Пример #1
0
    def test_positive_friction(self):
        chamfered_qc = bearing.chamfer_positive_friction(
            self.gef.df.qc.values, self.gef.df.depth.values)

        # pile tip level
        ptl = nap_to_depth(self.gef.zid, -13.5)
        tipping_point = nap_to_depth(self.gef.zid, -2.1)

        idx_ptl = np.argmin(np.abs(self.gef.df.depth.values - ptl))
        idx_tp = np.argmin(np.abs(self.gef.df.depth.values - tipping_point))
        s = slice(idx_tp, idx_ptl)

        f = bearing.positive_friction(self.gef.df.depth.values[s],
                                      chamfered_qc[s], 0.25 * 4, 0.01)

        # d-foundation result is 1375, we have 1371. Small difference due to chamfering method. We chamfer better ;)
        deviation = abs(1 - 1375 / (f.sum() * 1000))
        self.assertTrue(deviation < 1e-2)
        self.assertEqual(f.sum(), 1.3710468170000003)

        if SHOW_PLOTS:
            # show chamfer line
            fig = self.gef.plot(show=False)
            fig.axes[0].plot(chamfered_qc[s],
                             self.gef.df.depth[s],
                             color="red")
            fig.axes[0].hlines(ptl, 0, chamfered_qc.max())
            fig.axes[0].hlines(tipping_point, 0, chamfered_qc.max())
            plt.show()
Пример #2
0
    def positive_friction(
        self, positive_friction_range=None, agg=True, conservative=False
    ):
        """
        Determine shaft friction Rs.

        Parameters
        ----------
        positive_friction_range : np.array[float]
            Length == 2.
            Start and end depth of positive friction.

        agg : bool
            Influences return type.
                True: aggregates the friction values in total friction.
                False: Return friction values per cpt layer.

        conservative : bool

        Returns
        -------
        out : Union[float, np.array[float]]
            unit [MPa]
            See agg parameter
        """
        if positive_friction_range:
            self.positive_friction_slice = det_slice(
                positive_friction_range, self.merged_soil_properties.depth.values
            )
        self.chamfered_qc = bearing.chamfer_positive_friction(
            self.merged_soil_properties.qc.values, self.cpt.df.depth.values
        )[self.positive_friction_slice]
        positive_friction = bearing.positive_friction(
            depth=self.merged_soil_properties.depth.values[
                self.positive_friction_slice
            ],
            chamfered_qc=self.chamfered_qc,
            circum=self.circum,
            alpha_s=self.alpha_s,
        )
        self.rs = positive_friction.sum()
        if agg:
            return self.rs
        return positive_friction
Пример #3
0
negative_friction = (bearing.negative_friction(
    depth=df.depth.values[negative_friction_slice],
    grain_pressure=df.grain_pressure.values[negative_friction_slice],
    circum=circum,
    phi=df.phi[negative_friction_slice],
    gamma_m=1,
)).sum() * 1000

positive_friction_slice = slice(idx_tp, idx_ptl)

chamfered_qc = bearing.chamfer_positive_friction(
    df.qc.values, gef.df.depth.values)[positive_friction_slice]

rs = (bearing.positive_friction(
    depth=df.depth.values[positive_friction_slice],
    chamfered_qc=chamfered_qc,
    circum=circum,
    alpha_s=0.01,
)).sum() * 1000

rb = (bearing.compute_pile_tip_resistance(
    ptl=ptl,
    qc=df.qc.values,
    depth=df.depth.values,
    d_eq=1.13 * pile_width,
    alpha=0.7,
    beta=1,
    s=1,
    area=pile_width**2,
)) * 1000

print(rb, rs, negative_friction)