WO2008124674A1 - High torque density flexible composite driveshaft - Google Patents
High torque density flexible composite driveshaft Download PDFInfo
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- WO2008124674A1 WO2008124674A1 PCT/US2008/059543 US2008059543W WO2008124674A1 WO 2008124674 A1 WO2008124674 A1 WO 2008124674A1 US 2008059543 W US2008059543 W US 2008059543W WO 2008124674 A1 WO2008124674 A1 WO 2008124674A1
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- Prior art keywords
- composite
- driveshaft
- flexible composite
- bending
- diaphragm
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- 230000008878 coupling Effects 0.000 claims abstract description 17
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16C—SHAFTS; FLEXIBLE SHAFTS; ELEMENTS OR CRANKSHAFT MECHANISMS; ROTARY BODIES OTHER THAN GEARING ELEMENTS; BEARINGS
- F16C1/00—Flexible shafts; Mechanical means for transmitting movement in a flexible sheathing
- F16C1/02—Flexible shafts; Mechanical means for transmitting movement in a flexible sheathing for conveying rotary movements
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16C—SHAFTS; FLEXIBLE SHAFTS; ELEMENTS OR CRANKSHAFT MECHANISMS; ROTARY BODIES OTHER THAN GEARING ELEMENTS; BEARINGS
- F16C3/00—Shafts; Axles; Cranks; Eccentrics
- F16C3/02—Shafts; Axles
- F16C3/026—Shafts made of fibre reinforced resin
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16D—COUPLINGS FOR TRANSMITTING ROTATION; CLUTCHES; BRAKES
- F16D3/00—Yielding couplings, i.e. with means permitting movement between the connected parts during the drive
- F16D3/50—Yielding couplings, i.e. with means permitting movement between the connected parts during the drive with the coupling parts connected by one or more intermediate members
- F16D3/72—Yielding couplings, i.e. with means permitting movement between the connected parts during the drive with the coupling parts connected by one or more intermediate members with axially-spaced attachments to the coupling parts
- F16D3/725—Yielding couplings, i.e. with means permitting movement between the connected parts during the drive with the coupling parts connected by one or more intermediate members with axially-spaced attachments to the coupling parts with an intermediate member made of fibre-reinforced resin
Definitions
- This application is in the general field of materials, composite materials and material science engineering, and mechanical components made from engineered materials.
- Flexible driveshafts for rotary wing power transmission are crucially important components for conventional helicopters at engine to gearbox, tail-rotor drive, and main mast locations, hi the case of tilt-rotors the cross-over wins driveshafts rely extensively on the technology.
- titanium, aluminum or composite shafts are bolted through curvic face connectors to titanium diaphragm couplings to accommodate airframe distortions while transmitting the requisite power.
- These flexible drive trains emphasize minimum weight and hence demand torque density and small size, hi the case of drive trains passing through flexing wing and fuselage structures the need for motion accommodation is also greater than for ground-based equipment — typically between 1.0 and 2.0 degrees per end.
- Power transmission coupling elements which accommodate axial, bending, and transverse displacements, must do so while simultaneously carrying relatively large torsional large torsional loads, hi short, it is difficult for a structural metallic membrane to simultaneously carry very large torsional shear and remain conveniently compliant to imposed out-of-axis distortions.
- One expedient used to minimize weight is to operate at very high rotational speed such that torque is minimized for a given power. Limiting this high rpm is dynamic instability or classical 'whirling'. Additional instabilities that affect the spacer shaft also include axial or "hunting" motions and torsional oscillations.
- a representative diameter of the generally cylindrical driveshaft assembly and construct 10, as represented by the generally cylindrical spacing tube 200 is six inches.
- This driveshaft diameter is typical of tilt-rotor usage and larger conventional tail rotor drives.
- a drive element with two bolted split lines can be made in accordance with the disclosure exactly as for the incumbent titanium designs.
- This approach used carbon and glass fiber derivatives filament wound into very short hyperbolic geometries such that the outside diameter exhibited fiber angles of approximately 45 degrees and the inside diameter angles were approximately 80 degrees. For this reason, the effective shell stiffness tangentially is higher than it is radially and more angular motion is therefore transferred.
- a further advantage is the geodesic winding path that facilitates manufacture but also eliminates all stresses other than fiber direction teases, for thin membranes, when torque and motions are imposed.
- Limiting aspects include the thickness build-up where the fiber angle is steepest at the inside diameter. This detail requires that the diaphragms remain thin-walled and effectively limits the maximum torque that can be carried. Nevertheless, torque density and angular motion are comparable with metallic membranes.
