Functional Principles

Titus dampers slow down linear or rotary movement before reaching a resting position.

By converting kinetic energy into thermal energy, hydraulic dampers reduce hard shocks and oscillation amplitudes. In a linear damper, the kinetic energy of the moving object is transferred through the steel rod to the valve in the damping cylinder. Hydraulic fluid is pushed through the valve and heat is generated. As the spring returns the valve to its original position, hydraulic fluid flows back into the damping chamber.

Operating Scope

High coefficient of Titus damper assures efficient damping at any closing speed, even very slow. We can easily adapt damping force to your needs. Damping action is even and smooth for soft and reliable closing. 

 

Fh - damping force at slam speed (740mm/min)
Fl - damping force at slow speed (60mm/min)

 

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Reliable Damping at Any Speed

Higher coefficient means reliable damping at high speed and ensures that the system will reach its final position even at a very slow speed.

Damping Action

  • Flat Damping Action

    Flat Damping Action

    Flat or linear damping curve shows the uniform action produced during damper closing at a defined speed.

  • Progressive Damping Action

    Progressive Damping Action

    Ramp damping curve shows the progressive action produced during damper closing at a defined speed.

  • Damping Action with Final Release

    Damping Action with Final Release

    Damping curve with final release shows the flat/linear damping action produced during damper closing at a defined speed and drop of the force before the damper reaches the end position.

Even and Smooth Damping

High coefficient of Titus damper assures efficient damping at any closing speed, even very slow. We can easily adapt damping force to your needs. Damping action is even and smooth for soft and reliable closing.

 

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