Patent ID: 12246994

DETAILED DESCRIPTION

The detailed description of embodiments herein makes reference to the accompanying drawings, which show embodiments by way of illustration. While these embodiments are described in sufficient detail to enable those skilled in the art to practice the disclosure, it should be understood that other embodiments may be realized and that logical and mechanical changes may be made without departing from the spirit and scope of the disclosure. Thus, the detailed description herein is presented for purposes of illustration only and not for limitation. For example, any reference to singular includes plural embodiments, and any reference to more than one component or step may include a singular embodiment or step. Also, any reference to attached, fixed, connected or the like may include permanent, removable, temporary, partial, full and/or any other possible attachment option.

With initial reference toFIGS.1A and1B, aircraft wheel braking assembly10such as may be found on an aircraft, in accordance with various embodiments is illustrated. Aircraft wheel braking assembly may, for example, comprise a bogie axle12, a wheel14including a hub16and a wheel well18, a web20, a torque take-out assembly22, one or more torque bars24, a wheel rotational axis26, a wheel well recess28, an actuator30, multiple brake rotors32, multiple brake stators34, a pressure plate36, an end plate38, a heat shield40, multiple heat shield sections42, multiple heat shield carriers44, an air gap46, multiple torque bar bolts48, a torque bar pin50, a wheel web hole52, multiple heat shield fasteners53, multiple rotor lugs54, and multiple stator slots56.FIG.1Billustrates a portion of aircraft wheel braking assembly10as viewed into wheel well18and wheel well recess28.

In various embodiments, the various components of aircraft wheel braking assembly10may be subjected to the application of compositions and methods for protecting the components from oxidation.

Brake disks (e.g., interleaved rotors32and stators34) are disposed in wheel well recess28of wheel well18. Rotors32are secured to torque bars24for rotation with wheel14, while stators34are engaged with torque take-out assembly22. At least one actuator30is operable to compress interleaved rotors32and stators34for stopping the aircraft. In this example, actuator30is shown as a hydraulically actuated piston, but many types of actuators are suitable, such as an electromechanical actuator. Pressure plate36and end plate38are disposed at opposite ends of the interleaved rotors32and stators34. Rotors32and stators34can comprise any material suitable for friction disks, including ceramics or carbon materials, such as a carbon/carbon composite.

Through compression of interleaved rotors32and stators34between pressure plates36and end plate38, the resulting frictional contact slows rotation of wheel14. Torque take-out assembly22is secured to a stationary portion of the landing gear truck such as a bogie beam or other landing gear strut, such that torque take-out assembly22and stators34are prevented from rotating during braking of the aircraft.

Carbon-carbon composites (also referred to herein as composite structures, composite substrates, and carbon-carbon composite structures, interchangeably) in the friction disks may operate as a heat sink to absorb large amounts of kinetic energy converted to heat during slowing of the aircraft. Heat shield40may reflect thermal energy away from wheel well18and back toward rotors32and stators34. With reference toFIG.1A, a portion of wheel well18and torque bar24is removed to better illustrate heat shield40and heat shield sections42. With reference toFIG.1B, heat shield40is attached to wheel14and is concentric with wheel well18. Individual heat shield sections42may be secured in place between wheel well18and rotors32by respective heat shield carriers44fixed to wheel well18. Air gap46is defined annularly between heat shield sections42and wheel well18.

Torque bars24and heat shield carriers44can be secured to wheel14using bolts or other fasteners. Torque bar bolts48can extend through a hole formed in a flange or other mounting surface on wheel14. Each torque bar24can optionally include at least one torque bar pin50at an end opposite torque bar bolts48, such that torque bar pin50can be received through wheel web hole52in web20. Heat shield sections42and respective heat shield carriers44can then be fastened to wheel well18by heat shield fasteners53.

Under the operating conditions (e.g., high temperature) of aircraft wheel braking assembly10, carbon-carbon composites may be prone to material loss from oxidation of the carbon. For example, various carbon-carbon composite components of aircraft wheel braking assembly10may experience both catalytic oxidation and inherent thermal oxidation caused by heating the composite during operation. In various embodiments, composite rotors32and stators34may be heated to sufficiently high temperatures that may oxidize the carbon surfaces exposed to air. At elevated temperatures, infiltration of air and contaminants may cause internal oxidation and weakening, especially in and around brake rotor lugs54or stator slots56securing the friction disks to the respective torque bar24and torque take-out assembly22. Because carbon-carbon composite components of aircraft wheel braking assembly10may retain heat for a substantial time period after slowing the aircraft, oxygen from the ambient atmosphere may react with the carbon matrix and/or carbon fibers to accelerate material loss. Further, damage to brake components may be caused by the oxidation enlargement of cracks around fibers or enlargement of cracks in a reaction-formed porous barrier coating (e.g., a silicon-based barrier coating) applied to the carbon-carbon composite.

Elements identified in severely oxidized regions of carbon-carbon composite brake components include potassium (K) and sodium (Na). These alkali contaminants may come into contact with aircraft brakes as part of cleaning or de-icing materials. Other sources include salt deposits left from seawater or sea spray. These and other contaminants (e.g. Ca, Fe, etc.) can penetrate and leave deposits in pores of carbon-carbon composite aircraft brakes, including the substrate and any reaction-formed porous barrier coating. When such contamination occurs, the rate of carbon loss by oxidation can be increased by one to two orders of magnitude.

In various embodiments, brake disks of aircraft wheel braking assembly10may reach operating temperatures in the range from about 100° C. (212° F.) up to about 900° C. (1652° F.), or higher (e.g., 1093° C. (2000° F.)). However, it will be recognized that the oxidation protection systems compositions and methods of the present disclosure may be readily adapted to many parts in this and other braking assemblies, as well as to other carbon-carbon composite structures susceptible to oxidation losses from infiltration of atmospheric oxygen and/or catalytic contaminants.

In various embodiments, a method for limiting an oxidation reaction in a substrate (e.g., a composite structure) may comprise forming an oxidation protection system on the composite structure. With reference toFIG.2A, a method200for forming an oxidation protection system on a composite structure is illustrated. In accordance with various embodiments, method200may, for example, comprise applying an oxidation inhibiting composition to non-wearing surfaces of carbon-carbon composite brake components, such as non-wear surfaces45and/or lugs54. Non-wear surface45, as labeled inFIG.1A, simply references an exemplary non-wear surface on a brake disk, but non-wear surfaces similar to non-wear surface45may be present on any brake disks (e.g., rotors32, stators34, pressure plate36, end plate38, or the like). In various embodiments, method200may be used on the back face of pressure plate36and/or end plate38, an inner diameter (ID) surface of stators34including slots56, as well as outer diameter (OD) surfaces of rotors32including lugs54. The oxidation inhibiting composition of method200may be applied to preselected regions of a carbon-carbon composite structure that may be otherwise susceptible to oxidation. For example, aircraft brake disks may have the oxidation inhibiting composition applied on or proximate stator slots56, rotor lugs54, and/or non-wear surface45. Method200may be performed on densified carbon-carbon composites. In this regard, method200may be performed after carbonization and densification of the carbon-carbon composite.

In various embodiments, method200may comprise forming a composite slurry (step210) by combining a boron compound, a silicon compound, a glass compound, and an oxygen reactant compound with a carrier fluid (such as, for example, water). In various embodiments, the boron compound may comprise at least one boron-comprising refractory material (e.g., ceramic material). In various embodiments, the boron compound may comprise boron carbide, titanium diboride, boron nitride, zirconium boride, silicon hexaboride, and/or elemental boron.

In various embodiments, the silicon compound may comprise silicon carbide, a silicide compound, silicon, silicon dioxide (SiO2), and/or silicon carbonitride. In various embodiments, the glass compound may be a borosilicate glass composition in the form of a glass frit. In various embodiments, the borosilicate glass composition may comprise silicon dioxide, boron trioxide (B2O3), and/or aluminum oxide (Al2O3). The borosilicate glass composition may comprise in weight percentage 13% B2O3, 61% SiO2, 2% Al2O3, and 4% sodium oxide (Na2O), and may have a coefficient of thermal expansion (CTE) of 3.3×10−6cm/C, a working point of 2286° F. (1252° C.), and an annealing point of 1040° F. (560° C.). In various embodiments, the glass compound may comprise a lithia potash borosilicate glass composition in the form of a glass frit, powder, or other suitable pulverized form and having a CTE of 3.×10−6cm/C, a working point of 1954° F. (1068° C.), and an annealing temperature of 925° F. (496° C.). In various embodiments, the glass compound may comprise borophosphates, a borosilicate composition including in weight percentage, 96% SiO2and 4% B2O3(which is available under the trade name VYCOR® from Corning Incorporated of Corning, New York, USA), quartz, aluminosilicate, boroaluminosilicate, and/or any other suitable glass compound, which may be in the form of a glass frit, powder, or other suitable pulverized form.

The oxygen reactant compound comprises a compound that reacts with oxygen. The oxygen reactant compound tends to reduce the amount of oxygen available for oxidizing the boron component of the boron compound. In this regard, the oxygen reactant compound competes with the boron component of the boron compound for available oxygen, thereby inhibiting oxidation of the boron component. The oxygen reactant compound also reacts with oxidized boron (i.e., boron oxide) to form a glassy boron component (e.g., borosilicates, aluminoborates, borophosphates, etc.). By consuming available oxygen and reacting with oxidized boron, the oxygen reactant compound tends to decrease the amount of boron oxide within the oxidation protection system. Decreasing the amount of boron oxide, which is highly water soluble, tends to increase the water stability of the oxidation protection system. Stated differently, decreasing the amount of boron oxide decreases the probability that the boron oxide will be lost to the environment if the substrate is exposed to water.

In various embodiments, the oxygen reactant compound may be selected from one or more silica forming components such as, for example, SiO2, silicon, silicon carbide, silicon oxycarbide (SiOC), silicates (e.g., sodium silicate, magnesium silicate, etc.), organosilicates (e.g., tetraethylorthosilicate); one or more alumina forming components such as, for example, aluminum oxide, aluminum hydroxide, etc.; a phosphate; a glass composition represented by the formula A′Oxwhere A′ is selected from lithium (Li), Na, magnesium (Mg), barium (Ba), strontium (Sr), calcium (Ca), K, titanium (Ti), zirconium (Zr), and yttrium (Y); or combinations thereof.

