Compact Wire Rope Isolators
Vibration Isolation in a Small Package
Use Enidine Compact Wire Rope Isolators for the best performance in vibration isolation. The compact design is smaller than most wire ropes and can provide both shock and vibration absorption even in situations where package space and sway are an issue.
Enidine Compact Wire Rope Isolator is made of all-metal, which gives the best multi-axis shock and vibration isolation in a small package. Even reliable in hostile environments, the WRI products have almost no maintenance and are highly resistant to oil, ozone, abrasives, and chemicals. Using CWRI products can reduce the amount of premature equipment failure and costly machine downtime.
Even if you have a non-standard application, you may still be able to use regular Wire Rope Isolators. These standard products can suit nearly any application. In unique circumstances, Enidine can create a custom isolator for your needs.
WRI are naturally well suited for shock isolaton. Elastomeric parts can be specifically designed for severe shock and perform very well.
Elastomers are more flexible in creating custom isolator performance in multi axis systems. The WRI can also be wound differently to customize stiffness.
Describes the dissipation of energy with time or displacement. There are many common types of damping; viscous damping (orifice in a hydraulic shock absorber), hysteretic damping (occurs in an elastomeric isolator), and coulomb damping (as in a wire rope isolator).
The difference between a 200, 400, 600, and 800 index number has relative meaning within a series. The larger the number the taller the isolator but the lower the isolator stiffness.
No, the tension stiffness is significantly greater than the compression stiffness. Also, ITT Enidine Inc. Incorporated does not recommend that the WRI be used in tension.
Yes, The ITT Enidine Inc. Incorporated standard WRI product is made from stainless steel and aluminum. The standard product can be used successfully in most normal indoor environments. Where greater protection is required, such as exposure to salt water or corrosive chemicals, stainless steel should be considered.
In general it represents the number of loops in the isolator.
In order to be able to reduce disturbing noise levels, it is very important to identify two key elements. The first element is the source of the noise. The second is the frequency of the noise. Typically a vibration mount designed in accordance with vibration.
The WRI can be used over a greater temperature range with less change in performance. Proper elastomer selection will make elastomers useful for most applications.
WRI have between 5% and 20% damping. The amount of damping is related to wire diameter and stroke. The larger the wire diameter, the more damped (and stiffer) the isolator. Damping can be less with small amplitude vibration.
This represents the six directions of movement that a vibration isolation device such as an elastomer or wire rope isolator is capable of traveling.
The number following WR represents the wire diameter in 32nd of an inch. The WR5 series isolators use 5/32” diameter wire.
The system is said to have coulomb or dry friction damping if the damping force in a vibratory system is constant and independent of position or velocity of the system.
Critical damping is the smallest amount of damping required to return a system to its equilibrium position without oscillation.
A dimensionless ratio, which defines the amount of damping in a system. Commonly defined as C/Cr.
Defined as the number of oscillations per unit time that an external force or displacement is applied to a system, can also be referred to as 'forcing frequency'. Typically measured in Hz (cycles per second).
Describes the amount of shock or vibration that a particular piece of equipment can withstand. Isolation systems are often designed to limiit the transmission of forces to the fragility level of the isolated equipment.
G is the value of acceleration produced by the force of gravity.
Isolation efficiency is the percent of vibration force or motion that is not transmitted through the vibration mount.
Loss factor is the measure of the damping value in an elastomer.
Is the frequency at which oscillating system will vibrate if displaced from its equilibrium position and allowed to vibrate freely. Often described as Fn and measured in Hz(cycles per second).
Noise is vibration of air. Vibrations of the air typically have a frequency and an intensity (loudness) level. Noise is what you hear with your ear.
When the frequency of excitation is equal to the natural frequency of a system, resonance occurs. When this happens there is amplification of the vibration input to the system and this can only be limited by the damping in the isolation system.
Application dependent, but in general, for shock applications use mounting options "B," "D," or "E".
Elastomers are typically better for high frequency vibration (>500 Hz). Both are well suited for mid frequency isolation (20 to 100 Hz).