Bernoulli’s, Pascal’s, & Archimedes’ Principles

Slides:

Advertisements

Similar presentations

VII. Forces in Fluids (Ch. 8.5)

Advertisements

Chapter 13 Fluid Pressure.

Fluid Fluid - any substance that “flows”… liquids and gases.

Properties of Fluids. Buoyancy Fluid = a liquid OR gas Buoyancy = The ability of a fluid (a liquid or a gas) to exert an upward force on an object immersed.

Ch. 19 Liquids. Molecules flow, moving/flowing over one another. Takes the shape of its container.

Chapter 13 Forces in Fluids.

Ch TrueFalseStatementTrueFalse Pressure equals area/ force, and is measured in Pascals Pressure in a fluid increases as depth increases Air pressure.

Buoyancy & Archimedes’s Principle

The tendency or ability of an object to float.

Chapter 3 Section 2 Buoyancy and Density

Buoyancy, Density, and Water

Chapter 15 Fluid Mechanics. Density Example Find the density of an 4g mass with a volume of 2cm 3.

Liquids Liquids Pressure = Force/Area Pressure = Force/Area Pressure Liquid = Weight Density x Depth Pressure Liquid = Weight Density x Depth 1 Liter.

Chapter 11 – Forces in Fluids

Section 2 Properties of Fluids

- Pressure Area The area of a surface is the number of square units that it covers. To find the area of a rectangle, multiply its length by its width.

Bernoulli’s, Pascal’s, & Archimedes’ Principles Principles of Fluids.

Bernoulli’s, Pascal’s, & Archimedes’ Principles Principles of Fluids.

Forces in Fluids Chapter 13 What is pressure? The result of a force acting over a given area. Pressure = Force/Area What label? N/m 2 1 N/m 2 is known.

Floating and Sinking. Buoyancy When you pick up an object underwater it seems much lighter due to the upward force that water and other fluids exert known.

Chapter 19 Liquids.

Properties of Fluids 16-2.

Properties of Fluids 16.2 EQ – What are properties unique to fluids? How can I compare Archimedes’ Principle to Bernoulli’s principle? How can I calculate.

DENSITY & BUOYANCY. BUOYANCY BUOYANCY = the ability to float in a fluid. Examples of fluids = water, air BUOYANT FORCE = the upward force that acts on.

Liquids Definite volume but no definite shape!. Liquids Pressure Buoyancy Archimedes’ Principle Density Effects Pascal’s Principle.

Density and Buoyancy Review 1-20 study notes. 1. Density =

Liquids -They always take the shape of their container -They flow or you can pour them.

Properties of Fluids Mr Carter Science. How do ships float? The answer is buoyancy.

Forces in Fluids Chapter 13. Fluid Pressure  Section 13-1.

CONCEPTUAL PHYSICS Liquids.

Properties of Fluids.

Forces in Fluids Section 6-1 Pressure. Forces in Fluids What is pressure?  A force pushing on a surface How do force and pressure differ?  Your downward.

Chapter 7 Forces in Fluids.

Chapter 13 Forces in Fluids It’s a bit of a review…

Pressure – The result of force distributed over an area – Pressure = Force(in Newton's – N)/area (m 2 ) Pascal (Pa) – SI unit for Pressure – Named after.

Day 1. Fluids Particles are free to move past each other Gases and liquids.

PRESSURE & BUOYANCY Ch 11. I. PRESSURE A.The force exerted on a surface divided by the area over which the force is exerted. B.Pressure = Force = Newton’s.

Lesson 2 Chapter 16. Properties of Fluids A fluid is a gas or a liquid A fluid is a gas or a liquid –despite their weight ships are able to float. –greater.

$1 Million $500,000 $250,000 $125,000 $64,000 $32,000 $16,000 $8,000 $4,000 $2,000 $1,000 $500 $300 $200 $100 Welcome.

Archimede’s Principle An object immersed in a fluid has an upward (buoyant) force equal to the weight of the fluid it displaces. F B =  gV F B = buoyant.

Pressure Force per unit area Units: Pa (N/m 2 ), lb/in 2, atm, torr, mmHg P = pressure, N (psi) F=force, N (lb) A= area, m 2 (in 2 )

Buoyancy and Density Fluid  matter that flows  liquids and gases Buoyancy  The ability of a fluid to exert an upward force on an object immersed in.

