DE102011051263A1 - Device for generating aerosols and depositing a light-emitting layer - Google Patents

Abstract

The invention relates to a device with a storage container (4) for receiving a powder (5) and with a screw conveyor (8) to convey a metered amount of powder (5) from the storage container (4) to a feed point (13), at which feed point (13) the powder (5) is to be transported away through an aerosol line (15) in a carrier gas stream (25). For the technical improvement of an aerosol generator, it is proposed that the screw conveyor (8) have a carrier (10).

Description

The invention relates to a device with a reservoir for receiving a powder and with a screw conveyor to promote a metered amount of the powder from the reservoir to a feed point at which feed point, the powder enters a carrier gas stream to be suspended particles in the carrier gas stream by an aerosol to be transported away.

A device of this kind is from the US 6,037,241 described. A funnel-shaped reservoir is filled with an organic powder. Below the reservoir is a screw conveyor, which is driven by a motor to feed metered quantities of the powder at a feed point in a carrier gas line through which a carrier gas stream flows. The powder particles form an aerosol in the carrier gas stream, which is transported by an aerosol line into an evaporator. The evaporator is formed by a container whose walls are formed by an open-cell foam body which is heated by passing electrical current, so that heat is transferred to the aerosol particles coming into contact with the cell walls, resulting in their evaporation. Carrier gas and steam are passed via a vapor line into a process chamber of a CVD reactor, where the vapor condenses on the surface of a substrate, forming a light-emitting layer.

The US 7,501,152 B2 describes a device having a reservoir having on its underside an opening which opens into a storage tube in which a screw conveyor is mounted, with a dosed in the container powder can be transported dosed to an evaporator. The powder used is an organic precursor which is vaporized to condense on a substrate as a light-emitting layer.

The US 2009/0039175 A1 also describes an evaporator to which powdered organic material is supplied via a screw conveyor, with which OLED structures can be deposited on a substrate.

The invention has for its object to improve the aerosol generator mentioned above technically.

The object is achieved by the invention specified in the claims.

First and essentially it is provided that the screw conveyor has an axial flow channel through which flows the carrier gas stream. This improves the functionality of the aerosol generator in an evaporation device. The powder particles conveyed by the screw are transported radially inward at the end of the screw via a suitable shaping of the end of the bearing cavity of the screw and fed directly into the carrier gas stream emerging from the end of the screw conveyor. The flow channel runs in the axis of rotation of the screw. The powder particles are transported as suspended particles in an aerosol line from the carrier gas to an evaporator, in which the suspended particles evaporate by supplying heat to a vapor. The enriched with the vapor of the vaporized organic starting material carrier gas stream is fed through a vapor line to a CVD reactor. This has a gas distributor in the form of a shower head with arranged on its underside gas outlet surface having a plurality of sieve-like arranged gas outlet openings. Through this gas distributor and the gas outlet openings of the enriched with the steam carrier gas stream passes into a disposed below the gas distributor process chamber whose bottom is formed by a susceptor carrying a substrate to be coated, for example glass, which is cooled by coolant of the susceptor to a temperature in which the vapor condenses on the surface of the substrate. The feeding of the aerosol, which is formed directly at the end of the screw conveyor, into the aerosol line can take place in a second carrier gas flow flowing transversely to the screw. But it is also envisaged that the aerosol line is aligned with the flow channel. Even with an aligned arrangement, a second carrier gas can flow into the aerosol line at the feed point. While the first carrier gas flows out of the center of a rotationally symmetrical feed arrangement, the second carrier gas can be fed from a radially outer nozzle arrangement. The carrier gas feed line for the first carrier gas may comprise a valve which is alternately opened and closed so that carrier gas pulses flow through the flow channel of the feed screw. The second carrier gas can also be supplied pulsed. The valve is preferably a switching valve which directs the carrier gas flow either into the flow channel or into a vent line. The carrier gas stream is preferably metered. This is done with a mass flow controller. The reservoir may have a stirrer, as for example in the US 7,501,152 B2 is described. The agitator can be driven by the same motor that also turns the worm. The agitator is a helically bent wire which is rotated about the axis of the helix. The container has a rotational symmetry. The axis of the agitator runs parallel to the axis of the spindle.

Embodiments of the invention are explained below with reference to accompanying drawings. Show it:

1 schematically the device according to the invention,

2 an enlarged section according to the dotted line II-II in 1 .

