Esempio n. 1
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 def Geometry(self):
     
     O  = vm.Point2D((self.Ox, self.Oy))
     A  = O.Translation(vm.Point2D((self.LA*npy.cos(self.alpha0), self.LA*npy.sin(self.alpha0))))
     alpha = self.alpha0 - self.alphaA
     B  = A.Translation(vm.Point2D((self.L1*npy.cos(alpha), self.L1*npy.sin(alpha))))
     alpha = alpha - self.alphaB
     P  = B.Translation(vm.Point2D((self.L2*npy.cos(alpha), self.L2*npy.sin(alpha))))
     alpha = alpha + self.alphaP
     M  = P.Translation(vm.Point2D((self.L5*npy.cos(alpha), self.L5*npy.sin(alpha))))
     
     alpha = self.alpha0 - self.alphaE
     E  = O.Translation(vm.Point2D((self.LE*npy.cos(alpha), self.LE*npy.sin(alpha))))
     alphap = alpha - self.alpha1
     C  = E.Translation(vm.Point2D((self.L4*npy.cos(alphap), self.L4*npy.sin(alphap))))
     D  = E.Translation(vm.Point2D((-self.L3*npy.cos(alphap), -self.L3*npy.sin(alphap))))
     alpha = alphap + npy.pi/2. - self.alphaC
     F  = C.Translation(vm.Point2D((self.L7*npy.cos(alpha), self.L7*npy.sin(alpha))))
     alpha = alphap + npy.pi/2. + self.alphaD
     G  = D.Translation(vm.Point2D((self.L6*npy.cos(alpha), self.L6*npy.sin(alpha))))
     
     AB=vm.LineSegment2D(A, B)
     BP=vm.LineSegment2D(B, P)
     PM=vm.LineSegment2D(P, M)
     DE=vm.LineSegment2D(D, E)
     EC=vm.LineSegment2D(E, C)
     DG=vm.LineSegment2D(D, G)
     CF=vm.LineSegment2D(C, F)
     
     alpha = alphap - npy.pi/2.
     R = E.Translation(vm.Point2D((self.DI/2.*npy.cos(alpha), self.DI/2.*npy.sin(alpha))))
     # recherche du point F1 et F2
     def fonct(alpha, *data):
         line, d = data
         x  = R.Translation(vm.Point2D((d/2.*npy.cos(alpha + npy.pi/2.), d/2.*npy.sin(alpha + npy.pi/2.))))
         p = line.PointProjection(x)
         return p.PointDistance(x)
     sol1 = fsolve(fonct, 0, args=(DG, self.DF))
     F1  = R.Translation(vm.Point2D((self.DF/2.*npy.cos(npy.pi/2. + sol1), self.DF/2.*npy.sin(npy.pi/2. + sol1))))
     sol2 = fsolve(fonct, 0, args=(CF, self.DF))
     F2  = R.Translation(vm.Point2D((self.DF/2.*npy.cos(npy.pi/2. + sol2), self.DF/2.*npy.sin(npy.pi/2. + sol2))))
     
     
     Cr = vm.Circle2D(R, self.DF/2.)
     
     c=vm.CompositePrimitive2D([O, AB, BP, PM, DE, EC, DG, CF, R, Cr, F1, F2])
     c.MPLPlot(style='--ob')
Esempio n. 2
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@author: Mack Pro
"""

import numpy as npy
import volmdlr as volmdlr
import volmdlr.primitives3D as primitives3D
import volmdlr.primitives2D as primitives2D
import matplotlib.pyplot as plt
import random

