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WO1996034642A1 - Distributeur de matiere particulaire - Google Patents

Distributeur de matiere particulaire Download PDF

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Publication number
WO1996034642A1
WO1996034642A1 PCT/GB1996/001085 GB9601085W WO9634642A1 WO 1996034642 A1 WO1996034642 A1 WO 1996034642A1 GB 9601085 W GB9601085 W GB 9601085W WO 9634642 A1 WO9634642 A1 WO 9634642A1
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WO
WIPO (PCT)
Prior art keywords
dispenser
gas
particulate
column
mesh
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Ceased
Application number
PCT/GB1996/001085
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English (en)
Inventor
Andy Briggs
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Individual
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Individual
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Filing date
Publication date
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Publication of WO1996034642A1 publication Critical patent/WO1996034642A1/fr
Anticipated expiration legal-status Critical
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Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B05SPRAYING OR ATOMISING IN GENERAL; APPLYING FLUENT MATERIALS TO SURFACES, IN GENERAL
    • B05BSPRAYING APPARATUS; ATOMISING APPARATUS; NOZZLES
    • B05B7/00Spraying apparatus for discharge of liquids or other fluent materials from two or more sources, e.g. of liquid and air, of powder and gas
    • B05B7/14Spraying apparatus for discharge of liquids or other fluent materials from two or more sources, e.g. of liquid and air, of powder and gas designed for spraying particulate materials
    • B05B7/1404Arrangements for supplying particulate material
    • B05B7/1413Apparatus to be carried on or by a person, e.g. by hand; Apparatus comprising a container fixed to the discharge device
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M15/00Inhalators
    • A61M15/0065Inhalators with dosage or measuring devices
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M15/00Inhalators
    • A61M15/02Inhalators with activated or ionised fluids, e.g. electrohydrodynamic [EHD] or electrostatic devices; Ozone-inhalators with radioactive tagged particles
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M2202/00Special media to be introduced, removed or treated
    • A61M2202/06Solids
    • A61M2202/064Powder
    • A61M2202/066Powder made from a compacted product by abrading
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M2205/00General characteristics of the apparatus
    • A61M2205/07General characteristics of the apparatus having air pumping means
    • A61M2205/071General characteristics of the apparatus having air pumping means hand operated
    • A61M2205/073Syringe, piston type

