steel ship float in water when a steel marble sinks?

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Presentation transcript:

steel ship float in water when a steel marble sinks? Buoyancy If you drop a steel marble into a glass of water, it will sink to the bottom. The steel does not float because it has a greater density than the water. And yet many ships are made of steel. How does a steel ship float in water when a steel marble sinks?

Buoyancy is a force It is much easier to lift yourself in a swimming pool than to lift yourself on land. This is because the water in the pool exerts an upward force on you that acts in a direction opposite to your weight. We call this force buoyancy. Buoyancy is a measure of the upward force that a fluid exerts on an object that is submerged.

Archimedes’ principle In the third century BCE, a Greek mathematician named Archimedes realized that buoyant force is equal to the weight of the fluid displaced by an object. We call this relationship Archimedes’ principle. Archimedes’ principle – states that the buoyant force is equal to the weight of the fluid displaced by an object.

Look at the illustration above Look at the illustration above. A simple experiment can be done to measure the buoyant force on a rock (or other small object) using a spring scale. Suppose you have a rock with a volume of 1,000 cm3 and a mass of 3 kg. In air, the scale shows the rock’s weight as 29.4 newtons. The rock is then gradually immersed in a container of water, but not allowed to touch the bottom or sides of the container. As the rock enters the water, the reading on the scale decreases. When the rock is completely submerged, the scale reads 19.6 newtons.

Subtracting the two scale readings, 29. 4 newtons and 19 Subtracting the two scale readings, 29.4 newtons and 19.6 newtons, results in a difference of 9.8 newtons. This is the buoyant force exerted on the rock, and it is the same as the weight of the 1,000 cubic centimeters of water the rock displaced.

Suppose you place a block of foam in a tub of water Suppose you place a block of foam in a tub of water. The block sinks partially below the surface. Then it floats without sinking any farther. The upward buoyant force perfectly balances the downward force of gravity (the block’s weight). But how does the buoyant force “know” how strong it needs to be to balance the weight?

If a foam block and a wood block of the same size are both floating, the wood block sinks farther into the water. Wood has a greater density, so the wood block weighs more. A greater buoyant force is needed to balance the wood block’s weight, so the wood block displaces more water. The foam block has to sink only slightly to displace water with a weight equal to the block’s weight. A floating object displaces just enough water until the buoyant force is equal to the object’s weight.

If you know an object’s density, you can immediately predict whether it will sink or float—without measuring its weight. An object sinks if its density is greater than that of the liquid it is submerged into. It floats if its density is less than that of the surrounding fluid.

To make steel float, you have to reduce the apparent density somehow. Making the steel hollow does exactly that. Making a boat hollow expands its volume a tremendous amount without changing its mass. Steel is so strong that it is quite easy to reduce the apparent density of a boat to 10 percent of the density of water by making the shell of the boat relatively thin.

An object with an apparent density GREATER than the density of water will sink. density LESS than the density of water will float.

Charles’s Law Objects of lower density can float on gas of higher density. A hot air balloon floats because it is less dense than the surrounding air. What makes the air inside the balloon less dense? The word “hot” is an important clue. To get their balloons to fly, balloonists use a torch to heat the air inside the balloon. The heated air in the balloon expands and lowers the overall density of the balloon to less than the density of the surrounding cooler air.

The balloon example illustrates an important relationship, known as Charles’s law, discovered by Jacques Charles in 1787. According to Charles’s law, the volume of a gas increases with increasing temperature. The volume decreases with decreasing temperature.

A balloon filled with helium has a volume of 0. 50 m3 at 21°C A balloon filled with helium has a volume of 0.50 m3 at 21°C. Assuming the pressure and mass remain constant, what volume will the balloon occupy at 0°C?

A tire contains 255 cm3 of air at a temperature of 28°C A tire contains 255 cm3 of air at a temperature of 28°C. If the temperature drops to 1°C, what volume will the air in the tire occupy? Assume no change in pressure or mass.