US3069288A

US3069288A - Self-repairing coatings for metal

Info

Publication number: US3069288A
Authority: US
Inventors: Jr Gordon D Oxx; Jr Louis F Coffin
Original assignee: General Electric Co
Current assignee: General Electric Co
Priority date: 1959-08-06
Filing date: 1959-08-06
Publication date: 1962-12-18
Anticipated expiration: 1979-12-18

Description

Dec. 18, 1962 G. D. oXX, JR., ETAL SELF-REPAIRING coATINGs FOR METAL Filed Aug. 6. 1959 fr? Ven fOr-s4.- Gor-dor; D. XX JIT, .Low' Caa/h r.; b Q

heir' Azorney 3,069,288 Patented Dec. 18, 1962 hee 3,069,288 SELF-REPAIRING COATINGS FOR METAL Gordon D. Oxx, Jr., Scotia, and Louis F. Collin, Jr.,

Schenectady, N.Y., assignors to General Electric Company, a corporation of New York Filed Aug. 6, 1959, Ser. No. 832,084 19 Claims. (Cl. 117-71) This invention relates to the provision of protective coatings for structural components for use at elevated temperatures in reactive atmospheres, and more particularly to coatings containing a liquid phase rendering the coating self-repairing during use.

This application is a continuation-impart of applicants co-pending application, Serial No. 665,264, iiled June l2, 1957, now abandoned and assigned to the same assignee as the present application,

Metals and metal alloys, retaining to a great degree their strength to elevated temperatures, have found greatly increased usage in recent years due to the development of equipment utilizing higher temperatures. For example, molybdenum and alloys in which molybdenum is the principal constituent, are known to have high strength at elevated temperatures and, except for the fact that these materials are subject to drastic corrosion or oxidation when exposed to oxidizing atmospheres at temperatures over about 1400" F., would be excellent as structural materials for the fabrication of components subjected to high temperature and high stress in gas turbine applications. Similarly, materials such as columbium, tantalum, zirconium, tungsten and chromium have also been proposed for use at high temperatures in oxidizing atmospheres but have generally required some type of protective coating to enable such use.

Many ditferent coating materials have been applied to the various base metals in an attempt to prevent high temperature oxidation, but, while it has been found a relatively easy matter to provide stable, continuous coatings which exclude oxygen for long periods of time under static conditions, similar success has not been met in providing stable coatings where the bodies are flexed or otherwise subjected to oscillatory loads producing reversing stresses. Thus, these previously-known coatings have been effective for only brief periods of time Furthermore, in applications such as gas turbines where the coated articles are subjected to the action of solid particles carried by the gas stream, the surfaces of the articles are impinged upon with suicient force that the coating is either almost immediately ruptured, permitting access of the oxidizing atmosphere to the substrate and its consequent rapid corrosion and failure, or the coating is gradually eroded or braded by repeated impingements resulting in loss of coating and consequent destruction by oxidation of the article.

It is therefore a principal object of this invention to provide stable, adherent coatings for articles made of metals for use at elevated temperatures, which coatings resist oxidation and penetration of oxidizing atmospheres for long periods of time at elevated temperatures.

A further object of this invention is to provide articles constructed of metals for use at elevated temperatures having corrosionand erosion-resistant coatings which are self-repairing during use.

Other objects and advantages of this invention will be in part apparent and in part explained by reference to the accompanying specification and drawings.

In the drawings,

FIG. 1 is a graphical representation of the results of impact tests performed upon several molybdenum bodies coated in accordance with the present invention at various elevated temperatures;

FIG. 2 is a graphical representation of the relationship between the thickness of the applied coating and impact resistance at elevated temperatures; and

FIG. 3 is a schematic showing of a porous coating as applied to a metal body according to the present invention.

The present invention is predicated upon the discovery that under certain circumstances a corrosion and abrasion resistant, tightly adherent, porous covering layer or coating, having marked liquid phase retaining ability, can be provided on metal bodies. It is further based upon the discovery that there are special alloys which have the ability in the liquid phase of reacting with the substrate or matrix metal to form additional coating material thereby healing fractured or broken parts of the coating network to provide self-repair under high temperature operating conditions. It is a special feature of this invention that al1 essential parts of this network are contacted with the healing alloy and repairs thus are made automatically and immediately as the necessity arises, but without the loss of the healing or repairing liquid alloy due to centrifugal force or similar action incident to the use of the said refractory body.