Definitions

  • This invention relates to a method and apparatus for dispensing (or sorting) dry particulate for use in process technology; for production of research aerosols; and for producing aerosols or dispensing particulate for general use, including metered dose inhalation.
  • the method and apparatus may also be used to dispense damp particulate if the gas used in the dispensing process has some drying action on that particulate.
  • Metered Dose Inhalers find many medicinal uses, such as the administration of medicaments to treat asthma and the like.
  • the general disadvantages outlined above also apply here.
  • Inspiry-flow driven devices may get round this problem, but they can have an erratic performance due to their dependence on the rate of inspiration.
  • Most particulate used in inhalation therapy is hydroscopic, since it is required to dissolve in the fluid/blood in the lining of the lungs. Hence, humidity problems can cause particulate to stick together in devices such as these.
  • Fluidised beds take a long time to settle down to produce a steady output at any single through flow-rate.
  • the particulate tends to form into 'balls' between the jets of air.
  • Fluidised beds normally use a layer of ball bearings to counter this effect and to form an impactor to stop the progress of large particles and agglomerations.
  • fluidised beds tend to be restricted to very low particulate outputs per time.
  • a dispenser for dispensing dry particulate material from a column of agglomerated material including a support for the column, having a plurality of openings for allowing the passage of particles of the material there through, and at least one nozzle for directing a stream of gas across the supported end of the column and thence through the openings to release particles from the column and entrain them in the gas stream.
  • a dispenser for generating an aerosol of, or finely dividing, a particulate material from an agglomerated column of said material contained within the dispenser, wherein the dispenser comprises: i) a support upon which, in use, one end of the column rests, the support being provided with a plurality of perforations sized so as to allow passage of particles of the material therethrough; and ii) at least one nozzle adapted, in use, to direct a stream of gas into the column in the region of its supported end.
  • a method of generating an aerosol from, or finely dividing, a column of agglomerated particulate matter wherein one end of the column is held against a perforated support and wherein at least one stream of gas is directed across the column in the region of said one end.
  • a plurality of nozzles which may be spaced around the support and directed generally inwardly. Means may be provided for urging the column and the support together.
  • the dispenser includes a container having a first open end through which the material forming the column can be inserted and a second open end through which the material is dispensed.
  • the support which may be in the form of a mesh or perforated plate, may extend across the container and is preferably proximal to the second end. It is particularly preferred that the container be double-walled, in which case the nozzles may be formed in the inner wall and the gas may be supplied between the walls.
  • the gas may be supplied from a pressurised gas cylinder or by a manually operated pump, where single-shot dispensing is required. If continuous dispensing is needed, a pumped gas supply may be provided.
  • the walls may be provided with baffles or the like projecting into the space therebetween to enhance heat transfer to the gas, for example, from the hand when the device is hand-held.
  • the gas stream, or streams may simply skim the surface of the column which engages the support . More usually, it will enter the column immediately above the support. Conveniently, the gas stream or streams would initially be directed radially but a variety of gas streams may be appropriate for different purposes . For example, they may be fan-shaped or configured to set up a vortex or vortices .
  • the dispensed material may itself be entrained in a further gas stream for delivery to a remote point.
  • the support be relatively rigid, a flexible support may be employed, in which case the nozzle or nozzles may be located remote from the column and be adapted, in use, to direct one or more streams of gas through the mesh and into the particulate matter.
  • the streams of gas will tend elastically to distort the support and will traverse across the column of material thereby serving to generate the required aerosol.
  • Preferred embodiments of the present invention use no moving parts within the particulate chamber in order to entrain the particulate in the airstream, and afford excellent disagglomeration. Particles are stripped away from the bulk particulate by the action of the gas. A uniform dose is easy to achieve because the same amount of gas may be throughput each time, at the same rate, causing the same amount of particulate to be stripped from the bulk mass.
  • the column of particulate material comprises alternating layers of a first, "active” material, and a second, “inert” material, the relative thicknesses of the layers and the gas control means being such that, upon actuation, substantially a complete layer of "active” material bounded on either side by a partial layer of “inert” material is dispensed.
  • Each layer of “active” material may comprise a single measured dose of a medicament or the like, the intervening layers of "inert” material allowing for minor variations in the gas stream supply.