######## SWEEP TEST RANDOM

nb_point1, nb_point2 = 6, 5

radius_circle1, radius_circle2 = 0.008, 0.01
c1 = volmdlr.Circle2D(volmdlr.Point2D((0, 0)), radius_circle1)
contour1 = volmdlr.Contour2D([c1])

c2 = volmdlr.Circle2D(volmdlr.Point2D((0, 0)), radius_circle2)
contour2 = volmdlr.Contour2D([c2])

mini, maxi = -1, 1
pts1 = []
for k in range(nb_point1):
    a1, a2, a3 = random.randint(mini, maxi), random.randint(
        mini, maxi), random.randint(mini, maxi)
    c1, c2, c3 = random.randrange(0, 100, 1), random.randrange(
        0, 100, 1), random.randrange(0, 100, 1)
    pts1.append(volmdlr.Point3D((a1 * c1 / 100, a2 * c2 / 100, a3 * c3 / 100)))

radius1 = {
Esempio n. 3
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# -*- coding: utf-8 -*-
"""
Created on Tue May 12 17:14:06 2020

@author: masfaraud
"""

import numpy as npy
import volmdlr as volmdlr
import volmdlr.primitives3D as primitives3D
import volmdlr.primitives2D as primitives2D
import matplotlib.pyplot as plt
import random

radius_circle = 0.008
c = volmdlr.Circle2D(volmdlr.Point2D((0, 0)), radius_circle)
contour = volmdlr.Contour2D([c])
pt0 = volmdlr.Point3D((0.01, 0.04, 0.16))
pt1 = volmdlr.Point3D((0.03, 0, 0.2))
pt2 = volmdlr.Point3D((0.45, 0.01, 0.1))
pt3 = volmdlr.Point3D((0.45, 0, -0.1))
pt4 = volmdlr.Point3D((0.3, 0.04, -0.02))
pts = [pt0, pt1, pt2, pt3, pt4]
radius = {1: 0.03, 2: 0.01, 3: 0.07}
rl = primitives3D.OpenedRoundedLineSegments3D(pts,
                                              radius,
                                              adapt_radius=True,
                                              name='wire')
sweep = primitives3D.Sweep(contour, rl, name='pipe')

pt10 = volmdlr.Point3D((0.02, 0.22, 0.25))
Esempio n. 4
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p4 = vm.Point2D((0, r1))
p4.Rotation(pc, theta1 + theta3, False)
p5 = p4.Rotation(pc, theta2)
p6 = p1.Rotation(pc, theta)

l1 = primitives2D.RoundedLineSegments2D([p3, p4, p5, p6], {1: r3, 2: r3})

#l1=primitives2D.RoundedLines2D([p1,p2,p3,p4],{0:0.01,2:0.01})
#l2=vm.Circle2D(p5,0.01)
L = [a1, l1]
for i in range(Z - 1):
    thetar = (i + 1) * theta
    L.append(a1.Rotation(pc, thetar, True))
    L.append(l1.Rotation(pc, thetar, True))
#p7=vm.Point2D((0,r4))
l2 = vm.Circle2D(pc, r4)

c1 = vm.Contour2D(L)
c2 = vm.Contour2D([l2])

po = vm.Point3D((0, 0, 0))
xp = vm.Vector3D((1, 0, 0))
yp = vm.Vector3D((0, 1, 0))

#c1.MPLPlot()
#extr_vect=vm.Vector3D((0,0,e))

profile_straight = primitives3D.ExtrudedProfile(po,
                                                xp,
                                                yp,
                                                c1, [c2], (0, 0, e),
Esempio n. 5
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 def transversal_plot(self, offset=0, ax=None):
     oc = vm.Circle2D(vm.O2D, self.overall_rim_diameter * 0.5)
     fig, ax = oc.plot(ax=ax)
     for circle in self.bolt_circles():
         circle.plot(ax=ax)
     return fig, ax
Esempio n. 6
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#!/usr/bin/env python3
# -*- coding: utf-8 -*-
"""
Created on Fri May 12 10:04:09 2017

@author: steven
"""

import volmdlr as vm

l = 0.1

p1 = vm.Point2D((0, 0))
p2 = vm.Point2D((l, 0))
p3 = vm.Point2D((l, l))
p4 = vm.Point2D((0, l))

l1 = vm.LineSegment2D(p1, p2)
l2 = vm.LineSegment2D(p2, p3)
l3 = vm.LineSegment2D(p3, p4)
l4 = vm.LineSegment2D(p4, p1)

p5 = vm.Point2D((l / 2, l / 2))
c1 = vm.Circle2D(p5, l / 5)

ct1 = vm.Contour2D([l4, l3, l2, l1])
ct2 = vm.Contour2D([c1])
mesh = vm.Mesh2D([ct1, ct2], {}, 0.01)

print(mesh.GeoScript('mesh2D.geo'))
def circle_1_point_2_segments(point, line1, line2):
    
