Exemplo n.º 1
0
    def test_example2_1(self):
        nodes = []  # list holding the node objects
        elements = []  # list holding the element objects

        # create 2d frame analysis object
        analysis = FrameAnalysis2D()

        # create sections
        steel = Steel()
        section1 = Section(area=6000)
        section2 = Section(area=8000)

        # create nodes
        nodes.append(analysis.create_node(coords=[0, 0]))
        nodes.append(analysis.create_node(coords=[6000, 4000]))
        nodes.append(analysis.create_node(coords=[9000, 0]))

        # create truss elements
        elements.append(analysis.create_element(
            el_type='Bar2-2D', nodes=[nodes[0], nodes[1]], material=steel, section=section1
        ))
        elements.append(analysis.create_element(
            el_type='Bar2-2D', nodes=[nodes[1], nodes[2]], material=steel, section=section2
        ))

        # add supports
        freedom_case = cases.FreedomCase()
        freedom_case.add_nodal_support(node=nodes[0], val=0, dof=0)
        freedom_case.add_nodal_support(node=nodes[0], val=0, dof=1)
        freedom_case.add_nodal_support(node=nodes[2], val=0, dof=0)
        freedom_case.add_nodal_support(node=nodes[2], val=0, dof=1)

        # add loads
        load_case = cases.LoadCase()
        load_case.add_nodal_load(node=nodes[1], val=500e3, dof=0)

        # add analysis case
        analysis_case = cases.AnalysisCase(freedom_case=freedom_case, load_case=load_case)

        # linear static solver
        LinearStatic(analysis=analysis, analysis_cases=[analysis_case]).solve()

        # check node displacement
        n1_disp = nodes[1].get_displacements(analysis_case)

        u = n1_disp[0]
        v = n1_disp[1]

        self.assertEqual(np.around(u, 2), 2.41)
        self.assertEqual(np.around(v, 2), 0.72)

        # check axial forces
        (_, n1) = elements[0].get_afd(n=1, analysis_case=analysis_case)
        (_, n2) = elements[1].get_afd(n=1, analysis_case=analysis_case)

        self.assertEqual(np.around(n1/1e3, 1), 400.6)
        self.assertEqual(np.around(n2/1e3, 1), -277.8)
Exemplo n.º 2
0
    def test_example2_3(self):
        # create 2d frame analysis object
        analysis = FrameAnalysis2D()

        # create sections
        steel = Steel()
        section1 = Section(area=4000)
        section2 = Section(area=1000)

        # create nodes
        a = analysis.create_node(coords=[0, 0])
        b = analysis.create_node(coords=[2000, 2000])
        c = analysis.create_node(coords=[-4000, 2000])

        # create truss elements
        el1 = analysis.create_element(
            el_type='Bar2-2D', nodes=[c, a], material=steel, section=section1)
        el2 = analysis.create_element(
            el_type='Bar2-2D', nodes=[a, b], material=steel, section=section2)

        # add supports
        freedom_case = cases.FreedomCase()
        freedom_case.add_nodal_support(node=b, val=0, dof=0)
        freedom_case.add_nodal_support(node=b, val=0, dof=1)
        freedom_case.add_nodal_support(node=c, val=0, dof=0)
        freedom_case.add_nodal_support(node=c, val=0, dof=1)
        sup1 = freedom_case.add_nodal_support(node=a, val=0, dof=0)
        sup2 = freedom_case.add_nodal_support(node=a, val=-5, dof=1)

        # add loads
        load_case = cases.LoadCase()

        # add analysis case
        analysis_case = cases.AnalysisCase(freedom_case=freedom_case, load_case=load_case)

        # linear static solver
        LinearStatic(analysis=analysis, analysis_cases=[analysis_case]).solve()

        # check reactions
        self.assertEqual(np.around(sup1.get_reaction(analysis_case)/1e3, 1), 181.0)
        self.assertEqual(np.around(sup2.get_reaction(analysis_case)/1e3, 1), -355.7)
Exemplo n.º 3
0
    def setUp(self):
        # create materials
        steel = Steel()

        # create 2d frame analysis object
        self.analysis = FrameAnalysis2D()

        section1 = Section(area=6e3, ixx=200e6)
        section2 = Section(area=4e3, ixx=50e6)

        # create nodes
        self.node_a = self.analysis.create_node(coords=[0])
        self.node_b = self.analysis.create_node(coords=[8000])
        self.node_c = self.analysis.create_node(coords=[13000])

        # create beam elements
        self.element_ab = self.analysis.create_element(
            el_type='EB2-2D', nodes=[self.node_a, self.node_b], material=steel, section=section1
        )
        self.element_bc = self.analysis.create_element(
            el_type='EB2-2D', nodes=[self.node_b, self.node_c], material=steel, section=section2
        )
Exemplo n.º 4
0
    def test_fig8(self):
        """Simple Beam – Concentrated Load at Any Point"""

        a = self.length * np.random.uniform(0.1, 0.9)
        b = self.length - a

        # create 2d frame analysis object
        analysis = FrameAnalysis2D()

        # create section
        section = Section(ixx=self.ixx)

        # create nodes
        node_a = analysis.create_node(coords=[0])
        node_b = analysis.create_node(coords=[a])
        node_c = analysis.create_node(coords=[self.length])

        # create beam elements
        element_ab = analysis.create_element(el_type='EB2-2D',
                                             nodes=[node_a, node_b],
                                             material=self.steel,
                                             section=section)
        element_bc = analysis.create_element(el_type='EB2-2D',
                                             nodes=[node_b, node_c],
                                             material=self.steel,
                                             section=section)

        # add supports
        freedom_case = cases.FreedomCase()
        freedom_case.add_nodal_support(node=node_a, val=0, dof=0)
        freedom_case.add_nodal_support(node=node_a, val=0, dof=1)
        freedom_case.add_nodal_support(node=node_c, val=0, dof=1)

        # add loads
        load_case = cases.LoadCase()
        load_case.add_nodal_load(node=node_b, val=self.pl, dof=1)

        # add analysis case
        analysis_case = cases.AnalysisCase(freedom_case=freedom_case,
                                           load_case=load_case)

        # linear static solver
        LinearStatic(analysis=analysis, analysis_cases=[analysis_case]).solve()

        # check displacements
        def analytical_disp_ab(x):
            factor = self.pl * b * x / 6 / self.elastic_modulus / self.ixx / self.length
            l0 = self.length

            return factor * (l0 * l0 - b * b - x * x)

        def analytical_disp_bc(x):
            l0 = self.length
            factor = self.pl * a * (
                l0 - x) / 6 / self.elastic_modulus / self.ixx / l0

            return factor * (2 * l0 * x - a * a - x * x)

        # get displacements
        displacements_ab = element_ab.get_displacements(21, analysis_case)
        displacements_bc = element_bc.get_displacements(21, analysis_case)

        # loop through each station
        for disp in displacements_ab:
            xi = disp[0]
            x = a * xi
            v = disp[2]

            # check displacements
            self.assertTrue(np.isclose(v, analytical_disp_ab(x), atol=1e-06))

        # loop through each station
        for disp in displacements_bc:
            xi = disp[0]
            x = b * xi + a
            v = disp[2]

            # check displacements
            self.assertTrue(np.isclose(v, analytical_disp_bc(x), atol=1e-06))

        # check max displacement
        if a > b:
            aa = a
            bb = b
            disps = displacements_ab
        else:
            aa = b
            bb = a
            disps = displacements_bc

        l0 = self.length
        v_max = (self.pl * aa * bb *
                 (aa + 2 * bb) * np.sqrt(3 * aa * (aa + 2 * bb))) / (
                     27 * self.elastic_modulus * self.ixx * l0)

