Urban Search and Rescue and Rapid Field Assessment of Damaged and Collapsed Building Structures
Urban Search and Rescue (USAR) is a functional
capability that has been developed to allow the United Kingdom Fire
and Rescue Service to deal with ‘major incidents’ primarily involving
structural collapse. The nature of the work undertaken by USAR
means that staying out of a damaged or collapsed building structure is
not usually an option for search and rescue personnel. As a result
there is always a risk that they themselves could become victims. For
this paper, a systematic and investigative review using desk research
was undertaken to explore the role which structural engineering can
play in assisting search and rescue personnel to conduct structural
assessments when in the field. The focus is on how search and rescue
personnel can assess damaged and collapsed building structures, not
just in terms of structural damage that may been countered, but also
in relation to structural stability. Natural disasters, accidental
emergencies, acts of terrorism and other extreme events can vary
significantly in nature and ferocity, and can cause a wide variety of
damage to building structures. It is not possible or, even realistic, to
provide search and rescue personnel with definitive guidelines and
procedures to assess damaged and collapsed building structures as
there are too many variables to consider. However, understanding
what implications damage may have upon the structural stability of a
building structure will enable search and rescue personnel to better judge
and quantify risk from a life-safety standpoint. It is intended that this
will allow search and rescue personnel to make informed decisions
and ensure every effort is made to mitigate risk, so that they
themselves do not become victims.
[1] Gallagher, R.P., Reasenberg, P.A. and Poland, C.D. (1996) Earthquake
Aftershocks: Entering Damaged Buildings, ATC TechBrief 2 (ATC-TB-
2), Redwood City, CA: Applied Technology Council (ATC).
[2] Davis, J. and Lambert, R. (2002) Engineering in Emergencies: A
Practical Guide for Relief Workers, 2nd Edition, Rugby: Practical
Action Publishing.
[3] Sphere Project (2011) Humanitarian Charter and Minimum Standards
in Humanitarian Response, 3rd Edition, Rugby: Practical Action
Publishing.
[4] UNHCR (2007) Handbook for Emergencies, 3rd Edition, Geneva:
United Nations High Commissioner for Refugee (UNCHR).
[5] USAID (2005) Field Operations Guide: For Disaster Assessment and
Response, Version 4.0, Washington, DC: U.S. Agency for International
Development (USAID).
[6] Merchant, D.F. and Ashford-Smith, D. (2008) USAR Operations:
Proguide Series - Urban Search and Rescue Operations, London:
UVSAR.
[7] FEMA (2003) National Urban Search & Rescue (US&R) Response
System: Field Operations Guide, US&R-2-FG, US&R Resources
(Online) Available at: http://www.fema.gov/emergency/usr/
resources.shtm (Accessed: 16 November 2011).
[8] FEMA (2006) National Urban Search & Rescue (US&R) Response
System: Rescue Field Operations Guide, US&R-23-FG, US&R Resources (Online) Available at: http://www.fema.gov/emergency/usr/
resources.shtm (Accessed: 16 November 2011).
[9] USACE (2009) Urban Search & Rescue Structures Specialist Field
Operations Guide, 6th Edition, U.S. Army Corps of Engineers (USACE)
Urban Search and Rescue Program (Online) Available at:
http://www.disasterengineer.org/Library/tabid/57/Default.aspx
(Accessed: 15 February 2012).
[10] FEMA (2010) National US&R Response System: Structural Collapse
Technician Training Manual, Structural Collapse Technician Course:
Student Manual - Module 1c Structural Engineering Systems (Online)
Available at: http://www.fema.gov/emergency/usr/sctc.shtm (Accessed:
16 November 2011).
[11] FEMA (1994) Reducing the Risks of Non-Structural Earthquake
Damage: A Practical Guide, 3rd Edition, FEMA 74, FEMA Library
(Online) Available at: http://www.fema.gov/library/viewRecord.do?id=
3843 (Accessed: 9 November 2011).
[12] Hampshire Fire and Rescue Service (2012) Urban Search and Rescue.
Available at: http://www.hantsfire.gov.uk/theservice/specialistresponse/
specialistrescues/usar.htm (Accessed: 15 February 2012).
[13] Lancashire Fire and Rescue Service (2007) UK Urban Search and
Rescue. Available at: http://www.usar.org.uk/ (Accessed: 15 February
2012).
[14] IStructE (1995) Structural Engineer's Response to Explosion Damage,
London: Institution of Structural Engineers (IStructE).
[15] FEMA (1998) Evaluation of Earthquake Damaged Concrete and
Masonry Wall Buildings: Basic Procedures Manual, FEMA 306, FEMA
Library (Online) Available at: http://www.fema.gov/library/
viewRecord.do?id=1651 (Accessed: 9 November 2011).