1. According to Archimedes principle, what happens to the buoyant force of an object that floats in water? Increases upward 2. If you displaced 200N of.

Forces in Fluids. Pressure The force distributed over an area Pressure = Force/Area Unit: the Pascal (Pa) 1 Pa = 1 N/m 2.

Buoyancy, Density, and Water

Chapter 13 Forces in Fluids

Floating and Sinking.

3-3 Floating & Sinking.

Properties of Fluids.

Please write this  Forces in Fluids p

Physical Science 9 Chapter 16:Solids, Liquids, and Gases

Chapter 19: Liquids.

Archimedes Principle Greek mathematician Found that buoyant force on an object is equal to the weight of the fluid displaced by the object.

Chapter Fluid Pressure.

Characteristics of Fluids

Floating and Sinking.

Floating and Sinking Chapter 11 Section 2.

VII. Forces in Fluids Motion & Forces Archimedes’ Principle

Properties of Fluids.

Kinetic Theory Explains how particles in matter behave

Gas Laws Lesson 2.

Chapter 2 Forces in Fluids.

Fluid Properties Chapter 16 Section 2.

13.1 Fluid Pressure Pressure- force distributed over an area; Pressure= F/area Pressure in Fluids Water pressure increases as depth increases The pressure.

Properties of Fluids.

Pressure Force per unit area Units: Pa (N/m2), lb/in2, atm, torr, mmHg

Properties of Fluids.

Bernoulli’s, Pascal’s, & Archimedes’ Principles

Properties of Fluids.

Presentation transcript:

Bernoulli’s, Pascal’s, & Archimedes’ Principles Principles of Lift, Buoyancy, and Pressure

A. Bernoulli’s Principle As the Velocity (speed) of a fluid increases, the Pressure exerted by the fluid decreases Why?

A. Bernoulli’s Principle Airplane lift Curve Ball View airplane wings explanation.

B. Archimedes’ Principle The buoyant force on an object in a fluid is equal to the weight of the fluid displaced by the object

B. Archimedes’ Principle The upward force of a Fluid exerted on an object. What is the downward Force exerted on an object? Gravity

B. Archimedes’ Principle From Archimedes’s Principle : Buoyant Force = Weight of fluid displaced = mg (note : F = ma) = Vg (note :  = m ) V Thus FB =  V g FB = Buoyant Force or Upward thrust  = Density of fluid V = Volume of fluid displaced or the volume of the object that immersed in the fluid. g = force of gravity

B. Archimedes’ Principle Mass = 20g Volume = 20ml Mass of Fluid= 20g

B. Archimedes’ Principle Gravity = 20 Buoyant Force = 20 Object is in Liquid

B. Archimedes’ Principle Mass = 50g Volume = 20ml Mass of Fluid= 20g

B. Archimedes’ Principle Gravity = 50 Buoyant Force = 20 Object SINKS

B. Archimedes’ Principle Mass = 30g Volume = 60ml Mass of Fluid= 60g

B. Archimedes’ Principle Gravity = 30 Buoyant Force = 60 Object Floats

B. Archimedes’ Principle Recall Fg= mg and Fb= V g If the buoyant force is less than the force of gravity (Fb<Fg) the object will sink If the buoyant force is greater than the force of gravity (Fb>Fg) the object will float If the buoyant force is equal to the force of gravity (Fb=Fg) the object will maintain the same depth

View hydraulics explanation. B. Pascal’s Principle pressure applied to a fluid is transmitted unchanged throughout the fluid View hydraulics explanation.

B. Pascal’s Principle Platform: 1000 N = F2 F = 1000 N 250 m2 10 m2 A car weighing 1000 N sits on a 250 m2 platform. What force is needed on the 10 m2 plunger to keep the car from sinking? GIVEN: Platform: F = 1000 N A = 250 m2 Plunger: F = ? A = 10 m2 WORK: 1000 N = F2 250 m2 10 m2 (1000 N)(10 m2)=(250 m2)F2 F2 = 40 N

B. Pascal’s Principle A B Force ? Force = 15,000 N Area of A = 8 cm2 Area of B = 50 cm2 How much force must you apply on A to lift the object on B?

B. Pascal’s Principle A B FA = 15,000N 8 cm2 50cm2 FA =(8 cm2)(15,000 N) 50cm2 FA = 2,400 N