Contained earth (CE) is a structurally designed natural building material that combines containment, inexpensive reinforcement, and strongly cohesive earthen walls. CE is earthbag construction that can be calibrated for several seismic risk levels based on building soil strength and plan standards for adequate bracing.
There is a recognized need for structural understanding of alternative building materials. [1] Construction guidelines for CE are currently under development, based on the New Zealand's performance-based code for adobe and rammed earth. [2]
CE is differentiated from contained gravel (CG) or contained sand (CS) by the use of damp, tamped, cured cohesive fill. CE can be modular, built in poly-propylene rice bag material containers, or solid, built in mesh tubing that allows earthen fill to solidify between courses.
CG, filled with pumice or ordinary gravel and/ or small stones, is often used as water-resistant base walls under CE, which also provides an effective capillary break. Soilbags used mostly in horizontal applications by civil engineers contain loose fill which includes both CG and CS. CG courses, like soilbags, may contribute base isolation and/or vibration damping qualities, [3] [4] although out-of-plane strength needs research.
For clarity, earthbag built with a low cohesion fill, or filled with dry soil that does not solidify, is not CE but CS. Uncured CE also performs structurally like CS.
Builders used to working without engineers are proud of earthbag's unlimited variations. Few trainers discuss risk levels of building sites, or recommend accurate tests of soil strength, even though soil strength is a key factor of improved seismic performance for earthen walls. [5]
Need for or use of metal components are disputed, including rebar hammered into walls [6] and barbed wire between courses, although static friction of smooth bag-to-bag surfaces of heavy modular CE walls is 0.4 with no adhesion. [7]
Engineering knowledge of earthbag has been growing. [8] More is known about the performance of walls made with sand or dry or uncured soil than about the overwhelming majority of earthbag buildings which have used damp, cohesive soil fill. Reports based on tests of soilbags and loose or granular fill (or uncured fill) assumes that soil strength is less important to wall strength than bag fabric strength for. [9] However, shear tests show clearly that stronger cured, cohesive fill increases contained earth wall strength substantially. [10]
Earthbag developed gradually without structural analysis, first for small domes, [11] then for vertical wall buildings of many shapes. Although domes passed structural testing in California, no structural information was extracted from tests of the inherently stable shapes. [12] Builders borrowed guidelines for adobe to recommend plan details, [13] but code developed in low seismic risk New Mexico does not address issues for higher risk areas. [14] California's seismic risk levels are almost three times as high as New Mexico's, [15] and risk worldwide rises much higher.
Earthbag is often tried after disasters in the developing world, including Sri Lanka's 2004 tsunami, [16] Haiti's 2010 earthquake [17] and Nepal's 2015 earthquake. [18]
CE walls fail in shear tests when barbs flex or bend back or (with weak soil fill) by chipping cured bag fill. CS walls or uncured CE walls fail differently, by slitting bag fabric as barbs move through loose fill.
Because no earthbag buildings were seriously damaged by seismic motion up to 0.8 g in Nepal's 2015 quakes, Nepal's building code recognizes earthbag, [19] although the code does not discuss soil strengths or improved reinforcement. Nepal requires buildings to resist 1.5 g risk although hazard maps show higher values. Better trainers assume the use of cohesive soil and barbed wire, and recommend vertical rebar, buttresses, and bond beams, [20] but rule of thumb earthbag techniques should be differentiated from contained earth that follows more complete guidelines.
Earthquake damage results confirm the validity of New Zealand's detailed standards for non-engineered adobe and rammed earth [21] which allow unreinforced buildings to 0.6 g force levels.
Although earthbag without specific guidelines may often be this strong, conventional adobe can have severe damage at levels below 0.2 g forces. [22] Non-traditional earthbag built with barbed wire, barely cohesive soil and no rebar can have half the shear strength of NZ's unreinforced adobe. [23] Somewhere between 0.3 and 0.6 g forces, CE guidelines become important.
Based on static shear testing (Stouter, P. May 2017): The following approximate guidelines assume a single story of 380 mm (15 in) wide walls with 2 strands of 4 point barbed wire per course. Check NZS 4299 for bracing wall spacing and size of bracing walls and/ or buttresses. Vertical rebar must be spaced 1.5 m (5 ft) on center average and embedded in wall fill while damp. Follow NZS 4299 restrictions on building size, site slope, climate, and uses. Discuss foundation concerns with an engineer, since NZS 4299 assumes a full reinforced concrete footing.
