test-bench-nass-flexible-jo.../matlab/bench_dimensioning.m

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%% Clear Workspace and Close figures
clear; close all; clc;
%% Intialize Laplace variable
s = zpk('s');
% Flexible joint Geometry
% The flexible joint used for the Nano-Hexapod is shown in Figure [[fig:flexible_joint_geometry]].
% Its bending stiffness is foreseen to be $k_{R_y}\approx 5\,\frac{Nm}{rad}$ and its stroke $\theta_{y,\text{max}}\approx 25\,mrad$.
% #+name: fig:flexible_joint_geometry
% #+caption: Geometry of the flexible joint
% [[file:figs/flexible_joint_geometry.png]]
% The height between the flexible point (center of the joint) and the point where external forces are applied is $h = 20\,mm$.
% Let's define the parameters on Matlab.
kRx = 5; % Bending Stiffness [Nm/rad]
Rxmax = 25e-3; % Bending Stroke [rad]
h = 20e-3; % Height [m]
% Required external applied force
% The bending $\theta_y$ of the flexible joint due to the force $F_x$ is:
% \begin{equation}
% \theta_y = \frac{M_y}{k_{R_y}} = \frac{F_x h}{k_{R_y}}
% \end{equation}
% Therefore, the applied force to test the full range of the flexible joint is:
% \begin{equation}
% F_{x,\text{max}} = \frac{k_{R_y} \theta_{y,\text{max}}}{h}
% \end{equation}
Fxmax = kRx*Rxmax/h; % Force to induce maximum stroke [N]
% And we obtain:
sprintf('\\begin{equation} F_{x,max} = %.1f\\, [N] \\end{equation}', Fxmax)
% Required actuator stroke and sensors range
% The flexible joint is designed to allow a bending motion of $\pm 25\,mrad$.
% The corresponding stroke at the location of the force sensor is:
% \[ d_{x,\text{max}} = h \tan(R_{x,\text{max}}) \]
dxmax = h*tan(Rxmax);
sprintf('\\begin{equation} d_{max} = %.1f\\, [mm] \\end{equation}', 1e3*dxmax)