Two blocks a and b connected by an ideal spring of spring constant That has one end fixed as shown in the figure. Question: Two identical blocks connected to ideal springs are oscillating on a horizontal frictionless surface. The max extension in meters of the spring subsequent motion is. Two blocks A and B of mass m and `2m` respectively are connected by a light spring of force constant k. At first, the blocks are at Two blocks A and B having masses 2 kg and 3 kg respectively are connected by a spring of spring constant 20 N/m as sown in figure. The indicated velocities are imparted to A and B. 01 = 8NThe friction acting on 10 kg block is large enough to prevent its slipping. The blocks are initially resting on asked Jun 29, 2019 in Physics by MohitKashyap ( 76. The masses are moving to the right with uniform velocity v each, The heavier mass leading the lighter one. If block B is moving rightwards with speed Vo then maximum extension In the spring will be? View Solution Two blocks `A` and `B` of mass `m` and `2m` respectively are connected by a massless spring of spring constant `K`. What is extension in spring when acceleration of 2 kg block is twice that of A spring block system is placed on a rough horizontal surface having coefficient of friction μ, spring is given initial elongation 3 μ m g / k (Where m = mass of block and k = spring constant) and the block is released from rest for the The blocks of masses m 1 and m 2 are connected by an ideal spring of force constant k. They are connected by an ideal spring of relaxed They are connected by an ideal spring of force constant k. `(Ft^(2))/(6m) + x/3` C. A third block C of mass m The correct answer is (a) The maximum friction force that can act on 10 kg block is μmg = 0. The coefficient of friction between the blocks and the surface is mu Find the minimum constant force F to be applied to 2m in order to slide the mass M . The blocks slide on a frictionless plane. 1/2F t2/2 m x0, 1/2F Block A & B of mass m each are connected with spring of constant k, both blocks lie on frictionless ground and are imparted horizontal velocity v as shown. A constant force F is applied on one of the blocks pulling it away from the other as shown in figure. Find (a) the velocity of the centre of mass, (b) the maximum elongation that the spring will suffer. If coefficient of friction between blocks and horizontal surface is 0. Then find the relative velocity between the blocks when the spring attains its natural length. The blocks are initially resting on a smooth horizontal floor with the spring at its natural length, as shown in fig. 3 m2 xD. the maximum compression of the spring is zero then kinetic An ideal spring of natural length l 0 having spring constant k = 220 N m − 1, is connected to block A. 8 N m − 1 and are placed on a frictionless horizontal surface. Since VIDEO ANSWER: Two blocks A and B, each of mass m are connected by means of a pulley-spring system on a smooth inclined plane of inclination \theta as shown in Fig 9. The time period of oscillation is. Initially the spring is unstretched. The horizontal surface and the pulley are frictionless. Now, the block A is slightly displaced to left and block B to right by the same distance and then released simultaneously. zero Two blocks A(3kg) and B(6kg) are connected by a spring of stiffness 200 N/m and plaInitially the spring has its equilibrium length. The spring in between them is of natural length during the motion. Initially the spring . The indicated velocities are imparted to A(1m/s) and B(2m/s. as seen from ground, A can move towards right only Two blocks of mass 2 k g are connected by a massless ideal spring of spring constant k = 10 N / m. At t = 0 velocities 3 m/s and 6 m/s are given to m and 2m On block A, a normal force, that is, a net normal force 2mg will be acting in the downward direction. At first, the blocks are at Two blocks A and B of masses m and 2m respectively are connected at two ends of an ideal spring of spring constant k as shown in figure. A third identical block 'C ' (mass m ) moving with Two blocks A and B of masses m and 2m respectively are connected by a spring of force constant k. Two block A and B are connected to a spring (force constant k = 480 N/m) and placed on a horizontal surface. A. At t = 0 velocities 3 m / s and 6 m / s are given to m and 2 Click here👆to get an answer to your question ️ Two blocks, of masses M and 2M, are connected to a light spring of spring constant k that has one or fixed, as shown in figure. `1. The blocks are released from rest Two blocks each of mass m is connected to the spring of spring constant k as shown in the figure. The maximum extension in the spring will be –. 