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MET 305 tutorial_5-gear_train

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hotman1991

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MET 305 MECHANICS OF MACHINES Student Name & No._____________________________ Date: ______________________________ Section: _______________________________________ Score: _____________________________ GEAR TRAINS 4.1 Introduction Sometimes, two or more gears are made to mesh with each other to transmit power from one shaft to another. Such a combination is called gear train or train of toothed wheels. The nature of the train used depends upon the velocity ratio required and the relative position of the axes of shafts. A gear train may consist of spur, bevel or spiral gears. 4.2 Design of Spur Gears Sometimes, the spur gears (i.e. driver and driven) are to be designed for the given velocity ratio and distance between the centers of their shafts. Let c = Distance between the centers of two shafts, n1 = Speed of the driver, T1 = Number of teeth on the driver, d1 = Pitch circle diameter of the driver, n2, T2 and d2 = Corresponding values for the driven or follower, and p = Circular pitch. We know that the distance between the centers of two shafts c = (d1+d2) ---- (1) and speed ratio or velocity ratio, n1/n2 = d2/d1 = T2/T1 -------- (2) From the above equations, we can conveniently find out the values of d1 and d2 (or N1 and N2) and the circular pitch (p). The values of N1and N2, as obtained above, may or may not be whole numbers. But in a gear since the number of its teeth is always a whole number, therefore a slight alterations must be made in the values of c, d1 and d2, so that the number of teeth in the two gears may be a complete number. Example 1 In an epicyclic gear train, an arm C carries two gears A and B having 36 and 45 teeth respectively. If the arm C rotates at 150 rpm. in the anticlockwise direction about the centre of the gear A which is fixed, determine the speed of gear B. If the gear A instead of being fixed makes 300 rpm. in the clockwise direction, what will be the speed of gear B?
MET 305 MECHANICS OF MACHINES Solution Given: TA = 36; TB = 45 ; nc = 150 rpm (anticlockwise) The gear train is shown below. Tabular method First of all prepare the table of motions as given below. Table of motions Step Conditions of motion Revolutions of elements Arm C Gear A Gear B TA = 36 TB = 45 1. Arm fixed-gear A rotates through + 1 0 +1 -TA/Tb revolution (i.e. 1 rev. anticlockwise) 2. Arm fixed-gear A rotates through + x 0 +x -x (TA/Tb) revolutions 3. Add + y revolutions to all elements +y x+y Y-x(TA/Tb) Speed of gear B when gear A is fixed. Since the speed of arm is 150 rpm. anticlockwise, therefore from the third row of the table, y = + 150 rpm. Also the gear A is fixed, therefore x + y = 0 Speed of gear B = y – x . TA/TB = 150 + 150 x 36/45 = + 270 rpm (anticlockwise) Ans. Speed of gear B when gear A makes 300 rpm. clockwise Since the gear A makes 300 rpm. clockwise, therefore from the third row of the table, x + y = - 300 or x = - 300 -y = - 300 - 150 = - 450 rpm Speed of gear B, nB = y-x-TA/TB= 150 + 450 ( 36/45) = + 510 rpm. = 510 rpm. (anticlockwise) Ans. Example 2 In a reverted epicyclic gear train, the arm A carries two gears B and C and a compound gear D - E. The gear B meshes with gear E and the gear C meshes with gear D. The number of teeth on gears B, C and D are 75, 30 and 90 respectively. Find the speed and direction of gear C when gear B is fixed and the arm A makes 100 rpm. clockwise.