  • the physical characteristics of the "active" and “inert” particulate materials are the same or similar so as to avoid the generation of non-uniform turbulence on the column upon actuation of the dispenser.
  • the compressed gas may be released into the particulate by means of a valve from a pressurised container, or pressure-generated by hand or a gas compression machine.
  • a gas such as C0 2 as the carrier helps to counter humidity problems in the apparatus. If the particulate is tightly packed and permanently covered on all surfaces except near the mesh, humidity should only effect the layers near the mesh which may be in contact with the air or perhaps a person's breath. Air should be purged from the rest of the system by the gas, during the first few operations of the valve or other means of introducing the gas, and the gas should be retained for a while.
  • the exit may be covered, for example with a cap, while not in use.
  • the cap may advantageously contain desiccant, or may comprise a thin film which may be punctured or removed for operation of the device.
  • a shutter arrangement could be used, activated remotely or by the gas pressure.
  • Another solution would be to use alternate layers of hydrophobic particulate placed between the layers of substance to be administered. Use of a hydrophobic mesh may also reduce the possibility of wetting of the particulate.
  • Embodiments of the invention will immediately produce a steady output, which can be instantly varied by adjusting the flow rate. If the particulate is gravity-fed, and the gas is delivered through tubes in the walls instead of through an end cap arrangement at the particulate loading end, then the device can run for long periods of time with no maintenance or adjustment because it can be refilled continuously without significantly affecting the output characteristics. Larger output rates may be attainable than those achievable with fluidised beds.
  • Embodiments of the invention will disagglomerate the particulate and give a uniform delivery, making bulk processing in material processing industries more accurate.
  • the mass delivery per time for some embodiments of the present invention may be lower than that for a similar size existing processing instrument such as a hopper.
  • the apparatus can also be used as a separator (singularly or in multiple stages) for different size particulate. Smaller particulate is ejected while larger particulate is retained by the mesh. The mesh will tend not to be blocked by larger particulate because the gas passing through the particulate chamber will cause some turbulence and vibration so that larger particulate (assuming uniform density) will tend to move up the column.
  • the apparatus can be used in combination with other particle-influencing effects to select a required particle size fraction.
  • a number of dispensers together can be used for sequential (e.g. on a carousel) or combined dispensing.
  • Further advantages of embodiments of the present invention are easy filling of the active ingredient, and also that the particulate carrier can be supplied as a cartridge interchangeable with different gas- producing devices. Where C0 2 or similar is used as the propellant gas, relatively little environmental hazard will occur in comparison to systems which use volatile and/or ozone- destroying propellants.
  • FIGURE 1 shows a vertical section through a simple dispenser according to the present invention
  • FIGURE 2 shows the support mesh of the dispenser of Figure 1;
  • FIGURE 3 shows a vertical section through an alternative embodiment of the present invention
  • FIGURE 4 shows the support mesh of the dispenser of Figure 3
  • FIGURE 5 shows a vertical section through a metered dose inhaler
  • FIGURE 6 shows a section through an alternative metered dose inhaler provided with sheath air and a hand-pumped priming device
  • FIGURE 7 shows a particulate dispenser or aerosol generator for process engineering
  • FIGURE 8 shows a research aerosol generator
  • FIGURE 9 illustrates an alternative method of aerosol generation using a flexible mesh.
  • a mass of particulate matter (1) is retained in a container (2) by a fine mesh (3) attached across an open end of the container (2) .
  • the particulate (1) is pressed onto the mesh (3) by an external force such as gravity, gas pressure, or a spring (4) , pushing against the particulate (1) possibly via a follower (5) .
  • Gas is introduced under pressure through a series of holes or nozzles (6) at the mesh (3) covered end of the container (2) , a short distance above the mesh (3) .
  • Nozzles/holes (6) mounted in the container (2) wall at the perimeter of the mesh (3) are preferred, so that particulate (1) can continue to move freely towards the mesh (3) .
  • This arrangement helps to prevent the creation of a permanent cavern below a nozzle (6) , such as may happen if the gas was introduced in a ring of nozzles (6) placed radially in the centre of the mesh (3) .
  • the holes/nozzles (6) project the gas radially inward from the wall of the container (2) . The compression force ensures that the particulate
  • Particulate (1) is entrained by the gas as it flows between the holes/nozzles (6) and mesh (3) by the gas stripping off particles from the bulk.
  • the particulate (1) when driven through the mesh (3) , is subjected to high shearing forces, and will disagglomerate well.
  • the holes/nozzles (6) may be covered with fine gauze to stop particulate (1) moving into them while the dispenser is not operating.
  • the particular design specifications may be varied according to the required application.