3 in perspective view of a conveyor of an aerosol generator 1 .

4 a representation of in 3 illustrated conveyor with broken screw conveyor bearing,

5 a plan view of a conveyor according to the 3 and 4 with a cut-open tube into which particles conveyed by the conveyor are injected,

6 a section along the line VI-VI in 5 .

7 the conveyor of the 3 and 4 in another example of application in which the powder particles conveyed by the conveyor axially into an aerosol line 15 be fed

8th a section along the line VIII-VIII in 7 and

9 another example of application in the 3 and 4 illustrated conveyor, wherein also axially into an aerosol line 15 is fed.

The 1 schematically shows a device for depositing OLED layers on a substrate 20 , The CVD reactor used for this purpose 3 is in the 1 shown greatly reduced. In it is a gas distributor 18 in the form of a shower head, which has on its underside a plurality of gas outlet openings leading to a process chamber 19 show their soil from a susceptor 21 is formed, which is cooled and on the surface of which the substrate to be coated 20 lies. With a vacuum pump 22 can the total pressure within the process chamber 19 set in a wide range. Usually, total pressures between 1 and 100 mbar are used.

The gas distributor 18 is via a steam supply 17 supplied with a process gas. It is a transported by a carrier gas vapor of an organic starting material, which on the substrate 20 condensed as a thin layer.

To generate the steam is first in an aerosol generator 1 from a powdery organic starting material 5 and a carrier gas stream 25 an aerosol generated by an aerosol line 15 in an evaporator 2 is brought where the carrier gas flow 25 transported suspended particles are evaporated. For this purpose, the evaporator has 2 an evaporation body 16 which is heated. The evaporation body is preferably an open-cell structure. It can be an open-celled solid state foam. The walls of the cells form curvilinear channels. The channel walls form evaporation surfaces. Via surface contact with the evaporation surfaces, vaporization energy is supplied to the suspended particles so that they evaporate and as vapor from the carrier gas flow 25 through the steam line 17 to the CVD reactor 3 be transported.

The carrier gas flow 25 is from a mass flow controller 27 dosed. The thus metered carrier gas flow 25 can by means of a switching valve 26 either in a carrier gas feed line 12 or in a vent line 28 be directed. By switching quickly, the carrier gas feed line can 12 pulsed from the carrier gas 25 be flowed through.

The carrier gas feed line 12 flows into a flow channel 10 which is in the axis of a screw conveyor 8th runs. The screw conveyor 8th has on its outer shell wall, one or more helically arranged conveyor ribs. By turning the screw conveyor 8th by means of a drive device 11 is one in the reservoir 4 stored powdered organic starting material 5 to the end of the screw conveyor 8th promoted where the estuary 14 of the flow channel 10 located.

Inside the storage container 4 is one of a motor 7 driven agitator 8th , which ensures a uniform filling of the screw conveyor 8th provides.

By turning the screw conveyor 8th this will be between the helical webs 24 in a conveyor channel 23 pumped powder to a feed point 13 transported. The screw conveyor 8th turns in a bearing tube 9 whose end is funnel-shaped, so that through a gap between the end face and funnel-shaped end 9 ' the powder in front of the mouth 14 of the flow channel 10 is encouraged.

The from the mouth 14 emerging carrier gas stream 25 promotes the powder as suspended particles through the aerosol line 15 to the evaporator 16 ,

In the in the 3 and 4 illustrated embodiment are screw conveyor 8th and agitator 6 from a common engine 7 driven, wherein the mutually parallel shafts of the agitator 6 and screw conveyor 8th connected by gears. In the cylindrical reservoir 4 turns a wire helix, which is the agitator 6 forms. The end 33 of the bearing tube 9 is formed by a neck whose front end is the funnel 9 ' formed. This nozzle is intended to be inserted into an opening of a pipe.

In the in the 5 and 6 illustrated embodiment, the nozzle is inserted 33 in a shell opening of a tube, through which a second carrier gas flow 29 flows. Upstream of the feed point 13 The tube thus forms a carrier gas supply line 30 for the second carrier gas 29 , Downstream of the feed point 13 the pipe forms the aerosol line 15 , At the entry point 13 that's from the screw conveyor 8th pumped powder by means of the flow channel 10 passing first carrier gas stream 25 fed.

