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Consider the spur gears shown in Figure P3.15, where
Figure P3.15
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SYSTEM DYNAMICS LL+CONNECT
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- For the double slider mechanism shown in the following figure, the crank OA rotates at a uniform speed of 100 rad/s CW. we need to find the required torque for the crank, if two forces act at sliders B and C as shown in the figure. (P = 2KN, Q = 1KN). OA = 30 cm, AB = AC = 100 cm. mB = mC = 1 Kg. Neglect other links weights. The velocity of slip of slider B in m/s2 = Answer 1 Choose... The velocity of slip of slider C in m/s2 = Answer 2 Choose... The acceleration of slip of slider B in m/s2 = Answer 3 Choose... The acceleration of slip of slider C in m/s2 = Answer 4 Choose... The magnitude of required torque for the crank in N.m = Answer 5 Choose...arrow_forwardConsider a disc of mass, M with radius 0.5 m on a slope with angle 45 degrees to the horizontal. It has a good grip on the slope and does not slip. The disc is constructed so that its mass per unit area, ρ(r) = r1/2 kg m−2, with r being the radial distance in metres from the axis of the disc. What is the equation describing the linear acceleration of the centre of mass of the disc down the slope in terms of the angular acceleration of the disc.arrow_forwardTwo cylinders rolling in the opposite direction has a speed ratio of 3. If the diameter of driver is 10 inches, find the center distance between cylinders. A. 15 in B. 10 in C. 25 in. D. 20 in. Please solve the Problem elaborately. Your solution will be use as reference for my studies. Thank you so much your work will be appreciated much!arrow_forward
- For the double slider mechanism shown in the following figure, the crank OA rotates at a uniform speed of 24 rad/s ccw. we need to find the required torque for the crank, if two forces act at sliders B and C as shown in the figure. (P = 4 kN, Q = 2 kN). OA = 10 cm, AB = AC = 70 cm. mg = mc = 5 Kg. Neglect other links weights. (5) (2) (3) B (4) (6) C 45° X. The velocity of slip of slider B in m/s² = Choose.. + The velocity of slip of slider C in m/s? = Choose... + The acceleration of slip of slider B in m/s² = Choose.. + The acceleration of slip of slider C in m/s² = Choose.. + The magnitude of required torque for the crank in N.m = Choose..arrow_forward1. Using Lagrangian Mechanics, find the acceleration of the double Atwood machine assuming the pulley is masslessarrow_forwardA motor is attached to a pulley of radius 10 cm and mass 1 kg. A belt passes through the pulley that connects to a hollow sphere with a radius of 40 cm and a mass of 2 kg (see figure below). If the final speed of the first round, the angular speed of the SPHERE is 3πrad/s:a) What is the final energy consumption of the motor? b) If the torque is constant, what is the magnitude of the motor's torque? that there is no friction in the axes of the sphere and that all energy consumed by the motor is transformed into work.arrow_forward
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