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Applied mechanics lab manual

R
Rajat Dhiman

This document contains the laboratory manual for Applied Mechanics experiments at a government polytechnic institute. It lists 10 experiments for verifying mechanics laws and principles. The first experiment involves verifying the parallelogram, triangle, and polygon laws of forces using a Gravesand's apparatus. The other experiments include verifying forces in a jib crane, reactions in a simply supported beam, and calculating mechanical advantage, velocity ratio, and efficiency for devices like inclined planes and screw jacks. Procedures, observations tables, and precautions are provided for each experiment.

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1APPLIED MECHANICS GOVT. POLYTECHNIC, KANGRA APPLIED MECHANICS LABORATORY LAB MANUAL
2APPLIED MECHANICS LIST OF PRACTICALS 1. Verification of the following laws: a) Parallelogram law of forces. b) Triangle law of forces. c) Polygon law of forces. 2. To verify the forces in different members of jib crane. 3. To verify the reaction at the supports of a simply supported beam. 4. To find the mechanical advantage, velocity ratio and efficiency in case of inclined plane. 5. To find the mechanical advantage (M.A), velocity ratio (V.R) and efficiency (η) of a screw jack. 6. To find the mechanical advantage, velocity ratio and efficiency of worm and worm wheel. 7. To find mechanical advantage, velocity ratio and efficiency of single purchase winch crab. 8. To find M.A, V.R, and cof : a) First system of pulleys b) Second system of pulleys. 9. To find out center of gravity of: a) Regular lamina b) Irregular lamina. 10. To determine coefficient of friction between three pairs of given surface.
3APPLIED MECHANICS EXPERIMENT NO. 1 (A) AIM: VERIFICATION OF PARALLELOGRAM LAW OF FORCES APPRATUS:- Gravesand‟s apparatus complete with two freely moving guide pulleys, weights, thread, a small central ring, white paper sheet, three scale pans, tape, a mirror strip, set squares and pencil. THEORY: The „Parallelogram Law of forces‟ states that if a particle is acted upon by two forces represented in magnitude and direction by the two sides of a parallelogram drawn from a point, then the resultant is completely represented by the diagonal passing through the same point. PROCEDURE: I) Take any point O on the plane of paper and draw a line OA Parallel to forces Z. Similarly draw a line OB parallel to force X. II) Complete the parallelogram OAC‟B as shown in fig. 2 III) Join O to C‟ which is the diagonal of the parallelogram OC‟ to the given scale gives the resultant of forces X and Z.
4APPLIED MECHANICS IV) Draw a line OC equal and opposite to OC‟ which should be equal to the third force Y. OBSERVATIONS: Sr. No. Total weight PQ (X) Total weight QR (Y) Total Weight RP (Z) Resultant R‟ % age error Mean Value……………………………. PRECAUTIONS: I) The board should be perfectly vertical. II) The pulleys should be moving freely and if not moving freely, lubricate them. III) The weights should not touch the board. IV) The weights of the pans should be added to the weight in the pan to find the total force in each string. V) The directions of forces should be marked only after the system has come to complete rest. VI) The direction of forces should be marked with the mirror strip by keeping the eye, string and its image in the same line. •••••••••
5APPLIED MECHANICS EXPERIMENT NO. 1 (B) AIM: VERIFICATION OF TRIANGLE LAW OF FORCES APPRATUS:- Gravesand‟s apparatus complete with two freely moving guide pulleys, weights, thread, a small central ring, white paper sheet, three scale pans, tape, a mirror strip, set squares and pencil. THEORY: The triangle law of forces states that if two forces acting on a particle can be represented in magnitude and direction by the two side of a triangle taken in order then their resultant will be given by the third side of the triangle taken in the opposite direction. PROCEDURE: I) Fix the paper sheet centrally on the board. II) Take suitable length of thread and pass it over two pulleys, the ends of thread are to be attached to pans which are to carry weights. III) Take another piece of thread and tie to the middle of first thread which is to carry another weight. IV) Place the weights in the pans in such a way that the knot-comes nearly in the middle of the paper. V) For ensuring free movement of pulleys, displace the pans from their original positions. VI) Mark the directions of the strings on the paper sheet with the help of a strip of mirror which is put under the string length – wise one by one to get points for the purpose. VII) Note the magnitude of forces and mark the lines of forces. VIII) Remove the paper from the apparatus and produce the forces line to meet at point O. IX) Name the forces, X, Y, Z, according the Bow‟s Notation as PQ, QR, and RS. X) Choose a suitable scale and draw the line Pq parallel to force X and cut it equal to the magnitude of X according to the scale chosen. Now from point q draw the line qr parallel to force Y according to the same scale. Find the magnitude of rp i.e. R which
6APPLIED MECHANICS should be equal to the third force Z which proves the triangle law of forces. XI) If the magnitude of r p varies from that of the forces QR, then percentage error = XII) Repeat the above procedure at least two times more by varying the loads and tabulate the results. OBSERVATIONS: Sr. No. Total weight PQ (X) Total weight QR (Y) Total Weight RP (Z) Resultant R‟ % age error Mean Value……………………………. PRECAUTIONS: I) The board should be perfectly vertical. II) The pulleys should be moving freely and if not moving freely, lubricate them. III) The weights should not touch the board. IV) The weights of the pans should be added to the weight in the pan to find the total force in each string. V) The directions of forces should be marked only after the system has come to complete rest. VI) The direction of forces should be marked with the mirror strip by keeping the eye, string and its image in the same line. •••••••••
7APPLIED MECHANICS EXPERIMENT NO. 1 (C) AIM: VERIFICATION OF POLYGON LAW OF FORCES APPRATUS:- Gravesand‟s apparatus complete with two freely moving guide pulleys, weights, thread, a small central ring, white paper sheet, three scale pans, tape, a mirror strip, set squares and pencil. THEORY: Polygon law of forces states that if a number of forces acting on a particle are represented in magnitude and direction by the sides of a polygon taken in the same order then their resultant is represented in magnitude and direction by the closing side of the polygon taken in the opposite direction. PROCEDURE: I) Fix the paper sheet centrally on a board with the help of cello tape. II) Tie five segments of thread to form a knot and pass four of them over the guide pulleys as shown figure LW-4. III) Put four weights one each into the pans of the strings passing over the pulleys. IV) Attach a pan to the free end of the middle string and put weight into it. V) Adjust the weights in the pans in such a way that the knot comes in the center of paper and allows the system to come in the rest position. VI) Put the mirror under the threads turn by turn and mark the points by keeping the eye, the thread and its image in the same line without disturbing the system. VII) Write down the magnitude of forces in each string which will be the same as the corresponding weights.
8APPLIED MECHANICS VIII) Draw the vector diagram with suitable scale by drawing vectors ab, bc, cd, de representing magnitude and directions of corresponding forces AB, BC, CD, DE as show in fig. LW- 5(a) IX) Join e to a and measure vector ea with the chosen scale. It should have the same magnitude and direction as that of the forces EA. X) The magnitude of ea is different from that of force EA, then percentage of error = XI) Repeat the above procedure at least two times more by varying loads and tabulate the results. OBSERVATIONS: Sr. No. Suspended Weights of Forces Force ea as determined graphically % age error = Q=W1 R=W2 S=W3 T=W4 P=W5 Mean Value……………………………. PRECAUTIONS: I) The board should be perfectly vertical. II) The pulleys should be moving freely and if not moving freely, lubricate them. III) The weights should not touch the board. IV) The weights of the pans should be added to the weight in the pan to find the total force in each string. V) The directions of forces should be marked only after the system has come to complete rest.
