EP2475801A1

EP2475801A1 - Evaporator, arrangement of evaporators, and coating system

Info

Publication number: EP2475801A1
Application number: EP10734086A
Authority: EP
Inventors: Kurt Burger; Guenter Schneider; Carsten Herweg
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2009-09-07
Filing date: 2010-07-08
Publication date: 2012-07-18
Also published as: KR20120048671A; CN102482761A; DE102009029236A1; WO2011026674A1; DE102009029236B4

Abstract

The invention relates to an evaporator (1) having a heat source for evaporating preferably organic materials in a vacuum for producing large-area coatings, in particular in the production of organic light-emitting diodes or organic solar cells and/or organic electronics, comprising an evaporator container (3) having an outlet opening (5) for evaporated material and an outlet channel (7) located downstream of the outlet opening (5) through which outlet channel evaporated material can flow to a material to be coated. According to the invention, the free cross section of the outlet opening (5) and/or the free cross section of the outlet channel (7) are/is adjusted during evaporation of the material. The invention further relates to an arrangement of at least two, preferably only two evaporators, a coating system, and the use of an evaporator and/or an arrangement of evaporators and/or a coating system.

Description

description

Evaporator, arrangement of evaporators and Beschichtungsunqsanlaqe prior art

The invention relates to an evaporator for evaporating, preferably organic, materials in vacuum for producing large-area coatings, in particular in the production of organic light-emitting diodes and / or organic solar cells, according to the preamble of claim 1, an arrangement of at least two, preferably exclusively two, evaporators according to claim 12, a coating installation according to claim 15 and the use of an evaporator and / or an arrangement of evaporators and / or a coating installation according to claim 16.

In the production of OLEDs (organic, light-emitting diodes) and organic solar cells, predominantly thermal evaporators are used for the deposition of active organic layers and transport layers in a vacuum. The organic materials may be evaporated in vacuo, depending on the starting material used, in a temperature range between about 100 ° C and about 700 ° C. For this purpose, predominantly punctiform evaporation sources are used, in which the material vaporized in a crucible is distributed in heated tubes, which consist predominantly of ceramic or glass, with or without additional inert gas flow over a larger area. For a large-scale, homogeneous distribution of the organic material, this results in a large distance between the evaporation crucible and the substrate to be coated. In the known evaporators, the temperature of the pipelines carrying the steam must be higher than the temperature of the evaporator in order to prevent the evaporated material from being deposited in the pipelines. Therefore, in known evaporators, to achieve acceptable coating rates, the evaporation temperature of the or- Ganic materials are deliberately significantly exceeded, usually by more than 50 ° C. However, even a small excess of the evaporation temperature may, in many organic materials relevant to the production of OLEDs or organic solar cells, lead to damage to the molecular structure, which results in a low efficiency of the components produced.

Another disadvantage of known evaporators is the relatively long heating up time until the individual components of the evaporator system reach their necessary temperature, which must be kept constant for the coating period in a narrow temperature window. The heating time of known evaporators for vaporizing organic materials is up to several hours. Known evaporators work primarily with resistance heaters, via which the ceramic or quartz glass evaporation vessel, which are in direct mechanical contact with the resistance heaters, are heated.

In the non-specialized field of ceramic evaporation technology, it is known to use line-shaped evaporator, in the evaporation vessel two symmetrically arranged in direct contact with the evaporating material heating rods are arranged. Such an evaporator is described in DE 42 04 938 C1. The known evaporator is suitable for evaporating high-melting glasses and / or ceramic materials, such as SiO or Si0. ₂ Due to the occurring during the evaporation process, high temperatures, sometimes up to 2500 ° C, the known evaporator is not suitable for use in the production of OLEDs and / or organic solar cells, since the organic material to be evaporated are destroyed due to the high temperature would. In addition, the heating of the heating elements in the known evaporator is clearly too long and the controllability, due to the inertia of the heating elements too large.

Often, especially in organic photovoltaics, it is necessary to apply mixed layers of multiple materials to a substrate or to dope materials during vapor deposition. This requires that at least two different materials must be deposited simultaneously. These different materials often have significantly different evaporation temperatures. Differences of up to 400 ° C are possible. In In practice, very different mixing ratios, depending on the function and properties of the layers, are used. This includes mixed layers with a mixing ratio of 1: 1 to doping layers with a mixing ratio of, for example, 1:99.

