Abstract: A puncture repair kit includes a container configured to house puncture repair liquid; a hose configured to be connected to the container and carry the puncture repair liquid into a tire; a compressor configured to supply compressed air for supplying under pressure the puncture repair liquid in the container through the hose; and an assistor configured to correct a tilt of the container when the container is connected to a tire valve via the hose and pendent from the tire valve.

Abstract: The present invention relates to a method of introducing nitrogen into a beverage container. The beverage container (10) includes a cylindrical neck part (16) having a circumferential rim (18) defining an opening (20). The cylindrical neck part includes an outer circumferential flange (22) encircling the cylindrical neck part. A connecting element (36) having a circular closure plate (64) and a cylindrical housing (54) having a set of inwardly oriented locking parts (56) is positioned such that the cylindrical housing is at least partially covering the cylindrical neck part and a fluid path (58) is defined between the connecting element and the cylindrical neck part. A collar (42, 44) having a gas inlet (48) is placed about the cylindrical neck part and gas is injected into the beverage container via the gas inlet.

Abstract: A filling device includes a product space that ends in a filling valve with first and second valve elements disposed in a region thereof and moved by an actuator, a sealing face, a valve stem, a valve housing having a reduced-diameter edge, and a profiled plastic sleeve that runs over the reduced-diameter edge. One of the valve elements has a plastic lining. A valve stem forms one of the valve elements and the valve housing forms the other.

Abstract: A fuel tank system, comprising: a fuel tank configured to store a liquid fuel and a pressurized gaseous fuel capable of partially dissolving in the liquid fuel; a refueling conduit coupled to the fuel tank via a tank access valve; a first high pressure refueling port coupled to the refueling conduit; a low pressure refueling port coupled to the refueling conduit via a check valve. In this way, pressurized gaseous fuel or a pre-pressurized mix of fuels may be added to the fuel tank without active control any time the fuel pressure in the fuel tank is below a maximum allowable pressure, and liquid fuel may be added to the fuel tank with active control whenever the fuel pressure and liquid fuel level in the fuel tank are below threshold levels.

Abstract: An air flow controller for a pneumatically operated watercraft lift has a valve for opening and closing the air line to the pontoon and a manifold with a gate. The gate is biased to a first orientation in which air from the pontoon can be exhausted only to the atmosphere when the lift blower is switched “off.” When the blower is switched “on,” air flow from the blower moves the gate into a second orientation in which the blower can force air only into the pontoon. This configuration prevents flow of water into the blower during lowering of the pontoon while using relatively few and simple valve system components.

Abstract: A filler element includes a housing, a channel formed therein, a valve in the channel, an opening downstream from the valve that dispenses content into a container when the valve is open, a tube for fill-level adjustment, a controlled gas channel, and a collection space. The tube, which adjusts a fill level of content in the container, projects past the dispensing opening and extends into an interior of the container during filling thereof. This tube connects to a collection space separated from a content vat from which the content comes through the channel. To adjust the desired fill level, a gas pressure is applied to the interior through the tube, thereby displacing excess content from the container. The controlled gas channel permits the gas to enter the container interior.

Abstract: A fluid supply system adapted for vacuum and pressure cycling of fluid, including a transfer vessel adapted to supply a process canister with fluid drawn from a bulk canister under a vacuum, wherein delivery of fluid from the transfer vessel to the process canister is accomplished with positive pressure. A method is also disclosed of delivering fluid, including drawing fluid under vacuum from a bulk canister and pressurizing the transfer vessel to effect dispensing of the fluid into a process canister for delivery to a location of use.

Abstract: A filling device (2) for filling containers (10) with a liquid and in particular a beverage, including a first port (32) in order to supply a first liquid to the filling device (2), a second port (34) in order to supply a second liquid to the filling device (2), with the first port (32) and the second port (34) being spaced from one another, with a mixing chamber (42) formed within the filling device (2), in which the liquids may be mixed, including a first liquid channel (44) which guides the first liquid from the first port (32) to the mixing chamber (42), a second liquid channel (44) which guides the second liquid from the second port (34) to the mixing chamber (42), wherein the first liquid channel (55) and the second liquid channel guide the first liquid and the second liquid separately from one another, and a valve body (56) for controlling the discharge of the liquids from the filling device, and with an outlet (34) for discharging the liquids to the container.

