Structured Wall pipes represent a design approach primarily used for non-pressure applications where bending load is dominant, such as drain, waste, venting (DWV), and sewers under soil loads. Unlike pressure pipes that rely on uniform wall thickness for tensile strength, structured wall pipes utilize shape to achieve stiffness.
The fundamental principle behind Structured Wall pipes is to move material away from the center of the pipe cross-section. This increases the moment of inertia (I) of the pipe wall. Since pipe stiffness is proportional to I, this design increases stiffness without significantly increasing material weight. The resistance against bending is proportional to the wall thickness to the power of three. Leaving out the middle of the pipe wall offers a significant weight saving while retaining a large portion of the stiffness; for example, a 50% weight saving might cost only 12.5% of stiffness. The outer 50% of the wall is more effective for stiffness than the inner 50%.
Examples of Structured Wall pipes include Cordrain pipe, Double Wall Corrugated pipe (DWC), Ultrarib pipe, Wavihol pipe, and Foam core pipe. They are considered light weight pipes.
Standards for Structured Wall Pipes include EN13476 (for U-drain and Sewerage), ISO 21138, and AS/NZS 126027. These standards are often functional, prescribing a minimum pipe stiffness rather than a fixed wall thickness, although a minimum wall thickness base limit may still exist. For example, EN13476 prescribes a minimum stiffness of SN4 for pipes OD 500 mm and smaller. Some standards like AS/NZS 1260 specify minimum PVC content in the core (e.g., 80%) compared to others (e.g., 60% in EN13476).
Despite challenges, structured wall designs like DWC are used for applications like storm water.