In various embodiments, the oxygen reactant compound may form a 0.5% to 20.0% dry weight percentage of the composite slurry (i.e., the weight of the oxygen reactant compound is between 0.5% and 20% of the total weight of the combination of the boron compound, the silicon compound, the glass compound, and the oxygen reactant compound). In various embodiments, the oxygen reactant compound may form a 1.0% to 10.0% dry weight percentage of the composite slurry.

The weight percentage of the boron compound, the silicon compound, the glass compound, and the oxygen reactant compound within the composite slurry may be any suitable weight percentage. In various embodiments, the composite slurry comprises 60% to 70% by weight boron compound, silicon compound, glass compound, and oxygen reactant compound. Stated differently, in various embodiments, the composite slurry comprises 40% to 30% by weight carrier fluid. In various embodiments, the composite slurry comprises 62% to 67% by weight boron compound, silicon compound, glass compound, and oxygen reactant compound; or about a 66% by weight boron compound, silicon compound, glass compound, and oxygen reactant compound. As used in this context only, the term “about” means plus or minus one weight percent.

In various embodiments, the oxygen reactant compound may comprise a powder. The oxygen reactant compound may comprise particles having an average particle size between 20 nanometers (nm) and 20 micrometers (μm) (between 7.9×10−7inch and 7.9×10−4inch), between 30 nm and 10 μm (between 1.2×10−6inch and 3.9×10−4inch), between 30 nm and 2.0 μm (between 1.2×10−6inch and 7.9×10−5inch), or between 50 nm and 0.5 μm (between 2.0×10−6inch and 2.0×10−5inch inch).

In various embodiments, the composite slurry may comprise from 5% to 50% by weight boron compound, from 10% to 40% by weight boron compound, from 20% to 30% by weight boron compound, from 20% to 25% by weight boron compound, from 21% to 22% by weight boron compound, or about 21.1% by weight boron compound. As used in this context only, the term “about” means plus or minus 1 weight percent.

In various embodiments, the boron compound may comprise a boron compound powder (e.g., boron carbide powder). The boron compound comprises particles having an average particle size between 100 nm and 100 μm (between 3.9×10−6inch and 0.0039 inch), between 500 nm and 100 μm (between 2×10−5inch and 0.0039 inch), between 500 nm and 1 μm (between 2×10−5inch and 3.9×10−5inch), between 1 μm and 50 μm (between 3.9×10−5inch and 0.002 inch), between 1 μm and 20 μm (between 3.9×10−5inch and 0.0008 inch), between 1 μm and 10 μm (between 3.9×10−5inch and 0.0004 inch), about 0.7 μm (2.8×10−5inch), about 9.3 μm (0.0004 inch), and/or about 50 μm (0.0020 inches). As used in this context only, the term “about” means plus or minus ten percent of the associated value.

In various embodiments, the boron compound may comprise particles of varying size. In various embodiments, the boron compound comprises a first group of particles having a first average particle size and a second group of particles having a second average particle size greater than the first average particle size.

In various embodiments, the particles of the first group may have an average particle size between 100 nm and 20 μm (between 3.9×10−6inch and 0.0008 inch), between 500 nm and 10 μm (between 2×10−5inch and 0.0004 inch), between 500 nm and 1.0 μm (2×10−5inch and 3.9×10−5inch), or about 0.7 μm (2.8×10−5inch). As used in this context only, the term “about” means plus or minus ten percent of the associated value.

In various embodiments, the particles of the second group may have an average particle size between 500 nm and 60 μm (2×10−5inch and 0.0008 inch), 1 μm and 15 μm (between 2×10−5and 0.0006 inch), between 8 μm and 10.0 μm (between 0.0003 inch and 0.0008 inch), between 45 μm and 55 μm (between 0.0018 inch and 0.0022 inch), about 50 μm (0.0020 inch), and/or about 9.3 μm (0.00039 inch). As used in this context only, the term “about” means plus or minus ten percent of the associated value.

In various embodiments, the composite slurry may comprise from 10% to 40% by weight silicon compound, from 20% to 35% by weight silicon compound, from 25% to 30% by weight silicon compound, and/or about 27.2% by weight silicon compound. As used in this context only, the term “about” means plus or minus one weight percent.

In various embodiments, the silicon compound may comprise a silicon compound powder (e.g., silicon carbide powder). The silicon compound comprises particles having an average particle size between 100 nm and 50 μm (between 3.9×10−6inch and 0.0039 inch), between 500 nm and 20 μm (between 2×10−5inch and 0.0039 inch), between 500 nm and 1.5 μm (between 2×10−5inch and 3.9×10−5inch), between 15 μm and 20 μm (between 3.9×10−5inch and 0.002 inch), about 17 μm (0.0007 inch), and/or about 1.0 μm (4×10−5inch). As used in this context only, the term “about” means plus or minus ten percent of the associated value.

In various embodiments, the silicon compound may comprise silicon compound particles of varying size. In various embodiments, the silicon compound comprises a first group of silicon compound particles having a first average particle size and a second group of silicon compound particles having a second average particle size. The first silicon compound average particle size may be less than the second silicon compound average particle size.

In various embodiments, the silicon compound particles of the first group have an average particle size between 100 nm and 20 μm (between 3.9×10−6inch and 0.0008 inch), 500 nm and 10 μm (between 2×10−5and 0.0004 inch); between 500 nm and 1.5 μm (between 2×10−5and 6×10−5), or about 1.0 μm (4×10−5inch). In various embodiments, the silicon compound particles of the second group may have an average particle size between 1 μm and 50 μm (between 4×10−5inch and 0.002 inch), between 5 μm and 25 μm (between 0.0002 inch and 0.001), between 16 μm and 18 μm (between 0.0006 inch and 0.0007 inch), or about 17 μm (0.00067 inches). As used in this context only, the term “about” means plus or minus ten percent of the associated value. In various embodiments, the silicon compound particles of the first average particle size form a larger weight percentage of the composite slurry as compared to the weight percentage formed by the silicon compound particles of the second average particle size.

In various embodiments, the composite slurry may comprise from 1% to 35% by weight glass compound, from 5% to 25% by weight glass compound, from 12% to 20% by weight glass compound, from 17% to 19% by weight glass compound, or about 18.1% by weight glass compound. As used in this context only, the term “about” means plus or minus one weight percent.

In various embodiments, the glass compound comprises particles having an average particle size between 500 nm and 50 μm (between 3.9×10−6inch and 0.0039 inch), between 5 μm and 25 μm (between 2×10−5inch and 0.0039 inch), between 10 μm and 15 μm (between 2×10−5inch and 3.9×10−5inch), between 11.5 μm and 13 μm (between 3.9×10−5inch and 0.002 inch), or about 12.3 μm (0.0004 inch). As used in this context only, the term “about” means the term “about” means plus or minus ten percent of the associated value.

The remaining weight percent of the composite slurry other than the boron compound, the silicon compound, the glass compound, and the oxygen reactant compound may comprise the carrier fluid and/or any other suitable additives. In various embodiments, the composite slurry consists of boron carbide, silicon carbide, borosilicate glass, silicon dioxide, and water. In various embodiments, the composite slurry may be substantially free of phosphate. In this case, “substantially free” means less than 0.01 percent by weight of the composite slurry.

In various embodiments, the composite slurry may comprise about 21.1% by weight boron carbide having an average particle size of about 9.3 μm (0.0004 inch), about 27.1% by weight silicon carbide having an average particle size of about 1 μm (4×10−5inch), about 18.1% by weight borosilicate glass having an average particle size of about 12.3 μm (0.0005 inch), between about 0.5% and 0.6% by weight silicon dioxide, and about 33.2% by weight water; the borosilicate glass being comprised, in weight percentage of the borosilicate glass, of about 13% B2O3, about 61% SiO2, about 2% Al2O3, and about 4% Na2O. As used in this context only, the term “about” plus or minus ten percent of the associated value.

In various embodiments, method200further comprises applying the composite slurry to a composite structure (step220). Applying the composite slurry may comprise, for example, spraying or brushing the composite slurry to an outer surface of the composite structure. Embodiments in which the carrier fluid for the composite slurry is water tends to cause the aqueous composite slurry to be more suitable for spraying or brushing application processes. Any suitable manner of applying the composite slurry to the composite structure is within the scope of the present disclosure. As referenced herein, the composite structure may refer to a carbon-carbon composite structure. In accordance with various embodiments, the composite slurry may be applied directly on (i.e., in physical contact with) the surface of the composite structure. In this regard, method200generally does not include a pretreatment composition and/or a pretreating step and/or forming a sealing layer prior to applying the composite slurry.

In various embodiments, method200may further comprise heating the composite structure to form a boron-silicon-glass-oxygen reactant layer on the composite structure (step230). In various embodiments, the boron-silicon-glass-oxygen reactant layer may be formed directly adjacent to the composite structure. The heating of the composite structure may remove the carrier fluid from the composite slurry to form the boron-silicon-glass-oxygen reactant layer.

In various embodiments, step230may comprise heating the composite structure at a first, lower temperature followed by heating the composite structure at a second, higher temperature. For example, in various embodiments, the composite structure may undergo a first heat treatment at a first temperature of about 150° F. (65.5° C.) to about 250° F. (121.1° C.) followed by a second heat treatment at a second temperature of about 1600° F. (871° C.) to about 1700° F. (927° C.). In various embodiments, the first temperature may be about 200° F. (93.3° C.) and the second temperature may about 1650° F. (899° C.). As used in this context only, the term “about” means plus or minus 25° F. (4° C.). In various embodiment, the second temperature is selected to be below the working point of the glass compound, for example, below the working point of the borosilicate glass in the composite slurry.

Further, step230may be performed in an inert environment, such as under a blanket of inert or less reactive gas (e.g., nitrogen (N2), argon, other noble gases, and the like). The composite structure may be heated prior to application of composite slurry to aid in the penetration of the composite slurry. The temperature rise may be controlled at a rate that removes water without boiling and provides temperature uniformity throughout the composite structure.