Abstract: A cap unit is provided with: a cap body having a first flow channel for feeding the compressed air from a compressor into a bottle container, and a second flow channel for sequentially taking out a puncture repair agent and the compressed air from the bottle container; and a first and second inner lids which are independent from one another and which close the first and second flow channels. The cap body has a boss portion extending upward from the bottom surface of a mouth portion securing recess, and provided with a first inner lid securing portion. The first inner lid is fitted into the first inner lid securing portion The upper opening portion of the first flow channel opens further inward than the first inner lid securing portion, and the upper opening portion of the second flow channel opens further outward than the first inner lid securing portion.

Abstract: The present invention is capable of reducing the precision requirements when fitting a cap unit while ensuring the opening and closing of a first and second path. A cap unit (1) is provided with: a cap body (7) having a first flow channel (5) for feeding the compressed air from a compressor (3) into a bottle container (4), and a second flow channel (6) for sequentially taking out a puncture repair liquid (T) and the compressed air from the bottle container (4); and first and second closing plugs (8A, 8B) which are independent from one another and which close the first and second flow channels (5, 6). The cap body (7) has a boss portion (11) on which a first closing plug securing portion (11A) permitting elastic fitting of the first closing plug (8A) is disposed.

Abstract: A system to fluidize and convey finely divided particulate matter comprises a container with a top and bottom portion separated by a pan with apertures there through and a hatch to receive a volume of particulate matter into the container to be supported on the pan. The pan is funnel-shaped and has a discharge port at the lowermost portion of the pan. A bridging conveyor tube receives fluidized flow of the particulate matter from the discharge port and conveys the matter to a riser conveyor tube, which elevates the fluidized flow to a receiving bin remove from the container. The bridging conveyor tube and the riser conveyor tube receive gas streams provided through apertures from a bridging gas passage and a riser gas passage, respectively, to sustain fluidized flow from the discharge port of the pan to the receiving bin to minimize the air required to convey the matter.

Abstract: A filling system has a filling apparatus (200) and a container arrangement inserted into the filling apparatus. A main line includes a feed line (102), connected to a supply container (304), and a trunk line (104), connected linearly downstream of the feed line (102). Outside the trunk line (104), at a branching point (114), a branch line (116) branches from the main line (102) to a compressed-gas source (306), and the main line (102) and the branch line (116), on that side of the branching point (114) which is directed away from the trunk line, pass through a double-valve arrangement (214) having two hose-clamping valves (214a, 214b) controlled oppositely to one another.

Abstract: A dispensing device for a flowable, in particular powdery product, includes at least one screw conveyor discharging the product, a drive for rotating the screw conveyor about its longitudinal axis, and a forming tube for guiding a tubular film. The screw conveyor protrudes with its longitudinal axis into the forming tube, wherein at least one screw guide, in which the screw conveyor is guided transversally to its longitudinal axis, is formed by the inner wall of at least one cylindrical recess in the forming tube.

Abstract: Methods for loading a compressed fluid into and discharging the compressed fluid out of containment are provided. Compressed fluid is injected into a bottom portion of a container system for storage and/or transport until a target pressure is reached after which gas is withdrawn from an upper portion of the container system at a rate to maintain the target pressure while the compressed fluid is injected in the bottom portion. The compressed fluid is cooled through an expansion valve and by refrigerated chillers or by injecting a cold liquid of the same chemical composition as the compressed fluid into the compressed fluid prior to injection into the container system. Discharge from the container system to a receiving facility begins with blow down from the bottom portion of the container system without a displacement fluid and continues until pressure falls below an acceptable differential pressure.

Abstract: Embodiments disclosed herein generally relate to an HVPE chamber. The chamber may have two separate precursor sources coupled thereto to permit two separate layers to be deposited. For example, a gallium source and a separate aluminum source may be coupled to the processing chamber to permit gallium nitride and aluminum nitride to be separately deposited onto a substrate in the same processing chamber. The nitrogen may be introduced to the processing chamber at a separate location from the gallium and the aluminum and at a lower temperature. The different temperatures causes the gases to mix together, react and deposit on the substrate with little or no deposition on the chamber walls.