        # check value
        self.assertTrue(
            np.isclose(abs(v_max), max(np.abs(disps[:, 2])), atol=1e-06))

        # check position of max displacement
        pos = np.sqrt((aa * (aa + 2 * bb)) / 3)
        if b > a:
            pos = self.length - pos
            x = 1 / b * (pos - a)
        else:
            x = pos / a

        self.assertTrue(
            np.isclose(x, disps[np.abs(disps[:, 2]).argmax(), 0], atol=1e-06))

        # check displacement at point load
        v_ab = self.pl * a * a * b * b / 3 / self.elastic_modulus / self.ixx / self.length
        self.assertTrue(np.isclose(v_ab, displacements_bc[0, 2], atol=1e-06))

        # check bending moments
        def analytical_bmd_ab(x):
            return self.pl * b * x / self.length

        def analytical_bmd_bc(x):
            x = self.length - x
            return self.pl * a * x / self.length

        # get bmd
        (xis_ab, bmd_ab) = element_ab.get_bmd(11, analysis_case)
        (xis_bc, bmd_bc) = element_bc.get_bmd(11, analysis_case)

        # loop through each station
        for (i, m) in enumerate(bmd_ab):
            xi = xis_ab[i]
            x = a * xi

            # check bending moment
            self.assertTrue(np.isclose(m, analytical_bmd_ab(x), atol=1e-06))

        # loop through each station
        for (i, m) in enumerate(bmd_bc):
            xi = xis_bc[i]
            x = a + b * xi

            # check bending moment
            self.assertTrue(np.isclose(m, analytical_bmd_bc(x), atol=1e-06))

        # check max bending moment
        m_max = self.pl * a * b / self.length

        # check value
        self.assertTrue(np.isclose(abs(m_max), max(np.abs(bmd_ab)),
                                   atol=1e-06))

        # check position
        self.assertTrue(
            np.isclose(1, xis_ab[np.abs(bmd_ab).argmax()], atol=1e-06))

        # check shear force
        def analytical_sfd_ab(x):
            return -self.pl * b / self.length

        def analytical_sfd_bc(x):
            return self.pl * a / self.length

        # get sfd
        (xis, sfd_ab) = element_ab.get_sfd(11, analysis_case)
        (xis, sfd_bc) = element_bc.get_sfd(11, analysis_case)

        # loop through each station
        for (i, sf) in enumerate(sfd_ab):
            xi = xis_ab[i]
            x = a * xi

            # check shear force
            self.assertTrue(np.isclose(sf, analytical_sfd_ab(x), atol=1e-06))

        # loop through each station
        for (i, sf) in enumerate(sfd_bc):
            xi = xis_bc[i]
            x = a + b * xi

            # check shear force
            self.assertTrue(np.isclose(sf, analytical_sfd_bc(x), atol=1e-06))
Exemplo n.º 5
0
    def test_fig7(self):
        """Simple Beam – Concentrated Load at Center"""

        # create 2d frame analysis object
        analysis = FrameAnalysis2D()

        # create section
        section = Section(ixx=self.ixx)

        # create nodes
        node_a = analysis.create_node(coords=[0])
        node_b = analysis.create_node(coords=[self.length * 0.5])
        node_c = analysis.create_node(coords=[self.length])

        # create beam elements
        element_ab = analysis.create_element(el_type='EB2-2D',
                                             nodes=[node_a, node_b],
                                             material=self.steel,
                                             section=section)
        element_bc = analysis.create_element(el_type='EB2-2D',
                                             nodes=[node_b, node_c],
                                             material=self.steel,
                                             section=section)

        # add supports
        freedom_case = cases.FreedomCase()
        freedom_case.add_nodal_support(node=node_a, val=0, dof=0)
        freedom_case.add_nodal_support(node=node_a, val=0, dof=1)
        freedom_case.add_nodal_support(node=node_c, val=0, dof=1)

        # add loads
        load_case = cases.LoadCase()
        load_case.add_nodal_load(node=node_b, val=self.pl, dof=1)

        # add analysis case
        analysis_case = cases.AnalysisCase(freedom_case=freedom_case,
                                           load_case=load_case)

        # linear static solver
        LinearStatic(analysis=analysis, analysis_cases=[analysis_case]).solve()

        # check displacements
        def analytical_disp_ab(x):
            factor = self.pl * x / 48 / self.elastic_modulus / self.ixx
            l0 = self.length

            return factor * (3 * l0 * l0 - 4 * x * x)

        def analytical_disp_bc(x):
            x = self.length - x

            factor = self.pl * x / 48 / self.elastic_modulus / self.ixx
            l0 = self.length

            return factor * (3 * l0 * l0 - 4 * x * x)

        # get displacements
        displacements_ab = element_ab.get_displacements(11, analysis_case)
        displacements_bc = element_bc.get_displacements(11, analysis_case)

        # loop through each station
        for disp in displacements_ab:
            xi = disp[0]
            x = self.length * 0.5 * xi
            v = disp[2]

            # check displacements
            self.assertTrue(np.isclose(v, analytical_disp_ab(x), atol=1e-06))

        # loop through each station
        for disp in displacements_bc:
            xi = disp[0]
            x = self.length * 0.5 + self.length * 0.5 * xi
            v = disp[2]

            # check displacements
            self.assertTrue(np.isclose(v, analytical_disp_bc(x), atol=1e-06))

        # check max displacement
        l0 = self.length
        v_max = self.pl * l0 * l0 * l0 / 48 / self.elastic_modulus / self.ixx

        # check value
        self.assertTrue(
            np.isclose(abs(v_max),
                       max(np.abs(displacements_ab[:, 2])),
                       atol=1e-06))

        # check position
        self.assertTrue(
            np.isclose(1,
                       displacements_ab[np.abs(displacements_ab[:,
                                                                2]).argmax(),
                                        0],
                       atol=1e-06))

        # check bending moments
        def analytical_bmd_ab(x):
            return self.pl * x / 2

        def analytical_bmd_bc(x):
            x = self.length - x
            return self.pl * x / 2

        # get bmd
        (xis_ab, bmd_ab) = element_ab.get_bmd(11, analysis_case)
        (xis_bc, bmd_bc) = element_bc.get_bmd(11, analysis_case)

        # loop through each station
        for (i, m) in enumerate(bmd_ab):
            xi = xis_ab[i]
            x = self.length * 0.5 * xi

            # check bending moment
            self.assertTrue(np.isclose(m, analytical_bmd_ab(x), atol=1e-06))

        # loop through each station
        for (i, m) in enumerate(bmd_bc):
            xi = xis_bc[i]
            x = self.length * 0.5 + self.length * 0.5 * xi

            # check bending moment
            self.assertTrue(np.isclose(m, analytical_bmd_bc(x), atol=1e-06))

        # check max bending moment
        l0 = self.length
        m_max = self.pl * l0 / 4

        # check value
        self.assertTrue(np.isclose(abs(m_max), max(np.abs(bmd_ab)),
                                   atol=1e-06))

        # check position
        self.assertTrue(
            np.isclose(1, xis_ab[np.abs(bmd_ab).argmax()], atol=1e-06))

        # check shear force
        def analytical_sfd_ab(x):
            return -self.pl / 2

        def analytical_sfd_bc(x):
            return self.pl / 2

        # get sfd
        (xis, sfd_ab) = element_ab.get_sfd(11, analysis_case)
        (xis, sfd_bc) = element_bc.get_sfd(11, analysis_case)

        # loop through each station
        for (i, sf) in enumerate(sfd_ab):
            xi = xis_ab[i]
            x = self.length * 0.5 * xi

