def __init__(self, Ns): super(Failures, self).__init__() # inputs self.add('flags', VarTree(Flags(), iotype='in')) self.add('yN', Array(np.zeros(Ns + 1), iotype='in', desc='')) self.add('Finternal', Array(np.zeros((6, Ns + 1)), iotype='in', desc='')) self.add('strain', VarTree(Strain(Ns), iotype='in')) self.add('d', Array(np.zeros(Ns), iotype='in', desc='')) self.add('theta', Array(np.zeros(Ns), iotype='in', desc='')) self.add('nTube', Array(np.zeros(Ns), iotype='in', desc='')) self.add('nCap', Array(np.zeros(Ns), iotype='in', desc='')) self.add('yWire', Array([0], iotype='in', desc='')) self.add('zWire', Float(0., iotype='in', desc='')) self.add('EIxJ', Array(np.zeros(Ns), iotype='in', desc='')) self.add('EIzJ', Array(np.zeros(Ns), iotype='in', desc='')) self.add('lBiscuit', Array(np.zeros(Ns), iotype='in', desc='')) self.add('dQuad', Float(0., iotype='in', desc='')) self.add('thetaQuad', Float(0., iotype='in', desc='')) self.add('nTubeQuad', Float(0., iotype='in', desc='')) self.add('lBiscuitQuad', Float(0., iotype='in', desc='')) self.add('RQuad', Float(0., iotype='in', desc='')) self.add('hQuad', Float(0., iotype='in', desc='')) self.add('EIQuad', Array(np.zeros(Ns), iotype='in', desc='')) self.add('GJQuad', Array(np.zeros(Ns), iotype='in', desc='')) self.add('tWire', Float(0., iotype='in', desc='')) self.add('TWire', Array([0], iotype='in', desc='')) self.add('TEtension', Float(0., iotype='in', desc='')) # all this to get TQuad... maybe should be split out self.add('b', Int(0, iotype='in', desc='number of blades')) self.add('fblade', VarTree(Fblade(Ns), iotype='in')) self.add('mSpar', Array(np.zeros(Ns), iotype='in', desc='mass of spars')) self.add('mChord', Array(np.zeros(Ns), iotype='in', desc='mass of chords')) self.add('mElseRotor', Float(0., iotype='in', desc='')) # outputs self.add('fail', VarTree(Failure(Ns), iotype='out'))
class MassProperties(Component): """ Computes the total mass and CG of the helicopter """ # inputs flags = VarTree(Flags(), iotype='in') b = Int(iotype='in', desc='number of blades') mSpar = Array(iotype='in', desc='mass of spars') mChord = Array(iotype='in', desc='mass of chords') xCGChord = Array(iotype='in', desc='xCG of chords') xEA = Array(iotype='in', desc='') mQuad = Float(iotype='in', desc='') ycmax = Float(iotype='in', desc='') yWire = Array(iotype='in', desc='location of wire attachment along span') zWire = Float(iotype='in', desc='depth of wire attachement') tWire = Float(iotype='in', desc='thickness of wire') mElseRotor = Float(iotype='in', desc='') mElseCentre = Float(iotype='in', desc='') mElseR = Float(iotype='in', desc='') R = Float(iotype='in', desc='') mPilot = Float(iotype='in', desc='mass of pilot (kg)') # outputs xCG = Array(iotype='out', desc='') Mtot = Float(0.0, iotype='out', desc='total mass') mCover = Float(0.0, iotype='out', desc='mass of cover') mWire = Float(0.0, iotype='out', desc='mass of wire') def execute(self): self.xCG = ((self.xCGChord * self.mChord) + (self.xEA * self.mSpar)) / (self.mChord + self.mSpar) if self.flags.Cover: self.mCover = (self.ycmax**2 * 0.0528 + self.ycmax * 0.605 / 4) * 1.15 else: self.mCover = 0 wire_props = wireProperties[self.flags.WireType] LWire = sqrt(self.zWire**2 + self.yWire**2) self.mWire = pi * (self.tWire / 2)**2 * wire_props['RHO'] * LWire if self.flags.Quad: self.Mtot = (np.sum(self.mSpar)*self.b + np.sum(self.mChord)*self.b + self.mWire*self.b + self.mQuad + self.mCover) * 4 \ + self.mElseRotor + self.mElseCentre + self.mElseR * self.R + self.mPilot else: self.Mtot = np.sum(self.mSpar)*self.b + np.sum(self.mChord)*self.b + self.mWire*self.b + self.mCover \ + self.mElseRotor + self.mElseCentre + self.mElseR * self.R + self.mPilot
def __init__(self, Ns): super(MassProperties, self).__init__() # inputs self.add('flags', VarTree(Flags(), iotype='in')) self.add('b', Int(0, iotype='in', desc='number of blades')) self.add('mSpar', Array(np.zeros(Ns), iotype='in', desc='mass of spars')) self.add('mChord', Array(np.zeros(Ns), iotype='in', desc='mass of chords')) self.add('xCGChord', Array(np.zeros(Ns), iotype='in', desc='xCG of chords')) self.add('xEA', Array(np.zeros(Ns), iotype='in', desc='')) self.add('mQuad', Float(0., iotype='in', desc='')) self.add('ycmax', Float(0., iotype='in', desc='')) self.add( 'yWire', Array([0], iotype='in', desc='location of wire attachment along span')) self.add('zWire', Float(0., iotype='in', desc='depth of wire attachement')) self.add('tWire', Float(0., iotype='in', desc='thickness of wire')) self.add('mElseRotor', Float(0., iotype='in', desc='')) self.add('mElseCentre', Float(0., iotype='in', desc='')) self.add('mElseR', Float(0., iotype='in', desc='')) self.add('R', Float(0., iotype='in', desc='')) self.add('mPilot', Float(0., iotype='in', desc='mass of pilot (kg)')) # outputs self.add('xCG', Array(np.zeros(Ns), iotype='out', desc='')) self.add('Mtot', Float(0., iotype='out', desc='total mass')) self.add('mCover', Float(0., iotype='out', desc='mass of cover')) self.add('mWire', Float(0., iotype='out', desc='mass of wire'))