Abstract: The invention relates to systems and methods for filling a medical device with an active agent composition. In an embodiment, the invention includes a method for filling a medical device with an active agent composition. The method can include applying the active agent composition to the outside surface of the medical device, the medical device comprising a housing defining a lumen and a plurality of apertures. The method can also include contacting a surface of a press member against the outside surface of the medical device thereby pushing the active agent composition through the apertures and into the lumen of the medical device. Other embodiments are also included herein.

Abstract: A beverage bottling plant having a filling machine with multiple beverage filling elements, a filling machine with multiple beverage filling elements, a filling element and related method. The abstract of the disclosure is submitted herewith as required by 37 C.F.R. §1.72(b). As stated in 37 C.F.R. §1.72(b): A brief abstract of the technical disclosure in the specification must commence on a separate sheet, preferably following the claims, under the heading “Abstract of the Disclosure.” The purpose of the abstract is to enable the Patent and Trademark Office and the public generally to determine quickly from a cursory inspection the nature and gist of the technical disclosure. The abstract shall not be used for interpreting the scope of the claims. Therefore, any statements made relating to the abstract are not intended to limit the claims in any manner and should not be interpreted as limiting the claims in any manner.

Abstract: Filling element for filling bottles or similar containers with a liquid filler, comprising a liquid channel which is formed in a filling-element housing and which has a connection for delivery of the liquid filler into the liquid channel and has a discharge opening for discharging the liquid filler into a container that is to be filled, and comprising at least one liquid valve, which is arranged in the liquid channel and controls the discharging of the liquid filler, said liquid valve having a valve body provided on a gas tube that can be moved in a controlled manner in a filling-element axis in order to open and close the liquid valve and that acts as valve plunger.

Abstract: A filling element for filling a container includes a liquid channel configured in a filling element housing, a connector or inlet for feeding the liquid into the channel, a discharge opening for discharging the liquid into the container, and a liquid valve that controls liquid discharge into the container. The liquid valve is arranged in the channel and includes a valve seat and valve body movable to open and close the valve to engage the seat, and an insert configured as a swirl body or gas barrier. The insert is arranged, relative to a flow direction, upstream of the seat and is fixed in position in the channel so that it remains stationary relative to the valve body during opening and closing of the liquid valve.

Abstract: The present invention relates to a device for packaging bulk material such as milk powder, comprising a dispensing unit for dispensing the bulk material into a package, means for supplying the bulk material to the dispensing unit and means for emitting a gas, such as CO2 or a gas mixture of nitrogen and CO2, during the packaging. The device is further provided with means for emitting a gas for driving oxygen out of the package before dispensing of the bulk material. The invention further relates to a method for packaging a bulk material.

Abstract: The method provides: a first step, in which a radioactive fluid is conveyed from a source to a container; a second step, during which inert gas under pressure is conveyed towards the container; and a third step, during which, due to the action of the inert gas, the radioactive fluid is conveyed from the container to a bottle.

Abstract: Methods for loading a compressed fluid, such as natural gas, into and discharging the compressed fluid out of containment are provided. The compressed fluid is injected into a bottom portion of a container system for storage and/or transport until a target pressure is reached after which gas is withdrawn from an upper portion of the container system at a rate to maintain the target pressure while the compressed fluid is injected in the bottom portion. The compressed fluid is cooled through an expansion valve and by refrigerated chillers or by injecting a cold liquid of the same chemical composition as the compressed fluid, such as liquid natural gas, into the compressed fluid prior to injection into the container system. Withdrawal or discharge from the container system to a receiving facility begins with blow down from the bottom portion of the container system without a displacement fluid and continues until pressure falls below an acceptable differential pressure.