9APPLIED MECHANICS VI) The direction of forces should be marked with the mirror strip by keeping the eye, string and its image in the same line. •••••••••
10APPLIED MECHANICS EXPERIMENT NO. 2 AIM: TO VERIFY THE FORCES IN THE DIFFERENT MEMBERS OF A JIB CRANE. APPARATUS: Jib Crane apparatus, weights, meter rod, set squares, paper sheet cello tape etc. THEORY: This experiment is based on the triangle law of forces. According to this law if two forces acting on a body can be represented in magnitude and direction by the two side of a triangle taken in order, then their resultant can be given by the third side of the triangle, taken in the opposite direction. Thus with the help of Jib Crane‟s apparatus the three forces i.e. known load, forces in the tie and that in the Jib are also calculated and the same are compared with the readings observed from the spring balances, there in. PROCEDURE: I) Note the zero error in the compression spring balance and the tension spring balance separately. II) Attach a known weight W with the hook of the hanging chain. III) Note the final reading of the spring balances separately.
11APPLIED MECHANICS IV) Subtract the initial reading from the final readings. The difference between the two readings of the spring balances will give the observed value of the forces in the tie and that of the compression spring. V) Measure the height of vertical post from the junction of jib to the junction of tie and the length of jib and length of tie. VI) From these measurements, to a suitable scale, draw the space diagram as shown in this fig LW-7(a) and name the members by Bow‟s Notation. VII) Draw ab parallel and equal to W to some convenient scale to draw vector diagram direction. VIII) Draw ca parallel to P and bc parallel to Q meeting at c moving in anticlockwise respectively. IX) Compare the calculated values of the forces to that of the observed values and determine the percentage error if any. X) Repeat the experiment twice by changing the load. OBSERVATIONS: Height of Post = Length of tie = Length of Jib = Scale …………… PRECAUTIONS: I) The weight should be hung to the hook gently. The initial readings of balances should be taken into account. II) The Jib and the tie spring balances must be properly oiled for free movement. III) The measurement of length should be done accurately. IV) The space and force diagram should be carefully and accurately.
12APPLIED MECHANICS %errorCalculated forceinkg TiePJibQ Observedforce fromspring balancesinkg Tie=P1Jib=Q1 Final reading on balance inkg TieJib Initial spring Reading inKg TieJib Lengthof members RPQRPQ Weight W kg Sr. No.
13APPLIED MECHANICS EXPERIMENT NO. 3 AIM: To verify the reactions at the supports of a simply supported beam. APPARATUS: A parallel forces apparatus consisting of a wooden beam, two compression balances, weights, threads, hooks etc. THEORY: The experiment is based upon the fundamental principle of equilibrium which states that if a stationary body, subjected to coplanar forces, is in equilibrium, the algebraic sum of all the forces and their moments about any point lying in their plane, is zero. 1) The algebraic sum of vertical forces i.e. ∑F = 0 2) The algebraic sum of moments about a point must be zero i.e. ∑M = 0 PROCEDURE: I) Place the graduated beam on the compression spring balances. II) Either adjust the spring balances to zero reading with the help of adjusting screw or note the initial reading zero reading. III) Place sliding hooks at different point on the beam and suspend different weights. IV) Note down the final readings on the spring balance S1 and S2. These are called observed readings. V) Note down the distance of each weight from any one support say from left. VI) Take the moments about eh support to calculate the reaction. The second reaction may be found by subtraction first reaction from total vertical load. If there is difference in the observed and the calculated reactions and then calculate the percentage error. VII) Repeat the experiment by taking different load at different places.
14APPLIED MECHANICS OBSERVATIONS AND CALCULATIONS:%Errorinreactionsatthe support B=A= Calculated reactions RBRA Distanceof loadfrom supportA X3X2X1 Weight Suspended W 3 W2W1 Observe d Reaction at RBRA Final Readingof Balanceat BA Initial Readingsof Balanceat BA Sr.No. 1 2 3
15APPLIED MECHANICS By taking moments about A ( ) % age error in the reaction at support A = ……….. % age error in the reaction at support B = ……….. PRECAUTIONS: 1. The apparatus should be placed perfectly horizontal. 2. The balances should be adjusted to zero after placing the beam on the compression spring balance. 3. The hooks should be place in the groves of the beam. 4. The weights are hung to the hooks gently. 5. The measurement of distances of weights should be done from one end. •••••••••
16APPLIED MECHANICS EXPERIMENT NO. 4 AIM: TO FIND OUT MECHANICAL ADVANTAGE, VELOCITY RATIO AND EFFICIENCY IN CASE OF AN INCLINED PLANE. APPARATUS: Inclined plane apparatus, slider Block, Weight box, pan, thread, meter rod, paper sheet, set squares etc. THEORY: When a body moves or tends to move over another body its motion is opposed by a resistance along the surfaces in contact of the two bodies. The resistance so caused is called force of friction of friction. Consider a body move up the inclined pane when a force P is applied. Resolving W into two components. Mechanical advantage (M.A) = Velocity ratio (V.R) = Suppose an effort P moved down through one centimeter, moving the load along the plane = 1 cm. Therefore, Vertical up V.R =
17APPLIED MECHANICS % efficiency = M.A/V.R x100 = ……. PROCEDURE: 1. Take the suitable inclined plane apparatus and set the plane at a suitable angle. 2. Place the slider block on the inclined plane and pass the thread over the frictionless pulley. Let the pan hangs vertically downwards. 3. Note the weights of block and pan. Put some weights in the slider block and add extra weights in the pan gradually till the slider just tends to slide over the inclined plane in the upward direction. 4. Note the extra weights placed on the pan, add to it the weight of the pan, find out the total weight which will be effort P applied to move the slider block up the inclined plane. 5. Calculate mechanical advantage, velocity ratio and efficiency as explained and tabulate. 6. Repeat the experiment twice more by varying the load in the slider block. OBSERVATIONS: Nature of surface………….. Sr. No. Weight of slider block W. kg Weight of pan + wts. In pan = P kg Inclination of Plane % age efficiency = M.A. = W/P V.R = cosec % efficiency = M.A/V.R x100 1 2 3 PRECAUTIONS: 1. The inclined plane should be smooth and clean. 2. There should be no friction in the pulley. Proper lubrication should be done to make it frictionless. 3. The weights should be placed gently on the pan. 4. The thread used should be free from knots. 5. The weights should be increased gradually to such a limit that the slider block just begins to move slowly and not abruptly. •••••••••
18APPLIED MECHANICS EXPERIMENT NO. 5 AIM: TO FIND THE MECHANICAL ADVANTAGE, VELOCITY RATIO AND EFFICIENCY OF SIMPLE SCREW JACK. APPARATUS: Screw jack apparatus, pans, weights, string, vernier calipers, meter rod etc. Theory: The screw jack is a simple machine by means of which heavy loads can be raised with the application of small effort. It works on the principle of screw and nut. The screw is rotated with the help of a tommy bar at the end of which an effort is applied. By doing so, the screw passing through the nut is raised and so is the load placed on its head. The screw jack show in Figure is only experimental. It consist of a square threaded screw which is provide with double flanged circular table at its top to carry load to be lifted. The heavy body is providing with the two pulleys to hang the loads which act as an effort. Let the pitch of the screw be p and D the diameter of the flanged table on which the load W is to be placed and lifted. Let the table turns through one revolution. Then, the distance through which load rises in one revolution = p Effort moved in one revolution = πD Weight on the table = W kg
19APPLIED MECHANICS P = Total effort in the two pans including the weights of pans. PROCEDURE: I. Measure the circumference of the flanged table with the help of an inextensible thread or measure the diameter of table with an outside calipers. II. Measure the pitch of thread with the help of vernier calipers. III. Wrap the string round the circumference of the flanged table and pass it over one pulley. Similarly warp another string over the circumference of flanged table and pass it over the second pulley. The free ends of both the strings be tied to two pans in which the weights are to be placed. IV. Note down the weight of each pan. V. Place the load W on the top of the table and start adding weight in to the pans so that the load W is just lifted, the effort P is equal to the sum of weights placed on both the pans. VI. Calculate the M.A., V.R. and & in each case. VII. Repeat the experiment twice more by varying the load on the top of the table and in the pans. OBSERVATIONS: Sr. No. Circumference of the Table = Pitch of Screw P cm Velocity Ratio = Weight on Table = W N Total Effort P = P1 + P2 + wt. of pans M.A = W/ P 1 2 3 PRECAUTIONS: 1. The circumference of the disc and the pitch of the screw should be measure precisely. 2. Use both the pulleys to find the total thrust. 3. Lubricate the screw adequately to decrease friction. 4. Make use of both the pulley to find the total effort applied. 5. Put the weights in the pans gently. 6. The string should not overlap on the disc.
