Maximum Diameter of Particle Nipped by Rolls Solution

STEP 0: Pre-Calculation Summary
Formula Used
Maximum Diameter of Particle Nipped by Rolls = 0.04*Radius of Crushing Rolls+Half of Gap between Rolls
D[P,max] = 0.04*Rc+d
This formula uses 3 Variables
Variables Used
Maximum Diameter of Particle Nipped by Rolls - (Measured in Meter) - Maximum Diameter of Particle Nipped by Rolls is the max input diameter of a feed particle that a roll crusher can take.
Radius of Crushing Rolls - (Measured in Meter) - Radius of Crushing Rolls is the radius of the crushers used in the reduction process.
Half of Gap between Rolls - (Measured in Meter) - Half of Gap between Rolls is half the closest distance between the rolls.
STEP 1: Convert Input(s) to Base Unit
Radius of Crushing Rolls: 14 Centimeter --> 0.14 Meter (Check conversion here)
Half of Gap between Rolls: 3.5 Centimeter --> 0.035 Meter (Check conversion here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
D[P,max] = 0.04*Rc+d --> 0.04*0.14+0.035
Evaluating ... ...
D[P,max] = 0.0406
STEP 3: Convert Result to Output's Unit
0.0406 Meter -->4.06 Centimeter (Check conversion here)
FINAL ANSWER
4.06 Centimeter <-- Maximum Diameter of Particle Nipped by Rolls
(Calculation completed in 00.004 seconds)

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13 Formulas on Size Reduction Laws Calculators

Area of Product given Crushing Efficiency
Go Area of Product = ((Crushing Efficiency*Energy Absorbed by Material)/(Surface Energy per Unit Area*Length))+Area of Feed
Area of Feed given Crushing Efficiency
Go Area of Feed = Area of Product-((Crushing Efficiency*Energy Absorbed By Unit Mass Of Feed)/(Surface Energy per Unit Area))
Energy Absorbed by Material while Crushing
Go Energy Absorbed by Material = (Surface Energy per Unit Area*(Area of Product-Area of Feed))/(Crushing Efficiency)
Crushing Efficiency
Go Crushing Efficiency = (Surface Energy per Unit Area*(Area of Product-Area of Feed))/Energy Absorbed by Material
Power Consumption by Mill while Crushing
Go Power Consumption by Mill While Crushing = Power Consumption for Crushing Only+Power Consumption While Mill is Empty
Power Consumption for Crushing only
Go Power Consumption for Crushing Only = Power Consumption by Mill While Crushing-Power Consumption While Mill is Empty
Mechanical Efficiency given Energy fed to System
Go Mechanical Efficiency in Terms of Energy Fed = Energy Absorbed By Unit Mass Of Feed/Energy Fed to Machine
Radius of Crushing Rolls
Go Radius of Crushing Rolls = (Maximum Diameter of Particle Nipped by Rolls-Half of Gap between Rolls)/0.04
Maximum Diameter of Particle Nipped by Rolls
Go Maximum Diameter of Particle Nipped by Rolls = 0.04*Radius of Crushing Rolls+Half of Gap between Rolls
Power Required by Machine for Size Reduction of Particles
Go Power Required by Machine = Work Required for Reduction of Particles*Feed Rate to Machine
Feed Rate to Machine for Size Reduction of Particles
Go Feed Rate to Machine = Power Required by Machine/Work Required for Reduction of Particles
Work required for Reduction of Particles
Go Work Required for Reduction of Particles = Power Required by Machine/Feed Rate to Machine
Reduction Ratio
Go Reduction Ratio = Feed Diameter/Product Diameter

