A wedge of mass m fitted with a spring. Neglect friction betwee.

A wedge of mass m fitted with a spring `8. A small massless wedge is fitted on it as shown. A small ball of mass m is released from the top of the wedge, it slides over it and falls in the hole at distance / from the initial position of the ball. The system is in equilibrium. The wedge is free to slide on a horizontal frictionless surface as shown in the figure. Assuming that all surfaces are smooth, the potential energy stored in the spring is: Assuming that all surfaces are smooth, the potential energy stored in the spring is: A wedge of mass M fitted with a spring of spring constant k is kept on a smooth horizontal surface. System is in equilibrium and at rest Assuming that all surfaces are smooth, the potential energy stored in the spring is : A wedge of mass M fitted with a spring of stiffness ' k ' is kept on a smooth horizontal surface. magnitude of velocity of the beard relative to the wedge. It is attached by a spring (natural length xo, spring constant k) to a fixed vertical support. All surfaces are frictionless. What must the magnitude of be if the block is to remain at a constant height above the tabletop? A block of mass m_(1) lies on the top of fixed wedge as shown in fig. `7. 57 A wedge of mass M fitted with a spring of stiffness 'K' is kept on a smooth horizontal surface. mg(4) expansion in spring with spring constant k, is tbk2mg(b) corapression in spring with a spring constant k is tax(c A block of mass m lying on a smooth horizontal surface is attached to a spring of negligible mass of spring constant k. If there is no friction any where, the speed of the wedge, as the block leaves the wedge is `:` Oct 31, 2021 · The system shown in figure is in equilibrium. 0k points) In an ideal pulley particle system, mass m 2 is connected with a vertical spring of stiffness k. A block of mass m is attached to a wedge of mass M by a spring of natural length so and spring constant k. Initially, the spring makes an angle of 37° with the vertical when the system is released from rest. 5 m (D) 2. A rod of mass m is kept on the wedge as shown in the figure. The acceleration of bead with respect to rod isA. Find the maximum compression of the sprin At the other end of the string there is a mass M = 50 g. Assuming that all surfaces are smooth, the potential energy stored in the spring is Mar 26, 2019 · A wedge of mass M fitted with a spring of stiffness k' is kept a smooth horizontal surface. A wedge of mass M fitted with a spring of stiffness k is kept on a smooth horizontal surface. Assuming that all surfaces are smooth, the potential energy stored in the spring is: m k mg tan’ e mụg tan’ e (B) - 2k (0) m’g’ tan’ e mʻgʻtan In this case we are given the block slides through a distance l relative to the wedge While the block is displaced from point 1 to point 2 Work done by gravity A wedge of mass M fitted with a spring of stiffness 'k' is kept on a smooth horizontal surface. 0k points) A wedge of mass M fitted with a spring of stiffness ' k ' is kept on a smooth horizontal surface. System is in equilibrium and at rest. The spring of force constant 'k' is attached to the wedge. A wedge of mass M fitted with a spring of spring constant k is kept on a smooth horizontal surface. E s y s t e m = 1 2 k x 2 where x = maximum The spring is initially relaxed. The whole system is resting on a smooth horizontal surface. A block of mass m is pushed towards a movable wedge of mass nm and height h, with a velocity u. The block is displaced towards the right through a distance x and is released. below. System is in - 5522499 A block of mass m is connected rigidly with a smooth wedge (plank) by a light spring of stiffness k. Find the speed of the ring when the spring becomes vertical. The incline is at an angle θ = 31. The block is placed over a rough inclined surface for which the coefficient of friction is μ = 3 / 4. A wedge of mass M is fitted with a spring of stiffness ‘k’ is kept on a smooth horizontal surface. Assuming that all surfaces are smooth, the potential energy stored in the spring is Oct 4, 2022 · 58A wedge of mass M fitted with a spring of stiffness ' k ' is kept on a smoth horizontal surface. 1 m and spring constant k = 8 0 N/m is fixed to the ground and other end is fitted with a smooth ring of mass m = 2 g m, which is allowed to slide on a horizontal rod fixed at a height h = 0. Assuming that all surfaces are smooth, the potential energy stored in the spring is: Jun 28, 2019 · A ball of mass `m` is released from A inside a smooth wedge of mass `m` as shown in figure. 