A ship stays afloat on water due to the principle of buoyancy. The weight of the ship is displaced by an equal volume of water, creating an upward force called buoyancy that keeps the ship from sinking. The shape and design of the ship's hull help distribute the weight and control buoyancy to keep the ship stable and afloat.
A steel ship floats because of the principle of buoyancy. The weight of the water displaced by the ship is equal to the weight of the ship itself, allowing it to stay afloat.
water resistance
The amount of water needed to float a ship depends on the ship's weight or displacement. Ships with greater displacement require more water to provide the necessary buoyancy to stay afloat. The concept of buoyancy, based on Archimedes' principle, ensures that a ship displaces an equal volume of water to its own weight in order to stay afloat.
A ship floats on water because it has a lower density than water. The buoyant force acting on the ship is greater than its weight, allowing it to stay afloat.
The force that helps a ship float is buoyancy, which is generated by the displaced water pushing upward on the ship's hull. This force is equal to the weight of the water that the ship displaces, allowing the ship to stay afloat.
The ship was designed and built to stay afloat if four watertight compartments were breached, but the iceberg breached five compartments, so the ship couldn't stay afloat
The bouyancy of the vessel keeps it afloat. As long as the force of bouyancy is larger then the mass of the ship it will stay afloat.
A steel ship floats because of the principle of buoyancy. The weight of the water displaced by the ship is equal to the weight of the ship itself, allowing it to stay afloat.
water resistance
The amount of water needed to float a ship depends on the ship's weight or displacement. Ships with greater displacement require more water to provide the necessary buoyancy to stay afloat. The concept of buoyancy, based on Archimedes' principle, ensures that a ship displaces an equal volume of water to its own weight in order to stay afloat.
They stay afloat the same way any ship stays afloat. The displacement of the vessel has to be less then the amount of water being displaced. The armaments have to be carefully planned to make sure that things don't get too heavy. And the balance and location have to considered as well, to make sure the ship doesn't roll over.
A ship floats on water because it has a lower density than water. The buoyant force acting on the ship is greater than its weight, allowing it to stay afloat.
The ship floats because of its large volume which displaces an amount of water that is more than its weight. That creates an upward force called buoyant force which keeps the ship on the surface.
The force that helps a ship float is buoyancy, which is generated by the displaced water pushing upward on the ship's hull. This force is equal to the weight of the water that the ship displaces, allowing the ship to stay afloat.
A steel ship floats in water because of a principle called buoyancy. The weight of the water displaced by the ship is equal to the weight of the ship itself, allowing it to stay afloat. The shape of the ship's hull also helps distribute the weight evenly, helping it to float.
A ship floats on water due to a principle known as buoyancy. The weight of the water displaced by the ship is equal to the weight of the ship, allowing it to stay afloat. Essentially, the buoyant force exerted by the water is greater than the weight of the ship, keeping it on the surface.
A concrete ship floats due to the principle of buoyancy. The weight of the water displaced by the ship is equal to the weight of the ship itself, allowing it to stay afloat. The hollow and watertight design of a concrete ship helps to displace enough water to keep it buoyant.