Understand foundation design and construction

Name: Understand foundation design and construction
Uploaded: 2017-07-13T02:51:25+00:00
Duration: PTM22S33
Channel: Malcolm Osborne
Description: Understand foundation design and construction

Understand foundation design and construction
Topic Understand foundation design and construction Today’s Objective Identify different types of site surveys Understand the purpose of site investigation

Site Investigation Three stages:- A desk study. A walk-over survey
A physical exploration and inspection, of the ground by means of boreholes or trial pits. This third stage is sometimes called the ground investigation.

Site Investigation: Desk Study
Stage 1 The desk study is the first stage in the site investigation. Essentially, it comprises the collection and analysis of existing information (records) about the site. The information will come from a variety of sources and, and, once analysed, will form the basis for the second stage, the walk-over survey.

Desk Study The desk study has two main objectives:
to determine the nature, past use, and condition of the site. to determine whether this has any implications for the proposed building and its foundations It quickly ascertains whether the proposed structure can be built on the site In groups of 2/3 consider what sort of records would you be looking for?

Desk Study Sources of Information British Geological Survey
Ordnance Survey Landmark Information Group The Environment Agency The Local Authority County Records Utility Companies and the Coal Authority Local History Library The site vendor Aerial Photographs The bullet points list a number of potential sources of information for the desk study. Aerial photographs can also be useful.

Desk Study Outcome A check list for closer investigation during the walk-over survey Identification of potential hazards that may require specialist input When the desk study is complete it should be possible to produce a check list of items which require closer investigation during the walk-over survey. It may also be possible at this stage to identify hazards which require specialist input.

Site Investigation: Walk-over survey
This is the second stage in the site investigation. It's a detailed site inspection which: Enables much of the material discovered in the desk study to be confirmed or further investigated Identifies other potential hazards Enables the surveyor to collect photographic records Gives the surveyor/engineer the opportunity to create a site survey; a detailed drawings of all those items (trees, existing buildings, watercourses, topography, etc) which will have implications for the building design Obtains any additional information required to ensure that the building can be constructed safely and within budget.

Walk-over survey In stage 2 the need for specialist input may become apparent, even if it did not seem necessary during the desk study.

The NHBC recommend that this stage is divided into 6 sections: Topography Soils and rocks Surface water and ground water Vegetation Structural information Local information NHBC: (National House Builders Council)

Topography are there any abrupt changes in slope, or excavations at the base of slopes? are there depressions or valley bottoms that may be soft or filled? are there any signs of landslip such as sloping walls or tilting trees? is there evidence of imported soil or fill? is there any sign of subsidence?

Soils and Rocks what is the basic type of ground? is there evidence of peat, silt, or other highly compressible material? is there surface cracking or stickiness which might indicate a shrinkable clay? are there sudden changes in material, eg, clay to rock?

Site Investigation - Stage 2 Walk-over Survey- Water
Site Investigation: Walk-over survey Surface Water and Ground Water Site Investigation - Stage 2 Walk-over Survey- Water is a high water table indicated , eg, by waterlogged ground? are there any signs of flooding? are there any reeds or water loving plants? are there any springs, ditches or ponds etc? is there any discoloured water, if so, what is its source?

Vegetation is the vegetation sparse, dead or dying? what is the nature of the vegetation adjoining the land? what are the species, height and condition of the trees? is there evidence of tree removal? If, following the desk study and walk-over survey, hazards are suspected specialist input will be required and more detailed investigation will be necessary.

Site Investigation: Walk-over survey Structural and local information
is there evidence of damage to buildings on, or near, the site? is there other evidence of movement? is there evidence of buildings or services below the ground? is there local knowledge regarding past use of the site? do local place names, road names, etc. help identify former use of the site?

Understand foundation design and construction
Topic Understand foundation design and construction Today’s Objective Understand the purpose of ground investigation

Site Investigation: Ground Investigation
A direct ground investigation is the third stage in the site investigation. It provides detailed information on:- The nature and thickness of made up ground/top soil above the subsoil. The nature, thickness and stratum depth of subsoil An assessment of allowable bearing pressure. Groundwater levels, chemicals in the ground etc. Existing structures or hazards in the ground. Key term: Geotechnical properties How soil is likely to perform when imposing loads on it or what will happen when water is removed to allow work to take place.

Ground investigations should provide the following:- Classification of soils Soil profile Soil parameters Key term: Soil Parameters How the soil will react to the building works and imposing loads. The soil can be expected to carry a certain weight depending on its parameters and its characteristics.

