A driveshaft for an aircraft ram air turbine includes a substantially cylindrical elongate portion, a first end extending from the elongate portion, and a second end extending from the elongate portion opposite the first end. The first and second ends each include a substantially frusto-conical sect
A driveshaft for an aircraft ram air turbine includes a substantially cylindrical elongate portion, a first end extending from the elongate portion, and a second end extending from the elongate portion opposite the first end. The first and second ends each include a substantially frusto-conical section having a curved generatrix, such that distal portions of each of the first and second ends have smaller outer diameters than an outer diameter of the elongate portion. The elongate portion provides relatively high lateral stiffness and the first and second ends provide relatively low torsional stiffness, such that the driveshaft has a lateral natural frequency higher than an operating range of the driveshaft and has a torsional natural frequency below the operating range of the driveshaft.
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1. A driveshaft for an aircraft ram air turbine, the driveshaft comprising: an elongate portion, wherein the elongate portion is substantially cylindrical;a first end extending from the elongate portion; anda second end extending from the elongate portion opposite the first end, wherein the first an
1. A driveshaft for an aircraft ram air turbine, the driveshaft comprising: an elongate portion, wherein the elongate portion is substantially cylindrical;a first end extending from the elongate portion; anda second end extending from the elongate portion opposite the first end, wherein the first and second ends each include a substantially frusto-conical section having a curved generatrix such that distal portions of each of the first and second ends have smaller outer diameters than an outer diameter of the elongate portion;wherein the first and second ends are mechanically connected to a driveline that extends between a power conversion device and a turbine;wherein at least one of the first and second ends further comprises: a cylindrical portion located radially outward from the substantially frusto-conical section, wherein at least part of the cylindrical portion axially overhangs the substantially frusto-conical portion such that the cylindrical portion is separated from the distal portion of the corresponding first or second end by a radial gap,wherein the elongate portion provides higher lateral stiffness than the first and second ends, and wherein the first and second ends provide lower torsional stiffness than the elongate portion, such that the driveshaft has an overall lateral natural frequency higher than an operating range of the driveshaft and has an overall torsional natural frequency below the operating range of the driveshaft. 2. The driveshaft of claim 1, wherein the operating range of the driveshaft is approximately 8,000-12,000 RPM (133-200 Hz). 3. The driveshaft of claim 1, wherein the elongate portion is secured to each of the first and second ends with an electron beam welded butt joint. 4. The driveshaft of claim 1 and further comprising: splines formed at the distal portions of each of the first and second ends. 5. The driveshaft of claim 1, wherein at least one of the first and second ends further comprises: a plurality of circumferentially spaced cavities configured to accept one or more balancing weights. 6. The driveshaft of claim 5 and further comprising: a snap ring configured for engagement with a circumferentially-extending groove defined adjacent to the plurality of circumferentially spaced cavities in the at least one of the first and second ends, the circumferentially-extending groove being open in an inwardly facing direction. 7. The driveshaft of claim 6, wherein the circumferentially-extending groove is located radially outward from the plurality of circumferentially spaced cavities. 8. The driveshaft of claim 1, wherein the elongate portion is 5.67-5.75 times longer than each of the first and second ends. 9. The driveshaft of claim 1, wherein the first and second ends have identical configurations such that the driveshaft is symmetrically shaped. 10. The driveshaft of claim 1, wherein at least one of the first and second ends further comprises: a substantially flat annular surface defined adjacent to and radially outward from the substantially frusto-conical section. 11. The driveshaft of claim 10, wherein the at least one of the first and second ends further comprises: a plurality of circumferentially spaced cavities located along the substantially flat annular surface and configured to accept one or more balancing weights. 12. The driveshaft of claim 1, wherein the curved generatrix of the substantially frusto-conical section has a compound curvature defined by a plurality of radii. 