112b). A wedge of mass M fitted with a spring of stiffness ' k ' is kept on a smooth horizone of mass M fitted with a spring of stiffness ' k ' is kept on a smooth figurental surface. The block is initially at rest in its equilibrium position. Assuming that all surfaces are smooth, the potential energy stored in the spring is: A wedge of mass M fitted with a spring of spring constant k is kept on a smooth horizontal surface. speed of the wedge b. System is in equilibrium and at rest Assuming that all surfaces are smooth, the potential energy stored in the spring is? And angle is theta for inclined surface. 5 m (B)1. 0k points) Click here👆to get an answer to your question ️ (D) None U TU rad/sec (C) 12 rad/sec A wedge of mass M fitted with a spring of stiffness K' is kept on a smooth horizontal surface. 0k points) Nov 1, 2022 · Solution For 31. F/√mm kB. 1 kg` is released from rest from a point A of a wedge of mass `M = 2. 0k points) A block of mass m is released from rest from a height h onto a smooth sledge of mass M fitted with an ideal spring of stiffness k. Initially, the wedge is at rest at x = to and the particle m is at rest at the top of the A block of mass m is connected rigidly with a smooth wedge (plank) by a light spring of Jul 12, 2020 · Figure shows a flat car of mass `M` on a frictionless road. A block of mass m is connected rigidly with a smooth plank by a light spring of stiffness K. A light string is attached to the ring and is passing over a smooth peg distant a from the rod, and at the other end of the string is a mass M(M>m). What is the reading of the balance while the block slides? Ignore the recoil of the wedge. A. A rod of mass m is kept on the wedge as shown in the smooth, the potential energy stored in the spring is: A wedge of mass M fitted with a spring of spring constant k is kept on a smooth horizontal surface. If the plank is moved with constant velocity υ 0, find the work done by the external agent till the maximum compression of the spring. 6. 4 kg` free to slide on a frictionless horizontal plane. Assuming that all surfaces are smooth, the potential energy stored in the spring is A block of mass `m` is relesed from rest from a height `h` onto a smooth sledge of mass `M` fitted with an ideal spring of stiffness `k`. Find the maximum compression in the spring. A block of mass m, attached to a fixed position O on a smooth inclined wedge of mass M, oscillates with amplitude A and linear frequency f. k h/4 mB. A particle of mass m slides frictionlessly down the sloping face of the wedge, which makes a constant angle a with respect to the horizontal A ring of mass m slides on a smooth vertical rod. The ring is held on a level with the peg and released. 2 m//s` the particle in `m//s` relative to the wedge is :- A. The asked Jun 12, 2019 in Physics by JayantChakraborty ( 79. If mass m 2 is released from rest, when the spring is undeformed, find the maximum compression of the spring. Figure shows a flat car of mass `M` on a frictionless road. System is A wedge of mass M fitted with a spring of spring constant k is kept on a smooth horizontal surface. If the particle sticks to the wedge, then loss in kinetic energy of the system during collision is A rod of mass m is kept on the wedge as shown in the figure. 5 kg sits on a horizontal surface. When the wedge fitted moves with acceleration a, as shown in the figure, the block slides through a maximum distance l relative to the wedge. A rod of mass \( m \) is kept Nov 18, 2022 · A wedge of mass M fitted with a spring of stiffness ' k ' is kept on a smooth horizontal surface. Assuming that all surfaces are smooth, the potential energy stored in the spring is: Oct 22, 2018 · Find an answer to your question A wedge of mass M fitted with a spring of stiffness k is kept on a smooth horizontal surface. 27 shows a flat car of mass M on a frictionless road. A wedge of mass \[M\] with a spring of stiffness $k$ is kept on a smooth horizontal surface. The system is in equilibrium and at rest. Assuming that all surfaces are smooth, the potential energy stored in the spring is: A wedge of mass M fitted with a spring of stiffness 'k' is kept on a smooth horizontal surface. Assuming that all surfaces are smooth, the potential energy stored in the spring is: (A) 2 k m g 2 t a n 2 θ (B) 2 k m 2 g t a n 2 θ (C) 2 k m 2 g 2 t a n 2 θ Jan 24, 2023 · A wedge of mass M fitted with a spring of stiffness k is kept on smooth horizontal surface . E s y s t e m) = − [1 2 m v 0 2 - 1 2 (M + m) v 2] By putting v = m v 0 M + m, we obtain Δ K. When the wedge fitted moves with an acceleration a, as shown in figure. When the velocity of th ewedge is `0. Assuming that all surfaces are smooth, the potential energy stored in the spring is : A wedge of mass M fitted with a spring