The composite structure may be heated at the first temperature for any suitable length of time for the desired application. In various embodiments, step230may, for example, comprise heating the composite structure at the first temperature for 5 minutes to 8 hours, 10 minutes to 2 hours, 10 minutes to 30 minutes, or about 10 minutes, wherein the term “about” in this context only means plus or minus ten percent of the associated value. The composite may be heated at the second temperature for any suitable length of time for the desired application. In various embodiments, step230may, for example, comprise heating the composite structure at the second temperature for 5 minutes to 8 hours, 0.5 hours to 4 hours, about 1.5 hours to about 2.5 hours, or about 2 hours, wherein the term “about” in this context only means plus or minus ten percent of the associated value. In various embodiments, step230may be the final step, as method200generally does not include a sealing layer step, as may be associated with other oxidation protection systems, for example, oxidation protection systems comprising phosphate sealing layers and/or aluminum phosphate sealing layers. In this regard, the boron-silicon-glass-oxygen reactant layer may form an exterior surface of the oxidation protection system. Stated differently, the boron-silicon-glass-oxygen reactant layer extends from the surface of the composite substrate to the exterior surface of the oxidation protection system.

With additional reference toFIG.1, wear surfaces, such as wear surface33, of brake disks may reach extremely high temperatures during operation (temperatures in excess of 1093° C. (2000° F.)). At such extreme temperatures of wear surfaces, the oxidation protection systems on non-wear surfaces adjacent to the wear surface (e.g., non-wear surface45adjacent to wear surface33) may experience heating. As used herein, a “wear” surface refers to a surface of a friction disk that physically contacts an adjacent friction disk surface. As used herein, a “non-wear” surface refers to a surface of a friction disk that does not physically contact the surface of an adjacent friction disk.

Not to be bound by theory, it is believed that during operation, at elevated temperatures (e.g., around 1700° F. (927° C.) or 1800° F. (982° C.)), oxygen may diffuse through and/or travel through cracks in the boron-silicon-glass-oxygen reactant layer of the oxidation protection system and oxidize the boron compound in the boron-silicon-glass-oxygen reactant layer into boron trioxide (B2O3). At elevated temperatures (e.g., around 1700° F. (927° C.) or 1800° F. (982° C.)), the silicon compound in the boron-silicon-glass-oxygen reactant layer may also react (e.g., oxidize) to form silica. The silica may react with the boron trioxide to form borosilicate glass. The borosilicate glass may be formed in the cracks of the boron-silicon-glass-oxygen reactant layer. Therefore, the oxidation protection systems described herein have self-healing properties to protect against cracks formed in the layers of the oxidation protection systems, preventing, or mitigating against oxygen penetration and the resulting oxidation and loss of material. The oxygen reactant compound may also react (e.g., oxidize) to form, for example, additional silica, and/or alumina (i.e., aluminum oxide). The oxygen reactant compound reacts with the boron trioxide forming, for example, borosilicate glass, aluminoborate glass, borophosphate glass, etc. The oxygen reactant compound reacting with the boron trioxide, tends to decrease or eliminate unreacted boron trioxide from the boron-silicon-glass-oxygen reactant layer, thereby increasing the hydrolytic stability of the boron-silicon-glass-oxygen reactant layer.

In various embodiments and with reference toFIG.2B, a method250of forming an oxidation protection system on a composite structure is illustrated. In addition to steps210,220, and230from method200inFIG.2A, method250may further comprise applying a pretreatment composition (step215) prior to applying the composite slurry (step220). Step215may, for example, comprise applying a pretreatment composition to an outer surface of a composite structure, such as a component of aircraft wheel braking assembly10. In various embodiments, the pretreatment composition comprises an aluminum oxide, a silicon dioxide, or combinations thereof in water. For example, the aluminum oxide may comprise a nanoparticle dispersion of aluminum oxide (for example, NanoBYK-3600®, sold by BYK Additives & Instruments) and/or a nanoparticle dispersion of silicon dioxide. The pretreatment composition may further comprise a surfactant or a wetting agent. The composite structure may be porous, allowing the pretreatment composition to penetrate at least a portion of the pores of the composite structure. In various embodiments, after applying the pretreatment composition, the composite structure is heated to remove water and fix the aluminum oxide and/or silicon dioxide in place and thereby form a pretreatment layer comprised of aluminum oxide and/or silicon dioxide on the composite structure. The composite structure may be heated between about 100° C. (212° F.) and 200° C. (392° F.) or between 100° C. (212° F.) and 150° C. (302° F.). In accordance with various embodiments, method250may include applying the composite slurry (step220) after the composite structure is heated to remove the water (or other carrier fluid) from the pretreatment composition. In this regard, the composite slurry may be applied on the pretreatment layer.

Not to be bound by theory, it is believed that the aluminum oxide and/or silicon dioxide from the pretreatment composition may react with the boron trioxide, which may form in the boron-silicon-glass-oxygen reactant layer at elevated temperatures. The aluminum oxide and/or silicon dioxide reacting with the boron trioxide, tends to decrease or eliminate unreacted boron trioxide from the boron-silicon-glass-oxygen reactant layer, thereby increasing the water stability of the boron-silicon-glass-oxygen reactant layer. In addition, migration of free boron oxide to the wear surface is limited due to reaction with the pretreatment composition. Boric acid is a lubricant; thus, it is desirable to eliminate any mobilization of such species to the wear surface.

With reference toFIG.3A, a method300for forming an oxidation protection system on a composite structure is illustrated. In accordance with various embodiments, method300may, for example, comprise applying an oxidation inhibiting composition to non-wearing surfaces of carbon-carbon composite brake components, such as non-wear surfaces45and/or lugs54. The oxidation inhibiting composition of method300may be applied to preselected regions of a carbon-carbon composite structure that may be otherwise susceptible to oxidation. For example, aircraft brake disks may have the oxidation inhibiting composition applied on non-wear surfaces45. Method300may be performed on densified carbon-carbon composites. In this regard, method300may be performed after carbonization and densification of the carbon-carbon composite.

In various embodiments, method300may comprise forming a boron slurry (step310) by combining a boron compound, a glass compound, and an oxygen reactant compound with a carrier fluid (such as, for example, water). In various embodiments, the boron compound may comprise at least one boron-comprising refractory material (e.g., ceramic materials). In various embodiments, the boron compound may comprise titanium diboride, boron nitride, boron carbide, zirconium boride, silicon hexaboride, and/or elemental boron. In various embodiments, the glass compound may comprise a borosilicate glass. The oxygen reactant compound may be selected from one or more silica forming components, one or more alumina forming components, a phosphate, a glass composition represented by the formula A′Oxwhere A′ is selected from Li, Na, Mg, Ba, Sr, Ca, K, Ti, Zr, and Y, or combinations thereof.

In various embodiments, the oxygen reactant compound may form 0.5% to 20.0% of the dry weight percentage of the composite slurry (i.e., the weight of the oxygen reactant compound is between 0.5% and 20% of the total weight of the combination of the boron compound, the glass compound, and the oxygen reactant compound). In various embodiments, the oxygen reactant compound may form a 1.0% to 10.0% dry weight percentage of the boron slurry.

In various embodiments, the boron slurry may comprise from 5% to 50% by weight boron compound, from 15% to 40% by weight boron compound, from 30% to 40% by weight boron compound, or about 35% by weight boron compound. As used in this context only, the term “about” means plus or minus 1 weight percent.

In various embodiments, the boron compound may comprise a boron compound powder (e.g., boron carbide powder) comprising particles as described previously with regard to method200. In this regard, the boron compound may comprise particles of varying size as previously with regard to method200. In various embodiments, the boron compound comprises a first group of particles having a first average particle size, as previously with regard to method200, and a second group of particles having a second average particle size, as previously with regard to method200, that is greater than the first average particle size. In various embodiments, the boron compound particles of the second average particle size form a larger weight percentage of the boron slurry as compared to the weight percentage formed by the boron compound particles of the first size.

The glass compound of the boron slurry may comprise a borosilicate glass composition, borophosphate, quartz, aluminosilicate, boroaluminosilicate, and/or any other suitable glass compound, which may be in the form of a glass frit, powder, or other suitable pulverized form. In various embodiments, the borosilicate glass composition may comprise in weight percentage 13% B2O3, 61% SiO2, 2% Al2O3, and 4% sodium oxide (Na2O), and may have a CTE of 3.3×10−6cm/C, a working point of 2286° F. (1252° C.), and an annealing point of 1040° F. (560° C.). In various embodiments, the boron slurry may comprise from 1% to 35% by weight glass compound, from 5% to 15% by weight glass compound, or about 10% by weight glass compound. As used in this context only, the term “about” means plus or minus one weight percent.

In various embodiments, method300further comprises applying the boron slurry to a composite structure (step320). Applying the boron slurry may comprise, for example, spraying or brushing the boron slurry to an outer surface of the composite structure. Any suitable manner of applying the boron slurry to the composite structure is within the scope of the present disclosure. As referenced herein, the composite structure may refer to a carbon-carbon composite structure. In accordance with various embodiments, the boron slurry may be applied directly on (i.e., in physical contact with) the surface of the composite structure. In this regard, method300generally does not include a pretreatment composition and/or a pretreating step and/or forming a sealing layer prior to applying the boron slurry or the silicon slurry.

In various embodiments, method300may further comprise performing a first low temperature bake (step330). Step330may include heating the composite structure at a relatively low temperature (for example, a temperature of about 250° F. (121° C.) to about 350° F. (177° C.), or at about 300° F. (149° C.), wherein the term “about” in this context only means plus or minus 25° F. (4° C.)). Step330may include heating the composite structure for about 5 minutes to 8 hours, about 10 minutes to 2 hours, or about 1 hour, wherein the term “about” in this context only means plus or minus ten percent of the associated value.

In various embodiments, method300may comprise forming a silicon slurry (step340) by combining a silicon compound, a glass compound, and an oxygen reactant compound with a carrier fluid (such as, for example, water). In various embodiments, the silicon compound may comprise silicon carbide, a silicide compound, silicon, silicon dioxide, and/or silicon carbonitride.

