To calculate forging tonnage, you can use the formula: Tonnage = (Area of the part in square inches) × (Material yield strength in pounds per square inch) × (Safety factor). The area can be derived from the dimensions of the part being forged, while the yield strength varies based on the material. Typically, a safety factor of 1.5 to 2 is applied to account for variations in material and process conditions. This calculation helps determine the necessary force required for the forging operation.
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Forging
Well, First get the Dia of material in inches = A Get the thickness of material in inches = B Now, Multiplier for M.s is 80 & for soft material like copper, brass, alluminium is 6 0. now put the A X B X MULTIPLIER = TONNAGE Example, 1 inch dia 5mm thickness Material is M.S. SO TONNAGE is : 1 x 0.1968 x 80 = 15.75 is tonnage required... ENJOY TONNAGE FORMULA.
The tonnage is 3 ton, the seer is 10
Putting a hole in the forging after it is made. Can be done hot or cold. Usually done on a press with a punch.
For steel, the formula is (material thickness) x (inches of cut) x 50,000.
the tonnage capacity is the strain from the tub height and impact speed. The nominal (Stated) tonnage for a press is around 70% of peak.
2.23 tons
To calculate the input weight for steel forging, you would first need to determine the volume of the final desired shape or part. You can then calculate the weight of the steel needed based on the density of the specific type of steel you are using and the volume of the final product. The formula to calculate weight is: weight = volume x density.
you can calculate like this:length*wideth*height*density.If you need more information, pls contact me: mould@sinomould.com
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you have to times it by 1000000000000000 and then divide be 15 then times it by 2
The forging ratio is calculated by dividing the cross-sectional area of the billet (or workpiece) by the cross-sectional area of the finished part. It is expressed as a ratio, typically in the form of A1/A2, where A1 is the area of the billet and A2 is the area of the final product. A higher forging ratio indicates greater deformation of the material during the forging process, which can enhance mechanical properties. This ratio is important for determining the effectiveness and efficiency of the forging operation.
Length x width x depth in inches. Then x .00625 = tons
reduction ratio= initial cross sectional area/final cross sectional area
tonnage capacity is equal to area x shear strength of material. calculate area by multipying length and thickness of material.
1+1=2 2+2=4 3+3=hello i like tomatos