Interior separators and shelves are crucial for keeping similar cables and hoses compartmentalized. When no separation is used, cables can cross over one another and become tangled.

The clearance height of a compartment with several cables and hoses shouldn’t amount to more than 1.5 times the diameter of the largest cable or hose. Cables with wide differences in diameter should be laid in separate compartments. Cables and hoses with incompatible jackets should also be separated. (See point number 6 below for more on this.)

The maximum cable or hose diameter corresponds to the inner height of the selected cable carrier, with additional minimum clearance. We recommend leaving a 10% clearance surrounding electrical cables, and a 20% clearance surrounding hydraulic hoses.

A correctly separated cable carrier

While it may be hard to leave seemingly available cable carrier space unfilled, overfilling a cable carrier can obstruct free movement. Cables that do not have room to move properly will interfere with the movement of the cable carrier.

Additionally, if cables become caught on one another and bind, jacket abrasion can be significantly increased. There is also a greater chance of electromagnetic interference, or EMI, when power and data cables are positioned close together. As a rule, we recommend you space all power and data cables as far apart as possible in order to best prevent EMI.

An overfilled cable carrier

Without the proper strain relief, there is no way to control the length of the cable inside the carrier.

As the cable carrier moves back and forth, the cable will pull into the carrier and bunch up, causing premature system failure. Points outside the carrier, such as connectors or end termination points, will also absorb all the mechanical forces.

Typically, round electrical cables should be secured with strain relief at both ends. In exceptional cases, the cables may be fixed with strain relief at the moving end only. A gap of 10-30 times the cable diameter between the end of the bend radius and the fixed point is recommended.

Strain relieved cables inside cable carriers

Correctly strain relieved cables will position in the neutral axis of a cable carrier. The cables should not be pulled tight against the inner radius or pushed up against the outer radius.

Strain relief should be properly installed, and then tested in both the extended and the home position.

The cable is neither pulled tight against the inner bend radius, nor pushed against the outer radius.

If the cable carrier’s length is miscalculated, then the full range of movement could be compromised. Pulled or stretched cables can result in conductor breakage.

To properly calculate the length of an energy chain cable carrier, use the following equations:

LK = S/2 + K or LK = S/2 + ΔM + K

If the fixed end is located in the center of travel, the cable carrier’s length, “LK,” is calculated by using half the length of travel, and adding the value “K” for the bend radius. Placing the fixed end in the center of travel is the most cost-effective solution, as it requires the shortest possible cable carrier and cable/hose lengths. When the fixed end is not located in the center, the offset mounting value (ΔM) must be added.

Due to the wide variety of applications, we offer free consultation services for our customers and potential customers. Provide us with your applications's cable requirements, and receive our recommendations quickly, with no strings attached. Contact us directly at sales@igus.com, or by calling us at 1.800.521.2747 Monday-Friday, 8 AM - 8PM EST.