In various embodiments, the glass compound may comprise a borosilicate glass composition, borophosphate, quartz, aluminosilicate, boroaluminosilicate, and/or any other suitable glass compound, which may be in the form of a glass frit, powder, or other suitable pulverized form. In various embodiments, the borosilicate glass composition may comprise in weight percentage 13% B2O3, 61% SiO2, 2% Al2O3, and 4% sodium oxide (Na2O), and may have a CTE of 3.3×10−6cm/C, a working point of 2286° F. (1252° C.), and an annealing point of 1040° F. (560° C.).

The oxygen reactant compound may be selected from one or more silica forming components, one or more alumina forming components, a phosphate, a glass composition represented by the formula A′Oxwhere A′ is selected from Li, Na, Mg, Ba, Sr, Ca, K, Ti, Zr, and Y, or combinations thereof.

In various embodiments, the oxygen reactant compound may form a 0.5% to 20.0% dry weight percentage of the composite slurry (i.e., the weight of the oxygen reactant compound is between 0.5% and 20% of the total weight of the combination of the boron compound, the glass compound, and the oxygen reactant compound). In various embodiments, the oxygen reactant compound may form a 1.0% to 10.0% dry weight percentage of the boron slurry.

While method300describes forming both the boron slurry and the silicon slurry including an oxygen reactant compound, it is further contemplated and understood that oxygen reactant compound may be eliminated from either the boron slurry or the silicon slurry. In this regard, in various embodiments, method300may include forming either the boron slurry or the silicon slurry including an oxygen reactant compound.

In various embodiments, the silicon slurry may comprise from 10% to 70% by weight silicon compound, from 20% to 55% by weight silicon compound, from 40% to 50% by weight silicon compound, or about 45% by weight silicon compound. As used in this context only, the term “about” means plus or minus 2 weight percent.

In various embodiments, the silicon compound may comprise a silicon compound powder (e.g., silicon carbide powder) comprising particles, as described previously with regard to method200. In various embodiments, the silicon compound may comprise silicon compound particles of varying size, as described previously with regard to method200. In various embodiments, the silicon compound comprises a first group of silicon compound particles having a first average particle size, as described previously with regard to method200, and a second group of silicon compound particles having a second average particle size, as described previously with regard to method200. The first silicon compound average particle size may be less than the second silicon compound average particle size. In various embodiments, the silicon compound particles of the first average particle size form a larger weight percentage of the silicon slurry as compared to the weight percentage formed by the silicon compound particles of the second average particle size.

In various embodiments, the silicon slurry may comprise from 1% to 35% by weight glass compound, from 5% to 15% by weight glass compound, or about 10% by weight glass compound. As used in this context only, the term “about” means plus or minus one weight percent.

In various embodiments, method300further comprises applying the silicon slurry to the composite structure (step350). The silicon slurry may be applied over the boron compound of the boron slurry and after the low temperature bake of step330. In this regard, in various embodiments, the only heat treatment between application of the boron slurry (step320) and the application of the silicon slurry (step350) may be the first low temperature bake (step330). Applying the silicon slurry may comprise, for example, spraying or brushing the boron slurry to an outer surface of the composite structure. Any suitable manner of applying the silicon slurry to the composite structure is within the scope of the present disclosure. As referenced herein, the composite structure may refer to a carbon-carbon composite structure.

In various embodiments, method300may further comprise performing a second low temperature bake (step360). Step360may include heating the composite structure at a relatively low temperature (for example, a temperature of about 250° F. (121° C.) to about 350° F. (177° C.), or at about 300° F. (149° C.), wherein the term “about” in this context only means plus or minus 25° F. (4° C.)). Step360may include heating the composite structure for about 5 minutes to 8 hours, about 10 minutes to 2 hours, or about 1 hour, wherein the term “about” in this context only means plus or minus ten percent of the associated value.

In various embodiments, method300may further comprise performing a high temperature heat treatment to form a boron-oxygen reactant layer and a silicon-oxygen reactant layer on the composite structure (step370). Step370may include heating the composite structure at a relatively high temperature, for example, a temperature of about 1500° F. (816° C.) to about 1700° F. (927° C.), or at about 1650° F. (899° C.), wherein the term “about” in this context only means plus or minus 25° F. (4° C.)). Step370may include heating the composite structure for about 5 minutes to 8 hours, about 30 minutes to 5 hours, or about 2 hours, wherein the term “about” in this context only means plus or minus ten percent of the associated value. Step370is performed after the second low temperature bake (step360).

Not to be bound by theory, it is believed that boron components may become oxidized during service at high temperatures (e.g., temperatures greater than 1300° F. (704° C.)), thereby forming boron trioxide. The boron trioxide may come into contact with oxidized silicon components to form a borosilicate in situ, providing a method of self-healing. For a boron-silicon oxidation protection system, the probability of boron trioxide reacting with oxidized silicon compounds is kinetically controlled and influenced by the amount of each component, surface area, aspect ratio, etc. Boron trioxide is also volatile, especially when hydrated to form boric acid, and may be lost during extended service time. Method300tends to increase the probability of self-healing borosilicate formation by creating a layer of silicon compound by which boron trioxide must transport through prior to volatilization, reducing the dependence on aspect ratio and total amount of components in the slurry. The oxygen reactant compound in the boron-oxygen reactant layer and/or silicon-oxygen reactant layer may also react (e.g., oxidize) to form, for example, additional silica, and/or alumina (i.e., aluminum oxide). The oxygen reactant compound may also react with the boron trioxide forming, for example, borosilicate glass, aluminoborate glass, borophosphate glass, etc. in the boron-oxygen reactant and/or silicon-oxygen reactant layers. The oxygen reactant compound reacting with the boron trioxide, tends to decrease or eliminate unreacted boron trioxide, thereby increasing the water stability of the oxidation protection system.

In various embodiments and with reference toFIG.3B, a method390of forming an oxidation protection system on a composite structure is illustrated. In addition to steps310,320,330,340,350,360, and370from method300inFIG.3A, method390may comprise applying a pretreatment composition to the composite structure (step315) prior to applying the boron slurry (step320). Step315may, for example, comprise applying a pretreatment composition to an outer surface of a composite structure, such as a component of aircraft wheel braking assembly10. In various embodiments, the pretreatment composition comprises an aluminum oxide, a silicon dioxide, or combinations thereof in water. For example, the aluminum oxide may comprise a nanoparticle dispersion of aluminum oxide and/or a nanoparticle dispersion of silicon dioxide. The pretreatment composition may further comprise a surfactant or a wetting agent. In various embodiments, after applying the pretreatment composition, the composite structure is heated to remove water and fix the aluminum oxide and/or silicon dioxide in place. For example, the composite structure may be heated between about 100° C. (212° F.) and 200° C. (392° F.) or between 100° C. (212° F.) and 150° C. (302° F.). In accordance with various embodiments, method390may include applying the boron slurry (step320) after applying the pretreatment composition.

Not to be bound by theory, it is believed that the aluminum oxide and/or silicon dioxide from the pretreatment composition may react with the boron trioxide, which may form in the boron-oxygen reactant layer at elevated temperatures. The aluminum oxide and/or silicon dioxide reacting with the boron trioxide, tends to decrease or eliminate unreacted boron trioxide, thereby increasing the water stability of the oxidation protection system.

With reference toFIG.4, a method of400of forming an oxidation protection system on composite structure is illustrated. In accordance with various embodiments, method400may, for example, comprise applying an oxidation inhibiting composition to non-wearing surfaces of carbon-carbon composite brake components, such as non-wear surfaces45and/or lugs54inFIG.1A. Method400may be performed on densified carbon-carbon composites. In this regard, method400may be performed after carbonization and densification of the carbon-carbon composite.

In various embodiments, method400may comprise applying a pretreatment composition to an outer surface of a composite structure (step410). The composite structure may be a component of aircraft wheel braking assembly10inFIG.1A. In various embodiments, the pretreatment composition comprises an aluminum oxide, a silicon dioxide, or combinations thereof in water. For example, the aluminum oxide may comprise a nanoparticle dispersion of aluminum oxide and/or a nanoparticle dispersion of silicon dioxide. The pretreatment composition may further comprise a surfactant or a wetting agent. In various embodiments, after applying the pretreatment composition, the composite structure is heated to remove water and fix the aluminum oxide and/or silicon dioxide in place. For example, the composite structure may be heated between about 100° C. (212° F.) and 200° C. (392° F.), between 100° C. (212° F.) and 150° C. (302° F.).

Method400may further includes forming a boron-silicon-glass slurry (step420) by combining a boron compound, a silicon compound, and a glass compound with a carrier fluid (such as, for example, water). In various embodiments, the boron compound may comprise at least one boron-comprising refractory material (e.g., ceramic material). In various embodiments, the boron compound may comprise boron carbide, titanium diboride, boron nitride, zirconium boride, silicon hexaboride, and/or elemental boron.

In various embodiments, the silicon compound may comprise silicon carbide, a silicide compound, silicon, silicon dioxide, or silicon carbonitride. In various embodiments, the glass compound may be a borosilicate glass composition, borophosphate, quartz, aluminosilicate, boroaluminosilicate, and/or any other suitable glass compound, which may be in the form of a glass frit, powder, or other suitable pulverized form. In various embodiments, the borosilicate glass composition may comprise in weight percentage 13% B2O3, 61% SiO2, 2% Al2O3, and 4% sodium oxide (Na2O), and may have a CTE of 3.3×10−6cm/C, a working point of 2286° F. (1252° C.), and an annealing point of 1040° F. (560° C.).

In various embodiments, the composite slurry may comprise from 5% to 50% by weight boron compound, from 10% to 40% by weight boron compound, from 20% to 30% by weight boron compound, from 20% to 25% by weight boron compound, from 21% to 22% by weight boron compound, or about 21.2% by weight boron compound. As used in this context only, the term “about” means plus or minus 1 weight percent.

In various embodiments, the boron compound may comprise a boron compound powder (e.g., boron carbide powder) with particles having an average particle size as previously described with respect to method200. In various embodiments, the boron compound may comprise particles of varying size as previously described with respect to method200. In various embodiments, the boron compound comprises a first group of particles having a first average particle size and a second group of particles having a second average particle size greater than the first average particle size.

