• Faria, Paulina
• Gomes, Maria Idália
• Gonçalves, Teresa Diaz

Abstract

All over the world, many earth buildings are deteriorating due to lack of maintenance and repair. Repairs on rammed earth walls are mainly done with mortars, by rendering application; however, often the repair is inadequate, resorting to the use of incompatible materials, including cement-based mortars. It has been observed that such interventions, in walls that until that day only had presented natural ageing issues, created new problems, much more dangerous for the building than the previous ones, causing serious deficiencies in this type of construction. One of the problems is that the detachment of the new cement-based mortar rendering only occurs after some time but, until that occurrence, degradations develop in the wall itself. When the render detaches, instead of needing only a new render, the surface has to be repaired in depth, with a repair mortar. Consequently, it has been stablished that the renders, and particularly repair mortars, should have physical, mechanical and chemical properties similar to those of the rammed earth walls. This article intends to contribute to a better knowledge of earth-based mortars used to repair the surface of rammed earth walls. The studied mortars are based on four types of earth: three of them were collected from non-deteriorated parts of walls of unstabilized rammed earth buildings located in Alentejo region, south of Portugal; the fourth is a commercial earth, consisting mainly of clay. Other components were also used, particularly: sand to control shrinkage; binders stabilizers such as dry hydrated air-lime, natural hydraulic lime, Portland cement and natural cement; as well as natural vegetal fibers (hemp fibers). The experimental analysis of the mortars in the fresh state consisted in determining the consistency by flow table and the bulk density. In the hardened state, the tests made it possible to evaluate the following properties: linear and volumetric shrinkage; capillary water absorption; drying capacity; dynamic modulus of elasticity; flexural and compressive strength. ; Maria Idália Gomes was financially supported by a doctoral grant from the Portuguese Foundation for Science and Technology (FCT). This work was carried out at the National Laboratory for Civil Engineering (LNEC), in Lisbon. The authors are grateful to the people who collaborated in the experimental work, in particular LNEC technicians, José Costa, João Junior, Luis Nunes, and Bento Sabala. Thanks are due to Sorgila company for providing the reference earth and sand, to Lusical and Secil companies for providing hydrated air-lime powder, natural hydraulic lime and Portland cement and to the Aubiose Company for the hemp fiber. Thanks are also due to Georg Hilbert, Johannes Weber and Grzegorz Adamski, who, within the scope of the ROCARE EU project, provided the natural cement used in this work.

Topics

• density
• impedance spectroscopy
• surface
• strength
• cement
• elasticity
• aging
• drying
• lime