As the body floats then the weight of the body and weight of displaced liquid would be equal to each other. Hence it floats
if its floating, its zero : weight or force = upthrust from water note: upthrust from water = weight of water displaced
When an object is floating in equilibrium, the buoyant force equals the weight of the object. (The buoyant force is equal to the weight of the displaced fluid)
Right principle is "Archimedes Principle" When the weight of the sinking object exceeds the weight of the displaced liquid sinking continues. If otherwise the body would be pushed up and it would start floating on the surface. At the time of floating, the weight of the body = weight of the liquid displaced
The buoyant force on a fully submerged object is equal to the weight of the water displaced. In fact, that's also true of a floating object.
The upward bouyant force depends only on the weight of the displaced fluid. The NET force (object's weight - bouyant force) depends on the object's weight and will determine how fast it sinks.
if its floating, its zero : weight or force = upthrust from water note: upthrust from water = weight of water displaced
When an object is floating in equilibrium, the buoyant force equals the weight of the object. (The buoyant force is equal to the weight of the displaced fluid)
The weight of water displaced by the floating ship is less than the weight of the ship. So it floats. Thanks to Archimedes!
Right principle is "Archimedes Principle" When the weight of the sinking object exceeds the weight of the displaced liquid sinking continues. If otherwise the body would be pushed up and it would start floating on the surface. At the time of floating, the weight of the body = weight of the liquid displaced
As per Archimedes principle for floating the weight of the displaced water has to be equal to the weight of the boat. Hence for more water to get displaced the boat has to sink more.
The buoyant force on an object depends only on the weight of the fluid displaced: Fb = Vd*ρf*g Vd may not be the volume of the object; for example: if the object is floating on the liquid surface. Also, there may be other forces acting on the object, such as its weight (Mo*g)
The buoyant force on a fully submerged object is equal to the weight of the water displaced. In fact, that's also true of a floating object.
The weight of the water (or other liquid, or gas) displaced is equal to the force with which the water will push the object upwards.
An amount whose weight is the same as the sum of the weights of all the ships that are presently floating,
Archimedes's principle states that the buoyant force acting on an object immersed or floating in a fluid equals the weight of the fluid displaced.
Since the object is submerged, we know that the buoyant force is not sufficient to overcome the weight of the object, otherwise it would be floating rather than being submerged. Therefore, the buoyant force is equal to the weight of the displaced water, not the weight of the object itself.
The weight of water displaced by the floating block of wood is exactly equal to the weight of the ENTIRE block of wood, regardless of how much of the wood is above the water level.