A 0.87-kg air cart is attached to a spring and allowed to oscillate. (10.0 cm)cos((2.00 s-4)t...
Problem 13.29 5 of 12 A 0.93-kg air cart is attached to a spring and allowed to oscillate. Part A If the displacement of the air cart from equilibrium is (10.0 cm)cos(2.00 s-1)t+m], find the maximum kinetic energy of the cart. Express your answer using two significant figures. Kmax Submit Request Answer ? Part B Find the maximum force exerted on it by the spring Express your answer using two significant figures. Fmax Submit Request Answer
A 0.76-kg air cart is attached to a spring and allowed to oscillate. Part A If the displacement of the air cart from equilibrium is x=(10.0cm)cos[(2.00s−1)t+π], find the maximum kinetic energy of the cart in J. Find the maximum force exerted on it by the spring in N.
A 0.502 kg air cart is attached to a spring and allowed to oscillate. The displacement of the air cart from equilibrium is given by x = 11.2 cm·cos(1.88t + π), where t is in seconds. Calculate the maximum kinetic energy of the cart.
Review Correct A small wooden box is connected to a spring, and is allowed to oscillate horizontally on a flat surface. The box has mass 170 g, and the spring has spring constant 2.7 N/m The box moves with a velocity of 21 cm/s when zo =-5.2 cm ▼ Part C At the point where the box's acceleration is maximum, what is the box's position? Express your answer to two significant figures and include the appropriate units. cm Submit Previous...
A 220-g object attached to a spring oscillates on a friction amplitude of 29.0 cm. horizontal table with a frequency of 4.00 Hz and an 8 1) Calculate the maximum potential energy of the system. vour 0 answer to three significant figures.) J Submit 2) Calculate the displacement of the object when the potential energy is one-half of the maximum. (Express your answer to three significant figures.) cm Submit 3) Calculate the potential energy when the displacement is 10.0 cm....
Constants PartA A 2.00-kg, frictionless block is attached to an ideal spring with force constant 300 N/m. Att0 the block has velocity -4.00 m/s and displacement +0.200 m Find (a) the amplitude and (b) the phase angle SubmitR Request Answer Part B rad Submit Request Answer Part C Write an equation for the position as a function of time. Assume (t) in meters and t in seconds. a (t)- Submit F Request Answer
An air-track cart with mass mi = 0.23 kg and initial speed up = 0.95 m/s collides with and sticks to a second cart that is at rest initially. Part A If the mass of the second cart is m2 = 0.46 kg, how much kinetic energy is lost as a result of the collision? Express your answer to two significant figures and include appropriate units. μΑ ? Value Units Submit Request Answer
Constants A 2.00 kg , horizontal, uniform tray is attached to a vertical ideal spring of force constant 195 N/m and a 265 g metal ball is in the tray. The spring is below the tray, so it can oscillate up-and-down. The tray is then pushed down 17.0 cm below its equilibrium point (call this point A) and released from rest. Part A How high above point A will the tray be when the metal ball leaves the tray? (Hint:...
A 2.00-kg, frictionless block is attached to an ideal spring with force constant 300 N/m Att-0 the block has velocity -4.00 m/s and displacement +0.200 m. Correct Significant Figures Feedback: Your answer .382 m was either rounded differently or used a different number of significant figures than required for this part. ?: 1.02 rad Correct Significant Figures Feedback: Your answer 1.023 rad was either rounded differently or used a different number of significant figures than required for this part. Part...
An object with mass 3.9 kg is executing simple harmonic motoon, attached to a spring with spring constant 250 N/m. When the object is 0.018 m from its equilibrium position, it is moving with a speed of 0.50 m/s. A) Calculate the amplitude of the motion B) Calculate the maximum speed attained by the object Thank you! An object with mass 3.9 kg is executing simple harmonic motion, attached to a spring with spring constant 250 N/m. When the object...