20APPLIED MECHANICS EXPERIMENT NO. 6 AIM: TO FIND THE MECHANICAL ADVANTAGE, VELOCITY RATIO, AND EFFICIENCY OF A WORM AND WORM WHEEL. APPARATUS: Worm and worm wheel apparatus, weights string, meter rod, outside calipers, pan etc. THEORY: The apparatus consist of a horizontal spindle having worm provided on it. It is supported between two bearings. On the overhanging portion of the spindle a pulley is provided to which is attached a string, carrying pan to its free end where effort is applied. The worm is engaged to the teeth of the worm wheel which has a projecting drum. Another string is provided on be drum to which weight to be hanged is hooked. Let, D= diameter of pulley attached to worm D = diameter of drum fixed on the wheel T = number of teeth on worm wheel. Assuming the worm thread having single start, when one revolution is given to the pulley only one thread of the worm wheel moves. Displacement of effort P = Displacement of load W = Velocity Ratio V.R =
21APPLIED MECHANICS Mechanical Advantage = % age x 100 PROCEDURE: 1. Measure the circumference of both the pulleys and the drum with the help of a string and meter rod. 2. Wrap the string round the pulley of the worm for effort and also wrap another string round the drum to carry the load. 3. Suspend a known weight W with the string from the drum and add weights in the pan, till the load just starts moving upwards. 4. Note down the weight in the effort pan. 5. Calculate the M.A., V.R. and % 6. Repeat the experiment at least twice more by varying the load. OBSERVATIONS: Wt. of scale pan = Diameter of pulley = Diameter of load drum = Number of teeth on the worn wheel = Sr. NO. Load W in kg Total effort, P in kg = wt. of pan + Wt. in pan M.A = W/P V.R = 1. 2. 3. Mean Value………………………………….. PRECAUTIONS: i) The bearings of the worm, spindle and teeth of worm-wheel should be well lubricated to decrease friction. ii) Weights on the effort pan should be put gently. iii) The string should not overlap on the pulley or on the drum. iv) The load and effort should not touch the walls. v) The load and effort should move slowly.
22APPLIED MECHANICS EXPERIMENT NO. 7 AIM: TO FIND THE MECHANICAL ADVANTAGE, VELOCITY RATIO AND EFFICIENCY OF A SINGLE PURCHASE WINCH CRAB. APPARATUS: Single purchase winch crab apparatus, pan, weights, meter rod, outside caliper, string etc. THEORY: It is used to carry the load. It consists of two axles‟ viz. effort axle and load axle. Both of these are mounted on a rigid frame which is fixed frame which is fixed on to a wall. The effort axle carries a pinion and a load axle has drum and a spur wheel which meshes with the pinion. Separate strings are wound on the drum and their free ends are attached to effort pan and load respectively. To find V.R., M.A., and efficiency of a single purchase winch crab, we may proceed as follows: Let load lifted = W Effort applied = P No. of teeth on the Pinion (A) = T1 No. of teeth on the Gear (B) = T2 Diameter of pulley = D Diameter of load drum = D Let the pulley revolves through one revolution. Distance moved by effort P = Number of revolutions of spur gear or the load drum = Distance moved by load = M.A. = W/P
23APPLIED MECHANICS %age efficiency = PROCEDURE: I) Count the number of teeth of the pinion and spur gear. II) With the help of string and meter rod measure circumference of the pulley and the drum. III) Wrap the string round the effort pulley and attach a scale pan to its free end. IV) Wrap the other string round the load drum in such a manner that as the effort is applied, the load is lifted up. V) Now suspend a load W with the free end of the string wound on the drum and add weights in the effort pan so that load starts moving up gradually. VI) Note down the values of W and P. VII) Calculate the V.R., M.A. and efficiency. VIII) Increase the load W and again find the value of P. IX) Repeat the experiment at least four times more. To represent graphically the load versus effort and load versus efficiency curves proceed as follows. The load lifted W is taken along the horizontal axis or X – Axis and the effort is taken along the vertical axis of Y – axis.
24APPLIED MECHANICS From the tabulated reading marks the points and join them to get a smooth curve. It is seen that even at zero value of load, some effort is required to overcome the friction of the machine. When the load is increase the effort required to life up the load also increases. To represent graphically load versus efficiency, process as given below: The load is taken along X – axis and the efficiency the Y – axis. By Marking load and efficiency point corresponding to the load considered a smooth curve as shown in the fig is completed. Observations: Number of teeth of pinion T1 = Number of teeth of spur gear T2 = Diameter of pulley D = Diameter of load drum, d = Sr. No. Load in W in Kg Effort, P in kg M.A = W/P V.R = 1. 2. 3. 4. 5. Mean Value…………………………………
25APPLIED MECHANICS PRECAUTIONS: 1. Lubricate the pinion and the spur wheel adequately to decrease friction. 2. The strings on the pulley and drum should not overlap. 3. The weights should be gently put in the scale pan. 4. Add the weight of pan in the total effort. 5. Number of teeth on the pinion and the gear should be carefully counted.
26APPLIED MECHANICS EXPERIMENT NO. 8 (A) AIM: TO DETERMINE THE MECHANICAL ADVANTAGE, VELOCITY RATIO AND EFFICIENCY OF THE FIRST SYSTEM OF PULLEYS. APPARATUS: Set of pulleys, scale pan, weights, strings, hooks, meter road, etc. THEORY: in the first system of pulley numbers of fixed strings are equal to the number of movable pulleys. In the figure, pulley number 4 is fixed whereas the others are movable. The pulleys are assumed to be frictionless and the strings passing over other different pulleys are as shown in figure. Let W be the weight to be lifted and it is hanged at the lowest pulley. When the effort P is applied at the free end of the string, it is moved downward by distance y. Therefore, Distance moved by pulley 3 = Distance move by pulley 2 = Distance moved by pulley 1 =
27APPLIED MECHANICS Therefore, distance moved by load (W) attached to pulley 1 = If there are „n‟ number of movable pulleys, the distance moved by the load = Therefore, V.R = Hence % efficiency = PROCEDURE: 1. Fix one end of the string passing round each pulley to the hook and the second end to the block of next pulley. 2. From the lowest pulley, suspend weight W (load). 3. Keep on adding weight in the effort pan till the load just starts moving up. 4. Note down the value of effort P and the weight W. 5. Note down the distance covered by P and W separately in a fixed time. 6. Calculate M.A., V.R., and hence the percentage efficiency. 7. Repeat the experiment for different loads. Sr. No. Load W Effort, P = Weight of pan + weights in pan M.A. = W/P Distance moved by the effort (y) Distance moved by the load (x) V.R = y/x 1. 2. 3. 4. Mean value…………………. PRECAUTIONS: 1. The string should be inextensible and light in weight. 2. The pulleys must be parallel to each other. 3. The pulleys must be well lubricated and free to move. 4. The weights should be placed gently in the pan. 5. The load and effort pan should not touch any object.
