DE102006061585A1 - Method for rotation coating of disk-shaped substrate involves applying viscous liquid on substrate and substrate is rotated for distributing liquid - Google Patents

Abstract

The method involves applying a viscous liquid on the substrate (2) and substrate is rotated for distributing the liquid. The layer thickness of the liquid applied on the substrate is measured and is regulated by varying the viscosity of the applied liquid and/or by the number of revolutions of the rotation in dependence of the measured layer thickness. An independent claim is also included for a device for rotation coating of a disk-shaped substrate.

Description

The The invention relates to a method and a device for surface coating by rotation or spin-coating of disc-shaped substrates, such as optical data carriers, with a liquid. In particular, the invention relates to the production of an optical Cover layer (Coverlayer). In spin coating, the liquid, such as. a dye, a liquid paint or a fluid Glue, distributed by centrifuging on the surface.

at the production of optical data carriers, such as CDs, DVDs or Blu-ray discs, must the substrate surface coated, for example, painted, or for bonding two Substrates one as possible uniform thick adhesive layer are applied to one of the substrates. This usually happens by spincoating; this is arranged on a substrate carrier Substrate rotated, and the liquid to be applied is applied near the axis of rotation of the substrate to be coated and by the centrifugal force over the surface of the substrate.

One Disadvantage of this method is that the thickness of the applied Layer only inaccurately controlled or can be predetermined. Farther It may after spinning to an unevenly thick distribution of the applied Coating (paint or glue) come on the substrate. For example is an increase on CDs the paint density to the outer edge ascertainable. When spincoating in particular viscous paints or adhesives comes it at the edge of the substrate through adhesion and surface tension to an elevation of Liquid. Due to the liquid-gas interface that occurs at the edge is the liquid striving to their surface to minimize the gas.

The EP-A-1 363 280 describes a method of making an optical disc by spin coating with a coating liquid containing an actinic radiation curable resin to reduce thickening of the coating at the outer peripheral regions of the substrate. For this purpose, the coating liquid is first distributed on the substrate surface by centrifuging; Thereafter, the resin layer for curing is irradiated with actinic radiation while reducing the rotational speed of the substrate.

In the WO 2004/050261 A1 For example, there is described an apparatus and method for dispensing a viscous fluid over a surface of a substrate, wherein the substrate is selectively thermally conditioned prior to spin coating. The WO 2004/064055 A1 describes a spin coating process in which the applied liquid layer is heated in a defined manner.

task The present invention is an improved method for To provide coating by spin coating, with the thickness of the coating in particular at a narrow tolerances Layer thickness distribution over controlled the entire radius of the substrate and preferably a constant thickness over the entire radius can be achieved. Disturbing external influences, which affect the layer thickness or layer thickness distribution, should be compensated. Furthermore, by adhesion and surface tension occurring strong elevation at the outer edge of the substrate can be avoided.

These Tasks are solved with the features of the claims.

The The invention is based on the basic idea, the layer thickness or the layer thickness distribution of the liquid to be applied to regulate specifically during spin coating or centrifuging. The applied during spin coating near the axis of rotation liquid becomes radially inward due to the centrifugal force generated by the rotation outside on the surface of the substrate. The resulting layer thickness becomes, for example the ambient temperature and the viscosity of the applied liquid affected. Also can irregularities in the layer thickness distribution on the substrate. Especially it comes due to the effects described above by adhesion and Surface tension at Edge or at the edge of the substrate to an elevation of the liquid. Total layer thickness and / or locally targeted to influence, according to the present invention the viscosity of the liquid or the rotational speed varies selectively. This will be in dependence controlled a measurement of the layer thickness.

Around specifically influence the layer thickness of the liquid to be applied to be able to is immediately after the application of the liquid layer on a Substrate or after subsequent exposure measured with UV radiation, the layer thickness. This should be at least two positions of the substrate happen. During the measurement, this can be Substrate are rotated, so an average of the layer thickness at a defined distance from the center of the substrate. This layer thickness measurement must be very precise and independent of be the inclination or the tilt and the position of the substrate. The measurement the layer thickness is preferably carried out with a white light spectrometer, the is arranged perpendicular to the substrate.

