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 thelower 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, itsposition is actually adjustable.) The clamping force, R,depends on the geometry and on the squeezing force Fapplied to the handles. Determine the proportionalitybetween the clamping force, R, and the squeezing force F forthe dimensions given.d3d4R1Bd12d2D...d5F4FValues for dimensions on the figure are given in the followingtable. Note the figure may not be to scale.VariableValued165 mmd2156 mmd350 mm45d4d5113 mm30 mmR =F

Answered: Image /qna-images/answer/398325a6-8ab8-436b-9610-f8042fcddfa4.jpg

Answered: The lower jaw AB [Purple 1] and the…

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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As indicated, three blocks were suspended in the air by massless strings that passed through massless and fixed pulleys. m (middle mass) = 5.00 [kg]. When the system reached equilibrium, it was discovered that a = 60.0° and y = 30.0 Draw the free body diagrams of block A, B, and C. MA 1. Write down Newton's 2nd law along the x and y directions for all three blocks. You must have six equations total. 2. What is the magnitude of mA? 3. What is the magnitude of mc? 4. What would be the magnitude of mA and mc when a = y? MB mc
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
The block A and attached beam have a combined mass of F [m]kg and are confined to move along the [0]° guide under the action of the [F]-N force. The [L]-m long uniform beam has a mass of mB] kg and is welded to block A at point B (i.e. the beam is cantilevered at point B). Friction in the guide is negligible. The dimensions of block A are unknown. A B L (a) Calculate the acceleration a (magnitude and direction) of block A and the attached beam. Hint: Treat the block and beam as one lumped mass. (b) Calculate the bending moment reaction M (magnitude and direction) on the beam at point B. Hint: Draw a FBD of the beam only. Values m, = 54.5 55 F 754 L= 1.21 тв 24.1 -- -
Determine mass m, in pulley system shown in Figure -1. Also determine forces in points A & B. mass m1; A force in A ; : force in B; b. mass in [kg] forces in [N] m. m2 I. B
can you find the solution and free body diagram
2 Need help, please show all work, steps, units and round to 3 significant figures. Thank you
Please Draw The Freebody On a sheet of paper Only and Solve via Handwritten Only. Here I am facing difficulty in Typed based solution. [Reaction(N) and angle(°)]
can you please find the solution. need freebody diagram accurate calculation of coefficient of friction, accurate calculations of forces fmax and N
A 10 kg block rests on an 30-degree inclined plane. The block is attached to a bucket by pulley system depicted below. The mass in the bucket is gradually increased by the addition of sand. At some point, the bucket will accumulate enough sand to set the block in motion. The coefficients of static and kinetic friction are 0.60 and 0.50 respectively. Determine the mass of sand in [kg], including the bucket, needed to start the block moving. Find the blocks acceleration, in [m/s2] up the plane? The existing solution in the libarary is wrong. I know the correct answer to the first question is 20.39kg because half the weight of the sand is absorbed by the pulley system. Now what is the answer to the second question on the acceleration?
Determine the absolute value of the force at point O in [N] ? m = 30 kg F=422 N w = 8 rad/s
Don't Use Chat GPT Will Upvote And Give Handwritten Solution Please
a. b. The normal force which the path exerts on a particle is always on: The Normal direction The Transverse direction The Tangent direction The Radial direction It is time to draw, match the axis you will draw on the free body diagram or the kinetic diagram with the force or acceleration on this specific axis: Y axis Normal axis Tangent axis Radial axis Transverse axis N [Choose] [Choose] The normal force between the surface and the motorcycle The weight of the motorcycle The frictional force between the surface and the motorcycle The transverse acceleration (a theta) The radial acceleration (ar) [Choose] [Choose ] [Choose ]

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