Brieily stated, the present invention concerns the application of protective coatings to metals and alloys of metals such as molybdenum, chromium, columbium, tantalum, zirconium and tungsten, which protective coatings consist of an intermetallic compound of the base metal with a suitable reactive material and which contain a liquid phase containing a sufficient amount of the reactive material to heal or repair any cracks or other defects which occur in the coating during its normal usage.

In approaching the problem of selecting the proper materials to form coatings acceptable for use on the base materials mentioned in the preceding paragraph, several considerations must be kept in mind. The principal considerations which have to be considered in providing a coating for any selected basis metal are: (l) a corrosion resistant and impermeable intermetallic compound 0f the basis metal must be selected; (2) a method of applying a porous layer of the intermetallic compound on the surface of the basis metal must be obtained; and (3) a suitable liquid phase rendering the coating self-repairing must also be developed.

With particular regard to the alloy forming the liquid phase, several additional conditions must also be met. First of all, the material selected as the liquid phase must melt at a temperature below that at which it is desired to use the nal article. Obviously, if the protective liquid material is in fact not liquid at the operating temperature, where protection of the substrate metal is desired, then the self-repairing properties will be greatly reduced. An additional factor is that the material making up part of the alloy phase of the molten material must be capable of dissolving enough of the material reactive with the basis metal to vprovide sui'licient material to combine with the basis metal and form the self-repairing coating.

Another factor is that the allow containing the reactive material must not dissolve the basis metal or, of course, destruction of the basis metal will result from the would-be protective coating. A factor which is allied with the destruction by the liquid phase of the basis metal is that of solubility of the coating material in the basis metal. lf one or parts of the liquid phase are soluble in the basis metal, then no adequate, protective coating can be obtained.

Finally, it is apparent that if the coating is indeed protective, then it must be resistant to corrosion and impermeable to the passage of corroding gases therethrough, as well as have suicient resistance to erosion caused by impinging particles carried in the passing fluid streams.

Considering a specific problem which has been overcome by the present invention, previous attempts to provide buckets or blades for use in gas turbine engines with protective coatings have revealed three important sources of coating failure, namely, cracks which Vdevelop as the result of repeated thermal shocking of the coated bucket, overheating of the'bucket, and impact 'damage caused by the impingement of solid particles entrained in the gas stream.

The most frequently occurring coating failure in previously known coated buckets has had its origin in thermal stresses resulting from rapid temperature changes and the relatively large dilerence in the thermal coeicient of expansion of the substrate metal and the coating. Under repeated rapid thermal cycling, i.e., alternately raising and loweringthe temperature of the bucket producing thermal shocks, fatigue cracksV develop in the coating, permitting oxidation of the substrate metal.

Where the previously known coatings have been secured to the substrate with a brazing alloy or the like having a melting point only a few hundred degrees above the normal operating temperature of the bucket, temporary overheating of the bucket has caused this relatively low melting point material to fail under stress,

Vpermitting the coating to become separated from the bucket and has resulted in subsequent bucket failure.

As is well known, in the actual-operation of gas turbine engines, small particles of dust, sand, gravel, and

even larger metallic objects, such as nuts and bolts, can be drawn into the air intake and entrainedin the rapidly ilowing gas stream, and propelled at high speeds through the engine. While it is possible to prevent intake of larger particles, or if actually ingested, to prevent them from reaching the turbine stage of the engine,.it is not always practical and, in addition, no satisfactory solution is known for preventing the smaller particles from striking and abrading the rapidly moving, hot turbine buckets. With previously known coatings, some of these particles have had suiciently high energy, relative to the bucket, to penetrate through the coating, permitting oxidation and resulting in failure of the bucket.