- Prior composite couplings and integrated driveshaft developments include braided solutions; elastomeric matrix composites (under the writer's direction); and numerous filament wound and pressed diaphragms, link packs, shim packs and similar. These designs provide attractive bending motion and reduced weight but give up torque density to the extent that they are not fielded solutions today. Most commonly, torque capacities consistently fell short of expectations because the fiber architecture always included local bending in the braid or wind. Also, the prescribed geometry typically required that the composite laminate be 'pushed' into shape before curing. The beam-column behavior of compression fibers in the first instance and developed shear stresses due to bending in the second conspired to give up nearly 90% of the achievable torque in every case.
- Elastomeric matrix composites have frequently been proposed as materials suitable for flexible driveshafts because of the obvious out-of-plane compliance possible.
- the compression component of in-plane shear due to torque suffers from low micro-buckling strength and quite low torque density results.
- the compression strength is linearly proportional to the shear modulus of the matrix resin.
- Suitable elastomeric resins provide shear modulii from 1-10% of that obtained using a typical epoxy. Further, all available elastomeric systems tend to produce limiting hysteretic heating effects under imposed bending motions.
- FIG. 1 illustrates an embodiment of a flexible composite driveshaft of the disclosure
- FIG. 2 sets forth closed loop performance test results on flexible composite driveshafts of the disclosure
- FIG. 3 sets forth an interaction equation for strain components due to axial and bending imposed motions, and a plot of a representative coupling performance envelope
- FIGS. 4A-4C set forth plots of meridional stress with applied bending moment, hoop stress with applied bending moment, and in-plane shear stress with applied torque respectively for a flexible composite driveshaft of the disclosure
- FIGS. 5A-5C set forth plots of meridional stress with applied bending moment, hoop stress with applied bending moment, and in-plane shear stress with applied torque respectively for a flexible composite driveshaft of the disclosure
- FIGS. 6A-6B set forth plots of meridional stress with applied bending moment, hoop stress with applied bending moment respectively for a flexible composite driveshaft of the disclosure
- FIGS. 7A-7B set forth plots of meridional stress with applied bending moment, hoop stress with applied bending moment respectively for a flexible composite driveshaft of the disclosure
- FIG. 8 sets forth diaphragm bending stress for a family of 6 inch diameter hyperbolic coupling geometries of a flexible composite driveshaft of the disclosure subjected to 1/2 degree angular misalignment;
- FIG. 9 sets forth torque imposed on a family of 6 inch diameter hyperbolic coupling geometries in response to 1/2 degree rotations about the shaft axis for flexible composite driveshafts of the disclosure
- FIGS. 10A- 1OJ set forth a survey of design parameters for flexible composite driveshafts of the disclosure.
- the present disclosure is of high torque density flexible composite driveshafts 10 which include flexible composite coupling elements 100 and integral spacing tube or tubes 200, as shown for example in FIG. 1.
- Each coupling element includes one or more diaphragms, generally indicated at 102.
- Each diaphragm 102 may have in a representative form a first angled wall 1021, a second angled wall 1022, and an intermediate inner diameter wall 1023.
- Each coupling element 102 further includes a shaft attachment 1024 which is structurally attached to a drive element D for mechanical power transmission by the flexible composite driveshaft 10.
- the present disclosure has finessed both the design for performance and the manufacturing process using epoxy resins such that sustainable compression components of composite stress under pure torque are now approaching 170 ksi. This is achieved via a hands-off CNC controlled, repeatable process using traceable pre-impregnated materials and the approach also avoids bolted split lines and large fastener count. In the case of tilt rotor wing cross-over drives the weight savings may be as great as approximately 55%. Additionally, the avoidance of split line fasteners is designed to reduce windage losses and associated heat and noise generation substantially.
- the deeply sculpted diaphragms 102 of the coupling elements 100 are an integral part of a single continuously wound anisotropic shell created on a perfect geodesic path, in accordance with the design disclosure.
- the diaphragm regions are preferably comprised of constantly varying thickness and constantly varying material properties.
- the expression provided in FIG. 3 includes strain components due to axial and bending imposed motions.
- the LHS of the expression provides for the residual stain available to carry torque assuming a material design allowable. This approach is accurate assuming no thickness effects, and any combination of imposed motion and torque consume the available design strain.
- the expression is also that of an ellipse and the non-dimensional elliptical design space is shown where alpha is the helix angle made by the fiber at the inside diameter to the diametral plane.
- S2 -glass fiber is preferably used to carry torque with carbon fiber sandwiching in the spacing tube such that shaft stability, inertia, and natural frequencies can be optimized.