class Structures(Assembly): """ structural computation, first computes the mass of the helicopter based on the structural description of the spars and chord lengths. It then computes the deformation of the spars, the strains, and the resulting factor of safety for each of the failure modes. """ # flags flags = VarTree(Flags(), iotype='in') # inputs for spars yN = Array(iotype='in', desc='node locations for each element along the span') d = Array(iotype='in', desc='spar diameter') theta = Array(iotype='in', desc='wrap angle') nTube = Array(iotype='in', desc='number of tube layers') nCap = Array(iotype='in', desc='number of cap strips') lBiscuit = Array(iotype='in', desc='unsupported biscuit length') # joint properties Jprop = VarTree(JointProperties(), iotype='in') # inputs for chord b = Int(iotype='in', desc='number of blades') cE = Array(iotype='in', desc='chord of each element') xEA = Array(iotype='in', desc='') xtU = Array(iotype='in', desc='') # inputs for quad dQuad = Float(iotype='in', desc='diameter of quad rotor struts') thetaQuad = Float(iotype='in', desc='wrap angle of quad rotor struts') nTubeQuad = Int(iotype='in', desc='number of CFRP layers in quad rotor struts') lBiscuitQuad = Float(iotype='in', desc='') RQuad = Float( iotype='in', desc='distance from centre of helicopter to centre of quad rotors') hQuad = Float(iotype='in', desc='height of quad-rotor truss') # inputs for cover ycmax = Float(iotype='in', desc='') # inputs for wire yWire = Array(iotype='in', desc='location of wire attachment along span') zWire = Float(iotype='in', desc='depth of wire attachement') tWire = Float(iotype='in', desc='thickness of wire') TWire = Array(iotype='in', desc='') TEtension = Float(iotype='in', desc='') # inputs for 'other stuff' mElseRotor = Float(iotype='in', desc='') mElseCentre = Float(iotype='in', desc='') mElseR = Float(iotype='in', desc='') R = Float(iotype='in', desc='rotor radius') mPilot = Float(iotype='in', desc='mass of pilot') # inputs for FEM fblade = VarTree(Fblade(), iotype='in') presLoad = VarTree(PrescribedLoad(), iotype='in') def configure(self): self.add('spar', SparProperties()) self.connect('yN', 'spar.yN') self.connect('d', 'spar.d') self.connect('theta', 'spar.theta') self.connect('nTube', 'spar.nTube') self.connect('nCap', 'spar.nCap') self.connect('lBiscuit', 'spar.lBiscuit') self.connect('flags.CFRPType', 'spar.CFRPType') self.add('joint', JointSparProperties()) self.connect('flags.CFRPType', 'joint.CFRPType') self.connect('Jprop', 'joint.Jprop') self.add('chord', ChordProperties()) self.connect('yN', 'chord.yN') self.connect('cE', 'chord.c') self.connect('d', 'chord.d') self.connect('flags.GWing', 'chord.GWing') self.connect('xtU', 'chord.xtU') self.add('quad', QuadSparProperties()) self.connect('dQuad', 'quad.dQuad') self.connect('thetaQuad', 'quad.thetaQuad') self.connect('nTubeQuad', 'quad.nTubeQuad') self.connect('lBiscuitQuad', 'quad.lBiscuitQuad') self.connect('flags.CFRPType', 'quad.CFRPType') self.connect('RQuad', 'quad.RQuad') self.connect('hQuad', 'quad.hQuad') self.add('mass', MassProperties()) self.connect('flags', 'mass.flags') self.connect('b', 'mass.b') self.connect('spar.mSpar', 'mass.mSpar') self.connect('chord.mChord', 'mass.mChord') self.connect('chord.xCGChord', 'mass.xCGChord') self.connect('quad.mQuad', 'mass.mQuad') self.connect('xEA', 'mass.xEA') self.connect('ycmax', 'mass.ycmax') self.connect('zWire', 'mass.zWire') self.connect('yWire', 'mass.yWire') self.connect('tWire', 'mass.tWire') self.connect('mElseRotor', 'mass.mElseRotor') self.connect('mElseCentre', 'mass.mElseCentre') self.connect('mElseR', 'mass.mElseR') self.connect('R', 'mass.R') self.connect('mPilot', 'mass.mPilot') self.add('fem', FEM()) self.connect('flags', 'fem.flags') self.connect('yN', 'fem.yN') self.connect('spar.EIx', 'fem.EIx') self.connect('spar.EIz', 'fem.EIz') self.connect('spar.EA', 'fem.EA') self.connect('spar.GJ', 'fem.GJ') self.connect('cE', 'fem.cE') self.connect('xEA', 'fem.xEA') self.connect('spar.mSpar', 'fem.mSpar') self.connect('chord.mChord', 'fem.mChord') self.connect('mass.xCG', 'fem.xCG') self.connect('zWire', 'fem.zWire') self.connect('yWire', 'fem.yWire') self.connect('TWire', 'fem.TWire') self.connect('fblade', 'fem.fblade') self.connect('presLoad', 'fem.presLoad') self.add('strains', Strains()) self.connect('yN', 'strains.yN') self.connect('d', 'strains.d') self.connect('fem.k', 'strains.k') self.connect('fem.F', 'strains.F') self.connect('fem.q', 'strains.q') self.add('failure', Failures()) self.connect('flags', 'failure.flags') self.connect('yN', 'failure.yN') self.connect('strains.Finternal', 'failure.Finternal') self.connect('strains.strain', 'failure.strain') self.connect('d', 'failure.d') self.connect('theta', 'failure.theta') self.connect('nTube', 'failure.nTube') self.connect('nCap', 'failure.nCap') self.connect('yWire', 'failure.yWire') self.connect('zWire', 'failure.zWire') self.connect('joint.EIx', 'failure.EIxJ') self.connect('joint.EIz', 'failure.EIzJ') self.connect('lBiscuit', 