To prepare a composite body according to the present invention, the normal procedure is to select the, desired material, which is generally one of the metals such as columbium, tantalum, molybdenum, zirconium, tungsten or chromium, or alloys of these metals in which the combined amounts of such metals is not less than about 70 weight percent, although the amount of any one of the metals constituting a part of an alloy can be substantially less than 50 Yweight percent. Additionally, metal other vrthan those specically mentioned may also befused. A quantity of powdered metal, usually the same as lthe basis metal although not necessarily, is then compacted into a porous structure and sintered on the substrate body so that pores of capillary size remain to retain a liquid phase alloy which is subsequently infused thereinto. V Once the porous outer layer is properly in position, the article is impregnated with a quantity of an alloy containing a sufficient amount of a material reactive with the sintered powder and with the substrate to react therewith and change the porous layer into a protective intermetallic compound. Reaction also takes place with any exposed basis metal with the formation of a protective 'intermetallic layer. Generally, some of the reactive materials which maybe dissolved in the alloy are silicon, aluminum, boron, germanium, beryllium and carbon. The selection of the particular material used will depend upon the exact basis and porous metals chosen and will be determined in View of the considerations set forth earlier in the specification.; r

These intermetallics have excellent resistance to both corrosion and'erosion which vrenders them capable of withstandng'the conditions normally present inV gas turbines, for exa-mple, and similar apparatus. After the reaction of the alloy with the sintered powder material has taken place, there should be enough of the alloy remaining .in the pores to provide excess reactive material to repair any breaks or cracks which may later occur in the coating `as a result of thermal or mechanical stress cycling.

`Considering a particular example of the invention as Vapplied to a molybdenum base, the substrate should consist of at least 70 weight percent molybdenum. It has been found that a suitable alloy for infusing the pores of the sintered molybdenum layer on the outer surface of the substrate consists of gold containing from about 1.0 `to 30 weight percent silicon. The thickness and degree of porosity of the ponous molybdenum coating in which the gold-silicon alloy is to be infiltrated depends upon the operating conditions to which it is to be subjected. In general, however, thicknesses of from about 0.005 to 0.050 inch `and having a porosity of from 50` to 75 volume percent molybdenum and 50 to 25 volume percent porosity, respectively, Iare ydesirable for most applications. It will be appreciated, therefore, that these coat-ings, involving the porous molybdenum or molybdenum-rich alloy sintered layer and the gold alloy infiltrated therein, are composed in gross of fro-m about 20 weight percent silicon, 50 percent gold, land the remainder substantially all molybdenum when a 1.0 percent silicon-gold alloy is iniiltnated into a porous molybdenum coating having 50 percent porosity by volume; about 30 weight percent silicon, 25 weight percent gold, and the remainder substantially all molybdenum when the same alloy is infiltrated into a 25 percent by volume poro-sity molybdenum coating;

about 35 weight percent silicon, 20 percent gold, and the sintered in place `on its surface. The coated article is fthen immersed in a molten bath of an alloy consisting essentially of at least 1.0 weight percent silicon-and the remainder substantially Iall gold. The gold-silicon 'alloy must contain at least about 1.0 weight percent silicon in order that molybdenum 'dsilicide may be formed `as the product of Ithe reaction which occurs between the molybdenum comprising the sintered porous coating and the alloy. If a smaller amount of silicon is present in the molten alloy, other molybdenum silicides are formed which are not oxidation resistant at temperatures of about 22G0 F. and higher. Gold alloys containing amounts of silicon greater than 1.0 percent are desirable and such alloys containing las much Ias about 30 weight percent silicon or more may be used, depending upon the operating temperature to be employed.

As is well known, the binary alloys of gold land silicon form a simple euteotic system. The gold-silicon eutectic melts at about 698 F. and the liquidus, or temperature at which these .alloys become completely molten, decreases from the melting point of pure gold, 1945 F., as a smooth curve to 698 F. at the entectic composition, 94 percent gold and 6 percent silicon. As the silicon `content is increased, the liquidus increases as a curve having a progressively decreasing slope from 698 F. to become substantially constant at about 2552 F. at an alloy containing about 8O percent silicon, and Vat 100 percent silicon, of course, is the melting point of silicon, i.e., about 2590 F. As will be appreciated, all the alloys comprising this System yare completely molten `alt temperatures at and above the liquidus temperature. Alloys containing less than 6 percent silicon yare composed of a liquidiphase and an alpha phase solid solution between 698 F. and the liquidus temperature, and alloys containing more than 6 percent Asilicon are composed of a liquid phase and silicon in the solid state between 698 F. and the liquidus temperature. At temperatures below the eutectic temperature, i.e., 698 F., all gold-silicon binary alloys are completely solid and composed of an alpha solid solution and silicon.