            # check shear force
            self.assertTrue(np.isclose(sf, analytical_sfd_ab(x), atol=1e-06))

        # loop through each station
        for (i, sf) in enumerate(sfd_bc):
            xi = xis_bc[i]
            x = self.length * 0.5 + self.length * 0.5 * xi

            # check shear force
            self.assertTrue(np.isclose(sf, analytical_sfd_bc(x), atol=1e-06))
Exemplo n.º 6
0
    def test_fig4(self):
        """Simple Beam – Uniform Load Partially Distributed at Each End"""

        a = self.length * np.random.uniform(0.1, 0.4)
        c = self.length * np.random.uniform(0.1, 0.4)
        b = self.length - a - c
        q2 = -np.random.uniform(1, 10)

        # create 2d frame analysis object
        analysis = FrameAnalysis2D()

        # create section
        section = Section(ixx=self.ixx)

        # create nodes
        node_a = analysis.create_node(coords=[0])
        node_b = analysis.create_node(coords=[a])
        node_c = analysis.create_node(coords=[a + b])
        node_d = analysis.create_node(coords=[self.length])

        # create beam elements
        element_ab = analysis.create_element(el_type='EB2-2D',
                                             nodes=[node_a, node_b],
                                             material=self.steel,
                                             section=section)
        element_bc = analysis.create_element(el_type='EB2-2D',
                                             nodes=[node_b, node_c],
                                             material=self.steel,
                                             section=section)
        element_cd = analysis.create_element(el_type='EB2-2D',
                                             nodes=[node_c, node_d],
                                             material=self.steel,
                                             section=section)

        # add supports
        freedom_case = cases.FreedomCase()
        freedom_case.add_nodal_support(node=node_a, val=0, dof=0)
        sup1 = freedom_case.add_nodal_support(node=node_a, val=0, dof=1)
        sup2 = freedom_case.add_nodal_support(node=node_d, val=0, dof=1)

        # add loads
        load_case = cases.LoadCase()
        load_case.add_element_load(element_ab.generate_udl(q=self.q))
        load_case.add_element_load(element_cd.generate_udl(q=q2))

        # add analysis case
        analysis_case = cases.AnalysisCase(freedom_case=freedom_case,
                                           load_case=load_case)

        # linear static solver
        LinearStatic(analysis=analysis, analysis_cases=[analysis_case]).solve()

        # check reactions
        r1 = -sup1.get_reaction(analysis_case)
        r1_ana = (self.q * a *
                  (2 * self.length - a) + q2 * c * c) / (2 * self.length)
        r2 = -sup2.get_reaction(analysis_case)
        r2_ana = (q2 * c *
                  (2 * self.length - c) + self.q * a * a) / (2 * self.length)

        self.assertTrue(np.isclose(r1, r1_ana, atol=1e-06))
        self.assertTrue(np.isclose(r2, r2_ana, atol=1e-06))

        # check bending moments
        def analytical_bmd_ab(x):
            return r1 * x - self.q * 0.5 * x * x

        def analytical_bmd_bc(x):
            return r1 * x - self.q * a * 0.5 * (2 * x - a)

        def analytical_bmd_cd(x):
            return r2 * (self.length - x) - q2 * (self.length -
                                                  x) * (self.length - x) * 0.5

        # get bmds
        (xis_ab, bmd_ab) = element_ab.get_bmd(11, analysis_case)
        (xis_bc, bmd_bc) = element_bc.get_bmd(11, analysis_case)
        (xis_cd, bmd_cd) = element_cd.get_bmd(11, analysis_case)

        # element_ab - loop through each station
        for (i, m) in enumerate(bmd_ab):
            xi = xis_ab[i]
            x = a * xi

            # check bending moments
            self.assertTrue(np.isclose(m, analytical_bmd_ab(x), atol=1e-06))

        # element_bc - loop through each station
        for (i, m) in enumerate(bmd_bc):
            xi = xis_bc[i]
            x = b * xi + a

            # check bending moments
            self.assertTrue(np.isclose(m, analytical_bmd_bc(x), atol=1e-06))

        # element_cd - loop through each station
        for (i, m) in enumerate(bmd_cd):
            xi = xis_cd[i]
            x = c * xi + a + b

            # check bending moments
            self.assertTrue(np.isclose(m, analytical_bmd_cd(x), atol=1e-06))

        # check max bending moment
        if abs(r1) < abs(self.q * a):
            m_max = r1 * r1 / 2 / self.q
            pos = r1 / self.q
            x = pos / a

            # check value
            self.assertTrue(
                np.isclose(abs(m_max), max(np.abs(bmd_ab)), atol=1e-06))

            # check position
            self.assertTrue(
                np.isclose(x, xis_ab[np.abs(bmd_ab).argmax()], atol=1e-06))

        if abs(r2) < abs(q2 * c):
            m_max = r2 * r2 / 2 / q2
            pos = self.length - r2 / q2
            x = 1 / c * (pos - a - b)

            # check value
            self.assertTrue(
                np.isclose(abs(m_max), max(np.abs(bmd_cd)), atol=1e-06))

            # check position
            self.assertTrue(
                np.isclose(x, xis_cd[np.abs(bmd_cd).argmax()], atol=1e-06))

        # check shear force
        def analytical_sfd_ab(x):
            return -r1 + self.q * x

        def analytical_sfd_bc(x):
            return -r1 + self.q * a

        def analytical_sfd_cd(x):
            return r2 - q2 * (self.length - x)

        # get sfds
        (xis_ab, sfd_ab) = element_ab.get_sfd(11, analysis_case)
        (xis_bc, sfd_bc) = element_bc.get_sfd(11, analysis_case)
        (xis_cd, sfd_cd) = element_cd.get_sfd(11, analysis_case)

        # element_ab - loop through each station
        for (i, sf) in enumerate(sfd_ab):
            xi = xis_ab[i]
            x = a * xi

            # check shear forces
            self.assertTrue(np.isclose(sf, analytical_sfd_ab(x), atol=1e-06))

        # element_bc - loop through each station
        for (i, sf) in enumerate(sfd_bc):
            xi = xis_bc[i]
            x = b * xi + a

            # check shear forces
            self.assertTrue(np.isclose(sf, analytical_sfd_bc(x), atol=1e-06))

        # element_cd - loop through each station
        for (i, sf) in enumerate(sfd_cd):
            xi = xis_cd[i]
            x = c * xi + a + b

            # check shear forces
            self.assertTrue(np.isclose(sf, analytical_sfd_cd(x), atol=1e-06))
Exemplo n.º 7
0
    def test_fig3(self):
        """Simple Beam – Uniform Load Partially Distributed at One End"""

        a = self.length * np.random.uniform(0.1, 0.9)

        # create 2d frame analysis object
        analysis = FrameAnalysis2D()

        # create section
        section = Section(ixx=self.ixx)

        # create nodes
        node_a = analysis.create_node(coords=[0])
        node_b = analysis.create_node(coords=[a])
        node_c = analysis.create_node(coords=[self.length])

        # create beam elements
        element_ab = analysis.create_element(el_type='EB2-2D',
                                             nodes=[node_a, node_b],
                                             material=self.steel,
                                             section=section)
        element_bc = analysis.create_element(el_type='EB2-2D',
                                             nodes=[node_b, node_c],
                                             material=self.steel,
                                             section=section)

        # add supports
        freedom_case = cases.FreedomCase()
        freedom_case.add_nodal_support(node=node_a, val=0, dof=0)
        sup1 = freedom_case.add_nodal_support(node=node_a, val=0, dof=1)
        sup2 = freedom_case.add_nodal_support(node=node_c, val=0, dof=1)