'failure.lBiscuit') self.connect('dQuad', 'failure.dQuad') self.connect('thetaQuad', 'failure.thetaQuad') self.connect('nTubeQuad', 'failure.nTubeQuad') self.connect('lBiscuitQuad', 'failure.lBiscuitQuad') self.connect('RQuad', 'failure.RQuad') self.connect('hQuad', 'failure.hQuad') self.connect('quad.EIx', 'failure.EIQuad') self.connect('quad.GJ', 'failure.GJQuad') self.connect('tWire', 'failure.tWire') self.connect('TWire', 'failure.TWire') self.connect('TEtension', 'failure.TEtension') self.connect('b', 'failure.b') self.connect('fblade', 'failure.fblade') self.connect('spar.mSpar', 'failure.mSpar') self.connect('chord.mChord', 'failure.mChord') self.connect('mElseRotor', 'failure.mElseRotor') # link up the outputs self.create_passthrough('mass.Mtot') self.create_passthrough('fem.q') self.create_passthrough('strains.Finternal') self.create_passthrough('strains.strain') self.create_passthrough('failure.fail') self.driver.workflow.add('chord') self.driver.workflow.add('fem') self.driver.workflow.add('joint') self.driver.workflow.add('mass') self.driver.workflow.add('quad') self.driver.workflow.add('spar') self.driver.workflow.add('strains') self.driver.workflow.add('failure')
class Failures(Component): """ Computes the factor of safety for each of the failure modes of the spar. """ # inputs flags = VarTree(Flags(), iotype='in') yN = Array(iotype='in', desc='') Finternal = Array(iotype='in', desc='') strain = VarTree(Strain(), iotype='in') d = Array(iotype='in', desc='') theta = Array(iotype='in', desc='') nTube = Array(iotype='in', desc='') nCap = Array(iotype='in', desc='') yWire = Array(iotype='in', desc='') zWire = Float(iotype='in', desc='') EIxJ = Array(iotype='in', desc='') EIzJ = Array(iotype='in', desc='') lBiscuit = Array(iotype='in', desc='') dQuad = Float(iotype='in', desc='') thetaQuad = Float(iotype='in', desc='') nTubeQuad = Float(iotype='in', desc='') lBiscuitQuad = Float(iotype='in', desc='') RQuad = Float(iotype='in', desc='') hQuad = Float(iotype='in', desc='') EIQuad = Array(iotype='in', desc='') GJQuad = Array(iotype='in', desc='') tWire = Float(iotype='in', desc='') TWire = Array(iotype='in', desc='') TEtension = Float(iotype='in', desc='') # all this to get TQuad... maybe should be split out b = Int(iotype='in', desc='number of blades') fblade = VarTree(Fblade(), iotype='in') mSpar = Array(iotype='in', desc='mass of spars') mChord = Array(iotype='in', desc='mass of chords') mElseRotor = Float(iotype='in', desc='') # outputs fail = VarTree(Failure(), iotype='out') def execute(self): # Compute factor of safety for each failure mode # ---------------------------------------------- # computes material failure, euler buckling failure and torsional # buckling failure. All failure modes are computed at the nodes. # # For material failure it looks at a sample laminate on the top, # bottom, back and front of the spar. For each side of the spar # it computes the material failure for the cap, the plus angle # plys and the minus angle plys. For each ply it computes the # fracture of failure in the fibre direction, matrix direction # and shear. Thus there are 4x3x3=36 (side x lamina x direction) # possible failure modes in the tube. # ex. fail.top.cap = 3x(Ns+1) vector # fail.top.plus = 3x(Ns+1) vector # fail.top.minus = 3x(Ns+1) vector # # Stresses and strain are given as a 3x(Ns+1) vector # ex. sigma_11, sigma_22, sigma_12 # Positive sign denotes tensile stresses, negative denotes compressive # factor of safety for each failure mode # short aliases flags = self.flags yN = self.yN Finternal = self.Finternal strain = self.strain d = self.d theta = self.theta nTube = self.nTube nCap = self.nCap yWire = self.yWire zWire = self.zWire EIxJ = self.EIxJ EIzJ = self.EIzJ lBiscuit = self.lBiscuit dQuad = self.dQuad thetaQuad = self.thetaQuad nTubeQuad = self.nTubeQuad lBiscuitQuad = self.lBiscuitQuad RQuad = self.RQuad hQuad = self.hQuad EIQuad = self.EIQuad[0] # convert single element array to scalar GJQuad = self.GJQuad[0] # convert single element array to scalar tWire = self.tWire TWire = self.TWire TEtension = self.TEtension b = self.b fblade = self.fblade mSpar = self.mSpar mChord = self.mChord mElseRotor = self.mElseRotor TQuad = np.sum(fblade.Fz) * b - (np.sum(mSpar + mChord) * b + mElseRotor / 4) * 9.81 Ns = max(yN.shape) - 1 # number of elements fail = Failure() # Material failure fail.top = self.material_failure(Ns, strain.top, theta, nCap, flags) fail.bottom = self.material_failure(Ns, strain.bottom, theta, nCap, flags) fail.back = self.material_failure(Ns, strain.back, theta, [], flags) fail.front = self.material_failure(Ns, strain.front, theta, [], flags) # Euler Buckling failure in main spar from wire force k = 0.7 # pinned-pinned = 1, fixed-pinned = 0.7 with correction factor #kk = 1.42 # correction factor kk = 1 # correction factor was in error, never saw buckling failure thetaWire = atan2(zWire, yWire) L = yWire # wire attachment provides pinned end F = TWire * cos(thetaWire) + TEtension fail.buckling.x = np.zeros(Ns + 