In order to set the deposition rate of a single evaporator and thus indirectly also the mixing ratio of vaporized materials from two evaporators, a temperature control is typically realized. In other words, the deposition rate (vapor deposition rate) is set by adjusting the temperature of the evaporator. However, a temperature control is relatively slow regardless of the structure of the evaporator. The time constants are usually at least in the minute range. This makes precise control of the mixing ratio through temperature control extremely difficult. Any necessary gradient layers, in which the mixing ratio is changed during the growth of the layer, are virtually not possible via a temperature control of the coating rate.

Disclosure of the invention

Based on the above-described prior art, the present invention seeks to provide an evaporator, preferably for organic material, with which the coating rate is quickly adjustable or changeable. Preferably, with the evaporator, the mixing ratio of at least two materials to be evaporated in an array of at least two

Evaporates quickly, i. not sluggish, adjustable. Furthermore, the object is to provide an arrangement of two evaporators, of which at least one has an optimized as described above adjustment for the coating rate. In addition, the object is to specify a correspondingly optimized coating system. Most preferably, the coating system should be designed for the realization of gradient layers.

This object is achieved with regard to the evaporator having the features of claim 1, with regard to the arrangement having the features of claim 12 and with regard to the coating installation having the features of claim 15. solves. Advantageous developments of the invention are specified in the subclaims. All combinations of at least two features disclosed in the description, the claims and / or the figures fall within the scope of the invention.

The invention proposes additionally or preferably instead of a temperature control for adjusting the coating rate of the evaporator to provide means for the free cross section of the, preferably slit-shaped, outlet opening of the evaporation vessel and / or the free cross section of the outlet opening downstream exit channel through which the vaporized Material can flow towards the substrate, to vary. In other words, in an evaporator designed according to the concept of the invention, the size of the volumetric flow of vaporized material impinging on the substrate is changed by a change in the freely flowable cross-sectional area of the outlet opening and / or by a change in the free flow cross-section of the

Outlet channel set. Most preferably, the width of the, preferably slot-like, outlet opening and / or the width of the, preferably funnel-shaped, outlet channel is changed at least at one point. With an evaporator designed according to the concept of the invention, it is possible, the vapor deposition rate quickly and continuously, preferably between 0% and

100% of the maximum vapor deposition rate, to change. In the case of the arrangement of the evaporator in an arrangement of at least two evaporators, two different materials with an arbitrary mixing ratio and gradient can be vapor-deposited.

DE 10 2008 043 634 filed by the applicant at the time of filing of the present application describes an evaporator for organic materials. This document is intended to be disclosed as belonging to the present disclosure, such that any feature or combination of features of this application should be combinable and claimable with any feature or feature combination of DE 10 2008 043 634. In particular, features of the

DE 10 2008 043 634 are disclosed as advantageous developments of the evaporator according to the invention apply, such that any features of

DE 10 2008 043 634 having the features of the main claim or of a subordinate be combinable and claimable claim of the present application.

In a development of the invention, it is advantageously provided that the free cross section of the outlet opening and / or the free cross section of the outlet channel can be changed or adjusted in such a way that the evaporation container is arranged to be movable relative to the outlet channel. Most preferably, the evaporation container for this purpose is arranged pivotable about a, preferably parallel to the longitudinal extension of the outlet channel and / or transverse to a direction of movement of the material to be coated, the rotation axis. By relative pivoting of the outlet opening to the outlet channel, the free by ström bare cross-sectional area of the outlet channel and the outlet opening, preferably between 0 and 100%, can be changed. At the maximum vapor deposition rate (coating rate), the outlet opening and the outlet channel preferably overlap completely, whereas at reduced vapor deposition rate only a partial overlap is given.

Very particularly preferably, the evaporator comprises a control and / or control unit or the evaporator is associated with a control and / or control unit, the free cross section of the outlet opening and / or the free cross section of the outlet channel in dependence of a target and / or actual value setting or regulating is formed. Most preferably, the free cross-sectional area is set as a function of an actual vapor deposition rate to be measured (coating rate) and / or in the case of realizing an arrangement of at least two evaporators depending on an actual, preferably measured mixing ratio. Most preferably, the control and / or control unit controls and / or controls a motor, preferably an electric motor, for adjusting, preferably pivoting, the evaporation container relative to the outlet channel.