In various embodiments, the particles of the first group may have an average particle size between 100 nm and 20 μm (between 3.9×10−6inch and 0.0008 inch), between 500 nm and 10 μm (between 2×10−5inch and 0.0004 inch), between 500 nm and 1.0 μm (2×10−5inch and 3.9×10−5inch), or about 0.7 μm (2.8×10−5inch). As used in this context only, the term “about” means plus or minus ten percent of the associated value.

In various embodiments, the particles of the second group may have an average particle size between 500 nm and 60 μm (2×10−5inch and 0.0008 inch), 1 μm and 15 μm (between 2×10−5and 0.0006 inch), between 8 μm and 10.0 μm (between 0.0003 inch and 0.0008 inch), between 45 μm and 55 μm (between 0.0018 inch and 0.0022 inch), about 50 μm (0.0020 inch), and/or about 9.3 μm (0.00039 inch). As used in this context only, the term “about” means plus or minus ten percent of the associated value.

In various embodiments, the boron compound particles of the second average particle size form a larger weight percentage of the boron-silicon-glass slurry as compared to the weight percentage formed by the boron compound particles of the first average size. In various embodiments, the boron-silicon-glass slurry may comprise from 0% to 20% by weight the boron compound first average particle size, 5% to 8% by weight the boron compound first average particle size, about 6.36% by weight the first boron compound average particle size, or about 7.24% by weight the first boron compound average particle size. As used in this context only, the term “about” means plus or minus 0.5% weight percent. In various embodiments, the boron-silicon-glass slurry may comprise from 5% to 30% by weight the second boron compound average particle size, 10% to 25% by weight the second boron compound average particle size, 14% to 23% by weight the second boron compound average particle size, about 14.9% by weight the second boron compound average particle size about 16.9% by weight the second boron compound average particle size, or about 21.2% by weight the second boron compound average particle size. As used in this context only, the term “about” means plus or minus 0.5% weight percent.

In various embodiments, the boron-silicon-glass slurry may comprise from 10% to 40% by weight silicon compound, from 25% to 35% by weight silicon compound, from 27% to 32% by weight silicon compound, about 27.3% by weight silicon compound, or about 31.0% by weight silicon compound. As used in this context only, the term “about” means plus or minus one weight percent.

In various embodiments, the silicon compound may comprise a silicon compound powder (e.g., silicon carbide powder) with particles having an average particle size as described previously with regard to method200.

In various embodiments, the silicon compound may comprise silicon compound particles of varying size. In various embodiments, the silicon compound comprises a first group of silicon compound particles having a first average particle size and a second group of silicon compound particles having a second average particle size. The first silicon compound average particle size may be less than the second silicon compound average particle size.

In various embodiments, the silicon compound particles of the first group have an average particle size between 100 nm and 20 μm (between 3.9×10−6inch and 0.0008 inch), 500 nm and 10 μm (between 2×10−5and 0.0004 inch); between 500 nm and 1.5 μm (between 2×10−5and 6×10−5), or about 1.0 μm (4×10−5inch). In various embodiments, the silicon compound particles of the second group may have an average particle size between 1 μm and 50 μm (between 4×10−5inch and 0.002 inch), between 5 μm and 25 μm (between 0.0002 inch and 0.001), between 16 μm and 18 μm (between 0.0006 inch and 0.0007 inch), or about 17 μm (0.00067 inches). As used in this context only, the term “about” means plus or minus ten percent of the associated value.

In various embodiments, the silicon compound particles of the first average particle size form a larger weight percentage of the boron-silicon-glass composite slurry as compared to the weight percentage formed by the silicon compound particles of the second average particle size. In various embodiments, the boron-silicon-glass slurry may comprise from 0% to 30% by weight the second silicon compound average particle size, 0% to 25% by weight the second silicon compound average particle size, or about 9.3% by weight the second silicon compound average particle size. As used in this context only, the term “about” means plus or minus 1% weight percent. In various embodiments, the boron-silicon-glass slurry may comprise from 5% to 40% by weight the first silicon compound average particle size, 10% to 35% by weight the first silicon compound average particle size, 20% to 30% by weight the first silicon compound average particle size, about 21.7% by weight the second silicon compound average particle size, about 27.3% by weight the second silicon compound average particle size, or about 29.0% by weight the second silicon compound average particle size. As used in this context only, the term “about” means plus or minus 1% weight percent.

In various embodiments, the boron-silicon-glass slurry may comprise from 1% to 35% by weight glass compound, from 5% to 30% by weight glass compound, from 12% to 20% by weight glass compound, from 17% to 19% by weight glass compound, or about 18.2% by weight glass compound. As used in this context only, the term “about” means plus or minus one weight percent.

In various embodiments, the glass compound comprises particles, the average particle size may be between 500 nm and 50 μm (between 3.9×10−6inch and 0.0039 inch), between 5 μm and 25 μm (between 2×10−5inch and 0.0039 inch), between 10 μm and 15 μm (between 2×10−5inch and 3.9×10−5inch), between 11.5 μm and 13 μm (between 3.9×10−5inch and 0.002 inch), or about 12.3 μm (0.0004 inch). As used in this context only, the term “about” means the term “about” means plus or minus ten percent of the associated value.

The remaining weight percent of the boron-silicon-glass composite slurry other than the boron compound, the silicon compound, and the glass compound may comprise the carrier fluid and/or any other suitable additives. In various embodiments, the boron-silicon-glass slurry consists of boron carbide, silicon carbide, borosilicate glass, and water. In various embodiments, the boron-silicon-glass slurry may be substantially free of phosphate. In this case, “substantially free” means less than 0.01 percent by weight of the composite slurry.

In various embodiments, the boron-silicon-glass slurry may comprise about 21.2% by weight boron carbide having an average particle size of about 9.3 μm (0.0004 inch), about 27.3% by weight silicon carbide having an average particle size of about 1 μm (4×10−5inch), about 18.2% by weight borosilicate glass having an average particle size of about 12.3 μm (0.0005 inch), and about 33.3% by weight water; the borosilicate glass being comprised, in weight percentage of the borosilicate glass, of about 13% B2O3, about 61% SiO2, about 2% Al2O3, and about 4% Na2O. As used in this context only, the term “about” plus or minus ten percent of the associated value.

In various embodiments, method400further comprises applying the boron-silicon-glass slurry to a composite structure (step430). Applying the boron-silicon-glass slurry may comprise, for example, spraying or brushing the composite slurry to an outer surface of the composite structure. Embodiments in which the carrier fluid for the composite slurry is water tends to cause the aqueous composite slurry to be more suitable for spraying or brushing application processes. Any suitable manner of applying the composite slurry to the composite structure is within the scope of the present disclosure. As referenced herein, the composite structure may refer to a carbon-carbon composite structure. In accordance with various embodiments, the boron-silicon-glass slurry may be applied over the aluminum oxide and/or silicon dioxide of the pretreatment composition.

In various embodiments, method400may further comprise heating the composite structure to form a boron-silicon-glass layer on the composite structure (step440). Step440may remove the carrier fluid from the boron-silicon-glass slurry to form the boron-silicon-glass layer.

In various embodiments, step440may comprise heating the composite structure at a first, lower temperature followed by heating the composite structure at a second, higher temperature. For example, in various embodiments, the composite structure may undergo a first heat treatment at a first temperature of about 150° F. (65.5° C.) to about 250° F. (121.1° C.) followed by a second heat treatment at a second temperature of about 1600° F. (871° C.) to about 1700° F. (927° C.). In various embodiments, the first temperature may be about 200° F. (93.3° C.) and the second temperature may about 1650° F. (899° C.). As used in this context only, the term “about” means plus or minus 25° F. (4° C.). In various embodiment, the second temperature is selected to be below the working point of the glass compound, for example, below the working point of the borosilicate glass in the composite slurry.

Further, step440may be performed in an inert environment, such as under a blanket of inert or less reactive gas (e.g., nitrogen (N2), argon, other noble gases, and the like). The composite structure may be heated prior to application of composite slurry to aid in the penetration of the composite slurry. The temperature rise may be controlled at a rate that removes water without boiling and provides temperature uniformity throughout the composite structure.

The composite may be heated at the first temperature for any suitable length of time for the desired application. In various embodiments, step440may, for example, comprise heating the composite structure at the first temperature for 5 minutes to 8 hours, 10 minutes to 2 hours, 10 minutes to 30 minutes, or about 10 minutes, wherein the term “about” in this context only means plus or minus ten percent of the associated value. The composite may be heated at the second temperature for any suitable length of time for the desired application. In various embodiments, step440may, for example, comprise heating the composite structure at the second temperature for 5 minutes to 8 hours, 0.5 hours to 4 hours, about 1.5 hours to about 2.5 hours, or about 2 hours, wherein the term “about” in this context only means plus or minus ten percent of the associated value. In various embodiments, step440may be the final step, as method400generally does not include a sealing layer step, as may be associated with other oxidation protection systems, for example, oxidation protection systems comprising phosphate sealing layers and/or aluminum phosphate sealing layers. In this regard, the boron-silicon-glass layer may form an exterior surface of the oxidation protection system.

Not to be bound by theory, it is believed that boron components may become oxidized during service at high temperatures (e.g., temperatures greater than 1300° F. (704° C.)), thereby forming boron trioxide. The boron trioxide may come into contact with oxidized silicon components to form a borosilicate in situ, providing a method of self-healing. The aluminum oxide and/or silicon dioxide from the pretreatment composition may also react with the boron trioxide, which may form in the boron-silicon-glass layer at elevated temperatures. The aluminum oxide and/or silicon dioxide reacting with the boron trioxide, tends to decrease or eliminate unreacted boron trioxide, thereby increasing the water stability of the oxidation protection system.

With reference toFIG.5, a method500for forming an oxidation protection system on composite structure is illustrated. In accordance with various embodiments, method500may, for example, comprise applying an oxidation inhibiting composition to non-wearing surfaces of carbon-carbon composite brake components, such as non-wear surfaces45and/or lugs54inFIG.1A. The oxidation inhibiting composition of method500may be applied to preselected regions of a carbon-carbon composite structure that may be otherwise susceptible to oxidation. Method500may be performed on densified carbon-carbon composites. In this regard, method500may be performed after carbonization and densification of the carbon-carbon composite.

