US3610741A - Flame spraying aluminum oxide to make reflective coatings - Google Patents

Abstract

A method of making a hard, durable, diffuse reflecting surface of coating comprising flame spraying s synthetic sapphire (a pure monocrystal of aluminum oxide) on a surface, said coating having a reflectance that deviates less than 4 percent over the wavelength range of from 0.3 to 3.0 microns.

Description

United States Patent [72] Inventors John M. Davies [56] References Cited Cochituate; I UNITED STATES PATENTS zaglemyh' Mm 2,585,128 2/1952 Howe et al 1 17/35 v Q g 'i i 3,310,423 3/1967 lngham 331/945 x 1 e an. 123] Division 61' Ser. N0. 406,626, 00!. 26, FOREIGN PATENTS I964, abandoned 440.287 12/1935 Great Britain 1 17/35 [45] P t ed 0 5,1071 745,257 2/1956 Great Britain..... 73 Assignee Th U m sum of America as 852,484 10/1960 Great Britain represented by the Secretary of the Army Primary Examiner-David Schonberg 7 Assistant Examiner-Toby H. Kusmer Anomeysl-iarry M. Saragovitz. Edward J. Kelly, Herbert 54 FLAME SPRAYING ALUMINUM OXIDE TO MAKE and Lawrence Labadm' REFLECTIVE COATINGS 2 Claims 1 Drawing ABSTRACT: A method of making a hard, durable, diffuse [52] US. Cl 350/320, reflecting surface of coating comprising flame spraying s 1 17/35 S, l l7/l05.2 synthetic sapphire (a pure monocrystal of aluminum oxide) on [51] Int. Cl B05b 7/20 a surface, said coating having a reflectance that deviates less [50] Field of Search 350/320, than 4 percent over the wavelength range of from 0.3 to 3.0

290; 250/228; [17/35 A, 35 S, 35 V, l05.2 microns.

/MAGNESIUM OXIDE (3O MILS THICK) 7 .9 y X .8 FLAME SPRAYED SAPPHIRE (1O MILS) LL! 3 7 l w 1- FLAME SPRAYED COMMERCIALLY PURE a, ALUMINIUM OXIDE 1 1o MILS) l u. -6

LL! (I FLAME- SPRAYED SAPFHIRE (lMlL) WAVELENGTH 1J- PATENTEU mm 5 |97| 7:2: mmimnzw om mmw hm zzo S mmzImnzw Qw mmw mid INVENTORS JOHN M. DAVIES G.

WALTER ZAGIEBOYLO 'WM wAww' ATTORNEYS;

fectly difiuse reflectance, and having a reflectance that deviates less then 4 percent over the wavelength range of from 0.3 to 3.0 microns.

in the measurement of the ability of various materials to reflect and transmit light, especially when reflected or transmitted radiation is diffuse, it is common practice to use an integrating sphere as a component of the photometric system. Light reflected from or transmitted through the sample under measurement impinges on the inner reflective surface of the sphere, unifonnly brightening the whole sphere. The brightness of an area of the inner surface is then detected with a suitable device, as for example, a photocell or blackened thermocouple.

The requirements for the inner surface of such a sphere are the ability to scatter light difiusely, approaching the perfect case of unifonn distribution of reflected energy regardless of the direction of the incident beam, and the ability to reflect substantially uniformly at all wavelengths of interest and with sufficient intensity to permit proper operation of the detecting system. To meet these requirements, it has long been the practice to line the inner surface of integrating spheres with a coating of magnesium oxide, which is created by burning a ribbon of magnesium and allowing the white oxide smoke to coat the sphere. Such coatings have good diffusing properties, high-absolute reflectance, and reflectance that is fairly constant with respect to wavelength in the range of from 0.4 to 3.0 microns. On the other hand, while long employed for this purpose, and in fact presently used as a reflectance standard, magnesium oxide reflective coatings have several rather serious drawbacks in that they are not durable mechanically with the result that any blow transmitted to a surface so coated generally results in some loss of powdery coating, they exhibit some variation in reflectivity with wavelength and the reflectance of such coatings is not constant, diminishing with age. Also, the high value of average reflection is shown to be a disadvantage in some cases.

Typically reflected radiation is measured as a function of wavelength but very often in using reflectance and transmittance data, it is desirable to obtain an effective average reflectivity or transmissivity. Such average values of course will depend on the wavelength distribution of the radiation source. To obtain these averages, it is necessary to integrate the reflectivity or transmissivity properly weighted at the various wavelengths, that is, multiply the incident power at each wavelength by reflectivity (or transmissivity) at the wavelength and average the results over the wavelength range.