        # add loads
        load_case = cases.LoadCase()
        load_case.add_element_load(element_ab.generate_udl(q=self.q))

        # add analysis case
        analysis_case = cases.AnalysisCase(freedom_case=freedom_case,
                                           load_case=load_case)

        # linear static solver
        LinearStatic(analysis=analysis, analysis_cases=[analysis_case]).solve()

        # check reactions
        r1 = -sup1.get_reaction(analysis_case)
        r2 = -sup2.get_reaction(analysis_case)

        self.assertTrue(
            np.isclose(r1,
                       self.q * a / 2 / self.length * (2 * self.length - a),
                       atol=1e-06))
        self.assertTrue(
            np.isclose(r2, self.q * a * a / 2 / self.length, atol=1e-06))

        # check displacements
        def analytical_disp_ab(x):
            l0 = self.length
            factor = self.q * x / 24 / self.elastic_modulus / self.ixx / l0

            return factor * (a * a * (2 * l0 - a) *
                             (2 * l0 - a) - 2 * a * x * x *
                             (2 * l0 - a) + l0 * x * x * x)

        def analytical_disp_bc(x):
            l0 = self.length
            factor = self.q * a * a * (
                l0 - x) / 24 / self.elastic_modulus / self.ixx / l0

            return factor * (4 * x * l0 - 2 * x * x - a * a)

        # get displacements
        displacements_ab = element_ab.get_displacements(11, analysis_case)
        displacements_bc = element_bc.get_displacements(11, analysis_case)

        # loop through each station
        for disp in displacements_ab:
            xi = disp[0]
            x = a * xi
            v = disp[2]

            # check displacements
            self.assertTrue(np.isclose(v, analytical_disp_ab(x), atol=1e-06))

        # loop through each station
        for disp in displacements_bc:
            xi = disp[0]
            x = (self.length - a) * xi + a
            v = disp[2]

            # check displacements
            self.assertTrue(np.isclose(v, analytical_disp_bc(x), atol=1e-06))

        # check bending moments
        def analytical_bmd_ab(x):
            return r1 * x - self.q * x * x / 2

        def analytical_bmd_bc(x):
            return r2 * (self.length - x)

        # get bmds
        (xis_ab, bmd_ab) = element_ab.get_bmd(11, analysis_case)
        (xis_bc, bmd_bc) = element_bc.get_bmd(11, analysis_case)

        # element_ab - loop through each station
        for (i, m) in enumerate(bmd_ab):
            xi = xis_ab[i]
            x = a * xi

            # check bending moments
            self.assertTrue(np.isclose(m, analytical_bmd_ab(x), atol=1e-06))

        # element_bc - loop through each station
        for (i, m) in enumerate(bmd_bc):
            xi = xis_bc[i]
            x = (self.length - a) * xi + a

            # check bending moments
            self.assertTrue(np.isclose(m, analytical_bmd_bc(x), atol=1e-06))

        # check max bending moment
        m_max = r1 * r1 / 2 / self.q
        pos = r1 / self.q
        x = pos / a

        # check value
        self.assertTrue(np.isclose(abs(m_max), max(np.abs(bmd_ab)),
                                   atol=1e-06))

        # check position
        self.assertTrue(
            np.isclose(x, xis_ab[np.abs(bmd_ab).argmax()], atol=1e-06))

        # check shear force
        def analytical_sfd_ab(x):
            return -r1 + self.q * x

        def analytical_sfd_bc(x):
            return r2

        # get sfds
        (xis_ab, sfd_ab) = element_ab.get_sfd(11, analysis_case)
        (xis_bc, sfd_bc) = element_bc.get_sfd(11, analysis_case)

        # element_ab - loop through each station
        for (i, sf) in enumerate(sfd_ab):
            xi = xis_ab[i]
            x = a * xi

            # check shear forces
            self.assertTrue(np.isclose(sf, analytical_sfd_ab(x), atol=1e-06))

        # element_bc - loop through each station
        for (i, sf) in enumerate(sfd_bc):
            xi = xis_bc[i]
            x = (self.length - a) * xi + a

            # check shear forces
            self.assertTrue(np.isclose(sf, analytical_sfd_bc(x), atol=1e-06))
Exemplo n.º 8
0
    def test_fig1(self):
        """Simple Beam – Uniformly Distributed Load"""

        # create 2d frame analysis object
        analysis = FrameAnalysis2D()

        # create section
        section = Section(ixx=self.ixx)

        # create nodes
        node_a = analysis.create_node(coords=[0])
        node_b = analysis.create_node(coords=[self.length])

        # create beam elements
        element = analysis.create_element(el_type='EB2-2D',
                                          nodes=[node_a, node_b],
                                          material=self.steel,
                                          section=section)

        # add supports
        freedom_case = cases.FreedomCase()
        freedom_case.add_nodal_support(node=node_a, val=0, dof=0)
        freedom_case.add_nodal_support(node=node_a, val=0, dof=1)
        freedom_case.add_nodal_support(node=node_b, val=0, dof=1)

        # add loads
        load_case = cases.LoadCase()
        load_case.add_element_load(element.generate_udl(q=self.q))

        # add analysis case
        analysis_case = cases.AnalysisCase(freedom_case=freedom_case,
                                           load_case=load_case)

        # linear static solver
        LinearStatic(analysis=analysis, analysis_cases=[analysis_case]).solve()

        # check displacements
        def analytical_disp(x):
            factor = self.q * x / 24 / self.elastic_modulus / self.ixx
            l0 = self.length

            return factor * (l0 * l0 * l0 - 2 * l0 * x * x + x * x * x)

        # get displacements
        displacements = element.get_displacements(11, analysis_case)

        # loop through each station
        for disp in displacements:
            xi = disp[0]
            x = self.length * xi
            v = disp[2]

            # check displacements
            self.assertTrue(np.isclose(v, analytical_disp(x), atol=1e-06))

        # check max displacement
        l0 = self.length
        v_max = 5 * self.q * l0 * l0 * l0 * l0 / 384 / self.elastic_modulus / self.ixx

        # check value
        self.assertTrue(
            np.isclose(abs(v_max), max(np.abs(displacements[:, 2]))))

        # check position
        self.assertTrue(
            np.isclose(0.5,
                       displacements[np.abs(displacements[:, 2]).argmax(), 0],
                       atol=1e-06))

        # check bending moments
        def analytical_bmd(x):
            return self.q * x / 2 * (self.length - x)

        # get bmd
        (xis, bmd) = element.get_bmd(11, analysis_case)

        # loop through each station
        for (i, m) in enumerate(bmd):
            xi = xis[i]
            x = self.length * xi

            # check bending moment
            self.assertTrue(np.isclose(m, analytical_bmd(x), atol=1e-06))

        # check max bending moment
        l0 = self.length
        m_max = self.q * l0 * l0 / 8

        # check value
        self.assertTrue(np.isclose(abs(m_max), max(np.abs(bmd)), atol=1e-06))

        # check position
        self.assertTrue(np.isclose(0.5, xis[np.abs(bmd).argmax()], atol=1e-06))

        # check shear force
        def analytical_sfd(x):
            return self.q * (x - self.length / 2)

        # get sfd
        (xis, sfd) = element.get_sfd(11, analysis_case)

        # loop through each station
        for (i, sf) in enumerate(sfd):
            xi = xis[i]
            x = self.length * xi

            # check shear force
            self.assertTrue(np.isclose(sf, analytical_sfd(x), atol=1e-06))
Exemplo n.º 9
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    def __init__(self, buildProp, stiff_red = 0):
        """Inits the class, setting up calculation model
        :param buildProp: full scale properties of the building
        :type buildProp: :class:`~modelProp.buildProp`
        """
        # Setting up calculation model
        # ------------
        # preprocessor
        # ---------
        # constants & lists
        self.L = buildProp.H                # length of the beam [m]
        self.n = buildProp.nz               # no of nodes [-]
        self.z = buildProp.z_lev            # coordinates [m]

