# Spring Constant Units Calculator

#### Compression And Extension Spring Rate

Spring constant units in extension and sspring constant offer a linear force. Spring constant k is the master of your compression or extension spring design. You must consider the load you will be applying on the spring and how much deflection or travel you expect from your spring under that load. The spring constant units for load are pounds of force (lbf) or newtons (N) in the metric system of measurement. Spring constant units for travel are inches (in) or millimeters (mm). The formulas and diagrams provided below will help you calculate your compression or extension spring’s constant.

#### Constant Formula A.)

To calculate how much spring constant you need.

• X = distance traveled
• k = rate
k = F ÷ X

#### Rate Formula B.)

To calculate spring constant of a spring.

• d = Wire Diameter
• D outer = Outer Diameter
• D = Mean Diameter
• E = Young’s Modulus of Material
• G = Shear Modulus of Material
• L free = Free Length
• k = Spring Rate (Spring Constant)
• na = Active Coils
• v = Poison’s Ratio of Material
D = D outer – d
G = E ÷ 2 ( 1 + V )
k = Gd^4 ÷ (8D^3 * na)

#### Torsion Spring Constant

When it comes to torsion springs the force is radial. In this case, torsion spring rate is the amount of constant force or torque your torsion spring exerts per every 360 degrees of deflection (travel) or 1º degree of deflection. The formulas and diagrams provided below will help you calculate your torsion spring rate.

#### Torque Formula A.)

To calculate torsion spring rate per 360º (degrees).

• d = wire size (inches)
• D = Mean Diameter (inches)
• N = Number of active coils
• E = Modulus of Elasticity
• R = Rate per 360º
• R2 = Rate per Degree
R = Ed^4 / 10.8 DN R2 = R ÷ 360

#### Torque Formula B.)

To calculate how much torsion spring rate per degree you need.

• k2 = Rate per Degree
• X = Distance Traveled
• F = Torque or Load
k = F ÷ X