DE102009032908B4 - Method and device for conveying and distributing powders - Google Patents

Abstract

A method for conveying and distributing powders in a gas stream, which moves through a delivery space from a delivery chamber inlet to a delivery chamber outlet (3), wherein in the delivery chamber an exciter for sound waves is arranged, characterized in that - the gas flow (15) through a in the delivery chamber (1) opening powder inlet (5) between the exciter (4) and the delivery chamber outlet (3) the powder (19) is fed metered, - Sound waves are generated by the exciter (4), at least from the powder inlet ( 5) in the direction of the delivery chamber outlet (3) within the delivery chamber (1) propagate, - the powder via the powder inlet (5) by gravity and supported by a low-frequency operating excitation mechanism (9) from a powder container (6) is supplied to the gas stream, the excitation mechanism with a plunger (10) exerts impact stresses on the powder container (6) and couples vibrations in the powder container.

Description

The invention relates to a method and a device for conveying and distributing powders in a gas stream, which moves through a delivery chamber from a delivery chamber inlet to a delivery chamber outlet, wherein a pathogen for sound waves is arranged in the delivery chamber.

Methods for conveying and distributing powders in a gas stream are used in particular for feeding metered quantities of fine-grained powders, in particular for coatings. Powder deposits and agglomerations of the powder in the conveyor as well as the powder flow paths must be avoided. Furthermore, as little gas as possible, in particular air, is required to convey the powder. Finally, a cheap and simple production is sought.

In the DE 103 53 968 A1 discloses a coating powder delivery device which is intended to enable a coating with little fluidizing compressed air, while at the same time powder deposits in the powder conveying path should be avoided. The coating powder for the downstream spray coater is conveyed by a tubular membrane pump which mixes the coating powder with a small amount of compressed air per unit time and thereby fluidizes. In this case, the coating powder does not need to be fluidized with as much compressed air per unit time, as is necessary for pneumatic conveying, for example by means of an injector. This is a compressed air and energy savings connected to generate the compressed air. The elastically stretchable tubular membrane is arranged in a hollow hollow state in a continuously extending state in a delivery chamber, which forms a pressure chamber surrounding the tubular membrane in an annular manner. The delivery chamber has a powder inlet in which there is a powder inlet valve and a powder outlet in which a powder outlet valve is located.

A controller controls the supply and removal of fluid medium in the pressure chamber surrounding the tube membrane. By supplying pressure medium into the pressure chamber, the tube membrane is compressed against its elastic force and the volume in the tube membrane is reduced. By this compression of the tube membrane, a pressure stroke is generated which expels powder-air mixture in the tube membrane through the powder outlet valve while the powder inlet valve is closed. By removing pressure medium from the annular surrounding the tube membrane pressure chamber, the tube membrane deformed due to their elasticity back into their tube-like initial shape. As a result of this return deformation, the tube membrane generates a suction stroke, through which the coating powder and gas are sucked into the tube membrane through the now open powder inlet valve, while the powder outlet valve is closed. The powder inlet or outlet valve in the form of a membrane is closed or opened by means of the generated pressure surges. When extremely fine powders are being pumped, membrane cleaning fails due to the pressure surges and constipation ceases. In addition, the exact vote of the elasticity of the membrane is technologically difficult depending on the height of the pressure surges and the powder to be delivered. Finally, only fluidizable powders from a powder container can be conveyed with the known peristaltic pump.

The promotion of extremely fine powder with particle sizes of less than 10 microns is virtually impossible with the known coating powder conveyor. Below this grain size, the adhesion forces between the powder particles increase considerably. The surface of the particles increases considerably in relation to the volume. A cube with an edge length of 1 cm has a surface of 0.006 m ² . The same volume filled with particles of five nanometers edge length, however, has a surface area of 2,400 m ² . The strong increase in surface forces prevents the promotion of such small particles. Only by permanent energy coupling, in particular high flow velocities, which are associated with high air consumption, agglomeration of the powder / gas mixture could be avoided. However, high gas volume flows are disadvantageous in various downstream working processes, such as in plasma coating processes or laser coating processes. In addition, high gas flow rates require a higher energy input for the promotion. There are also downstream processes where the powder / gas mixture requires the use of inert gases. Due to the high cost of inert gases, a reduction in gas consumption is also desirable for this reason.