        # everything starts with the analysis object
        self.analysis = FrameAnalysis2D()

        ### NODES
        # -------------
        # Coordinates for geometrie
        self.node_coords_geom = []
        for i in range(buildProp.nF+1):
            node = i * buildProp.hL
            self.node_coords_geom.append(node)
        
        # Sort from bottom to top of building, 
        # must be done for inserting loads at right order!
        self.node_coords_geom = sorted(self.node_coords_geom, reverse=True)

        self.node_coords_load = []
        for i in range(buildProp.nz):
            node = round(buildProp.z_lev[i], 1)
            self.node_coords_load.append(node)
        
        # Sort from bottom to top of building, 
        # must be done for inserting loads at right order!
        self.node_coords_load = sorted(self.node_coords_load, reverse=True)

        # Merge / sort / remove duplicate nodes
        self.node_coords = sorted(list(set(self.node_coords_geom + self.node_coords_load)), reverse=True)
            
        # Insert nodes 
        self.nodes = []
        for i in range(len(self.node_coords)):
            node = self.analysis.create_node(coords=[0, self.node_coords[i]])
            self.nodes.append(node)
        
        ## BEAMS
        # -------------
        self.beams = []

        # Counter for stiffness reduction
        j = -1

        # Determine coords. where reductions shall be made
        hModule = buildProp.H / buildProp.nM

        # Reset wall mass to 0
        buildProp.M_DL_CWall  = 0
        buildProp.recalcBuildMass()
        
        # Remark: Reverse node order here, going from bottom to tip
        for i in range(1, len(self.nodes)): #! n+1 (support, tip)
            # Get z-coord of current node
            z_i = self.nodes[-i].y

            # Raise counter if next module for reduction is reached
            if z_i % hModule == 0:
                j = j + 1

            # Recalculate dist. mass
            # For concrete walls: mue_walls = A_walls [m2] * 2.5 [t/m3]
            if buildProp.structSys == 'concreteCore':
                mue_DL_CWall= ((buildProp.bCore + buildProp.t)**2 - (buildProp.bCore - buildProp.t)**2) * 2.5 
                mue_SLS_Tot = buildProp.M_SLS_Tot / buildProp.H + (1 - stiff_red) ** j * mue_DL_CWall

                # Add mass of walls to total mass            
                buildProp.M_DL_CWall += (1 - stiff_red) ** j * mue_DL_CWall * (self.nodes[-i-1].y - self.nodes[-i].y) 
            
            else:
                raise('No structural system specified')

            ## MATERIAL
            # -------------
            self.material = Material("Dummy", buildProp.E, 0.3, mue_SLS_Tot, colour='w')

            ## SECTION
            # -------------
            if buildProp.structSys == 'concreteCore':
                I = buildProp.I * (1 - stiff_red) ** j
            
            else:
                raise('No structural system specified')

            self.section = Section(area=1, ixx=I)

            # Add beams
            beam = self.analysis.create_element(
                   el_type='EB2-2D', nodes=[self.nodes[-i], self.nodes[-i-1]], material=self.material, section=self.section)
            self.beams.append(beam)

            # Print stiffness distribution for control
            # print('at z = ' + str(self.nodes[-i].y))
            # print('I = ' + str(beam.section.ixx))
        
        # Recalculate the building mass, now with walls
        buildProp.recalcBuildMass()
            
        # boundary conditions are objects
        self.freedom_case = cases.FreedomCase()
        self.freedom_case.add_nodal_support(node=self.nodes[-1], val=0, dof=0)
        self.freedom_case.add_nodal_support(node=self.nodes[-1], val=0, dof=1)
        self.freedom_case.add_nodal_support(node=self.nodes[-1], val=0, dof=5)
Exemplo n.º 10
0
    def calcMeanDeflection(self, fname, F_p_j, H_fs, E, I, nz, z_lev_fs):
        # Setting up static calculation
        # ------------
        # preprocessor
        # ---------

        # constants & lists
        L = H_fs                        # length of the beam [m]
        n = nz                          # no of nodes [-]
        z = np.append(L, z_lev_fs)      # coordinates [m], append top of building
        z = np.append(z, 0)             # coordinates [m], append support node

        # everything starts with the analysis object
        analysis = FrameAnalysis2D()

        # materials and sections are objects
        mat_dummy = Material("Dummy", E, 0.3, 1, colour='w')
        section = Section(area=1, ixx=I)

        # nodes are objects
        nodes = []
        for i in range(0,n+2): #! n+2 (support, tip)
            node = analysis.create_node(coords=[0, z[i]])
            nodes.append(node)

        # and so are beams!
        beams = []
        for i in range(0,n+1): #! n+1 (support, tip)
            beam = analysis.create_element(
                el_type='EB2-2D', nodes=[nodes[i], nodes[i+1]], material=mat_dummy, section=section)
            beams.append(beam)

        # boundary conditions are objects
        freedom_case = cases.FreedomCase()
        freedom_case.add_nodal_support(node=nodes[-1], val=0, dof=0)
        freedom_case.add_nodal_support(node=nodes[-1], val=0, dof=1)
        freedom_case.add_nodal_support(node=nodes[-1], val=0, dof=5)

        # so are loads!
        load_case = cases.LoadCase()

        for i in range(n):
            F_p = np.mean(F_p_j[i])        #[in KN]
            load_case.add_nodal_load(node=nodes[i+1], val=F_p , dof=0) # i+1 (support, tip)

        # an analysis case relates a support case to a load case
        analysis_case = cases.AnalysisCase(freedom_case=freedom_case, load_case=load_case)

        # ------
        # solver
        # ------

        # you can easily change the solver settings
        settings = SolverSettings()
        settings.linear_static.time_info = False

        # the linear static solver is an object and acts on the analysis object
        solver = LinearStatic(analysis=analysis, analysis_cases=[analysis_case], solver_settings=settings)
        solver.solve()

        # ----
        # post
        # ----
        # there are plenty of post processing options!
        # analysis.post.plot_geom(analysis_case=analysis_case)
        # analysis.post.plot_geom(analysis_case=analysis_case, deformed=True, def_scale=1e2)
        # analysis.post.plot_frame_forces(analysis_case=analysis_case, shear=True)
        # analysis.post.plot_frame_forces(analysis_case=analysis_case, moment=True)
        # analysis.post.plot_reactions(analysis_case=analysis_case)
        
        # Support reactions, to check bending moment for validation
        for support in analysis_case.freedom_case.items:
            if support.dof in [5]:
                reaction = support.get_reaction(analysis_case=analysis_case)

        # read out deformation at top 
        self.delta_p_mean = nodes[0].get_displacements(analysis_case)[0]

        writeToTxt(fname, "delta_p_mean:    " + '{:02.3f}'.format(self.delta_p_mean))
Exemplo n.º 11
0
    def test_example5_7(self):
        l_a = np.sqrt(8000 * 8000 - 3000 * 3000)

        # create materials
        steel = Steel()

        # create 2d frame analysis object
        analysis = FrameAnalysis2D()

        section = Section(area=6e3, ixx=200e6)

        # create nodes
        node_a = analysis.create_node(coords=[0])
        node_b = analysis.create_node(coords=[l_a, 3000])
        node_c = analysis.create_node(coords=[l_a + 8000, 3000])

        # create beam elements
        element_ab = analysis.create_element(
            el_type='EB2-2D', nodes=[node_a, node_b], material=steel, section=section
        )
        element_bc = analysis.create_element(
            el_type='EB2-2D', nodes=[node_b, node_c], material=steel, section=section
        )