[16] FEMA (1994) Reducing the Risks of Non-Structural Earthquake
Damage: A Practical Guide, 3rd Edition, FEMA 74, FEMA Library
(Online) Available at: http://www.fema.gov/library/viewRecord.do?id=
3843 (Accessed: 9 November 2011).
[17] Concrete Society (2000) Diagnosis of Deterioration in Concrete
Structures: Identification of Defects, Evaluation and Development of
Remedial Action, Technical Report 54, Camberley: Concrete Society.
[18] Concrete Society (2008) Assessment, Design and Repair of Fire-
Damaged Concrete Structures, Technical Report 68, Camberley:
Concrete Society.
[19] Hoxley, M. (2009) Building Condition Surveys, Good Practice Guide,
London: RIBA Publishing.
[20] Houghton-Evan R.W. (2005) Well Built? A Forensic Approach to the
Prevention, Diagnosis and Cure of Building Defects, London: RIBA
Publishing.
[21] IStructE (2008) Guide to Surveys and Inspections of Buildings and
Associated Structures, London: Institution of Structural Engineers
(IStructE).
[22] IStructE (2010a) Appraisal of Existing Structures, 3rd Edition, London:
Institution of Structural Engineers (IStructE).
[23] Mays, G. (Eds.) (1992) Durability of Concrete Structures: Investigation,
Repair, Protection, London: E & FN Spon.
[24] Kay, T. (1992) Assessment and Renovation of Concrete Structures,
Harlow: Longman Scientific & Technical.
[25] De Pauw, C. and Lauritzen E.K. (Eds.) (1994) Disaster Planning,
Structural Assessment, Demolition and Recycling, RILEM Report 9,
London: E. & F.N. Spon.
[26] Chen, W. and Scawthorn, C. (2003) Earthquake Engineering Handbook,
London: CRC Press.
[27] ATC (1989) Procedures for Post-Earthquake Safety Evaluation of
Building, ATC-20 Report, Redwood City, CA: Applied Technology
Council (ATC).
[28] ATC (1995) Addendum to the ATC-20 Post-Earthquake Building Safety
Evaluation Procedures, ATC-20-2 Report, Redwood City, CA: Applied
Technology Council (ATC).
[29] ATC (1996) Case Studies in Rapid Post-Earthquake Safety Evaluation
of Buildings, ATC-20-3 Report, Redwood City, CA: Applied
Technology Council (ATC).
[30] ATC (2005) Field Manual: Procedures for Post-Earthquake Safety
Evaluation of Building, ATC-20-1 Report, 2nd Edition, Redwood City,
CA: Applied Technology Council (ATC).
[31] IStructE (1981) Structural Failures in Buildings, London: Institution of
Structural Engineers (IStructE).
[32] EEFIT (2006) The Indian Ocean Tsunami of 26 December 2004:
Mission Findings in Sri Lanka and Thailand, Earthquake Engineering
Field Investigation Team (EEFIT) Reports (Online) Available at:
http://www.istructe.org/knowledge/EEFIT/Documents/Indian_Ocean_Ts
unami.pdf (Accessed: 9 November 2011).
[33] EEFIT (2008) The Wenchuan, China Earthquake of 12 May 2008: A
Preliminary Field Report by EEFIT, Earthquake Engineering Field
Investigation Team (EEFIT) Reports (Online) Available at:
http://www.istructe.org/knowledge/EEFIT/Documents/Wenchuan_Preli
minary_Report.pdf (Accessed: 9 November 2011).
[34] EEFIT (2010a) The Haiti Earthquake of 12 January 2010: A Field
Report by EEFIT, Earthquake Engineering Field Investigation Team
(EEFIT) Reports (Online) Available at: http://www.istructe.org/
knowledge/EEFIT/Documents/field-report-12-jan-2010.pdf (Accessed: 9
November 2011).
[35] EEFIT (2010b) The MW8.8 Maule Chile Earthquake of 27th February
2010: A Preliminary Field Report by EEFIT, Earthquake Engineering
Field Investigation Team (EEFIT) Reports (Online) Available at:
http://www.istructe.org/knowledge/EEFIT/Documents/eefit-chilereport.
pdf (Accessed: 9 November 2011).
[36] EEFIT (2011) The MW9.0 Tohoku Earthquake and Tsunami of 11th
March 2011: A Field Report by EEFIT, Earthquake Engineering Field
Investigation Team (EEFIT) Reports (Online) Available at:
http://www.istructe.org/knowledge/EEFIT/Documents/field-reporttohoku-
japan-11-march-2011.pdf (Accessed: 13 December 2011).