The WO2008 / 063549 A2 describes powdered fuels and internal combustion engines that are operated with powdered fuels. The smallest particle size of the powder is 50 μm. Within an inlet tube of the powder-operated motor, a powder container is arranged, which emits via a closable opening fluidized powder into the inlet tube. An airtight seal maintains a constant gas pressure in the powder container, while fuel powder is removed from the powder container or this is supplied. An ultrasonic vibrator may be located immediately below the closable opening within the inlet tube to aid in powder dispersion and gas turbulence. In the flow direction in front of the reservoir is a connection for a compressed air source, wherein the compressed-air blast mixes with the released from the closable opening fuel powder. Furthermore, the powder flow in the powder container can be assisted by a further ultrasonic vibrator whose vibrations are introduced directly into the container wall.

Based on this prior art, the invention is based on the object to provide a method for conveying and distributing powders in a gas stream, the promotion of extremely fine powders, especially those with a particle size of less than 10 microns, with low Gas quantities allowed in the case of agglomerations of the powder are nevertheless avoided or dissolved. Furthermore, a conveyor of simple design for conveying extremely fine powders with a small amount of gas should be proposed.

• – dem Gasstrom durch einen in dem Förderaum mündenden Pulvereinlass zwischen dem Erreger und dem Förderraumauslass das Pulver dosiert zugeführt wird,
• – Schallwellen von dem Erreger erzeugt werden, die sich zumindest von dem Pulvereinlass in Richtung des Förderraumauslasses innerhalb des Förderraums ausbreiten
• – das Pulver über den Pulvereinlass durch Schwerkraft und unterstützt durch einen niederfrequent arbeitenden Anregungsmechnismus aus einem Pulverbehälter dem Gasstrom zugeführt wird, wobei der Anregungsmechanismus mit einem Stößel Schlagbeanspruchungen auf den Pulverbehälter ausübt und Schwingungen in den Pulverbehälter einkoppelt.

This object is achieved in a method for conveying and distributing powders in a gas stream in that

• The powder is metered into the gas stream through a powder inlet opening in the delivery chamber between the exciter and the delivery chamber outlet,
• - Sound waves are generated by the exciter, which propagate at least from the powder inlet in the direction of the delivery chamber outlet within the delivery chamber
• - The powder is fed via the powder inlet by gravity and supported by a low-frequency operating excitation from a powder container the gas stream, wherein the excitation mechanism with a plunger impact loads on the powder container and couples vibrations in the powder container.

The sound waves prevent the formation of agglomerates of the powder in the gas stream. Furthermore, the energy coupled in by the sound waves causes a dissolution of existing agglomerates of the powder, which reach the delivery chamber via the delivery chamber inlet. An increase in the amount of gas for the gas flow through the pumping chamber is not required because the suppression or dissolution of the agglomerates primarily the sound waves are responsible. In the flow direction behind the powder inlet, the gas stream mixes with the powder and conveys it in the direction of the delivery chamber outlet.

A supply of fluidized powder into the delivery chamber is no longer required in the method according to the invention. The fine-grained powder is fed via the powder inlet by gravity and supported by a metering device from a powder container to the gas stream. The dosing device is a low-frequency stimulator, which couples vibrations in the powder container.

In experiments, it has been found that agglomerated powders can be distributed very well in the gas flow by sound waves in a frequency range from 20 kHz to 1 GHz. Furthermore, agglomerates of the powder are dissolved particularly effectively or prevented from forming in this frequency range.