        # add supports
        freedom_case = cases.FreedomCase()
        sup_a = [0, 0, 0]
        sup_a[0] = freedom_case.add_nodal_support(node=node_a, val=0, dof=0)
        sup_a[1] = freedom_case.add_nodal_support(node=node_a, val=0, dof=1)
        sup_a[2] = freedom_case.add_nodal_support(node=node_a, val=0, dof=5)
        sup_c = [0, 0, 0]
        sup_c[0] = freedom_case.add_nodal_support(node=node_c, val=0, dof=0)
        sup_c[1] = freedom_case.add_nodal_support(node=node_c, val=0, dof=1)
        sup_c[2] = freedom_case.add_nodal_support(node=node_c, val=0, dof=5)

        # add loads
        load_case = cases.LoadCase()
        load_case.add_nodal_load(node=node_b, val=50e3 * 3000 / 8000, dof=0)
        load_case.add_nodal_load(node=node_b, val=-50e3 * l_a / 8000, dof=1)
        load_case.add_element_load(element_bc.generate_udl(q=-4))

        # add analysis case
        analysis_case = cases.AnalysisCase(freedom_case=freedom_case, load_case=load_case)

        # linear static solver
        LinearStatic(analysis=analysis, analysis_cases=[analysis_case]).solve()

        # check node displacement
        disp_b = node_b.get_displacements(analysis_case)
        u_b = disp_b[0]
        v_b = disp_b[1]
        r_b = disp_b[5]

        self.assertEqual(np.around(u_b, 4), 0.9950)
        self.assertEqual(np.around(v_b, 3), -4.982)
        self.assertEqual(np.around(r_b, 6), -0.000534)

        # check reactions
        ra_x = sup_a[0].get_reaction(analysis_case=analysis_case)
        ra_y = sup_a[1].get_reaction(analysis_case=analysis_case)
        ra_m = sup_a[2].get_reaction(analysis_case=analysis_case)
        rc_x = sup_c[0].get_reaction(analysis_case=analysis_case)
        rc_y = sup_c[1].get_reaction(analysis_case=analysis_case)
        rc_m = sup_c[2].get_reaction(analysis_case=analysis_case)

        self.assertEqual(np.around(ra_x/1e3, 1), 130.5)
        self.assertEqual(np.around(ra_y/1e3, 1), 55.7)
        self.assertEqual(np.around(ra_m/1e6, 2), 13.37)
        self.assertEqual(np.around(rc_x/1e3, 1), -149.3)
        self.assertEqual(np.around(rc_y/1e3, 1), 22.7)
        self.assertEqual(np.around(rc_m/1e6, 2), -45.36)
Exemplo n.º 12
0
    def test_example5_6(self):
        # create materials
        steel = Steel()

        # create 2d frame analysis object
        analysis = FrameAnalysis2D()

        section_ab = Section(area=6e3, ixx=200e6)
        section_bc = Section(area=4e3, ixx=50e6)

        # create nodes
        node_a = analysis.create_node(coords=[0])
        node_b = analysis.create_node(coords=[8000])
        node_p = analysis.create_node(coords=[10000])
        node_c = analysis.create_node(coords=[13000])

        # create beam elements
        element_ab = analysis.create_element(
            el_type='EB2-2D', nodes=[node_a, node_b], material=steel, section=section_ab
        )
        element_bp = analysis.create_element(
            el_type='EB2-2D', nodes=[node_b, node_p], material=steel, section=section_bc
        )
        element_pc = analysis.create_element(
            el_type='EB2-2D', nodes=[node_p, node_c], material=steel, section=section_bc
        )

        # add supports
        freedom_case = cases.FreedomCase()
        sup_a = freedom_case.add_nodal_support(node=node_a, val=0, dof=1)
        sup_b = freedom_case.add_nodal_support(node=node_b, val=0, dof=1)
        sup_c = [0, 0, 0]
        sup_c[0] = freedom_case.add_nodal_support(node=node_c, val=0, dof=0)
        sup_c[1] = freedom_case.add_nodal_support(node=node_c, val=0, dof=1)
        sup_c[2] = freedom_case.add_nodal_support(node=node_c, val=0, dof=5)

        # add loads
        load_case = cases.LoadCase()
        load_case.add_element_load(element_ab.generate_udl(q=-2))
        load_case.add_nodal_load(node=node_p, val=-20e3, dof=1)

        # add analysis case
        analysis_case = cases.AnalysisCase(freedom_case=freedom_case, load_case=load_case)

        # linear static solver
        LinearStatic(analysis=analysis, analysis_cases=[analysis_case]).solve()

        # check node displacement
        disp_a = node_a.get_displacements(analysis_case)
        disp_b = node_b.get_displacements(analysis_case)
        r_a = disp_a[5]
        r_b = disp_b[5]

        self.assertEqual(np.around(r_a, 7), -5.681e-4)
        self.assertEqual(np.around(r_b, 7), 0.696e-4)

        # check reactions
        ra_y = sup_a.get_reaction(analysis_case=analysis_case)
        rb_y = sup_b.get_reaction(analysis_case=analysis_case)
        rc_y = sup_c[1].get_reaction(analysis_case=analysis_case)
        rc_m = sup_c[2].get_reaction(analysis_case=analysis_case)

        self.assertEqual(np.around(ra_y/1e3, 2), 6.13)
        self.assertEqual(np.around(rb_y/1e3, 2), 23.00)
        self.assertEqual(np.around(rc_y/1e3, 2), 6.87)
        self.assertEqual(np.around(rc_m/1e6, 2), -9.32)
Exemplo n.º 13
0
    def test_example2_2(self):
        # create 2d frame analysis object
        analysis = FrameAnalysis2D()

        # create sections
        steel = Steel()
        section1 = Section(area=5000)
        section2 = Section(area=3000)

        # create nodes
        a = analysis.create_node(coords=[0, 0])
        b = analysis.create_node(coords=[3000, 3000])
        c = analysis.create_node(coords=[3000, -3000])
        d = analysis.create_node(coords=[-3000/np.tan(np.pi/6), 3000])
        e = analysis.create_node(coords=[-3000/np.tan(np.pi/6), -3000])

        # create truss elements
        el1 = analysis.create_element(
            el_type='Bar2-2D', nodes=[e, a], material=steel, section=section1)
        el2 = analysis.create_element(
            el_type='Bar2-2D', nodes=[d, a], material=steel, section=section1)
        el3 = analysis.create_element(
            el_type='Bar2-2D', nodes=[b, a], material=steel, section=section2)
        el4 = analysis.create_element(
            el_type='Bar2-2D', nodes=[c, a], material=steel, section=section2)

        # add supports
        freedom_case = cases.FreedomCase()
        freedom_case.add_nodal_support(node=b, val=0, dof=0)
        freedom_case.add_nodal_support(node=b, val=0, dof=1)
        freedom_case.add_nodal_support(node=c, val=0, dof=0)
        freedom_case.add_nodal_support(node=c, val=0, dof=1)
        freedom_case.add_nodal_support(node=d, val=0, dof=0)
        freedom_case.add_nodal_support(node=d, val=0, dof=1)
        freedom_case.add_nodal_support(node=e, val=0, dof=0)
        freedom_case.add_nodal_support(node=e, val=0, dof=1)

        # add loads
        load_case = cases.LoadCase()
        load_case.add_nodal_load(node=a, val=1000e3, dof=0)

        # add analysis case
        analysis_case = cases.AnalysisCase(freedom_case=freedom_case, load_case=load_case)

        # linear static solver
        LinearStatic(analysis=analysis, analysis_cases=[analysis_case]).solve()

        # check node displacement
        disp_a = a.get_displacements(analysis_case)
        u = disp_a[0]
        v = disp_a[1]

        self.assertEqual(np.around(u, 2), 2.55)
        self.assertEqual(np.around(v, 2), 0)

