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This article was co-written by Bess Ruff, MA. Bess Ruff is a graduate student in geography at Florida. She received her Master’s degree in Environmental Science and Management from the Bren School of Environmental Science & Management, UC Santa Barbara in 2016. She has conducted survey work for marine spatial planning projects in the coastal area. Caribbean and support research as a contributor to the Sustainable Fisheries Group.
There are 9 references cited in this article that you can view at the bottom of the page.
This article has been viewed 21,174 times.
Buoyancy is the force acting on an object submerged in a fluid in the opposite direction of gravity. When an object is placed in a fluid, its weight pushes down on the fluid (liquid or gas) while buoyancy pushes the object upwards, in the opposite direction of gravity. In general, this buoyancy force can be calculated using the equation F b = V s × D × g , where F b is the buoyancy force, V s is the volume of the submerged part, and D is the density of the enclosing fluid. around the object, and g is the force of gravity. To learn how to determine the buoyancy of an object, start by watching Step 1 below.
Steps
Using the buoyancy equation
- For an object that is completely submerged in the fluid, the submerged volume will be equal to the volume of the object itself. For bodies floating on the surface of a fluid, we only consider the volume below the surface of the fluid.
- For example, suppose we want to find the buoyant force acting on a rubber ball floating in water. If the ball is a perfect sphere with a diameter of 1 m and it floats with exactly one half submerged, we can find the volume of the submerged part by calculating the volume of the whole ball and dividing it by two. Since the volume of the sphere is (4/3)π(radius) 3 , we have the volume of the ball as (4/3)π(0.5) 3 = 0.524 m 3 . 0.524/2 = 0.262 m 3 sunk .
- In the example above, the ball floats in the water. Refer to the study material that tells us that water has a density of 1,000 kg/m 3 .
- The densities of many common fluids are given in the technical literature. You can find this list here.
- In the above example, if we have an ordinary static system, it can be assumed that the only downward force acting on the fluid and the body is the standard gravitational force — 9.81 Newton/kilogram .
- Solve the example problem by substituting the values into the equation F b = V s × D × g. F b = 0.262 m 3 × 1,000 kg/m 3 × 9.81 N/kg = 2,570 Newtons . The other units will cancel each other out, leaving only the Newton unit.
- A suspended object will not float on water or sink to the bottom while in water. It will be suspended in the liquid halfway between the surface and the bottom. [1] X Research Source
- For example, suppose we want to know whether a cylindrical wooden crate weighing 20 kg with a diameter of 0.75 m and a height of 1.25 m can float in water. We have to perform many steps for this problem:
- The first is to find the volume using the formula for the volume of a cylinder V = π(radius) 2 (height). V = π(0.375) 2 (1,25) = 0.55 m 3 .
- Next, assuming the standard gravity and density of the water are known, we solve for the buoyant force acting on the barrel. 0.55 m 3 × 1000 kg/m 3 × 9.81 N/kg = 5,395.5 Newton .
- Now we have to find the gravity acting on the wooden crate. G = (20 kg)(9.81 m/s 2 ) = 196.2 Newtons . This result is much less than the buoyancy force, so the barrel will float.
Do a simple experiment on buoyancy
- For this experiment, we assume water has a density of 1000 kg/m 3 . Unless you use brine or a completely different liquid, most waters have a density close to this reference value so the results should not be affected.
- If you have a dropper, you can use it to drip water into the container inside so that the water level is close to the edge.
- For this example, let’s say we’re pressing a 0.05 kg toy car into its inner container. We don’t need to know the volume of the car to calculate the buoyancy force, as we will in the next step.
- In other words, if the object is floating, the volume of water that spills out will be equal to the volume of the object that is submerged below the surface of the water. If the object sinks, the volume of water that spills out will be equal to the volume of the entire object.
- In the example above, assume the toy car is submerged in its inner container and displaces about 2 tablespoons of water (0.0003 m 3 ). To find the mass of water, you multiply this value by the density: 1,000 kg/m 3 × 0.0003 m 3 = 0.03 kg .
- Therefore, objects with light mass but large volume are the ones that can float best. This property shows that hollow objects can float very well. Let’s take a look at the canoe — it floats well because it’s hollow inside, so it can take up a lot of water, but it’s not too heavy. If the canoe is solid inside, it can’t float well.
- In the above example, the vehicle has a mass of 0.05 kg which is 0.03 kg more than the displaced water mass. This is consistent with what we observe: the car has sunk.
Advice
- Use a scale that automatically zeroes after each weighing for accurate readings.
Things you need
- Small cup or bowl
- Large bowl or pail
- Small objects that can be submerged in water (such as rubber balls)
- Measuring cup
This article was co-written by Bess Ruff, MA. Bess Ruff is a graduate student in geography at Florida. She received her Master’s degree in Environmental Science and Management from the Bren School of Environmental Science & Management, UC Santa Barbara in 2016. She has conducted survey work for marine spatial planning projects in the coastal area. Caribbean and support research as a contributor to the Sustainable Fisheries Group.
There are 9 references cited in this article that you can view at the bottom of the page.
This article has been viewed 21,174 times.
Buoyancy is the force acting on an object submerged in a fluid in the opposite direction of gravity. When an object is placed in a fluid, its weight pushes down on the fluid (liquid or gas) while buoyancy pushes the object upwards, in the opposite direction of gravity. In general, this buoyancy force can be calculated using the equation F b = V s × D × g , where F b is the buoyancy force, V s is the volume of the submerged part, and D is the density of the enclosing fluid. around the object, and g is the force of gravity. To learn how to determine the buoyancy of an object, start by watching Step 1 below.
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