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Mechanical Engineering Chapter 13 Observatory pp. 424-454 STEST ASTSE
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4.Motion Transmission Systems Motion Transmission is the mechanical function of relaying a motion from one part to another without altering the nature of the motion. A Motion Transmission System is a set of components that perform the function of transmitting motion. 435
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Some definitions: Driver component: receives the force required to activate the system eg: crankset on a bike Driven component: receives the motion and transfers it to another part Eg: rear gears on a bike Intermediate component: located between the driver and driven component – not all systems have this. Eg: the chain on a bike 445
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Characteristics of Motion in Transmission Systems The most common rotational transmission systems are: Gear Trains Chain and Sprocket Systems Worm and Worm Gear Systems Friction Gear Systems Belt and Pulley Systems 436
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Motion Transmission Systems See Figure on p. 437 for the main types
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Construction Considerations for Motion TRANSMISSION Systems Depending on the need, a system may only rotate in one direction. That will affect the choice of system. 438
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Gear Trains Gear Trains The direction of rotation changes from one wheel to the next. The system can be reversed. 438
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Gear Trains
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Gear Train Factors Gear Train Factors Gear teeth: all the gear teeth in a system must be identical – same shape, direction, size and be equally spaced. E.g. Straight or helical Gear type: the rotational axis of the gears can be positioned different ways (eg: car differentials) Gear size: the higher the number of teeth, the lower the speed of rotation – or bigger diameter slower speed.
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Helical Gears
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Car Differentials
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Chain and Sprocket Systems The direction of rotation of all sprockets on the same side of the chain is the same. A sprocket on the other side of the chain rotates in the opposite direction. It can be reversed. The smaller the sprocket the faster it turns Requires frequent lubrication 439
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Worm and Worm Gear Systems The direction of rotation depends on the direction of the threads on the worm screw shaft. It is not reversible. Worm must be the driver 440
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Friction Gear Systems The direction alternates from one gear to the next. It is reversible. The smaller the diameter of the gear, the faster its rotation 440
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Friction Gear Systems Friction gear systems are similar to gear trains except that motion is transferred by FRICTION and not by the GEAR TEETH. They are less efficient because of slippage. Factors that affect friction gear systems are: gear type (straight, bevel or spherical), gear size and choice of material.
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Belt and Pulley Systems Belt and Pulley Systems Similar to the chain and sprocket system. The chain is replaced by a belt. The sprocket is replaced by a pulley. The choice of the belt material and the tightness of the belt affect the friction and hence the efficiency of the system. The direction is the same for any pulley on the same side of the belt. It is reversible. The smaller the pulley, the faster its rotation 441
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Belt and Pulley systems
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Speed Changes in Motion Transmission Systems A Speed Change occurs in a motion transmission system when the driver does not turn at the same speed as the driven component(s). The speed change depends on the ratio of gears/threads of the driver compared to that of the driven component. 442
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Speed Changes in a Pulley or Sprocket Transmission System To increase the speed, the driven component should have a smaller diameter. To decrease the speed, the driven component should have a larger diameter. To keep the same speed, the two pulleys should have the same diameter. E.g. Driver Diameter = 15cm Driven Diameter 5 cm Driven Diameter 5 cm So the driven pulley is 3 times FASTER 442
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Calculating Gear Ratios See p. 443
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Speed Changes in Worm and Worm Gear Systems Worm Gear Worm Gear The larger the diameter of the worm gear, the greater the decrease in speed. To increase the speed, the driven component should have a smaller diameter. 442
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Torque
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Torque Torque involves two forces of equal strength but applied in opposite directions which cause a component to rotate about an axis. Engine Torque increases the rotational speed of components in mechanical systems; provided by the engine Resisting Torque slows or stops the rotation of components in mechanical systems; caused by friction, air resistance, gravitational force. 444
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Torque and Speed Change If engine torque = resisting torque, No speed change If engine torque > resisting torque, speed increases If engine torque < resisting torque, speed decreases 445
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