  • many materials and hole sizes can be used. For example, where it is desired to dispense 6 ⁇ m alumina powder, a No. 50 US Mesh hole size metal sieve is suitable for good retention and shearing. A 25 ⁇ m hole- size square weave steel mesh may also be used. With no gas emanating from the holes/nozzles (6) , even if the mesh (3) hole size is considerably larger than the mean particulate (1) particle size, in many cases the particulate (1) will not significantly exit the mesh (3) . This is due to cohesive forces present within the particulate (1) , and adhesive forces between the particulate (1) and the mesh (3) .
  • the particulate (1) does not easily exit even if the device is shaken vigorously, since by compression towards the mesh (3) the particulate (1) is hindered from reciprocal motion relative to the mesh (3) .
  • the gas flow rate may be varied to suit the desired application. In many applications, a flow rate of 3 to 100 litres/minute is suitable.
  • Gas may be introduced into the particulate (1) through any number of holes or nozzles (6) . 12 holes (6) of 2mm diameter spaced evenly round the circumference of the inner wall of the container (2) may be provided. Use of any small nozzles (6) or other gas entry holes at the base of the particulate (1) column near to the mesh (3) will succeed in producing some particulate (1) output with gas flow through these nozzles (6) .
  • the preferred design for simplicity, cost, ease of construction and aesthetic appeal, is to use a double-walled container (2) with gas entry holes (6) drilled into the circumference of the inner wall.
  • the void between the two walls is then pressured to achieve 'jets' of gas at the inlet holes (6) .
  • These jets of gas may be directed radially toward one another causing the resultant flow to be out of the device at approximately right angles to the initial trajectory of the jets.
  • the gas entry nozzles/holes (6) could be placed in the mesh (3) itself or could be angled in a more axial direction to allow higher output velocities.
  • the nozzles (6) may be angled backwards away from the mesh (3) to produce lower output velocities, or indeed angled back from within the body of the mesh (3) or from just outside the mesh (3) i.e. outside the cylinder (2).
  • the latter arrangement may improve the disagglomeration of the particulate (1) .
  • this arrangement may cause the gas-borne particulate (1) to deposit on the injection nozzles (6) due to the positions of the nozzles (6) in relation to the particulate (1) bulk and due to turbulence caused by injecting gas from these positions.
  • Example 1 There will now be described a general hand-held aerosol generator or particulate dispenser with specific reference to Figures 1 and 2.
  • a column of particulate (1) matter is retained in a double-walled cylinder (2) by a fine mesh (3) attached across an open end of the cylinder (2) .
  • the particulate (1) is pressed onto the mesh (3) by a helical spring (4) and follower (5) .
  • Other compression devices could alternatively be used, but it is preferred to use a spring (4) and follower (5) arrangement because, as gas is injected at the base of the particulate (1) column, the spring (4) may cushion forces acting upward towards the follower (5) or indeed allow the particulate (1) bulk to move away from the mesh (3) so that a more consistent degree of compaction may be maintained throughout the particulate (1) bulk. This helps to avoid increasing compaction of the particulate (1) around the mesh (3) by sequential gas pulses during pulsed delivery operation, thereby maintaining a consistent output.
  • a bleed hole may be provided at the end of the container (2) furthest from the mesh (3) so as to allow ambient or other gas to enter the container as the particulate (1) bulk moves towards the mesh (3) . This helps to prevent the generation of a partial vacuum as the particulate (1) bulk moves along the container (2) .
  • the top of the particulate bulk (1) may be sealed against these ambient or other gases by using a sealed plunger as a follower (5) .
  • the particulate (1) column is first loaded on to the mesh (3) , then the follower (5) and spring (4) are placed on the particulate surface.
  • the end cap (C) is then screwed on, compressing the spring (4) and compacting the particulate (1) towards the mesh (3) .
  • Gas entry holes (6) are installed in the inner wall of the container (2) near to the mesh (3) .
  • a pressurised gas container (7) is mounted outside the particulate cylinder (2) by screwing to the end cap (C) .
  • the pointed plunger (8) punctures the gas container (7) and gas is released to the valve (9) . This short-release valve (9) is opened manually.
  • valve (9) When the valve (9) is open, gas is introduced under pressure through a series of fine gauze-covered holes/nozzles (6) in the internal surface of the cylinder (2) , a short distance above the mesh (3) . Particulate (1) is entrained by the gas by way of stripping/pushing forces as the gas rushes between the holes/nozzles (6) and mesh (3) . The gas/particulate (1) mixture is expelled through the mesh (3) .
  • the mesh (3) needs to be rigid enough to retain a consistent position near to the pressurised air inlets (6) under the force of the spring (4) and follower (5) , and to retain the size of its holes as gas/particulate
  • (1) is driven through it. It could be a metal gauze with or without crossed beam supports, a perforated plate, a moulded plastic sieve, a sinter, or any other rigid mesh.
  • the bulk of the particulate (1) column may tend to become supported by a central column of particulate (1) at the centre of the mesh (3) , thereby leaving the zone near the nozzles (6) free of particulate (1) .
  • the severity of this effect depends on the action of the jets (i.e. whether vortices or the like are created) .