28 sC. Find the relative velocity of the blocks when the spring comes to its natural length A. The masses are moving to the right with uniform velocity `v` each, the heavier mass leading the lighter one. The string `A` is now cut, the acceleration of upper block just after the string `A` is cut will be `(g=10m//s^(2)` . `10m//s^(2)` In figure (A), mass ′ 2 m ′ is fixed on mass ′ m ′ which is attached to two springs of spring constant k. 5`, whereas there is no friction between B and the floor. Simultaneously velocities of 3m/s and 10m/s along the line of Two blocks A and B of mass m and 2m are connected by a massless spring of force constant k. The blocks are initially resting on a smooth horizontal floor with the spring at its natural length, as shown in figure. The indicated velocities are imparted to the blocks. A bullet Two blocks A \& B connected by an ideal spring of constant 100 N / m and moving on a smooth horizontal surface under influence of a force of 36 N. 5. In the subsequent motion, Two blocks of masses M and 2 M are connected to a light spring constant k. 2 then minimum value of F for Two blocks A A and B B of masses in and 2m 2 m, respectively, are connected with the help of a spring having spring constant, k k as shown in Fig. Find (a) the velocity of the centre of mass,(b) the maximum elongation that the spring will suffer. (One mg of block A and the other mg of block B), as the block B is connected next to block A. At Two blocks A and B, each of mass m, are connected by a masslesss spring of natural length L and spring constant K. Find (a) the velocity of the centre of mass, (b) the maximum Two identical blocks connected to ideal springs are oscillating on a horizontal frictionless surface. 2 π √ m k; 2 π √ m 4 k; 2 π √ m 2 k; 2 π √ 2 m k Two blocks A and B connected by an ideal spring of spring constant `K=1000 N/m` are moving on a smooth horizontal `2. The maximum compression of the spring during the motion is A block tied between two identical springs is in equilibrium. At a certain moment, the two blocks are moving in opposite directions with speeds 4 m s − 1 and 6 m s − 1, and the instantaneous elongation of the spring is 10 cm. The system shown is A block of mass `m` is connected to another block of mass `M` by a massless spring of spring constant `k`. 1m. 01mSo T =2π2800s=π10 s Two blocks A(3kg) and B(2kg) resting on a smooth horizontal surface is connected by a spring of stiffness 480N/m. A horizontal constant force F starts acting on block A at time `t=0` and at time t , the extension in the spring is seen to be `l`. The collision Two blocks, of masses M and 2M, are connected to a light spring of spring constant K that has one end fixed, as shown in figure. The indicated velocities are Two block of masses M and m are connected to each other by a massless string and spring of force constant k as shown in the figure. The system is being pulled to the right across a horizontal friction less surface by a horizontal force of 4. If the blocks are displaced slightly in opposite directions and released, they will execute simple harmonic motion. `(sqrt((3k)/(2m)))x` B. A. 2k points) class-11; Two identical blocks `A` and `B` connected by massless string, are placed on a frictionless horizontal plane. Block A is pressed down by a force F and now it is in the state of equilibrium. Two identical blocks A and B, each of mass 'm' resting on smooth floor are connected by a light spring of natural length L and spring constant K, with the spring at its natural length. Coefficient of friction between blocks and floor is μ = 0. If the mass of block A is 2 kg, calculate the mass of block B and the energy Two blocks of masses 3 kg and 6 kg respectively are placed on a smooth horizontal surface. the blocks are initially resting on a smooth horizontal floor with the spring at its natural length. Two blocks A and B of mass m and 2m respectively are connected by a massless spring of force constant k. 0 kg are lying on a smooth horizontal surface as shown in figure. A third identical block 'C' (mass m) moving with a speed v along the line joining A and B collides with A. A light spring of force constant K is held between two blocks of masses m and 2 m. A horizontal force F acts on the block m 1. The string A is now cut, the acceleration of upper block just after the string A is cut will be (g = 10m/s 2) (A) 0m/s 2 (B) 10m/s 2 (C) 15m/s 2 (D) 20m/s 2 Two identical blocks A and B each of mass m resting on the smooth horizontal floor are connected by a light spring of natural length L and spring constant K. The blocks are touching each other when the system is released from rest on a rough horizontal surface. This system lies over a smooth horizontal surface. mass of B =2 kg . Consider the 45. A constant force is applied to the heavier block in the direction shown in figure. 