MET 305 MECHANICS OF MACHINES Solution Given : TB= 75 ; TC= 30 ; TD= 90 ; nA= 100 rpm. (clockwise) The reverted epicyclic gear train is shown above. First find the number of teeth on gear E (NE). Since the number of teeth on each gear, for the same module, are proportional to their pitch circle diameters, therefore TE+TB = TC+TD TE = TC +TD – TB = 30 + 90 – 75 = 45 The table of motions is prepared as follows: Table of motions Revolutions of elements Step Conditions of motion Compound Gear B Gear C No Arm A gear D-E 75 30 90, 45 1. Arm fixed-compound gear D-E rotated through + 1 revolution ( i.e. 1 rev. 0 1 -TE/TB -TD/TC anticlockwise) 2. Arm fixed-compound gear D-E rotated 0 +x through + x revolutions - x (TE/TB) -x (TD/TC) 3. Add + y revolutions to all elements +y x+ y y- x (TE/TB) y-x (TD/TC) Since the gear B is fixed, therefore from the fourth row of the table, y- x (TE/TB) = 0 y – x (45/75) = 0. Also the arm A makes 100 rpm. clockwise, therefore y = -100 substituting we get x = - 166.67 speed of gear C, nc = y – x(TD/TC) = - 100 + 166.67 (90/30) = + 400 rpm (anticlockwise) Ans Compound Epicyclic Gear Train—Sun and Planet Gear A compound epicyclic gear train is shown below. It consists of two co-axial shafts S, and S2, an annulus gear A which is fixed, the compound gear (or planet gear) B-C, the sun gear D and the arm H. The annulus gear has internal teeth and the compound gear is carried by the arm and revolves freely on a pin of the arm H. The sun gear is co-axial with the annulus gear and the arm but independent of them. The annulus gear A meshes with the gear B and the sun gear D meshes with the gear C. It may be noted that when the annulus gear is fixed, the sun gear provides the drive and when the sun gear is fixed, the annulus gear provides the drive. In both cases, the arm acts as a follower. Note : The gear at the centre is called the sun gear and the gears whose axes move are called planet gears.
MET 305 MECHANICS OF MACHINES Arm (H) Compound epicyclic gear train In the simple example of epicyclic train shown below, the only gear left to take an output from, after putting inputs to sun and arm, is the planet. A more useful configuration is shown to which a ring gear has been added. This ring gear meshes with planet and pivots at O2. Therefore it can be easily made the output member. Most planetary trains will be arranged with ring gears to bring the planetary motion back to a grounded pivot. Note how the sun gear, ring gears, an arm are all brought out as concentric hollow shafts so that each can be accessed to tap its angular velocity and torque as an input or an output. Example 3 An epicyclic gear consists of three gears A, B and C as shown below. The gear A has 72 internal teeth and gear C has 32 external teeth. The gear B meshes with both A and C and is carried on an arm EF which rotates about the centre of A at 18 rpm. If the gear A is fixed, determine the speed of gears B and C.
MET 305 MECHANICS OF MACHINES Solution. Given : TA = 72 ; TC = 32 ; Speed of arm EF = 18 rpm. Considering the relative motion of rotation as shown below. Table of motions Step No. Conditions of motion Revolutions of elements Arm EF Gear C Gear B Gear A 1 Arm fixed, gear C rotates 0 1 -TC/TB -(TC/TB) (TB/TA) = through +1 revolution -TC/TA 2 Arm fixed, gear C rotates 0 +x -x(TC/TB) -x(TC/TA) through +x 3 Add +y to all elements +y x +y y-x(TC/TB) y-x(TC/TA) Speed of gear C We know that the speed of the arm is 18 rpm. therefore, y = 18 rpm. and the gear A is fixed, therefore y-x(NC/NA)= 0 x = 18(72/32) = 40.5 Speed of gear C = x+y = 40.5 + 18 = +58.5 rpm. in the direction of arm. Ans. Speed of gear B Let dA, dB and dc be the pitch circle diameters of gears A, B and C respectively. Therefore, from the geometry. dB + dc /2 = dA/2 ie. 2 dB + dc = dA
MET 305 MECHANICS OF MACHINES Since the number of teeth are proportional to their pitch circle diameters, therefore 2Tb + Tc = TA Tb = (72-32) / 2 = 20 Speed of gear B = y-x(TC/TB) = 18-40.5 (32/20) = - 46.8 rpm. in the opposite direction of arm. Problem 1 In a reverted Epicyclic train shown below, the arm F carries two wheels A and D and a compound wheel B-C. Wheel A meshes with wheel B and wheel D meshes with wheel C. The following data apply. Number of teeth on A = 40, Number of teeth on D = 24 and number of teeth on C = 36.Determine the angular speed of wheel D when wheel A is fixed and arm F rotates at 300 rpm counterclockwise. Problem 2 Fig. shows an epicyclic gear train arrangement. Wheel E is a fixed wheel and wheels C and D are integrally cast, and mounted on one pin. If the arm A makes one revolution/sec clockwise, determine the speed and the direction of rotation of wheels B and F. Problem 3 An epicyclic train is shown below. It comprises a fixed annular wheel A having 150 teeth. Wheel B meshes with wheel A and drives wheel D through an idler C. The wheels A and D are concentric. Arm F carries wheels B and C and rotates at 100 rpm clockwise about the axis of A or D. If the wheels B and D have 25 and 40 teeth respectively, determine the number of teeth on C and it’s speed and direction of rotation, and the speed of gear wheel D.
