Abstract: A method includes producing an amorphous precursor to a nanocomposite, the amorphous precursor comprising a material that is substantially without crystals not exceeding 20% volume fraction; performing devitrification of the amorphous precursor, wherein the devitrification comprises a process of crystallization; forming, based on the devitrification, the nanocomposite with nano-crystals that contains an induced magnetic anisotropy; tuning, based on one or more of composition, temperature, configuration, and magnitude of stress applied during annealing and modification, the magnetic anisotropy of the nanocomposite; and adjusting, based on the tuned magnetic anisotropy, a magnetic permeability of the nanocomposite.

Abstract: A method comprises inputting used oil analysis data to a pre-trained predictive model, the used oil analysis data including values quantifying a plurality of chemical components measured in a sample of used oil taken from an engine under analysis, determining a probability of at least one fail code with the pre-trained predictive model in response to the used oil analysis data, the at least one fail code corresponding to one of a plurality of predetermined engine failure types, providing the at least one fail code and the probability of the at least one fail code to an expert system, performing with the expert system a root cause analysis of the at least one fail code determine a root cause indicating a preventative maintenance action, and performing the predictive maintenance action on the engine under analysis.

Abstract: A method includes producing an amorphous precursor to a nanocomposite, the amorphous precursor comprising a material that is substantially without crystals not exceeding 20% volume fraction; performing devitrification of the amorphous precursor, wherein the devitrification comprises a process of crystallization; forming, based on the devitrification, the nanocomposite with nano-crystals that contains an induced magnetic anisotropy; tuning, based on one or more of composition, temperature, configuration, and magnitude of stress applied during annealing and modification, the magnetic anisotropy of the nanocomposite; and adjusting, based on the tuned magnetic anisotropy, a magnetic permeability of the nanocomposite.

Abstract: A method includes producing an amorphous precursor to a nanocomposite, the amorphous precursor comprising a material that is substantially without crystals not exceeding 20% volume fraction; performing devitrification of the amorphous precursor, wherein the devitrification comprises a process of crystallization; forming, based on the devitrification, the nanocomposite with nano-crystals that contains an induced magnetic anisotropy; tuning, based on one or more of composition, temperature, configuration, and magnitude of stress applied during annealing and modification, the magnetic anisotropy of the nanocomposite; and adjusting, based on the tuned magnetic anisotropy, a magnetic permeability of the nanocomposite.

Abstract: A support member for mounting photovoltaic modules on a support surface and a mounting system including the same are disclosed herein. The support member may comprise a body portion, the body portion including a ballast receiving portion for accommodating one or more ballasts, the body portion further including at least one support portion; and at least one clamp subassembly, the at least one clamp subassembly rotatably coupled to the at least one support portion of the body portion, the at least one clamp subassembly configured to be coupled to one or more photovoltaic modules, the at least one clamp subassembly including a downwardly sloped flange portion configured to facilitate an insertion of the one or more photovoltaic modules into the at least one clamp subassembly, and to limit a rotation of the at least one clamp subassembly on the at least one support portion of the body portion.

Abstract: A support member for mounting photovoltaic modules on a support surface and a mounting system including the same are disclosed herein. The support member may comprise a body portion, the body portion including a ballast receiving portion for accommodating one or more ballasts, the body portion further including at least one support portion; and at least one clamp subassembly, the at least one clamp subassembly rotatably coupled to the at least one support portion of the body portion, the at least one clamp subassembly configured to be coupled to one or more photovoltaic modules, the at least one clamp subassembly including a downwardly sloped flange portion configured to facilitate an insertion of the one or more photovoltaic modules into the at least one clamp subassembly, and to limit a rotation of the at least one clamp subassembly on the at least one support portion of the body portion.

Abstract: A support member for mounting photovoltaic modules on a support surface and a mounting system including the same are disclosed herein. The support member may comprise a body portion that includes a ballast receiving portion for accommodating one or more ballasts, the body portion further including a first support portion with a first surface and a second support portion with a second surface, the first support portion being spaced apart from the second support portion by the ballast receiving portion. The support member is configured to bridge a plurality of rows of photovoltaic modules, the first surface of the support member configured to support one or more photovoltaic modules in a first row of the plurality of rows of photovoltaic modules, and the second surface of the support member configured to support one or more photovoltaic modules in a second row of the plurality of rows of photovoltaic modules.

Abstract: A support member for mounting photovoltaic modules on a support surface and a mounting system including the same are disclosed herein. The support member may comprise a body portion that includes a ballast receiving portion for accommodating one or more ballasts, the body portion further including a first support portion with a first surface and a second support portion with a second surface, the first support portion being spaced apart from the second support portion by the ballast receiving portion. The support member is configured to bridge a plurality of rows of photovoltaic modules, the first surface of the support member configured to support one or more photovoltaic modules in a first row of the plurality of rows of photovoltaic modules, and the second surface of the support member configured to support one or more photovoltaic modules in a second row of the plurality of rows of photovoltaic modules.

Abstract: A method includes producing an amorphous precursor to a nanocomposite, the amorphous precursor comprising a material that is substantially without crystals not exceeding 20% volume fraction; performing devitrification of the amorphous precursor, wherein the devitrification comprises a process of crystallization; forming, based on the devitrification, the nanocomposite with nano-crystals that contains an induced magnetic anisotropy; tuning, based on one or more of composition, temperature, configuration, and magnitude of stress applied during annealing and modification, the magnetic anisotropy of the nanocomposite; and adjusting, based on the tuned magnetic anisotropy, a magnetic permeability of the nanocomposite.