As already mentioned, when lthe coated molybdenum article is immersed in the completely molten gold-silicon alloy, 4the silicon in the alloy reacts with the molybdenum in the porous coating to form :a porous coating of m-olybdenum disilicide, the molten gold-silicon alloy filling and being retained within the pores and interstices and covering the outer surface of the porous coating. This molten gold-silicon yalloy wets the surfaces and pores of the coating and serves as a reservoir of liquid containing silicon which i-s available to react with molybdenum surfaces which may be subsequently exposed by the rupture ofthe molybdenum disilicide coating to form a new layer of molybdenum disilicide at the point of rupture. Molybdenum disilicide is quite resistant to oxidation at elevated temperatures and, further, is quite hard, although alone is somewhat brittle. The gold-silicon alloy above its melting point is held in the porous molybdenum disilicide coating by capillary attraction and at the elevated temperatures contemplated is stable and, since it is liquid, is not liable to rupture by thermal stresses. In fact, if such thermal stresses tend to form cracks in the molybdenum disilicide, the molten gold alloy appears to immediately iill them and the silicon is available to repair the defect by forming a new protective layer of the disilicide.

Since the operating temperature range of such coated molybdenum bodies is contemplated to lie between about llt-80 F., the temperature at which unprotected molybdenum and molybdenum-rich alloys begin to oXidize in a catastrophic manner, and temperatures as high as about 25G0 F., and since the gold-silicon alloy employed should have a major portion in the liquid phase at the particular operating temperature, it will be apparent that the alloys of our invention should contain from at least 1.0 to about 30 percent silicon and preferably from 1.0 to about percent silicon, the remainder substantially all gold. These alloys are useful in this temperature range since the liquidus for these alloys is about l830 F. for 1.0 percent silicon, about 1650 F for 2.0 percent silicon, about lll5 F. for 5.0 percent silicon, about 698 F. for 6.0 percent silicon, about 1115 F. for 7.5 percent silicon, about l470 F. for l0 percent silicon, about 1870 F. for l5 percent silicon, about 2070 F. for 20 percent silicon, and about 2300 F. for 30 percent silicon. if

higher operating temperatures are contemplated, then,

of course, the silicon content may be increased commensurately.

The following specific examples have been selected to illustrate how such an alloy containing even a relatively small amount of silicon present in gold may be successfully employed with the sintered porous molybdenum coating to protect molybdenum articles at high temperatures as shown by the various test results set forth.

A number' of molybdenum articles were produced with a porous coating by dipping the articles in a slurry of molybdenum powder with an average particle size of 2 to 4 microns suspended in Water. This slurry may consist of from about to 120 grams of this powder suspended in about l5 cc. of water. The articles were dried and the thickness of the powder layer deposited thereon was built up by successive dipping and drying steps until the desired thicknesses were obtained. For example, using such a suspension, to 5 dipping and intervening drying steps were needed to form a coating about 0.020 inch in thickness. The coated articles were then fired at about 2550 F. in a protective atmosphere and permitted to cool in the atmosphere to cause the molybdenum powder to sinter into a porous layer firmly attached to the basis metal. It was found that the resulting porous layer consisted ofV about 60 volume percent molybdenum and 40 volume percent porosity. It will, of course, be immediately apparent to those skilled in the art that variations in powder particle size, temperature of sintering and other variables lmay be employed to control the porosity, strength and firmness of attachment of the porous layer to the substrateand that other means may be employed to prepare the porous layer. Furthermore, while the particular articles disclosed herein were composed of substantially pure molybdenum coated with substantially pure molybdenum powder, it will be obvious that a coating prepared from powdered molybdenum-rich alloy may be applied to either a substantially pure molybdenum substrate or to a molybdenum-rich alloy substrate and powdered substantially pure molybdenum may be applied to a molybdenum-rich alloy substrate in the same manner with equal facility.

The porous surface layers of these articles were then infiltrated with a gold base alloy containing about 1.5 weight percent silicon. This alloy begins to melt at about 700 F. and is completely molten at l650 F. The gold-silicon alloy was melted and the articles dipped into the melt. It Was found that all the pores of the coating were rapidly filled and that the molybdenum in the porous coating reacted with the alloy to form molybdenum disilicide. Because an essentially infinite silicon source (the melt) was used, the gold-silicon alloy in the pores was approximately 1.5 percent silicon after reV` action and impregnation were completed. These coatedA articles were then subjected to a number of tests, examples of which are hereinafter set forth.