MET 305 MECHANICS OF MACHINES Problem 4 Figure shows an epicyclic gear train with the following particulars: A has 40 teeth external. B has 80 teeth internal or annular. Compound wheel C has 20 teeth external D has 50 teeth external Compound wheel E has 20 teeth external F has 40 teeth external G has 90 teeth external. Gear wheel C gears with A and B, D gear with E, F gears with G. Wheel A is fixed and the arm runs at 100 rpm. in counter clockwise direction. Determine the torque exerted on gear wheel G, if the input torque to the arm is 1000 N-m. Problem 5 In an epicyclic gear of the sun and planet type shown, the pitch circle diameter of the annular wheel A is to be nearly 226 mm and the module, 4 mm. When the annular ring is stationary, the spider which carries three planet wheels P of equal size is to make one revolution for every five revolutions of the driving spindle carrying the sun wheel. Determine the number of teeth for all the wheels and the exact diameter of the pitch circle of the angular wheel. If an input torque of 20 N-m is applied to the spindle carrying the sun wheel; determine the fixed torque on the annular ring.
MET 305 MECHANICS OF MACHINES Problem 6 An epicyclic train of gears is arranged as shown in Fig. How many revolutions does the arm, to which the pinions B and C are attached, make :. 1. when A makes one revolution clockwise and D makes half a revolution anticlockwise, and 2. when A makes one revolution clockwise and D is stationary ? The number of teeth on the gears A and D are 40 and 90 respectively. Problem 7 Fig. shows diagrammatically a compound epicyclic gear train. Wheels A , D and E are free to rotate independently on spindle O, while B and C are compound and rotate together on spindle P, on the end of arm OP. All the teeth on different wheels have the same module. A has 12 teeth, B has 30 teeth and C has 14 teeth cut externally. Find the number of teeth on wheels D and E which are cut internally. If the wheel A is driven clockwise at 1 r.p.s. while D is driven counter clockwise at 5 r.p.s., determine the magnitude and direction of the angular velocities of arm OP and wheel E. Solution. Given : TA = 12 ; tb = 30 ;TC = 14 ; na = 1 r.p.s. ; ND = 5 r.p.s. Problem 8 In a gear train, as shown in Fig. 13.23, gear B is connected to the input shaft and gear F is connected to the output shaft. The arm A carrying the compound wheels D and E, turns freely on the output shaft. If the input speed is 1000 r.p.m. counter- clockwise when seen from the right, determine the speed of the output shaft under the following conditions:
MET 305 MECHANICS OF MACHINES When gear C is fixed, and 2. when gear C is rotated at 10 rpm. counter clockwise.
MET 305 MECHANICS OF MACHINES When gear C is fixed, and 2. when gear C is rotated at 10 rpm. counter clockwise.
MET 305 MECHANICS OF MACHINES When gear C is fixed, and 2. when gear C is rotated at 10 rpm. counter clockwise.