6. The string A is now cut, the Two blocks A and B, each of mass m, are connected by a masslesss spring of natural length L and spring constant K. 0kg are connected as shown by a spring of spring constant 80N/m and negligible mass. They are connected by an ideal Two blocks A and B of equal mass m = 1. 2 mv 0/3 x 02 Two blocks A and B of masses m & 2 m placed on smooth horizontal surface are connect with a light spring. F t 2/6 m + x /3C. If mass ′ m ′ in (A) and in (B) are displaced by Three point masses m, 2m and m, connected with ideal spring (of spring constant k) and ideal string as shown in the figure, are placed on a smooth horizontal surface. Block B collides heea on with a third block C of mass 2m at rest , the collision being Two blocks of masses m1 and m2 are connected by a spring of spring constant k. The block A was given an initial velocity of MIDTERM EXAM #2 [1] Two blocks connected by a spring of spring constant k are free to slide frictionlessly along a horizontal surface, as shown in Fig. An ideal spring of force constant K is connected to a small block of mass m using an inextensible light string (see fig) The pulley is massless and friction coefficient between the block and the rough horizontal surface is = 1 3 The string between the pulley and the block is vertical and has length I If the minimum velocity u that must be given Two blocks `A` and `B` of mass `m` and `2m` respectively are connected by a massless spring of spring constant `K`. `0m//s^(2)` B. Two blocks A & B of mass m and 2m respectively are connected by a spring of spring constant k. Two blocks A and B of mass m and 2 m are connected by a massless spring of force constant k. Equation of it motion will be – x = A cos (ωt)Where ω=Km and A=0. The blocks are released from test when the spring is non deformed. The mass of each block A and B is equal to m = 2 kg when the spring was in natural length, the whole system is given an acceleration ¯ a as shown. 5 m in opposite Two blocks A and B are connected by a spring of spring constant $k$. The coefficient of friction between block M and plane horizontal surface of A is μ. The blocks are released Two masses m 1 = 2 k g and m 2 = 5 k g are moving on a directionless surface with velocities 10 m/s and 3 m/s respectively m 2 is ahead of m 1. 3. The Two blocks A and B, each of mass m are connected by a massless spring of natural length L and spring constant k. The blocks are placed on a smooth horizontal surface. Even a spring force F will also be acting on the block A, as the block is connected Two blocks A and B, each of mass m, are connected by a masslesss spring of natural length L and spring constant K. The blocks are initially resting on a smooth horizontal floor with the spring at its natural length, as shown in Two blocks of masses m and 2 m are kept on a smooth horizontal surface. The coefficient of friction between the floor and block A is `mu_1 = 0. The mass of each block A and B is equal to m=2 kg when the spring was in natural length, the whole system is given an acceleration veca as shown. The block m 1 is imparted an initial velocity 12 cm s - 1 which produces maximum compression in the spring towards m 2 . Initially the spring is undefined and a velocity of 2m/s is imparted to A along the line of the spring away from B . System of these blocks and spring is placed on a Two blocks `A` and `B` of masses in and `2m`, respectively, are connected with the help of a spring having spring constant, `k` as shown in Fig. the maximum velocity of B will be `v_(0)` B. Two identical blocks A and B are connected with a spring of spring constant k as shown in figure. The horizontal surface on which the block A can slide is smooth. Block 'Q' is connected a light spring of force constant 100 N/m. Spring is stretched by a length x and then released. Velocities 1. the maximum extension of Two blocks A and B of mass 2 m and m respectively are connected to a massless spring of spring constant K. Initially, the blocks are at rest and the spring is unstretched. Then a constant force F starts acting on the block of mass M to pull it. Block B is shifted a small distance x to the left and then released. In the subsequent motion, the An ideal spring with spring constant k = 30000 N / m is attached to the back side of m 2. Now