  • a shaped mesh (3) may also direct the jets better to skim the mesh (3) and thereby more easily to entrain the particulate (1) .
  • baffle plates (10) help to warm the gas before it enters the particulate (1) .
  • a filtering device, mesh or series of baffle plates (10) may be installed within the container (2) walls. Baffle plates (10) help to warm the gas before it enters the particulate (1) .
  • a somewhat warmer gas should enter the particulate (1) .
  • the mesh (3) can be changed to one with a suitable hole size, along with changing the gas flow rate or pressure.
  • the particulate (1) total output will tend to increase with increasing mesh (3) hole size, but so will the number of agglomerations present.
  • the optimum condition of flow rate, velocity, nozzle (6) distance from the mesh (3) , mesh (3) hole size and mesh (3) design can best be obtained by experimentation with the type of particulate (1) required to be dispensed.
  • Example 2 An alternative embodiment of the apparatus shown in Figures 1 and 2 shall now be described with reference to Figures 3 and 4.
  • the mesh (3) supporting the column of particulate (1), and also the column of particulate (1) is generally annular in shape.
  • container (2) may be in the shape of a hollow cylinder (which may have a non-circular, e.g. oval cross-section).
  • Nozzles (6) may be spaced around the mesh (3) end of the device, inside and outside the annular column of particulate (1) , and be arranged to project gas outwardly from the inside of the column of particulate (1) and inwardly from the outside of the column of particulate (1) .
  • This enables the particle (1) to be ejected from a relatively large diameter annulus, yet provides good particulate (1) disagglomeration due to there being a thin wall of particulate (1) "sandwiched" by jets of gas .
  • the particulate carrier can be supplied as a cartridge interchangeable with different gas-producing devices.
  • Particulate rushing through the mesh or air rushing through the particulate can generate static electricity, which may hinder the delivery of the aerosol to the desired target area. This effect, however, can be reduced by earthing the mesh/container by hand.
  • the production of charged aerosol due to static is common with most dry particulate dispensers. Notwithstanding the above, the production of charged aerosol may be beneficial in some instances.
  • the mesh (3) may be allowed to become, or be deliberately, electrostatically charged by varying amounts in order to change the output characteristics of the device.
  • Example 3 A Metered Dose Inhaler (MDI) according to the present invention will now be described with reference to Figures 5 and 6.
  • a column of particulate (1) matter is retained in a double walled cylinder (2) by a fine mesh (3) attached across an open end of the cylinder (2) .
  • the particulate (1) is pressed onto the mesh (3) by a helical spring (4) and follower (5) .
  • Other compression devices could be used as an alternative.
  • the particulate (1) column is loaded on to the mesh (3) , then the follower (5) and spring (4) are placed on the particulate surface.
  • the end cap (C) is then screwed on, compressing the spring (4) and compacting the particulate (1) towards the mesh (3) .
  • Gas entry holes/nozzles (6) are installed in the inner wall of the container (2) near to the mesh (3) .
  • a pressurised gas container (7) is mounted outside the particulate cylinder (2) by screwing to the end cap (C) .
  • the pointed plunger (8) punctures the gas container (7) and gas is released to the valve (9) .
  • This short-release valve (9) is opened manually.
  • valve (9) When the valve (9) is open, gas is introduced under pressure through the fine gauze-covered holes/nozzles (6) in the internal surface of the cylinder (2) a short distance above the mesh (3) . Particulate (1) is entrained by the gas by stripping forces, as it rushes between the holes/nozzles (6) and mesh (3) . The gas/particulate (1) mixture is expelled into the actuating nozzle (A) , from which it is inhaled. Inhalation will need to be timed to coincide with the gas valve (9) release.
  • An in-line actuator (A) is the simplest design and will minimise losses as the particulate (1) is expelled.
  • the actuator (A) may also be described as a mouthpiece. This may contain a trigger device (not shown) to activate the MDI during inhalation and to time the "firing" of the gas into the particulate (1) column to coincide with the inhalation.
  • baffle plates (10) may be installed within the container (2) walls. Baffle plates (10) , for example, would help warm the gas before inhalation. Likewise, if only half the cylinder (2) wall space capacity is expelled upon each depression of the gas valve (9) , a somewhat warmer gas should be inhaled.
  • FIG. 6 An alternative embodiment is shown in Figure 6 where the particulate dispenser is mounted in a sheath tube (ST) .
  • ST sheath tube
  • the gas injection device when primed may be in the form of an expanded balloon (BAL) which blocks the sheath tube (ST) .
  • the container (2) is single-walled and the gas is injected to the nozzles (6) via independent tubes (TU) .
  • the priming valve (VP) is a one-way valve that allows the balloon (BAL) to be inflated and independently to maintain this condition until the release valve (VR) is opened.
  • the release valve (VR) may preferably be a device that, each time it is operated (triggered) , opens to the same degree in the same time period. This means that the gas output velocity and volume flow rate will be the same on each operation of the valve (VR) .