In various embodiments, method500may comprise applying a pretreatment composition to an outer surface of a composite structure (step505). The composite structure may be a component of aircraft wheel braking assembly10inFIG.1A. In various embodiments, the pretreatment composition comprises an aluminum oxide, a silicon dioxide, or combinations thereof in water. For example, the aluminum oxide may comprise a nanoparticle dispersion of aluminum oxide and/or a nanoparticle dispersion of silicon dioxide. The pretreatment composition may further comprise a surfactant or a wetting agent. In various embodiments, after applying the pretreatment composition, the composite structure is heated to remove water and fix the aluminum oxide and/or silicon dioxide in place. For example, the composite structure may be heated between about 100° C. (212° F.) and 200° C. (392° F.), between 100° C. (212° F.) and 150° C. (302° F.).

Method500may further includes forming a boron slurry (step510) by combining a boron compound and a glass compound with a carrier fluid (such as, for example, water). In various embodiments, the boron compound may comprise at least one boron-comprising refractory material (e.g., ceramic materials). In various embodiments, the boron compound may comprise titanium diboride, boron nitride, boron carbide, zirconium boride, silicon hexaboride, and/or elemental boron. In various embodiments, the glass compound may comprise a borosilicate glass.

In various embodiments, the boron-silicon-glass composite slurry may comprise from 5% to 50% by weight boron compound, from 15% to 40% by weight boron compound, from 30% to 40% by weight boron compound, or about 35% by weight boron compound. As used in this context only, the term “about” means plus or minus 1 weight percent.

In various embodiments, the boron compound may comprise a boron compound powder (e.g., boron carbide powder) with particles having an average particle size as described previous with respect to method200. In various embodiments, the boron compound may comprise particles of varying size. In various embodiments, the boron compound comprises a first group of particles having a first average particle size and a second group of particles having a second average particle size greater than the first average particle size.

In various embodiments, the particles of the first group may have an average particle size between 100 nm and 20 μm (between 3.9×10−6inch and 0.0008 inch), between 500 nm and 10 μm (between 2×10−5inch and 0.0004 inch), between 500 nm and 1.0 μm (2×10−5inch and 3.9×10−5inch), or about 0.7 μm (2.8×10−5inch). As used in this context only, the term “about” means plus or minus ten percent of the associated value.

In various embodiments, the particles of the second group may have an average particle size between 500 nm and 60 μm (2×10−5inch and 0.0008 inch), 1 μm and 15 μm (between 2×10−5and 0.0006 inch), between 8 μm and 10.0 μm (between 0.0003 inch and 0.0008 inch), between 45 μm and 55 μm (between 0.0018 inch and 0.0022 inch), about 50 μm (0.0020 inch), and/or about 9.3 μm (0.00039 inch). As used in this context only, the term “about” means plus or minus ten percent of the associated value.

In various embodiments, the boron compound particles of the second average particle size form a larger weight percentage of the boron slurry as compared to the weight percentage formed by the boron compound particles of the first size. In various embodiments, the boron-silicon-glass composite slurry may comprise from 0% to 20% by weight the boron compound first average particle size, 5% to 15% by weight the boron compound first average particle size, or about 10.5% by weight the first boron compound average particle size. As used in this context only, the term “about” means plus or minus 0.5% weight percent. In various embodiments, the boron slurry may comprise from 5% to 50% by weight the second boron compound average particle size, 10% to 30% by weight the second boron compound average particle size, 20% to 25% by weight the second boron compound average particle size, or about 24.5% by weight the second boron compound average particle size. As used in this context only, the term “about” means plus or minus 0.5% weight percent.

In accordance with various embodiments, the glass compound of the boron slurry may be a borosilicate glass composition, borophosphate, quartz, aluminosilicate, boroaluminosilicate, and/or any other suitable glass compound, which may be in the form of a glass frit, powder, or other suitable pulverized form. In various embodiments, the borosilicate glass composition may comprise in weight percentage 13% B2O3, 61% SiO2, 2% Al2O3, and 4% sodium oxide (Na2O), and may have a CTE of 3.3×10−6cm/C, a working point of 2286° F. (1252° C.), and an annealing point of 1040° F. (560° C.).

In various embodiments, the boron-slurry may comprise from 1% to 35% by weight glass compound, from 5% to 15% by weight glass compound, or about 10% by weight glass compound. As used in this context only, the term “about” means plus or minus 0.5 weight percent.

In various embodiments, the glass compound comprises particles, the average particle size may be between 500 nm and 50 μm (between 3.9×10−6inch and 0.0039 inch), between 5 μm and 25 μm (between 2×10−5inch and 0.0039 inch), between 10 μm and 15 μm (between 2×10−5inch and 3.9×10−5inch), between 11.5 μm and 13 μm (between 3.9×10−5inch and 0.002 inch), or between about 12.3 μm (0.0004 inch). As used in this context only, the term “about” means plus or minus 0.5 weight percent.

In various embodiments, method500further comprises applying the boron slurry to a composite structure (step520). Applying the boron slurry may comprise, for example, spraying or brushing the boron slurry to an outer surface of the composite structure. Any suitable manner of applying the boron-slurry to the composite structure is within the scope of the present disclosure. As referenced herein, the composite structure may refer to a carbon-carbon composite structure. The boron slurry may be applied over the aluminum oxide and/or silicon dioxide of the pretreatment composition.

In various embodiments, method500may further comprise performing a first low temperature bake (step530). Step530may include heating the composite structure at a relatively low temperature (for example, a temperature of about 250° F. (121° C.) to about 350° F. (177° C.), or at about 300° F. (149° C.), wherein the term “about” in this context only means plus or minus 25° F. (4° C.)). Step530may include heating the composite structure for about 5 minutes to 8 hours, about 10 minutes to 2 hours, or about 1 hour, wherein the term “about” in this context only means plus or minus ten percent of the associated value.

In various embodiments, method500may comprise forming a silicon slurry (step540) by combining a silicon compound and a glass compound with a carrier fluid (such as, for example, water). In various embodiments, the silicon compound may comprise silicon carbide, a silicide compound, silicon, silicon dioxide, and/or silicon carbonitride.

The weight percentage of the silicon compound within the silicon slurry may be any suitable weight percentage for the desired application. In various embodiments, the silicon slurry may comprise from 10% to 70% by weight silicon compound, from 20% to 55% by weight silicon compound, from 40% to 50% by weight silicon compound, or about 45% by weight silicon compound. As used in this context only, the term “about” means plus or minus 2 weight percent.

In various embodiments, the silicon compound may comprise a silicon compound powder (e.g., silicon carbide powder) including particles having an average particle size as described previously with respect to method200. In various embodiments, the silicon compound may comprise silicon compound particles of varying size. In various embodiments, the silicon compound comprises a first group of silicon compound particles having a first average particle size and a second group of silicon compound particles having a second average particle size. The first silicon compound average particle size may be less than the second silicon compound average particle size.

In various embodiments, the silicon compound particles of the first group have an average particle size between 100 nm and 20 μm (between 3.9×10−6inch and 0.0008 inch), 500 nm and 10 μm (between 2×10−5and 0.0004 inch); between 500 nm and 1.5 μm (between 2×10−5and 6×10−5), or about 1.0 μm (4×10−5inch). In various embodiments, the silicon compound particles of the second group may have an average particle size between 1 μm and 50 μm (between 4×10−5inch and 0.002 inch), between 5 μm and 25 μm (between 0.0002 inch and 0.001), between 16 μm and 18 μm (between 0.0006 inch and 0.0007 inch), or about 17 μm (0.00067 inches). As used in this context only, the term “about” means plus or minus ten percent of the associated value.

In various embodiments, the silicon compound particles of the first average particle size form a larger weight percentage of the boron-silicon-glass composite slurry as compared to the weight percentage formed by the silicon compound particles of the second average particle size. In various embodiments, the silicon slurry may comprise from 0% to 30% by weight the second silicon compound average particle size, 0% to 20% by weight the second silicon compound average particle size, or about 13% by weight the second silicon compound average particle size. As used in this context only, the term “about” means plus or minus 1% weight percent. In various embodiments, the silicon slurry may comprise from 5% to 80% by weight the first silicon compound average particle size, 20% to 60% by weight the first silicon compound average particle size, 30% to 50% by weight the first silicon compound average particle size, about 31.5% by weight the second silicon compound average particle size, or about 45.0% by weight the second silicon compound average particle size. As used in this context only, the term “about” means plus or minus 1% weight percent.

In various embodiments, the glass compound of the silicon slurry may be a borosilicate glass composition, borophosphate, quartz, aluminosilicate, boroaluminosilicate, and/or any other suitable glass compound, which may be in the form of a glass frit, powder, or other suitable pulverized form. In various embodiments, the borosilicate glass composition may comprise in weight percentage 13% B2O3, 61% SiO2, 2% Al2O3, and 4% sodium oxide (Na2O), and may have a CTE of 3.3×10−6cm/C, a working point of 2286° F. (1252° C.), and an annealing point of 1040° F. (560° C.).

In various embodiments, the silicon slurry may comprise from 1% to 35% by weight glass compound, from 5% to 15% by weight glass compound, or about 10% by weight glass compound. As used in this context only, the term “about” means plus or minus 0.5 weight percent.

In various embodiments, the glass compound comprises particles having an average particle size of between 500 nm and 50 μm (between 3.9×10−6inch and 0.0039 inch), between 5 μm and 25 μm (between 2×10−5inch and 0.0039 inch), between 10 μm and 15 μm (between 2×10−5inch and 3.9×10−5inch), between 11.5 μm and 13 μm (between 3.9×10−5inch and 0.002 inch), or about 12.3 μm (0.0004 inch). As used in this context only, the term “about” means plus or minus 0.5 weight percent.

