Pressure is inversely proportional to flow. This means that as pressure increases, flow decreases and vice versa. This relationship is described by the principles of fluid dynamics, specifically Bernoulli's principle.
for ideal fluid pv=nRT, so when pressure increase velocity decreases since vel. is inversly proportional to pressure....
In a flapper nozzle, the flow rate of the fluid passing through is directly proportional to the difference in pressure across the nozzle. As the pressure increases, the flow rate also increases. This relationship between pressure and flow rate is governed by equations such as Bernoulli's principle and the equation of continuity.
No, resistance is not directly proportional to charge. Resistance is determined by the material, length, and cross-sectional area of a conductor, while charge is a property of matter. The resistance will affect the flow of charge in a circuit, but it is not directly proportional to the charge itself.
Poiseuille's law states that the rate of flow of a fluid through a tube is directly proportional to the pressure difference along the tube. When pressure drops, the flow rate will increase accordingly if all other factors remain constant. This relationship highlights the importance of pressure in influencing fluid flow dynamics.
Yes, the colligative property you are referring to is osmotic pressure. Osmotic pressure is the pressure required to prevent the flow of solvent across a semipermeable membrane. It is directly proportional to the concentration of solute particles in the solution.
Blood flow is directly proportional to blood pressure, vessel diameter, and heart rate. When these factors increase, blood flow also increases, and vice versa.
current flow is proportional to the voltage and inversly proportional to the resistance
The rate of flow against pressure gradient graph typically shows a linear relationship. As the pressure gradient increases, the rate of flow also increases proportionally. This is in accordance with Poiseuille's law, where flow is directly proportional to the pressure gradient and the fourth power of the radius of the vessel and inversely proportional to the viscosity of the fluid.
A hydraulic variable that describes the power provided by a hydraulic system. HHP is directly proportional to flow rate and pressure and inversely proportional to the efficiency of a system
for ideal fluid pv=nRT, so when pressure increase velocity decreases since vel. is inversly proportional to pressure....
In a flapper nozzle, the flow rate of the fluid passing through is directly proportional to the difference in pressure across the nozzle. As the pressure increases, the flow rate also increases. This relationship between pressure and flow rate is governed by equations such as Bernoulli's principle and the equation of continuity.
No, resistance is not directly proportional to charge. Resistance is determined by the material, length, and cross-sectional area of a conductor, while charge is a property of matter. The resistance will affect the flow of charge in a circuit, but it is not directly proportional to the charge itself.
Poiseuille's law states that the rate of flow of a fluid through a tube is directly proportional to the pressure difference along the tube. When pressure drops, the flow rate will increase accordingly if all other factors remain constant. This relationship highlights the importance of pressure in influencing fluid flow dynamics.
Blood pressure = (Blood flow)(Resistance). This equation is usually found in the following form: MAP = (CO)(R) Where MAP is the mean arterial pressure CO is the cardiac output R is the peripheral resistance
Yes, the colligative property you are referring to is osmotic pressure. Osmotic pressure is the pressure required to prevent the flow of solvent across a semipermeable membrane. It is directly proportional to the concentration of solute particles in the solution.
CFM is a unit of flow PSI is a unit of pressure you cant equate these except to say that they are inversely proportional... as pressure increases flow decreases
"Viscosity" is basically a resistance to flow. Viscosity is inversly proportional to Temperature. For example, high viscous heavy fuel is heated to right temperature to lower its viscosity for proper combustion in diesel engines or boiler.