A number of molybdenum panels inch square andl 0.100 inch thick were provided with porous coatings of sintered molybdenum powder about 0.005 inch, 0.010'V inch, 0.015 inch and 0.020 inch in thickness and impregnated with the 1.5 percent silicon-gold alloy as previously set forth.

One such specimen having a sintered porous coating 0.010 inch thick was, after impregnation, subjected to a temperature of 2500 F. in a flowing air atmosphere for 1000 hours without failure of the coating. Periodically during this heating, the specimen was removed from the furnace and cooled to room temperature in order to weigh and inspect the coating, after which the specimen was reheate'd by placing it directly in the hotzone of the furnace. This .thermal cycling was performed 20 timesy during the test.

This specimen was then heated at one end with a gasoxygen torch to |2500 F. The heated end of the specimen was held at 2500 F. for tive seconds and then quenched in a stream of water to room temperature. This heating and quenching cycle was repeated for 55 cycles before failure occurred in the coating. During this thermal cycle, the heating rate was about F. per second and the cooling rate about F. per second. Another substantially identical but freshly prepared coated specimen withstood 88 cycles under the same test conditions.

Referring -to FIG. 3 of the drawings, numeral 10 represents a molybdenum body, or specimen, to which a coating 11, like that just described has lbeen sintered. The coating 11 is integrally attached to the base 10 and` is made up of the molybdenum disilicide porous matrix 12 which holds the gold-silicon alloy 13 by'capillary attract-ion when the article is being used. Of course, the same structural arrangement is present when metals other than molybdenum are used.

The resistance of the coatings to impact was determined in .the following manner. Coated specimens were heated to various elevated temperatures in air by a gas-oxygen torch and a projectile of known weight impelled against the heated surfaces thereof from a .22 caliber pistol. This pistol was powered by compressed gas so that the veloci-ty and hence the energy of the project-ile was closely controllable and readily determined. The projectile was a .22 caliber lead slug which was provided with a hardened steel tip ground to a radius of 1,/32 inch at the front end. Since the pistol barrel was rifled, the projectile always struck the heated specimen with lthe steel tip and with the `axis of the projectile perpendicular to the specimens surface.

Specimens having coatings ofl three different thicknesses were tested in this manner: 0.005 inch, 0.015 inch and 0.020 inch, and at three different temperatures, l800 F., 2000 F., and 2500 F. The highest projectile energy which did not cause penetration through the coating has been plotted in FlG. 1 with impact resistance in foot pounds as the axis of ordinates and the temperature in degrees F. as the axis of abscissas. Curve 1 represents the highest projectile energies which did not cause the penetration of the specimens having the 0.020 inch thick coating at the various elevated temperatures, While curves 2 and 3 `are similar plots for the specimens provided with 0.015 inch and 0.005 inch thick coatings, respectively.

In FIG. 2, this data has been plotted with imp-act resistance in foot pounds as the axis of ordinates and the coating thickness in inches for two temperatures, i.e., curve 4 for tests at l800 F. and cur-ve 5 for tests at 2000 F.

It will be seen from the foregoing that the coatings are oxidation resistant in oxidizing atmospheres, are thermally stable, and resist the diffusion of oxygen therethrough at temperatures at least as high as 2500 F. Further, that these coatings have a quite high resistance to impact at temperatures as high as 2500 F. and are not susceptible to failure from repeated thermal shocks.

Considering the application of the present invention with regard to another of the metals listed, specifically, zirconium, a zirconium body was dipped into a suspension of zirconium powder, amyl acetate and cellulose nitrate. One hundred grams of zirconium, 50 cc. of amyl acetate and l cc. of cellulose nitrate were used. It was found that the zirconium samples-dipped into this slurry would acquire a layer of zirconium about l mil thick. The layer was dried and the sample redipped to build up the coating to an approximate thickness of about 0.015 inch. The coating thus applied to the body Iand the body were sintered in vacuum by heating the sample slowly to a sintering temperature of l000 C. and holding this temperature for about 2 hours. Good adherence and no cracking of the porous structure thus obtained were observed. In this case, the alloy selected for infiltration of the pores of the outer coating was a silver-silicon bath consisting of 6.0 percent silicon and the remainder substantially all silver. The eutectic in this system is at 1472" F. so that reaction was effected at about 1600 F. It was found that the zirconium did not dissolve in the bath after 30 minutes but did react to form a surface layer consisting of zirconium disilicide. n