In various embodiments, method500further comprises applying the silicon slurry to the composite structure (step550). The silicon slurry may be applied over the boron compound of the boron slurry and after the low temperature bake of step530. In this regard, in various embodiments, the only heat treatment between application of the boron slurry (step520) and the application of the silicon slurry (step550) may be the first low temperature bake (step530). Applying the silicon slurry may comprise, for example, spraying or brushing the silicon slurry over an outer surface of the composite structure. Any suitable manner of applying the silicon slurry to the composite structure is within the scope of the present disclosure. As referenced herein, the composite structure may refer to a carbon-carbon composite structure.

In various embodiments, method500may further comprise performing a second low temperature bake (step560). Step560may include heating the composite structure at a relatively low temperature (for example, a temperature of about 250° F. (121° C.) to about 350° F. (177° C.), or at about 300° F. (149° C.), wherein the term “about” in this context only means plus or minus 25° F. (4° C.)). Step560may include heating the composite structure for about 5 minutes to 8 hours, about 10 minutes to 2 hours, or about 1 hour, wherein the term “about” in this context only means plus or minus ten percent of the associated value.

In various embodiments, method500may further comprise performing a high temperature heat treatment to form the boron layer and the silicon layer (step570). Step570may include heating the composite structure at a relatively high temperature (for example, a temperature of about 1500° F. (816° C.) to about 1700° F. (927° C.), or at about 1650° F. (899° C.), wherein the term “about” in this context only means plus or minus 25° F. (4° C.)). Step570may include heating the composite structure for about 5 minutes to 8 hours, about 30 minutes to 5 hours, or about 2 hours, wherein the term “about” in this context only means plus or minus 10% of the associated value. Step570is performed after the second low temperature bake (step560).

Not to be bound by theory, it is believed that boron components may become oxidized during service at high temperatures (e.g., temperatures greater than 1300° F. (704° C.)), thereby forming boron trioxide. The boron trioxide may come into contact with oxidized silicon components to form a borosilicate in situ, providing a method of self-healing. Method500tends to increase the probability of self-healing borosilicate formation by creating a layer of silicon compound by which boron trioxide must transport through prior to volatilization, reducing the dependence on aspect ratio and total amount of components in the slurry. Additionally, the aluminum oxide and/or silicon dioxide from the pretreatment composition may react with the boron trioxide. The aluminum oxide and/or silicon dioxide reacting with the boron trioxide, tends to decrease or eliminate unreacted boron trioxide, thereby increasing the water stability of the oxidation protection system. Further, locating the silicon layer (e.g., a silicon carbide layer) over the boron layer (e.g., a boron carbide layer), such that the boron layer is between the composite structure and the silicon layer tends to protect the boron layer, which may slow the rate of oxidation of boron within the boron layer.

In various embodiments and with reference toFIG.6A, a method600of forming an oxidation protection system on a composite structure is illustrated. In various embodiments, method600may comprise applying a pretreatment composition to the composite structure (step610). Step610may, for example, comprise applying a pretreatment composition to an outer surface of a composite structure, such as a component of aircraft wheel braking assembly10. In various embodiments, the pretreatment composition comprises an aluminum oxide, a silicon dioxide, or combinations thereof in water. For example, the aluminum oxide may comprise a nanoparticle dispersion of aluminum oxide (for example, NanoBYK-3600®, sold by BYK Additives & Instruments) and/or a nanoparticle dispersion of silicon dioxide. The pretreatment composition may further comprise a surfactant or a wetting agent. The composite structure may be porous, allowing the pretreatment composition to penetrate at least a portion of the pores of the composite structure. In various embodiments, after applying the pretreatment composition, the composite structure is heated to remove water and fix the aluminum oxide and/or silicon dioxide in place and thereby form a pretreatment layer comprised of aluminum oxide and/or silicon dioxide on the composite structure. The component may be heated between about 100° C. (212° F.) and 200° C. (392° F.) or between 100° C. (212° F.) and 150° C. (302° F.).

In accordance with various embodiments, method600may further include forming a boron layer over the composite structure (step620) after applying the pretreatment composition. Step620may be performed after the water is removed from the pretreatment composition. In various embodiments, the boron layer may be formed using chemical vapor deposition (CVD). The boron layer comprises a boron compound. The boron compound may be at least one of titanium diboride, boron nitride, boron carbide, zirconium boride, silicon hexaboride, or elemental boron. In accordance with various embodiments, the pretreatment layer is located between the boron layer and the surface of the composite structure.

In accordance with various embodiments, method600may further include forming a silicon layer over the boron layer (step630). In various embodiments, the silicon layer may be formed using CVD. The silicon layer comprises a silicon compound. The silicon compound may comprise silicon carbide, a silicide compound, silicon, silicon dioxide (SiO2), or silicon carbonitride. In accordance with various embodiments, the boron layer is located between the pretreatment layer and the silicon layer. In various embodiments, the boron layer comprises boron carbide and the silicon layer comprises silicon carbide.

Not to be bound by theory, it is believed that the aluminum oxide and/or silicon dioxide from the pretreatment composition may react with the boron trioxide, which may form in the boron layer at elevated temperatures. The aluminum oxide and/or silicon dioxide reacting with the boron trioxide, tends to decrease or eliminate unreacted boron trioxide from the boron layer, thereby increasing the water stability of the boron layer. In addition, migration of free boron oxide to the wear surface is limited due to reaction with the pretreatment composition. Boric acid is a lubricant, therefore, it is desirable to eliminate any mobilization of such species to the wear surface. Further, locating the silicon layer over the boron layer tends to protect and/or form a barrier over the boron layer, which may slow the oxidation rate of boron within the boron layer.

In various embodiments and with reference toFIG.6B, a method650of forming an oxidation protection system on a composite structure is illustrated. In addition to steps610,620, and630from method600inFIG.6A, method650may further comprise applying a sealing layer (step640) on the silicon layer (i.e., after step630). Step640may, for example, comprise forming a sealing slurry and applying the sealing slurry over the silicon layer. The sealing slurry may be in direct contact with the silicon layer. Applying the sealing slurry may comprise, for example, spraying or brushing the sealing slurry to the silicon layer. Any suitable manner of applying the slurry to the composite structure is within the scope of the present disclosure.

In various embodiments, the sealing slurry may comprise a monoaluminum phosphate solution and a carrier fluid (e.g., water). The monoaluminum phosphate solution may comprise any suitable make-up. In various embodiments, the monoaluminum phosphate solution may comprise about 50% by weight monoaluminum phosphate and about 50% by weight carrier fluid (e.g., water), wherein “about” as used in this context means plus or minus 40% by weight.

In various embodiments, the sealing slurry may further comprise phosphoric acid. In such embodiments, the sealing slurry may comprise about 10% to 30% by weight phosphoric acid, about 20% to 30% by weight phosphoric acid, about 20% by weight phosphoric acid, and/or about 25% by weight phosphoric acid (“about” used in this context means plus or minus 5% weight). In various embodiments, the sealing slurry may further comprise water and/or a surfactant. In such embodiments, the sealing slurry may comprise about 10% to 20% by weight water, about 15% to 20% by weight water, or about 19% by weight water (“about” used in this context means plus or minus 3% weight), and about 1% by weight surfactant (“about” used in this context means plus or minus 0.5% weight). The surfactant may comprise, for example, a silicon-based surfactant. In various embodiments, the sealing slurry may comprise about 25% by weight phosphoric acid and about 75% by weight monoaluminum phosphate solution, the monoaluminum phosphate solution being 50% by weight monoaluminum phosphate and 50% by weight water. In this context only, the term “about” means plus or minus 10% by weight. In various embodiments, the sealing slurry may comprise about 20% by weight phosphoric acid, about 20% by weight water, about 1% by weight silicon based surfactant, and about 60% by weight monoaluminum phosphate solution, the monoaluminum phosphate solution being 50% by weight monoaluminum phosphate and 50% by weight water. In this context only, the term “about” means plus or minus 10% by weight.

In various embodiments, the sealing slurry may be a phosphate glass sealing slurry comprising a pre-slurry composition and a carrier fluid (such as, for example, water). The pre-slurry composition may comprise a phosphate glass composition in glass frit or powder form. In various embodiments, the pre-slurry composition may further comprise ammonium dihydrogen phosphate (ADHP) and/or aluminum orthophosphate.

The phosphate glass composition may comprise and/or be combined with one or more alkali metal glass modifiers, one or more glass network modifiers and/or one or more additional glass formers. In various embodiments, boron oxide or a precursor may optionally be combined with the P2O5mixture to form a borophosphate glass, which has improved self-healing properties at the operating temperatures typically seen in aircraft braking assemblies. In various embodiments, the phosphate glass and/or borophosphate glass may be characterized by the absence of an oxide of silicon. Further, the ratio of P2O5to metal oxide in the fused glass may be in the range from about 0.25 to about 5 by weight.

The phosphate glass composition may be prepared by combining the above ingredients and heating them to a fusion temperature. In various embodiments, depending on the particular combination of elements, the fusion temperature may be in the range from about 700° C. (1292° F.) to about 1500° C. (2732° F.). The resultant melt may then be cooled and pulverized and/or ground to form a glass frit or powder. In various embodiments, the phosphate glass composition may be annealed to a rigid, friable state prior to being pulverized. Glass transition temperature (Tg), glass softening temperature (Ts) and glass melting temperature (Tm) may be increased by increasing refinement time and/or temperature. Before fusion, the phosphate glass composition comprises from about 20 mol % to about 80 mol % of P2O5. In various embodiments, the phosphate glass composition comprises from about 30 mol % to about 70 mol % P2O5, or precursor thereof. In various embodiments, the phosphate glass composition comprises from about 40 mol % to about 60 mol % of P2O5. In this context, the term “about” means plus or minus 5 mol %.

The phosphate glass composition may comprise, or be combined with, from about 5 mol % to about 50 mol % of the alkali metal oxide. In various embodiments, the phosphate glass composition may comprise, or be combined with, from about 10 mol % to about 40 mol % of the alkali metal oxide. Further, the phosphate glass composition may comprise, or be combined with, from about 15 mol % to about 30 mol % of the alkali metal oxide or one or more precursors thereof. In various embodiments, the phosphate glass composition may comprise, or be combined with, from about 0.5 mol % to about 50 mol % of one or more of the above-indicated glass formers. The phosphate glass composition may comprise, or be combined with, about 5 mol % to about 20 mol % of one or more of the above-indicated glass formers. As used herein, mol % is defined as the number of moles of a constituent per the total moles of the solution.

