The lower jaw AB [Purple 1] and the upper jaw-handle AD [Yellow 2] exert vertical clamping forces on the object at R. The hand squeezes the upper jaw- handle AD [2] and the lower handle BC [Orane 4] with forces F. (Member CD [Red 3] acts as if it is pinned at D, but, in a real vise-grips, its position is actually adjustable.) The clamping force, R, depends on the geometry and on the squeezing force F applied to the handles. Determine the proportionality between the clamping force, R, and the squeezing force F for the dimensions given. d3 Variable Value dl 65 mm d2 155 mm d3 48 mm d4 110 mm d5 26 mm R- 2.27 Values for dimensions on the figure are given in the following table. Note the figure may not be to scale. di X F ds

The lower jaw AB [Purple 1] and the upper jaw-handle AD [Yellow 2] exert vertical clamping forces on the object at R. The hand squeezes the upper jaw- handle AD [2] and the lower handle BC [Orane 4] with forces F. (Member CD [Red 3] acts as if it is pinned at D, but, in a real vise-grips, its position is actually adjustable.) The clamping force, R, depends on the geometry and on the squeezing force F applied to the handles. Determine the proportionality between the clamping force, R, and the squeezing force F for the dimensions given. d3 Variable Value dl 65 mm d2 155 mm d3 48 mm d4 110 mm d5 26 mm R- 2.27 Values for dimensions on the figure are given in the following table. Note the figure may not be to scale. di X F ds

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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Chemical and Phase Equilibrium

Phase diagrams or equilibrium phase diagrams are the graphical representations that show the phase transformations of the constituting elements with respect to the pressure, temperature, and compositions. The diagrams show the conditions that limit the different phases, namely solid, liquid, and gas. The diagram can also be utilized to verify the relations between the state variables. Most of the phase diagrams are temperature-pressure phase diagrams, with the variable parameter as the composition. Usually other variables such as solubility and pressure parameters are not indicated in the phase diagram. For a one-component system (unary phase diagram), the phase diagram is generally a function of temperature and pressure as the state variables, or temperature and volume. However, for a binary system (two-phase) having two components, the phase diagram is a function of temperature and composition as the state variables only. Coexisting of the different phases of the constituting elements is indicated in the phase diagram. A ternary phase diagram can be characterized by consisting of three phases in equilibrium.

Question

The lower jaw AB [Purple 1] and the upper jaw-handle AD [Yellow 2] exert
vertical clamping forces on the object at R. The hand squeezes the upper jaw-
handle AD [2] and the lower handle BC [Orane 4] with forces F. (Member CD
[Red 3] acts as if it is pinned at D, but, in a real vise-grips, its position is
actually adjustable.) The clamping force, R, depends on the geometry and on
the squeezing force F applied to the handles. Determine the proportionality
between the clamping force, R, and the squeezing force F for the dimensions
given.
R
d3
Variable Value
di
65 mm
d2
155 mm
d3
48 mm
d4
110 mm
d5
26 mm
R= 2.27
B
d₁
d₁
X F
dz
Values for dimensions on the figure are given in the following table. Note the
figure may not be to scale.
D.
ds

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