13. The driveshaft of claim 1, wherein an outer diameter of the elongate portion is in the range of 3.77 to 3.88 times an outer diameter at the distal portion of each of the first and second ends. 14. The driveshaft of claim 1, wherein the elongate portion is 5.67-5.75 times longer than each of the first and second ends, and wherein an outer diameter of the elongate portion is in the range of 3.77 to 3.88 times an outer diameter at the distal portion of each of the first and second ends. 15. A ram air turbine for use with an aircraft, the ram air turbine comprising: a power conversion device;a turbine assembly;a driveshaft mechanically connected to a driveline that extends between the power conversion device and the turbine, the driveshaft comprising: a middle portion, wherein the middle portion is substantially cylindrical;a first end extending from the middle portion;a second end extending from the middle portion opposite the first end, wherein the first and second ends have the same shape, wherein the first and second ends each include a substantially frusto-conical section having a curved conical surface and are configured such that distal portions the first and second ends each have smaller outer diameters than an outer diameter of the middle portion, and wherein each of the first and second ends defines a plurality of circumferentially spaced cavities configured to accept one or more balancing weights; andmating features formed at the distal portions of each of the first and second ends,wherein a diameter of the middle portion of the drive shaft is sufficiently larger than the distal portions of each of the first and second ends to provide higher lateral stiffness than the first and second ends while the first and second ends of the driveshaft provide lower torsional stiffness than the middle portion such that the driveshaft has an overall lateral natural frequency higher than an operating range of the driveshaft and has an overall torsional natural frequency below the operating range of the driveshaft,wherein the middle portion of the driveshaft is 5.67-5.75 times longer than each of the first and second ends, and wherein an outer diameter of the middle portion is in the range of 3.77 to 3.88 times an outer diameter at the distal portion of each of the first and second ends. 16. The ram air turbine of claim 15, wherein the operating range of the driveshaft is approximately 8,000-12,000 RPM (133-200 Hz). 17. The ram air turbine of claim 15, wherein the middle portion is secured to each of the first and second ends with an electron beam welded butt joint. 18. The ram air turbine of claim 15, wherein at least one of the first and second ends of the driveshaft further comprises: a substantially flat annular surface defined adjacent to and radially outward from the substantially frusto-conical section;a plurality of circumferentially spaced cavities located along the substantially flat annular surface and configured to accept one or more balancing weights; anda snap ring configured for engagement with a circumferentially-extending groove defined adjacent to the plurality of circumferentially spaced cavities in the at least one of the first and second ends, wherein the circumferentially-extending groove is located radially outward from the plurality of circumferentially spaced cavities. 19. The ram air turbine of claim 15, wherein at least one of the first and second ends of the driveshaft further comprises: a cylindrical portion located radially outward from the substantially frusto-conical section, wherein at least part of the cylindrical portion axially overhangs the substantially frusto-conical portion such that the cylindrical portion is separated from the distal portion of the corresponding first or second end by a radial gap. 20. A method of making a driveshaft for a ram air turbine, the method comprising: providing a cylindrical member having a diameter;providing a pair of end pieces that each have a curved taper such that distal portions of the end pieces have a smaller diameter than the cylindrical member, such that the driveshaft has an overall lateral natural frequency higher than an operating range of the driveshaft and has an overall torsional natural frequency below the operating range of the driveshaft, and such that an outer diameter of the cylindrical member is in the range of 3.77 to 3.88 times an outer diameter at the distal portion of each of the end pieces;welding the pair of end pieces to opposite ends of the cylindrical member using electron beam welding; andoperatively engaging the pair of end pieces in a driveline that extends between a power conversion device and a turbine. 21. A method of installing a driveshaft in a ram air turbine, the method comprising: providing a driveshaft having a substantially cylindrical middle portion, a first end extending from the middle portion, a second end extending from the middle portion opposite the first end, wherein the first and second ends have the same shape, wherein the first and second ends each include a substantially frusto-conical section having a curved conical surface and are configured such that distal portions the first and second ends each have smaller outer diameters than an outer diameter of the middle portion, and wherein each of the first and second ends defines a plurality of circumferentially spaced cavities configured to accept one or more balancing weights, and mating features formed at the distal portions of each of the first and second ends, wherein the first and second ends of the driveshaft provide lower torsional stiffness than the middle portion such that the driveshaft has an overall torsional natural frequency determined by the torsional stiffness of the first and second ends that is below the operating range of the driveshaft, and wherein the first and second ends each further include a cylindrical portion located radially outward from the substantially frusto-conical section with at least part of the cylindrical portion axially overhanging the substantially frusto-conical portion such that the cylindrical portion is separated from the distal portion of the corresponding first or second end by a radial gap to tailor the torsional stiffness;positioning the driveshaft at least partially within a strut; andoperatively engaging the driveshaft in a driveline that extends between a turbine and a power conversion device.
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