A falling-cylinder viscometer consists of a long vertical cylindrical tube (of radius R), capped at both ends, and a solid cylindrical slug (of radius kR). The system is sketched in Fig. 1. The slug is equipped with fins so that its axis coincides with that of the tube. One can observe the rate of descent of the slug in the cylindrical container when the latter is filled with fluid. The objective of this exercise is to find an equation that gives the viscosity of the fluid (assumed to be incompressible and Newtonian) in terms of the terminal velocity Vof the slug and of the various geometric quantities shown in Fig. 1. Cylindrical slug descends with speed V through the liquid Liquid fills the cylindrical cavity Figure 1: Sketch of the falling-cylinder viscometer. Assume that the flow is laminar and neglect the entrance and end effects that are present when the fluid enters and leaves the gap between the tube and the slug. Therefore, assume that the only nonzero component of the fluid velocity vector is v, and that in space this depends solely on r, where r denotes the radial coordinate of a cylindrical coordinate system. Answer all the questions in the reported order. a) From the point of view of an observer integral with the laboratory where the viscometer is placed, is this fluid dynamic problem steady-state or not? Justify your answer.

Please state clearly the answer for a

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A falling-cylinder viscometer consists of a long vertical cylindrical tube (of radius R), capped at both ends, and a solid cylindrical slug (of radius kR). The system is sketched in Fig. 1. The slug is equipped with fins so that its axis coincides with that of the tube. One can observe the rate of descent of the slug in the cylindrical container when the latter is filled with fluid. The objective of this exercise is to find an equation that gives the viscosity of the fluid (assumed to be incompressible and Newtonian) in terms of the terminal velocity Vof the slug and of the various geometric quantities shown in Fig. 1. KKR- Cylindrical slug descends with speed V through the liquid Liquid fills the cylindrical cavity y Figure 1: Sketch of the falling-cylinder viscometer. Assume that the flow is laminar and neglect the entrance and end effects that are present when the fluid enters and leaves the gap between the tube and the slug. Therefore, assume that the only nonzero component of the fluid velocity vector is a cylindrical coordinate system. Vz and that in space this depends solely on r, where r denotes the radial coordinate of Answer all the questions in the reported order. а) From the point of view of an observer integral with the laboratory where the viscometer is placed, is this fluid dynamic problem steady-state or not? Justify your answer.