It will be understood that the binary system of silver and silicon also possesses eutectic compositions similar to the gold-silicon alloy used on the molybdenum base bodies and that the temperature at which the zirconium body is to be used will play a major part in determining the specific amount of silicon which should be present in the bath. If the contemplated temperature of operation is high enough, then increased percentages of silicon can be used, whereas if lower temperatures are contemplated, then the silicon content can be lowered slightly, although to become molten, it will be necessary for the eutectic temperature to be reached. A

The silver-silicon alloy used on the zirconium bodies was also used in the same compositional percentages on columbium, tungsten and chromium and was found to form a suitable reaction product, and formed a protective coating infiltrated with the alloy to provide the selfrepairing properties. It should be mentioned in connection with the chromium that the chromium might often be used as an additional protective coating on the outside of a different substrate material such as molybdenum and that the abrasion and corrosion resistant porous coating will be applied over the chromium coating. In this case, a chromium powder can be used rather than a molybdenum powder since the chromium is the material which is exposed to the corroding atmosphere.

A binary alloy of silver containing dissolved aluminum is effective on substrate bodies of columbium or containing major proportions of columbium, since the aluminum will react with the columbium to form a protective intermetallic compound.

Obviously, `alloys may be used for infiltrating the porous outer coating other than those which have been specifically mentioned. For example, ternary alloys ywill work as effectively as the binary alloys, providing that sufficient solubility of silicon is possible and provided that the particular alloy chosen does not adversely react with .the substrate material. Alloys which were prepared and found acceptable for use on zirconium bodies consisted of the following ingredients. The first was 55 weight percent silver, 30 weight percent bismuth and 6.0 weight percent silicon. Another which was found suitable was 12.2 Weight percent germanium, 81.9 weight percent antimony and 5.9 weight percent silicon, while a further composition consisted of 6.8 weight percent copper, 89.6 weight percent bismuth and 3.6 weight percent silicon. It is thus apparent that any number of alloys can be used, provided they meet the conditions set forth earlier in the specification. Y p

While for the purpose 'of illustrating our invention, the foregoing specification has set forth several specific examples, we do not intend that our invention be limited in any manner except as recited in the appended claims.

What we claim as new and desire to secure by Letters Patent of the United States is:

l. A composite article comprising a solid substrate body, and a corrosion resistant coating secured to and overlying at least a portion of the surface of said substrate body, said coating consisting of an intermetallic compound of said substrate metal present as a porous matrix defining a capillary network, and an alloy located in said capillary network which is liquid at the temperature of use of said composite article and which contains an amount of a material reactive with said substrate metal sufficient to form a corrosion resistant intermetallic compound of a composition corresponding to that of said porous matrix.

2. A composite article comprising a solid substrate body consisting essentially of at least 7-0 weight percent of a metal reactive with silicon to form a silicide, and a corrosion resistant coating secured to and overlying at least a portion of the surface of said substrate body, said coating consisting of a silicide of said substrate metal present as a porous matrix defining a capillary network, and an alloy located in said capillary network which is liquid at the temperature of use of said composite article and which contains an amount of silicon sufficient to react with said substrate metal and form a corrosion resistant compound.

3. A composite article comprising a solid substrate body consisting essentially of at least 70 weight percent kof a metal selected from the group consisting of molybdenum, zirconium, tantalum, columbium, tungsten, chromium and alloys thereof, and an oxidation resistant coating secured to and overlying at least a portion of the surface of said substrate body, said coating consisting of a silicide of said substrate metal present as a porous matrix defining a capillary network, and an alloy located in said capillary network which is liquid at the temperature of use of said composite article and which contains an amount of silicon sufficient to react with said substrate metals and form a corrosion resistant compound.

4. A composite article comprising a solid substrate body consisting essentially of at least 70 weight percent of a metal selected from the group consisting of molybdenum, zirconium, columbium, tantalum, tungsten and chromium, and alloys thereof, and an oxidation resistant coating secured to and overlying at least a portion of the surface of said substrate body, said coating consisting of a silicide of said substrate metal present as a porous matrix dening a capillary network, and an alloy located in said capillary network consisting of silver containing a sufficient amount of silicon to react With said substrate metal and form a corrosion resistant compound, said alloy being liquid at vthe temperature at which said article is used.