Classification of soils Soil is classified by: 1. Geological origin 2. Physical properties 3. Chemical composition 4. Particle size The simplest classification used by geologists is:- Rock Granular soils ( sands and gravel) Cohesive soils (clays) Organic soils ( peat and top soil) Fill or made up ground. These broad soil classifications coupled with simple tests to determine soil parameters or to detect the presence of harmful chemicals to construction materials are normally sufficient for low rise buildings.

Soil profile:- Identification of the layers of soil below ground level, depth and type. Boundaries between the various layers/types are not always distinct, which means it is sometimes difficult to tell what condition will actually be found when digging into the earth

Site Investigation: Subsoil survey
Soil profile:- Complete the worksheet

Soil Parameters:- The load imposed by a building and the ability of the ground to support this needs to be quantified. Eg. Approved Documents; Part A, Table 10 Analysis of soil type and loadings, giving recommended foundation widths. Engineering design and calculations may be required to find out the soil parameters especially ground that has difficult soils such as clays since these soils perform variably. Hence the need to quantify the load imposed by a building and the ability of the ground to support this load (See table 10). E.g. rock - well Peat – very weak, therefore must transfer load to a suitable substrata below the peat (pile foundations).

Plan the direct methods required for site investigation. Identify the depths of investigations required at different locations around the site. Boreholes should penetrate completely through made up ground or in fill. Identify suitable in-situ and lab testing methods. Decide on the number and location of bore holes, frequency of testing. Plan and Make allowances for any unforeseen ground and groundwater conditions on site. Key term: Borehole Holes sunk into the ground to extract soil samples at differing levels. The information is recorded as the holes are drilled so that the design engineer discovers at what depth each soil is found. Key term: Made Ground Any ground that has been artificially made from previous works, e.g. layers of stone compacted and laid to form a level surface ready for construction work.

Stage 4: Keep Records Records of any investigation, record the basis of the planned site investigation and the expected ground conditions. The specialist contractor who carries out the work will then know if the ground conditions they encounter are unforeseen, in which case they may have to alter the scope of the field or testing work.

Techniques: Trial pits (Max 5m deep) Trial pits are particularly useful in the investigation of sites intended for low – rise construction Records need to be kept as a ‘log’ with the profile recorded as the hole is dug. Trial pits are relatively cheap but care must be taken with exposed excavations, and some may need shoring with timber or hydraulic earth supports. These also need to be well identified as open excavation can also be dangerous to any person on site. Extremely valuable if the depth of the investigation is limited to approx 5m or less. Can be excavated using a back-actor or 360 degree slew hydraulic excavator. Trial pits are particularly useful in the investigation of sites intended for low – rise construction because the foundation type for this type of structure is generally 0.4 to 0.6m wide and max 3m deep. Thus the depth would be around 3 to 5m.

For low rise housing, on green-field sites, machine-dug trial pits are probably the most common method of ground investigation. The pits do not normally need to be deeper than 4-5 metres unless specific problems are encountered. BS 8103 states that; "The depth of the trial pits should be at least 2 metres. If, at this depth, the ground is unsuitable for the proposed foundations, (ie, strip foundations) a suitable qualified person should be consulted". Trial pits should be excavated close to the proposed foundation, but not so close as to affect its actual construction. The number of pits is usually a matter for judgement and will depend on the size of the proposed development, the nature of the site, and the consistency of the soil across the site.

Trial pits clip Extremely valuable if the depth of the investigation is limited to approx 5m or less. Can be excavated using a back-actor or 360 degree slew hydraulic excavator. Trial pits are particularly useful in the investigation of sites intended for low – rise construction because the foundation type for this type of structure is generally 0.4 to 0.6m wide and max 3m deep. Thus the depth would be around 3 to 5m.

Trial holes List the advantages and disadvantages For low rise housing, on green-field sites, machine-dug trial pits are probably the most common method of ground investigation. The pits do not normally need to be deeper than 4-5 metres unless specific problems are encountered. BS 8103 states that; "The depth of the trial pits should be at least 2 metres. If, at this depth, the ground is unsuitable for the proposed foundations, (ie, strip foundations) a suitable qualified person should be consulted". Trial pits should be excavated close to the proposed foundation, but not so close as to affect its actual construction. The number of pits is usually a matter for judgement and will depend on the size of the proposed development, the nature of the site, and the consistency of the soil across the site.