  • the balloon (BAL) is primed through the priming valve (VP) by pumping the plunger (PG) via the handle (HA) to displace the gas in the cylinder (CY) mounted in the carry tube (CT) .
  • these embodiments provide the following further advantages over conventional MDIs: i) The particulate/gas mixture will be expelled at low velocity from the actuator compared to conventional pressurised liquid MDIs because it does not emanate from a single small jet. This is an advantage because the aerosol can then follow the breathing streamlines into the lungs, instead of substantially impacting onto the back of the throat as happens with high velocity delivery. A sheathed gas flow may further assist the transport of the aerosol to the target area in the lung. ii) The particulate can be loaded as a pre-determined particle size for maximum lung deposition. A large proportion of the aerosol from some compressed liquid MDIs is in large particle form, which impacts onto the throat, missing the target area.
  • MDIs because the output of these contains a complex of surfactant and propellant particles as well as the active drug particles. iv) It is not necessary to add a larger sized particulate to help fluidise the mixture, though this may assist disagglomeration. v) The same particulate carrier can be supplied as a cartridge interchangeable with different gas- producing devices. vi) The device may be used as a simple MDI, where the individual doses are not prepackaged or mechanically separated. There need not be a "hard” barrier defining the extent of one dosage, but instead each dosage of particulate (1) may be "sandwiched" between two layers of similar but “inert” particulate.
  • Dispensing may thereby be more accurate and consistent.
  • a column of particulate matter (1) is retained in a double-walled cylinder (2) by a fine mesh (3) attached across an open end of the cylinder (2) .
  • the particulate (1) is pressed onto the mesh (3) by its own and an additional weight (4) and possibly a follower (5) rested on the top of the particulate (1) column.
  • Other compression means such as a spring or gas pressure, may be used.
  • the end cap (C) With the particulate (1) and weight (4) inside the container (2) , the end cap (C) is placed onto the cylinder (2) and held in place against rubber seals (R) by the use of clips (K) .
  • the compressed gas is introduced through a nozzle (N) on the end cap (C) and into the base of the particulate (1) column.
  • the gas is introduced under pressure through a series of fine gauze-covered holes (6) in the internal surface of the cylinder (2) a short distance above the mesh (3) .
  • Particulate (1) is entrained by the gas as it flows between the holes (6) and mesh (3) .
  • the particulate (1) is entrained in the gas by the effect of the gas stripping off particles as it rushes through the base of the particulate (1) column.
  • a metallic earth lead (L) may be attached to a suitable earth point in the working area so as to discharge the build-up of static electricity in the apparatus.
  • these embodiments provide the following further advantages over conventional dispensers used in material processing: i) The output rate steadies quickly. ii) The particulate becomes very finely divided, improving reactability, miscibility etc. with other materials used in processing.
  • a column of particulate matter (1) is retained in a double-walled cylinder (2) by a fine mesh (3) attached across an open end of the cylinder (2) .
  • the particulate (1) is pressed onto the mesh (3) by its own and an additional weight (4) and possibly a follower (5) rested on the top of the particulate (1) column.
  • Other compression devices could be used, such as a spring, or gas pressure.
  • the end cap (C) With the particulate (1) and weight (4) inside the container (2) , the end cap (C) is placed onto the cylinder (2) and held in place against rubber seals (R) by the use of clips (K) .
  • Compressed gas is introduced through a nozzle (N) on the end cap (C) and into the base of the particulate (1) column.
  • the gas is introduced under pressure through a series of fine gauze covered holes (6) in the internal surface of the cylinder (2) a short distance above the mesh (3) .
  • Particulate (1) is entrained by the gas as it flows between the holes (6) and mesh (3) .
  • the particulate (1) is entrained in the gas by the effect of the gas stripping off particles as it rushes through the base of the particulate (1) column.
  • a metallic earth lead (L) can be attached to a suitable earth point in a room/working area so as to discharge the build-up of static electricity in the apparatus.
  • a conduit (T) around the cylinder (2) extending on the output side of the mesh (3) may be used for coupling to other apparatus or for producing a sheath air system to channel the particulate (1) output to improve delivery to the target.
  • this will produce suction at the output side of the mesh (3) , increasing the output velocity, and will in addition create a sheath of air to channel the particulate (1) output into the centre of the output gas stream .
  • Radioactive sources or electric fields could also be used to control the amount of electric charge retained by the particulate/aerosol upon output. In embodiments with low velocity outputs, it may be necessary to eject the output from the mesh (3) into an additional faster gas stream in order to project the particulate in directions other than downwards.
  • a rigid mesh (3) is generally preferred, certain embodiments of the present invention may advantageously employ a flexible mesh (90) as shown in Figure 9.
  • a mesh (90) combined with gas injected inward from outside the mesh (90) towards the container (2) may be a useful method of dispensing the particulate (1) .