[37] Clifton, C., Bruneau, M., Fussell, A., Leon and MacRae, G. (2011) Steel
Building Damage from the Christchurch Earthquake Series of 2010 and
2011: Technical Report, Canterbury Earthquakes Royal Commission
Document Library (Online) Available at:
http://canterbury.royalcommission.govt.nz/documents-bykey/
20111104.759 (Accessed: 6 March 2012).
[38] Kam, W.Y. (2011) Preliminary Report from the Christchurch 22 Feb.
2011 6.3MW Earthquake: Pre-1970s RC and RCM Buildings, and
Precast Staircase Damage, NZSEE Structural Database, (Online)
Available at: http://db.nzsee.org.nz:8080/documents/43301/b274721ed91a-
424c-b8bb-fd51a99d0954 (Accessed: 6 March 2012).
[39] Kam, W.Y. and Pampanin, S. (2011) ‘The Seismic Performance of RC
Buildings in the 22 February 2011 Christchurch Earthquake,’ Structural
Concrete, Volume 12 (Issue 4): Pages 223-233.
[40] NZSEE and RSNZ (2011) The Canterbury Earthquakes: Scientific
Answers to Critical Questions, New Zealand Society for Earthquake
Engineering (NZSEE) and Royal Society of New Zealand (RSNZ)
(Online) Available at: http://www.nzsee.org.nz/ (Accessed: 6 March
2012).
[41] EEFIT (2009) The L’Aquila, Italy Earthquake of 6 April 2009:A
Preliminary Field Report by EEFIT, Earthquake Engineering Field
Investigation Team (EEFIT) Reports (Online) Available at:
http://www.istructe.org/webtest/files/b8/b8df351b-a28b-4375-9d5a-
20afd9be569b.pdf(Accessed: 10 December 2014).
[1] Gallagher, R.P., Reasenberg, P.A. and Poland, C.D. (1996) Earthquake
Aftershocks: Entering Damaged Buildings, ATC TechBrief 2 (ATC-TB-
2), Redwood City, CA: Applied Technology Council (ATC).
[2] Davis, J. and Lambert, R. (2002) Engineering in Emergencies: A
Practical Guide for Relief Workers, 2nd Edition, Rugby: Practical
Action Publishing.
[3] Sphere Project (2011) Humanitarian Charter and Minimum Standards
in Humanitarian Response, 3rd Edition, Rugby: Practical Action
Publishing.
[4] UNHCR (2007) Handbook for Emergencies, 3rd Edition, Geneva:
United Nations High Commissioner for Refugee (UNCHR).
[5] USAID (2005) Field Operations Guide: For Disaster Assessment and
Response, Version 4.0, Washington, DC: U.S. Agency for International
Development (USAID).
[6] Merchant, D.F. and Ashford-Smith, D. (2008) USAR Operations:
Proguide Series - Urban Search and Rescue Operations, London:
UVSAR.
[7] FEMA (2003) National Urban Search & Rescue (US&R) Response
System: Field Operations Guide, US&R-2-FG, US&R Resources
(Online) Available at: http://www.fema.gov/emergency/usr/
resources.shtm (Accessed: 16 November 2011).
[8] FEMA (2006) National Urban Search & Rescue (US&R) Response
System: Rescue Field Operations Guide, US&R-23-FG, US&R Resources (Online) Available at: http://www.fema.gov/emergency/usr/
resources.shtm (Accessed: 16 November 2011).
[9] USACE (2009) Urban Search & Rescue Structures Specialist Field
Operations Guide, 6th Edition, U.S. Army Corps of Engineers (USACE)
Urban Search and Rescue Program (Online) Available at:
http://www.disasterengineer.org/Library/tabid/57/Default.aspx
(Accessed: 15 February 2012).
[10] FEMA (2010) National US&R Response System: Structural Collapse
Technician Training Manual, Structural Collapse Technician Course:
Student Manual - Module 1c Structural Engineering Systems (Online)
Available at: http://www.fema.gov/emergency/usr/sctc.shtm (Accessed:
16 November 2011).
[11] FEMA (1994) Reducing the Risks of Non-Structural Earthquake
Damage: A Practical Guide, 3rd Edition, FEMA 74, FEMA Library
(Online) Available at: http://www.fema.gov/library/viewRecord.do?id=
3843 (Accessed: 9 November 2011).
[12] Hampshire Fire and Rescue Service (2012) Urban Search and Rescue.
Available at: http://www.hantsfire.gov.uk/theservice/specialistresponse/
specialistrescues/usar.htm (Accessed: 15 February 2012).