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MET 305 tutorial_5-gear_train

  • 1. MET 305 MECHANICS OF MACHINES Student Name & No._____________________________ Date: ______________________________ Section: _______________________________________ Score: _____________________________ GEAR TRAINS 4.1 Introduction Sometimes, two or more gears are made to mesh with each other to transmit power from one shaft to another. Such a combination is called gear train or train of toothed wheels. The nature of the train used depends upon the velocity ratio required and the relative position of the axes of shafts. A gear train may consist of spur, bevel or spiral gears. 4.2 Design of Spur Gears Sometimes, the spur gears (i.e. driver and driven) are to be designed for the given velocity ratio and distance between the centers of their shafts. Let c = Distance between the centers of two shafts, n1 = Speed of the driver, T1 = Number of teeth on the driver, d1 = Pitch circle diameter of the driver, n2, T2 and d2 = Corresponding values for the driven or follower, and p = Circular pitch. We know that the distance between the centers of two shafts c = (d1+d2) ---- (1) and speed ratio or velocity ratio, n1/n2 = d2/d1 = T2/T1 -------- (2) From the above equations, we can conveniently find out the values of d1 and d2 (or N1 and N2) and the circular pitch (p). The values of N1and N2, as obtained above, may or may not be whole numbers. But in a gear since the number of its teeth is always a whole number, therefore a slight alterations must be made in the values of c, d1 and d2, so that the number of teeth in the two gears may be a complete number. Example 1 In an epicyclic gear train, an arm C carries two gears A and B having 36 and 45 teeth respectively. If the arm C rotates at 150 rpm. in the anticlockwise direction about the centre of the gear A which is fixed, determine the speed of gear B. If the gear A instead of being fixed makes 300 rpm. in the clockwise direction, what will be the speed of gear B?
  • 2. MET 305 MECHANICS OF MACHINES Solution Given: TA = 36; TB = 45 ; nc = 150 rpm (anticlockwise) The gear train is shown below. Tabular method First of all prepare the table of motions as given below. Table of motions Step Conditions of motion Revolutions of elements Arm C Gear A Gear B TA = 36 TB = 45 1. Arm fixed-gear A rotates through + 1 0 +1 -TA/Tb revolution (i.e. 1 rev. anticlockwise) 2. Arm fixed-gear A rotates through + x 0 +x -x (TA/Tb) revolutions 3. Add + y revolutions to all elements +y x+y Y-x(TA/Tb) Speed of gear B when gear A is fixed. Since the speed of arm is 150 rpm. anticlockwise, therefore from the third row of the table, y = + 150 rpm. Also the gear A is fixed, therefore x + y = 0 Speed of gear B = y – x . TA/TB = 150 + 150 x 36/45 = + 270 rpm (anticlockwise) Ans. Speed of gear B when gear A makes 300 rpm. clockwise Since the gear A makes 300 rpm. clockwise, therefore from the third row of the table, x + y = - 300 or x = - 300 -y = - 300 - 150 = - 450 rpm Speed of gear B, nB = y-x-TA/TB= 150 + 450 ( 36/45) = + 510 rpm. = 510 rpm. (anticlockwise) Ans. Example 2 In a reverted epicyclic gear train, the arm A carries two gears B and C and a compound gear D - E. The gear B meshes with gear E and the gear C meshes with gear D. The number of teeth on gears B, C and D are 75, 30 and 90 respectively. Find the speed and direction of gear C when gear B is fixed and the arm A makes 100 rpm. clockwise.