For comparison to NZS 4299 the following risk levels are based roughly on 0.2 second spectral acceleration (Ss) from 2% probability of exceedance in 50 years. Builders may refer to the Unified Facilities Handbook online [24] for these values for some cities worldwide. These risk levels are based on ultimate strength, but deformation limits may require stiffer detailing or lower risk levels.
Medium strength soil: 1.7 MPa (250 psi) unconfined compressive strength
Strong soil: 2.2 MPa (319 psi) unconfined compressive strength
Additional research and engineering analysis is needed to create valid CE manuals.
Adobe is a building material made from earth and organic materials. Adobe is Spanish for mudbrick, but in some English-speaking regions of Spanish heritage the term is used to refer to any kind of earthen construction. Most adobe buildings are similar in appearance to cob and rammed earth buildings. Adobe is among the earliest building materials, and is used throughout the world.
Geotechnical engineering, also known as geotechnics, is the branch of civil engineering concerned with the engineering behavior of earth materials. It uses the principles of soil mechanics and rock mechanics for the solution of its respective engineering problems. It also relies on knowledge of geology, hydrology, geophysics, and other related sciences. Geotechnical (rock) engineering is a subdiscipline of geological engineering.
Rebar, known when massed as reinforcing steel or reinforcement steel, is a steel bar or mesh of steel wires used as a tension device in reinforced concrete and reinforced masonry structures to strengthen and aid the concrete under tension. Concrete is strong under compression, but has weak tensile strength. Rebar significantly increases the tensile strength of the structure. Rebar's surface is often "deformed" with ribs, lugs or indentations to promote a better bond with the concrete and reduce the risk of slippage.
Retaining walls are relatively rigid walls used for supporting soil laterally so that it can be retained at different levels on the two sides. Retaining walls are structures designed to restrain soil to a slope that it would not naturally keep to. They are used to bound soils between two different elevations often in areas of terrain possessing undesirable slopes or in areas where the landscape needs to be shaped severely and engineered for more specific purposes like hillside farming or roadway overpasses. A retaining wall that retains soil on the backside and water on the frontside is called a seawall or a bulkhead.
Soil liquefaction occurs when a saturated or partially saturated soil substantially loses strength and stiffness in response to an applied stress such as shaking during an earthquake or other sudden change in stress condition, in which material that is ordinarily a solid behaves like a liquid. In soil mechanics, the term "liquefied" was first used by Allen Hazen in reference to the 1918 failure of the Calaveras Dam in California. He described the mechanism of flow liquefaction of the embankment dam as:
If the pressure of the water in the pores is great enough to carry all the load, it will have the effect of holding the particles apart and of producing a condition that is practically equivalent to that of quicksand… the initial movement of some part of the material might result in accumulating pressure, first on one point, and then on another, successively, as the early points of concentration were liquefied.
Earthbag construction is an inexpensive building method using mostly local soil to create structures which are both strong and can be quickly built.
Seismic retrofitting is the modification of existing structures to make them more resistant to seismic activity, ground motion, or soil failure due to earthquakes. With better understanding of seismic demand on structures and with our recent experiences with large earthquakes near urban centers, the need of seismic retrofitting is well acknowledged. Prior to the introduction of modern seismic codes in the late 1960s for developed countries and late 1970s for many other parts of the world, many structures were designed without adequate detailing and reinforcement for seismic protection. In view of the imminent problem, various research work has been carried out. State-of-the-art technical guidelines for seismic assessment, retrofit and rehabilitation have been published around the world – such as the ASCE-SEI 41 and the New Zealand Society for Earthquake Engineering (NZSEE)'s guidelines. These codes must be regularly updated; the 1994 Northridge earthquake brought to light the brittleness of welded steel frames, for example.
Earthquake engineering is an interdisciplinary branch of engineering that designs and analyzes structures, such as buildings and bridges, with earthquakes in mind. Its overall goal is to make such structures more resistant to earthquakes. An earthquake engineer aims to construct structures that will not be damaged in minor shaking and will avoid serious damage or collapse in a major earthquake. Earthquake engineering is the scientific field concerned with protecting society, the natural environment, and the man-made environment from earthquakes by limiting the seismic risk to socio-economically acceptable levels. Traditionally, it has been narrowly defined as the study of the behavior of structures and geo-structures subject to seismic loading; it is considered as a subset of structural engineering, geotechnical engineering, mechanical engineering, chemical engineering, applied physics, etc. However, the tremendous costs experienced in recent earthquakes have led to an expansion of its scope to encompass disciplines from the wider field of civil engineering, mechanical engineering, nuclear engineering, and from the social sciences, especially sociology, political science, economics, and finance.