Abstract: A tool for refilling an implantable pump having at least one reservoir. The tool includes a plurality of independent fluid channels; a fluid reservoir in fluid communication with a first one of the fluid channels; at least one pump fluidly coupled to the fluid channels, the at least one pump and the independent fluid channels differing from each other in number, wherein (i) a pump is configured to apply positive pressure to the first fluid channel so as to drive fluid from the fluid reservoir therethrough, and (ii) a pump is configured to apply negative pressure to the second fluid channel; and a connector for removably connecting the fluid channels to the at least one reservoir.

Abstract: Embodiments of the present invention provide thermoplastic hoses for an airborne vehicles. The hoses have an inner layer comprised of polyamide and an external layer of polyamide, and the hose is configured to allow the hose to both operate safely under pressures below 55 psi and withstand internal pressures of at least 15 pounds per square inch, and in specific embodiments, at least about 165 pounds per square inch. Specific embodiments of the hoses described are particularly useful on-board helicopters and smaller aircraft.

Abstract: A device for dividing up a volume of liquid contained in an original container by filling bottles that are smaller than the original container, including a source of pressurized gas, a first line running from the source of pressurized gas and opening into the original container so as to place it under pressure, and a line for withdrawing the contents of the original container, connecting the latter to one of the smaller bottles. A second line runs from the pressure source and ends in the smaller bottle to be filled. Means are provided for closing and opening the first and second lines and a member is provided for activating the means for closing/opening so as to open the second line then the pressurization line in sequence, and close these same lines in sequence in the reverse order.

Abstract: An apparatus for repairing and/or inflating a damaged and/or deflated inflatable article, includes a first container (1) for receiving and retaining for dispensing a sealant composition, a second container (100) which has housed thereon a compressor assembly which is releasably connectable to the first container (1), and means (200) allowing for controlled dispensing of the sealant composition from the first container (1) to the inflatable article, the said compressor assembly includes a housing (201) for a compressor which defines, with the interposition of valve means (200) a seating for the first container (1). The valve means (200) includes a main body portion which, in use, is releasably connected to neck portions of both the first and second containers (1,100). The valve means (200) includes passageways (203, 220) to be connected, via hoses (205, 223) to the first container (1) and inflatable article respectively.

Abstract: Methods and devices are provided for transfer of particulate material, such as biomass feedstocks, into and out of pressurized reactors. Improved sluice devices have an L-shaped sluice chamber having an upper, vertical component in communication with a horizontal loading chamber and a lower component in communication with a vertical reactor inlet or outlet. Piston valves seal the sluice inlet and outlet by axial displacement across the vertical component of the sluice chamber and across the vertical reactor inlet or outlet. Relative to other methods for reactor unloading, these devices consume less steam and significantly reduce furfural content of unloaded, pretreated biomass. An optional hybrid plug/sluice method of biomass feeding using the devices permits biomass loading at sluice pressures intermediate between atmospheric and reactor pressure, thereby reducing “pump cycle” time and increasing biomass throughput capacity.

Abstract: An automated workstation (10) for the preparation, from different substances, each of which is contained in a vessel, of a final product for medical or pharmaceutical use packaged in a container, includes at least an isolated chamber (16) which delimits different internal functional areas, a loading area (18) including rapid decontamination elements, a lock device for introducing the vessels and containers into the loading area (18), an area (20) for storing the filled vessels and containers which communicates with the loading area (18), a transfer area (24), an area (22) for preparing the final products which communicates at least with the storage area via the transfer area, and which includes the rapid decontamination elements, a lock device (26) for unloading the final products from the workstation; and at least one robot or one programmable logic controller for handling the objects contained in the storage area and/or in the preparation area.

Abstract: The present invention describes methods and systems of oxygen transfill that includes the step of delivering a quantity of liquid oxygen to an evaporation chamber in a liquid oxygen evaporation device. Next, at least a portion of the liquid oxygen in the evaporation chamber is evaporated and a quantity of gaseous oxygen is maintained at a predetermined pressure level in the evaporation chamber. The method includes filling a portable compressed oxygen device with at least a portion of the gaseous oxygen.