28APPLIED MECHANICS EXPERIMENT NO. 8 (B) AIM: TO DETERMINE THE MECHANICAL ADVANTAGE, VELOCITY RATIO AND EFFICIENCY OF SECOND SYSTEM OF PULLEYS. APPARATUS: Two blocks of pulley each contain two or three pulleys, weights, pan, meter rod etc. THEORY: It consists of two blocks of pulleys. The upper block is fixed to a support whereas the lower block is movable. Either the pulleys in the two blocks are equal or at least one pulley in the upper block is more that the lower block. The string is continuously passed over the pulley in the order as shown in figure. Let weight attached to the lower block is W. Let the weights is to be raised by a distance x. The each string of the two blocks will moved by distance x. The total distance through which the effort will have to move = Where n is the number of pulleys. Therefore, V.R = To obtain higher value of V.R., number of pulleys can be increased.
29APPLIED MECHANICS M.A. = W/P Therefore, percentage efficiency = PROCEDURE: I) Take one end of the string and pass it over all the pulleys as shown. II) From the lower block of pulleys, suspend weight W (load). III) Attach an effort pan to the free end of the string and place weight in it. The value of weight should be such that the load W just starts moving up. IV) Note down the value of effort P and the weight W. V) Note down the distance covered by P and W separately in a fixed time. VI) Calculate M.A.., V.R., and hence the percentage efficiency. VII) Repeat the experiment for different loads. Sr. No. Load W Effort, P = Weight of pan + weights in pan M.A. = W/P Distance moved by the effort (y) Distance moved by the load (x) V.R = y/x 1 2 3 Mean value……………………….. PRECAUTIONS: 1. The string should be inextensible and light in weight. 2. The pulleys must be parallel to each other. 3. The pulleys must be well lubricated and free to move. 4. The weight should be placed gently in the pan. 5. The load and effort pan should not touch any object.
30APPLIED MECHANICS EXPERIMENT NO. 9 (A) AIM: TO FIND OUT CENTER OF GRAVITY OF REGULAR LAMINA. APPARATUS: Regular lamina, A stand, Inextensible string, meter rod, pencil etc. THEORY: The center of gravity of a body is that point at which the whole weight of the body may be assumed to be acting. When the body is considered to be composed of infinite number of small weights each of which is acting vertically downward, then the point where the resultant of all of these small weights acts, gives the position of the center of gravity of the body. The center of gravity of a plane figure or lamina referred to as the centroid or center of area. A very thin sheet of any cross section is known as lamina. The center of gravity of irregular bodies is determined by the principle of free suspension of bodies, which is as stated below: If a body is suspended vertically with the help of a string, the forces which come into play are:- I) The weight of the body acting vertically downward through its C.G. II) The tension in the string.
31APPLIED MECHANICS PROCEDURE: I) Take a lamina of any regular shape of some suitable material. II) Tie the string at point A as shown in figure. III) Suspend the lamina vertically by fixing the other end of the string to the stand and drawing line along the plumb line. IV) Now suspend the lamina at some other suitable point so that the lamina is suspended vertically and again draws the line along the plumb line. V) The center of gravity of the lamina will be the point where these two plumb lines intersect. VI) Suspended the lamina at another point C and draw the plumb line, which should pass through the C.G center of gravity already located. PRECAUTIONS: I) The lamina should be of perfectly uniform mass. II) The point of suspension should be quite small. III) Draw the plumb line when lamina and string come to rest. IV) The thickness of the lamina should be uniform.
32APPLIED MECHANICS EXPERIMENT NO. 9 (B) AIM: TO FIND OUT THE CENTER OF GRAVITY OF IRREGULAR LAMINA. APPARATUS: i) Irregular Lamina ii) Stand iii) Inextensible string iv) Meter rod and pencil. PROCEDURE: I) Take the lamina of irregular shape of some suitable material. II) Tie the string at point A as shown in figure. III) Suspend the lamina vertically by fixing other end of the string to the stand and drawing line along the plumb line IV) Now suspend the lamina vertically at some other suitable point B and again draw the line along the plumb line. V) The center of gravity of the lamina will be the point where these two plumb line intersect. VI) Suspend the lamina at another point C and draw the plumb line, which should pass through the center of gravity already located. PRECAUTIONS: I) The lamina should be of perfectly uniform mass. II) The point of suspension should be quite small. III) Draw the plumb line when lamina and string come to rest. IV) The thickness of the lamina should be uniform.
33APPLIED MECHANICS EXPERIMENT NO. 10 AIM: TO DETERMINE COEFFICIENT OF FRICTION BETWEEN 3 PAIRS OF RUBBER SURFACES. (WOOD GLASS, RUBBER, LEATHER AND GLASS). APPARATUS: Horizontal plane apparatus, weight box, pan, thread, wooden block, glass plate rubber piece and leather piece etc. Theory: The coefficient of friction is the ratio of limiting force of friction to the normal reaction. Let a wooden block of weight W be placed on the rough horizontal plane and this block is just allowed to move by applying a pull „P‟ as show in Fig. If “F” be the limiting friction and “R” be the normal reaction. The weights of the block W acts vertically downwards. The normal reaction R acting vertically upward and when the block is in equilibrium given as ; R = W. If a force „P‟ is applied in a direction parallel to the surface by putting weights in the pan. A force of Friction „F‟ tends to oppose the motion in a direction opposite to „P‟. IN equilibrium state; R = W and F= P PROCEDURE: (WOOD AND GLASS) I) Note down the weight of the block and the pan. II) Place the glass plate on the horizontal plane. III) Mark a particular region on the horizontal plane. IV) Place the wooden block in this region. Tie the thread to the hook of the block and pass over a smooth pulley fixed on the edge of the apparatus and tie the pan to the free end of the thread. V) Add some weights on the block as well as into the pan. VI) Go on increasing the weights into0 the pan till the block just beings to move. VII) Note down the weights of the block as well as the pan. VIII) Repeat the practical by putting different weights to the block and final out the difference values of weight in the pan.
34APPLIED MECHANICS IX) Calculate the coefficient of friction „ ‟ between wood and glass. X) Similarly take out other pairs of surface .i.e., rubber and glass and leather and glass one by one and repeat the above procedure systematically covering all the steps and calculate the value of coefficient of friction. OBSERVATIONS: S.No. Weight of block + weight added in the block „W‟ in kg Weight of pan + weight added in the pan “P” in kg 1. 2. 3. RESULT: I) Coefficient of friction between wood and glass…………. II) Coefficient of friction between rubber and glass……………. III) Coefficient of friction between leather and glass…………………. PRECAUTIONS: 1. Lubricate the pulley to minimize friction. 2. The thread should be knot free. 3. The plane should be kept perfectly horizontal. 4. The weights in the pan should be added gently.