of stiffness k is kept on a smooth horizontal surface. Block B, having mass 2M, rests on wedge A and is supported by a vertical spring. If a force F acts on the wedge; the blocks do not slide relative to the wedge, find the a cceleration of the wedge. ) - 324005 A wedge of mass M fitted with a spring of stiffness ' k ' is kept on a smooth horizontal surface. The inclined frictionless surface O of the wedge makes an angle a to the horizontal. Assuming that all surfaces are smooth, the potential energy stored in the spring is mg tano (A) 2k (B) mºg tano 2k mʻgʻtan A wedge of mass M fitted with a spring of stiffness k is kept on a smooth horizontal surface. Assuming the surfaces are smooth, the potential energy stored in the spring is: Nov 27, 2022 · A wedge of mass M fitted with a spring of stiffness ' k ' is kept on a smooth horizontal surface. K A wedge of mass 'M' and angle of inclination 'o' and a block of mass 'm' are arranged in a manner shown in the ligure. System is in equilibrium and at rest Assuming that all surfaces are smooth, the potential energy stored in the spring is : 9600002 M mgtan? mgtan? 6 2K (c) mʻgʻtan? m’g tano (D) 2K 2K K Cornorate Office : CG Tower A-46 & 52, IPIA, Near City Mall, Jhalawar Road, Kota (Rai. Find the distance the flat car moves till the ball get into the hole. The wedge surface is smooth and gradually flattens. 7 degrees with respect to the horizontal, and g = 9. What is the reading of the b A wedge of mass M fitted with a spring of stiffness 'k' is kept on a smooth horizontal surface. The wedge is free to slide on the horizontal frictionless surface, as shown in the figure below. Assuming that all surfaces are smooth, the potential energy stored in the spring is A block of mass m attached with an ideal spring of for constant k is placed on a rough inclined plane having inclination θ with the horizontal and coefficient of friction μ = 1 / 2 tan θ. Find the speed of the block as it passes through the mean position shown. v 0√ k / m 2 v 0√ m / k 2 v 0√ k / m The velocity of the combinational at the time of maximum compression of the spring = v = m v 0 M + m obtained by conserving the momentum of the system. If the wedge is moved with constant velocity v_0 , find the work done by the external agent till the maximum compression of the spring. Neglect friction betwee Question: 9. sy Feb 13, 2023 · A wedge of mass \( \mathrm{M} \) fitted with a spring of stiffness ' \( \mathrm{k} \) ' is kept on a smooth horizontal surface. Q. Find 2 y . P5. A wedge of mass M fitted with a spring of spring constant k is kept on a smooth horizontal surface. Show that it first comes to rest after falling a distance 2 m M a M 2 − m 2 Jun 18, 2019 · A block of mass `m` slides down a wedge of mass `M` as shown . Two smooth blocks of masses m and m ′ connected by a light inextensible strings are moving on a smooth wedge of mass M. The wedge-block system is free to slide on a frictionless surface. Assuming that all surfaces are smooth, the potential energy stored in the spring is : nown mgtan? e 2K m’gtan? 0 (A) m?g? tane whailm?g? tane (D) — (B) (C A wedge of mass M fitted with a spring of stiffness ' k ' is kept on a smooth horizontal surface. All surfaces are smooth. The maximum height climbed by the particle on the wedge is given by : (1) 2v 2 /7g (2) 2v 2 /7g (3) 2v 2 /5g (4) 2v 2 /7g Aug 5, 2023 · A wedge of mass m and two springs of spring constants k, and k, are kept on a smooth horizontalplane and both the springs are in natural lengths. Assuming that all surfaces are smooth, the potential energy stored in the spring is Click here👆to get an answer to your question ️ A wedge of mass M fitted with a spring of stiffness 'k' is kept on a smooth horizontal surface. There is no friction anywhere and the thread QS is parallel to the incline surface. g sinα+a0cosα One end of a spring of natural length h and spring constant k is fixed at the ground and the other is fitted with a smooth ring of mass m which is allowed to slide on a horizontal rod fixed at a height h (figure). The spring balance S is showing a reading of `sqrt2` Mg. Assuming that all surfaces are smooth, the potential energy stored in the spring is: D 10. of mass m is kept on the wedge as shown in the figure. The second end of the spring is attached to a second block of mass M as shown in figure. There is no friction between the particle and the plane or between the particle and the wedge. The ring is held in level with the pulley and then released. System is in equilibrium and at rest Assuming that all surfaces are smooth, the potential energy stored in the spring is: A wedge of mass M fitted with a spring of spring constant k is kept on a smooth