Depending on This measurement is the viscosity the liquid to be applied and / or the rotational speed varies selectively to the layer thickness, achieved in particular in the subsequent coating operations will be able to regulate specifically. This can be achieved by varying the viscosity by heating or cooling the applied layer. The viscosity can be uniform over the Radius of the substrate can be varied so as to total the layer thickness to control.

The viscosity a liquid is generally temperature dependent, so by heating and cooling the viscosity can be influenced. By deliberately heating or cooling on the substrate surface to be distributed liquid while of spin coating, the viscosity can be influenced so that control the thickness or the thickness distribution of the liquid on the substrate leaves. The for a temperature increase required amount of heat can the liquid by heat radiation, by heat conduction, So targeted temperature control of the substrate, or by convection, ie targeted introduction of a tempered gas flow to the substrate, supplied become. A cool down the liquid let yourself by heat conduction and convection.

The Layer thickness can be Also control by varying the speed during spin coating. For example, at a lower outside temperature, the speed elevated be high, resulting from the low outside temperature viscosity compensate.

at an uneven layer thickness distribution can the viscosity the liquid to be applied still locally be varied. For example, an increase in the layer thickness to the outside to avoid, the liquid when hurling the possibility be given to drain more easily. This can be done by local change the viscosity the liquid for example, by a local suitably adjustable temperature control can be achieved. If So for example the viscosity the liquid decreases towards the edge, the formation of an elevation at the outer edge can be avoided there the liquid due to the lower viscosity can drain off easier there.

In addition to The controlled control of the viscosity can, to the special conditions on Substrate edge, i. at the radially outermost Part of the surface to be coated, to take account of there targeted and local limits the viscosity be greatly reduced. This can be done for example by an infrared lamp done through which the edge of the substrate with a focused Infrared beam is irradiated.

The inventive method Can be used for coating with a variety of liquids in the manufacturing process optical disk needed will be used. Such is the use of the method according to the invention for painting substrates, for coating with dyes, in particular with in organic solvents dissolved Dyes, as they are easily described for example in the production optical disk be used, or for applying adhesives, in particular UV curable Glue suitable. In all these cases can the viscosity by temperature change changed become. Further, the thickening of a solvent-containing liquid and with it increase the viscosity by partial evaporation of the solvent by heating the liquid possible. For UV-curing Adhesives can by dosed irradiation the polymerization reaction to an increase initiated the viscosity and / or accelerated or slowed down to the appropriate variation or viscosity become. The use of the method according to the present invention is particularly preferred in the manufacture of an optical co-translator.

The device for adjusting the viscosity can irreversibly or reversibly influence the viscosity, depending on the fluid used (adhesive, lacquer, solvent-containing fluid):
When using a solvent-containing fluid is increased by increasing the temperature of the solvent, depending on the temperature more or less strongly evaporated, so that the viscosity increases more or less strong; Similarly, when using a UV-curing fluid by more or less strong UV irradiation, the polymerization is driven more or less vigorously, thus increasing the viscosity more or less. These two processes are irreversible, ie the viscosity increases steadily or remains constant at best.

at Fluids for which the above irreversible processes have no or play only a minor role, is also a reversible, temperature-dependent change the viscosity possible, i.e. not just an increase the viscosity by lowering the temperature, but also a lowering of the viscosity by temperature increase and vice versa, such as with pseudoplastic liquids.

Under consideration of these properties, the means for adjusting the viscosity is selected, e.g. the type of radiation, such as heat radiation, IR radiation or UV radiation and their local distribution on the surface of the substrate, for optimum distribution of the fluid as uniform as possible on the surface to reach the substrate.

With the method according to the invention a targeted control of the layer thickness during spin coating possible. Furthermore, the layer thickness can be controlled by locally varying the viscosity of the liquid to be applied as a function of the distance to the center or to the axis of rotation of the substrate, for example falling radially outwards. Thus it can be avoided that during spin coating, the layer thickness increases outwards and is generally dependent on the temperature of the process space and the viscosity of the base material. Such external influences that interfere with the production of a tightly tolerated layer thickness can be compensated for by the method of the present invention. A strong elevation at the outer edge of the substrate can be avoided. By means of the invention, the spin coating can thus be carried out more economically, since rejects are reduced.