To generate the gas flow in the delivery chamber whose delivery chamber inlet is connected to a compressed gas supply, in particular a supply for compressed air as a carrier medium for the powder. Alternatively, preferably nitrogen, argon, CO2 or mixed gases with hydrogen content are used as compressed gas. The volume flow of the compressed gas is for example between two l / min to ten l / min at an absolute pressure of for example 1.5 bar.

In order to avoid excessive flow velocities of the gas stream in the region of the powder inlet, in one embodiment of the process according to the invention the gas stream is temporarily divided into a blowing stream and a suction stream, wherein the suction stream has a lower flow velocity than the blowing stream, the powder is metered into the suction stream and the suction flow is accelerated in the direction of the delivery outlet upon encountering the motive flow. The flow distribution is realized by arranged in the delivery chamber tubes with cross-sectional constrictions. If the motive flow surrounds the suction flow annularly, the suction flow is additionally channeled in the direction of the pumping chamber outlet when it encounters the motive flow.

The best possible dissolution of the powder inlet via the powder inlet to the delivery chamber supplied agglomerates of the powder is achieved when the gas flow, the powder is supplied dosed in spatial proximity to the exciter of the sound waves. If the powder inlet is tubular and protrudes into the delivery chamber, the exciter is preferably arranged immediately below the tube end, so that the sound waves propagate querab to the flowing under the action of gravity from the tube into the pumping space powder particles. The distribution of the powder in the gas stream is particularly uniform in this procedure. Furthermore, it has been found to be advantageous if the gas flow flows around the exciter for the sound waves annularly through the delivery chamber.

An advantageous apparatus for carrying out the method results from the features of claim 7 and the following subclaims:
If the gas flow in the delivery chamber is to be divided into a motive and a suction flow, the device for carrying out the process is characterized in that the delivery chamber comprises an outer tube, which tapers at an end face to the delivery chamber outlet, forming an inner tube extends into the outer tube to form an annular space, the powder inlet opens on the lateral surface in the inner tube, the exciter is arranged for sound waves in the direction of the gas flow in front of the powder inlet in the inner tube, the inner tube ends at a distance from the delivery chamber outlet and both the outer and inner tubes communicate with the delivery chamber inlet at its front end in the direction of the gas flow.

In the annulus between the outer and inner tube, the motive flow is channeled while moving through the inner tube, the suction flow at a lower flow rate. The powder inlet opens on the lateral surface in the inner tube, so that the powder enters the suction flow at a lower flow rate. For example, in order to throttle the flow velocity in the inner tube, it may have constrictions.

In order to ensure optimum flow conditions at the powder inlet, the exciter for sound waves in the direction of the gas flow is arranged in front of the powder inlet in the inner tube, wherein the suction flow is passed through the annular gap surrounding the exciter within the inner tube.

The inner tube terminates at a distance from the Förderraumauslass so that between the Förderraumauslass and the mouth of the inner tube, a mixing space remains in the pumping chamber, in which the suction flow at a lower flow velocity impinges on the drive flow at a higher speed and accelerates from this towards the Förderraumauslasses becomes.

Both the inner and the outer tube communicate in gas-conducting communication with the delivery chamber inlet, which is in particular connected to the compressed air supply. Constructively advantageous for this purpose, the delivery chamber inlet is arranged on a housing which receives the inner and the outer tube to form gas flow paths to the inner and outer tube. The gas of the compressed gas source is fed into the outer tube, preferably via the end-side annular gap between the outer and inner tube, while the feed into the inner tube via at least one opening in the shell of the inner tube, preferably in a region of the inner tube, which does not protrude into the outer tube.

In order to avoid flow deflections of the powder distributed in the gas flow within the inner tube, it is provided in an advantageous embodiment of the invention that in the direction of the gas flow behind the powder inlet, an opening in the inner tube is arranged, which connects the inner tube with the annulus. The opening is preferably located on a line parallel to the tube axis on the jacket of the inner tube which passes through the powder inlet.