horizontal surface. m M M One end of a spring of natural length h and spring constant k is fixed at the ground and the other is fitted with a smooth ring of mass m which is allowed to slide on a horizontal rod fixed at a height h figure. System is in equilibrium and at rest Assuming that all surfaces are smooth, the potential energy stored in the spring is : (A) mg2tan2θ2K (B) m2 g tan2θ2K (C) m2 g2 tan2θ2K (D) m2 g2 tan2θK A body of mass m hangs by an inextensible string that passes over a smooth mass less pulley that is fitted with a light spring of stiffness k as shown asked May 21, 2019 in Physics by MohitKashyap ( 76. Assuming that all surfaces are smooth, the potential energy stored in the spring is A wedge of mass M fitted with a spring of stiffness k is kept on a smooth horizontal surface. `5` C. There is no friction between wedge and ground. A wedge of mass M fitted with a spring of stiffness ' k ' is kept on a smooth horizontal surface. `10` Figure below shows a flat car of mass 'M' on a frictionless road. The Δ K. One end of a spring of natural length h and spring constant k is fixed at the ground and the other is fitted with a smooth ring of mass m which is allowed to slide on a horizontal rod fixed at a height h (figure 8-E13). 2 ngh √2 gh1 1/ n √2 gh1+1/n Jul 12, 2020 · A smooth block of mass m is released from rest from a height h. System is in equilibrium and at rest Assuming that all surfaces are smooth, the potential energy stored in the spring is : 2 K m g 2 t a n 2 θ 2 K m 2 g t a n 2 θ 2 K m 2 A wedge of mass M fitted with a spring of stiffness 'k' is kept on a smooth horizontal surface. The wedge is at- tached by a spring of natural length co and spring constant k to a fixed vertical support. Assuming that all surfaces are smooth, the potential energy stored in the spring is Sep 4, 2018 · A wedge of mass M fitted with a spring of stiffness k is kept on a smooth horizontal surface. What is the speed 2sqrt3))^(1//2)` D. The particle slides down the smooth face Ab of the wedge. A rod of mass m is kept on the wedge as shown in figure. A block of mass m is connected rigidly with a smooth wedge (plank) by a light spring of stiffness k. A block of mass m is attached with a massless spring of force constant k. Jun 15, 2019 · A body of mass m hangs by an inextensible string that passes over a smooth mass less pulley that is fitted with a light spring of stiffness k as shown asked May 21, 2019 in Physics by MohitKashyap ( 76. 8` B. E s y s t e m = M m v 0 2 2 (M + m) Δ P. The block can slide on a frictionless table as shown in figure. Next, make free body diagram of block of mass m. Initially the bead is at the middle of the rod and the rod moves translationaly up in a vertical plane with an acceleration a 0 in a direction forming an angle α with the horizontal plane. Initially, the spring makes an angle of 3 7 o with vertical when the system is released from rest. Oct 18, 2019 · A body of mass `m` hangs from a smooth fixed pulley `P_(1)` by the inextensible string fitted with the springs of stiffness `k_(1)` and `k_(2)` . A wedge of mass M fitted with a spring of stiffness ' K ' is kept on a smooth horizontal surface. then a sphere of mass mis put slowly as shown ingiven figure. when sphere is at rest on the wedge then : (k, = 2k and k2 = k). Figure-$2. Assuming that all the surfaces are smooth, the potential energy stored in the spring: a) mg 2 tan 2?/2k b) m 2 g tan 2?/2k c) m 2 g 2 tan 2?/2k d) m 2 g 2 tan 2?/k May 31, 2019 · A block of mass m is connected rigidly with a smooth wedge (plank) by a light spring of stiffness k. 0 m (A) 1. It slides and compresses the spring of stiffness k. F/π√m k Figure shows a flat car of mass M on a frictionless road. The block and the man are resting on a rough wedge of mass M. May 16, 2019 · A wedge of mass M=4 m lies on a frictionless plane. The man starts walking towards right while holding the rope in his hands. Assuming that all surfaces are smooth, the potential energy stored in the spring is. A rod of mass mis kept on the wedge as shown in the figure. The spring is initially relaxed. `4. The minimum value of M required to move the block up the plane is (Neglect mass of string and pulley and friction in pulley) 3 5 m; 4 5 m; 2 m; 3 2 m Figure shows a flat car of mass `M` on a frictionless road. If the natural length of spring is L 0 and it is compressed to half its length when the block is released, find the velocity of the block, when the spring has natural length. Assuming that all surfaces are smooth, the potential energy stored in the spring is: A wedge of mass M fitted with a spring of stiffness k is kept on a smooth horizontal surface. For wedge of mass M the