5. A composite article comprising a solid substrate body consisting essentially of at least 70 weight percent of a metal selected from the group consisting of molybdenum, zirconium, columbium, tantalum, tungsten and chromium, and alloys thereof, and an oxidation resistant coating secured to and overlying at least a portion of the surface of said substrate body, said coating consisting of a silicide of said substrate metal present as a porous matrix deiining a capillary network,Y and an alloy located in said capillary network which is liquid at the temperature of use of said composite article, said alloy consisting of 55 weight percent silver, 39 weight percent bismuth and 6.0 weight percent silicon.

6. A composite article comprising a solid substrate body consisting essentially of at least 70 weight percent of a metal selected from the group consisting of molybdenum, zirconium, columbium, tantalum, tungsten and chromium, and alloys thereof, and an oxidation resistant coating secured to and overlying at least a portion of the surface of said substrate body, said coating consisting of a silicide of said substrate metal present as a porous matrix dening a capillary network, and an alloy located in said capillary network which is liquid at the temperature of use of said composite article, said alloy consisting of 12.2 weight percent germanium, 81.9 weight percent antimony, and 5.9 weight percent silicon.

7. A composite article comprising a solid substrate body consisting essentially of at least 70 weight percent of a metal selected from the group consisting of molybdenum, zirconium, columbium, tantalum, tungsten and chromium, and alloys thereof, and an oxidation resistant coating secured to and overlying at least a portion of the surface of said substrate body, said coating consisting of a silicide of said substrate metal present as a porous matrix defining a capillary network, and an alloy located in said capillary network which is liquid at the temperature of use of said composite article, said alloy consisting of 6.8 weight percent copper, 89.6 weight percent bismuth and 3.6 weight percent silicon.

8. A composite article comprising a solid substrate body consisting essentially of at least 70 weight percent molybdenum, and a corrosion resistant coating secured to and overlying at -least a portion of the surface of said substrate body, and consisting essentially of a porous molybdenum disilicide as a matrix, and a gold-silicon alloy held within the pores of said matrix, said layer having the gross composition, by weight, of from about to about 40 percent silicon, 8.0 to about 50 percent gold and the remainder being substantially all molyb denum.

9. A composite article as recited in claim 8 in which said porous body of molybdenum disilicide was formed by reacting a porous layer consisting of at least 70` Weight percent molybdenum and having from to 50 percent by volume porosity with sufficient silicon to convert subl stantially all the molybdenum in said layer to molybdeJ num disilicide.

10. An article as recited in claim 8 in which said layer has the gross composition, by weight, of from about 20 to percent silicon, 25 to 50 percent gold and the remainder substantially all molybdenum.

11. An article as recited in claim 8 in which said layer has the gross composition, by weight, of from about l@ to 40 percent silicon, 8.0 to 20 percent gold and the re mainder substantially all molybdenum.

12. A method for providing the surface of an article composed of at least 70 weight percent of molybdenum with an oxidation, erosion and abrasion resistant coating comprising the steps of sintering to at least a portion of the surface of said article an adherent porous coating of metal consisting of at least 70 weight percent molybdenum, said coating having from about 25 to 75 percent by volume porosity, and impregnating said porous coating with an alloy consisting essentially of from about 1.0 to 30 weight percent silicon and the remainder substantially all gold.

13. In combination with a solid metal body for use at elevated temperatures and comprising at least 70 weight percent molybdenum, a self-repairing coating protecting said body against abrasion and oxidation, said coating consisting essentially of a matrix of molybdenum disilicide having pores dispersed throughout, and an alloy consisting of from about 1.0 to 30 Weight percent silicon, the remainder substantially all gold, retained at said elevated temperatures in a liquid state in the pores of said body by capillary attraction to provide silicon for reaction with said body repairing cracks or similar defects occurring in said coating.

14. A method for providing the surface of a metal body composed of at least 70 weight percent molybdenum with an abrasion and oxidation resistant coating comprising the steps, applying a coating `of molybdenum powder to the surface of the metal body, sintering the molybdenum powder into an adherent porous coating on the body, and immersing the body in an alloy consisting essentially of 1.0 to 30 weight percent silicon, the remainder substantially all gold to impregnate the sintered coating and form a porous molybdenum disilicide matrix containing molten gold-silicon alloy.

