1. Introduction
On El Hierro island, in order to achieve energy autonomy through fully renewable energy sources, the company Gorona del Viento El Hierro S.A. carried out a project consisting in the implementation of a new energy model, combining wind and hydraulic energy. As the successful bidder for the project, the company IDOM Consulting, Engineering, Architecture, S.A.U. carried out the detailed engineering design of El Hierro hydro-wind plant, inaugurated in 2014. Among the elements of this plant, highlights the upper water reservoir, located in the natural depression of an inactive volcanic crater, “La Caldera”, whose bottom has been waterproofed by placing a PVC geomembrane.
2. Geological Settings
El Hierro is the smallest, youngest (1.2 Ma) [
1], and most isolated of the Canary Islands. These involve a chain of volcanic islands located off the north-western coast of Africa, whose origins are linked to a hot spot or plume. The formation of this island is due to the succession and stacking of two important volcanic structures (Tiñor and El Golfo), and a last stage of dorsal volcanism [
2], with three axes that give the island its characteristic “Y” shape.
The location of the upper reservoir is an inactive volcanic crater, with slopes that are made up of competent and resistant volcanic rocks (“aa” lava flows). These rocks are basic to ultrabasic in composition, and based on the Mg content classified as basalts and traquibasalts. Moreover, the bottom is formed by a volcanic vent mainly filled with soils. The foot of the inner slopes of the crater is covered by colluvial deposits, derived from the action of erosion and gravity on the upper slopes of the crater (
Figure 1). Beneath these recent deposits, a large thickness of soils generated by intense weathering of volcanic materials was identified. In the southeast of the reservoir, by geophysical techniques (PSC-7 to 8 and TEC-1) and rotary boreholes (S-1 to 3), 46.5 m of maximum thickness of soil was identified.
3. Geotechnical Settings
3.1. Site Investigation and Laboratory Tests
The investigations carried out in the bottom of the upper reservoir are indicated in
Table 1.
12 samples of rock and paleosoil were taken in outcrops in La Caldera for their geochemical analysis. Disturbed samples taken in trial pits and undisturbed samples and core samples taken from boreholes were tested in the laboratory (
Table 2).
3.2. Geotechnical Units
Based on the physical and mechanical characteristics of the soils that fill the crater, the geotechnical units indicated in
Table 3 were established. Excluding colluvial soils, the observed characteristics are typical of soils derived from weathering of volcanic materials, with very high void ratios and low dry density [
3,
4].
The soil structure is line with the typical structure generated by weathering of volcanic materials: the younger soils (the more superficial ones), have higher density, high content of silt and sand and low clay content, while the older soils (the deeper ones) show an intense weathering, evidenced by the decrease in the content in primary minerals, and are characterized by a lower density and cementation and an increase in clay content [
5].
4. Soil Improvement: Pre-Loading
Previous experiences in this type of residual volcanic soils had already been described on the island of La Palma, where significant settlements had been occurred in the Barlovento water reservoir (2.35 m estimated at the lowest point), resulting in the failure of the PVC geomembrane [
6]. The high deformability of the soils filling the crater La Caldera and the limitation, imposed by the characteristics of the geomembrane, of a maximum postconstructive settlement of 10–12 cm, led to propose a soil improvement by preloading.
The selected preloading method was a “mobile dune”, which consists in moving the total volume of earth excavated in the work, to cover, in successive phases, the entire bottom of the reservoir. This would simulate the conditions of the reservoir filled with water.
Previously to the mobile dune, in the southeast area of the deposit, a trial embankment of 10 m height was built and monitored by eight settlement plates. This provided key information regarding the behavior of these soils under the action of preloading, very useful for the design of the mobile dune execution stages (
Figure 2).
The behavior of the soils was mainly of plastic type, producing a maximum settlement of 0.98 m in the center of the embankment (P-5 in
Figure 2A) and a maximum rebound of the bottom when removing the embankment of 8 cm (P-3 in
Figure 2B) [
7].
The settlements generated by the action of the mobile dune in the southeast area of the reservoir were monitored by four settlement cells: C-10 to C-13 (
Figure 2C). The settlement varied between a minimum value of 0.42 m recorded in cell C-13 (near the edge of the crater) and a maximum value of 0.68 m recorded in cell C-11 (located towards the center of the crater).
The accumulated settlement in the lousy point of the southeast area of the upper reservoir (
Figure 2D), sum of those recorded during the execution of the trial embankment and the mobile dune, reached a value close to 1.5 m.
5. Conclusions
The soils that fill the crater “La Caldera” have been generated by the intense weathering of volcanic materials, which increases with depth.
The high settlements in the southeast area of the upper reservoir were due to the fact that this area may be the emission point of the crater, where greatest thickness of residual soils (up to 46.5 m) were identified. In addition, the geotechnical unit with greatest deformability, LN, has only been identified in this area of the upper reservoir.
The behavior of these soils during the preloading carried out for soil improvement (trial embankment and mobile dune) was mainly of plastic type, producing an accumulated settlement close to 1.5 m.
Author Contributions
D.A. contributed to the geological-geotechnical research and interpretation of results, advising IDOM in the development of the Project; Á.R.-O. carried out the geochemical study of the samples; F.F.-B. partner of IDOM, was responsible of geological-geotechnical investigation, collaborated in data analysis and wrote the paper.
Acknowledgments
The authors thank Gorona del Viento El Hierro, S.A. for the award to IDOM Consulting, Engineering, Architecture, S.A.U. of the engineering design of the hydro-wind plant project. Special thanks to IDOM staff and external advisors who have participated in the development of this project.
Conflicts of Interest
The information contained in this article is based on the results of the Geological and Geotechnical Study for the Detail Design of Hydro-wind Plant of El Hierro, carried out by the company IDOM. This project was funded by Gorona del Viento El Hierro, S.A. and financed (65%) by the Ministry of Industry, Tourism and Commerce and the IDAE.
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