Abstract: A device for handling containers of a collapsible type, including one or more stations and a transport unit. The device is arranged to receive the containers oriented in a first direction and the transport unit is arranged to transport the containers to at least one of the stations by moving the containers in a second direction along a curved path, the second direction being perpendicular to the first direction. The device has a holding device provided for at least one station and located in a stationary position adjacent to the station and a transfer device, which is provided for the at least one station and carried by the transport unit and which is cyclically movable along an endless path between a pick-up position and a delivery position located adjacent to the station. The transfer device is arranged to pick up at least one container in the pick-up position and transfer the at least one container, in the delivery position, to the holding device.

Abstract: A particulate feed arrangement used in pulverized coal gasification under pressure is provided. The arrangement includes a reservoir for stocking the pulverized coal, a plurality of powder injection tubes, and a metering unit. Pure carbon dioxide is fed to the components that are at operating pressure, namely the power injection tube and the metering unit, as the inerting and flow medium or fluidizing medium. The carbon dioxide-carrying components are heated in such a manner that the temperature is above the threshold of the diphase range. A method is also provided. The method allows elimination of any nitrogen in the product gas, which nitrogen is caused by the powder injection system, especially when used in pulverized coal gasification under pressure to produce a synthesis gas for the production of different hydrocarbons.

Abstract: Vehicle tires are filled with perfluorocarbon gas to extend tire life.

Abstract: An aseptic filling device for filling carbonate beverages capable of decreasing the size of the clean booth, facilitating maintenance around the filling valve, and reliably sterilizing the interior of gas piping is provided. The aseptic filling device includes a plurality of filling valves, a fluid rotary joint, a filling fluid tank, a fluid surface level sensor, a fluid flow adjustment valve, a container gripper, a plurality of exhaust conduits, an exhaust conduit on/off valve, a plurality of counter gas conduits, a counter gas conduit on/off valve, a rotary joint, an ascetic gas conduit, a flow meter, and a sterilizing filter, wherein rotary conveyed containers contact at least one of the filling valves and are sealed by a sealing member. Filling is performed under a gas pressure, for example, carbon dioxide gas pressure, and a sterilizing filter for sterilizing the gas is mounted on a gas pipe connecting the rotary joint and the filling fluid tank.

Abstract: A connector apparatus for connecting an air supply unit and a mattress or cushion.

Abstract: An LNG supply system may include first and second LNG tanks, a connecting line connecting the first LNG tank with the second LNG tank and in which a time relay valve is disposed, a charging line one side of which is connected to a fuel supply portion and the other side of which is connected to the first LNG tank for charging fuel, a vent line, one side of which is connected to the second LNG tank and the other side of which is open, a direct line connecting the first LNG tank and the second LNG tank, and a supply line branched from one side of the connecting line to supply an engine with LNG, wherein the time relay valve is opened for a predetermined period so as to equalize the amount of LNG that is charged in the first LNG tank and the second LNG tank.

Abstract: An in-vehicle hydrogen storage apparatus has a hydrogen gas filling passage connected from a hydrogen gas filling port up to the storage device that stores a hydrogen gas to be supplied to a fuel cell, and an odorizing agent supplying device that supplies an odorizing agent to hydrogen gas in at least one of the inside of the storage device and the inside of the hydrogen gas filling passage.

Abstract: A method and apparatus to remove vapor from a storage tank comprising introducing a stream of gas into the storage tank to cause mixing of the vapor within the tank. The stream of gas is preferably introduced into the storage tank through a gas nozzle that increases the velocity of the gas. Furthermore, the gas nozzle may have a fixed or variable orientation that introduces the stream of gas to flow into a region of the storage tank to prevent retention of the vapor in that region. A mixture of the vapor and the gas is withdrawn from the storage tank through an outlet port and provided to an abatement unit, such as a condenser or burner. Where the abatement device is a condenser, the gas and any uncondensed vapor may be returned to the storage tank through the gas nozzle, or through a second gas nozzle.

Abstract: A nozzle for accelerating filling a container with gas up to a required gas pressure including a barrel having venturi openings in a side of said barrel and a sleeve that, in one position uncovers the tunnels and in another position, closes off the openings. In another version the nozzle further includes a pressure chamber, having a wall coupled to the sleeve. In a contracted position the sleeve is moved by the wall of the chamber to close off the tunnels. In another position of the wall where the chamber is in an expanded position the tunnels are so as to increase the rate of flow.