Geotechnical investigations are performed by geotechnical engineers or engineering geologists to obtain information on the physical properties of soil earthworks and foundations for proposed structures and for repair of distress to earthworks and structures caused by subsurface conditions. This type of investigation is called a site investigation. Additionally, geotechnical investigations are also used to measure the thermal resistivity of soils or backfill materials required for underground transmission lines, oil and gas pipelines, radioactive waste disposal, and solar thermal storage facilities. A geotechnical investigation will include surface exploration and subsurface exploration of a site. Sometimes, geophysical methods are used to obtain data about sites. Subsurface exploration usually involves soil sampling and laboratory tests of the soil samples retrieved.
An earth structure is a building or other structure made largely from soil. Since soil is a widely available material, it has been used in construction since prehistoric times. It may be combined with other materials, compressed and/or baked to add strength. Soil is still an economical material for many applications, and may have low environmental impact both during and after construction.
This is an alphabetical list of articles pertaining specifically to structural engineering. For a broad overview of engineering, please see List of engineering topics. For biographies please see List of engineers.
Mechanically stabilized earth is soil constructed with artificial reinforcing. It can be used for retaining walls, bridge abutments, seawalls, and dikes. Although the basic principles of MSE have been used throughout history, MSE was developed in its current form in the 1960s. The reinforcing elements used can vary but include steel and geosynthetics.
Superadobe is a form of earthbag construction that was developed by Iranian architect Nader Khalili. The technique uses layered long fabric tubes or bags filled with adobe to form a compression structure. The resulting beehive-shaped structures employ corbelled arches, corbelled domes, and vaults to create sturdy single and double-curved shells. It has received growing interest for the past two decades in the natural building and sustainability movements.
National Center for Research on Earthquake Engineering is an organisation in Da'an District, Taipei, Taiwan.
Ground–structure interaction (SSI) consists of the interaction between soil (ground) and a structure built upon it. It is primarily an exchange of mutual stress, whereby the movement of the ground-structure system is influenced by both the type of ground and the type of structure. This is especially applicable to areas of seismic activity. Various combinations of soil and structure can either amplify or diminish movement and subsequent damage. A building on stiff ground rather than deformable ground will tend to suffer greater damage. A second interaction effect, tied to mechanical properties of soil, is the sinking of foundations, worsened by a seismic event. This phenomenon is called soil liquefaction.
Mete Avni Sözen was Kettelhut Distinguished Professor of Structural Engineering at Purdue University, Indiana, United States from 1992 to 2018.
Hybrid masonry is a new type of building system that uses engineered, reinforced masonry to brace frame structures. Typically, hybrid masonry is implemented with concrete masonry panels used to brace steel frame structures. The basic concept is to attach a reinforced concrete masonry panel to a structural steel frame such that some combination of gravity forces, story shears and overturning moments can be transferred to the masonry. The structural engineer can choose from three different types of hybrid masonry and two different reinforcement anchorage types. In conventional steel frame building systems, the vertical force resisting steel frame system is supported in the lateral direction by steel bracing or an equivalent system. When the architectural plans call for concrete masonry walls to be placed within the frame, extra labor is required to ensure the masonry fits around the steel frame. Usually, this placement does not take advantage of the structural properties of the masonry panels. In hybrid masonry, the masonry panels take the place of conventional steel bracing, utilizing the structural properties of reinforced concrete masonry walls.
Medhat Haroun was an Egyptian-American expert on earthquake engineering. He wrote more than 300 technical papers and received the Charles Martin Duke Lifeline Earthquake Engineering Award (2006) and the Walter Huber Civil Engineering Research Prize (1992) from the American Society of Civil Engineers.
Alker is an earth-based stabilized building material produced by the addition of gypsum, lime, and water to earth with the appropriate granulometric structure and with a cohesive property. Unbaked and produced on-site either as adobe blocks or by pouring into mouldings, it has significant economical and ecological advantages. Its physical and mechanical properties are superior to traditional earth construction materials, and are comparable to other stabilized earthen materials. The ratios of the mixture are determined in accordance with the purpose of construction. Alker has primarily been used as a wall construction material; for this purpose, the addition of 8-10% gypsum, 2.5-5% lime, and 20% water to earth produces optimum results. These ratios may change according to the nature and content of clay in the soil.
Andrew Stuart Whittaker is an American structural engineer who is currently a SUNY Distinguished Professor in the Department of Civil, Structural and Environmental Engineering at the University at Buffalo, State University of New York.