Ciria Report 108 Concrete Pressure On Formwork Official

This article breaks down every aspect of CIRIA 108, explaining how to apply its formulas, why it outperforms older standards like ACI 347, and how to prevent formwork failure on your next pour. Before CIRIA 108, engineers primarily relied on hydraulic pressure formulas, assuming that fresh concrete behaved like a liquid (Pressure = Density x Depth). While this approach (often called the "hydrostatic" model) is safe, it is wildly uneconomical. It assumes that until concrete hardens, every inch of height exerts full fluid pressure.

Order a penetration resistance test (ASTM C403 / BS EN 480-2) on your specific mix at the expected site temperature.

Rearrange the formula: R_max = P_allowed / (1.2 × D × E) If your formwork is rated for 80 kN/m², you solve for R to determine the maximum trucks per hour. ciria report 108 concrete pressure on formwork

In the late 1970s and early 1980s, CIRIA undertook a massive research project, observing real-world pours in walls, columns, and slipforms. The result, published in , provided empirical evidence that concrete stiffens (develops "shear strength") as it hydrates, thereby reducing peak pressure significantly below the hydrostatic maximum.

Published by the Construction Industry Research and Information Association (CIRIA), Report 108 fundamentally changed how the industry calculates the lateral pressure exerted by fresh concrete. Even with the advent of Self-Compacting Concrete (SCC) and modern admixtures, the principles laid out in this 1985 report remain the industry benchmark. This article breaks down every aspect of CIRIA

For decades, engineers and contractors have relied on a single, authoritative document to navigate this risk:

Have a ready-mix engineer track the concrete temperature. If the truck arrives cooler than expected, recalculate P_max immediately. Case Study: The Heathrow Terminal 5 Pours When constructing the massive diaphragm walls for Heathrow Terminal 5 (London), engineers faced pours up to 15 meters deep. Ordinary hydrostatic assumptions would have required 200 kN/m² formwork—impractical and expensive. It assumes that until concrete hardens, every inch

Water exerts pressure equally in all directions. Concrete, however, is a granular material with thixotropy (it thickens when left undisturbed) and cohesiveness. Once the concrete begins to set, it forms an arching action against the formwork.