Calculates design values related to lifetime for rolling element bearings when the following is true:
This calculator does not calculate for:
$C$ = Basic dynamic load rating, pounds force or Newtons
$C_{0}$ = Basic static load rating, *pounds force* or *Newtons*
$L$ = Load on bearing, pounds force or Newtons
$S_{0}$ = Safety factor for static loads, *unitless*
$C_{x}$ = Rated lifetime hours, *revolutions*
$n$ = Average rotations per minute of bearing at load L.
$r$ = Revolutions
$h$ = Operating hours
$x$ = bearing type factor, from table:
| Type | factor |
|---|---|
| Ball Bearing | 3 |
| Roller Bearing | (10 / 3) |
$a_{1}$ = Rotation factor, from table:
| Rotating member | factor |
|---|---|
| Inner Ring | 1 |
| Outer Ring | 1.2 |
$a_{2}$ = Reliability factor, from table:
| Reliability | factor |
|---|---|
| 90% | 1 |
| 95% | 0.62 |
| 96% | 0.53 |
| 97% | 0.44 |
| 98% | 0.33 |
| 99% | 0.21 |
$a_{3}$ = Application factor, generally 1.0.
$a_{3}$ = 1.0 under ideal lubrication condition, when rolling element and track surface are completely isolated by oil film and surface failure can be ignored.
$a_{3}$ < 1 for poor lubrication conditions (such as low viscocity, minimal or dirty lubrication), extremely slow speeds, shock loading, vibration, or extreme temperatures. Value should not fall below *0.5*.
$a_{3}$ > 1 for supremely excellent conditions.
Safety factor: $$ S_{0} = \frac { C_{0} } {L} $$
Revolutions: $$ r = \left( \frac {C}{ L \, a_{1}} \right)^x \, C_{x} \, a_{2} \, a_{3} $$
Hours: $$ h = \frac {r}{60 \, n} $$
Basic static load: $$ C_{0} = S_{0} \, L $$
Revolutions: $$ r = 60 \, h \, n $$
Basic dynamic load:
$$ C = L \, a_{1} \left( \frac {r} {C_{x} \, a_{2} \, a_{3}} \right)^ \frac{1}{x} $$
Safety factor: $$ S_{0} = \frac { C_{0} } {L} $$
Revolutions: $$ r = 60 \, h \, n $$
Load: $$ L = \frac {C} { a_{1} \, \left( \frac {r} {C_{x} \, a_{2} \, a_{3}} \right)^ \frac{1}{x} } $$
Safety factor: $$ S_{0} = \frac { C_{0} } {L} $$
Revolutions: $$ r = \left( \frac {C} {L \, a_{1}}\right)^x \, C_{x} \, a_{2} \, a_{3} $$
RPM: $$ n = \frac{r}{60 \, h} $$