Adjustable Shock Absorber
Bansbachs industrial shock absorbers are a superior alternative to coil springs or rubber bump stops for energy absorption and linear deceleration. We offer many different models from mild to extreme. Our shock absorbers are the perfect solution for a wide range of applications, from a simple cabinet door, to the corrosive environments of the medical field, or the extreme environment of industrial machine equipment. Bansbach shock absorbers are designed to absorb the impact with no bounce back. This steady, gradual deceleration allows faster cycle rates, increased equipment life, and higher production rates while reducing maintenance expenses.
|Model||Stroke mm||Max. absorption energy J (kgfm)||Max. equivalent mass kg (kgf)||Range of impact rate m/s||Orifice type|
|FA-2540LB-C||40||63.7 (6.5)||500 (500)||0.3~1||Single-orifice type|
|FA-2540LD-C||200 (200)||0.7~3||Multiple-orifice type|
|FWM-2540LBD-C||350 (350)||0.3~2||Multiple-varying orifice type|
|Max. drag N (kgf)||3920 (400)|
|Max. cycle rate cycle/min||60|
|Max. absorption energy per minute J/min (kgfm/min)||637 (65)|
|Recovering power of the piston rod N (kgf)||71.4 (7.29) or lower|
|Operating temperature °C||-5 ~ 70|
|Mass: C type g||475.1|
|FA-2540LB series||Single orifice||For low speed|
|FA-2540LD series||Multiple-varying orifice||For medium speed|
|FWM-2540LBD series||Multiple-orifice||For high-speed|
|Stopper nut OP-020LB||Square flange OP-040LB|
Precautions for Use
* Do not use this product without carefully reading the attached owner's manual.
* Ensure that an external stopper (Stopper nut OP-020LB) is also used.
* Do not turn the oil inlet screw located at the bottom of the main unit.
* Ensure that sufficient mounting strength is secured for this product.
(As a guideline, it should be 2 to 3 times the maximum drag listed in the catalogue.)
* Do not use this product in a vacuum or a location where it may come in contact with oil.
* Ensure that an eccentric load is not applied to the soft absorber. (Allowable eccentric angle: within ±2.5°)