        # check axial forces
        (_, n1) = el1.get_afd(n=1, analysis_case=analysis_case)
        (_, n2) = el2.get_afd(n=1, analysis_case=analysis_case)
        (_, n3) = el3.get_afd(n=1, analysis_case=analysis_case)
        (_, n4) = el4.get_afd(n=1, analysis_case=analysis_case)

        self.assertEqual(np.around(n1/1e3, 1), 368.8)
        self.assertEqual(np.around(n2/1e3, 1), 368.8)
        self.assertEqual(np.around(n3/1e3, 1), -255.5)
        self.assertEqual(np.around(n4/1e3, 1), -255.5)
Exemplo n.º 14
0
    def calcPeakDeflection(self, fname, F_r_std, H_fs, E, I, mue, nz, z_lev_fs):
        # Setting up dynamic calculation
        # ------------
        # preprocessor
        # ---------

        # constants & lists
        L = H_fs                        # length of the beam [m]
        n = nz                          # no of nodes [-]
        z = np.append(L, z_lev_fs)      # coordinates [m], append top of building
        z = np.append(z, 0)             # coordinates [m], append support node
        num_modes = 1

        # everything starts with the analysis object
        analysis = FrameAnalysis2D()

        # materials and sections are objects
        mat_dummy = Material("Dummy", E, 0.3, mue, colour='w')
        section = Section(area=1, ixx=I)

        # nodes are objects
        nodes = []
        for i in range(0,n+2): #! n+2 (support, tip)
            node = analysis.create_node(coords=[0, z[i]])
            nodes.append(node)

        # and so are beams!
        beams = []
        for i in range(0,n+1): #! n+1 (support, tip)
            beam = analysis.create_element(
                el_type='EB2-2D', nodes=[nodes[i], nodes[i+1]], material=mat_dummy, section=section)
            beams.append(beam)

        # boundary conditions are objects
        freedom_case = cases.FreedomCase()
        freedom_case.add_nodal_support(node=nodes[-1], val=0, dof=0)
        freedom_case.add_nodal_support(node=nodes[-1], val=0, dof=1)
        freedom_case.add_nodal_support(node=nodes[-1], val=0, dof=5)

        # add analysis case
        analysis_case = cases.AnalysisCase(freedom_case=freedom_case, load_case=cases.LoadCase())

        # ----------------
        # frequency solver
        # ----------------

        settings = SolverSettings()
        settings.natural_frequency.time_info = True
        settings.natural_frequency.num_modes = num_modes

        solver = NaturalFrequency(
            analysis=analysis, analysis_cases=[analysis_case], solver_settings=settings)

        # Manual solver, see feastruct/solvers/naturalfrequency.py, in order
        # to extract mass/stiffness-matrix and eigenvectors      
        # assign the global degree of freedom numbers
        solver.assign_dofs()

        # Get the global stiffness / mass matrix
        (K, Kg) = solver.assemble_stiff_matrix()
        M = solver.assemble_mass_matrix()

        # apply the boundary conditions
        K_mod = solver.remove_constrained_dofs(K=K, analysis_case=analysis_case)
        M_mod = solver.remove_constrained_dofs(K=M, analysis_case=analysis_case)

        # Solve for the eigenvalues
        (w, v) = solver.solve_eigenvalue(A=K_mod, M=M_mod, eigen_settings=settings.natural_frequency)

        # compute natural frequencies in Hz
        f = np.sqrt(w) / 2 / np.pi

        # Normalize Eigenvector
        v = v / v[0] * L

        # # Get only dof ux
        # u = np.zeros(n+1)
        # for i in range(0, n+1):
        #     j = i * 3
        #     u[i] = v[j]

        # Get generalized quantities
        K_mod = K_mod.toarray()
        K_gen = np.dot(np.dot(v.T, K_mod), v)

        M_mod = M_mod.toarray()
        M_gen = np.dot(np.dot(v.T, M_mod), v)  

        # To check, compute 
        # f_k = np.sqrt(K_gen/M_gen) / 2 / np.pi  
        # print(f/f_k)
        # K_gen = 3 * E * I /(L^3) / L
        K_gen = K_gen[0][0] 

        # Calculate peak displacement
        delta_r_std = v[0][0] / K_gen * F_r_std 
        g_peak = response.calcPeakFactor(self, 3600, f[0])      # Peak Factor   
        

        delta_r_max = g_peak * delta_r_std        

        writeToTxt(fname, "delta_r_std:     " + '{:02.3f}'.format(delta_r_std))
        writeToTxt(fname, "g_peak:          " + '{:02.3f}'.format(g_peak))
        writeToTxt(fname, "delta_r_max:     " + '{:02.3f}'.format(delta_r_max))
Exemplo n.º 15
0
def preprocessor(length, depth, panels, freq):
    w = 10  # load per unit length [N/mm]
    dx = length / panels  # length of a truss panel

    # create 2d frame analysis object
    analysis = FrameAnalysis2D()

    # create materials and sections
    steel = Steel()
    section_deck = Section(area=3230, ixx=23.6e6)  # 200UB25
    section_vertical = Section(area=3000, ixx=3.91e6)  # 100x9 SHS
    section_diagonal = Section(area=314)  # 20 dia rod
    section_tie = Section(area=1018)  # 36 dia rod

    # create deck nodes
    nodes_deck = []

    for i in range(panels + 1):
        nodes_deck.append(analysis.create_node(coords=[i * dx]))

    # create tie nodes - first node coincides with first deck node
    nodes_tie = [nodes_deck[0]]

    for i in range(panels - 1):
        # fit parabola
        x = (i + 1) * dx
        y = 4 * depth / length / length * x * x - 4 * depth / length * x

        nodes_tie.append(analysis.create_node(coords=[x, y]))

    # last node coincides with last deck node
    nodes_tie.append(nodes_deck[-1])

    # create deck (beam) elements
    elements_deck = []

    for i in range(panels):
        elements_deck.append(
            analysis.create_element(el_type='EB2-2D',
                                    nodes=[nodes_deck[i], nodes_deck[i + 1]],
                                    material=steel,
                                    section=section_deck))

    # create tie (bar) elements
    elements_tie = []

    for i in range(panels):
        elements_tie.append(
            analysis.create_element(el_type='Bar2-2D',
                                    nodes=[nodes_tie[i], nodes_tie[i + 1]],
                                    material=steel,
                                    section=section_tie))

    # create vertical (beam) elements
    elements_vertical = []

    for i in range(panels - 1):
        elements_vertical.append(
            analysis.create_element(
                el_type='EB2-2D',
                nodes=[nodes_deck[i + 1], nodes_tie[i + 1]],
                material=steel,
                section=section_vertical))

    # create diagonal (bar) elements
    elements_diaongal = []

    for i in range(panels - 2):
        elements_diaongal.append(
            analysis.create_element(
                el_type='Bar2-2D',
                nodes=[nodes_deck[i + 1], nodes_tie[i + 2]],
                material=steel,
                section=section_diagonal))

        elements_diaongal.append(
            analysis.create_element(
                el_type='Bar2-2D',
                nodes=[nodes_deck[i + 2], nodes_tie[i + 1]],
                material=steel,
                section=section_diagonal))

    # add supports
    freedom_case = cases.FreedomCase()
    freedom_case.add_nodal_support(node=nodes_deck[0], val=0, dof=0)
    freedom_case.add_nodal_support(node=nodes_deck[0], val=0, dof=1)
    freedom_case.add_nodal_support(node=nodes_deck[-1], val=0, dof=1)