Techniques: Boreholes ( mm) Light percussion equipment is used to drive a hollow tube in to the soil In clay soils a ‘clay cutter’ is used In granular soils a ‘flap valve’ is used The main advantage of light percussion drilling is its ability to make deeper holes in a wide range of ground conditions. This method is considerably more expensive than shallow trial pits and auger holes. Clay cutter – dropping a hollow tube into the clay so that the clay becomes lodged in the base. The clay cutter and contents is then carefully lifted to the surface. Flap Valve – hollow tube is pressed into ground using water pressure creating a water/soil mix. Soil drops out of this mixture are collected and retained as ‘disturbed samples. Can be analysed in a lab to determine it’s load bearing capacity.

Bore hole clip Clay cutter – dropping a hollow tube into the clay so that the clay becomes lodged in the base. The clay cutter and contents is then carefully lifted to the surface. Flap Valve – hollow tube is pressed into ground using water pressure creating a water/soil mix. Soil drops out of this mixture are collected and retained as ‘disturbed samples. Can be analysed in a lab to determine it’s load bearing capacity.

Boreholes List the advantages and disadvantages

Exploratory holes: How deep? Depth depends on ‘stress distribution’ under the foundation. Boreholes should penetrate all deposits unsuitable for foundation purposes such as unconsolidated fill or materials that need compacting e.g. peat, organic silts, and very soft compressible clays. Depth requirements should be reconsidered when the results of the first tests have become available, as it may be possible to reduce the depth of the subsequent borings. Key term: Stress Distribution How the foundation distributes the load of a building. A very wide, flat foundation will support more load than a narrow thin strip. Compressible clay can be compressed to increase its strength or load bearing capacity.

Exploratory holes: How many? The maximum number of boreholes will depend on the complexity of the local geology and construction project. The number can change as more information becomes available from earlier investigations. Exploratory holes: Where? The location of boreholes is dependent on the nature of the site and proposed construction. Additional boreholes are drilled at problem areas and near the site of the proposed structure. Where practicable boreholes should be located along ‘grid lines’ at regular intervals to enable section drawing to be produced across indicated planes. Grid lines – An imaginary series of lines running north/south and east/west allows designers and engineers to plot exactly the key positions on the site. Section drawings: A profile of the ground using information from the boreholes next to one another. This allows the engineers to predict what happens to the ground between each borehole.

Site Investigation: Radon Gas
Radon is a naturally radioactive gas and is found in many areas within the UK. It has no taste, colour or smell, it can gather in concentrated levels below construction projects. Building regulations require that buildings and extensions constructed after 2000 in RADON affected areas have protective measurers installed during construction. To prevent the build up of radon gas, barriers are built into the structure. This barrier must cover the total area of the foundation footprint of the structure. Environmental health officers are appointed by LA’s to determine safe levels of radon gas in existing properties. The HSE has the task of monitoring how contractors deal with radon gas during construction work. Contractors have a duty of care under the HASWA 1974 to provide a safe place of work

Site Investigation: Groundwater Conditions
Ground water is found below the ground in the spaces and cracks between soil, sand and rock. The level of water in the ground is known as the water table.

Why is it important to know the water table level? Any design and operations will be affected by the presence of water. Digging into the ground can cause ground water to fill some trenches and excavations with water. Construction companies have to plan how to remove or deal with any water during construction; ground water conditions are significant because they can affect construction in a number of ways.

What is the impact on construction of a high water table? Extra costs – from dewatering techniques, increased trench support and ground stabilisation requirements all making construction more difficult, longer and increasing costs. The presence of chemicals in any water such as acids can lead to damage of foundations and other materials used below ground level. A high ground water table implies that pore water pressure in the soil is high (gaps between soils), which usually means that the soil is weaker. As well as influencing foundations, high pore water pressure will and can affect the stability of slopes (landslides?) and the pressure on retaining structures. Pore-water pressure is the pressure that water exerts on the ground as it moves through the fissures and cracks in the ground Retaining structures – walls or buildings that hold back or support the earth.

What is the significance of this information on the building contractor? Viability of site Cost of ground works Type of foundations Amount of labour required Skill of labour required Requirement of engineered foundations Any contamination – remediation? Pore-water pressure is the pressure that water exerts on the ground as it moves through the fissures and cracks in the ground Retaining structures – walls or buildings that hold back or support the earth.

Site Investigation Remember!
The cost of a typical site investigation is around 0.5 – 1% of the capital cost of a project. It is considered good practice to investigate adequately at this stage. Key term: Capital Cost The total cost of all the equipment and necessary expense to complete the works.

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