Abstract: In a breather system for a fuel tank having a tank body, a fuel supply port opened and closed by a fuel cap provided in a central portion of an upper wall of the tank body, wherein an upper end of a breather pipe is located to face a central portion of a fuel supply port. When the fuel supply port is closed by the fuel cap, a breather chamber is formed in the fuel cap and the breather chamber communicates with the breather pipe. Thus, when the fuel tank is inclined, fuel is prevented from entering the breather pipe, and the fuel supply port is not immersed in the fuel, thereby maintaining the sealability of the fuel supply port.

Abstract: A broad crystal display panel having a color filter substrate is supported by supporting nails and the middle portion of a supporting span is pressed by a loading bar. From this state, the supporting nails are removed to release the supporting, and subsequently the supporting nails are also removed to release the supporting the color filter substrate. While preventing the displacement between the color filter substrate and a TFT array substrate, the color filter substrate and the TFT array substrate can be stacked with a specified distance.

Abstract: A pump is capable of inflating and deflating an inflatable object. The pump includes a cylinder, a piston and a nozzle. The cylinder defines an outlet through which air can only flow into the cylinder and an inlet through which air can only flow from the cylinder. The piston reciprocates in the cylinder. The nozzle defines a first hole for communication with the inflatable object and a second hole for communication with the exterior. The nozzle is rotationally mounted on the cylinder between an inflating mode and a deflating mode. In the inflating mode, the first hole is communicated with the outlet, and the second hole with the inlet. In the deflating mode, the first hole is communicated with the inlet, and the second hole with the outlet.

Abstract: A lightweight carbon fiber air/gas supply vessel storing high pressure air/gas. The air/gas supply vessel output is controlled by an adjustable pressure reduction valve which varies output pressure from very high to low pressure levels. An alternative multi-valve system uses a first pressure reduction valve to reduce output pressure from the very high levels in the air/gas supply vessel to an intermediate pressure level, and a second pressure reduction valve that reduces the air/gas pressure from the intermediate level to a fine tunable low pressure level. In both embodiments, the output of the last pressure reduction valve used is connected to a high pressure cable which in turn uses a standard universal fitting which can be coupled to most pneumatically powered equipment. Additional high pressure reservoir vessels can be used to replenish the lightweight air/gas supply vessel when its supply of air/gas is depleted.

Abstract: A method in which large-volume gas containers, for example, airships having a gas holding capacity of, for example, 400,000 m3, can be filled with a process gas, includes first completely filling the container with an auxiliary gas, the density of which differs from that of the process gas. The process gas is then quiescently introduced into an upper area of the gas container in such a way that no significant mixing with the air occurs and, at the same time, the auxiliary gas is removed by suction from the lower area of the gas container. To purify the contents of the gas container, purified or fresh process gas is quiescently introduced into the upper area of the gas container in such a way that no significant mixing with the contaminated process gas present in the gas container. At the same time, the contaminated process gas is removed by suction from the lower area of the gas container. To empty the gas container, the above-described process is reversed.

Abstract: A gas cylinder charging system includes (1) at least two gas inlet ports and (2) at least two gas outlet ports, (3) a gas compressor having an input port and an output port, where the input port selectively receives gas from a gas inlet port and selectively transfers the gas to a gas outlet port, and (4) a controller, receiving status signals and transmitting control signals, and connected to and controlling the gas compressor. A method aspect of filling a gas cylinder using the described cylinder charging system further including an input/output selector valve for selecting one of the gasses to transfer to the gas cylinder, includes the following steps. A gas cylinder is connected to one of the cylinder connectors. A user manipulates the selector valve selecting the gas to be transferred to the gas cylinder and activates the cylinder charging system filling the gas cylinder with the selected gas.