In the in the 7 and 8th illustrated embodiment, the feeding of the aerosol from the front side takes place in the Aerosolleitung 15 , Here is the nozzle 33 in a nozzle head 31 , with which a second carrier gas stream 29 into the aerosol line 15 can be fed. This is done by a nozzle 33 surrounding feed zone for the second carrier gas 29 that have a lot of openings 32 forms, through which the second carrier gas 29 , which by means of a carrier gas supply line 30 in the nozzle head 31 is fed into the aerosol line 15 flows.

That in the 9 illustrated embodiment does not use a second carrier gas. Here is the tube end of the aerosol line 15 directly on the neck 33 attached. That by the in the axis of rotation of the screw conveyor 8th arranged flow channel 10 passing carrier gas 25 takes at the mouth 14 of the flow channel 10 with the conveyed from radially outward to the center of rotation powder particles and transported as suspended particles to the evaporator 2 ,

All disclosed features are essential to the invention. The disclosure of the associated / attached priority documents (copy of the prior application) is hereby also incorporated in full in the disclosure of the application, also for the purpose of including features of these documents in claims of the present application. The subclaims characterize in their optional sibling version independent inventive development of the prior art, in particular to make on the basis of these claims divisional applications.

LIST OF REFERENCE NUMBERS

1

Aerosol Generator

2

Evaporator

3

CVD reactor

4

reservoir

5

powdery organic starting material

6

agitator

7

engine

8th

Auger

9

bearing tube

9 '

The End

10

flow channel

11

driving means

12

Trägergaseinspeiseleitung

13

infeed

14

muzzle

15

aerosol line

16

Evaporating body

17

steam line

18

gas distributor

19

process chamber

20

substratum

21

susceptor

22

vacuum pump

23

delivery channel

24

helical webs

25

Carrier gas stream

26

Valve

27

Mass Flow Controller

28

Vent line

29

second carrier gas

30

Carrier gas supply line

31

nozzle head

32

opening

33

Support

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 6037241 [0002]
• US 7501152 B2 [0003, 0007]
• US 2009/0039175 A1 [0004]

Claims (10)

Device with a storage container ( 4 ) for receiving a powder ( 5 ) and with a screw conveyor ( 8th ) to a metered amount of the powder ( 5 ) from the reservoir ( 4 ) to a feed point ( 13 ) at which feed-in point ( 13 ) the powder ( 5 ) into a carrier gas stream ( 25 ) to be used as suspended particles in the carrier gas stream ( 25 ) by an aerosol line ( 15 ), characterized in that the screw conveyor ( 8th ) one from the carrier gas stream ( 25 ) flowed through the axial flow channel ( 10 ) having. Device according to claim 1 or in particular according thereto, characterized by one of the aerosol lines ( 15 ) fed evaporator ( 16 ) in which the suspended particles are vaporized by the addition of heat to a vapor which is separated from the carrier gas flow ( 25 ) through a steam line ( 17 ) is transported away. Device according to one or more of the preceding claims or in particular according thereto, characterized by one of the steam line ( 17 ) gas distributors ( 18 ) of a CVD reactor ( 3 ), which has a process chamber ( 19 ) with a susceptor ( 21 ) has for receiving a substrate ( 20 ), which is coated by condensation of the vapor. Device according to one or more of the preceding claims or in particular according thereto, characterized in that the aerosol line ( 15 ) with the flow channel ( 10 ) is aligned or transversely to the flow channel ( 10 ) runs. Device according to one or more of the preceding claims or in particular according thereto, characterized by a in the region of the feed point ( 13 ) into the aerosol line ( 15 ) opening second carrier gas supply ( 30 ). Device according to one or more of the preceding claims or in particular according thereto, characterized by a in the carrier gas line ( 12 ) arranged valve ( 26 ) that can be alternately opened or closed to produce a pulsed carrier gas stream. Device according to one or more of the preceding claims or in particular according thereto, characterized by a in the carrier gas line ( 12 ) arranged mass flow controller ( 27 ) for dosing the carrier gas stream ( 25 ). Device according to one or more of the preceding claims or in particular according thereto, characterized by a in the reservoir ( 4 ) arranged agitator ( 6 ). Device according to one or more of the preceding claims or in particular according thereto, characterized in that the evaporator ( 2 ) has heat transfer surfaces heated by an evaporation body ( 16 ) are formed, which is in particular a solid state foam. Device according to one or more of the preceding claims or in particular according thereto, characterized in that the susceptor ( 21 ) Has means to the substrate ( 19 ) to cool.

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