  • 3. MET 305 MECHANICS OF MACHINES Solution Given : TB= 75 ; TC= 30 ; TD= 90 ; nA= 100 rpm. (clockwise) The reverted epicyclic gear train is shown above. First find the number of teeth on gear E (NE). Since the number of teeth on each gear, for the same module, are proportional to their pitch circle diameters, therefore TE+TB = TC+TD TE = TC +TD – TB = 30 + 90 – 75 = 45 The table of motions is prepared as follows: Table of motions Revolutions of elements Step Conditions of motion Compound Gear B Gear C No Arm A gear D-E 75 30 90, 45 1. Arm fixed-compound gear D-E rotated through + 1 revolution ( i.e. 1 rev. 0 1 -TE/TB -TD/TC anticlockwise) 2. Arm fixed-compound gear D-E rotated 0 +x through + x revolutions - x (TE/TB) -x (TD/TC) 3. Add + y revolutions to all elements +y x+ y y- x (TE/TB) y-x (TD/TC) Since the gear B is fixed, therefore from the fourth row of the table, y- x (TE/TB) = 0 y – x (45/75) = 0. Also the arm A makes 100 rpm. clockwise, therefore y = -100 substituting we get x = - 166.67 speed of gear C, nc = y – x(TD/TC) = - 100 + 166.67 (90/30) = + 400 rpm (anticlockwise) Ans Compound Epicyclic Gear Train—Sun and Planet Gear A compound epicyclic gear train is shown below. It consists of two co-axial shafts S, and S2, an annulus gear A which is fixed, the compound gear (or planet gear) B-C, the sun gear D and the arm H. The annulus gear has internal teeth and the compound gear is carried by the arm and revolves freely on a pin of the arm H. The sun gear is co-axial with the annulus gear and the arm but independent of them. The annulus gear A meshes with the gear B and the sun gear D meshes with the gear C. It may be noted that when the annulus gear is fixed, the sun gear provides the drive and when the sun gear is fixed, the annulus gear provides the drive. In both cases, the arm acts as a follower. Note : The gear at the centre is called the sun gear and the gears whose axes move are called planet gears.
  • 4. MET 305 MECHANICS OF MACHINES Arm (H) Compound epicyclic gear train In the simple example of epicyclic train shown below, the only gear left to take an output from, after putting inputs to sun and arm, is the planet. A more useful configuration is shown to which a ring gear has been added. This ring gear meshes with planet and pivots at O2. Therefore it can be easily made the output member. Most planetary trains will be arranged with ring gears to bring the planetary motion back to a grounded pivot. Note how the sun gear, ring gears, an arm are all brought out as concentric hollow shafts so that each can be accessed to tap its angular velocity and torque as an input or an output. Example 3 An epicyclic gear consists of three gears A, B and C as shown below. The gear A has 72 internal teeth and gear C has 32 external teeth. The gear B meshes with both A and C and is carried on an arm EF which rotates about the centre of A at 18 rpm. If the gear A is fixed, determine the speed of gears B and C.
  • 5. MET 305 MECHANICS OF MACHINES Solution. Given : TA = 72 ; TC = 32 ; Speed of arm EF = 18 rpm. Considering the relative motion of rotation as shown below. Table of motions Step No. Conditions of motion Revolutions of elements Arm EF Gear C Gear B Gear A 1 Arm fixed, gear C rotates 0 1 -TC/TB -(TC/TB) (TB/TA) = through +1 revolution -TC/TA 2 Arm fixed, gear C rotates 0 +x -x(TC/TB) -x(TC/TA) through +x 3 Add +y to all elements +y x +y y-x(TC/TB) y-x(TC/TA) Speed of gear C We know that the speed of the arm is 18 rpm. therefore, y = 18 rpm. and the gear A is fixed, therefore y-x(NC/NA)= 0 x = 18(72/32) = 40.5 Speed of gear C = x+y = 40.5 + 18 = +58.5 rpm. in the direction of arm. Ans. Speed of gear B Let dA, dB and dc be the pitch circle diameters of gears A, B and C respectively. Therefore, from the geometry. dB + dc /2 = dA/2 ie. 2 dB + dc = dA
  • 6. MET 305 MECHANICS OF MACHINES Since the number of teeth are proportional to their pitch circle diameters, therefore 2Tb + Tc = TA Tb = (72-32) / 2 = 20 Speed of gear B = y-x(TC/TB) = 18-40.5 (32/20) = - 46.8 rpm. in the opposite direction of arm. Problem 1 In a reverted Epicyclic train shown below, the arm F carries two wheels A and D and a compound wheel B-C. Wheel A meshes with wheel B and wheel D meshes with wheel C. The following data apply. Number of teeth on A = 40, Number of teeth on D = 24 and number of teeth on C = 36.Determine the angular speed of wheel D when wheel A is fixed and arm F rotates at 300 rpm counterclockwise. Problem 2 Fig. shows an epicyclic gear train arrangement. Wheel E is a fixed wheel and wheels C and D are integrally cast, and mounted on one pin. If the arm A makes one revolution/sec clockwise, determine the speed and the direction of rotation of wheels B and F. Problem 3 An epicyclic train is shown below. It comprises a fixed annular wheel A having 150 teeth. Wheel B meshes with wheel A and drives wheel D through an idler C. The wheels A and D are concentric. Arm F carries wheels B and C and rotates at 100 rpm clockwise about the axis of A or D. If the wheels B and D have 25 and 40 teeth respectively, determine the number of teeth on C and it’s speed and direction of rotation, and the speed of gear wheel D.
