Liquids - PowerPoint PPT Presentation

1 / 25
About This Presentation
Title:

Liquids

Description:

Liquids Chapter 19 Liquids While in the liquid phase, a substance will take the shape of their container, but will not expand to fill the container. – PowerPoint PPT presentation

Number of Views:92
Avg rating:3.0/5.0
Slides: 26
Provided by: Admini1015
Category:
Tags: liquids | object | pascal

less

Transcript and Presenter's Notes

Title: Liquids


1
Liquids
  • Chapter 19

2
Liquids
  • While in the liquid phase, a substance will take
    the shape of their container, but will not expand
    to fill the container.
  • In the liquid state, molecules can flow. They
    freely move from place to place by sliding over
    one another.

3
Pressure in Liquids
  • Any contained fluid exerts a force on the walls
    of its container. The ratio of this force to the
    surface area of the container is called pressure.
  • F
  • P A
  • The unit for pressure is the Newton per meter
    squared, or the Pascal.

4
Pressure in Liquids
  • In a fluid, pressure is exerted equally in all
    directions.
  • Therefore, the pressure always acts perpendicular
    to every surface.

5
Pressure in Liquids
  • For a liquid of uniform density, the pressure is
    proportional to the depth of measurement

6
Pressure in Liquids
  • For a liquid of uniform density, the pressure is
    proportional to the depth of measurement

Pressure weight density x depth Pressure
density x g x depth
7
Pressure in Liquids
  • For a liquid of uniform density, the pressure is
    proportional to the depth of measurement

Pressure density x g x depth
8
Pressure in Liquids
  • Pascals Vases demonstrate that the pressure of
    the liquid depends on the depth alone, and not
    the volume or shape of the fluid.

9
Buoyancy
  • When an object is placed in water, it weighs less
    than it did in air. This is due to an upward
    force exerted on the object by the water.
  • The upward force is called the buoyant force.

10
Buoyancy
  • When an object is placed in water, it weighs less
    than it did in air. This is due to an upward
    force exerted on the object by the water.
  • The upward force is called the buoyant force.

11
Buoyancy
  • If the buoyant force on an object is greater than
    the weight, the object will float.

12
Archimedes Principle
  • When an object is submerged in a liquid, some of
    that liquid is displaced.
  • The volume of liquid displaced is equal to the
    volume of the immersed object.

13
Archimedes Principle
  • The Greek philosopher Archimedes determined the
    relationship between buoyancy and the amount of
    liquid displaced.
  • An immersed object is buoyed up by a force equal
    to the weight of the fluid it displaces.

14
Archimedes Principle
15
Archimedes Principle
  • The buoyant force depends on the volume of the
    object that is being submerged in the fluid
    nothing else matters.
  • For every liter of volume (or 1000 cm3), there is
    a 10-newton buoyant force.

16
Archimedes Principle
  • For example, what is the buoyant force on
  • - a half liter block of wood?
  • - a 100 milliliter brass weight?
  • - a 2 liter bottle of ginger ale?
  • - a 2 liter bottle half full of ginger ale?
  • - a 2 liter bottle full of air?

17
Archimedes Principle
  • The buoyant force acting on an object does not
    depend on the depth of the water.

18
Density and Submersion
  • Whether an object will sink or float in a liquid
    has to do with how great the buoyant force is
    compared to the objects weight.
  • This can be summed up with three simple rules
  • If an object is denser than the fluid in which it
    is immersed, it will sink.
  • If an object is less dense than the fluid in
    which it is immersed, it will float.
  • If an object has a density equal to the density
    of the fluid in which it is immersed, it will
    neither sink nor float.

19
Flotation
  • How can you make iron float?
  • If the iron can be made less dense than water, it
    will float. This can be done by filling the
    piece of iron with pockets of air.
  • This can be done by making bubbles in the iron as
    it cools, or by making a hollow object of iron.

20
Flotation
21
Flotation
  • The Principle of Flotation
  • A floating object displaces a weight of fluid
    equal to its own weight.
  • For example, the aircraft carrier USS Enterprise
    weighs 90,000 tons.
  • It displaces 90,000 tons of water.

22
(No Transcript)
23
Flotation
  • To see how a submarine is able to make use of
    this principle to submerge and then re-surface,
    take a look at my website.

24
Pascals Principle
  • Changes in pressure at any point in an enclosed
    fluid at rest are transmitted undiminished to all
    points in the fluid and act in all directions.

25
Homework
  • Read ch 19 and do problems 1-20 on pages 280 and
    281.
  • Due Monday, 3/6
Write a Comment
User Comments (0)
About PowerShow.com