The invention will be explained in more detail with reference to the figures. Show it:

1 a schematic representation of an apparatus according to the invention for carrying out the method

2a , B a further embodiment of an apparatus for carrying out the method according to the invention and

3 an advantageous arrangement of the exciter of the sound waves in the delivery chamber.

1 shows a device for conveying and distributing in particular fine powders which have a delivery chamber ( 1 ), connectable to a compressed air source, not shown, the delivery chamber inlet ( 2 ) and a delivery room outlet ( 3 ) having. In the delivery room ( 1 ) is a pathogen ( 4 ) arranged for sound waves. Between the pathogen ( 4 ) and the delivery chamber outlet ( 3 ) opens a powder inlet ( 5 ) in the delivery room ( 1 ). The powder inlet ( 5 ) is located at the front end of a funnel-shaped tapering powder container ( 6 ) of a dosing system ( 7 ), with the aid of which via the powder inlet ( 5 ) the delivery room ( 1 ) Powder is metered. The dosing system ( 7 ) comprises a box-like receptacle ( 8th ) for holding the powder container ( 6 ) above the pumping room ( 1 ).

Near the powder inlet ( 5 ) forming mouth of the powder container ( 6 ) is on the box-like receptacle ( 8th ) a low-frequency excitation mechanism ( 9 ) arranged with a plunger ( 10 ) Impact stresses on the powder container ( 6 ) exercises. As a result, in the powder container ( 6 ) located to agglomerations prone fine-grained powder through the powder inlet ( 5 ) and without blockages of the powder inlet ( 5 ) the delivery room ( 1 ).

The germ ( 4 ) for sound waves in the ultrasonic range consists essentially of a stepped longitudinal oscillator ( 11 ), which is connected via a connecting part ( 12 ) the vibrations on a swinging plate ( 13 ), whereby the oscillatory movement ( 14 ) axially parallel to the longitudinal axis of the delivery chamber ( 1 ) is performed.

The powder inlet ( 5 ) is located at a short distance to the swing plate ( 13 ), from which sound waves travel in the direction of the delivery chamber outlet ( 3 ).

About the compressed air supply is the pump room inlet ( 2 ) supplied under positive pressure air with a flow rate of 2-10 l / min, so that an air flow ( 15 ) through the delivery room ( 1 ) from the delivery room inlet ( 2 ) to the delivery room outlet ( 3 ) emotional. In the range of the oscillator ( 11 ) the air flow ( 15 ) through the remaining annular gap ( 16 ) between the oscillator ( 11 ) and the inner wall of the delivery chamber ( 1 ) forming tube passed. The air flow ( 15 ) is passed through the powder inlet ( 5 ) the powder from the powder container ( 6 ) metered, so that in the flow direction ( 17 ) behind the powder inlet ( 5 ) the powder ( 19 ) in the gas stream ( 15 ) is promoted and distributed. From the powder container ( 6 ) in the delivery room ( 1 ) metered agglomerates ( 18 ) of the powder ( 19 ) are caused by the pathogen ( 4 ) outgoing sound waves resolved.

A device in which by the delivery chamber ( 1 ) moving air flow temporarily in a drive current ( 20 ) and a suction flow ( 21 ) is divided into 2 shown. The delivery room ( 1 ) comprises an outer, in particular circular cylindrical tube ( 22 ) located at its in the flow direction ( 17 ) front end conical to the delivery chamber outlet ( 3 ) rejuvenated. Into the outer tube ( 22 ) extends an inner tube ( 23 ) forming an annular space ( 24 ) between the outer shell of the inner tube ( 23 ) and the inner shell of the outer tube ( 22 ).

The one with the in 2 the sake of clarity not shown dosing connected powder inlet ( 5 ) opens on the lateral surface in the inner tube ( 23 ). The powder inlet ( 5 ) forming pipe section ( 25 ) is gas-tight with the powder container ( 6 ) in order to prevent the entry of external air into the delivery chamber ( 1 ) to prevent.

