Gravity in Water: Effects on Dropped Objects

In summary, the effects of gravity on an object dropped underwater are the same as in air. However, the presence of drag and buoyancy must be taken into account in order to accurately model the dynamics of the object. This can be done through various equations, such as the one provided, which take into account factors such as the body's mass and density, fluid's density, drag coefficient, and displacement. Solving these equations can be done analytically, numerically, or with the help of a math program. When dealing with a partially submerged object, the Archimedes' principle must also be considered in the calculation of buoyancy.
  • #1
jared30
what are the effects on gravity if the object is dropped underwater?
 
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  • #2
gravity's pull is the same, you just have a lot more drag underwater so it falls more slowly
 
  • #3
so are there any equations for the free fall acceleration of an object underwater?
 
  • #4
There is also a Bouyant force acting on a body underwater, this acts to reduce the "weight" of a body.

To model dynamics underwater you would need to take bouyancy and drag into account. There are different ways of modeling drag, usually it is a lossy term in the inital differential equations which is depentend on velocity.
 
  • #5
m(d2x/dt2) = (rhoB-rhoA)(g*V) - 0.5(Cd)(rhoA)(A)(dx/dt)^2

Where m = body's mass, rhoA = fluid's density, rhoB = body's density, g = gravity (may be assumed to vary with height -> which is where the "effects of gravity" come in), x = displacement, t = time, Cd = drag coefficient, V = body volume, A = body area.

If the height changes are vast, you would also probably want to make rho, V and A a function of x as well.

Be a bit careful with the drag term in the equation - some quoted values of Cd use, for example, wetted area while others use cross-sectional area. Check the definitions before using it.

You can analytically solve that, write up your own program to solve it numerically or buy a math program which is capable of solving differential equations - MathCad comes to mind. Option 1 will help you only in the most ideal circumstances, while option 3 is a bit more general. Option 2 is the most general but most difficult to learn, and will solve even your nasty partial integro-differential equations with the most unusual boundary conditions, etc.


Edit: Note that the equation here is for a fully submerged body. For a partially submerged one, break the first RHS term to the body weight and a bouyant force, the latter as per Archimedes' principle.
 
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  • #6
It's no different than an object dropped in air. Normally, though, one neglects the buoyancy in air, since what we drop is so much more dense than air. But an example where it cannot be neglected is a helium balloon.
 

1. What is the relationship between gravity and water?

Gravity is a fundamental force that causes objects with mass to be drawn towards each other. In water, gravity is still present and affects the movement of objects, but the properties of water can also impact the strength and direction of gravitational pull.

2. How does gravity affect objects dropped in water?

When an object is dropped in water, it experiences the force of gravity pulling it towards the bottom of the body of water. However, the buoyancy force of the water also acts in the opposite direction, pushing the object upwards. The balance between these two forces determines the object's movement in water.

3. What factors influence the effects of gravity on dropped objects in water?

The density and shape of the object, as well as the density and viscosity of the water, can all impact the effects of gravity on dropped objects in water. Objects with higher densities will sink faster, while objects with lower densities may float or take longer to sink. The shape of the object can also affect how it moves through water and how gravity and buoyancy forces act on it.

4. Can gravity be manipulated in water to change the behavior of dropped objects?

Yes, the behavior of dropped objects in water can be manipulated by changing the density or viscosity of the water. For example, adding salt to water can increase its density and make objects sink faster, while adding substances like soap or oil can decrease the density and cause objects to float or move slower.

5. How is the study of gravity in water useful in real-world applications?

The study of gravity in water can be useful in various fields, including marine engineering, oceanography, and physics. Understanding how objects behave in water allows for more accurate predictions and calculations in these areas. It is also important for industries like shipping and fishing, where the effects of gravity on objects in water can impact operations and safety.

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