- the use of S2-glass fiber provides for three times the strain to failure of standard modulus carbon fiber without giving up load density.
- Shafts can be built with spacing tube diameters equal to the outside diameter of the integral flex element. This is primarily because, for suitably compliant hyperbolic geometries, the fiber angle exiting the diaphragm is typically 42-48 degrees, hi the paradigm shift that is an integral all-composite flexible shaft it makes no sense to reduce the diameter of the spacing tube because tube wall thickness would have to increase as the fiber angle also increased and shear strength reduced.
- the flexible composite driveshafts of the disclosure sustain essentially steady state stresses due to both applied torque and imposed axial motion but high frequency cyclic loading due to imposed angular misalignment. For this reason the magnitude of bending stresses are of particular interest.
- the bending stiffness of the shallower diaphragm pair in FIG. 4A-4C is 993 in.lb/deg while the deeper diaphragm of FIGS. 5A-5C is less than 250 in/lb/deg.
- FIGS. 6A-6B and 7A-7B clearly demonstrate the benefits of installed axial tension to offset both peek hoop and meridionol stresses sustained under angular misalignment. While the skinnier geometry of FIGS. 5A-5C and 7A-7B appears to have a slight advantage in sustaining motion with lower bending stress, there remains the issue of torsional buckling of thinner, deeper diaphragms.
- FIG. 8 plots the meridional stress due to diaphragm bending against inside diameter and outer composite thickness. This indicates a much smaller penalty exists for adding thickness to deeper diaphragms than to shallower ones.
- FIG. 9 plots the torque reaction of the geometries studied following 14 degree of torsional wind-up. Superimposed on these are eigenvalue buckling solutions suggesting minimum outer thickness of 0.025_inch for a 4.0_inch ID and 0.02 _inch for a 4.9_inch ID.
- FIGS. 16A-J provides a survey of design parameters for all-composite integral flexible shafts produced in accordance with the disclosure. All-inclusive shift weights are plotted using steel flanges optimized for infinite fatigue life. These weights are preferably reduced by 2.7 Ib per 8 inch shaft and 1.6 Ib per 6 inch shaft when using titanium. Fundamental flexural resonance is calculated using spacing tubes which comprise 90 degree (hoop) carbon fiber both inside and outside of the +/-45 degree continuous S2-glass. hi the event that higher sub-critical speeds are required then some fraction of the 0.04 inch thick (total) carbon hoop material may be replaced by 0 degree plies, hi this way longitudinal modulus increases without a change in shaft weight being incurred.
- a design and manufacturing process and resulting products are disclosed in which all- composite, fully flexible driveshafts are designed and produced to take advantage of both part count reduction, and overall weight savings approaching 50% when compared with assembled titanium flex elements and carbon fiber spacing tubes.
- a manufacturing process is also disclosed that provides for precise and repeatable CNC control and which uses the perfect geodesic path to maximize torque density. Under imposed axial and bending motions a design space has been identified that minimizes diaphragm bending stresses using hyperbolic geometry just thick enough to avoid torsional buckling of the diaphragm. Increased torque and bending motions are achieved when shafts are installed with axial pre-tension, and operational compression is avoided.
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- Shafts, Cranks, Connecting Bars, And Related Bearings (AREA)
Abstract
An all-composite continuous filament wound flexible composite driveshaft with integral spacing tube and flexible diaphragms and methods of manufacture is disclosed. The flexible composite driveshaft obsoletes the split lines and associated fasteners required to attach metallic flex elements and either metallic or composite spacing tubes in current solutions. Sub-critical driveshaft weights half that of incumbent technology are projected for typical rotary wing shaft lengths. Fully anisotropic material properties are mapped to the deeply sculpted diaphragm geometry of flexible composite coupling elements, and a parametric numerical study of the complex shell disclosed. Continuous filament wound spacing tubes are described, which comprise an integral part of the initial tooling but which remain part of the finished shaft and control natural frequencies and torsional stability in conjunction with the flexible composite diaphragms.
Description
U.S. PATENT APPLICATION Lawrie Technology, Inc.
TITLE OF THE INVENTION
HIGH TORQUE DENSITY FLEXIBLE COMPOSITE DRIVESHAFT
RELATED APPLICATION DATA
This application claims priority to US. provisional patent application number 60/921,953 filed April 6, 2007.
FIELD OF THE INVENTION
This application is in the general field of materials, composite materials and material science engineering, and mechanical components made from engineered materials.