To the powder ( 19 ) in the suction stream ( 21 ) optimally distributed, is the swing plate ( 13 ) of the pathogen ( 4 ) adjacent, in particular at a distance of about 10 mm, to the powder inlet ( 5 ) arranged. The flow regulator ( 13 ) is located in 2 approximately below the direction of flow ( 17 ) rear wall of the pipe section ( 25 ), which enters the inner tube ( 23 ) opens. Overall, based on the in 2 horizontal longitudinal axis of the delivery chamber ( 1 ) the distance between the swing plate ( 13 ) and in the flow direction ( 17 ) rear edge of the delivery room inlet ( 2 ) in the horizontal direction a distance of 0-20 millimeters, preferably not exceed 10 mm. A contact between the swinging plate ( 13 ) and the pipe section ( 25 ) should be avoided in any case.

In the vertical direction is different from the illustration in 2 as shown in 3 an overlap of the pipe section ( 25 / 6 / 5 ) with the swinging plate ( 13 ) by a few millimeters advantageous. After all, it has become appropriate 3 proved to be advantageous when the powder inlet ( 5 ) forming mouth of the pipe section ( 25 ) flattened, in particular formed as a slot. This effectively prevents too large agglomerates ( 18 ) of the powder ( 19 ) in the delivery chamber ( 1 ) reach.

Out 2 is further evident that the inner tube ( 23 ) at its in the flow direction ( 17 ) front end a constriction ( 26 ), whose mouth at a distance from the delivery chamber outlet ( 3 ) ends. At the constriction ( 26 ) opposite ends the inner tube ( 23 ) over the outer tube ( 22 ). In this collar end ( 27 ) of the inner tube ( 23 ) are several beyond the scope of the Collaring ( 27 ) distributed openings ( 28 ) for the air inlet into the inner tube ( 23 ) arranged. The air inlet into the outer tube ( 22 ) takes place via the annular opening ( 29 ), which between the lateral surface of the inner tube ( 23 ) and the outer surface of the outer tube ( 22 ) is formed at the front side in the flow direction.

Both the inner and the outer tube ( 22 . 23 ) are in a housing ( 30 ), the component of the delivery chamber ( 1 ). The housing ( 30 ) takes the inner and the outer tube ( 23 . 22 ) with formation of flow paths to the openings ( 28 respectively. 29 ) on. At the in 2 illustrated embodiment, the flow paths ( 31 ) annularly between the housing ( 30 ) and the outer shell of the outer tube ( 22 ) in the direction of the openings ( 28 . 29 ) out.

Finally located in the flow direction ( 17 ) behind the powder inlet ( 5 ) an opening ( 32 ) in the inner tube ( 23 ), which is the inner tube ( 23 ) with the annulus ( 24 ) for the purpose of pressure equalization.

The device after 2 works as follows:
To the delivery room inlet ( 2 ), a compressed air source is connected, for example, with a delivery volume of 2 l / min and a pressure of 1.5 bar. The airflow ( 15 ) passes through the flow paths ( 31 ) to the openings ( 29 . 28 ) in the inner or outer tube ( 23 . 22 ). There the air stream splits ( 15 ) in the blowing current ( 20 ) and the suction flow ( 21 ) on. The through the inner tube ( 23 ) guided suction flow ( 21 ) has a lower flow velocity than that through the annulus ( 24 ) guided drive current ( 20 ) on. The suction flow ( 21 ) the powder ( 19 ) from the powder container ( 6 ) over the pipe section ( 25 ) metered, for example, with a mass flow of 2 g / min, wherein the powder comprises particles in a size range of 1 to 30 microns. In the mouth area ( 33 ) the suction flow ( 21 ) in the direction of the delivery chamber outlet ( 3 ) speeds up. The acceleration takes place in particular by an exchange of pulses with the higher velocity driving current ( 20 ) in the mouth area ( 33 ).

