1. Ch. 4.0 Unit B – Systems in Action Introduction

2. Systems in Action System - A group of individual parts or procedures that work together as a complex whole to accomplish a desired task Component – all the different parts of a system

3. Categories of Systems Mechanical System – composed of physical parts working together – mechanical systems use forces to transfer energy – ie. a city bus, which has physical parts that work together to provide transportation

4. Categories of Systems Non-mechanical System – a set of procedures, methods, or rules that accomplish a task. – ie. A bus schedule and routes maps.

5. Ch. 4.1 Force

6. Force force – a push or a pull that acts on an object – measured in newtons (N) Classifying Forces – contact forces – action-at-a-distance forces (or non-contact forces)

7. Contact Forces contact forces – force that acts between objects that are touching. – example: hitting a tennis ball; friction between a tire and the road

8. Friction friction – a force that opposes the relative motion of an object surfaces can exhibit different amounts of friction on an object – a hockey puck slid across a wooden floor will slow down and stop due to the friction between the wooden floor and the puck – that same hockey puck slid across an ice rink (with the same amount of initial force) will go farther before stopping because the ice applies less friction to the puck than the wooden floor

9. Friction Why are tires on street bikes used by Tour de France competitors so thin? Let’s talk about curling, shall we.

10. Action-at-a-Distance Forces action-at-a-distance forces – forces that can push or pull an object without touching it. – WHAT?!?! How’s that even possible? – examples: gravity, static electricity, and magnetism – These are also called non-contact forces

11. Gravity What is gravity?

12. Gravity gravity – the attraction between two objects due to their mass – the amount of attraction depends upon the amount of each object’s mass and the distance between the two objects – when I let go of a ball, the ball is pulled back down to the ground by the force of gravity, even though nothing is touching it this is because both the Earth and the ball have mass

13. Gravity What else, other than the Earth, produces gravitational force?

14. Mass vs. Weight Once we have identified the type of force, it is often necessary to measure the amount of force. – before measuring the amount of force, it is important to know the difference between mass and weight

15. Mass mass – the amount of matter in an object – the metric unit for measuring mass is the gram (g) or kilogram (kg) – ie. the mass of a bowling ball is greater than the mass of a tennis ball because the bowling ball contains more matter

16. Weight weight – the amount of force on an object due to gravity – so, weight is the same thing as the force of gravity

17. Weight vs. Mass no matter where an object is located, its mass stays the same, but its weight changes due to the gravitational force LocationMass (kg)Weight (N) Earth50490 Moon5080 Mars50160 Jupiter501,140

18. Units of Force “BUT WAIT!” you say. “I weigh myself in kilograms (or pounds), not newtons.” – when you “weigh” yourself, you are not actually finding your weight (in newtons), but are finding your mass in kilograms

19. Measuring Force spring scale (Newton gauge) – most common force meter; consists of a spring with a hook on the end; as more force is applied to the hook, the spring stretches further

20. Calculating the Force of Gravity (Weight) the mass of an object and its weight are directly proportional – an object with twice the mass will also have twice the weight multiplying any mass by 9.8 N / kg will yield that objects weight on Earth 9.8 N / kg is called Earth’s gravitational field strenght (g)

21. Calculating the Force of Gravity (Weight) the force of gravity (F g ) on any mass (m) near the surface of the earth can be calculated by: force of gravity = (mass of an object) x (the strength of the earth’s gravitational field) OR F g = mg where mass is in kilograms (kg) and g is 9.8 N/kg

22. Calculating the Force of Gravity (Weight) example: find the weight of a 50-kg student on Earth F g = mg F g = (50 kg)(9.8N/kg) F g = 490 N

23. Let’s Review 1.Use the words “mass” or “weight” to correctly complete the following sentences: a)Even if gravity changes, the of an object does not change. b)The of an object would cange if the gravity changed. c)Kilogram (kg) is the metric unit for. d)The newton (N) is the metric unit for. mass weight mass

24. Let’s Review 2.The following masses are located on Earth. Calculate the weight of each object: a)25 kg b)40 kg c)150 kg 3.An object has a mass of 5.0 kg on the surface of the Moon. What would be the object’s: a)mass on Earth? b)Force of gravity on Earth? F g = 25 kg x 9.8 N/kg = 245 N F g = 40 kg x 9.8 N/kg = 392 N F g = 150 kg x 9.8 N/kg = 1,470 N mass = 5.0 kg no matter where it is located F g = 5.0 kg x 9.8 N/kg = 49 N