1) fail.buckling.z = np.zeros(Ns + 1) for s in range(Ns): if yN[s] <= yWire: critical_load_x = pi**2 * EIxJ / (k * L)**2 critical_load_z = pi**2 * EIzJ / (k * L)**2 fail.buckling.x[s] = kk * F / critical_load_x fail.buckling.z[s] = kk * F / critical_load_z else: fail.buckling.x[s] = 0 fail.buckling.z[s] = 0 # no buckling at tip fail.buckling.x[Ns] = 0 fail.buckling.z[Ns] = 0 # Torsional Buckling failure fail.buckling.torsion = self.torsional_buckling_failure( Ns, Finternal, d, theta, nTube, nCap, lBiscuit, flags) # Quad Buckling failure if EIQuad != 0: k = 1 L = sqrt(RQuad**2 + hQuad**2) alpha = atan2(hQuad, RQuad) P = TQuad / sin(alpha) critical_load = pi**2 * EIQuad / (k * L)**2 fail.quad_buckling = P / critical_load else: fail.quad_buckling = 0 # Quad bending moment failure (does not include torsion since they don't occur at the same time) RotorMoment = 1400 if EIQuad != 0: TbottomWire = TQuad / tan(alpha) BM = TbottomWire * zWire + RotorMoment strainQuad = -np.array([BM * (dQuad / 2) / EIQuad, 0, 0]).reshape( 1, -1).T # strain on compression side mf = self.material_failure(1, strainQuad, [thetaQuad], [], flags) fail.quad_bend = abs( mf.plus[0, 0]) # use only compressive failure in fibre direction else: fail.quad_bend = 0 # Quad torsional material failure if GJQuad != 0: strainQuad = np.array([0, 0, dQuad / 2 * RotorMoment / GJQuad ]).reshape(1, -1).T mf = self.material_failure(1, strainQuad, [thetaQuad], [], flags) fail.quad_torsion = abs(mf.plus[0, 0]) else: fail.quad_torsion = 0 # Quad torsional buckling failure FRotorMoment = np.array([0, 0, 0, 0, RotorMoment]).reshape(1, -1).T tbf = self.torsional_buckling_failure(1, FRotorMoment, [dQuad], [thetaQuad], [nTubeQuad], [0], [lBiscuitQuad], flags) fail.quad_torbuck = tbf[0] # Wire tensile failure wire_props = wireProperties[flags.WireType] fail.wire = np.zeros(len(yWire)) for i in range(len(yWire)): stress_wire = TWire[i] / (pi * (tWire / 2)**2) fail.wire[i] = stress_wire / wire_props['ULTIMATE'] self.fail = fail def material_failure(self, Ns, strain, theta, nCap, flags): failure = MaterialFailure() failure.cap = np.zeros((3, Ns + 1)) failure.plus = np.zeros((3, Ns + 1)) failure.minus = np.zeros((3, Ns + 1)) # Material Properties tube_props = prepregProperties[flags.CFRPType] # Cap Prepreg Properties (MTM28-M46J 140 37 %RW 12") cap_props = prepregProperties[flags.CFRPType] # Populate Q matrix for tube Q_TUBE = np.zeros((3, 3)) Q_TUBE[0, 0] = tube_props['E_11'] Q_TUBE[1, 1] = tube_props['E_22'] Q_TUBE[0, 1] = tube_props['E_22'] * tube_props['V_12'] Q_TUBE[1, 0] = Q_TUBE[0, 1] Q_TUBE[2, 2] = tube_props['G_12'] # Populate Q matrix for caps Q_CAP = np.zeros((3, 3)) Q_CAP[0, 0] = cap_props['E_11'] Q_CAP[1, 1] = cap_props['E_22'] Q_CAP[0, 1] = cap_props['E_22'] * cap_props['V_12'] Q_CAP[1, 0] = Q_CAP[0, 1] Q_CAP[2, 2] = cap_props['G_12'] stress = MaterialFailure() stress.cap = np.zeros((3, Ns)) stress.plus = np.zeros((3, Ns)) stress.minus = np.zeros((3, Ns)) for s in range(Ns): # Compute stresses in structural axes for each lamina angle # Q is the matrix of elastic constants in the material axis # Q_bar is the matrix of elastic constants in the structural axes for a # lamina at a ply angle theta. # Failure is computed at each node, but using the ply angle of the # element (this shouldn't cause a large discrepency). Failure at tip is # zero, since stresses/strains at tip are zero. # Transform the elastic constants for the plus angle ply x = theta[s] # Composite angle (in radians) T_PLUS = np.array([[cos(x)**2, sin(x)**2, 2 * sin(x) * cos(x)], [sin(x)**2, cos(x)**2, -2 * sin(x) * cos(x)], [ -sin(x) * cos(x), sin(x) * cos(x), (cos(x)**2) - (sin(x)**2) ]]) # MATLAB version: Qbar_TUBE_PLUS = (T_PLUS\Q_TUBE)/T_PLUS' tmp = np.linalg.solve(T_PLUS, Q_TUBE) Qbar_TUBE_PLUS = np.linalg.solve(T_PLUS, tmp.T) # Transform the elastic constants for the minus angle ply x = -theta[s] # Composite angle (in radians) T_MINUS = np.array([[cos(x)**2, sin(x)**2, 2 * sin(x) * cos(x)], [sin(x)**2, cos(x)**2, -2 * sin(x) * cos(x)], [ -sin(x) * cos(x), sin(x) * cos(x), (cos(x)**2) - (sin(x)**2) ]]) # MATLAB version: Qbar_TUBE_MINUS = (T_MINUS\Q_TUBE)/T_MINUS' tmp = np.linalg.solve(T_MINUS, Q_TUBE) Qbar_TUBE_MINUS = np.linalg.solve(T_MINUS, tmp.T) # Compute stresses in structural coordinates stress.cap[:, s] = np.dot(Q_CAP, strain[:, s]) # using Q for the cap stress.plus[:, s] = np.dot( Qbar_TUBE_PLUS, strain[:, s]) # using Q_bar for the + angle plys stress.minus[:, s] = np.dot( Qbar_TUBE_MINUS, strain[:, s]) # using Q_bar for the - angle plys # Transform stresses to material axes for each lamina angle stress.plus[:, s] = np.dot(T_PLUS, stress.plus[:, s]) stress.minus[:, s] = np.dot(T_MINUS, stress.minus[:, s]) # Determine fraction of failure for each lamina angle # ULTIMATE_11_TENS and ULTIMATE_11_COMP are both positive values # indicating the maximum tensile and compressive stress before failure. # failure.cap[0,s] will be positive for tensile failures and negative for # compressive failures. # Cap failure if len(nCap) == 0 or (nCap == 0).all(): failure.cap[0, s] = 0 failure.cap[1, s] = 0 failure.cap[2, s] = 0 else: if stress.cap[0, s] > 0: # tensile stress in fibre failure.cap[ 0, s] = stress.cap[0, s] / cap_props['ULTIMATE_11_TENS'] else: failure.cap[ 0, s] = stress.cap[0, s] / cap_props['ULTIMATE_11_COMP'] if stress.cap[1, s] > 0: # tensile stress in matrix failure.cap[ 1, s] = stress.cap[1, s] / cap_props['ULTIMATE_22_TENS'] else: failure.cap[ 1, s] = stress.cap[1, s] / cap_props['ULTIMATE_22_COMP'] failure.cap[2, s] = stress.cap[2, s] / cap_props['ULTIMATE_12'] # Plus angle ply failure if stress.plus[0, s] > 0: # tensile stress in fibre failure.plus[ 0, s] = stress.plus[0, s] / tube_props['ULTIMATE_11_TENS'] else: failure.plus[ 0, s] = stress.plus[0, s] / tube_props['ULTIMATE_11_COMP'] if stress.plus[1, s] > 0: # tensile stress in matrix failure.plus[ 1, s] = stress.plus[1, s] / tube_props['ULTIMATE_22_TENS'] else: failure.plus[ 1, s] = stress.plus[1, s] / tube_props['ULTIMATE_22_COMP'] failure.plus[2, s] = stress.plus[2, s] / tube_props['ULTIMATE_12'] # Minus angle ply failure if stress.minus[0, s] > 0: # tensile stress in fibre failure.minus[ 0, s] = stress.minus[0, s] / tube_props['ULTIMATE_11_TENS'] else: failure.minus[ 0, s] = stress.minus[0, s] / tube_props['ULTIMATE_11_COMP'] if stress.minus[1, s] > 0: # tensile stress in matrix failure.minus[ 1, s] = stress.minus[1, s] / tube_props['ULTIMATE_22_TENS'] else: failure.minus[ 1, s] = stress.minus[1, s] / tube_props['ULTIMATE_22_COMP'] failure.minus[2, s] = stress.minus[2, s] / tube_props['ULTIMATE_12'] return failure def torsional_buckling_failure(self, Ns, Finternal, d, theta, nTube, nCap, lBiscuit, flags): # Material Properties tube_props = prepregProperties[flags.CFRPType] V_21_TUBE = tube_props['V_12'] * (tube_props['E_22'] / tube_props['E_11']) # Coordinate system: x is axial direction, theta is circumferential direction mu_prime_x = tube_props['V_12'] mu_prime_theta = V_21_TUBE Q = np.zeros((3, 3)) # Preallocate Q-matrix # Matrix of elastic constants (AER1401, Composite Lamina, slide 8) Q[0, 0] = tube_props['E_11'] / (1 - tube_props['V_12'] * V_21_TUBE) Q[1, 1] = tube_props['E_22'] / (1 - tube_props['V_12'] * V_21_TUBE) Q[0, 1] = tube_props['E_22'] * tube_props['V_12'] / ( 1 - tube_props['V_12'] * V_21_TUBE) Q[1, 0] = Q[0, 1] Q[2, 2] = tube_props['G_12'] failure = np.zeros(Ns + 1) for s in range(Ns): if nCap[s] != 0: AF_torsional_buckling = 1.25 # See "Validation - Torsional Buckling.xlsx" else: AF_torsional_buckling = 1 # Determine elastic properties of rotated tube laminate x = theta[s] # Composite angle (in radians) # Transformation matrix T = np.array( [[cos(x)**2, sin(x)**2, 2 * sin(x) * cos(x)], [sin(x)**2, cos(x)**2, -2 * sin(x) * cos(x)], [-sin(x) * cos(x), sin(x) * cos(x), cos(x)**2 - sin(x)**2]]) # Transform the elastic constants using the transformation matrix to obtain the # elastic constants at the composite angle. # MATLAB version: Qbar = (T\Q)/T' tmp = np.linalg.solve(T, Q) Qbar = np.linalg.solve(T, tmp.T) # Breakout tube elastic constants at the transformed angle E_x = Qbar[0, 0] E_theta = Qbar[1, 1] # Calculate tube geometric properties t_tube = nTube[s] * tube_props[ 'T_PLY'] # Shell thickness, CR-912 p.xxxvi R = ( d[s] + t_tube ) / 2 # Radius from axis of rotation to centroidal surface of cylinder wall, CR-912 p.xxxiv L = lBiscuit[s] # Unsupported length of cylinder, CR-912 p.xxx # Calculate tube elastic properties (CR-912 p.576) D_x = E_x * (1. / 12) * (t_tube**3) D_theta = E_theta * (1. / 12) * (t_tube**3) B_x = E_x * t_tube B_theta = E_theta * t_tube # Calculate Gamma rho = ((D_x * D_theta) / (B_x * B_theta))**(1. / 4) Gamma = 3.6125e-07 * ((R / (rho * 1000)) ** 6) + \ -1.9724e-05 * ((R / (rho * 1000)) ** 5) + \ 0.0004283 * ((R / (rho * 1000)) ** 4) + \ -0.0048315 * ((R / (rho * 1000)) ** 3) + \ 0.031801 * ((R / (rho * 1000)) ** 2) + \ -0.12975 * (R / (rho * 1000)) + \ 0.88309 # Calculate factors required in critical torque equation Z = ((B_theta * (1 - mu_prime_x * mu_prime_theta) * (L**4)) / (12 * D_x * (R**2)))**(1. / 2) Z_s = ((D_theta / D_x)**(5. / 6)) * ((B_x / B_theta)**(1. / 2)) * Z K_s = 0.89 * (Z_s**(3. / 4)) N_x_theta = (Gamma * K_s * (pi**2) * D_x) / (L**2) # Calculate critical torque critical_torque = AF_torsional_buckling * N_x_theta * 2 * pi * (R** 2) failure[s] = abs(Finternal[4, s] / critical_torque) failure[Ns] = 0 # no torsion at tip return failure