The opening ( 32 ) between the inner tube ( 23 ) and the annulus ( 24 ) ensures that in the suction flow ( 21 ) distributed powder in a substantially straight line in the direction of the mouth of the inner tube ( 23 ) emotional.

• a) Volumenstrom der Druckluftzufuhr: 2 l/min Druck der Druckluftzufuhr: 1,5 bar Pulver: Aluminiumpartikel der Größe 1 bis 30 μm Dosierung des Pulvers: 2 g/min Geschwindigkeit Treibstrom: 85 mm/sek Geschwindigkeit Saugstrom: 59 mm/sek
• b) Volumenstrom der Druckluftzufuhr: 5 l/min Druck der Druckluftzufuhr: 1,5 bar Pulver: Aluminiumpartikel der Größe 1 bis 30 μm Dosierung des Pulvers: 2 g/min Geschwindigkeit Treibstrom: 205 mm/sek Geschwindigkeit Saugstrom: 150 mm/sek
• c) Volumenstrom der Druckluftzufuhr: 10 l/min Druck der Druckluftzufuhr: 1,5 bar Pulver: Aluminiumpartikel der Größe 1 bis 30 μm Dosierung des Pulvers: 2 g/min Geschwindigkeit Treibstrom: 403 mm/sek Geschwindigkeit Saugstrom: 318 mm/sek

In experiments with a device after 2 result under the following boundary conditions following flow velocities for the motive or suction flow ( 20 . 21 ):

• a) Volume flow of compressed air supply: 2 l / min Compressed air supply pressure: 1.5 bar Powder: aluminum particles of size 1 to 30 μm Dosage of powder: 2 g / min Speed of motive flow: 85 mm / sec Velocity of suction: 59 mm / sec
• b) Volume flow of compressed air supply: 5 l / min Compressed air supply pressure: 1.5 bar Powder: aluminum particles of size 1 to 30 μm Dosage of powder: 2 g / min Speed of motive flow: 205 mm / sec Velocity of suction: 150 mm / sec
• c) Volume flow of compressed air supply: 10 l / min Compressed air supply pressure: 1.5 bar Powder: Aluminum particles of size 1 to 30 μm Dosing of powder: 2 g / min Speed of motive flow: 403 mm / sec Velocity of suction: 318 mm / sec

Under the aforementioned test conditions, there was always a perfect distribution of the fine powders in the air stream. Agglomeration of the powders in the flow was avoided. As far as agglomerates ( 18 ) in the inner tube ( 23 ), these were reliably from the in the direction of Förderraumauslasses ( 3 ) spreading ultrasonic waves dissolved. The powder / gas mixture was at the delivery chamber outlet ( 3 ) via a branch ( 34 ) and two hose lines fed to a downstream coating process. LIST OF REFERENCE NUMBERS No. description No. description 1 delivery chamber 29 Frontal opening 2 Pumping chamber inlet 30 casing 3 Förderraumauslass 31 flow paths 4 pathogen 32 opening 5 powder inlet 33 mouth area 6 powder container 34 diversion 7 dosing 35 8th admission 36 9 excitation mechanism 37 10 tappet 38 11 Schwinger 39 12 connecting part 40 13 vibration plate 41 14 oscillating movement 42 15 airflow 43 16 annular gap 44 17 flow direction 45 18 agglomerates 46 19 powder 47 20 drive current 48 21 suction 49 22 outer tube 50 23 inner tube 51 24 annulus 52 25 pipe section 53 26 constriction 54 27 Kragende 55 28 openings 56

Claims (10)