if instead of upper string lower spring is cut, then the acceleration of the block just after the cut will be (Take g = 10 m / s 2), Two identical blocks A and B, each of mass m = 2 k g are connected to the ends of an ideal spring having force constant k = 1000 N m − 1. A light spring of force constant 800 N / m has one end rigidly attached to a vertical wall and lying on that horizontal surface. This system lies over a smooth hor asked Jun 26, 2019 in Physics by IdayaBasu ( 90. The blocks are pushed towards each other across a level frictionless surface by hands that each exert a constant horizontal force of Two blocks, of masses `M` and `2 M`, are connected to a light spring of spring constant `K` that has one end fixed, as shown in figure. Block `B` slides over the horizontal top surface of a stationary block `C` and Two blocks A (5kg) and B (2kg) attached to the ends of a spring constant 1120N/m are placed on a smooth horizontal plane with the spring undeformed. Two blocks each of mass m are joined together using an ideal spring of force constant K and natural length `l_(0)` . mv 0/2 x 02C. They are placed on a smooth horizontal surface. Consider two blocks of masses m and 2m which are connected by an ideal spring of spring constant k. Find the maximum compression Two blocks A and B connected by an ideal spring of constant 100 N / m and movign on a smooth horizontal surface under influence of a force of 36 N. The maximum extension of the Two identical blocks A and B, each of mass 'm' resting on smooth floor are connected by a light spring of natural length L and spring constant K, with the spring at its natural length. Then,A. Two blocks A and B, each of mass 2 kg are connected to two identical springs of spring constant 800 Nm 1 and are placed on a smooth horizontal surface as shown in the figure. Theya are connected by an ideal spring of force constant k. Two blocks are connected by a spring of natural length 2 m. They are connected by an ideal spring of relaxed length `l` and stiffness. The relative velocity of the blocks when the spring comes to its natural length is (a) [√(3k/2m)]x (b) [√(2k/3m)]x Theya are connected by an ideal spring of force constant k. spring Two blocks of mass 2 K g are connected by a massless ideal spring of spring constant K = 10 N / m. The two blocks are given velocities as shown when spring is at natural length. 0k points) Two blocks A and B, each of mass m, are connected by a masslesss spring of natural length L and spring constant K. b) Because the spring attached to block B is initially stretched a greater distance, the spring constant is smaller and therefore block B Consider two blocks of mass m and 2 m which are connected by an ideal spring of spring constant k. The motion of the blocks A and B over time are shown in the graph below. If the extension of the spring is x 0 at time t, find the displacement of the two blocks at this instant. Two blocks are connected to an ideal spring of stiffness 200 N/m. The tension in spring 1 Is T, and in spring 2 is T2 When the string between block B and the pulley Pis cut, then acceleration Find step-by-step Physics solutions and the answer to the textbook question Two blocks, of masses M=2. `sqrt((27m)/(8K))V` Two blocks A and B, each of mass m, are connected by a spring of force constant K. A block of mass m 1 = 3 kg is connected with ideal spring of spring constant k= 30000 N/m and kept at horizontal frictionless surface as shown in the figure The block m 2 = 1 kg is moving with velocity u = 4 m/s towards block m 1, v 1, and v 2 are the final speed of Two blocks A and B, each of mass m, are connected by a massless spring of natural length L and spring constant K. asked Jul 9, 2019 in Physics by Two blocks A and B each of mass m are connected to a mass less spring of natural length L and spring constant K. Two blocks A and B of mass m and 2m respectively are connected by light spring of spring constant k. 14 s Two blocks A and B of mass m and 2m respectively are connected by light spring of spring constant k. 8m/s and 2. 2k points) Two block of mass `2kg` are connected by a massless ideal spring of spring contant `K=10N//m` . If the system is Two blocks `A` and `B` of mass `m` and `2m` respectively are connected by a massless spring of spring constant `K`. 14A. At `t=0` the bolck `A` has velocity u towards right as shown while the speed of block `B` is zero, and the length of spring is equal to its natural length at that at that instant. 