BACKGROUND OF THE INVENTION
Flexible driveshafts for rotary wing power transmission are crucially important components for conventional helicopters at engine to gearbox, tail-rotor drive, and main mast locations, hi the case of tilt-rotors the cross-over wins driveshafts rely extensively on the technology. Typically, titanium, aluminum or composite shafts are bolted through curvic face connectors to titanium diaphragm couplings to accommodate airframe distortions while transmitting the requisite power. These flexible drive trains emphasize minimum weight and hence demand torque density and small size, hi the case of drive trains passing through flexing wing and fuselage structures the need for motion accommodation is also greater than for ground-based equipment — typically between 1.0 and 2.0 degrees per end. Power transmission coupling elements, which accommodate axial, bending, and transverse displacements, must do so while simultaneously carrying relatively large torsional large torsional loads, hi short, it is difficult for a structural metallic membrane to simultaneously carry very large torsional shear and remain conveniently compliant to imposed out-of-axis distortions. Aircraft use, particularly rotary wing, more typically demands high angular motion to follow structural deformations. One expedient used to minimize weight is to operate at very high rotational speed such that torque is minimized for a given power. Limiting this high rpm is dynamic instability or classical 'whirling'. Additional instabilities that affect the spacer shaft also include axial or "hunting" motions and torsional oscillations. Variables that drive this behavior are mass per unit length, axial, bending, and torsional
stiffnesses - and boundary conditions. Clearly the primary objective for drive trains such as these is to allow bending rotations at each end, thus prescribing the boundary conditions. This, then, reduces the speed at which the fundamental bending or whirling speed is encountered.
State-of-the-art helicopter transmissions are operated below this critical speed in order to avoid the large lateral excursions that occur and the associated risk to the shaft plus adjacent wiring harnesses and hydraulic lines. A large literature exists concerning math modeling of this kind of dynamic behavior. However, axial force, large applied torques, shear forces and end moments all affect the prediction of natural frequencies. Much of the literature decouples the effects of some or all of the applied loading to reduce the complexity of the problem. For this reason natural frequencies are most often determined experimentally. Modem composite materials add greatly to functionality and design freedom but anisotropic material properties further complicate the analyses.
SUMMARY OF THE DISCLOSURE AND INVENTIONS
A representative diameter of the generally cylindrical driveshaft assembly and construct 10, as represented by the generally cylindrical spacing tube 200 is six inches. This driveshaft diameter is typical of tilt-rotor usage and larger conventional tail rotor drives. A drive element with two bolted split lines can be made in accordance with the disclosure exactly as for the incumbent titanium designs. This approach used carbon and glass fiber derivatives filament wound into very short hyperbolic geometries such that the outside diameter exhibited fiber angles of approximately 45 degrees and the inside diameter angles were approximately 80 degrees. For this reason, the effective shell stiffness tangentially is higher than it is radially and more angular motion is therefore transferred. A further advantage is the geodesic winding path that facilitates manufacture but also eliminates all stresses other than fiber direction teases, for thin membranes, when torque and motions are imposed. Limiting aspects include the thickness build-up where the fiber angle is steepest at the inside diameter. This detail requires that the diaphragms remain thin-walled and effectively limits the maximum torque that can be carried. Nevertheless, torque density and angular motion are comparable with metallic membranes.
Outstanding fatigue performance of the unidirectional composites used in the designs of the disclosure is achieved because all loading actions give rise to differential tension and compression in the fiber direction and shear stresses tend to zero when the wall thickness is
small. Unlike metal diaphragms this is also projected to allow significant damage to be present without catastrophic consequences without in-plane shear- each of hundreds of individual fiber bundles comprising the diaphragms behave exactly like a large number of redundant load paths.
Prior composite couplings and integrated driveshaft developments include braided solutions; elastomeric matrix composites (under the writer's direction); and numerous filament wound and pressed diaphragms, link packs, shim packs and similar. These designs provide attractive bending motion and reduced weight but give up torque density to the extent that they are not fielded solutions today. Most commonly, torque capacities consistently fell short of expectations because the fiber architecture always included local bending in the braid or wind. Also, the prescribed geometry typically required that the composite laminate be 'pushed' into shape before curing. The beam-column behavior of compression fibers in the first instance and developed shear stresses due to bending in the second conspired to give up nearly 90% of the achievable torque in every case. Elastomeric matrix composites have frequently been proposed as materials suitable for flexible driveshafts because of the obvious out-of-plane compliance possible. Unfortunately, the compression component of in-plane shear due to torque suffers from low micro-buckling strength and quite low torque density results. For a given fiber volume fraction in a composite shell the compression strength is linearly proportional to the shear modulus of the matrix resin. Suitable elastomeric resins provide shear modulii from 1-10% of that obtained using a typical epoxy. Further, all available elastomeric systems tend to produce limiting hysteretic heating effects under imposed bending motions.