Abstract: A liquid aerating apparatus—in combination with a cylinder containing gas under pressure (53); a cylinder holder (30) for retaining a pressure gas cylinder; an aerating (61) head for retaining a bottle (63) which contains a liquid to be aerated; an intermediate chamber (38), for receiving gas discharged from the cylinder (531); a cylinder valve (32) for normally preventing discharge from the cylinder into the chamber and permitting it when desired; valve actuating means (17′) which have an inactive position, in which they do not act on the cylinder valve, and an active position, in which they cause the cylinder valve to be opened and gas to be discharged from the cylinder to the intermediate chamber; gas conduit mans (20 connecting the intermediate chamber with the aerating head; and auxiliary valve means (39) for sealing off the intermediate chamber from the conduit means when the cylinder valve is not fully closed and the valve actuating means are in the inactive position.

Abstract: A gas filling apparatus for gas shock absorber comprises the assembly location correction unit, a gas filling unit, wherein the gas filling unit includes a rod chucking unit, a calking jig, an oil seal pushing unit, and a jig housing. A gas filling method for gas shock absorber comprises the steps of correcting the assembly location of the tube assembly and the rod guide, clamping the base shell assembly; lowering the gas filling unit primarily, lowering the rod chucking unit, lowering the collet housing device; letting the oil seal break away, filling the gas, lowering the gas filling unit secondarily and simultaneously calking primarily, and calking secondarily the base shell assembly. The apparatus and the method need not punch a hole for filling the gas at a circumference of the base shell assembly when filling the gas into a base shell assembly of the gas shock absorber.

Abstract: Apparatus for the recovery of an inert gas, preferably for the recovery of CO2, for use in counterpressure filling machines, the filling elements of which—prior to introduction of a liquid filling material into a container—evacuate this container and at least prepressurize this container with an inert gas under pressure from the pressurizing gas distribution channel:and which elements, during the subsequent introduction of a filling material, conduct the inert gas containing return gas displaced from a corresponding container into a return gas collection channel, wherein a first evacuation system is provided with which the air can be removed from the bottle, and then there is carried out a prepressurizing of the bottles using an inert gas; and a second independent evacuation system is provided with which can be removed and collected, independently of the first evacuation, the inert gas that is being removed by suction.

Abstract: A device for program-controlled variation of the composition of a gaseous mixture for inflating a tire for performing the method, comprising a first source of at least one main gas, a second source of at least one additional gas, at least one first compressor suitable for compressing to a preset pressure a gaseous mixture of at least said main gas and additional gas, at least one dispenser of compressed mixture which is connected to the delivery of said compressor, and further comprising at least one mixer for said at least one main gas and said at least one additional gas which is suitable for delivering a gaseous mixture having a desired composition, a gas analyzer means arranged downstream of said mixer, valve means for controlling the flow between said mixer and said first and second gas sources, and program control means arranged to control said valve means in response to control signals from said analyzer means.

Abstract: A process of bulk filling containers which includes the steps of arranging a number of containers upside down in a tray (24) that has a raised peripheral lip (26). This tray full of containers is then placed in a vacuum chamber (28) which is then evacuated to a predetermined level below atmospheric pressure. Liquid (36) is then introduced into the tray through a reservoir (38) and conduit (40) which penetrates the wall of the vacuum chamber and the vacuum within the chamber is gradually released at a rate that draws the liquid into the containers. At this point in the process unwanted liquid is rinsed away and the tray is removed from the chamber and turned right side up. The final step is to seal the top of the containers with an appropriate cap, barrier, tip or connection. A second embodiment adds a step to the process by positioning the containers upside down in a rack (74) and positioning the rack directly above the tray containing the liquid.

Abstract: A balloon-inflating device capable of mixing a multiple type of gases, which includes a body having an air-inlet cavity and a compression cavity; at least one air pump mounted to the body to pump air from the air-inlet cavity to the compression cavity; at least an air nozzle mounted to the body and having an air-inlet connected to the compression cavity, wherein the nozzle is provided with a stopper to seal the air-inlet in normal operating condition; at least a second gas supply valve having an air-outlet connected to the air nozzle and having an air-inlet connected to a second gas supplier; and a control device for controlling the operation of the air pump and the second gas supply valve, thereby the opening and closing of the air pump and the second gas supply valve inflate a balloon with either air or a second gas, or a mixture of the compressed air of the air pump and the second gas.