class FEM(Component): """ Computes the deformation of the spar """ # inputs flags = VarTree(Flags(), iotype='in') yN = Array(iotype='in', desc='') EIx = Array(iotype='in', desc='') EIz = Array(iotype='in', desc='') EA = Array(iotype='in', desc='') GJ = Array(iotype='in', desc='') cE = Array(iotype='in', desc='chord of each element') xEA = Array(iotype='in', desc='') fblade = VarTree(Fblade(), iotype='in') mSpar = Array(iotype='in', desc='mass of spars') mChord = Array(iotype='in', desc='mass of chords') xCG = Array(iotype='in', desc='') yWire = Array(iotype='in', desc='location of wire attachment along span') zWire = Float(iotype='in', desc='depth of wire attachement') TWire = Array(iotype='in', desc='') presLoad = VarTree(PrescribedLoad(), iotype='in') # outputs k = Array(iotype='out', desc='local elastic stiffness matrix') K = Array(iotype='out', desc='global stiffness matrix') F = Array(iotype='out', desc='global force vector') q = Array(iotype='out', desc='deformation') def execute(self): # short aliases yN = self.yN EIx = self.EIx EIz = self.EIz EA = self.EA GJ = self.GJ xEA = self.xEA cE = self.cE mSpar = self.mSpar mChord = self.mChord xCG = self.xCG yWire = self.yWire zWire = self.zWire TWire = self.TWire fblade = self.fblade presLoad = self.presLoad Ns = len(yN) - 1 # number of elements dy = np.zeros(Ns) for s in range(Ns + 1): dy[s - 1] = yN[s] - yN[s - 1] # length of each element # FEM computation for structural deformations # ------------------------------------------- # Initialize global stiffness matrix K = np.zeros(((Ns + 1) * 6, (Ns + 1) * 6)) # global stiffness F = np.zeros(((Ns + 1) * 6, 1)) # global force vector # Create global stiffness maxtrix and force vector k = np.zeros((12, 12, Ns)) for s in range(Ns): # Local elastic stiffness matrix k[0, 0, s] = 12 * EIx[s] / (dy[s] * dy[s] * dy[s]) k[0, 5, s] = -6 * EIx[s] / (dy[s] * dy[s]) k[5, 0, s] = k[0, 5, s] k[0, 6, s] = -12 * EIx[s] / (dy[s] * dy[s] * dy[s]) k[6, 0, s] = k[0, 6, s] k[0, 11, s] = -6 * EIx[s] / (dy[s] * dy[s]) k[11, 0, s] = k[0, 11, s] k[1, 1, s] = EA[s] / dy[s] k[1, 7, s] = -EA[s] / dy[s] k[7, 1, s] = k[1, 7, s] k[2, 2, s] = 12 * EIz[s] / (dy[s] * dy[s] * dy[s]) k[2, 3, s] = 6 * EIz[s] / (dy[s] * dy[s]) k[3, 2, s] = k[2, 3, s] k[2, 8, s] = -12 * EIz[s] / (dy[s] * dy[s] * dy[s]) k[8, 2, s] = k[2, 8, s] k[2, 9, s] = 6 * EIz[s] / (dy[s] * dy[s]) k[9, 2, s] = k[2, 9, s] k[3, 3, s] = 4 * EIz[s] / dy[s] k[3, 8, s] = -6 * EIz[s] / (dy[s] * dy[s]) k[8, 3, s] = k[3, 8, s] k[3, 9, s] = 2 * EIz[s] / dy[s] k[9, 3, s] = k[3, 9, s] k[4, 4, s] = GJ[s] / dy[s] k[4, 10, s] = -GJ[s] / dy[s] k[10, 4, s] = k[4, 10, s] k[5, 5, s] = 4 * EIx[s] / dy[s] k[5, 6, s] = 6 * EIx[s] / (dy[s] * dy[s]) k[6, 5, s] = k[5, 6, s] k[5, 11, s] = 2 * EIx[s] / dy[s] k[11, 5, s] = k[5, 11, s] k[6, 6, s] = 12 * EIx[s] / (dy[s] * dy[s] * dy[s]) k[6, 11, s] = 6 * EIx[s] / (dy[s] * dy[s]) k[11, 6, s] = k[6, 11, s] k[7, 7, s] = EA[s] / dy[s] k[8, 8, s] = 12 * EIz[s] / (dy[s] * dy[s] * dy[s]) k[8, 9, s] = -6 * EIz[s] / (dy[s] * dy[s]) k[9, 8, s] = k[8, 9, s] k[9, 9, s] = 4 * EIz[s] / dy[s] k[10, 10, s] = GJ[s] / dy[s] k[11, 11, s] = 4 * EIx[s] / dy[s] # Perform dihedral and sweep rotations here if needed # Assemble global stiffness matrix K[(6*s):(6*s + 12), (6*s):(6*s + 12)] = \ K[(6*s):(6*s + 12), (6*s):(6*s + 12)] + k[:, :, s] Faero = np.zeros((6, 1)) if self.flags.Load == 0: # include aero forces # aerodynamic forces xAC = 0.25 Faero[0] = fblade.Fx[s] / 2 Faero[1] = 0 Faero[2] = fblade.Fz[s] / 2 Faero[3] = fblade.Fz[s] * dy[s] / 12 Faero[4] = fblade.My[s] / 2 + (xEA[s] - xAC) * cE[s] * fblade.Fz[s] / 2 Faero[5] = -fblade.Fx[s] * dy[s] / 12 Fg = np.zeros((6, 1)) Fwire = np.zeros((12, 1)) if (self.flags.Load == 0) or (self.flags.Load == 1): # gravitational forces g = 9.81 Fg[0] = 0 Fg[1] = 0 Fg[2] = -(mSpar[s] + mChord[s]) * g / 2 Fg[3] = -(mSpar[s] + mChord[s]) * g * dy[s] / 12 Fg[4] = (xCG[s] - xEA[s]) * cE[s] * (mSpar[s] + mChord[s]) * g / 2 Fg[5] = 0 # Wire forces (using consistent force vector) for w in range(len(yWire)): if (yWire[w] >= yN[s]) and (yWire[w] < yN[s + 1]): thetaWire = atan2(zWire, yWire[w]) a = yWire[w] - yN[s] L = dy[s] FxWire = -cos(thetaWire) * TWire[w] FzWire = -sin(thetaWire) * TWire[w] Fwire[0] = 0 Fwire[1] = FxWire * (1 - a / L) Fwire[2] = FzWire * (2 * (a / L)**3 - 3 * (a / L)**2 + 1) Fwire[3] = FzWire * a * ((a / L)**2 - 2 * (a / L) + 1) Fwire[4] = 0 Fwire[5] = 0 Fwire[6] = 0 Fwire[7] = FxWire * (a / L) Fwire[8] = FzWire * (-2 * (a / L)**3 + 3 * (a / L)**2) Fwire[9] = FzWire * a * ((a / L)**2 - (a / L)) Fwire[10] = 0 Fwire[11] = 0 else: Fwire = np.zeros((12, 1)) Fpres = np.zeros((12, 1)) if self.flags.Load == 2: # Prescribed point load (using consistent force vector) if (presLoad.y >= yN[s]) and (presLoad.y < yN[s + 1]): a = presLoad.y - yN[s] L = dy[s] Fpres[0] = 0 Fpres[1] = 0 Fpres[2] = presLoad.pointZ * (2 * (a / L)**3 - 3 * (a / L)**2 + 1) Fpres[3] = presLoad.pointZ * a * ((a / L)**2 - 2 * (a / L) + 1) Fpres[4] = presLoad.pointM * (1 - a / L) Fpres[5] = 0 Fpres[6] = 0 Fpres[7] = 0 Fpres[8] = presLoad.pointZ * (-2 * (a / L)**3 + 3 * (a / L)**2) Fpres[9] = presLoad.pointZ * a * ((a / L)**2 - (a / L)) Fpres[10] = presLoad.pointM * (a / L) Fpres[11] = 0 # Prescribed distributed load Fpres[0] = Fpres[0] + presLoad.distributedX * dy[s] / 2 Fpres[1] = Fpres[1] + 0 Fpres[2] = Fpres[2] + presLoad.distributedZ * dy[s] / 2 Fpres[ 3] = Fpres[3] + presLoad.distributedZ * dy[s] * dy[s] / 12 Fpres[4] = Fpres[4] + presLoad.distributedM * dy[s] / 2 Fpres[ 5] = Fpres[5] - presLoad.distributedX * dy[s] * dy[s] / 12 Fpres[6] = Fpres[6] + presLoad.distributedX * dy[s] / 2 Fpres[7] = Fpres[7] + 0 