forces acting along the floor are N sinθ (normal reaction from block of mass m) and kx. A rod of mass m is kept on the wedge . May 27, 2019 · A block of mass m is welded with a light spring of stiffness k. The inclined frictionless surface of the wedge makes an angle a to the horizontal. The other end of the rope is in the hands of a man of mass 2M as shown in figure. If the body is released from rest and the spring is released, calculate the maximum elongation of the spring. A block of mass m is attached to a wedge of mass M by a spring of natural length lo and M spring constant k. The minimum value of u for which the block reaches the top of the wedge is B. π F /√ mk / m √ mk D. If the wedge is moved with constant velocity `v_0 asked Jun 15, 2019 in Physics by MohitKashyap ( 76. A block of mass m is pushed against a spring whose spring constant is k fixed at one end with a wall. The mass m is released from rest on mass M, which is also initially at rest. A body of mass m hangs by an inextensible string that passes over a smooth massless pulley that is fitted with a light spring of stiffness k as shown in the figure, such that the spring is initially at natural length. Initially, the spring makes an angle of 37 ∘ with the vertical when the system is released from rest. Click here👆to get an answer to your question ️ A wedge of mass M fitted with a spring of stiffness ' k ' is kept on a smooth horizontal surface. Assuming that all surfaces are smooth, the potential energy stored in the spring is: m k mg tan’ e mụg tan’ e (B) - 2k (0) m’g’ tan’ e mʻgʻtan? 0 2k A wedge of mass M fitted with a spring of stiffness k is kept on a smooth horizontal surface. Initially, the spring makes an angle of 37∘ with the vertical when the system is released from rest. Solving these equationsNsinθ = kx,Ncosθ = mg,We get the value of x, hence value of potential energy can be evaluated. A block with mass is placed on the wedge, and a horizontal force F → is applied to the wedge (Fig. . The whole system is at rest , when the height of the block is `h` above the ground. A particle of mass m slides frictionlessly down the sloping face of the wedge. Assuming that all surfaces are smooth, the potential energy stored in the spring is A wedge of mass M fitted with a spring of spring constant k is kept on a smooth horizontal surface. and another block of mass m_(2) lies on top of wedge which is free to move as shown in fig. 162$ shows a wedge of mass $2\, kg$ resting on a frictionless floor. 8 m/s. Surface PQ of wedge A, having mass M, is horizontal. A block of mass m is moving with an initial velocity v 0 towards a stationary spring of stiffness k attached to the wall as shown. Maximum compression of the spring is √ y m g h k . Assuming that all surfaces are smooth, the potential energy stored in the spring is Jan 6, 2021 · VIDEO ANSWER: A block of mass m is attached to a wedge of mass M by a spring with spring constant k. Find the minimum value of h so that the block M bounces off the ground, if the block of mass m sticks to the spring immediately after it comes into contact with it. A wedge of mass M fitted with a spring of stiffness 'k' is kept on a smooth horizontal surface. Assuming that all surfaces are smooth, the potential energy stored in the spring is (1 ) A wedge of mass M fitted with a spring of stiffness 'k' is kept on a smooth horizontal surface. Forces acting on it perpendicular to the floor are N cosθ and mg. The wedge makes an angle a with the horizontal . At time t=0 both the blocks are released from rest from a vertical height h above the respective horizontal surface on which the wedge is placed as shown. Assuming the pulleys to be massless and all surfaces to be frictionless, find the compression of the spring under equilibrium condition. g sinαC. Assuming that all surfaces are smooth, potential energy stored in the spring is : A wedge of mass M fitted with a spring of spring constant k is kept on a smooth horizontal surface. 3 kg sits on the sloping side of the wedge. Another mass m = 2. A ball of mass \\( m \\) collides horizontally with a stationary wedge on a rough horizontal surface, in the two orientations as shown. 4k points) Oct 6, 2022 · A wedge of mass M fitted with a spring of stiffness ' K ' is kept on a smooth horizontal surface. ← Prev Question Next Question → 0 votes Figure 1. Jun 29, 2019 · A particle mass `m = 0. A small block of mass m_1 can move along the frictionless incline of the wedge. 