Patent Application
20170133120
The present disclosure relates to electrical systems, and more particularly to structures for electrically isolating energized and non-energized structures in electrical systems.
Aircraft electrical systems commonly include isolation that electrically insulates energized structures from non-energized structures. The isolation generally includes materials with a dielectric constant and thermal conductivity suitable for dissipating heat generated by energized structures. The low dielectric constant of the material typically enables the isolation to electrically insulate the energized structure from surrounding de-energized structures. The thermal conductivity of the material is typically such that, when power is applied to an energized structure, heat generated by the energized structure readily dissipates to the surrounding environment. Examples of materials used for electrical isolation include plastics materials, which typically include a polymeric material doped with a material enhance the thermal conductivity of the material without impairing the resistivity of the polymeric material. The dopants disposed within the polymeric material can influence certain physical properties of the material, typically according to the amount of dopant incorporated in the polymeric material. For example, increasing the amount of dopant to improve thermal conductivity can reduce the material strength of some materials and/or render the material more dense than materials with lower amounts of dopant.
Such conventional systems and methods have generally been considered satisfactory for their intended purpose. However, there is still a need in the art for improved materials for isolation structures. The present disclosure provides a solution for this need.
A nanocomposite structure includes a nanocomposite. The nanocomposite includes a bulk matrix phase and a nanophase filler distributed within the bulk matrix phase. The nanophase filler includes a plurality of nanotubes with a material having thermal conductivity that is greater than the thermal conductivity of the bulk matrix phase of the nanocomposite.
In certain embodiments, the material forming the nanotubes can have a resistivity that is equal to or greater than the resistivity of the bulk matrix phase. The bulk matrix phase of the nanocomposite can be an insulator. The nanophase filler can be an insulator. The nanocomposite can be an insulator. The nanotubes of the nanophase filler can include boron nitride, and in an exemplary embodiment are substantially entirely formed from boron nitride. The bulk matrix phase can include one or more of a polymeric material, a resin, or an adhesive. The nanocomposite can be thermally anisotropic. The nanocomposite can have anisotropic material strength, such as yield strength, compressive strength, tensile strength, fatigue strength, and/or impact strength by way of non-limiting example.
In accordance with certain embodiments, the nanotubes can have lengths and widths where the length is greater than the width of the nanotube. The length can be substantially greater than the width of the nanotube, e.g., the width of a given nanotube being greater than ten (10) times the width of the nanotube. Widths of the nanotubes can be submicron; lengths of the nanotubes can be micron-size or greater. Two or more of the nanotubes can be in contact with one another within the bulk matrix phase. Two or more of the nanotubes can intermesh with one another within the bulk matrix phase. The intermeshed nanotubes can form a fibrous body within the nanocomposite, heat transfer and/or the material strength of the nanocomposite being anisotropic.
It is also contemplated that, in accordance with certain embodiments, the nanocomposite can have thermal conductivity that is greater than the thermal conductivity of a composite having an equivalent volume fraction of filler material with the same composition as the nanophase, in a particulate form, and disposed within the bulk matrix phase. The nanocomposite can have strength that is greater than the strength of a composite with an equivalent volume fraction of filler material of the same composition as the nanophase, in a particulate form, and disposed within the bulk matrix phase. The nanocomposite can have thermal conductivity that is equivalent to the thermal conductivity of a composite with a greater volume fraction of a filler material with the same composition as the nanophase, in a particulate form, and disposed within the bulk matrix phase. It is further contemplated that, for a given density, the nanocomposite can have a greater thermal conductivity and/or material strength than a composite with an equivalent volume fraction of filler material of the same composition as the nanophase, in a particulate form, and disposed within the bulk matrix phase.
An electrical device includes a structure as described above and a conductor in thermal communication with the structure. The structure is configured and adapted to transfer heat generated by resistive heating of the conductor to the environment external to the electrical device. In certain embodiments the conductor can includes a wire, a cable, a coil, or a winding. The accordance with certain embodiments, the structure can be a housing or a moveable element of a contactor or breaker assembly. It is also contemplated that the structure can be in intimate mechanical contact with the conductor, such as a sheath for a wire or a cable.
These and other features of the systems and methods of the subject disclosure will become more readily apparent to those skilled in the art from the following detailed description of the preferred embodiments taken in conjunction with the drawings.