Such a procedure is time-consuming and of questionable accuracy since the wavelength distribution of the various light sources are not well known. A single direct measurement of the correctly weighted average reflectivity (or transmissivity) values, on the other hand, may be obtained by measuring the total energy reflected or transmitted for a given source rather than using small wavelength intervals. For this type of measurement, however, the requirements of the sphere coating are somewhat more stringent in that the coating'must reflect the energy at all wavelengths of interest equally. For measurement wherein the source is the sun or a carbon are a constancy of reflection within the range of 0.35 to 2.5 microns and preferably from 0.3 to 3.0 microns in necessary.

We have discovered a reflective coating that meets these stringent requirements which is hard and durable as contrasted with the soft powdery magnesium oxide coating, ap

proaches perfection in the diffuseness of the reflected light, can be adjusted to give a range of reflectivity from 50 percent to percent of the incident light and exhibits a reflectance curve that shows very little variation over the spectral range of interest. This reflective coating is obtained by flame spraying synthetic sapphire rods. Such rods, which are pure monocrystals of aluminum oxide, are formed by the Vemeuil process wherein crystallizable aluminum oxide powder passes through an oxyhydrogen'flame fusing the powder which collects on a support containing a crystal seed and in colling grows to form a large single crystal. The preparation of such synthetic sapphire is well known, e.g., see US. Pat. No. 2,852,890. The fact that a flame-sprayed sapphire coating reflects unifonnly over the spectral range of from 0.3 to 3.0 microns is somewhat surprising since flame-sprayed commercially pure aluminum oxide either as a powder or a resin bonded rod exhibits significant variation in spectral responses which is most severe in the near ultraviolet range with the result that such a coating would be unsuitable for making measurements of correctly weighted average reflectivity or transmissivity. The reasons for this substantial difference is reflective properties are not clear but is has been observed that flame-sprayed sapphire results in a denser coating than the commercially pure aluminum oxide. The latter material can be flame sprayed at a lower temperature than the sapphire and this may in some way contribute to the difference in properties. In addition, it is possible that the trace of impurity found in commercially pure aluminum oxide also contributes to its spectral aberration.

Accordingly, it is among the objects of the present invention to provide a reflective coating which approaches the ideal of perfect diffusivity.

Another object is to provide a reflective coating that reflects substantially uniformly over the spectral range of from 0.3 to 3.0 microns.

Another object is to obtain a reflective coating which is durable, constant with age and can be varied to reflect from 50 percent to 80 percent of the incident light.

Other objects and advantages will appear from the following description taken together with the accompanying drawing wherein: v 1 The FIGURE is a chart bearing curves which illustrate the reflectance of magnesium oxide, flame-sprayed commercially pure aluminum oxide, and flame-sprayed synthetic sapphire coatings over the wavelength range of 0.3 to 3.0 microns.

The aluminum oxide coating of the present invention is obtained by flame-spraying a synthetic sapphire, Le, a pure monocrystal of aluminum oxide on a suitable base or surface. Synthetic sapphires are available from many commercial sources and the techniques of forming such pure crystals. as previously noted, is well known. Flame-spraying is a technique whereby a rod of the material which is to form the coating is fed into a high-temperature blast of gas which fuses, atomizes and sprays the molten material. Flame-spraying of metal oxides is described in British Pat. Specification No. 745,257 to Norton Grinding Wheel Co., Ltd.

The principles of out invention will now be more fully described in connection with the coating of the inner surface of an aluminum integrating sphere. Such a sphere, consisting of two matching hemispherical sections is lightly sandblasted to roughen the inner surface to improve adhesion of the flame-- sprayed coating material. A synthetic sapphire rod, having a diameter of 0.3 cm., is fed into an oxyacetylene flame in a device such as that shown in British Pat. No. 745,257. The. amount of oxygen fed into the flame is gradually increased until a temperature is reached at which the sapphire rod begins to spray molten material. Preheating the aluminum hemispheres slightly facilitates adhesion of the coating material. The flame-sprayed molten oxide is then directed against" the object to be coated. if the object is too close or too far from the source of molten oxide, the latter will not adhere to the former. In order not to burn the object being treated, the

flame-spraying device is held some distance from the object and gradually brought closer thereto until the flame-sprayed oxide is seen to adhere to the surface to be treated. Coating thickness can be varied within wide limits but for an integrating sphere it is preferably in the range of l to mils. The thickness of the coating will be determined by the length of time a surface is exposed to the flame-sprayed material. The coating thus obtained is very hard and dense, and tightly adherent to the substrate.

