The size of the upthrust, also known as buoyant force, depends on the volume of the fluid displaced by the object and the density of that fluid. The material or object itself does not directly affect the size of the upthrust, but rather how much fluid it displaces. denser fluids will create a greater upthrust, while less dense fluids will result in a smaller upthrust
To find the upthrust needed to keep a 1600 N object afloat, you need to consider the weight of the object. The upthrust must equal the weight of the object for it to stay afloat, so the upthrust required would be 1600 N.
We can't find the term "upthrust" in any of the myriad volumes in our vast reference library. If the object's weight balances the weight of a 500g standard while in air, and the weight of a 400g standard while in water, then the effect of the water is to produce an upward force on the object equal to the weight of a 100g standard, or 0.978 Newton. By Archimedes' principle, this is also the weight of the water displaced by the object, which tells us that the object has a volume very near 100 cc.
Upthrust, also known as buoyant force, acts on objects submerged in a fluid (liquid or gas), pushing them upward. It is a result of the pressure difference between the top and bottom of the submerged object. You would typically find upthrust acting on objects floating or submerged in water, such as boats, submarines, or objects in a fish tank.
Same as his weight
To find the net acceleration of an object, you need to determine the total force acting on the object and divide it by the object's mass. The formula to calculate acceleration is: acceleration = total force / mass. This net acceleration represents the overall change in velocity of the object over time.
To find the upthrust needed to keep a 1600 N object afloat, you need to consider the weight of the object. The upthrust must equal the weight of the object for it to stay afloat, so the upthrust required would be 1600 N.
Well, darling, upthrust, also known as buoyant force, is calculated by the formula: upthrust = weight of fluid displaced. So, if you want to find out how much your object will be floating around like a happy little buoy, just remember to take into account the weight of the fluid it's shoving out of the way. Easy peasy lemon squeezy!
We can't find the term "upthrust" in any of the myriad volumes in our vast reference library. If the object's weight balances the weight of a 500g standard while in air, and the weight of a 400g standard while in water, then the effect of the water is to produce an upward force on the object equal to the weight of a 100g standard, or 0.978 Newton. By Archimedes' principle, this is also the weight of the water displaced by the object, which tells us that the object has a volume very near 100 cc.
Upthrust, also known as buoyant force, acts on objects submerged in a fluid (liquid or gas), pushing them upward. It is a result of the pressure difference between the top and bottom of the submerged object. You would typically find upthrust acting on objects floating or submerged in water, such as boats, submarines, or objects in a fish tank.
The answer depends on what information you do have about the object.
Same as his weight
The answer depends on the information that has been provided.
Nope. it occurs in other liquids and even things. like in the air. for example, when you throw a pen in the air, you will find things like... when you throw a pen, there is a push from the muscle and the gravity. The push from the muscle is greater in this occation so the pen goes up. And when it falls, there is nomore of the push from the muscle and there is an upthrust and gravity. (this is where upthrust works) the force of gravity is greater so it falls. Also, it is because of the upthrust that we are standing on the earth. There's an upthrust acting on us as well as the gravity. But ofcourse, as the gravity is stronger, we do not float up to the sky. but if there wasn't any upthrust, we would be sinking into the earth by now! Also upthrust acts on other liquids like oil and salt water.... whoa.. i wrote alot... hope it helped you!
Depends on the object. For four-sided figures, use length times width.
There is no single formula. It depends on the shape of the object whose volume you are trying to find.
The answer depends on the shape of the object. There are some objects whose volume you simply cannot obtain by calculation.
It depends on what kind of material the matter is made of. Find the weight of the object, divide by 10 or 9.8 you should find the mass.