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  • Biophysics (AREA)
  • Hematology (AREA)
  • Animal Behavior & Ethology (AREA)
  • General Health & Medical Sciences (AREA)
  • Public Health (AREA)
  • Veterinary Medicine (AREA)
  • Containers And Packaging Bodies Having A Special Means To Remove Contents (AREA)
  • Nozzles (AREA)

Abstract

Cette invention concerne un distributeur qui peut produire un aérosol de matière particulaire (1) ou bien diviser très finement de ladite matière particulaire elle-même contenue sous forme de colonne agglomérée dans un distributeur. Ce distributeur comprend: i) un support (3) sur lequel repose, lors de son utilisation, une extrémité de la colonne, ledit support (3) comportant une pluralité de perforations dimensionnées de manière à laisser passer les particules de matière (1); et ii) au moins un diffuseur (6) adapté, lors de son utilisation, pour envoyer un flux de gaz à l'intérieur de la colonne dans la zone correspondant à son extrémité supportée.
PCT/GB1996/001085 1995-05-05 1996-05-07 Distributeur de matiere particulaire Ceased WO1996034642A1 (fr)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
GB9509170.8 1995-05-05
GBGB9509170.8A GB9509170D0 (en) 1995-05-05 1995-05-05 Particulate dispenser

Publications (1)

Publication Number Publication Date
WO1996034642A1 true WO1996034642A1 (fr) 1996-11-07

Family

ID=10774045

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/GB1996/001085 Ceased WO1996034642A1 (fr) 1995-05-05 1996-05-07 Distributeur de matiere particulaire

Country Status (2)

Country Link
GB (2) GB9509170D0 (fr)
WO (1) WO1996034642A1 (fr)

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2006108557A1 (fr) * 2005-04-08 2006-10-19 Nycomed Gmbh Nebuliseur a sec
EP2976125A4 (fr) * 2012-03-24 2016-04-13 Rhinocare Ltd Systèmes et procédés de préparation d'un mélange contrôlé en vue d'un traitement hyperthermal

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4582254A (en) * 1984-06-06 1986-04-15 Eutectic Corporation Device for the controlled multiple feeding of powder material
US4859121A (en) * 1985-03-05 1989-08-22 Bertin & Cie Method and device for the dispersion of ultra-fine powders
EP0365038A2 (fr) * 1988-10-21 1990-04-25 The Perkin-Elmer Corporation Système haute pression d'alimentation en poudre
US5159765A (en) * 1990-04-24 1992-11-03 Metri Airfluid Ag Apparatus for fluidizing and transferring powdered material

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4582254A (en) * 1984-06-06 1986-04-15 Eutectic Corporation Device for the controlled multiple feeding of powder material
US4859121A (en) * 1985-03-05 1989-08-22 Bertin & Cie Method and device for the dispersion of ultra-fine powders
EP0365038A2 (fr) * 1988-10-21 1990-04-25 The Perkin-Elmer Corporation Système haute pression d'alimentation en poudre
US5159765A (en) * 1990-04-24 1992-11-03 Metri Airfluid Ag Apparatus for fluidizing and transferring powdered material

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2006108557A1 (fr) * 2005-04-08 2006-10-19 Nycomed Gmbh Nebuliseur a sec
EP2976125A4 (fr) * 2012-03-24 2016-04-13 Rhinocare Ltd Systèmes et procédés de préparation d'un mélange contrôlé en vue d'un traitement hyperthermal
US9642981B2 (en) 2012-03-24 2017-05-09 Michael Blum Systems and methods of preparing a controlled mixture for hyperthermal treatment

Also Published As

Publication number Publication date
GB9509170D0 (en) 1995-06-28
GB9521588D0 (en) 1995-12-20

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