60`, the block slides through a maximum distance `l` relative to the wedge. A rod of mass m is kept on the wedge as shown in the figure A block of mass m is connected rigidly with a smooth wedge (plank) by a light spring of stiffness k. g sinα a0cosαB. Assuming that all surfaces are smooth, the potential energy stored in the spring is : A wedge of mass M fitted with a spring of spring constant k is kept on a smooth horizontal surface. A block of mass m_(1) lies on the top of fixed wedge as shown in fig. 4 M VIIMMMMM One end of a spring of natural length ℓ 0 = 0. The distance by which the mass 'm' moves down before coming to rest for the first time, is (C) 2. A small ball of mass `m` is released from the top of the wedge, it slides over it and falls in the hole at distance `l` from the initial position of the ball. A particle of mass m strikes normally to a stationary wedge of mass 5m kept on the smooth horizontal surface as shown. A block of mass $1\, kg$ is kept on the wedge and the wedge is given an acceleration of $5\, m / \sec ^{2}$ towards right. The thread QS is cut. 5` D. A rod of mass m is kept on the wed… jatin200328 jatin200328 A block of mass m is dropped onto a spring of spring constant k from a height h. Problem 2 Sliding on a Wedge A wedge of mass M slides frictionlessly on a smooth table top. A small ball of mass m is released from the top of the wedge, it slides over it and fall in the hole at distance l from the initial position of the ball. A small ball of mass 'm' is released from the top of the wedge, it slides over it and falls in the hole at distance 'l' from the initial position of the ball. A wedge of mass m_2 is kept on a spring balance. Initially the block is held stationary with the spring in its relaxed state, find the maximum extension in the spring if the block is released. A rod mass m is kept on the wedge as shown in the figure. A small massless wedge is fitted on A triangular wedge of mass \( M \) is kept on a spring balance, A small block of mass \( m \) can move along the frictionless incline of the wedge. `sqrt(3)/(2)gR` LIVE Course for free Question: (In): A block of mass m is attached to a wedge of mass M by a spring with spring constant k. g + a 0 sinαD. k h/8√ A bead of mass m is fitted on a rod and can move on it without friction. As a result, the wedge slides due left Find the a. A rod of mass m is kept on the wedge as shown in the fig. The other end of the spring is fixed as shown in the figure. Nov 20, 2022 · is2A wedge of mass M fitted with a spring of stiftness k is kept on a smoth hrizontal surface. System is in equilibrium and at rest Assuming that all surfaces are smooth, the potential energy stored in the spring is : 9600002 M mgtan? mgtan? 6 2K (c) mʻgʻtan? m’g tano (D) 2K 2K Nov 27, 2022 · A WEER ENERGY A wedge of mass M fitted with a spring of stiffness ' k ' is kept on a smooth horizontal surface. A block of mass m is attached to a wedge of mass M by a spring with spring constant k. Find the speed of the ring A bead of mass m kept at the top of a smooth hemispherical wedge of mass M and radius R, is gently pushed towards right. System is in equilibrium. Find the distance the flat car moves till the ball gets into the hole. Jun 8, 2019 · A block of mass m is connected rigidly with a smooth wedge (plank) by a light spring of stiffness k. If the coefficient of kinetic friction between the block and the wedge is μ, find the maximum deformation l of the spring by using the work-energy theorem. A rod of mass m is kept on the wedge as shown in the figure . \( I ^{x} \) A wedge of mass M fitted with a spring of stiffness 'k' is kept on a smooth horizontal surface. 0k points) ,A block of mass m is attached to two unstretched springs of spring constants k1 and k2 as shown in the figure (8-E9). Assuming that all surfaces are smooth, the potential energy stored in the spring is:a)b)c)d)Correct answer is option 'C'. A wedge with mass M rests on a frictionless, horizontal table top. A particle of mass m approaches the wedge with speed v. 1 m. The inclined frictionless surface of the wedge makes an angle \alpha to the horizontal. View Solution A wedge of mass M = 4. Suppose the wedge moves only in the x-direction (horizontally). m M 100000 a X A wedge of mass M can slide frictionlessly on a smooth table-top. The wedge is free to slide on a horizontal frictionless surface, as shown in Fig. If the angle of the wedge is 60 0, then the force of friction acting on the wedge is given by (coefficient of static friction = μ A block of mass M is tied to one end of a massless rope. 4 M VIIMMMMM Click here👆to get an answer to your question ️ (1 ) A wedge of mass M fitted with a spring of stiffness 'k' is kept on a smooth horizontal surface. If now the block is pulled with a constant force F, the maximumA. 0 m Q. The wedge is located on a rough horizontal surface. hsq vbbqzp qjdx twmbxs jfu eufp jgjttbu fvchek jgxepff iaj