Abstract: A support assembly for supporting one or more photovoltaic modules on a support surface is disclosed herein. The support assembly includes (i) a body portion, the body portion including a base portion for accommodating one or more ballasts, the body portion comprising polymer; and (ii) integrated grounding means, the integrated ground means configured to provide integrated grounding between adjacent photovoltaic modules. The support assembly is configured to bridge multiple rows of photovoltaic modules without being directly secured to any other support assembly. Thus the support assembly can be utilized to support a wide variety of different sizes of photovoltaic modules. A mounting system for supporting a plurality of photovoltaic modules on a support surface, which comprises a plurality of separate support assemblies, is also disclosed herein.

Abstract: A support assembly for supporting one or more photovoltaic modules on a support surface is disclosed herein. The support assembly includes (i) a body portion, the body portion including a base portion for accommodating one or more ballasts, the body portion comprising polymer; and (ii) integrated grounding means, the integrated ground means configured to provide integrated grounding between adjacent photovoltaic modules. The support assembly is configured to bridge multiple rows of photovoltaic modules without being directly secured to any other support assembly. Thus the support assembly can be utilized to support a wide variety of different sizes of photovoltaic modules. A mounting system for supporting a plurality of photovoltaic modules on a support surface, which comprises a plurality of separate support assemblies, is also disclosed herein.

Abstract: The invention discloses a soft magnetic amorphous alloy and a soft magnetic nanocomposite alloy formed from the amorphous alloy. Both alloys comprise a composition expressed by the following formula: (Fe1-x-yCoxMy)100-a-b-cTaBbNc where, M is at least one element selected from the group consisting of Ni and Mn; T is at least one element selected from the group consisting of Nb, W, Ta, Zr, Hf, Ti, Cr, Cu, Mo, V and combinations thereof, and the content of Cu when present is less than or equal to 2 atomic %; N is at least one element selected from the group consisting of Si, Ge, C, P and Al; and 0.01?x+y?0.5; 0?y?0.4; 1?a?5 atomic %; 10?b?30 atomic %; and 0?c?10 atomic %. A core, which may be used in transformers and wire coils, is made by charging a furnace with elements necessary to form the amorphous alloy, rapidly quenching the alloy, forming a core from the alloy; and heating the core in the presence of a magnetic field to form the nanocomposite alloy.

Abstract: A support assembly for supporting one or more photovoltaic modules on a support surface is disclosed herein. The support assembly includes (i) a body portion, the body portion including a base portion for accommodating one or more ballasts, the body portion comprising polymer; and (ii) integrated grounding means, the integrated ground means configured to provide integrated grounding between adjacent photovoltaic modules. The support assembly is configured to bridge multiple rows of photovoltaic modules without being directly secured to any other support assembly. Thus the support assembly can be utilized to support a wide variety of different sizes of photovoltaic modules. A mounting system for supporting a plurality of photovoltaic modules on a support surface, which comprises a plurality of separate support assemblies, is also disclosed herein.

Abstract: A support assembly for supporting one or more photovoltaic modules on a support surface is disclosed herein. The support assembly includes (i) a body portion, the body portion including a base portion for accommodating one or more ballasts, the body portion comprising polymer; and (ii) integrated grounding means, the integrated ground means configured to provide integrated grounding between adjacent photovoltaic modules. The support assembly is configured to bridge multiple rows of photovoltaic modules without being directly secured to any other support assembly. Thus the support assembly can be utilized to support a wide variety of different sizes of photovoltaic modules. A mounting system for supporting a plurality of photovoltaic modules on a support surface, which comprises a plurality of separate support assemblies, is also disclosed herein.

Abstract: The invention discloses a soft magnetic amorphous alloy and a soft magnetic nanocomposite alloy formed from the amorphous alloy. Both alloys comprise a composition expressed by the following formula: (Fe1-x-yCoxMy)100-a-b-cTaBbNc where, M is at least one element selected from the group consisting of Ni and Mn; T is at least one element selected from the group consisting of Nb, W, Ta, Zr, Hf, Ti, Cr, Cu, Mo, V and combinations thereof, and the content of Cu when present is less than or equal to 2 atomic %; N is at least one element selected from the group consisting of Si, Ge, C, P and Al; and 0.01?x+y<0.5; Q?y?0.4; 1<a<5 atomic %; 10<b<30 atomic %; and 0<c<10 atomic %. A core, which may be used in transformers and wire coils, is made by charging a furnace with elements necessary to form the amorphous alloy, rapidly quenching the alloy, forming a core from the alloy; and heating the core in the presence of a magnetic field to form the nanocomposite alloy.

Abstract: Electromagnetic assemblies, core segments that form the same, and their methods of manufacture. The segments have an interlocking engagement, whereby a variety of assemblies can be produced from a very small number of similar or complementary segments in a manner that provides excellent mechanical stability. The articles and methods of formation offer design flexibility and provide for a large variety of patterns from a small number of primary shapes, provide an economical manufacturing method for large transformer and inductor cores, and improve uniformity of magnetic properties of the assemblies when compared to conventional practices.

Abstract: Electromagnetic assemblies, core segments that form the same, and their methods of manufacture. The segments have an interlocking engagement, whereby a variety of assemblies can be produced from a very small number of similar or complementary segments in a manner that provides excellent mechanical stability. The articles and methods of formation offer design flexibility and provide for a large variety of patterns from a small number of primary shapes, provide an economical manufacturing method for large transformer and inductor cores, and improve uniformity of magnetic properties of the assemblies when compared to conventional practices.