ENGINEERING GEOLOGY AND GEOMECHANICS - 2018/9
Module code: ENG1075
Engineering Geology & Geomechanics is explained in this module, not only as being significant in civil engineering works, but also as the root of sustainability. The lectures provide an explanation of the processes by which the rocks and soils are formed, how they behave as an engineering material and provide a valuable non-renewable resource for construction. The hazards geological features pose to construction will also be considered. Particular emphasis is placed on both sediments as well as sedimentary rocks. In this way the basic tools for characterising engineering soils will be outlined. Initial understanding of stresses in the soils. The module will also cover the flow of water in soils as well as practical sessions on borehole logging and five day residential field course in Devon which reinforces the learning from the lectures and borehole logging. This module is supplemented by two laboratory sessions covering sample description and seepage.
Civil and Environmental Engineering
SINGH RM Dr (Civl Env Eng)
Number of Credits: 15
ECTS Credits: 7.5
Framework: FHEQ Level 4
JACs code: H250
Module cap (Maximum number of students): N/A
Prerequisites / Co-requisites
Normal entry requirements for a degree course in Civil Engineering
Indicative content includes:
Recognition, nature and origin of common geomaterials
Basic recognition characteristics and classification of igneous, sedimentary and metamorphic rocks. Description common soil and rocks according to BS EN ISO 14688 & 14689 and BS5930:1999. Characterisation and classification of engineering soils. Natural construction materials and associated sustainability issues in terms of reserves and environmental impact of extraction from the ground.
Soil phase relationship and index properties:
Soil phase or block diagram, mass-volume & weight-volume relationship, particle size distribution curve, sieve analysis, hydrometer analysis, relative density, liquid limit, plastic limit, shrinkage limit.
Stress in soils and hydrostatic pressure:
Total stress, effective stress, pore water pressure, stress in the soils due to surface load.
Groundwater in its various forms (artesian and perched groundwater conditions) and its importance in construction.
Permeability and Seepage
Darcy’s law; coefficient of permeability and factors affecting it, the Laplace equation and various solutions (e.g. flow nets) , Dupuit approach; anisotropy, its causes and incorporation in solutions is considered. The quick condition, seepage through earth dams is reviewed.
A range of hazards to structures and construction associated with earthquakes, volcanoes, landslip, shrinkable soils, collapsing soils and subsidence are reviewed. Issues associated with some geotechnical hazards relating to climate change are discussed.
The recognition and description of geomaterials and geological structures together with the construction of a 3D ground model based on borehole log is covered in this activity. An introduction to health and safety issues related to fieldwork forms an integral part of this activity.
|Assessment type||Unit of assessment||Weighting|
|Examination||EXAMINATION (2 HOURS)||60|
|Practical based assessment||FIELDWORK||20|
|Practical based assessment||LABORATORY WORK||20|
Alternative instrument of assessment for fieldwork: coursework related to the fieldwork (including a presentation). [Learning outcomes assessed 2, 5, 6, b, d, e, f, g] Alternative instrument of assessment for Laboratory work, coursework related to seepage and coursework related to the description of selected soils and rocks.
The assessment strategy is designed to provide students with the opportunity to demonstrate
Explain the basic principles of geology, describe geological features and hazards, geosustainability and seepage theory (Learning outcomes 1, 2, 3, 4, 5,7). This is assessed through a 2 hour unseen examination.
Demonstrate practical skills in seepage and recognition and description of common geomaterials. This is assessed through laboratory work and subsequent reporting and interpretation of results (Learning outcomes 2, 4, a,b,c,f,g).
Demonstrate the necessary practical skills to recognise, describe and interpret geological features. This is assessed through fieldwork tasks together with oral and paper presentation of results (eg geological mapping) (Learning outcomes 2,5,6,b,d,e,f,g).
Interpret geological maps (Learning outcomes 5,b,c,e,g). This is assessed through fieldwork mapping task and unseen examination.