19 Important Formulas in Size Reduction Laws Calculators

Half of Gaps between Rolls
Go Half of Gap between Rolls = ((cos(Half Angle of Nip))*(Radius of Feed+Radius of Crushing Rolls))-Radius of Crushing Rolls
Area of Product given Crushing Efficiency
Go Area of Product = ((Crushing Efficiency*Energy Absorbed by Material)/(Surface Energy per Unit Area*Length))+Area of Feed
Radius of Feed in Smooth Roll Crusher
Go Radius of Feed = (Radius of Crushing Rolls+Half of Gap between Rolls)/cos(Half Angle of Nip)-Radius of Crushing Rolls
Critical Speed of Conical Ball Mill
Go Critical Speed of Conical Ball Mill = 1/(2*pi)*sqrt( [g]/(Radius of Ball Mill-Radius of Ball))
Area of Feed given Crushing Efficiency
Go Area of Feed = Area of Product-((Crushing Efficiency*Energy Absorbed By Unit Mass Of Feed)/(Surface Energy per Unit Area))
Projected Area of Solid Body
Go Projected Area of Solid Particle Body = 2*(Drag Force)/(Drag Coefficient*Density of Liquid*(Velocity of Liquid)^(2))
Energy Absorbed by Material while Crushing
Go Energy Absorbed by Material = (Surface Energy per Unit Area*(Area of Product-Area of Feed))/(Crushing Efficiency)
Crushing Efficiency
Go Crushing Efficiency = (Surface Energy per Unit Area*(Area of Product-Area of Feed))/Energy Absorbed by Material
Radius of Ball Mill
Go Radius of Ball Mill = ([g]/(2*pi*Critical Speed of Conical Ball Mill)^2)+Radius of Ball
Terminal Settling Velocity of Single Particle
Go Terminal Velocity of Single Particle = Settling Velocity of Group of Particles/(Void fraction)^Richardsonb Zaki Index
Power Consumption while Mill is Empty
Go Power Consumption While Mill is Empty = Power Consumption by Mill While Crushing-Power Consumption for Crushing Only
Power Consumption for Crushing only
Go Power Consumption for Crushing Only = Power Consumption by Mill While Crushing-Power Consumption While Mill is Empty
Mechanical Efficiency given Energy fed to System
Go Mechanical Efficiency in Terms of Energy Fed = Energy Absorbed By Unit Mass Of Feed/Energy Fed to Machine
Radius of Crushing Rolls
Go Radius of Crushing Rolls = (Maximum Diameter of Particle Nipped by Rolls-Half of Gap between Rolls)/0.04
Maximum Diameter of Particle Nipped by Rolls
Go Maximum Diameter of Particle Nipped by Rolls = 0.04*Radius of Crushing Rolls+Half of Gap between Rolls
Work required for Reduction of Particles
Go Work Required for Reduction of Particles = Power Required by Machine/Feed Rate to Machine
Product Diameter Based on Reduction Ratio
Go Product Diameter = Feed Diameter/Reduction Ratio
Feed Diameter based on Reduction Law
Go Feed Diameter = Reduction Ratio*Product Diameter
Reduction Ratio
Go Reduction Ratio = Feed Diameter/Product Diameter

Maximum Diameter of Particle Nipped by Rolls Formula

Maximum Diameter of Particle Nipped by Rolls = 0.04*Radius of Crushing Rolls+Half of Gap between Rolls
D[P,max] = 0.04*Rc+d

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How to Calculate Maximum Diameter of Particle Nipped by Rolls?

Maximum Diameter of Particle Nipped by Rolls calculator uses Maximum Diameter of Particle Nipped by Rolls = 0.04*Radius of Crushing Rolls+Half of Gap between Rolls to calculate the Maximum Diameter of Particle Nipped by Rolls, Maximum Diameter of Particle Nipped by Rolls is the max input diameter of a feed particle that a roll crusher can take. Maximum Diameter of Particle Nipped by Rolls is denoted by D[P,max] symbol.

How to calculate Maximum Diameter of Particle Nipped by Rolls using this online calculator? To use this online calculator for Maximum Diameter of Particle Nipped by Rolls, enter Radius of Crushing Rolls (Rc) & Half of Gap between Rolls (d) and hit the calculate button. Here is how the Maximum Diameter of Particle Nipped by Rolls calculation can be explained with given input values -> 406 = 0.04*0.14+0.035.

FAQ

What is Maximum Diameter of Particle Nipped by Rolls?
Maximum Diameter of Particle Nipped by Rolls is the max input diameter of a feed particle that a roll crusher can take and is represented as D[P,max] = 0.04*Rc+d or Maximum Diameter of Particle Nipped by Rolls = 0.04*Radius of Crushing Rolls+Half of Gap between Rolls. Radius of Crushing Rolls is the radius of the crushers used in the reduction process & Half of Gap between Rolls is half the closest distance between the rolls.
How to calculate Maximum Diameter of Particle Nipped by Rolls?
Maximum Diameter of Particle Nipped by Rolls is the max input diameter of a feed particle that a roll crusher can take is calculated using Maximum Diameter of Particle Nipped by Rolls = 0.04*Radius of Crushing Rolls+Half of Gap between Rolls. To calculate Maximum Diameter of Particle Nipped by Rolls, you need Radius of Crushing Rolls (Rc) & Half of Gap between Rolls (d). With our tool, you need to enter the respective value for Radius of Crushing Rolls & Half of Gap between Rolls and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
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