The diffuse reflectance of a sphere coated as described above was measured and compared with spheres coated with freshly prepared magnesium oxide and flame-sprayed commercially pure aluminum oxide. Diffuse reflectance was measured with a goniophotometer (described in U.S. National Bureau of Standards Circular 429, July I952), employing a tungsten filament lamp as a source and a barrier layer photocell as a detector. The results for magnesium oxide, flame-sprayed commercially pure aluminum oxide synthetic sapphire coatings were found to approach an ideal diffuse reflector.

The diffuse reflectance of the same three coating materials was determined for the wavelength range 0.3 to 3.0 microns. Measurements were made with a spectrophotometer and the values given were measured relative to magnesium oxide but are expressed in absolute terms. The results are shown in FIG. 1. The magnesium oxide curve shows a decrease in reflectance of about 4 percent at 0.3 microns which becomes greater on aging. The sprayed sapphire curve is at least as flat as MgO and is permanent and stable. The commercially pure aluminum oxide, onthe other hand, demonstrated considerable variation in reflectance along with a large decrease in the ultraviolet.

The effect of coating thickness of the flame-sprayed sapphire coating on reflectance values was determined over the same wavelength spectrum. Average reflectance values varied from a low of 50 percent for a thinnest (1 mil) to a high of 80 percent for the thickest coating (at least 10 mils). This ability to vary reflectance with thickness of coating is of some value since the reduction in average reflectance of the sphere reduces the amplification of the error caused by nonuniform reflectance. Expressed differently, the 4 percent reflection variation in the ultraviolet region of MgO over the average reflection of about 96 percent will result in a larger error than a 4 percent reflection variation over any lesser average reflection. It the variation in reflectance over the spectrum is the same, then a reduction in average reflectance reduces the error in the brightness reading since the brightness is proportional to the ratio 1/ l-R, where R is the average reflectance of the coating.

ln addition to use as a coating for the inner reflective surface of an integrating sphere, the high reflectance, durability and relatively high-thermal conductivity of flame-sprayed sapphire coatings are singularlysuited for coating calorimeters, radiometers and optical monitors which are exposed to intense light radiation as from solar furnaces and lasers. This coating can also be used as a permanent optical standard. In this case having known average reflectances over a range of 50 percent to percent is an advantage.

Thermal radiation sensing devices and, in particular, calorimeters for measuring thermal radiation have surfaces designed to absorb definite fractions of the incident radiation. For sensitive devices for measuring low levels of radiation, the surface is usually black to absorb a large fraction of the incident radiation whereas for intense radiation, the sensitivity can be adequate with surfaces which reflect more and absorb less radiation. There are two requirements for such surfaces; 1) they must be stable in that they can withstand the high temperatures attained by the body absorbing the radiation with no change in reflectance and (2) the reflectance should be constant over the wavelength of interest.

In the measurement of the thermal radiation of a solar furnace we have heretofore employed copper disks having a thermocouple moldered to the back surface and having the front surface coated with electrolytically deposited carbon black or camphor smoke. Such coatings absorb energy independent of wavelength but, at intensities above 20 cal. cm", the temperature generated burns off the coating and melts the solder connection unless very short exposures are used. Coating the front surface of the calorimeter with flame-sprayed aluminum oxide in the manner heretofore described results in a surface which will absorb energy independent of wavelength and will also withstand intensities as high as cal. cm." since the surface will reflect as such of four-fifths of the incident energy. Longer exposures can be made and, in particular, the same exposures can be used as are needed for checking on tests or experiments in question.

This invention described in detail in the foregoing specification is subject to changes and modifications without departing from the principle and spirit thereof. The terminology used is for the purpose of description and not of limitation, the scope of the invention being defined in the claims.

We claim:

l. A method of forming a hard, dense, optically stable coating that reflects light diffusely and has a reflectance that varies less than 4 percent over the spectral range of 0.3 to 3.0 microns, which comprises flame spraying a synthetic sapphire crystal, causing the molten material to impinge on and adhere to the surface to be coated until coating of desired thickness is obtained.

2. A method of forming a hard, dense, optically stable coating that reflects light diffusely and has a reflectance that varies less than 4 percent over the spectral range of 0.3 to 3.0 microns, which comprises feeding a synthetic sapphire crystal into a high-temperature blast of gas which fuses, atomizes and sprays the molten material and directing the molten material onto the surface to be coated until a coating of desired thickness is obtained.

Claims (1)

1. 2. A method of forming a hard, dense, optically stable coating that reflects light diffusely and has a reflectance that varies less than 4 percent over the spectral range of 0.3 to 3.0 microns, which comprises feeding a synthetic sapphire crystal into a high-temperature blast of gas which fuses, atomizes and sprays the molten material and directing the molten material onto the surface to be coated until a coating of desired thickness is obtained.

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