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Applied mechanics lab manual

  • 2. 2APPLIED MECHANICS LIST OF PRACTICALS 1. Verification of the following laws: a) Parallelogram law of forces. b) Triangle law of forces. c) Polygon law of forces. 2. To verify the forces in different members of jib crane. 3. To verify the reaction at the supports of a simply supported beam. 4. To find the mechanical advantage, velocity ratio and efficiency in case of inclined plane. 5. To find the mechanical advantage (M.A), velocity ratio (V.R) and efficiency (η) of a screw jack. 6. To find the mechanical advantage, velocity ratio and efficiency of worm and worm wheel. 7. To find mechanical advantage, velocity ratio and efficiency of single purchase winch crab. 8. To find M.A, V.R, and cof : a) First system of pulleys b) Second system of pulleys. 9. To find out center of gravity of: a) Regular lamina b) Irregular lamina. 10. To determine coefficient of friction between three pairs of given surface.
  • 3. 3APPLIED MECHANICS EXPERIMENT NO. 1 (A) AIM: VERIFICATION OF PARALLELOGRAM LAW OF FORCES APPRATUS:- Gravesand‟s apparatus complete with two freely moving guide pulleys, weights, thread, a small central ring, white paper sheet, three scale pans, tape, a mirror strip, set squares and pencil. THEORY: The „Parallelogram Law of forces‟ states that if a particle is acted upon by two forces represented in magnitude and direction by the two sides of a parallelogram drawn from a point, then the resultant is completely represented by the diagonal passing through the same point. PROCEDURE: I) Take any point O on the plane of paper and draw a line OA Parallel to forces Z. Similarly draw a line OB parallel to force X. II) Complete the parallelogram OAC‟B as shown in fig. 2 III) Join O to C‟ which is the diagonal of the parallelogram OC‟ to the given scale gives the resultant of forces X and Z.
  • 4. 4APPLIED MECHANICS IV) Draw a line OC equal and opposite to OC‟ which should be equal to the third force Y. OBSERVATIONS: Sr. No. Total weight PQ (X) Total weight QR (Y) Total Weight RP (Z) Resultant R‟ % age error Mean Value……………………………. PRECAUTIONS: I) The board should be perfectly vertical. II) The pulleys should be moving freely and if not moving freely, lubricate them. III) The weights should not touch the board. IV) The weights of the pans should be added to the weight in the pan to find the total force in each string. V) The directions of forces should be marked only after the system has come to complete rest. VI) The direction of forces should be marked with the mirror strip by keeping the eye, string and its image in the same line. •••••••••
  • 5. 5APPLIED MECHANICS EXPERIMENT NO. 1 (B) AIM: VERIFICATION OF TRIANGLE LAW OF FORCES APPRATUS:- Gravesand‟s apparatus complete with two freely moving guide pulleys, weights, thread, a small central ring, white paper sheet, three scale pans, tape, a mirror strip, set squares and pencil. THEORY: The triangle law of forces states that if two forces acting on a particle can be represented in magnitude and direction by the two side of a triangle taken in order then their resultant will be given by the third side of the triangle taken in the opposite direction. PROCEDURE: I) Fix the paper sheet centrally on the board. II) Take suitable length of thread and pass it over two pulleys, the ends of thread are to be attached to pans which are to carry weights. III) Take another piece of thread and tie to the middle of first thread which is to carry another weight. IV) Place the weights in the pans in such a way that the knot-comes nearly in the middle of the paper. V) For ensuring free movement of pulleys, displace the pans from their original positions. VI) Mark the directions of the strings on the paper sheet with the help of a strip of mirror which is put under the string length – wise one by one to get points for the purpose. VII) Note the magnitude of forces and mark the lines of forces. VIII) Remove the paper from the apparatus and produce the forces line to meet at point O. IX) Name the forces, X, Y, Z, according the Bow‟s Notation as PQ, QR, and RS. X) Choose a suitable scale and draw the line Pq parallel to force X and cut it equal to the magnitude of X according to the scale chosen. Now from point q draw the line qr parallel to force Y according to the same scale. Find the magnitude of rp i.e. R which
  • 6. 6APPLIED MECHANICS should be equal to the third force Z which proves the triangle law of forces. XI) If the magnitude of r p varies from that of the forces QR, then percentage error = XII) Repeat the above procedure at least two times more by varying the loads and tabulate the results. OBSERVATIONS: Sr. No. Total weight PQ (X) Total weight QR (Y) Total Weight RP (Z) Resultant R‟ % age error Mean Value……………………………. PRECAUTIONS: I) The board should be perfectly vertical. II) The pulleys should be moving freely and if not moving freely, lubricate them. III) The weights should not touch the board. IV) The weights of the pans should be added to the weight in the pan to find the total force in each string. V) The directions of forces should be marked only after the system has come to complete rest. VI) The direction of forces should be marked with the mirror strip by keeping the eye, string and its image in the same line. •••••••••
  • 7. 7APPLIED MECHANICS EXPERIMENT NO. 1 (C) AIM: VERIFICATION OF POLYGON LAW OF FORCES APPRATUS:- Gravesand‟s apparatus complete with two freely moving guide pulleys, weights, thread, a small central ring, white paper sheet, three scale pans, tape, a mirror strip, set squares and pencil. THEORY: Polygon law of forces states that if a number of forces acting on a particle are represented in magnitude and direction by the sides of a polygon taken in the same order then their resultant is represented in magnitude and direction by the closing side of the polygon taken in the opposite direction. PROCEDURE: I) Fix the paper sheet centrally on a board with the help of cello tape. II) Tie five segments of thread to form a knot and pass four of them over the guide pulleys as shown figure LW-4. III) Put four weights one each into the pans of the strings passing over the pulleys. IV) Attach a pan to the free end of the middle string and put weight into it. V) Adjust the weights in the pans in such a way that the knot comes in the center of paper and allows the system to come in the rest position. VI) Put the mirror under the threads turn by turn and mark the points by keeping the eye, the thread and its image in the same line without disturbing the system. VII) Write down the magnitude of forces in each string which will be the same as the corresponding weights.
  • 8. 8APPLIED MECHANICS VIII) Draw the vector diagram with suitable scale by drawing vectors ab, bc, cd, de representing magnitude and directions of corresponding forces AB, BC, CD, DE as show in fig. LW- 5(a) IX) Join e to a and measure vector ea with the chosen scale. It should have the same magnitude and direction as that of the forces EA. X) The magnitude of ea is different from that of force EA, then percentage of error = XI) Repeat the above procedure at least two times more by varying loads and tabulate the results. OBSERVATIONS: Sr. No. Suspended Weights of Forces Force ea as determined graphically % age error = Q=W1 R=W2 S=W3 T=W4 P=W5 Mean Value……………………………. PRECAUTIONS: I) The board should be perfectly vertical. II) The pulleys should be moving freely and if not moving freely, lubricate them. III) The weights should not touch the board. IV) The weights of the pans should be added to the weight in the pan to find the total force in each string. V) The directions of forces should be marked only after the system has come to complete rest.