  • 7. MET 305 MECHANICS OF MACHINES Problem 4 Figure shows an epicyclic gear train with the following particulars: A has 40 teeth external. B has 80 teeth internal or annular. Compound wheel C has 20 teeth external D has 50 teeth external Compound wheel E has 20 teeth external F has 40 teeth external G has 90 teeth external. Gear wheel C gears with A and B, D gear with E, F gears with G. Wheel A is fixed and the arm runs at 100 rpm. in counter clockwise direction. Determine the torque exerted on gear wheel G, if the input torque to the arm is 1000 N-m. Problem 5 In an epicyclic gear of the sun and planet type shown, the pitch circle diameter of the annular wheel A is to be nearly 226 mm and the module, 4 mm. When the annular ring is stationary, the spider which carries three planet wheels P of equal size is to make one revolution for every five revolutions of the driving spindle carrying the sun wheel. Determine the number of teeth for all the wheels and the exact diameter of the pitch circle of the angular wheel. If an input torque of 20 N-m is applied to the spindle carrying the sun wheel; determine the fixed torque on the annular ring.
  • 8. MET 305 MECHANICS OF MACHINES Problem 6 An epicyclic train of gears is arranged as shown in Fig. How many revolutions does the arm, to which the pinions B and C are attached, make :. 1. when A makes one revolution clockwise and D makes half a revolution anticlockwise, and 2. when A makes one revolution clockwise and D is stationary ? The number of teeth on the gears A and D are 40 and 90 respectively. Problem 7 Fig. shows diagrammatically a compound epicyclic gear train. Wheels A , D and E are free to rotate independently on spindle O, while B and C are compound and rotate together on spindle P, on the end of arm OP. All the teeth on different wheels have the same module. A has 12 teeth, B has 30 teeth and C has 14 teeth cut externally. Find the number of teeth on wheels D and E which are cut internally. If the wheel A is driven clockwise at 1 r.p.s. while D is driven counter clockwise at 5 r.p.s., determine the magnitude and direction of the angular velocities of arm OP and wheel E. Solution. Given : TA = 12 ; tb = 30 ;TC = 14 ; na = 1 r.p.s. ; ND = 5 r.p.s. Problem 8 In a gear train, as shown in Fig. 13.23, gear B is connected to the input shaft and gear F is connected to the output shaft. The arm A carrying the compound wheels D and E, turns freely on the output shaft. If the input speed is 1000 r.p.m. counter- clockwise when seen from the right, determine the speed of the output shaft under the following conditions:
  • 9. MET 305 MECHANICS OF MACHINES When gear C is fixed, and 2. when gear C is rotated at 10 rpm. counter clockwise.
  • 10. MET 305 MECHANICS OF MACHINES When gear C is fixed, and 2. when gear C is rotated at 10 rpm. counter clockwise.
  • 11. MET 305 MECHANICS OF MACHINES When gear C is fixed, and 2. when gear C is rotated at 10 rpm. counter clockwise.