    # point will be called I(x_I, y_I)
    # semgent1 will be [AB]
    # segment2 will be [CD]

    I = vm.Vector2D((point[0], point[1]))
    A = vm.Vector2D((line1.points[0][0], line1.points[0][1]))
    B = vm.Vector2D((line1.points[1][0], line1.points[1][1]))
    C = vm.Vector2D((line2.points[0][0], line2.points[0][1]))
    D = vm.Vector2D((line2.points[1][0], line2.points[1][1]))
    
    # CHANGEMENT DE REPAIRE
    new_u = vm.Vector2D((B-A))
    new_u.Normalize()
    new_v = new_u.NormalVector(unit=True)
    new_basis = vm.Frame2D(I, new_u, new_v)
    
    new_A = new_basis.NewCoordinates(A)
    new_B = new_basis.NewCoordinates(B)
    new_C = new_basis.NewCoordinates(C)
    new_D = new_basis.NewCoordinates(D)
    
# =============================================================================
# LES SEGMENTS DECRIVENT UNE SEULE ET MEME DROITE
#   => AUCUNE SOLUTION   
# =============================================================================
    if new_C[1] == 0 and new_D[1] == 0:

        return None, None
    
# =============================================================================
# LES SEGMENTS SONT PARALLELES
#   => 1 SOLUTION
# =============================================================================
    elif math.isclose(line1.DirectionVector(unit=True).Dot(line2.NormalVector(unit=True)), 0, abs_tol=1e-06):

        segments_distance = abs(new_C[1] - new_A[1])
        r = segments_distance / 2
        new_circle_center = vm.Point2D((0, r))
        circle_center = new_basis.OldCoordinates(new_circle_center)
        circle = vm.Circle2D(circle_center, r)
        
        return circle, None
# =============================================================================
# LES SEGMENTS SONT PERPENDICULAIRES
#   => 2 SOLUTIONS
# =============================================================================
    elif math.isclose(line1.DirectionVector(unit=True).Dot(line2.DirectionVector(unit=True)), 0, abs_tol=1e-06):

        line_AB = vm.Line2D(vm.Point2D(new_A), vm.Point2D(new_B))
        line_CD = vm.Line2D(vm.Point2D(new_C), vm.Point2D(new_D))
        new_pt_K = vm.Point2D.LinesIntersection(line_AB ,line_CD)
        
        r = abs(new_pt_K[0])
        new_circle_center1 = vm.Point2D((0, r))
        new_circle_center2 = vm.Point2D((0, -r))
        circle_center1 = new_basis.OldCoordinates(new_circle_center1)
        circle_center2 = new_basis.OldCoordinates(new_circle_center2)
        circle1 = vm.Circle2D(circle_center1, r)
        circle2 = vm.Circle2D(circle_center2, r)
        
        return circle1, circle2
    
# =============================================================================
# LES SEGMENTS SONT QUELCONQUES
#   => 2 SOLUTIONS
# =============================================================================
    else:

        line_AB = vm.Line2D(vm.Point2D(new_A), vm.Point2D(new_B))
        line_CD = vm.Line2D(vm.Point2D(new_C), vm.Point2D(new_D))
        new_pt_K = vm.Point2D.LinesIntersection(line_AB ,line_CD)
        pt_K = vm.Point2D(new_basis.OldCoordinates(new_pt_K))