  • 9. 9APPLIED MECHANICS VI) The direction of forces should be marked with the mirror strip by keeping the eye, string and its image in the same line. •••••••••
  • 10. 10APPLIED MECHANICS EXPERIMENT NO. 2 AIM: TO VERIFY THE FORCES IN THE DIFFERENT MEMBERS OF A JIB CRANE. APPARATUS: Jib Crane apparatus, weights, meter rod, set squares, paper sheet cello tape etc. THEORY: This experiment is based on the triangle law of forces. According to this law if two forces acting on a body can be represented in magnitude and direction by the two side of a triangle taken in order, then their resultant can be given by the third side of the triangle, taken in the opposite direction. Thus with the help of Jib Crane‟s apparatus the three forces i.e. known load, forces in the tie and that in the Jib are also calculated and the same are compared with the readings observed from the spring balances, there in. PROCEDURE: I) Note the zero error in the compression spring balance and the tension spring balance separately. II) Attach a known weight W with the hook of the hanging chain. III) Note the final reading of the spring balances separately.
  • 11. 11APPLIED MECHANICS IV) Subtract the initial reading from the final readings. The difference between the two readings of the spring balances will give the observed value of the forces in the tie and that of the compression spring. V) Measure the height of vertical post from the junction of jib to the junction of tie and the length of jib and length of tie. VI) From these measurements, to a suitable scale, draw the space diagram as shown in this fig LW-7(a) and name the members by Bow‟s Notation. VII) Draw ab parallel and equal to W to some convenient scale to draw vector diagram direction. VIII) Draw ca parallel to P and bc parallel to Q meeting at c moving in anticlockwise respectively. IX) Compare the calculated values of the forces to that of the observed values and determine the percentage error if any. X) Repeat the experiment twice by changing the load. OBSERVATIONS: Height of Post = Length of tie = Length of Jib = Scale …………… PRECAUTIONS: I) The weight should be hung to the hook gently. The initial readings of balances should be taken into account. II) The Jib and the tie spring balances must be properly oiled for free movement. III) The measurement of length should be done accurately. IV) The space and force diagram should be carefully and accurately.
  • 13. 13APPLIED MECHANICS EXPERIMENT NO. 3 AIM: To verify the reactions at the supports of a simply supported beam. APPARATUS: A parallel forces apparatus consisting of a wooden beam, two compression balances, weights, threads, hooks etc. THEORY: The experiment is based upon the fundamental principle of equilibrium which states that if a stationary body, subjected to coplanar forces, is in equilibrium, the algebraic sum of all the forces and their moments about any point lying in their plane, is zero. 1) The algebraic sum of vertical forces i.e. ∑F = 0 2) The algebraic sum of moments about a point must be zero i.e. ∑M = 0 PROCEDURE: I) Place the graduated beam on the compression spring balances. II) Either adjust the spring balances to zero reading with the help of adjusting screw or note the initial reading zero reading. III) Place sliding hooks at different point on the beam and suspend different weights. IV) Note down the final readings on the spring balance S1 and S2. These are called observed readings. V) Note down the distance of each weight from any one support say from left. VI) Take the moments about eh support to calculate the reaction. The second reaction may be found by subtraction first reaction from total vertical load. If there is difference in the observed and the calculated reactions and then calculate the percentage error. VII) Repeat the experiment by taking different load at different places.
  • 14. 14APPLIED MECHANICS OBSERVATIONS AND CALCULATIONS:%Errorinreactionsatthe support B=A= Calculated reactions RBRA Distanceof loadfrom supportA X3X2X1 Weight Suspended W 3 W2W1 Observe d Reaction at RBRA Final Readingof Balanceat BA Initial Readingsof Balanceat BA Sr.No. 1 2 3
  • 15. 15APPLIED MECHANICS By taking moments about A ( ) % age error in the reaction at support A = ……….. % age error in the reaction at support B = ……….. PRECAUTIONS: 1. The apparatus should be placed perfectly horizontal. 2. The balances should be adjusted to zero after placing the beam on the compression spring balance. 3. The hooks should be place in the groves of the beam. 4. The weights are hung to the hooks gently. 5. The measurement of distances of weights should be done from one end. •••••••••
  • 16. 16APPLIED MECHANICS EXPERIMENT NO. 4 AIM: TO FIND OUT MECHANICAL ADVANTAGE, VELOCITY RATIO AND EFFICIENCY IN CASE OF AN INCLINED PLANE. APPARATUS: Inclined plane apparatus, slider Block, Weight box, pan, thread, meter rod, paper sheet, set squares etc. THEORY: When a body moves or tends to move over another body its motion is opposed by a resistance along the surfaces in contact of the two bodies. The resistance so caused is called force of friction of friction. Consider a body move up the inclined pane when a force P is applied. Resolving W into two components. Mechanical advantage (M.A) = Velocity ratio (V.R) = Suppose an effort P moved down through one centimeter, moving the load along the plane = 1 cm. Therefore, Vertical up V.R =
  • 17. 17APPLIED MECHANICS % efficiency = M.A/V.R x100 = ……. PROCEDURE: 1. Take the suitable inclined plane apparatus and set the plane at a suitable angle. 2. Place the slider block on the inclined plane and pass the thread over the frictionless pulley. Let the pan hangs vertically downwards. 3. Note the weights of block and pan. Put some weights in the slider block and add extra weights in the pan gradually till the slider just tends to slide over the inclined plane in the upward direction. 4. Note the extra weights placed on the pan, add to it the weight of the pan, find out the total weight which will be effort P applied to move the slider block up the inclined plane. 5. Calculate mechanical advantage, velocity ratio and efficiency as explained and tabulate. 6. Repeat the experiment twice more by varying the load in the slider block. OBSERVATIONS: Nature of surface………….. Sr. No. Weight of slider block W. kg Weight of pan + wts. In pan = P kg Inclination of Plane % age efficiency = M.A. = W/P V.R = cosec % efficiency = M.A/V.R x100 1 2 3 PRECAUTIONS: 1. The inclined plane should be smooth and clean. 2. There should be no friction in the pulley. Proper lubrication should be done to make it frictionless. 3. The weights should be placed gently on the pan. 4. The thread used should be free from knots. 5. The weights should be increased gradually to such a limit that the slider block just begins to move slowly and not abruptly. •••••••••
  • 18. 18APPLIED MECHANICS EXPERIMENT NO. 5 AIM: TO FIND THE MECHANICAL ADVANTAGE, VELOCITY RATIO AND EFFICIENCY OF SIMPLE SCREW JACK. APPARATUS: Screw jack apparatus, pans, weights, string, vernier calipers, meter rod etc. Theory: The screw jack is a simple machine by means of which heavy loads can be raised with the application of small effort. It works on the principle of screw and nut. The screw is rotated with the help of a tommy bar at the end of which an effort is applied. By doing so, the screw passing through the nut is raised and so is the load placed on its head. The screw jack show in Figure is only experimental. It consist of a square threaded screw which is provide with double flanged circular table at its top to carry load to be lifted. The heavy body is providing with the two pulleys to hang the loads which act as an effort. Let the pitch of the screw be p and D the diameter of the flanged table on which the load W is to be placed and lifted. Let the table turns through one revolution. Then, the distance through which load rises in one revolution = p Effort moved in one revolution = πD Weight on the table = W kg
  • 19. 19APPLIED MECHANICS P = Total effort in the two pans including the weights of pans. PROCEDURE: I. Measure the circumference of the flanged table with the help of an inextensible thread or measure the diameter of table with an outside calipers. II. Measure the pitch of thread with the help of vernier calipers. III. Wrap the string round the circumference of the flanged table and pass it over one pulley. Similarly warp another string over the circumference of flanged table and pass it over the second pulley. The free ends of both the strings be tied to two pans in which the weights are to be placed. IV. Note down the weight of each pan. V. Place the load W on the top of the table and start adding weight in to the pans so that the load W is just lifted, the effort P is equal to the sum of weights placed on both the pans. VI. Calculate the M.A., V.R. and & in each case. VII. Repeat the experiment twice more by varying the load on the top of the table and in the pans. OBSERVATIONS: Sr. No. Circumference of the Table = Pitch of Screw P cm Velocity Ratio = Weight on Table = W N Total Effort P = P1 + P2 + wt. of pans M.A = W/ P 1 2 3 PRECAUTIONS: 1. The circumference of the disc and the pitch of the screw should be measure precisely. 2. Use both the pulleys to find the total thrust. 3. Lubricate the screw adequately to decrease friction. 4. Make use of both the pulley to find the total effort applied. 5. Put the weights in the pans gently. 6. The string should not overlap on the disc.