BRIEF DESCRIPTION OF THE FIGURES
In the accompanying Figures:
FIG. 1 illustrates an embodiment of a flexible composite driveshaft of the disclosure;
FIG. 2 sets forth closed loop performance test results on flexible composite driveshafts of the disclosure;
FIG. 3 sets forth an interaction equation for strain components due to axial and bending imposed motions, and a plot of a representative coupling performance envelope;
FIGS. 4A-4C set forth plots of meridional stress with applied bending moment, hoop stress with applied bending moment, and in-plane shear stress with applied torque respectively for a flexible composite driveshaft of the disclosure;
FIGS. 5A-5C set forth plots of meridional stress with applied bending moment, hoop stress with applied bending moment, and in-plane shear stress with applied torque respectively for a flexible composite driveshaft of the disclosure;
FIGS. 6A-6B set forth plots of meridional stress with applied bending moment, hoop stress with applied bending moment respectively for a flexible composite driveshaft of the disclosure;
FIGS. 7A-7B set forth plots of meridional stress with applied bending moment, hoop stress with applied bending moment respectively for a flexible composite driveshaft of the disclosure;
FIG. 8 sets forth diaphragm bending stress for a family of 6 inch diameter hyperbolic coupling geometries of a flexible composite driveshaft of the disclosure subjected to 1/2 degree angular misalignment;
FIG. 9 sets forth torque imposed on a family of 6 inch diameter hyperbolic coupling geometries in response to 1/2 degree rotations about the shaft axis for flexible composite driveshafts of the disclosure, and
FIGS. 10A- 1OJ set forth a survey of design parameters for flexible composite driveshafts of the disclosure.
DETAILED DESCRIPTION OF PREFERRED AND ALTERNATE EMBODIMENTS OF THE DISCLOSURE
The present disclosure is of high torque density flexible composite driveshafts 10 which include flexible composite coupling elements 100 and integral spacing tube or tubes 200, as shown for example in FIG. 1. Each coupling element includes one or more diaphragms, generally indicated at 102. Each diaphragm 102 may have in a representative form a first angled wall 1021, a second angled wall 1022, and an intermediate inner diameter wall 1023. Each coupling element 102 further includes a shaft attachment 1024 which is structurally attached to a drive element D for mechanical power transmission by the flexible composite driveshaft 10.
The present disclosure has finessed both the design for performance and the manufacturing process using epoxy resins such that sustainable compression components of composite stress under pure torque are now approaching 170 ksi. This is achieved via a hands-off CNC controlled, repeatable process using traceable pre-impregnated materials and
the approach also avoids bolted split lines and large fastener count. In the case of tilt rotor wing cross-over drives the weight savings may be as great as approximately 55%. Additionally, the avoidance of split line fasteners is designed to reduce windage losses and associated heat and noise generation substantially.
Continuing development of coupling elements (without spacing tubes) focused upon hyperbolic geometries offering acceptable torque and minimum shell bending stress without reducing thickness so much that torsional buckling of the diaphragm occurred before the in- plane strength was reached. With two degrees of bending per shaft end targeted a single hyperbolic flex element was required to provide a 1A degree per end. In no case was hysteretic heating experienced but it was clear that when thickness was increased above that required for 60,000 in.lb torque in a 6 inch diameter then Vz degree per diaphragm resulted in delamination over time. All comparison tests included axial and bending stiffness measurement, spin testing up to a 1A degree bending per diaphragm (1 degree per flex element) and 7,500 rpm followed by static torque to failure. Repeat axial stiffness tests were conducted after each increasing angular misalignment on a spin rig in an effort to pinpoint the onset of through-thickness shear failure.
The deeply sculpted diaphragms 102 of the coupling elements 100 are an integral part of a single continuously wound anisotropic shell created on a perfect geodesic path, in accordance with the design disclosure. The diaphragm regions are preferably comprised of constantly varying thickness and constantly varying material properties.