        # CHANGEMENT DE REPERE:
        new_u2 = vm.Vector2D(pt_K-I)
        new_u2.Normalize()
        new_v2 = new_u2.NormalVector(unit=True)
        new_basis2 = vm.Frame2D(I, new_u2, new_v2)
        
        new_A = new_basis2.NewCoordinates(A)
        new_B = new_basis2.NewCoordinates(B)
        new_C = new_basis2.NewCoordinates(C)
        new_D = new_basis2.NewCoordinates(D)
        new_pt_K = new_basis2.NewCoordinates(pt_K)

        teta1 = math.atan2(new_C[1], new_C[0] - new_pt_K[0])
        teta2 = math.atan2(new_D[1], new_D[0] - new_pt_K[0])
        
        if teta1 < 0:
            teta1 += math.pi
        if teta2 < 0:
            teta2 += math.pi
            
        if not math.isclose(teta1, teta2, abs_tol=1e-08):
            if math.isclose(teta1, math.pi, abs_tol=1e-08) or math.isclose(teta1, 0., abs_tol=1e-08):
                teta = teta2 
            elif math.isclose(teta2, math.pi, abs_tol=1e-08) or math.isclose(teta2, 0., abs_tol=1e-08):
                teta = teta1
        else:
            teta = teta1
            
        r1 = new_pt_K[0] * math.sin(teta) / (1 + math.cos(teta))
        r2 = new_pt_K[0] * math.sin(teta) / (1 - math.cos(teta))
        
        new_circle_center1 = vm.Point2D((0, -r1))
        new_circle_center2 = vm.Point2D((0, r2))
        
        circle_center1 = new_basis2.OldCoordinates(new_circle_center1)
        circle_center2 = new_basis2.OldCoordinates(new_circle_center2)
        
        if new_basis.NewCoordinates(circle_center1)[1] > 0:
            circle1 = vm.Circle2D(circle_center1, r1)
            circle2 = vm.Circle2D(circle_center2, r2)
        else:
            circle1 = vm.Circle2D(circle_center2, r2)
            circle2 = vm.Circle2D(circle_center1, r1)
        
        return circle1, circle2
Esempio n. 8
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Created on Tue May 26 09:45:01 2020

@author: Mack Pro
"""

import volmdlr as volmdlr
import volmdlr.primitives3D as primitives3D
import volmdlr.primitives2D as primitives2D
import random
import math

posmin, posmax = -100, 100

number_holes = 5

outer_circle = volmdlr.Circle2D(volmdlr.O2D, 0.06)

circles = []
delta_angle = 2*math.pi/number_holes
inner_circle = volmdlr.Circle2D(volmdlr.O2D, 0.04)
first_circle = volmdlr.Circle2D(volmdlr.Point2D((0, 0.05)), 0.005)
circles = [inner_circle, first_circle]
for i in range(1, number_holes):
    circles.append(first_circle.Rotation(volmdlr.O2D, i*delta_angle))
    
xn, yn, zn = random.randrange(posmin, posmax, 1)/100, random.randrange(posmin, posmax, 1)/100, random.randrange(posmin, posmax, 1)/100
xc, yc, zc = random.randrange(posmin, posmax, 1)/100, random.randrange(posmin, posmax, 1)/100, random.randrange(posmin, posmax, 1)/100

n = volmdlr.Vector3D([xn,yn,zn])
n.Normalize()
c = volmdlr.Point3D((xc,yc,zc))
Esempio n. 9
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f, a = inner_contour.MPLPlot()
outer_contour.MPLPlot(a)

sides = primitives3D.ExtrudedProfile(vm.o3D, vm.x3D, vm.y3D, outer_contour,
                                     [inner_contour],
                                     (height - 2 * thickness) * vm.z3D,
                                     'sides')
bottom = primitives3D.ExtrudedProfile(vm.o3D, vm.x3D, vm.y3D, outer_contour,
                                      [], -thickness * vm.z3D, 'bottom')

screw_holes_rl = inner_rl.Offset(-(thickness + screw_holes_clearance +
                                   0.5 * screw_holes_diameter))
screw_holes = []
l = screw_holes_rl.Length()
for i in range(n_screws):
    s = i * l / n_screws
    p = screw_holes_rl.PointAtCurvilinearAbscissa(s)
    screw_holes.append(
        vm.Contour2D([vm.Circle2D(p, screw_holes_diameter * 0.5)]))