  • 20. 20APPLIED MECHANICS EXPERIMENT NO. 6 AIM: TO FIND THE MECHANICAL ADVANTAGE, VELOCITY RATIO, AND EFFICIENCY OF A WORM AND WORM WHEEL. APPARATUS: Worm and worm wheel apparatus, weights string, meter rod, outside calipers, pan etc. THEORY: The apparatus consist of a horizontal spindle having worm provided on it. It is supported between two bearings. On the overhanging portion of the spindle a pulley is provided to which is attached a string, carrying pan to its free end where effort is applied. The worm is engaged to the teeth of the worm wheel which has a projecting drum. Another string is provided on be drum to which weight to be hanged is hooked. Let, D= diameter of pulley attached to worm D = diameter of drum fixed on the wheel T = number of teeth on worm wheel. Assuming the worm thread having single start, when one revolution is given to the pulley only one thread of the worm wheel moves. Displacement of effort P = Displacement of load W = Velocity Ratio V.R =
  • 21. 21APPLIED MECHANICS Mechanical Advantage = % age x 100 PROCEDURE: 1. Measure the circumference of both the pulleys and the drum with the help of a string and meter rod. 2. Wrap the string round the pulley of the worm for effort and also wrap another string round the drum to carry the load. 3. Suspend a known weight W with the string from the drum and add weights in the pan, till the load just starts moving upwards. 4. Note down the weight in the effort pan. 5. Calculate the M.A., V.R. and % 6. Repeat the experiment at least twice more by varying the load. OBSERVATIONS: Wt. of scale pan = Diameter of pulley = Diameter of load drum = Number of teeth on the worn wheel = Sr. NO. Load W in kg Total effort, P in kg = wt. of pan + Wt. in pan M.A = W/P V.R = 1. 2. 3. Mean Value………………………………….. PRECAUTIONS: i) The bearings of the worm, spindle and teeth of worm-wheel should be well lubricated to decrease friction. ii) Weights on the effort pan should be put gently. iii) The string should not overlap on the pulley or on the drum. iv) The load and effort should not touch the walls. v) The load and effort should move slowly.
  • 22. 22APPLIED MECHANICS EXPERIMENT NO. 7 AIM: TO FIND THE MECHANICAL ADVANTAGE, VELOCITY RATIO AND EFFICIENCY OF A SINGLE PURCHASE WINCH CRAB. APPARATUS: Single purchase winch crab apparatus, pan, weights, meter rod, outside caliper, string etc. THEORY: It is used to carry the load. It consists of two axles‟ viz. effort axle and load axle. Both of these are mounted on a rigid frame which is fixed frame which is fixed on to a wall. The effort axle carries a pinion and a load axle has drum and a spur wheel which meshes with the pinion. Separate strings are wound on the drum and their free ends are attached to effort pan and load respectively. To find V.R., M.A., and efficiency of a single purchase winch crab, we may proceed as follows: Let load lifted = W Effort applied = P No. of teeth on the Pinion (A) = T1 No. of teeth on the Gear (B) = T2 Diameter of pulley = D Diameter of load drum = D Let the pulley revolves through one revolution. Distance moved by effort P = Number of revolutions of spur gear or the load drum = Distance moved by load = M.A. = W/P
  • 23. 23APPLIED MECHANICS %age efficiency = PROCEDURE: I) Count the number of teeth of the pinion and spur gear. II) With the help of string and meter rod measure circumference of the pulley and the drum. III) Wrap the string round the effort pulley and attach a scale pan to its free end. IV) Wrap the other string round the load drum in such a manner that as the effort is applied, the load is lifted up. V) Now suspend a load W with the free end of the string wound on the drum and add weights in the effort pan so that load starts moving up gradually. VI) Note down the values of W and P. VII) Calculate the V.R., M.A. and efficiency. VIII) Increase the load W and again find the value of P. IX) Repeat the experiment at least four times more. To represent graphically the load versus effort and load versus efficiency curves proceed as follows. The load lifted W is taken along the horizontal axis or X – Axis and the effort is taken along the vertical axis of Y – axis.
  • 24. 24APPLIED MECHANICS From the tabulated reading marks the points and join them to get a smooth curve. It is seen that even at zero value of load, some effort is required to overcome the friction of the machine. When the load is increase the effort required to life up the load also increases. To represent graphically load versus efficiency, process as given below: The load is taken along X – axis and the efficiency the Y – axis. By Marking load and efficiency point corresponding to the load considered a smooth curve as shown in the fig is completed. Observations: Number of teeth of pinion T1 = Number of teeth of spur gear T2 = Diameter of pulley D = Diameter of load drum, d = Sr. No. Load in W in Kg Effort, P in kg M.A = W/P V.R = 1. 2. 3. 4. 5. Mean Value…………………………………
  • 25. 25APPLIED MECHANICS PRECAUTIONS: 1. Lubricate the pinion and the spur wheel adequately to decrease friction. 2. The strings on the pulley and drum should not overlap. 3. The weights should be gently put in the scale pan. 4. Add the weight of pan in the total effort. 5. Number of teeth on the pinion and the gear should be carefully counted.
  • 26. 26APPLIED MECHANICS EXPERIMENT NO. 8 (A) AIM: TO DETERMINE THE MECHANICAL ADVANTAGE, VELOCITY RATIO AND EFFICIENCY OF THE FIRST SYSTEM OF PULLEYS. APPARATUS: Set of pulleys, scale pan, weights, strings, hooks, meter road, etc. THEORY: in the first system of pulley numbers of fixed strings are equal to the number of movable pulleys. In the figure, pulley number 4 is fixed whereas the others are movable. The pulleys are assumed to be frictionless and the strings passing over other different pulleys are as shown in figure. Let W be the weight to be lifted and it is hanged at the lowest pulley. When the effort P is applied at the free end of the string, it is moved downward by distance y. Therefore, Distance moved by pulley 3 = Distance move by pulley 2 = Distance moved by pulley 1 =
  • 27. 27APPLIED MECHANICS Therefore, distance moved by load (W) attached to pulley 1 = If there are „n‟ number of movable pulleys, the distance moved by the load = Therefore, V.R = Hence % efficiency = PROCEDURE: 1. Fix one end of the string passing round each pulley to the hook and the second end to the block of next pulley. 2. From the lowest pulley, suspend weight W (load). 3. Keep on adding weight in the effort pan till the load just starts moving up. 4. Note down the value of effort P and the weight W. 5. Note down the distance covered by P and W separately in a fixed time. 6. Calculate M.A., V.R., and hence the percentage efficiency. 7. Repeat the experiment for different loads. Sr. No. Load W Effort, P = Weight of pan + weights in pan M.A. = W/P Distance moved by the effort (y) Distance moved by the load (x) V.R = y/x 1. 2. 3. 4. Mean value…………………. PRECAUTIONS: 1. The string should be inextensible and light in weight. 2. The pulleys must be parallel to each other. 3. The pulleys must be well lubricated and free to move. 4. The weights should be placed gently in the pan. 5. The load and effort pan should not touch any object.