In various embodiments, the phosphate glass composition may be represented by the formula:
a(A′2O)x(P2O5)y1b(GfO)y2c(A″O)z[1]

In Formula 1, A′ is selected from: lithium, sodium, potassium, rubidium, cesium, and mixtures thereof; Gfis selected from: boron, silicon, sulfur, germanium, arsenic, antimony, and mixtures thereof; A″ is selected from: vanadium, aluminum, tin, titanium, chromium, manganese, iron, cobalt, nickel, copper, mercury, zinc, thulium, lead, zirconium, lanthanum, cerium, praseodymium, neodymium, samarium, europium, gadolinium, terbium, dysprosium, holmium, erbium, thulium, ytterbium, actinium, thorium, uranium, yttrium, gallium, magnesium, calcium, strontium, barium, tin, bismuth, cadmium, and mixtures thereof; a is a number in the range from 1 to about 5; b is a number in the range from 0 to about 10; c is a number in the range from 0 to about 30; x is a number in the range from about 0.050 to about 0.500; y1 is a number in the range from about 0.100 to about 0.950; y2 is a number in the range from 0 to about 0.20; and z is a number in the range from about 0.01 to about 0.5; (x+y1+y2+z)=1; and x<(y1+y2). The phosphate glass composition may be formulated to balance the reactivity, durability, and flow of the resulting glass boron layer for optimal performance. As used in this context, the term “about” means plus or minus ten percent of the respective value.

The phosphate glass sealing slurry may comprise any suitable weight percentage phosphate glass composition. For example, the phosphate glass sealing slurry may comprise between 20% and 50% by weight phosphate glass composition, between 20% and 40% by weight phosphate glass composition, between 20% and 30% by weight phosphate glass composition, and/or between 30% and 40% by weight phosphate glass composition. The pre-slurry composition (and/or the resulting glass sealing layer) may comprise any suitable weight percentage of phosphate glass composition. For example, the pre-slurry composition may comprise between 50% and 95% by weight phosphate glass composition, between 60% and 90% by weight phosphate glass composition, and/or between 70% and 80% by weight phosphate glass composition.

In various embodiments, the sealing slurry may be a borosilicate glass sealing slurry comprising a borosilicate glass and a carrier fluid (e.g., water). In various embodiments, the borosilicate glass sealing slurry may comprise from 10% to 60% by weight borosilicate glass, from 20% to 50% by weight borosilicate glass, and/or from about 30% to 40% by weight borosilicate glass. In various embodiments, the borosilicate glass sealing slurry may comprise about 40% by weight borosilicate glass. In various embodiments, the borosilicate glass sealing slurry may comprise about 60% by weight water. In various embodiments, the borosilicate glass sealing slurry may comprise from 40% to 90% by weight water, from 50% to 80% by weight water, and/or from 60% to 70% by weight water. In various embodiments, the borosilicate glass sealing slurry may comprise about 40% by weight borosilicate glass and 60% by weight water. In this context, “about” means plus or minus 5% by weight. In various embodiments, the borosilicate glass comprised in the borosilicate glass sealing slurry may comprise any suitable borosilicate glass and/or any suitable composition. In various embodiments, the borosilicate glass may comprise silicon dioxide (SiO2), boron trioxide (B2O3), and/or aluminum oxide (Al2O3).

In various embodiments, step640may further comprise heating the composite structure to form a sealing layer from the sealing slurry (including, for example, forming a borosilicate and/or phosphate glass sealing layer from the borosilicate and/or phosphate glass sealing slurry). The composite structure may be heated to 200° C. (292° F.) to about 1000° C. (1832° F.). The composite structure may be heated at a temperature sufficient to adhere the sealing layer to the silicon layer by, for example, drying or baking the carbon-carbon composite structure at a temperature in the range from about 200° C. (392° F.) to about 1000° C. (1832° F.). In various embodiments, the composite structure is heated to a temperature in a range from about 600° C. (1112° F.) to about 1000° C. (1832° F.), or between about 200° C. (392° F.) to about 900° C. (1652° F.), or further, between about 400° C. (752° F.) to about 850° C. (1562° F.), wherein in this context only, the term “about” means plus or minus 10° C. Further, step260may, for example, comprise heating the composite structure for a period between about 0.5 hour and 3 hours, between about 0.5 hour and about 8 hours, or for about 2 hours, where the term “about” in this context only means plus or minus 0.25 hours.

In various embodiments, step640may comprise heating the composite structure to a first, lower temperature (for example, about 30° C. (86° F.) to about 300° C. (572° F.)) followed by heating at a second, higher temperature (for example, about 300° C. (572° F.) to about 1000° C. (1832° F.)). Further, step640may be performed in an inert environment, such as under a blanket of inert or less reactive gas (e.g., nitrogen, argon, other noble gases, and the like).

In various embodiments, the oxidation protection system may comprise one sealing layer comprising monoaluminum phosphate and phosphoric acid, and/or a borosilicate and/or phosphate glass sealing layer. In various embodiments, the oxidation protection system may comprise multiple sealing layers in any suitable layering order atop the silicon layer. For example, forming an oxidation protection system may comprise disposing a sealing layer comprising monoaluminum phosphate and phosphoric acid onto the composite structure (e.g., onto the silicon layer of the oxidation protection system), heating the composite structure to form a first phosphate sealing layer as described herein, disposing a second sealing slurry (e.g., a glass sealing slurry) onto the first phosphate sealing layer, and heating the composite structure as described herein to form a phosphate glass sealing layer. Either phosphate sealing layer in the previous example may be disposed first or second onto the silicon layer.

In various embodiments, step640may comprise applying a first sealing slurry to the silicon layer, heating the composite structure to a temperature sufficient to form a first sealing layer, applying a second sealing slurry to the first sealing layer, and heating the composite structure to a temperature sufficient to form a second sealing layer. In various embodiments, the first sealing slurry may comprise about 20% by weight phosphoric acid, about 20% by weight water, about 1% by weight silicon based surfactant, and about 60% by weight monoaluminum phosphate solution, the monoaluminum phosphate solution being 50% by weight monoaluminum phosphate and 50% by weight water. The second sealing slurry may comprise about 25% by weight phosphoric acid and about 75% by weight monoaluminum phosphate solution, the monoaluminum phosphate solution being 50% by weight monoaluminum phosphate and 50% by weight water. In this context only, the term “about” means plus or minus 10% by weight. In various embodiments, the sealing slurry may

As will be appreciated by those skilled in the art, the silicon layer and/or the boron layer of the oxidation protection system may experience cracking during thermal oxidation. The effects of the cracking may be mitigated by adding sealing layer(s), for example, phosphate sealing layers and/or aluminum phosphate sealing layers, over the silicon layer.

Not to be bound by theory, it is believed that during operation, at elevated temperatures (e.g., around 1700° F. (927° C.) or 1800° F. (982° C.)), oxygen may diffuse and/or travel through cracks in the silicon layer and/or on the sealing layer(s) of the oxidation protection system and oxidize the boron compound in the boron layer into boron trioxide (B2O3). At elevated temperatures (e.g., around 1700° F. (927° C.) or 1800° F. (982° C.)), the silicon compound in the silicon layer may also react (e.g., oxidize) to form silica. The silica may react with the boron trioxide to form borosilicate glass. The borosilicate glass may be formed in the cracks in the silicon layer and/or sealing layer(s), and/or flow into cracks formed in the silicon layer and/or sealing layer(s). Therefore, the oxidation protection systems described herein have self-healing properties to protect against cracks formed in the layers of the oxidation protection systems, preventing, or mitigating against oxygen penetration and the resulting oxidation and loss of material. Further, the aluminum oxide and/or silicon dioxide from the pretreatment composition may react with the boron trioxide, which may form in the boron layer at elevated temperatures. The aluminum oxide and/or silicon dioxide reacting with the boron trioxide, tends to decrease or eliminate unreacted boron trioxide from the boron layer, thereby increasing the water stability of the oxidation protection system. In addition, migration of free boron oxide to the wear surface is limited due to reaction with the pretreatment composition. Boric acid is a lubricant; thus, it is desirable to eliminate any mobilization of such species to the wear surface.

Benefits and other advantages have been described herein with regard to specific embodiments. Furthermore, the connecting lines shown in the various figures contained herein are intended to represent exemplary functional relationships and/or physical couplings between the various elements. It should be noted that many alternative or additional functional relationships or physical connections may be present in a practical system. However, the benefits, advantages, solutions to problems, and any elements that may cause any benefit, advantage, or solution to occur or become more pronounced are not to be construed as critical, required, or essential features or elements of the disclosure. The scope of the disclosure is accordingly to be limited by nothing other than the appended claims, in which reference to an element in the singular is not intended to mean “one and only one” unless explicitly so stated, but rather “one or more.” Moreover, where a phrase similar to “at least one of A, B, or C” is used in the claims, it is intended that the phrase be interpreted to mean that A alone may be present in an embodiment, B alone may be present in an embodiment, C alone may be present in an embodiment, or that any combination of the elements A, B and C may be present in a single embodiment; for example, A and B, A and C, B and C, or A and B and C.

Systems, methods and apparatus are provided herein. In the detailed description herein, references to “one embodiment,” “an embodiment,” “an example embodiment,” etc., indicate that the embodiment described may include a particular feature, structure, or characteristic, but every embodiment may not necessarily include the particular feature, structure, or characteristic. Moreover, such phrases are not necessarily referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with an embodiment, it is submitted that it is within the knowledge of one skilled in the art to affect such feature, structure, or characteristic in connection with other embodiments whether or not explicitly described. After reading the description, it will be apparent to one skilled in the relevant art(s) how to implement the disclosure in alternative embodiments.

Furthermore, no element, component, or method step in the present disclosure is intended to be dedicated to the public regardless of whether the element, component, or method step is explicitly recited in the claims. No claim element herein is intended to invoke 35 U.S.C. 112(f), unless the element is expressly recited using the phrase “means for.” As used herein, the terms “comprises,” “comprising,” or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.