Method for conveying and distributing powders in a gas stream that flows through a delivery space from a delivery chamber inlet to a delivery chamber outlet ( 3 ), wherein in the delivery chamber a pathogen for sound waves is arranged, characterized in that - the gas flow ( 15 ) through a in the delivery room ( 1 ) opening powder intake ( 5 ) between the pathogen ( 4 ) and the delivery chamber outlet ( 3 ) the powder ( 19 ) is metered, - sound waves from the pathogen ( 4 ), at least from the powder inlet ( 5 ) in the direction of the delivery chamber outlet ( 3 ) within the pumping room ( 1 ), - the powder through the powder inlet ( 5 ) by gravity and supported by a low-frequency excitation mechanism ( 9 ) from a powder container ( 6 ) is supplied to the gas stream, wherein the Excitation mechanism with a pestle ( 10 ) Impact stresses on the powder container ( 6 ) and couples vibrations into the powder container. A method according to claim 1, characterized in that sound waves are generated in a frequency range of 20 kHz to 1 GHz. Method according to claim 1 or 2, characterized in that the delivery chamber inlet ( 2 ) with a compressed gas supply for the formation of the gas stream in the delivery chamber ( 1 ) is connected. Method according to one of claims 1 to 3, characterized in that the gas stream temporarily characterized in a drive current ( 20 ) and a suction flow ( 21 ), that the delivery room ( 1 ) an outer tube ( 22 ) located at its in the flow direction ( 17 ) front end conical to the delivery chamber outlet ( 3 ) and rejuvenated into the outer tube ( 22 ) an inner tube ( 23 ) forming an annular space ( 24 ) between the outer shell of the inner tube ( 23 ) and the inner shell of the outer tube ( 22 ) passing through the inner tube ( 23 ) guided suction flow ( 21 ) a lower flow velocity than that through the annulus ( 24 ) guided drive current ( 20 ), the suction flow ( 21 ) the powder ( 19 ) is metered and the suction flow ( 21 ) when encountering the drive current ( 20 ) in the direction of the delivery chamber outlet ( 3 ) is accelerated. Method according to Claim 4, characterized in that the drive current ( 20 ) the suction flow ( 21 ) surrounds annularly. Method according to one of claims 1 to 5, characterized in that the gas stream ( 15 ) the powder in close proximity to the pathogen ( 4 ) the sound waves is metered. Device for carrying out the method according to one of claims 1 to 6, characterized in that the delivery chamber ( 1 ) can be connected to a compressed gas source delivery chamber inlet ( 2 ) and a delivery room outlet ( 3 ), in the conveying space ( 1 ) a pathogen ( 4 ) is arranged for sound waves and a powder inlet ( 5 ) between the pathogen ( 4 ) and the delivery chamber outlet ( 3 ) in the delivery room ( 1 ) and the device opens a low-frequency excitation mechanism ( 9 ) for supporting the supply of the powder from a powder container ( 6 ) in the gas stream, which with a plunger ( 10 ) Impact stresses on the powder container ( 6 ) exercises. Apparatus according to claim 7 for carrying out the method according to one of claims 4 to 6, characterized in that - the delivery chamber ( 1 ) an outer tube ( 22 ), which at an end face to the delivery chamber outlet ( 3 ), - an inner tube ( 23 ) in the outer tube ( 22 ) forming an annular space ( 24 ), - the powder inlet ( 5 ) on the lateral surface in the inner tube ( 23 ), - the pathogen ( 4 ) for sound waves in direction ( 17 ) of the gas stream in front of the powder inlet ( 5 ) in the inner tube ( 23 ) - the inner tube ( 23 ) at a distance from the delivery chamber outlet ( 3 ) - and both the outer and the inner tube ( 22 . 23 ) at his in direction ( 17 ) of the gas stream ( 15 ) front end with the delivery chamber inlet ( 2 ) communicate. Apparatus according to claim 8, characterized in that the pressure chamber with the source of gas supply connectable ( 2 ) on a housing ( 30 ) is arranged, which the inner and the outer tube ( 22 . 23 ) with formation of flow paths ( 31 ) for the gas to the inner and outer tube ( 22 . 23 ). Apparatus according to claim 8 or 9, characterized in that in direction ( 17 ) of the gas stream ( 15 ) behind the powder inlet ( 5 ) an opening ( 32 ) in the inner tube ( 23 ) is arranged, which the inner tube ( 23 ) with the annulus ( 24 ) connects.

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