Farther By the present invention, a device for spin coating a disc-shaped Substrate provided.

The Invention will be explained in more detail below with reference to the figures, wherein

1 schematically a cross-sectional view of an embodiment of the device according to the invention and

2 a flow diagram of the method according to the invention for spin coating shows.

at The spin coating is initially the viscous to be applied liquid on the substrate to be coated, which on a rotatable substrate carrier or Spin chuck is located near the middle of the center. the axis of rotation of the substrate applied. Due to the rotation of the substrate is the applied liquid distributed over the substrate surface.

This in 1 The device according to the invention has separately a region A, in which the layer thickness measurement is performed, and a region B, in which spin coating is performed. In region B, a device for varying the viscosity by tempering the layer to be applied is provided. The conceivable possibility of realizing both areas in a single device is disadvantageous in that it must be ensured that the required cooling of the substrate before the layer thickness measurement, since the heat input in the temperature control can be very high.

The substrate 2 is in area A of a bracket 1 carried. In area A, an additional (in the 1 not shown) for rotating the substrate 2 be provided so that an average measurement of the layer thickness can be obtained at a certain distance from the axis of rotation. The layer of viscous liquid is on the substrate surface 3 applied. The thickness of this layer is determined by the facilities 4 at different locations with different radial distance to the central axis of the substrate surface 3 measured. This can be done for example by means of a spectrometer. In area B is a rotatable substrate carrier or spin chuck 1' provided on which the substrate to be coated 2 is arranged. By the drive device or the engine 7 may be the substrate carrier 1' be offset in rotation according to the arrow R. Above the substrate surface 3 there is a facility 6 for influencing the viscosity of the on the substrate surface 3 located liquid layer.

The measuring devices 4 give the measurement data to a controller 5 over the entrances 51 . 52 one. The control device 5 is generally a microcomputer that processes the input data in a control algorithm. Depending on the facilities 4 measured layer thicknesses, controls the controller 5 the device 6 for influencing the viscosity and / or the speed of the motor 7 over the exits 53 and 54 , Thus, the layer thickness of the on the substrate 2 applied coating can be regulated.

The device 6 for local influencing of the viscosity can also be performed as a radially adjustable tempering device having, for example, a plurality of infrared radiators. When using multiple infrared radiators, the location-dependent variation of the heating can be achieved that the power of the radiator is variable. In addition, a radial and azimuthal intensity distribution can be adjusted by means of adjustable diaphragms. Furthermore, a device can be used with which at the same time can heat the entire surface of the substrate to be coated. With such a device can target specific areas of the substrate 2 both locally, ie radially and azimuthally, as well as temporally variable, in particular depending on the rotational speed of the substrate 2 to be heated. When using infrared radiators, the wavelength of the radiation source should be approximately in the range in which the liquid absorbs maximum.

To an undesirable excessive elevation of the coating on the outer edge of the substrate 2 To avoid this, an infrared radiator (not shown) may additionally be used, which, when being centrifuged off, the liquid at the edge of the substrate 2 heated by means of a focused infrared beam and thus greatly reduces the viscosity of the outermost edge liquid. Thus, the excess liquid accumulated there can easily be thrown off.

The 2 shows a flow diagram of the method according to the invention for spin coating. In particular, the in-line control for the production of a co-translator is described. This in 2 The flow chart shown describes the method used in a device which is divided into two main areas I and II, each having a sub-area B for the coating and a sub-area A for the measurement, similar to FIG 1 shown. Preferably, a measurement is actually carried out only in the sub-area A of the second main area, the sub-area A of the first area then serves only for cooling and drying the applied layer. Thus, a sub-layer is applied in each of the two main areas, but only the total thickness of this layer is measured and controlled.