Fpres[8] = Fpres[8] + presLoad.distributedZ * dy[s] / 2 Fpres[ 9] = Fpres[9] - presLoad.distributedZ * dy[s] * dy[s] / 12 Fpres[10] = Fpres[10] + presLoad.distributedM * dy[s] / 2 Fpres[11] = Fpres[ 11] + presLoad.distributedX * dy[s] * dy[s] / 12 # Assemble global force vector F[(s * 6 + 0)] = F[(s * 6 + 0)] + Fpres[0] + Fwire[0] + Fg[0] + Faero[0] # x force F[(s * 6 + 1)] = F[(s * 6 + 1)] + Fpres[1] + Fwire[1] + Fg[1] + Faero[1] # y force F[(s * 6 + 2)] = F[(s * 6 + 2)] + Fpres[2] + Fwire[2] + Fg[2] + Faero[2] # z force F[(s * 6 + 3)] = F[(s * 6 + 3 )] + Fpres[3] + Fwire[3] + Fg[3] + Faero[3] # x moment F[(s * 6 + 4)] = F[(s * 6 + 4 )] + Fpres[4] + Fwire[4] + Fg[4] + Faero[4] # y moment F[(s * 6 + 5)] = F[(s * 6 + 5 )] + Fpres[5] + Fwire[5] + Fg[5] + Faero[5] # z moment F[(s * 6 + 6)] = F[(s * 6 + 6)] + Fpres[6] + Fwire[6] + Fg[0] + Faero[0] # x force F[(s * 6 + 7)] = F[(s * 6 + 7)] + Fpres[7] + Fwire[7] + Fg[1] + Faero[1] # y force F[(s * 6 + 8)] = F[(s * 6 + 8)] + Fpres[8] + Fwire[8] + Fg[2] + Faero[2] # z force F[(s * 6 + 9)] = F[(s * 6 + 9 )] + Fpres[9] + Fwire[9] - Fg[3] - Faero[3] # x moment F[(s * 6 + 10)] = F[(s * 6 + 10)] + Fpres[10] + Fwire[10] + Fg[4] + Faero[ 4] # y moment F[(s * 6 + 11)] = F[(s * 6 + 11)] + Fpres[11] + Fwire[11] - Fg[5] - Faero[ 5] # z moment # Add constraints to all 6 dof at root if self.flags.wingWarp > 0: # Also add wingWarping constraint raise Exception( 'FEM is untested and surely broken for wingWarp > 0') ii = np.array([]) for ss in range((Ns + 1) * 6 - 1): if (ss > 5) and (ss != self.flags.wingWarp * 6 + 5): ii = np.array([ii, ss]).reshape(1, -1) Fc = F[(ii - 1)] Kc = K[(ii - 1), (ii - 1)] else: Fc = F[6:] Kc = K[6:, 6:] # Solve constrained system qc, _, _, _ = np.linalg.lstsq(Kc, Fc) if self.flags.wingWarp > 0: self.q[ii, 1] = qc else: # self.q = np.array([0, 0, 0, 0, 0, 0, qc]).reshape(1, -1) self.q = np.append( np.array([0, 0, 0, 0, 0, 0]).reshape(-1, 1), qc).reshape(-1, 1) # output the stiffness and force arrays as well (for use in failure analysis) self.k = k self.K = K self.F = F
def __init__(self, Ns): super(FEM, self).__init__() # inputs self.add('flags', VarTree(Flags(), iotype='in')) self.add('yN', Array(np.zeros(Ns + 1), iotype='in', desc='')) self.add('EIx', Array(np.zeros(Ns), iotype='in', desc='')) self.add('EIz', Array(np.zeros(Ns), iotype='in', desc='')) self.add('EA', Array(np.zeros(Ns), iotype='in', desc='')) self.add('GJ', Array(np.zeros(Ns), iotype='in', desc='')) self.add( 'cE', Array(np.zeros(Ns), iotype='in', desc='chord of each element')) self.add('xEA', Array(np.zeros(Ns), iotype='in', desc='')) self.add('fblade', VarTree(Fblade(Ns), iotype='in')) self.add('mSpar', Array(np.zeros(Ns), iotype='in', desc='mass of spars')) self.add('mChord', Array(np.zeros(Ns), iotype='in', desc='mass of chords')) self.add('xCG', Array(np.zeros(Ns), iotype='in', desc='')) self.add( 'yWire', Array([0], iotype='in', desc='location of wire attachment along span')) self.add('zWire', Float(0., iotype='in', desc='depth of wire attachment')) self.add('TWire', Array([0], iotype='in', desc='')) self.add('presLoad', VarTree(PrescribedLoad(), iotype='in')) # outputs self.add( 'k', Array(np.zeros((Ns + 2, Ns + 2, Ns)), iotype='out', desc='local elastic stiffness matrix')) self.add( 'K', Array(np.zeros((Ns + 2, Ns + 2, Ns)), iotype='out', desc='global stiffness matrix')) self.add( 'F', Array(np.zeros((6 * (Ns + 1), 1)), iotype='out', desc='global force vector')) self.add( 'q', Array(np.zeros((6 * (Ns + 1), 1)), iotype='out', desc='deformation'))
def __init__(self, Ns): super(Structures, self).__init__() # flags self.add('flags', VarTree(Flags(), iotype='in')) # inputs for spars self.add( 'yN', Array(np.zeros(Ns + 1), iotype='in', desc='node locations for each element along the span')) self.add('d', Array(np.zeros(Ns), iotype='in', desc='spar diameter')) self.add('theta', Array(np.zeros(Ns), iotype='in', desc='wrap angle')) self.add( 'nTube', Array(np.zeros(Ns), iotype='in', desc='number of tube layers')) self.add('nCap', Array(np.zeros(Ns), iotype='in', desc='number of cap strips')) self.add( 'lBiscuit', Array(np.zeros(Ns), iotype='in', desc='unsupported biscuit length')) # joint properties self.add('Jprop', VarTree(JointProperties(), iotype='in')) # inputs for chord self.add('b', Int(0, iotype='in', desc='number of blades')) self.add( 'cE', Array(np.zeros(Ns), iotype='in', desc='chord of each element')) self.add('xEA', Array(np.zeros(Ns), iotype='in', desc='')) self.add('xtU', Array(np.zeros(Ns), iotype='in', desc='')) # inputs for quad self.add('dQuad', Float(0., iotype='in', desc='diameter of quad rotor struts')) self.add( 'thetaQuad', Float(0., iotype='in', desc='wrap angle of quad rotor struts')) self.add( 'nTubeQuad', Int(0, iotype='in', desc='number of CFRP layers in quad rotor struts')) self.add('lBiscuitQuad', Float(0., iotype='in', desc='')) self.add( 'RQuad', Float( 0., iotype='in', desc= 'distance from centre of helicopter to centre of quad rotors')) self.add('hQuad', Float(0., iotype='in', desc='height of quad-rotor