So that those skilled in the art to which the subject disclosure appertains will readily understand how to make and use the devices and methods of the subject disclosure without undue experimentation, embodiments thereof will be described in detail herein below with reference to certain figures, wherein:
Reference will now be made to the drawings wherein like reference numerals identify similar structural features or aspects of the subject disclosure. For purposes of explanation and illustration, and not limitation, a partial view of an exemplary embodiment of an electrical device with a nanocomposite structure in accordance with the disclosure is shown in
Referring now to
Nanocomposite 100 includes a bulk matrix phase 102 and a nanophase filler 104. Bulk matrix phase 102 can be an insulator and includes one or more of a polymeric material, a resin material, and/or an adhesive material with predetermined physical properties including a thermal conductivity T102, a material strength S102, and an electrical resistivity R102. Nanophase filler 104 can be an electrical insulator. In embodiments, nanophase filler 104 has an electrical resistance that is greater than 1012 Ωcm. In certain embodiments, nanophase filler 104 has an electrical resistance that is greater than 1014 Ωcm.
Nanophase filler 104has predetermined physical properties including a thermal conductivity T104, a material strength S104, and an electrical resistivity R104. In embodiments, resistivity R104 of nanophase filler 104 can be equal to or greater than the resistivity R102 of bulk matrix phase 102. In certain embodiments, thermal conductivity T104 of nanophase filler 104 is greater than the thermal conductivity T102 of bulk matrix phase 102. In accordance with certain embodiments, material strength of S104 of nanophase filler 104 is greater than material strength S102 of bulk matrix phase 102. In this respect one or more of the yield strength, compressive strength, tensile strength, fatigue strength, and/or impact strength of nanophase filler 104 may be greater than that of bulk matrix phase 102.
With reference to
With reference to
Nanophase filler 104 also includes a plurality of nanotubes 106D-106F that intermesh with one another. Intermeshing of nanotubes 106D-106F cause force applied to one of intermeshed nanotubes 106D-106F to transfer through the intermeshed nanotubes to the other intermeshed nanotubes. In this respect a force F applied to nanotube 106D exerts associated force components on nanotube 106E and nanotube 106F, distributing force exerted on one of the nanotubes across the other intermeshed nanotubes. The distribution of the force reduces the peak stress exerted locally on nanocomposite 100, enabling nanocomposite 100 to withstand greater force than would otherwise be possible. As will also be appreciated by those of skill in the art in view of the present disclosure, intermeshed nanotubes 106D-106F provide heat transfer benefits similar to those of contacting nanotubes 106A-106C.
Intermeshed nanotubes 106D-106F form a fibrous body 118 disposed within bulk matrix phase 102. Fibrous body 118 supports bulk matrix phase 102, reinforcing bulk matrix phase 102. In the illustrated exemplary embodiment the contacting nanotubes, e.g., nanotubes 106A-106C, and the intermeshed nanotubes, e.g., nanotubes 106D-106F, are well distributed within nanocomposite structure. As used herein, well distributed means that the dispersal of the volume fraction of nanotubes incorporated within the bulk matrix phase is such that the cooperative effects of thermal conductivity and/or material strength are realized, but density of the composite is less than that of a composite having similar or equivalent heat transfer and/or material strength properties and incorporating a filler material of the same composition in particulate form. In this respect
With reference to
With reference to
In embodiments described herein, nanocomposites include nanophase fillers with compositions having a greater thermal conductivity than the compositions incorporated in the bulk matrix phase of the nanocomposite. The compositions are electrically resistive, and have electrical resistance that is equivalent or greater than the electrical resistance of the composition(s) forming the bulk matrix phase material. This allows structures formed from the nanocomposites to provide electrical isolation with improved thermal conductivity.
In certain embodiments described herein, the nanophase filler includes the composition in nanotube form. The discrete nanotubes contact and/or intermesh with one another within the bulk matrix phase, thereby forming a fibrous body within the bulk matrix body. The contacting and/or intermeshed nanotubes within the bulk nanophase are randomly oriented and well distributed within the bulk nanophase, thereby providing anisotropic thermal conductivity and/or material strength. It is contemplated that the contacting and/or intermeshed nanotubes of the fibrous body provide equivalent or superior thermal conductivity and/or material strength that a composite including the composition of the nanophase in particulate form, thereby providing weight savings through lower relative density.
The methods and systems of the present disclosure, as described above and shown in the drawings, provide for nanocomposites with superior properties including improved thermal conductivity, material strength, and/or reduced density. While the apparatus and methods of the subject disclosure have been shown and described with reference to preferred embodiments, those skilled in the art will readily appreciate that changes and/or modifications may be made thereto without departing from the scope of the subject disclosure.