The expression provided in FIG. 3 includes strain components due to axial and bending imposed motions. The LHS of the expression provides for the residual stain available to carry torque assuming a material design allowable. This approach is accurate assuming no thickness effects, and any combination of imposed motion and torque consume the available design strain. The expression is also that of an ellipse and the non-dimensional elliptical design space is shown where alpha is the helix angle made by the fiber at the inside diameter to the diametral plane. Given that compressively loaded fibers fail before tensile fibers in the shell, and that only fiber direction tension and compression exists for small thickness (when wound on a perfect geodesic) then greater torque and higher bending is achievable when axial shortening is avoided and shafts are initially installed with small axial tension. The left upper quadrant of the elliptical design space depicted is considered to represent the strain space following snap-through budding of the diaphragms. Because
associated shock loading is undesirable in dynamic shaft applications this large additional design space is, regrettably, unavailable although the steadily reducing stiffness as snap- through is approached might be useful. Couplings with <10,000 in.lb torque to failure and small thickness were produced which exhibited this behavior and provided for >5 degree angular misalignment and >0.3 inch axial motion per diaphragm pair. When 20% more thickness was incorporated, the torque to failure increased by 150% and, indeed, the failure mode was demonstrably one of torsional buckling in the diaphragms. In fully integral or even assembled driveshafts at least one pair of diaphragms per end is required. Inevitably this means that one diaphragm will attract all the motion because of the unstable stiffness response.
In the FIG. 3 plot showing angular misalignment the straight generation lines used to represent two hyperbolic fiber paths do not cross on the centerline - unlike that shown for axial displacement. It is useful to visualize a bundle of straws or pencils bound mid-length and then twisted about the axis to produce a hyperbola when viewed laterally. In the case of the composite flex element an open inside diameter exists such that the inside radius provides the torque arm necessary for each fiber bundle to contribute to power transmission.
In resolving fiber strains a family of trigonometric relations were developed and simply scaled by the number of fiber passes used to provide axial, bending and torsional stiffness values plus anticipated strength limits. It is not useful to reproduce these here. Steel and titanium flanges were analyzed via finite element modeling and the respective flange stiffnesses subtracted as springs in series from test results for the purpose of comparing composite performance with the analytical models. The lack of bending symmetry in the above referenced schematic (FIG. 3) created concerns as to fidelity of motion in a misaligned, rotating, shaft thus constructed. In fact, very smooth operation was always observed and the precisely controlled manufacturing process even produced shafts that did not require subsequent balancing, hi summary, the inability to closely match bending and axial stiffness predictions and the non-existence of lateral oscillations under imposed bending points toward diaphragm bending stress development not predicted by the analytical models. Torsional performance remains accurately predicted however.
S2 -glass fiber is preferably used to carry torque with carbon fiber sandwiching in the spacing tube such that shaft stability, inertia, and natural frequencies can be optimized. The use of S2-glass fiber provides for three times the strain to failure of standard modulus carbon
fiber without giving up load density. Shafts can be built with spacing tube diameters equal to the outside diameter of the integral flex element. This is primarily because, for suitably compliant hyperbolic geometries, the fiber angle exiting the diaphragm is typically 42-48 degrees, hi the paradigm shift that is an integral all-composite flexible shaft it makes no sense to reduce the diameter of the spacing tube because tube wall thickness would have to increase as the fiber angle also increased and shear strength reduced. While this trade-off is at zero weight change, tooling would be adversely affected, as would torsional buckling performance at reduced tube diameters. With (0/90) carbon content in the tube dedicated to achieving torsional stability and tuning natural frequencies, the S2-glass fiber (+/-45) obviously allows for increased torsional wind-up in long shafts. While the lower modulus is desirable in the compliant, integral flex elements the spacing tube serendipitously compensates via the larger than traditional tube diameter.
An ANSYS parametric FEA file was written allowing for variable hyperbolic geometry including length, inside diameter, outside diameter, outer composite thickness and boundary conditions. The metallic flange attachments were represented by springs and PLANE25 harmonic asymmetric elements were used to keep the run time low while still allowing fully orthotropic material properties and non-axisymmetric loads (bending). Meshing strategy maintained 10 elements through the thickness and acceptable aspect ratios regardless of hyperbolic geometry. Prior analytic models accurately provided for membrane fiber direction stresses so the primary objective of the numerical model was to quantify diaphragm bending stresses and determine the critical locations. The fiber crossing angle changes rapidly with radial position, as does the developed composite thickness. Because composite shell elements were not deemed suitable for our present purpose, only the element I J side was practical for a material coordinate system. All nine independent stiffness terms were mapped as a function of 0 and curve fitted with the resulting expressions used to generate 78 discrete material property cards.
Three sequential load steps were used to apply 10,000 in.Ib torque; 100 Ib axial compression; and 100 in.lb bending. By interrogating the as-calculated solution, meridional (I Jside) stresses were plotted as well as hoop (circumferential) and in-plane shear stresses due to torque.