truss')) # inputs for cover self.add('ycmax', Float(0., iotype='in', desc='')) # inputs for wire self.add( 'yWire', Array([0], iotype='in', desc='location of wire attachment along span')) self.add('zWire', Float(0., iotype='in', desc='depth of wire attachement')) self.add('tWire', Float(0., iotype='in', desc='thickness of wire')) self.add('TWire', Array([0], iotype='in', desc='')) self.add('TEtension', Float(0., iotype='in', desc='')) # inputs for 'other stuff' self.add('mElseRotor', Float(0., iotype='in', desc='')) self.add('mElseCentre', Float(0., iotype='in', desc='')) self.add('mElseR', Float(0., iotype='in', desc='')) self.add('R', Float(0., iotype='in', desc='rotor radius')) self.add('mPilot', Float(0., iotype='in', desc='mass of pilot')) # inputs for FEM self.add('fblade', VarTree(Fblade(Ns), iotype='in')) self.add('presLoad', VarTree(PrescribedLoad(), iotype='in')) # configure self.add('spar', SparProperties(Ns)) self.connect('yN', 'spar.yN') self.connect('d', 'spar.d') self.connect('theta', 'spar.theta') self.connect('nTube', 'spar.nTube') self.connect('nCap', 'spar.nCap') self.connect('lBiscuit', 'spar.lBiscuit') self.connect('flags.CFRPType', 'spar.CFRPType') self.add('joint', JointSparProperties(Ns)) self.connect('flags.CFRPType', 'joint.CFRPType') self.connect('Jprop', 'joint.Jprop') self.add('chord', ChordProperties(Ns)) self.connect('yN', 'chord.yN') self.connect('cE', 'chord.c') self.connect('d', 'chord.d') self.connect('flags.GWing', 'chord.GWing') self.connect('xtU', 'chord.xtU') self.add('quad', QuadSparProperties(Ns)) self.connect('dQuad', 'quad.dQuad') self.connect('thetaQuad', 'quad.thetaQuad') self.connect('nTubeQuad', 'quad.nTubeQuad') self.connect('lBiscuitQuad', 'quad.lBiscuitQuad') self.connect('flags.CFRPType', 'quad.CFRPType') self.connect('RQuad', 'quad.RQuad') self.connect('hQuad', 'quad.hQuad') self.add('mass', MassProperties(Ns)) self.connect('flags', 'mass.flags') self.connect('b', 'mass.b') self.connect('spar.mSpar', 'mass.mSpar') self.connect('chord.mChord', 'mass.mChord') self.connect('chord.xCGChord', 'mass.xCGChord') self.connect('quad.mQuad', 'mass.mQuad') self.connect('xEA', 'mass.xEA') self.connect('ycmax', 'mass.ycmax') self.connect('zWire', 'mass.zWire') self.connect('yWire', 'mass.yWire') self.connect('tWire', 'mass.tWire') self.connect('mElseRotor', 'mass.mElseRotor') self.connect('mElseCentre', 'mass.mElseCentre') self.connect('mElseR', 'mass.mElseR') self.connect('R', 'mass.R') self.connect('mPilot', 'mass.mPilot') self.add('fem', FEM(Ns)) self.connect('flags', 'fem.flags') self.connect('yN', 'fem.yN') self.connect('spar.EIx', 'fem.EIx') self.connect('spar.EIz', 'fem.EIz') self.connect('spar.EA', 'fem.EA') self.connect('spar.GJ', 'fem.GJ') self.connect('cE', 'fem.cE') self.connect('xEA', 'fem.xEA') self.connect('spar.mSpar', 'fem.mSpar') self.connect('chord.mChord', 'fem.mChord') self.connect('mass.xCG', 'fem.xCG') self.connect('zWire', 'fem.zWire') self.connect('yWire', 'fem.yWire') self.connect('TWire', 'fem.TWire') self.connect('fblade', 'fem.fblade') self.connect('presLoad', 'fem.presLoad') self.add('strains', Strains(Ns)) self.connect('yN', 'strains.yN') self.connect('d', 'strains.d') self.connect('fem.k', 'strains.k') self.connect('fem.F', 'strains.F') self.connect('fem.q', 'strains.q') self.add('failure', Failures(Ns)) self.connect('flags', 'failure.flags') self.connect('yN', 'failure.yN') self.connect('strains.Finternal', 'failure.Finternal') self.connect('strains.strain', 'failure.strain') self.connect('d', 'failure.d') self.connect('theta', 'failure.theta') self.connect('nTube', 'failure.nTube') self.connect('nCap', 'failure.nCap') self.connect('yWire', 'failure.yWire') self.connect('zWire', 'failure.zWire') self.connect('joint.EIx', 'failure.EIxJ') self.connect('joint.EIz', 'failure.EIzJ') self.connect('lBiscuit', 'failure.lBiscuit') self.connect('dQuad', 'failure.dQuad') self.connect('thetaQuad', 'failure.thetaQuad') self.connect('nTubeQuad', 'failure.nTubeQuad') self.connect('lBiscuitQuad', 'failure.lBiscuitQuad') self.connect('RQuad', 'failure.RQuad') self.connect('hQuad', 'failure.hQuad') self.connect('quad.EIx', 'failure.EIQuad') self.connect('quad.GJ', 'failure.GJQuad') self.connect('tWire', 'failure.tWire') self.connect('TWire', 'failure.TWire') self.connect('TEtension', 'failure.TEtension') self.connect('b', 'failure.b') self.connect('fblade', 'failure.fblade') self.connect('spar.mSpar', 'failure.mSpar') self.connect('chord.mChord', 'failure.mChord') self.connect('mElseRotor', 'failure.mElseRotor') # link up the outputs self.create_passthrough('mass.Mtot') self.create_passthrough('fem.q') self.create_passthrough('strains.Finternal') self.create_passthrough('strains.strain') self.create_passthrough('failure.fail') self.driver.workflow.add('chord') self.driver.workflow.add('fem') self.driver.workflow.add('joint') self.driver.workflow.add('mass') self.driver.workflow.add('quad') self.driver.workflow.add('spar') self.driver.workflow.add('strains') self.driver.workflow.add('failure')