belt_outer_rl = inner_rl.Offset(-(2 * screw_holes_clearance +
                                  screw_holes_diameter + thickness))
belt_outer_contour = vm.Contour2D([belt_outer_rl])
belt = primitives3D.ExtrudedProfile(vm.z3D * (height - 2 * thickness), vm.x3D,
                                    vm.y3D, belt_outer_contour,
                                    [inner_contour] + screw_holes,
                                    thickness * vm.z3D, 'belt')

casing = vm.primitives3D.Fuse([bottom, sides, belt], 'Lower Casing')
model = vm.VolumeModel([('casing', [casing])])
model.FreeCADExport('casing')
Esempio n. 10
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p15 = vm.Point2D((0.03, 0.05))

points1 = [
    p0, p1, p2, p3, p4, p5, p6, p7, p8, p9, p10, p11, p12, p13, p14, p15
]
c1 = primitives2D.ClosedRoundedLineSegments2D(points1, {
    2: 0.005,
    3: 0.005,
    4: 0.005,
    8: 0.005,
    9: 0.005,
    10: 0.005,
    14: 0.005
})

circle0 = vm.Circle2D(vm.Point2D((0.12, 0.25)), 0.02)
circle1 = vm.Circle2D(vm.Point2D((0.19, 0.25)), 0.02)
circle2 = vm.Circle2D(vm.Point2D((0.15, 0.08)), 0.08)
c2 = vm.Contour2D([circle0])
c3 = vm.Contour2D([circle1])
c4 = vm.Contour2D([circle2])

e0 = vm.Point2D((0, 0.00))
e1 = vm.Point2D((0, 0.03))
e2 = vm.Point2D((0.11, 0.03))
e3 = vm.Point2D((0.11, 0.04))
e4 = vm.Point2D((0.13, 0.04))
e5 = vm.Point2D((0.13, 0))

points2 = [e0, e1, e2, e3, e4, e5]
c5 = primitives2D.ClosedRoundedLineSegments2D(points2, {})
Esempio n. 11
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#!/usr/bin/env python3
# -*- coding: utf-8 -*-
"""
Created on Tue Mar 14 13:55:59 2017

@author: steven
"""

# Debug of area and inertia

import volmdlr as vm

r = 0.05

p1 = vm.Point2D((0, 0))
p2 = vm.Point2D((0, -r))
p3 = vm.Point2D((r, 0))
p4 = vm.Point2D((0, r))

c1 = vm.Arc2D(p2, p3, p4)

print(c1.SecondMomentArea(p1))

c2 = vm.Circle2D(p1, r)

print(c2.SecondMomentArea(p1))
Esempio n. 12
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                                          x,
                                          y,
                                          outer_contour, [],
                                          -thickness_min * extrusion_vector,
                                          alpha=alpha,
                                          name='bottom')

    # Screw
    screw_holes_rl = inner_contour.Offset(-(thickness + screw_holes_clearance +
                                            0.5 * screw_holes_diameter))
    screw_holes = []
    l = screw_holes_rl.Length()
    for i in range(n_screws):
        s = i * l / n_screws
        p = screw_holes_rl.PointAtCurvilinearAbscissa(s)
        screw_holes.append(vm.Circle2D(p, screw_holes_diameter * 0.5))

    # Belt
    belt_outer_contour = inner_contour.Offset(
        -(2 * screw_holes_clearance + screw_holes_diameter + thickness))

    belt = primitives3D.ExtrudedProfile(
        origin + basis_plane.normal * height_bot_belt,
        x,
        y,
        belt_outer_contour, [inner_contour] + screw_holes,
        height_belt * extrusion_vector,
        alpha=alpha,
        name='belt')

    # Hat floors
Esempio n. 13
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 def transversal_plot(self, ax=None):
     oc = vm.Circle2D(vm.O2D, self.diameter * 0.5)
     ic = vm.Circle2D(vm.O2D, self.rim_diameter * 0.5)
     fig, ax = oc.MPLPlot(ax=ax)
     ic.MPLPlot(ax=ax)
     return fig, ax