Verdrehung (Feminine)

Description: Torsion is a load state that causes twisting $\vartheta $ due to the action of a torsional moment MT. A torsional moment is created, for example, by the action of a transverse Force and a lever arm d. The deformation depends on the cross-sectional geometry of the component being twisted. Components with a round cross-section, for example, do not exhibit any warping. The twisting per unit of length $\frac{d\vartheta }{dx}$ can be calculated based on the active torsional moment MT , the material-dependent shear modulus G, the cross-sectional geometry and the resultant torsional moment of inertia IT. The following generally applies to torsions: $\frac{d\vartheta }{dx}=\frac{{{M}_{T}}}{G\cdot {{I}_{T}}}$. In the case of a component with a circular cross-section, the torsional moment of inertia ${{I}_{T}}$ is equivalent to the polar Area moment of inertia ${{I}_{P}}$. The largest shear stresses $\tau $ are found at the edges of this component. The maximum Shear stress is calculated as follows: ${{\tau }_{\max }}=\frac{{{M}_{T}}}{{{R}_{T}}}$ . The torsional Resistance moment ${{R}_{T}}$ represents the component's cross-sectional geometry.

Description: The deformation depends on the twisted component's cross-sectional geometry. The worker can reach everything within this zone without having to twist his or her torso. To remove and then refit the spring clip, twist it in or out of position and lock it in place.

Description: Diagonal struts stabilise the frame construction against twisting and support the Roller Conveyors. This relationship between work of deformation and displacement/twisting applies only to Hooke's materials. Torsion is a load state that causes twisting ? due to the action of a torsional moment MT.