In order to provide a well controllable, ie a low inertia, having evaporator, is provided in a further development of the invention that the evaporation vessel, which is designed to hold, preferably organic, materials is heated exclusively by heat radiation from the outside. In other words, at least one heat radiator is arranged in a vacuum outside the evaporation container of the evaporator, which evaporator only by heat radiation, so not by Konvekti- ons phenomena and / or heat conduction due to physical contact heated. Such an evaporator is not only easy to control with regard to the temperature of the organic material to be evaporated, but also short heating times of less than ten minutes with a very uniform heat distribution can be realized.

Particularly good results, with regard to the heating rate and the controllability of the temperature of the evaporation vessel or of the organic material to be vaporized, can be achieved by the use of at least one

Quartz radiator, in particular at least one double-tube quartz radiator can be achieved.

An embodiment in which the evaporation container is thin-walled is preferred. Particularly preferably, the wall thickness of the evaporation container is less than 3 mm, in order thus to further shorten the heating time and to be able to regulate the evaporator very precisely in narrow temperature limits owing to the resulting lower heat capacity and the consequent lower inertia. Advantageously, the evaporation tank is formed of metal, which leads due to the good thermal conductivity of the metal very quickly to a good heat distribution.

In order to be able to produce large-area coatings of organic material as uniformly as possible, an embodiment of the evaporator is preferred in which the evaporation container and / or the outlet opening, through which the vaporous organic material emerges in the direction of the substrate to be coated, is elongate. For this purpose, the outlet opening preferably has a linear extension. Advantageously, the longitudinal extension of the outlet opening corresponds, at least approximately, to the width of the substrate to be coated, which is moved relative to the outlet opening. Very particular preference is given to an embodiment in which the outlet opening is arranged such that the evaporated organic material can pass directly from the outlet opening to the substrate to be coated, ie without a change in direction. The distance between the line-shaped outlet opening and the substrate to be coated is preferably low. It is important to produce a very homogeneous, uniform vapor stream over the entire length with a linearly extended evaporator. Only in this way can a constant layer thickness be achieved over the entire width of the substrate to be coated. For a good, homogeneous temperature distribution is necessary, but usually not sufficient. The organic materials to be evaporated are usually powdery and remain in this state even at the evaporation temperature. Typically, such a powder is not exactly evenly distributed after filling in the evaporator tube, thereby an uneven vapor flow would result even over the same temperature length, if the tube would be opened in its full width in the extreme case. Through the throttle point now forms in the evaporator tube a slightly higher, over the length of uniform vapor pressure of the material. This ensures that the same vapor stream flows through the slot over the entire length. A narrow slot thus means a very homogeneous but low vapor flow. For an economical coating but the highest possible steam flow is desired. The slot width is therefore designed so narrow that the required homogeneity is safely met. In addition, a desired coating profile can be set via the variation (adaptation) of the slot width over the length. The slot can also be replaced by a hole pattern, this can be useful for a very long expansion of the evaporator for reasons of stability or ease of manufacture.

By realizing an elongated expansion of the evaporation container, it is easily scalable up to the meter range. Due to the linear expansion of the evaporator results in a direct coating path with a small distance between the evaporator and the large-area substrate, whereby the material to be evaporated at temperatures just above the evaporation point (depending on the material between about 100 ° C and about 700 ° C), can be evaporated, at the same time higher coating rates. Thus, for the first time, materials with a good vapor deposition rate can be evaporated, the decomposition temperature of which is only slightly above the evaporation temperature.

Ideally, the evaporation container is a tube, in particular oriented transversely to the direction of substrate movement, preferably with circular cross-section. Most preferably, the thin-walled tube is formed of metal and slotted in the direction of its longitudinal extension, preferably on the substrate facing the top of the tube. The longitudinal slot of the tube preferably forms the outlet opening, through which evaporated organic material can flow directly to the coating substrate. The slot-shaped outlet opening preferably has a small width relative to the pipe diameter. It thereby forms a throttle point which, with a suitable design, produces a very homogeneous distribution of the vapor stream over the entire length of the evaporator, even with an uneven distribution of the vapor deposition material in the evaporation tube. Due to the adjustable diameter and the length of the tube, preferably made of metal, a large storage volume of organic material to be vaporized can be obtained, so that when using the evaporator in inline coating systems a very long operating time until the necessary refilling (maintenance cycle) achieved becomes.

In a further development of the invention is advantageously provided that not only a single (heat) radiator is provided, but several distributed around the evaporation vessel arranged radiator, the position and the number of radiators is chosen so that the most homogeneous possible heating of Evaporation container and thus a homogeneous heating of the evaporated, organic material is ensured. Preferably, the radiator has a greater length extension than the evaporation vessel to prevent a temperature drop at the ends of the evaporation vessel.

