Warm Up What is the difference between Automation and Robotics? What is a robot? What are some of the types of robots we have studied so far? What are the 4 D’s robots are used for?
Review 1. What is the difference between Automation and Robotics? Automation involves a mechanical device that can imitate the actions of people or animals. Robotics involves the design, construction, and operation of a robot.
2. What is a robot? A robot is a machine that performs complicated tasks and is guided by automatic controls.
3. What are some of the types of robots we have studied so far 3. What are some of the types of robots we have studied so far? Industrial Medical Assistive Exploratory Household
4. What are the 4 D’s robots are used for? Robots are used to perform dirty, dull, or dangerous tasks, or to help someone with a disability.
Section 2.2: Mechanical Systems In this section we will: Use ratios to solve mechanical advantage problems. Use numerical and algebraic expressions and equations to solve real-life problems, such as gear ratios. Use the characteristics of a specific mechanism to evaluate its purpose and applications. Apply knowledge of mechanisms to solve a unique problem for speed, torque, force, or type of motion.
Observing Mechanisms Mechanisms Gateway To Technology® Unit 2 – Lesson 2.2 – Mechanical Systems Observing Mechanisms
Introduction Think about a bicycle, an eggbeater, a sewing machine, a hand cranked drill, and a workshop vice. What do they have in common?
All of them have at least one mechanism that provides movement. Some of the devices use human effort, while others use electricity.
If the devices were taken apart, you would find a series of gears that redirect the applied force so they can accomplish their tasks. Gears come in all sizes. Small gears are found in mechanical watches. Very large gears are found in cranes that are used to raise large bridge sections into place.
Mechanisms Gateway To Technology® Unit 2 – Lesson 2.2 – Mechanical Systems What is a Mechanism? A mechanism is the part of a machine which contains two or more pieces arranged so that the motion of one compels the motion of the others. A system of parts working together in a machine
Mechanisms Generally used to: Change the direction of movement Change the type of movement Change the speed of movement Change the amount of torque or force available to do work
Mechanism Movement Rotary Oscillating Linear Reciprocating Mechanisms Gateway To Technology® Unit 2 – Lesson 2.2 – Mechanical Systems Mechanism Movement Rotary Oscillating Linear Reciprocating
Rotary Motion Motion is around in a circle
Oscillating Motion To swing back and forth at a regular rate.
Linear Motion To move straight in one direction.
Reciprocating Motion Moving back and forth in a straight line.
In this class we will often use gear based mechanisms Gears come in all sizes. Small gears are found in mechanical watches. Very large gears are found in cranes that are used to raise large bridge sections into place.
Gear Train A gear train is a mechanism used for transmitting rotary motion and torque. Gears transmit rotary motion through interlocking teeth. A gear train is made when two or more gears are meshed. Meshed gears always turn in opposite directions. Cannon: 1850’s Wool Mill: 1840’s
Gear Train Energy input causes the drive gear to move Energy is transferred to the driven gear called the output gear
Drive Gear, Driven Gear The drive gear is the input gear; the driven gear is the output gear.
Gear Ratio Gear ratios compare the input drive gear to the output driven gear. The input gear transfers the energy to the output gear. If the input (drive) completes one revolutions and for every two completed by the output (driven), then the gear ratio is 1:2. Crank Drive Driven
Gear Ratio Variables to know n = number of teeth d = diameter Nin: Nout 36:24 3:2 Din: Dout 10:5 2:1 Gear Ratio Variables to know n = number of teeth d = diameter ** Subscripts in and out are used to distinguish between gears ** Drive Nin: Nout 36:24 3:2 Din: Dout 10:5 2:1 Driven
Calculating Gear Ratios # Teeth Input gear # Teeth output gear Gear Ratio Explanation 8 40 40:8 or 5:1 The input (drive) gear must turn 5 times to move the output (driven) gear once. Torque increases. 36 4 6 48 16 20
Force & Torque A force is a push or a pull in a straight line. Torque is a push or pull in a circular direction.
Torque and Speed There is an inverse relationship between torque and speed: -more torque = less speed -more speed = less torque
Example A ten-speed bicycle has ten different gear selections. When you pedal up a hill, you use a gear train that provides more torque (turning force) but, in doing so, less speed. When you pedal on flat land, you use a gear train that provides more speed, but in doing so, less torque within the gear train. When pedaling up a hill, we trade off speed for torque. In other words a reduction in speed is a trade-off to increase torque and make pedaling easier.
Mechanical Advantage As the size of the driven gear decreases in relation to the size of the drive gear, output speed increases. •As the size of the driven gear increases in relation to the size of the drive gear, output torque increases. Output B Input A
This means: bigger gear=more Torque smaller gear= more speed
Which gear train provides more torque? Which gear train provides more speed? Which would you use to ride up a hill on your bike?
Driven Gear To increase torque what happens to the size of the driven gear? To increase speed what happens to the driven gear?
List 5 different mechanisms in the Rube Goldberg picture above and predict the purpose of each. Does the mechanism change speed, force, torque, direction, or type of movement? Put a number on the picture to indicate location.