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goldleader
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Hello everybody... another basic question. While trying interpreting a blueprint I stumbled on RADIAL FLOAT . Do you know a definition for a Radial Float?
Thnx
Thnx
goldleader said:Hello everybody... another basic question. While trying interpreting a blueprint I stumbled on RADIAL FLOAT . Do you know a definition for a Radial Float?
Thnx
berkeman said:Welcome to the PF. Just Googling the title of your thread gives lots of informative hits. Here's one:
http://www.cutting-tool.americanmachinist.com/guiEdits/Content/bdeee9/bdeee9_1.aspx
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Radial float is a phenomenon that occurs when an object is suspended in a fluid or gas and is able to move freely in all directions around a central point. It is typically caused by the forces of buoyancy and gravity acting on the object. The amount of radial float an object experiences depends on its weight, density, and the density of the surrounding fluid.
Radial float is different from other types of float, such as linear or rotational float, because it allows an object to move freely in all directions rather than just along one axis or in a circular motion. This makes it a more complex and dynamic form of float.
One example of radial float is a hot air balloon, which is able to rise and fall in the air by adjusting the amount of hot air inside the balloon. Another example is a submarine, which uses ballast tanks to control its buoyancy and move up or down in the water. Radial float also plays a role in the movement of particles in fluids, such as in ocean currents and weather patterns.
Understanding radial float is essential in many fields of science, including fluid dynamics, aerodynamics, and oceanography. By studying the forces that cause radial float, scientists can better understand the behavior of fluids and gases and how they interact with objects. This knowledge is crucial for developing new technologies and solving real-world problems.
Yes, radial float can be controlled and manipulated through various methods. For example, engineers can design objects with specific shapes and densities to achieve a desired amount of radial float. In addition, techniques such as adding or removing weights or changing the temperature of a fluid can also affect the amount of radial float an object experiences. Understanding how to control radial float is important for many applications, such as designing aircrafts and ships that can stay afloat in different conditions.