It is very particularly preferred if the outlet opening of the preferably metallic evaporation container opens into an outlet channel which is preferably funnel-shaped, that is widened in the direction towards the substrate to be coated. The outlet channel serves to guide the organic material vapor toward the substrate to be coated and protects other components of the evaporator from parasitic coating. Preferably, the exit channel is arranged vertically and allows a linear passage for vaporized organic material.

In order to avoid a parasitic coating of components of the evaporator with organic material largely, is in the invention with Advantage provided that the temperature of the wall of the outlet channel is easily kept above the temperature of the evaporation tube, so that settling of organic material can be avoided on the Austrittskanalwandung. Because of the short path to be traveled by the vaporized organic material until it reaches the substrate, a temperature of the outlet channel wall lying above the evaporation temperature is sufficient. Preferably, the wall of the outlet channel is less than 20 ° C, most preferably less than 10 ° C warmer than the evaporation tank temperature. As already indicated, it is preferred if the at least one

Emitter is associated with a temperature control device that controls the heat radiation of the radiator. In order to obtain an actual temperature in the region of the evaporation container, preferably directly in the evaporation container, sensor means are advantageously provided which are signal-conducting connected to the temperature regulation device. As a sensor means, for example

Thermocouples or temperature resistors, such as PT100 are used.

Preferably, the temperature control device is designed such that it controls the temperature of the evaporation container such that the temperature of the evaporation container is only slightly above the evaporation temperature of the organic material, in particular in a temperature range between 100 ° C and about 700 ° C. In order to avoid an inadmissible heating of the surroundings of the evaporator, it is advantageously provided in a further development of the invention that the radiators, preferably together with the evaporation tank, are arranged in a coolable housing. Preferably, the housing is assigned a water cooling, in order to provide sufficient heat dissipation.

The invention also leads to an arrangement of at least two evaporators, of which at least one, preferably all, evaporators are designed as described above. Most preferably, the evaporators of the arrangement housed in separate and preferably separately cooled housings, whereby significantly different evaporation temperatures, preferably less than 400 ° C, realized without cross-influencing can be. By providing at least one evaporator with an adjustable, ie changeable, outlet opening and / or outlet channel cross-sectional area during the evaporation of the material, the vapor deposition rate of at least one material and thus the mixing ratio of a plurality of materials can be adjusted quickly and continuously, preferably regulated.

It is very particularly preferred in a further development of the invention that the at least two, preferably only two, evaporation containers of at least two, preferably only two, evaporators are aligned in parallel. That the, preferably slot-shaped, outlet openings are aligned parallel to each other and are in the transport direction of the substrate one behind the other.

It is particularly expedient if the evaporators, preferably their housings, are movable relative to one another, preferably pivotable, even more preferably about pivot axes running parallel to one another. By relative mobility, preferably pivotability, a more even or only partially by mixing the at least two, preferably only two, different materials can be ensured or adjusted. The relatively movable, preferably relatively pivotable, arrangement of the evaporator brings a total of more degrees of freedom in the process optimization with it.

The invention also leads to a coating system, preferably for in-line coating. The coating installation is characterized by at least one evaporator designed according to the concept of the invention and / or by at least one arrangement of at least two evaporators designed according to the concept of the invention. It is essential that a relative movement between substrate and evaporator or evaporator arrangement is realized. Most preferably, the, in particular slot-shaped, outlet opening of the at least one evaporation container of the at least one evaporator extends transversely to the direction of movement of the substrate. By using an evaporator designed according to the concept of the invention, an optimal, uniform planar coating can be realized by a linear movement of the substrate above the evaporator. In this case, the substrate is preferably transported or moved from roll to roll. The longitudinal Extension of the evaporator (transverse to the direction of movement of the substrate) can be preferably adapted to the substrate width to be coated, so that a homogeneous coating over the entire width of the substrate is ensured.

Further advantages, features and details of the invention will become apparent from the following description of preferred embodiments and from the drawings.

These show in:

1 is a perspective, partially sectioned view of a possible embodiment of an evaporator, in which the free cross-sectional area of the outlet opening and the free cross-sectional area of the outlet channel are adjustable during operation,

FIG. 2 shows a sectional view through an evaporator of a coating installation, and FIG

3 shows a sectional view through an evaporator arrangement of a coating installation, two evaporators being arranged so as to be pivotable relative to one another.