Furthermore, a first rotatable substrate carrier and a second rotatable substrate carrier are respectively provided in the lower region B of the first and second main regions. The first rotatable substrate carrier has an infrared radiator for tempering during spin coating. At the second rotatable substrate carrier no tempering is provided. The terms IR emitter 1 and IR emitter 2 in the 2 denote the tempering device on the first rotatable substrate carrier in the lower region B of the first and second main area. The term pot 2 in 2 refers in each case to the second rotatable substrate carrier in the main areas I and II, which are used only for rotation but not for temperature control.

During the Data conditioning is preferably in each case a measured value on the inner radius (m1), taken in the middle (m2) and on the outer radius (m3). From the measured values of several discs, corresponding mean values M1, M2 and M3 educated.

The Number N1, N2 and N3 of the discs used to form the respective averages be used, hang from the deviations of previously determined average values M1old, M2alt and M3deviates to the respective target values W1, W2 and W3, respectively. The measured values are checked for plausibility, that is called You need to within calculated limits. These limits result from the deviations of the old means M1alt, M2alt and M3alt to the respective setpoints W1, W2 or W3 and a specified Measuring tolerance t. If only one of the three measured values lies outside the bandwidth, then the disc is no longer for the scheme used. If the measured values are within the Limits, averages M1, M2 and M3 are formed over N1, N2 and N3 disks, respectively.

The in the previous control cycle determined manipulated variable for the Abschleudergeschwindigkeit on Pot 2 (Y1.1alt) now decides whether the regulation at the inner radius sets the speed of the spin-off or the spin-off time. Is this old manipulated variable Y1.1alt within specified limits (G1.1), the speed of the spin-off will be in the regulation included. The Abschleuderzeit corresponds, however, the set reference discharge time (R1.2). Is the old one Manipulated variable, however outside the limits, the spin speed is at the limit (G1.1) and the spin-off time is included in the control.

In In the actual control, the amplification factors of the controllers are predefined for the available manipulated variable Factors (kp1, kp2, kp3), as well as the deviations of the mean values (M1, M2, M3) to the respective desired values (W1, W2, W3), calculated. Using the calculated gain factors (Kp1, Kp2, Kp3) are now the available manipulated variables Abschleudergeschwindigkeit or Abschleuderzeit pot 2, ie on the rotatable substrate carrier without Tempering device in the main area II, the power IR emitters 1 in the main area I and the power IR emitter 2 in the main area II according to the following Formulas influenced:

Controller 1.1 Discharge speed Pot 2:

• Y1.1 = Y1.1alt - Y1.1alt · (1 - X1 / W) · Kp1

Controller 1.2 Discharge time pot 2:

• Y1.2 = Y1.2alt - Y1.2alt · (1 - X1) / W) · Kp1

Regulator 2 power IR emitter 1:

• Y2 = Y2alt - Y2alt · (1 - (X2 - ΔX2) / X1) · Kp2

Regulator 3 power IR emitter 2:

• Y3 = Y3alt - Y3alt · (1 - (X3 - ΔX3) / X1) · Kp3

When Last step, a limit check is performed. Lie the determined manipulated variables Y1.1, Y1.2, Y2 and Y3 within specified limits G1.1, G1.2, G2 or G3, the determined manipulated variables become effective. Lie outside of these specified limits, so instead of the determined Control variables default values used to control the process.

The in 2 Thus, the control algorithm illustrated has the task, based on preferably three actual values, of keeping the coverlayer layer thickness constant. For this purpose, the four control variables Ab spin pot 2, spin pot 2, power IR emitter 1 and power IR emitter 2, depending on the individual actual values influenced.

The inventive method can be used in all spin coating processes, for example also for coating a DVD or a Blue-Ray-Disk. Particularly Case of production z. B. a 100μm cover layer A blue-ray disc can spin-coat the viscosity of the UV-curable Lacks with the help of an above-described, radially adjustable temperature control be influenced so that precisely adjustable and uniform layer thickness within the required tolerances. After coating centrifuging, the paint should be immediately cured by UV irradiation, to avoid the formation of a bead on the edge during the cooling of the paint. additionally can this elevation on Edge by the above-described intensive irradiation of the edge area during the Throwing off or even while UV curing be prevented. The beginning and the duration of the irradiation depend on the coating substance used and other parameters, such as for example, the rotational speed of the substrate. The However, the duration of the irradiation is decoupled from the Abschleuderzeiten.