15. In combination with a solid metal body for use at elevated temperatures and comprising at least 70 weight percent zirconium, a self-repairing coating protecting said body against abrasion and oxidation, said coating consisting essentially of a matrix of zirconium disilicide having pores dispersed throughout, and an alloy consisting of not less than about 3.0 weight percent silicon, the remainder substantially all silver, retained at said elevated temperatures in a liquid state in the pores of said body by capillary attraction to provide silicon for reaction with said body repairing cracks or similar defects occurring in said coating.

16. A composite article comprising a solid substrate body consisting essentially of at least 10 weight percent of a metal selected from the group consisting of molybdenum, zirconium, tantalum, columbium, tungsten, chromium and alloys thereof and an oxidation-resistant coating secured to and overlying at least a portion of the surface of said substrate body, said coating consisting of an intermetallic compound of said substrate which is present as a porous matrix defining a capillary network and a metal located in said capillary network which is liquid at the temperature of use of said composite article and which contains material reactive with said substrate metal to combine therewith and form said intermetallic compound.

17. A composite article comprising a solid substrate body consisting essentially of at least 70 Weight percent of a metal selected from the group consisting of molybdenum, zirconium, tantalum, columbium, tungsten, chromium and alloys thereof, a porous matrix composed of an intermetallic compound of said substrate metal deiining a capillary network secured to and overlying at least a portion of said substrate body, a metal located in said capillary network which is liquid at the temperature of use of said composite article, and a material selected from the group consisting of silicon, aluminum, boron, germanium, beryllium, and carbon which is soluble in said capillary-held liquid metal and reactive with said substrate metal, said selected material being dissolved in said liquid metal to combine lwith said 4substrate metal and form said intermetallic compound. Y

' 18` A `composite article comprising a solid substrate body consisting essentially of at least 70 weight percent of a metal selected from the group consisting of molybdenum, zirconium, tantalum, columbium, tungsten, chromium and alloys thereof, a porous matrix composed of an intermetallic compound of said substrate metal defining a capillary network secured to and overlying at least a portion of said substrate body, a metal selected from the group consisting of gold, silver, bismuth, antimony, `copper and alloys thereof which is liquid at the temperature of use of said composite article located in said capillary network, and a material which is soluble in said capillary-held liquid metal and reactive with said substrate metal, said material being dissolved in said liquid metal to combine with said substrate metal and form said intermetallic compound.

.19. A composite article comprising a solid substrate body consisting essentially of at least 70 weight percent of a metal selected from the group consisting of molybdenum, zirconium, tantalum, columbium, tungsten, chromium and alloys thereof, a porous matrix composed of an intermetallic compound of said substrate metal defining a capillary network secured to and overlying at least a portion of said substrate body, a metal selected from the group consisting of gold, silver, bismuth, antimony, copper and alloys thereof which is liquid at the temperature of use of said composite article located in said capillary network, and a material selected from the group consisting of silicon, aluminum, boron, germanium, beryllium and' carbon which is soluble in said capllary-held liqud metal and reactive with said substrate metal, said selected material being dissolved in said liquid metal combined with said substrate metal t0 kform said intermetallic compound. Y

References Cited in the iile of this patent UNITED STATES PATENTS 1,228,194 Fahrenwald May 29, 1917 2,190,237 Koehring Feb. 13, 1940 2,293,840 Lignian Aug. 25, 1942 2,370,242 Hensel Feb. 27, 1945 2,491,866 Kurtz Dec. 120, 1949 2,690,409 Wainer Sept. 28, 1954 2,876,139 :Flowers Mar. 3, 1959 2,878,554 Long Mar. 24, 1959 2,970,933 Barera et al. Feb. 7, 1961

Claims

1. AN COMPOSITION ARTICLE COMPRISING A SOLID SUBSTRATE BODY, AND A CORROSION RESISTANT COATING SECURED TO AND OVERLYING AT LEAST A PORTION OF THE SURFACE OF SAID SUBSTRATE BODY, SAID COATING CONSISTING OF AN INTERMETALLIC COMPOUND OF SAID SUBSTRATE METAL PRESENT AS A POROUS MATRIX DEFINING A CAPILLARY NETWORK, AND AN ALLOY LOCATED IN SAID CAPILLARY NETWORK WHICH IS LIQUID AT THE TEMPERATURE OF USE OF SAID COMPOSITE ARTICLE AND WHICH CONTAINS