In the figures, like elements and elements having the same function are denoted by the same reference numerals.

FIG. 1 shows an evaporator 1 for vaporizing active organic materials in an OLED or solar cell manufacturing process or in a process for producing organic electronics. The evaporator 1 comprises a water-cooled housing 2, in which a tubular evaporation tank 3 is accommodated. The evaporation container 3 extends transversely to a substrate movement direction 4 of not shown, to be coated substrate.

The evaporation container 3 is a metal tube with a very small wall thickness, wherein the evaporation container 3 is longitudinally slit on its upper side facing the substrate, so that an elongated, line-shaped outlet opening 5 is formed, can flow through the vaporized organic material perpendicular to the longitudinal extent of the evaporation vessel 3 and perpendicular to the substrate movement direction 4 toward the substrate.

Around the evaporation vessel 3, a total of five radiators 6 designed as double-tube quartz radiators are arranged, which take care of uniform heating of the evaporation vessel 3. The longitudinal extent of the radiator 6 is greater than the longitudinal extent of the evaporation tank 3 to prevent temperature drops in the region of the ends of the tubular evaporation tank 3 safe.

As can be seen from FIG. 1, the radiators 6 are arranged at a distance from the evaporation container 3. The entire evaporator 1 is arranged in a vacuum, so that the heat transfer from the radiators 6 to the evaporation tank 3 takes place exclusively by thermal radiation.

Due to the thinness of the metallic tubular evaporation vessel 3 and due to the provision of radiators 6 for heating the evaporation vessel 3, good temperature controllability of the evaporator 1 is provided. For this purpose, the radiators 6 are associated with a temperature control device, not shown, which cooperates with sensor means (also not shown) arranged in the region of the evaporation container 3, preferably directly on the evaporation container 3, which serve to detect the actual temperature.

1, the outlet opening 5 opens into the funnel-shaped outlet channel 7 which, like the outlet opening 5, is elongated transversely to the substrate movement direction 4 and whose width extension in the substrate movement direction 4 increases with increasing distance from the outlet opening 5. The wall 8 of the rectilinear outlet channel 7 is heatable, wherein the temperature of the wall 8 is also controlled by means of the mentioned temperature control device and indeed to a temperature which is slightly above the temperature of the evaporation vessel 3. Due to the elongated expansion of the organic material filled evaporation tank

3, the evaporator 1 is easily scalable. The recording volume of the evaporation tank 3 can be adjusted in a simple manner by changing the diameter of the here in cross-section circular contoured evaporation tank 3.

As is further apparent from Fig. 1, the evaporation container 3 is arranged to pivot about a parallel to the outlet opening 5 extending pivot axis 9. By pivoting the evaporation vessel 3 about the pivot axis 9, the free cross section, i. the effective width of the slot-shaped outlet opening and the free cross section of the outlet channel 7 and the free cross section of a lower inlet opening 10 of the funnel-shaped outlet channel 7 are changed by the overlap region between the outlet opening 5 and inlet opening 10 and outlet channel 7 is varied.

For pivoting the evaporation container 3 about the pivot axis 9, an electric motor 1 1, which is indicated only schematically, is provided, wherein the electric motor 1 1 is controlled by a control and / or control unit, which the electric motor based on user input and / or on the basis of a , preferably to be measured, actual value.

As is apparent from Figs. 1 and 2, the discharge channel 7 bounding sheet extends to both longitudinal sides of the inlet opening 10 a piece in the circumferential direction around the evaporation vessel 3 around, so that the outlet opening, if this under one of the circumferentially extending , Curved portions 17 of the sheet is pivoted, is completely covered or closed to prevent the escape of evaporated material from the outlet opening 5 at least substantially.

FIG. 2 shows a coating installation 13 with an evaporator 1. The evaporator 1 is arranged below a substrate 14 to be vaporized, which is movable transversely to the longitudinal extent of the outlet opening 5 in a substrate movement direction. Schematically indicated is a cloud of vapor 15 of vaporized, organic material which exits through the outlet opening 5 of the evaporation vessel 3, the inlet opening 10 of the outlet channel 7 passes through and migrates through the outlet channel 7 upwards in the direction of the substrate 14. As is further apparent from FIG. 2, the evaporation container 3 can be pivoted in both circumferential directions about a pivot axis 9 in order to be able to vary the overlap region between the outlet opening 5 and the inlet opening 10.