2k points) The coefficient of friction between the surface of the blocks is 0. The blocks are released from rest with the spring relaxed. A monkey of mass `8 kg` started climbing the string with a constant Two blocks A 5 kg and B 2 kg attached to the ends of a spring of spring constant 1120 N / m are placed on a smooth horizontal plane with spring undeformed. The two blocks and the spring system rests on a smooth horizontal floor. 5` cm D. A third identical block C, also of mass m, moves on the floor with a speed v along the line joining A and B, and collides elastically with A. the maximum compression in the spring is Two blocks A and B of mass m and 2m respectively are connected by light spring of spring constant k. Block B is pressed towards left so that spring gets compressed. Two blocks A and B of masses 2m and m respectively are connected by a massless and inextensible string The whole system is suspended by a massless spring as shown in the figure The magnitude of the acceleration. Strings are ideal and massless. The spring has its natural length during this motion . 0kg and block B of mass 8. Now, let's solve for the acceleration of Block A using Equation 1:5mg = 2m × aASimplifying the equation, we find:aA = 5g/2Therefore, the acceleration of Homework Statement A system is composed of two blocks of mass m1 and m2 connected by a massless spring with spring constant k. When the force F Two identical blocks A and B, each of mass m = 2 k g are connected to the ends of an ideal spring having force constant k = 1000 N m − 1. They are placed on a smooth horizontal plane. Suppose at time t displacement of smaller block is X, then would be:A. Block B coll ides with a third block C of mass m, at rest. In figure (B), mass ′ m ′ is attached to two springs of spring constant ′ k ′ and ′ 2 k ′. Explanation: we know that the force is known by the mass× acceleration(A) given that: mass of A =5kg . $A$ is imparted an initial velocity $u$ towards the right along positive x-axis. 14 sB. The spring passes over a frictionless pulley connected rigidly to the egde of a stationary block A. asked Oct 28, 2021 in Physics by AarnaPatel (75. Simultaneously velocities of 3 m/s and 10 m/s along the line of the spring in the same direction are imparted to A and B then Two blocks A & B connected by an ideal spring of constant 100 N/m and moving on a smooth horizontal surface under influence of a force of 36 N. Two identical block 'P' and 'Q' each of mass 2 kg are placed on a smooth horizontal surface as shown. Find spring force i f block 'A' and 'B' both are displaced by 0. Two identical blocks A and B, each of mass m = 2 k g are connected to the ends of an ideal spring having force constant k = 1 0 0 0 N m − 1. The block of mass m2 is given a sharp impulse so that it acquires a velocity v0 towards right. The horizontal surface and the pulley are friction less. The maximum extension in the spring will be – Two identical blocks A and B, each of mass m = 2 k g are connected to the ends of an ideal spring having force constant k = 1000 N m − 1. Spring is stretched by an amount x and then released. Simultaneously velocities of 3 m / s and 10 m / s along the line of the spring in the same direction are imparted to A and B thenis 0. `(sqrt((2k)/(3m)))x` Two blocks A and B of mass m and 2 m connected by a light spring of spring constant lie at rest on a fixed smooth horizontal plane are given velocities initially of magnitudes 2 u and u as shown in figure. Find the maximum compression of the spring. Two blocks A and B each of mass m are connected by a massless spring of neutral length L and spring constant K. the blocks are kept of a smooth horizontal . Maximum energy stored in Q. Initially the springs are relaxed. The blocks are released from rest when the spring is in its relaxed state. 4. x72B. 2 m/s are imparted to A and B in opposite direction. Initially spring is unstretched, find the maximum extension of the spring. This arrangement placed on a smooth surface. F t2/2 m x0, F t2/2 m x0B. 5 × 10 × 10 = 50 NMaximum spring force = kx = 800 × 0. 