The inventive method can also stick to the production of DVDs or Blue-Ray discs two (or more) sub-substrates are used in the a slight increase in the thickness of the adhesive layers to the outer edge can be observed. With the method according to the invention, it is possible to viscosity of glue in dependence From the distance to the axis of rotation to influence so that a constant thick adhesive layer over the entire radius is achieved. Thereafter, a second substrate half (or Sub-substrate) placed on the constantly thick adhesive layer and thus forming a constantly thick intermediate layer with the first substrate half or glued to the first sub-substrate. This constancy of through The intermediate layer formed by the adhesive is especially in the HD format DVD required.

Claims (24)

Method for spin-coating a disc-shaped substrate with the steps: Applying a viscous liquid on the substrate and rotating the substrate to disperse the liquid, measure up the layer thickness of the liquid applied to the substrate and Control the layer thickness of the applied to the substrate liquid by varying the viscosity of the to be applied liquid and / or the speed of rotation as a function of the measured layer thickness. The method of claim 1, wherein the layer thickness for subsequent Coating processes is regulated. A method according to claim 1 or 2, wherein the viscosity is Heat or cooling the liquid to be applied is varied. The method of claim 1, 2 or 3, wherein the applied Substance a paint, such as a UV-curing Paint, has. The method of claim 1, 2 or 3, wherein the applied liquid a solvent-containing Liquid, in particular a dye dissolved in an organic solvent having. Method according to one of the preceding claims, wherein the viscosity is varied by infrared radiation. Method according to one of claims 1, 2 or 3, wherein the applied liquid an adhesive, preferably a UV-curing adhesive. The method of claim 7, wherein the viscosity is Irradiation with UV light is varied. Method according to one of the preceding claims, wherein the layer thickness is measured by spectroscopy. Method according to one of the preceding claims, wherein the layer thickness at least two positions with different Radial distance from the axis of rotation is measured. Method according to one of the preceding claims, wherein the substrate during the measurement of the layer thickness is rotated. Method according to one of the preceding claims wherein the viscosity the liquid locally, in particular is varied radially and / or azimuthally. The method of claim 12, wherein the viscosity of the applied liquid at the radially outer edge of the substrate is reduced. Method according to one of the preceding claims, wherein the disc-shaped Substrate an optical disk is. Method according to one of the preceding claims, wherein the disc-shaped Substrate is a CD or a DVD or a Blu-ray Disc half-substrate. Apparatus for spin-coating a disk-shaped substrate ( 2 ), in particular according to the method according to one of claims 1 to 14, with a rotatable substrate carrier ( 1 ) through which the substrate ( 2 ) and set in rotation, a facility ( 6 ) for varying the viscosity of the applied liquid as a function of the measured layer thickness of a device ( 4 ) for measuring the layer thickness of a by spin coating on the substrate ( 2 ) applied viscous liquid and a control device ( 5 ) for controlling the device ( 6 ) for varying the viscosity and / or for controlling the rotational speed of the substrate carrier ( 1 ) depending on the measured layer thickness. Apparatus according to claim 16, wherein the means for varying the viscosity comprises means for heating the substrate surface ( 13 ) having. The device of claim 17, wherein the device for heating having an infrared radiator. Device according to one of claims 16 to 18, wherein the device ( 6 ) has a UV emitter for varying the viscosity. Device according to one of claims 16 to 19, wherein the device ( 4 ) has a spectrometer for measuring the layer thickness. Device according to one of claims 16 to 20, wherein the device for varying the viscosity a facility for location-dependent, in particular radial and / or azimuthal variation of the viscosity. Apparatus according to any one of claims 16 to 21, wherein the means for varying the viscosity comprises means for varying the viscosity at the edge of the substrate ( 1 ) having. Device according to one of Claims 16 to 22, with a device for reducing the viscosity of the liquid at the edge of the substrate ( 2 ). Apparatus according to claim 23, wherein the means for reducing the viscosity of the liquid at the edge of the substrate ( 2 ) an infrared radiator for irradiating the edge of the substrate ( 1 ) with a focused infrared beam.