Glass manufacturing – Processes – With program – time – or cyclic control
Reexamination Certificate
2000-01-12
2003-02-04
Vincent, Sean (Department: 1731)
Glass manufacturing
Processes
With program, time, or cyclic control
C065S032100, C065S033200, C065S157000, C065S350000
Reexamination Certificate
active
06513347
ABSTRACT:
BACKGROUND OF THE INVENTION
The present invention is directed to a technique for heat conditioning glass substrates, which are subsequently surface treated by vacuum surface treatment. The invention departs from requirements which are encountered when large glass substrates for display panel production from 300 cm
2
up to 1 m
2
and more have to be heat conditioned.
PRIOR ART
For subsequent vacuum coating surfaces of glass substrates in the flat panel industry, as by aluminum sputtering, water molecules must previously have been removed from the surface of the substrate. This is customarily performed by heating which additionally degases and cleans the surfaces from further surface contaminations.
To perform such heat conditioning it is known to convey a multitude of substrates into an oven which is heated e.g. up to 250° C. The oven is operated at vacuum atmosphere. Thereby, considerable time lapses, until the substrates reach the final desired temperature. So as not to deteriorate the high throughput of the overall vacuum processing plants by such low-speed process, a multitude of substrates must be heat conditioned simultaneously, whereas other processes of the overall processing plant are performed in single substrate mode. Thus, one can say the single processed substrates are-collected for heating. If other processes of the plant operate in batch mode, each batch then representing one workpiece, the described approach necessitates accordingly multiple batch heating.
SUMMARY OF THE INVENTION
It is a prime object of the present invention to provide for a heat conditioning process and heat conditioning chamber by which an improved heating rate of the glass substrate is achieved compared with prior art attempts, so that, especially in a cluster-type processing vacuum plant, heat-conditioning may be performed by single substrate operation without limiting overall throughput of the plant. Thus, the inventive technique shall fully comply in time consumption with single workpiece treatment, be it single substrate treatment or single batch treatment, where “a batch” is considered as “one workpiece” with respect to heat treatment. This object is realised by the inventive process for heat conditioning at least one glass substrate for subsequent surface treatment by at least one vacuum surface treatment process, as for subsequent vacuum coating, which inventive process comprises the steps of
introducing said substrate into a chamber;
having said chamber evacuated before the introducing or evacuating said chamber after the introducing;
predetermining the spectral absorption characteristics of the substrate in the infrared spectral band and including its lower slope, where absorption rises with increasing wavelength;
selecting at least one lamp with a radiation spectrum band overlapping said absorption spectrum of said substrate at least along a predominant part of the slope and/or towards longer wavelengths;
exposing the substrate in the evacuated chamber to radiation from the lamp directly via the evacuated atmosphere of said chamber.
The infrared spectral band is here defined by
500 nm≦&lgr;≦10000,
wherein &lgr; is the wavelength of light.
In a preferred mode of the inventive process a lamp is selected with a radiation peak at a wavelength &lgr;
r
1500 nm≦&lgr;
r
,
thereby there is preferred
1500 nm≦&lgr;
r
≦6000 nm,
thereby especially
2000 nm≦&lgr;
r
≦6000 nm,
and especially preferred
2500 nm≦&lgr;
r
≦4500 nm.
It is further preferably proposed to reflect radiation transmitted through the substrate back towards the workpiece, so as to minimise thermal loss.
Also it would be possible to provide therefor a rigid structure with a reflecting surface, in a further preferred form of realisation reflecting is performed by means of a foil-like or mise thermal lose. The material of the reflecting surface is thereby preferably selected so as to reflect light in the radiation spectral band of the lamp to at least 50%, even to at least 80%, thereby absorbing minimal energy. As material of a reflecting surface preferably aluminum is selected. In combination with such Aluminum &lgr;
r
should be selected above 1500 nm to minimise absorption of lamp radiation and thus to minimise system inertia.
Especially with Aluminum as material of the reflecting surface more than 99% of radiation in the near infrared and infrared spectral band may be reflected and approx. 90% of radiation in the visible spectral range.
In spite of the fact that double-side direct exposure to respective lamps is possible in a preferred mode, heating the substrate is performed by direct exposure to the lamp radiation from one side and reflecting radiation from the other side back to the substrate, which has the advantage that the substrate is thermically loaded substantially equally and more efficiently from both sides, which prevents thermal stress warping and deterioration of the substrate by inhomogeneous heat loading.
Thereby it must be emphasised that thermal gradients in the substrate would lead to different magnitude expansion within the substrate, thereby leading to bending of the glass up to breakage. This is clearly to be avoided.
To further prevent overheating of the reflector arrangement, in a further preferred mode the reflector arrangement, and especially a foil-like or sheet-like reflector arrangement, is cooled from its side unexposed to the radiation from the lamp. This is preferably performed via a rigid chamber wall distant from and adjacent to the reflector arrangement and fluid-cooling the rigid wall, which is preferably made of stainless steel. This cooling effect is preferably further improved by providing a black-body radiation coating on that side of the reflector arrangement which is not exposed to the radiation of the lamp.
So as to improve heating homogeneity along the substrate, especially along a large substrate, it is proposed to provide more than one lamp and to preferably provide such lamps at respectively selected different mutual distances, which distances are preferably adjustable.
Up to now the present invention was optimised with respect to heating efficiency. Nevertheless, cooling efficiency may be as important as heating efficiency in view of the overall heat conditioning treatment cycles. To optimise cooling efficiency the heat transfer mechanism is—for cooling—switched to completely different physics, namely from radiation heating to conductance cooling. In a preferred mode of operating in the cooling cycle, a heat conducting gas, as preferably a noble gas, as especially Helium, is introduced into the treatment chamber. Especially as the outer wall of the chamber is cooled, heat conductance leads to rapid decrease of substrate temperature.
With respect to evacuating the treatment chamber it is recommended—for heating operation—to pump it down to a vacuum where heat conductance practically ceases. This to avoid thermal losses to the surrounding and to rise heating efficiency. Further, the lamp is preferably positioned beneath the substrate to prevent particle contamination of the substrate. The heating rate may be controlled by means of a negative feedback control loop, thereby using preferably a pyrometer sensor directed towards the substrate to detect its actual thermal state to be compared with a desired thermal state value. The resulting comparison result, as a control difference, acts on the lamp control to adjust its power and/or thereby especially to shift its radiation spectrum, and/or on a gas inlet control valve so as to control thermal conductivity and thus thermal loss and/or on the control of an evacuating pump. It has to be noted that by controlling the electrical supply of the lamps their radiation spectrum may be shifted, which again leads to adjustments of the thermal state of the substrate.
We recommend the use of so-called “black-type lamps” sold by the firm USHIO Inc. or of carbon-radiator lamps as available from the firm HERAEUS Inc.
Thus, more generically halogen lamps are preferred with a black coating on the glass bulb. Thereby transfor
Deschamps Arnaud
Galdos Aitor
Mueller Willi
Rhyner Stephan
Balzers Hochvakuum AG
Vincent Sean
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