Thus, the summative assessment for this module consists of:
Examination [Learning outcomes assessed 1, 2, 3, 4, 5,7] (2 hours,60%)
Fieldwork comprising rock material and rock mass description, description of geological features through sketching and commentary and geological mapping through daily reports [Learning outcomes assessed 2, 5, 6, b, d, e, f, g] (27 hours,20%)
Seepage Laboratory report [Learning outcomes assessed 4, a, b, c] (15 hours,10%) and Soil and Rock description [Learning outcomes assessed 2,b,g] (15 hours, 10%).
Formative assessment and feedback
Formative assessment will be through a range of self assessment excersises provided on SurreyLearn. These excersises will provide automatic feedback where necessary. Feedback will also be given in tutorial sessions.
Students will receive written feedback on the laboratory work as well as verbal feedback. Both verbal and written feedback will be provided on the fieldwork.
- Provide an appreciation of the nature and range of geological features and hazards, and their occurrence
- Describe potential impact of geological and geotechnical hazards on civil engineering construction
- Describe the sources of the principal type of construction materials and to consider their sustainability
- Provide the ability to recognise and describe common geomaterials and characterise soils based on their physical properties
- Describe the understanding of total stress, effective stress and porewater pressure
- Provide the ability to assess desired density in the field
- Provide the ability to construct a simple geological model of the ground based on borehole log and field evidence
|001||Describe a range of ground related hazards and risks and explain their significance for civil engineering construction.||K|
|002||Recognise and describe a range of commonly occurring geomaterials and geological structures.||KCPT|
|003||Characterise engineering soils in terms of their physical properties||CPT|
|004||Determine compaction characteristics of soil||KPT|
|005||Understand the concept of stress in soils||KCPT|
|006||Evaluate one- and two-dimensional steady-state flow problems associated with soils||KCPT|
|007||Interpret borehole logs in terms of soil strata and soil properties||KCPT|
|008||Construct a basic geological model of a site through the application of borehole log, field observations and measurements||KCPT|
|009||Recognise the issues associated with the use of geomaterials in engineering construction in relation to sustainability||K|
|010||Technical report writing||T|
|011||Oral & written communication||T|
|012||Graphical presentation of data||T|
|014||3D spatial awareness||T|
C - Cognitive/analytical
K - Subject knowledge
T - Transferable skills
P - Professional/Practical skills
Overall student workload
Workshop Hours: 22
Independent Study Hours: 94
Lecture Hours: 15
Tutorial Hours: 15
Laboratory Hours: 4
Methods of Teaching / Learning
This module forms to foundation to all the modules in Geotechnical Engineering at FHEQ Levels 5, 6 and 7 on the BEng and MEng programmes in Civil Engineering. It provides a basic knowledge of geology, geomechanics, seepage theory and the characterisation of engineering soils. It also reinforces some of the knowledge gained from ENG1063 in terms of the sources of commonly used construction materials and issues of sustainability.
The module is delivered principally by lectures but also includes laboratory work in seepage and the recognition and description of geomaterials. In addition the module introduces the students to ground mapping using borehole log interpretation through practical sessions and fieldwork. The fieldwork element is also a key component in reinforcing the student’s knowledge of geological structures as well as the description of rock material and rock masses.
The tentative learning and teaching methods include:
Geology and Geomechanics Lectures/Tutorials (20 hours)
Soil seepage Lectures/Tutorials (10hours)
Soil & Rock identification and description laboratory class (2 hours)
Seepage laboratory class (2 hours)
Geology fieldwork (22 hours)
Directed and guided reading (including revision, assessments and preparation for lab classes and fieldwork) (78 hours)
Report writing (16 hours)
Indicated Lecture Hours (which may also include seminars, tutorials, workshops and other contact time) are approximate and may include in-class tests where one or more of these are an assessment on the module. In-class tests are scheduled/organised separately to taught content and will be published on to student personal timetables, where they apply to taken modules, as soon as they are finalised by central administration. This will usually be after the initial publication of the teaching timetable for the relevant semester.
Reading list for ENGINEERING GEOLOGY AND GEOMECHANICS : http://aspire.surrey.ac.uk/modules/eng1075
Please note that the information detailed within this record is accurate at the time of publishing and may be subject to change. This record contains information for the most up to date version of the programme / module for the 2018/9 academic year.