After completion of the axis-symmetric sensitivity study the model was further developed to produce a full 3_D mesh suitable for extracting eigenvalue buckling solutions
under applied torque. In this fashion the design space possible between thin, unstable diaphragms and those too thick to sustain required bending motions was sought out.
Two different hyperbolic geometries are presented graphically to show significant findings. While all results presented use a 6_inch outside diameter the inside diameter was varied from 3.75_inch to 4.9_inch and outer thickness varied from 0.018 inch to 0,03_inch. All meridional stress maximums occurred in the middle of the diaphragm whether caused by axial or bending loads. Conversely, all hoop stress maximums occurred at the outer extremity as did in-plane shear stress due to applied torque. This is true regardless of hyperbolic geometry although peak values may vary.
There is different thickness distribution developed by the deeper cross-section with small outer thickness versus the shallower profile with larger outer thickness. In the latter case the torque capacity is substantially higher and the developed bending stresses much lower. Regardless of the technology used, the flexible composite driveshafts of the disclosure sustain essentially steady state stresses due to both applied torque and imposed axial motion but high frequency cyclic loading due to imposed angular misalignment. For this reason the magnitude of bending stresses are of particular interest. The bending stiffness of the shallower diaphragm pair in FIG. 4A-4C is 993 in.lb/deg while the deeper diaphragm of FIGS. 5A-5C is less than 250 in/lb/deg. So while the skinnier profile sustains three times the meridional stress of the thicker profile under 100 in.lb bending moment the actual applied bending moment will only be one quarter because structural deflections are applied in service rather than bending moments. Review of axial loading in FIGS. 6A-6B and 7A-7B clearly demonstrate the benefits of installed axial tension to offset both peek hoop and meridionol stresses sustained under angular misalignment. While the skinnier geometry of FIGS. 5A-5C and 7A-7B appears to have a slight advantage in sustaining motion with lower bending stress, there remains the issue of torsional buckling of thinner, deeper diaphragms.
FIG. 8 plots the meridional stress due to diaphragm bending against inside diameter and outer composite thickness. This indicates a much smaller penalty exists for adding thickness to deeper diaphragms than to shallower ones. FIG. 9 plots the torque reaction of the geometries studied following 14 degree of torsional wind-up. Superimposed on these are eigenvalue buckling solutions suggesting minimum outer thickness of 0.025_inch for a 4.0_inch ID and 0.02 _inch for a 4.9_inch ID.
FIGS. 16A-J provides a survey of design parameters for all-composite integral flexible
shafts produced in accordance with the disclosure. All-inclusive shift weights are plotted using steel flanges optimized for infinite fatigue life. These weights are preferably reduced by 2.7 Ib per 8 inch shaft and 1.6 Ib per 6 inch shaft when using titanium. Fundamental flexural resonance is calculated using spacing tubes which comprise 90 degree (hoop) carbon fiber both inside and outside of the +/-45 degree continuous S2-glass. hi the event that higher sub-critical speeds are required then some fraction of the 0.04 inch thick (total) carbon hoop material may be replaced by 0 degree plies, hi this way longitudinal modulus increases without a change in shaft weight being incurred.
A design and manufacturing process and resulting products are disclosed in which all- composite, fully flexible driveshafts are designed and produced to take advantage of both part count reduction, and overall weight savings approaching 50% when compared with assembled titanium flex elements and carbon fiber spacing tubes.
A manufacturing process is also disclosed that provides for precise and repeatable CNC control and which uses the perfect geodesic path to maximize torque density. Under imposed axial and bending motions a design space has been identified that minimizes diaphragm bending stresses using hyperbolic geometry just thick enough to avoid torsional buckling of the diaphragm. Increased torque and bending motions are achieved when shafts are installed with axial pre-tension, and operational compression is avoided.
Claims
What is claimed is: 1. A composite material flexible driveshaft comprising: an integral composite spacing tube having first and second ends; a first coupling element formed at the first end of the integral composite tube and a second coupling element formed at the second end of the integral composite tube, each coupling element having at least one diaphragm having a sculpted profile which extends from an outer diameter to an inner diameter, the sculpted profile formed by a first angled wall which extends from the outer diameter generally defined by a diameter of the integral composite tube to the inner diameter of the diaphragm, an inner diameter wall located at the inner diameter of the diaphragm and contiguous with the first angled wall, and a second angled wall which extends from an opposite side of the inner diameter wall and to the outer diameter, and a shaft attachment structure which extends from the diaphragm and is configured for attachment to a drive element; the spacing tube and first and second coupling elements being formed by continuous filament wound in a perfect geodesic path.