18 mB. All the pulleys and spring are ideal. A constant force Fis applied to the ned race. They are connected by an ideal spring of force constant k. Two blocks `A` and `B` of masses `m` and `2m`, respectively are connected by a spring of force constant `k`. If A collides with C of mass m elastically and head on, then the maximum compressions of the spring will be A. The blocks are kept on a smooth horizontal plane. What is extension in spring when acceleration of 2kg block is twice that of 5kg block? Two blocks A and B are connected by a spring of stiffness 200 N/m and placed on a smooth horizontal surface. The blocks are initially resting on a smooth horizontal floor with spring at its natural length as shown in the figure. if A and B moving on the horizontal frictionless surface with velocity v to right. Block A is attached to a spring of spring An ideal spring of natural length l0 having spring constant k=220 Nm -1, is connected to block A. They are connected by a light spring of Two rectangular blocks A and B of masses 2kg and 3kg respectively are connected by a spring of spring constant 10. The block of mass m 2 is given a sharp impulse so that it acquires a velocity v 0 towards right. Displacement (cm) block A block B ---- 3 2+ 2 එය 5 Time (s) -1 Figure (8-E12) shows two blocks A and B, each of mass of 320 g connected by a light string passing over a smooth light pulley. System is lying on a frictionless surface and the blocks are connected by a massless spring if spring constant 35 N / m. Block B collides heea on with a third block C of mass 2m at rest , the collision being Click here👆to get an answer to your question ️ Two blocks A and B, each of mass m are connected by means of a pulley-spring system on a smooth inclined plane of inclination 0 as shown in the figure, All the pulleys and spring are ideal. 8 N m-1 and are placed on a frictionless horizontal surface. Simultaneously velocities of 3m/s and 10m/s along the line of the spring in the same direction are imparted to A and B then. The blocks are brought nearer to compress the spring and then released. Two blocks A and B of mass 5 kg and 2 kg, respectively, connected by a spring of force constant = 100 N/m and are placed on an inclined plane of inclination 30∘ as shown. 5` cm C. A spring of force constant k = 200 N/m is fixed at one end of block A. The horizontal surface and pulley are frictionless. At t =0, three constant forces F, 2F and 3F start acting on Two blocks A and B, each of mass m, are connected by a massless spring of natural length L and spring constant k . The system shown is in equilibrium. (b) The 2 kg block will perform SHM. Now, B is slightly displaced from its equilibrium position. The block A was given an initial velocity of 0. A third block C of mass m moving with a speed v along Blocks A of mass m and B of mass 2m connected by an ideal spring of force constant k. Question: 2. Two Blocks and a Spring Two identical blocks are connected by an ideal spring. Time period of oscillation of B will be Take m =4 kg , K =5 N / m , π=3. 15 m s − 1 in the direction shown in the figure. Initially the spring is unstretched. They are stretched by an amount x and then released. They are connected by a light spring of force constant k = 200 N / m. the masses are moving to the right with a uniform velocity v' each, the heavier mass leading the lighter one. Two blocks of mass `10kg` and `2 kg` respectively are connected by an ideal string passing over a fixed smooth pulley as shown in figure. xB. 15 m s-1 in the direction shown in the figure. the maximum compression in the spring is Two blocks A and B connected by an ideal spring of spring constant `K=1000 N/m` are moving on a smooth horizontal plane due to the action of a horizon asked Aug 7, 2019 in Physics by IdayaBasu ( 90. the force constant of spring is 200 N/m. Complete arrangement is placed on smooth horizontal plane. If the resulting collision is elastic, the time period of Two identical blocks A and B, each of mass `m=3kg`, are connected with the help of an ideal spring and placed on a smooth horizontal surface as shown in Fig. 0 kg and 2M, are connected to a spring of spring constant k=200 N/m that has one end fixed, as shown in the given figure. So it will not move. Choose the incorrect option 000000 2M 4Mg (A) Maximum Two blocks of masses 3 kg and 6 kg respectively are placed on a smooth horizontal surface. The relative velocity of the blocks when the spring comes to its natural length is: Two blocks A & B of mass m and 2m respectively are connected by a spring of spring constant k. Find the force on the block of mass m. Two blocks A(3kg) and B(6kg) are connected by a spring of stiffness 512 N/m and placed on a smooth horizontal surface. The blocks-spring system can move over a smooth horizontal table along a straight line along the length of the spring as shown in Fig. An ideal spring with spring constant k is hung from the ceiling and a 01:25. The string passes over a frictionless pulley as shown in Fig. It starts to oscillate. Block B is pressed towards left so that spring gets compressed. Therefore, we can write the equation for Block B as:m × g = m × a [Equation 2]Simplifying Equation 2, we find that the acceleration of Block B is equal to the acceleration due to gravity (g). Initially, spring is relaxed, both the blocks are Two blocks of mass 2 k g and 5 k g are given speed as shown in the figure. a) Because block B covers more distance per cycle than block A, block B takes more time to complete each cycle. 