforming compartment; (d) one insulation layer surrounding said external compartment; and, optionally, (e) one or more elongated internal gas oxidation compartment(s) positioned in said steam-reforming compartment s

Abstract: A method of preparing Group XIII selenide nanoparticles comprises reacting a Group XIII ion source with a selenol compound. The nanoparticles have an MxSey semiconductor core (where M is In or Ga) and an organic capping ligand attached to the core via a carbon-selenium bond. The selenol provides a source of selenium for incorporation into the semiconductor core and also provides the organic capping ligand. The nanoparticles are particularly suitable for solution-based methods of preparing semiconductor films.

Abstract: A method for producing nitrogen gas from a raw material gas using a PSA system, the method including using a second adsorbent, which is packed in an auxiliary adsorption tank provided in a line connecting two main adsorption tanks packed with a first adsorbent, to reduce the oxygen concentration within a recovered gas discharged from the main adsorption tank performing a depressurization equalization step, and then introducing the gas into the main adsorption tank performing a pressurization equalization step.

Abstract: A plurality of mesoporous metal nitride materials may be formed by a method that includes treating with ammonia (or a related bonded nitrogen and hydrogen containing reducing material) a mixed metal oxide material that comprises at least one first metal that forms an unstable product with ammonia and at least one second metal that forms a stable product with ammonia to form the metal nitride materials that include the second metal but not the first metal. The method contemplates forming metal nitride materials, as well as metal oxynitride materials. A related method that uses a non-bonded nitrogen and hydrogen containing reducing material may yield a mesoporous metal oxide. In particular the at least one metal that forms an unstable product with ammonia comprises zinc metal.

Abstract: The present invention relates to a specific process for producing trisilylamine from monochlorosilane and ammonia in the liquid phase. The invention further relates to a plant wherein such a process can be carried out with advantage.

Abstract: A method for making carbon nanotube composite wire includes providing a carbon nanotube array. A carbon nanotube film is drawn from the carbon nanotube array using a tool. The carbon nanotube film is treated using a graphene solution to obtain a carbon nanotube composite wire.

Abstract: Apparatus to produce carbon nanotubes (CNTs) of arbitrary length using a chemical vapor deposition (CVD) process reactor furnace is described, where the CNTs are grown axially along a portion of the length of the furnace. The apparatus includes a spindle and a mechanism for rotating the spindle. The spindle located within a constant temperature region of the furnace and operable to collect the CNT around the rotating spindle as the CNT is grown within the furnace.

Abstract: A process for producing a graphitic film comprising the steps of (a) mixing graphene platelets with a carbon precursor polymer and a liquid to form a slurry and forming the slurry into a wet film under the influence of an orientation-inducing stress field to align the graphene platelets on a solid substrate; (b) removing the liquid to form a precursor polymer composite film wherein the graphene platelets occupy a weight fraction of 1% to 99%; (c) carbonizing the precursor polymer composite film at a carbonization temperature of at least 300° C. to obtain a carbonized composite film; and (d) thermally treating the carbonized composite film at a final graphitization temperature higher than 1,500° C. to obtain the graphitic film.

Abstract: A re-forming process is carried out in which a material graphite film is heat-treated to not less than 2000° C. while the material graphite film is being pressured. Through the re-forming process, sag of a graphite film is controlled. By using, during the re-forming process, a plurality of inner cores having respective different surface states, it is possible to produce a graphite film having two or more sag forms which have respective effects.

Abstract: A method for manufacturing a graphene layer includes performing a sputtering process to form a graphite layer on a substrate, and performing a lithography process on the graphite layer for thinning the graphite layer and thereafter making the graphite layer thinned to become a graphene layer.

Abstract: Methods of fabricating graphene using an alloy catalyst may include forming an alloy catalyst layer including nickel on a substrate and forming a graphene layer by supplying hydrocarbon gas onto the alloy catalyst layer. The alloy catalyst layer may include nickel and at least one selected from the group consisting of copper, platinum, iron and gold. When the graphene is fabricated, a catalyst metal that reduces solubility of carbon in Ni may be used together with Ni in the alloy catalyst layer. An amount of carbon that is dissolved may be adjusted and a uniform graphene monolayer may be fabricated.

Abstract: A copper foil for producing graphene including Cu having a purity of 99.95% by mass or more.

Abstract: The physical properties of a diamond are altered by: applying a cationic elemental plasma to a diamond at a plasma temperature of less than 300° C.; allowing the cationic plasma to chemically bond with atoms in defects within the diamond; and removing the plasma from the diamond. The cationic elemental plasma may exemplary be selected from the group consisting of as H+, Na+, Li+ and K+. It is preferred that no plasma is projected from a source at the diamond and that the plasma is provided as an environment surrounding the diamond.

Abstract: By controlling the pre-treatment of biomass materials and pyrolysis conditions, silica samples with various surface areas and levels of crystallinity were synthesized. With proper treatment, biogenic silica nanoaggregate (25-30 nm in diameter) can be synthesized from biomass materials. The characterizations revealed that the silica nanoaggregates were composed of smaller primary silica nanoparticles (ca. 4.2 nm in diameter). Under controlled melting catalyzed by metal salt cations, the silica nanoaggregates may be fuse to form semi-crystalline porous silica frameworks with tunable pore size and structural integrity. Organosilicon complexes were synthesized from the bio derived silica nanoaggregates.

Abstract: Precipitated silicas including clusters of large primary silica particles having at the surface thereof small primary silica particles, have a specific surface area CTAB (SCTAB) ranging from 60 to 400 m2/g; a cluster average size d50, as measured by XDC grading after ultrasound deagglomeration, such that d50 (nm)>(6214/SCTAB (m2/g)+23; a pore volume distribution such that V(d5-d50)/V(d5-d100)>0.906?(0.0013×SCATB (m2/g)); and a pore size distribution such that Mode (nm)>(4166/SCTAB (m2/g))?9.2; such silicas are useful reinforcing fillers for polymers.