FIG. 3 shows a coating installation 13 with an arrangement 16 of two essentially identical evaporators 1. The structure of the evaporator 1 corresponds, for example, to the structure of the evaporator 1 shown in FIG. 1 or FIG. 2. It is thus possible with both evaporators 1 to set the deposition rate (coating rate) and thus the mixing ratio of two materials.

As is further apparent from FIG. 3, both evaporators 1, or more precisely the cooled housings 2 of the evaporators 1, can each be pivoted about an unillustrated axis of rotation, so that a pivoting angle oc can be varied, thus providing more

Have degrees of freedom in process optimization. In Fig. 2, both evaporators 1 are in an initial position (not pivoted - solid lines) and on the other hand in a deflected, i. pivoted, position (dashed lines) shown.

Claims

claims

1 . Evaporator, with a heat source for evaporating, preferably organic, materials in vacuum for producing large-area coatings, in particular in the production of organic light-emitting diodes or organic solar cells and / or organic electronics, comprising an evaporation tank (3) having an outlet opening (5) for vaporized material and an outlet channel (7) arranged downstream of the outlet opening (5), through which vaporized material can flow to a material to be coated, characterized in that the free cross section of the outlet opening (5) and / or the free cross section of the outlet channel (7 ) are adjustable during evaporation of the material.

2. evaporator according to claim 1,

characterized,

in that the evaporation container (3) is arranged, preferably pivotable, relative to the outlet channel (7) and that the free cross section of the outlet opening (5) and / or by relative movement, preferably relative pivoting, of the evaporation container (3) relative to the outlet channel (7) the outlet channel (7) is adjustable.

3. Vaporizer according to one of claims 1 or 2,

characterized,

that a control and / or control unit (12) for adjusting the free cross section of the outlet opening (5) and / or the free cross section of the outlet channel (7) as a function of a desired and / or actual value, preferably an on steam rate or a mixing ratio is provided.

4. evaporator according to one of the preceding,

characterized,

in that the heat source is a radiator (6), which is arranged outside the evaporation container (3), the evaporation container (3) from the outside, heated exclusively by thermal radiation, preferably a quartz emitter, in particular a double tube quartz emitter.

5. Evaporator according to one of the preceding claims,

characterized,

that the, preferably metallic, evaporation vessel (3) is thin-walled.

6. Evaporator according to one of the preceding claims,

characterized,

the evaporation container (3) and / or the outlet opening (5) have an elongated, in particular linear, extension.

7. Evaporator according to one of the preceding claims,

characterized,

the evaporation container (3) is designed as a preferably longitudinally slotted, in particular metallic, tube.

8. Evaporator according to one of the preceding claims,

characterized,

that a number and arrangement of radiators (6) ensuring homogeneous heating of the evaporation container (3) is realized.

9. Evaporator according to one of the preceding claims,

characterized,

in that the outlet channel (7) is funnel-shaped and in that through the outlet channel (7) the vaporized material can flow directly onto a substrate (14) which is moved relative to the outlet channel (7).

10. Evaporator according to one of the preceding claims, characterized

a wall (8) of the outlet channel (7) can be heated, preferably to a temperature which is slightly above an evaporation temperature of the organic material.

1 1. Evaporator according to one of the preceding claims,

characterized,

in that sensor means are provided for monitoring the temperature in the region of the evaporation container (3) which are connected to a temperature control device in a signal-conducting manner.

12. Evaporator according to one of the preceding claims,

characterized,

that a, in particular by means of water, coolable housing (2) is provided.

13. Arrangement of at least two evaporators (1), of which at least one is designed according to one of the preceding claims.

14. Arrangement according to claim 13,

characterized,

the evaporation containers (3) of the evaporators (1) are aligned in parallel.

15. Arrangement according to one of claims 13 or 14,

characterized,

in that the evaporators (1), preferably their housings (2), are movable relative to one another, preferably pivotable, in particular around pivot axes (9) running parallel to one another.

16. coating system with, in particular for in-line coating, with an evaporator (1) according to one of claims 1 to 12 and / or with an arrangement of at least two evaporators (1) according to one of Claims 13 to 15, and comprising means for generating a relative movement between the substrate to be coated (14) and the at least one evaporator (1).

17. Use of an evaporator (1) according to any one of claims 1 to 12 and / or an arrangement according to any one of claims 13 to 15 and / or a coating system (13) according to claim 16 for vaporizing organic materials in vacuo for the production of large-scale coatings gene in the production of organic light-emitting diodes or organic solar cells.