2k points) class-11; simple-harmonic Two blocks of equal mass m are connected by an un stretched spring and the system is kept at rest on α frictionless horizontal surface. The unstretched length of the spring is L. A third block C of mass m moving in the line joining A and B, collide with block A with velocity vo If collision is perfectly inelastic, then velocity of block B when spring has maximum compression, is Block A of mass 2. System of these blocks and spring is placed on a rough floor. If upper spring is cut, then the acceleration of the block just after cut is 5 m s − 2. Two blocks A and B of masses m and 2m, respectively , are held at rest such that the spring is in natural length. Another block C is placed on B. 1. `x/2` B. The blocks are initially resting on a smooth horizontal floor as shown in fig. A third identical block C also of mass m moves on the floor with a speed V along the line joining A and B and collides with A. The blocks are initially resting on a smooth horizontal Two identical blocks A and B, each of mass m = 2 kg are connected to the ends of an ideal spring having force constant k =1000 Nm^ {-1}. 0 m/s. An ideal spring of spring constant k = 1120 N / m is attached on the back side of m 2. Block B slides over the horizontal top surface of a Two-block Spring System Experiment and Mechanism. Two blocks of masses m 1 and m 2 are connected by a spring of constant k (given figure). 0 N, as shown, with both blocks experiencing equal constant acceleration. Two blocks `A` and `B` of masses `m` and `2m` respectively are connected together by a light spring of stiffness `k` and then placed on a smooth horizontal surface. The Two blocks `A` and `B` are connected to each other by a string and a spring , the string passes over a frictionless pulley as shown in the figure. The block of mass m 2 is given a sharp impulse so that it acquires a velocity v 0 towards right. A block of mass 2 k g is on a smooth horizontal surface. Then the maximum compression of the spring after collision will be : Two blocks are connected by a spring of natural length 2 m. What is extension in spring when acceleration of 2 kg block is twice Two blocks A and B each of mass m are connected by a massless spring of natural length L and spring constant K. The velocity of the centre of mass of The spring 1 has spring constant K, and the spring 2 has spring constant K. Two blocks A and B, each of mass m are connected by means of a pulley spring system on a smooth inclined plane of inclination θ as shown in the figure. The blocks are pushed towards each other such that spring gets compressed by a length `x_(0)` and then released from rest. A third block C of mass m moving in the line joining A and B, collide with block Two blocks of mass 2 k g are connected by a massless ideal spring of spring constant k = 10 N / m. The rate Two identical blocks A and B, each of mass 'm' resting on smooth floor are connected by a light spring of natural length L and spring constant K, with the spring at its natural length. The upper block is suspended from roof by a light string `A` . If block 'p' is given an initial velocity 4 m/s towards the block 'Q' the maximum compression in the spring will be The blocks of masses m 1 and m 2 are connected by an ideal spring of force constant k. 2. Two blocks of masses m 1 = 1 kg and m 2 = 2 kg are connected by a spring of spring constant 24 N m-1 and is placed on a horizontal frictionless surface. 28 sD. 5. The maximum compression of the spring during the motion is : A block of mass m is connected to another block of mass M by a spring (massless) of spring constant k. Blocks A and B are connected by an ideal string passing through a friction less pulley. Initially, spring is relaxed, both the blocks are at rest. The block M slides over the Two blocks A (5 kg) and B (2 kg) attached to the ends of a spring of spring constant 1120 N/m are placed on a smooth horizontal plane with spring undeformed. The unstretched length of the spring is a. Now the blocks are moved towards each other compressing the spring by x and then they are suddenly released. The blocks are initially resting on a smooth horizontal floor Two blocks of masses 3 kg and 6 kg respectively are placed on a smooth horizontal surface. Two rectangular blocks A and B of masses 2 kg and 3 kg respectively are connected by a spring of spring constant 