    # add loads
    load_case = cases.LoadCase()

    # if frequency analysis, don't bother adding load
    if not freq:
        for el in elements_deck:
            load_case.add_element_load(el.generate_udl(q=-w))

    # add analysis case
    analysis_case = cases.AnalysisCase(freedom_case=freedom_case,
                                       load_case=load_case)

    return (analysis, analysis_case)
Exemplo n.º 16
0
    def test_example4_15(self):
        # create materials
        steel = Material(name='steel_imperial', elastic_modulus=29e3, poissons_ratio=0.3, rho=0)

        # create 2d frame analysis object
        analysis = FrameAnalysis2D()
        analysis.post.n_subdiv = 3

        beam = Section(ixx=128.5)

        # create nodes
        n = 20  # number of beam segments (must be an even number to ensure point load in centre)
        L = 300  # length
        k_L = 15  # spring length
        k = 1.5  # foundation modulus
        dx = L/n
        spring = Section(area=k*dx*k_L/29e3)
        beam_nodes = []
        spring_nodes = []

        # beam nodes
        for i in range(n+1):
            beam_nodes.append(analysis.create_node(coords=[i*L/n]))

        # spring nodes
        for i in range(n-1):
            spring_nodes.append(analysis.create_node(coords=[(i+1)*L/n, -k_L]))

        # create elements
        beam_elements = []
        spring_elements = []

        # create beam elements
        for i in range(n):
            beam_elements.append(analysis.create_element(
                el_type='EB2-2D', nodes=[beam_nodes[i], beam_nodes[i+1]], material=steel,
                section=beam
            ))

        # create spring elements
        for i in range(n-1):
            spring_elements.append(analysis.create_element(
                el_type='Bar2-2D', nodes=[beam_nodes[i+1], spring_nodes[i]], material=steel,
                section=spring
            ))

        # add supports
        freedom_case = cases.FreedomCase()
        spring_supports_x = []
        spring_supports_y = []

        # add end supports
        freedom_case.add_nodal_support(node=beam_nodes[0], val=0, dof=0)
        freedom_case.add_nodal_support(node=beam_nodes[0], val=0, dof=1)
        freedom_case.add_nodal_support(node=beam_nodes[-1], val=0, dof=1)

        # add spring support
        for spring_node in spring_nodes:
            spring_supports_x.append(freedom_case.add_nodal_support(
                node=spring_node, val=0, dof=0))
            spring_supports_y.append(freedom_case.add_nodal_support(
                node=spring_node, val=0, dof=1))

        # add loads
        load_case = cases.LoadCase()
        load_case.add_nodal_load(node=beam_nodes[int(n/2)], val=-40, dof=1)

        # add analysis case
        analysis_case = cases.AnalysisCase(freedom_case=freedom_case, load_case=load_case)

        # linear static solver
        LinearStatic(analysis=analysis, analysis_cases=[analysis_case]).solve()

        # check node displacement
        disp = beam_nodes[int(n/2)].get_displacements(analysis_case)
        v_p = disp[1]

        self.assertEqual(np.around(v_p, 3), -0.238)

        # check bending moments
        (_, m) = beam_elements[int(n/2)].get_bmd(n=2, analysis_case=analysis_case)
        self.assertEqual(np.around(m[0], 0), -547)
Exemplo n.º 17
0
from feastruct.solvers.naturalfrequency import NaturalFrequency
from feastruct.solvers.feasolve import SolverSettings

# ------------
# preprocessor
# ------------

# constants & lists
n = 20  # number of elements (make even to ensure point load in centre)
L = 10000  # length of arch
h = 3000  # height of arch
nodes = []  # list holding the node objects
elements = []  # list holding the element objects

# create 2d frame analysis object
analysis = FrameAnalysis2D()

# create materials and sections
steel = Steel()
section = Section(area=3230, ixx=23.6e6)

# create nodes
for i in range(n + 1):
    x = i * L / n
    y = h * np.sin(np.pi * x / L)
    nodes.append(analysis.create_node(coords=[x, y]))

# create beam elements
for i in range(n):
    elements.append(
        analysis.create_element(el_type='EB2-2D',
Exemplo n.º 18
0
    def test_example3_3(self):
        nodes = []  # list holding the node objects
        elements = []  # list holding the element objects

        # create 2d frame analysis object
        analysis = FrameAnalysis2D()

        # create sections
        steel = Steel()
        section1 = Section(area=15e3)
        section2 = Section(area=18e3)
        section3 = Section(area=20e3)

        # create nodes
        nodes.append(analysis.create_node(coords=[0, 0]))
        nodes.append(analysis.create_node(coords=[4000/np.tan(np.pi/6), 4000]))
        nodes.append(analysis.create_node(coords=[4000/np.tan(np.pi/6) + 4000, 0]))
        nodes.append(analysis.create_node(coords=[0, 4000]))

        # create truss elements
        elements.append(analysis.create_element(
            el_type='Bar2-2D', nodes=[nodes[0], nodes[1]], material=steel, section=section1
        ))
        elements.append(analysis.create_element(
            el_type='Bar2-2D', nodes=[nodes[1], nodes[2]], material=steel, section=section3
        ))
        elements.append(analysis.create_element(
            el_type='Bar2-2D', nodes=[nodes[0], nodes[2]], material=steel, section=section2
        ))
        elements.append(analysis.create_element(
            el_type='Bar2-2D', nodes=[nodes[3], nodes[1]], material=steel, section=section3
        ))

        # add supports
        freedom_case = cases.FreedomCase()
        sup1 = freedom_case.add_nodal_support(node=nodes[0], val=0, dof=0)
        sup2 = freedom_case.add_nodal_support(node=nodes[0], val=0, dof=1)
        sup3 = freedom_case.add_nodal_support(node=nodes[2], val=0, dof=1)
        sup4 = freedom_case.add_nodal_support(node=nodes[3], val=0, dof=0)
        sup5 = freedom_case.add_nodal_support(node=nodes[3], val=0, dof=1)

        # add loads
        load_case = cases.LoadCase()
        load_case.add_nodal_load(node=nodes[1], val=500e3*np.cos(2*np.pi/9), dof=0)
        load_case.add_nodal_load(node=nodes[1], val=500e3*np.sin(2*np.pi/9), dof=1)

        # add analysis case
        analysis_case = cases.AnalysisCase(freedom_case=freedom_case, load_case=load_case)

        # linear static solver
        LinearStatic(analysis=analysis, analysis_cases=[analysis_case]).solve()

        # check node displacement
        disp_a = nodes[1].get_displacements(analysis_case)
        disp_b = nodes[2].get_displacements(analysis_case)

        u_a = disp_a[0]
        v_a = disp_a[1]
        u_b = disp_b[0]

        self.assertEqual(np.around(u_a, 2), 0.38)
        self.assertEqual(np.around(v_a, 2), 1.23)
        self.assertEqual(np.around(u_b, 2), -0.44)

        # check reactions
        rc_x = sup1.get_reaction(analysis_case=analysis_case)
        rc_y = sup2.get_reaction(analysis_case=analysis_case)
        rb_y = sup3.get_reaction(analysis_case=analysis_case)
        rd_x = sup4.get_reaction(analysis_case=analysis_case)
        rd_y = sup5.get_reaction(analysis_case=analysis_case)

        self.assertEqual(np.around(rc_x/1e3, 1), -162.5)
        self.assertEqual(np.around(rc_y/1e3, 1), -177.1)
        self.assertEqual(np.around(rb_y/1e3, 1), -144.3)
        self.assertEqual(np.around(rd_x/1e3, 1), -220.5)
        self.assertEqual(np.around(rd_y/1e3, 1), 0)