  • 28. 28APPLIED MECHANICS EXPERIMENT NO. 8 (B) AIM: TO DETERMINE THE MECHANICAL ADVANTAGE, VELOCITY RATIO AND EFFICIENCY OF SECOND SYSTEM OF PULLEYS. APPARATUS: Two blocks of pulley each contain two or three pulleys, weights, pan, meter rod etc. THEORY: It consists of two blocks of pulleys. The upper block is fixed to a support whereas the lower block is movable. Either the pulleys in the two blocks are equal or at least one pulley in the upper block is more that the lower block. The string is continuously passed over the pulley in the order as shown in figure. Let weight attached to the lower block is W. Let the weights is to be raised by a distance x. The each string of the two blocks will moved by distance x. The total distance through which the effort will have to move = Where n is the number of pulleys. Therefore, V.R = To obtain higher value of V.R., number of pulleys can be increased.
  • 29. 29APPLIED MECHANICS M.A. = W/P Therefore, percentage efficiency = PROCEDURE: I) Take one end of the string and pass it over all the pulleys as shown. II) From the lower block of pulleys, suspend weight W (load). III) Attach an effort pan to the free end of the string and place weight in it. The value of weight should be such that the load W just starts moving up. IV) Note down the value of effort P and the weight W. V) Note down the distance covered by P and W separately in a fixed time. VI) Calculate M.A.., V.R., and hence the percentage efficiency. VII) Repeat the experiment for different loads. Sr. No. Load W Effort, P = Weight of pan + weights in pan M.A. = W/P Distance moved by the effort (y) Distance moved by the load (x) V.R = y/x 1 2 3 Mean value……………………….. PRECAUTIONS: 1. The string should be inextensible and light in weight. 2. The pulleys must be parallel to each other. 3. The pulleys must be well lubricated and free to move. 4. The weight should be placed gently in the pan. 5. The load and effort pan should not touch any object.
  • 30. 30APPLIED MECHANICS EXPERIMENT NO. 9 (A) AIM: TO FIND OUT CENTER OF GRAVITY OF REGULAR LAMINA. APPARATUS: Regular lamina, A stand, Inextensible string, meter rod, pencil etc. THEORY: The center of gravity of a body is that point at which the whole weight of the body may be assumed to be acting. When the body is considered to be composed of infinite number of small weights each of which is acting vertically downward, then the point where the resultant of all of these small weights acts, gives the position of the center of gravity of the body. The center of gravity of a plane figure or lamina referred to as the centroid or center of area. A very thin sheet of any cross section is known as lamina. The center of gravity of irregular bodies is determined by the principle of free suspension of bodies, which is as stated below: If a body is suspended vertically with the help of a string, the forces which come into play are:- I) The weight of the body acting vertically downward through its C.G. II) The tension in the string.
  • 31. 31APPLIED MECHANICS PROCEDURE: I) Take a lamina of any regular shape of some suitable material. II) Tie the string at point A as shown in figure. III) Suspend the lamina vertically by fixing the other end of the string to the stand and drawing line along the plumb line. IV) Now suspend the lamina at some other suitable point so that the lamina is suspended vertically and again draws the line along the plumb line. V) The center of gravity of the lamina will be the point where these two plumb lines intersect. VI) Suspended the lamina at another point C and draw the plumb line, which should pass through the C.G center of gravity already located. PRECAUTIONS: I) The lamina should be of perfectly uniform mass. II) The point of suspension should be quite small. III) Draw the plumb line when lamina and string come to rest. IV) The thickness of the lamina should be uniform.
  • 32. 32APPLIED MECHANICS EXPERIMENT NO. 9 (B) AIM: TO FIND OUT THE CENTER OF GRAVITY OF IRREGULAR LAMINA. APPARATUS: i) Irregular Lamina ii) Stand iii) Inextensible string iv) Meter rod and pencil. PROCEDURE: I) Take the lamina of irregular shape of some suitable material. II) Tie the string at point A as shown in figure. III) Suspend the lamina vertically by fixing other end of the string to the stand and drawing line along the plumb line IV) Now suspend the lamina vertically at some other suitable point B and again draw the line along the plumb line. V) The center of gravity of the lamina will be the point where these two plumb line intersect. VI) Suspend the lamina at another point C and draw the plumb line, which should pass through the center of gravity already located. PRECAUTIONS: I) The lamina should be of perfectly uniform mass. II) The point of suspension should be quite small. III) Draw the plumb line when lamina and string come to rest. IV) The thickness of the lamina should be uniform.
  • 33. 33APPLIED MECHANICS EXPERIMENT NO. 10 AIM: TO DETERMINE COEFFICIENT OF FRICTION BETWEEN 3 PAIRS OF RUBBER SURFACES. (WOOD GLASS, RUBBER, LEATHER AND GLASS). APPARATUS: Horizontal plane apparatus, weight box, pan, thread, wooden block, glass plate rubber piece and leather piece etc. Theory: The coefficient of friction is the ratio of limiting force of friction to the normal reaction. Let a wooden block of weight W be placed on the rough horizontal plane and this block is just allowed to move by applying a pull „P‟ as show in Fig. If “F” be the limiting friction and “R” be the normal reaction. The weights of the block W acts vertically downwards. The normal reaction R acting vertically upward and when the block is in equilibrium given as ; R = W. If a force „P‟ is applied in a direction parallel to the surface by putting weights in the pan. A force of Friction „F‟ tends to oppose the motion in a direction opposite to „P‟. IN equilibrium state; R = W and F= P PROCEDURE: (WOOD AND GLASS) I) Note down the weight of the block and the pan. II) Place the glass plate on the horizontal plane. III) Mark a particular region on the horizontal plane. IV) Place the wooden block in this region. Tie the thread to the hook of the block and pass over a smooth pulley fixed on the edge of the apparatus and tie the pan to the free end of the thread. V) Add some weights on the block as well as into the pan. VI) Go on increasing the weights into0 the pan till the block just beings to move. VII) Note down the weights of the block as well as the pan. VIII) Repeat the practical by putting different weights to the block and final out the difference values of weight in the pan.
  • 34. 34APPLIED MECHANICS IX) Calculate the coefficient of friction „ ‟ between wood and glass. X) Similarly take out other pairs of surface .i.e., rubber and glass and leather and glass one by one and repeat the above procedure systematically covering all the steps and calculate the value of coefficient of friction. OBSERVATIONS: S.No. Weight of block + weight added in the block „W‟ in kg Weight of pan + weight added in the pan “P” in kg 1. 2. 3. RESULT: I) Coefficient of friction between wood and glass…………. II) Coefficient of friction between rubber and glass……………. III) Coefficient of friction between leather and glass…………………. PRECAUTIONS: 1. Lubricate the pulley to minimize friction. 2. The thread should be knot free. 3. The plane should be kept perfectly horizontal. 4. The weights in the pan should be added gently.