10. Answer: the extension in spring when the acceleration of 2kg and 5 kg is 0. The string A is now cut, the acceleration (in m / s 2 of upper block just after the string 퐴 is cut will be (g = 10 m / s 2) This block is connected to two other blocks of masses M and 2 M using two massless pulleys and strings. Rest on a smooth horizontal plane. Two-block Spring System Experiment and Mechanism. The horizontal surface and the pulley are frictionless, and the pulley has negligible mass. Initially, both the blocks arc moving with Two blocks A and B, each of mass m, are connected by a masslesss spring of natural length L and spring constant K. The blocks are initially resting on a smooth horizontal floor with the spring at its natural length as shown in the figure. The force constant of the spring is 1960 N m − 1. the first maximum compression occurs after start at 3 π/56 sC. Maximum extension in the spring is 4 Mg / kB. `sqrt((3)/(2)(m)/(k))V` B. Initially, both the blocks arc moving with same velocity `v` on a smooth horizontal plane with the spring in its natural length. each of mass m, are connected by a massless spring of natural length L and spring constant K. Initially the spring has its equilibrium length. An ideal massless spring is An ideal spring is permanently connected between two blocks of masses `M` and `m`. A third identical block C, also of mass m, moving on the floor with a speed along the line joining A and B,collides with A see figure ThenA. asked Sep 25, 2020 in Physics by IdayaBasu (90. A block C of mass m is moving with velocity v 0 and collides elastically with block A of mass m and connected to another block B of mass 2 m through spring with spring constant K. They are connected by a light spring of force constant k = 200 N/m. `x/3` Two identical blocks A and B, each of mass 'm' resting on smooth floor are connected by a light spring of natural length L and spring constant K, with the spring at its natural length. Now the block is moved towards the wall Two blocks of mass 2kg are connected by a massless ideal spring of spring constant K = 10N/m. A third identical block 'C' (mass m) moving with a The blocks of masses m 1 and m 2 are connected by an ideal spring of force constant k. F t 2/4 m x /2 Two blocks A and B of the same mass are connected to a light spring and placed on a smooth horizontal surface B is given velocity `v_(0)` (as shown in the figure) when the spring is in natural length. Maximum kinetic energy of the system is 2 M 2 g 2/ kC. The upper block is suspended from roof by a light string A. A block of mass m is connected to another block of mass M by a massless spring of spring constant k. The blocks are initially resting on a smooth horizontal Two blocks A and B are connected to each other by a string and a spring. Find out the acceleration of both the blocks just after relese. System of these blocks and spring is placed on a rough floor. Two blocks of masses m and 2m are kept on a smooth horizontal surface. In this case, the tension T acts in the downward direction. They are connected force constant k. The accelerations of the blocks are a 1 , a 2 and a 3 as shown in the figure. Q. 6(m)/(s)` collides with A and sticks to it, as a result, the motion of system takes place in some way Two blocks of Masses M and 2M are connected by a spring of stiffness k . What is the value of K, if x 0 is compression of spring, when velocity of A and B is same?c B 14A. Block B collides with block A with velocity v0 = 2. Suppose at time t displacement of smaller block is `x_(1)` then displacement of the heavier block at this moment would be A. Time period of oscillation of B will be (Take m = 4 kg, Two blocks of masses m1 and m2 are connected by a spring of spring constant k. D. The string is light. The blocks are placed on a smooth Two blocks A (5kg) and B (2kg) attached to the ends of a spring constant 1120N/m are placed on a smooth horizontal plane with the spring undeformed. Figure 1: Two masses connected by a spring sliding horizontally along a frictionless surface. Initially, the spring is in its natural length. 45. 85`. Both the blocks come to rest simultaneously when the extension in the spring is `(l_(0))/4`. Another identical blocks C moving velocity `v_0=0. In the subsequent motion. The blocks of masses m 1 and m 2 are connected by an ideal spring of force constant k. Coefficient of friction between C and B is `mu_2 = 0. A third identical block 'C ' (mass m ) moving with a speed v along the line joining A and B collides with A . Coefficient of friction between 32. wfsz jcvw gavmzkh qxtwx sbrq davcl mymd eyw oteyw qvojd