Priority Applications (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US12/594,896 US20100144451A1 (en) | 2007-04-06 | 2008-04-07 | High torque density flexible composite driveshaft |
EP08745218A EP2150710A4 (en) | 2007-04-06 | 2008-04-07 | High torque density flexible composite driveshaft |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US92195307P | 2007-04-06 | 2007-04-06 | |
US60/921,953 | 2007-04-06 |
Publications (1)
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WO2008124674A1 true WO2008124674A1 (en) | 2008-10-16 |
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Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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PCT/US2008/059543 WO2008124674A1 (en) | 2007-04-06 | 2008-04-07 | High torque density flexible composite driveshaft |
Country Status (3)
Country | Link |
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US (1) | US20100144451A1 (en) |
EP (1) | EP2150710A4 (en) |
WO (1) | WO2008124674A1 (en) |
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102287339A (en) * | 2010-06-21 | 2011-12-21 | 远景能源(丹麦)有限公司 | A wind turbine and a drive shaft for the wind turbine |
EP2397690A1 (en) * | 2010-06-21 | 2011-12-21 | Envision Energy (Denmark) ApS | Flexible shaft wind turbine |
KR101523617B1 (en) * | 2014-12-11 | 2015-05-28 | 원광이엔텍 주식회사 | Drive Shaft Assembly adopting CFRP |
CZ305275B6 (en) * | 2009-05-28 | 2015-07-15 | Jan Lochman | Flexible composite transmission shaft |
DE102015004302A1 (en) | 2015-04-01 | 2016-10-06 | Chr. Mayr Gmbh + Co. Kg | Drive hollow shaft made of composite material with multi-mountable and removable frictionally engaged shaft-hub connection |
Families Citing this family (3)
Publication number | Priority date | Publication date | Assignee | Title |
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CH702093A1 (en) * | 2009-10-28 | 2011-04-29 | Chirmat Sarl | Drive shaft for surgical reamer. |
US11396904B2 (en) | 2018-10-29 | 2022-07-26 | Hamilton Sundstrand Corporation | Composite drive shafts |
US12060148B2 (en) | 2022-08-16 | 2024-08-13 | Honeywell International Inc. | Ground resonance detection and warning system and method |
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FR2564538B1 (en) * | 1984-05-18 | 1986-09-26 | Skf Cie Ste Financiere Immobil | ROTARY TRANSMISSION SHAFT. |
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AT403837B (en) * | 1997-02-04 | 1998-05-25 | Geislinger Co Schwingungstechn | CLUTCH LINK |
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2008
- 2008-04-07 US US12/594,896 patent/US20100144451A1/en not_active Abandoned
- 2008-04-07 EP EP08745218A patent/EP2150710A4/en not_active Withdrawn
- 2008-04-07 WO PCT/US2008/059543 patent/WO2008124674A1/en active Application Filing
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US3970495A (en) * | 1974-07-24 | 1976-07-20 | Fiber Science, Inc. | Method of making a tubular shaft of helically wound filaments |
US4084409A (en) * | 1976-05-06 | 1978-04-18 | Controlex Corporation Of America | Flexible coupling for rotatable shafts |
US4391594A (en) * | 1980-08-25 | 1983-07-05 | Lord Corporation | Flexible coupling |
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Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CZ305275B6 (en) * | 2009-05-28 | 2015-07-15 | Jan Lochman | Flexible composite transmission shaft |
CN102287339A (en) * | 2010-06-21 | 2011-12-21 | 远景能源(丹麦)有限公司 | A wind turbine and a drive shaft for the wind turbine |
EP2397690A1 (en) * | 2010-06-21 | 2011-12-21 | Envision Energy (Denmark) ApS | Flexible shaft wind turbine |
EP2397309A1 (en) * | 2010-06-21 | 2011-12-21 | Envision Energy (Denmark) ApS | A Wind Turbine and a Shaft for a Wind Turbine |
US8664792B2 (en) | 2010-06-21 | 2014-03-04 | Envision Energy (Denmark) Aps | Wind turbine and a shaft for a wind turbine |
KR101523617B1 (en) * | 2014-12-11 | 2015-05-28 | 원광이엔텍 주식회사 | Drive Shaft Assembly adopting CFRP |
DE102015004302A1 (en) | 2015-04-01 | 2016-10-06 | Chr. Mayr Gmbh + Co. Kg | Drive hollow shaft made of composite material with multi-mountable and removable frictionally engaged shaft-hub connection |
Also Published As
Publication number | Publication date |
---|---|
EP2150710A1 (en) | 2010-02-10 |
US20100144451A1 (en) | 2010-06-10 |
EP2150710A4 (en) | 2011-05-04 |
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