Control of an Architectural Cable Net Geometry

TL;DR

This paper presents a novel feedback control method for precisely shaping cable net structures used as flexible formwork in constructing doubly curved concrete shells, ensuring high accuracy despite fabrication uncertainties.

Contribution

It introduces a new control algorithm based on Sequential Quadratic Programming for cable net formwork, with proven convergence and practical sparse input computation.

Findings

Control algorithm guarantees feasibility at each step

Experimental results show high control accuracy

Extension for sparse inputs enhances practicality

Abstract

Doubly curved thin concrete shells are very efficient building structures, suitable for light-weight construction because of their high structural stability. In the process of constructing such shells, an efficient innovative flexible formwork that is based on a cable network can be used instead of the costly conventional timber formwork. To guarantee the structural properties of such a shell, the desired form, that is designed and optimized in advance, needs to be precisely achieved. The sensitivity of the flexible cable net formwork to fabrication tolerances and uncertainties makes high accuracy challenging. We propose a new construction method where the form of the cable net structure is measured and controlled in a feedback loop during its construction. Two models based on a force and on an energy approach are reviewed and their equivalence is shown. An efficient control algorithm, which is based on a variant of Sequential Quadratic Programming, and which guarantees feasibility at every iteration, is derived. Based on mild assumptions on the cable net, global convergence to a stationary point is shown. For practical applicability, an extension of the control algorithm for computing sparse input vectors is given. Experimental results on a cable net formwork prototype for a shell roof structure are presented to demonstrate the control performance.