[13] Lancashire Fire and Rescue Service (2007) UK Urban Search and
Rescue. Available at: http://www.usar.org.uk/ (Accessed: 15 February
2012).
[14] IStructE (1995) Structural Engineer's Response to Explosion Damage,
London: Institution of Structural Engineers (IStructE).
[15] FEMA (1998) Evaluation of Earthquake Damaged Concrete and
Masonry Wall Buildings: Basic Procedures Manual, FEMA 306, FEMA
Library (Online) Available at: http://www.fema.gov/library/
viewRecord.do?id=1651 (Accessed: 9 November 2011).
[16] FEMA (1994) Reducing the Risks of Non-Structural Earthquake
Damage: A Practical Guide, 3rd Edition, FEMA 74, FEMA Library
(Online) Available at: http://www.fema.gov/library/viewRecord.do?id=
3843 (Accessed: 9 November 2011).
[17] Concrete Society (2000) Diagnosis of Deterioration in Concrete
Structures: Identification of Defects, Evaluation and Development of
Remedial Action, Technical Report 54, Camberley: Concrete Society.
[18] Concrete Society (2008) Assessment, Design and Repair of Fire-
Damaged Concrete Structures, Technical Report 68, Camberley:
Concrete Society.
[19] Hoxley, M. (2009) Building Condition Surveys, Good Practice Guide,
London: RIBA Publishing.
[20] Houghton-Evan R.W. (2005) Well Built? A Forensic Approach to the
Prevention, Diagnosis and Cure of Building Defects, London: RIBA
Publishing.
[21] IStructE (2008) Guide to Surveys and Inspections of Buildings and
Associated Structures, London: Institution of Structural Engineers
(IStructE).
[22] IStructE (2010a) Appraisal of Existing Structures, 3rd Edition, London:
Institution of Structural Engineers (IStructE).
[23] Mays, G. (Eds.) (1992) Durability of Concrete Structures: Investigation,
Repair, Protection, London: E & FN Spon.
[24] Kay, T. (1992) Assessment and Renovation of Concrete Structures,
Harlow: Longman Scientific & Technical.
[25] De Pauw, C. and Lauritzen E.K. (Eds.) (1994) Disaster Planning,
Structural Assessment, Demolition and Recycling, RILEM Report 9,
London: E. & F.N. Spon.
[26] Chen, W. and Scawthorn, C. (2003) Earthquake Engineering Handbook,
London: CRC Press.
[27] ATC (1989) Procedures for Post-Earthquake Safety Evaluation of
Building, ATC-20 Report, Redwood City, CA: Applied Technology
Council (ATC).
[28] ATC (1995) Addendum to the ATC-20 Post-Earthquake Building Safety
Evaluation Procedures, ATC-20-2 Report, Redwood City, CA: Applied
Technology Council (ATC).
[29] ATC (1996) Case Studies in Rapid Post-Earthquake Safety Evaluation
of Buildings, ATC-20-3 Report, Redwood City, CA: Applied
Technology Council (ATC).
[30] ATC (2005) Field Manual: Procedures for Post-Earthquake Safety
Evaluation of Building, ATC-20-1 Report, 2nd Edition, Redwood City,
CA: Applied Technology Council (ATC).
[31] IStructE (1981) Structural Failures in Buildings, London: Institution of
Structural Engineers (IStructE).
[32] EEFIT (2006) The Indian Ocean Tsunami of 26 December 2004:
Mission Findings in Sri Lanka and Thailand, Earthquake Engineering
Field Investigation Team (EEFIT) Reports (Online) Available at:
http://www.istructe.org/knowledge/EEFIT/Documents/Indian_Ocean_Ts
unami.pdf (Accessed: 9 November 2011).
[33] EEFIT (2008) The Wenchuan, China Earthquake of 12 May 2008: A
Preliminary Field Report by EEFIT, Earthquake Engineering Field
Investigation Team (EEFIT) Reports (Online) Available at:
http://www.istructe.org/knowledge/EEFIT/Documents/Wenchuan_Preli
minary_Report.pdf (Accessed: 9 November 2011).
[34] EEFIT (2010a) The Haiti Earthquake of 12 January 2010: A Field
Report by EEFIT, Earthquake Engineering Field Investigation Team
(EEFIT) Reports (Online) Available at: http://www.istructe.org/
knowledge/EEFIT/Documents/field-report-12-jan-2010.pdf (Accessed: 9
November 2011).
[35] EEFIT (2010b) The MW8.8 Maule Chile Earthquake of 27th February
2010: A Preliminary Field Report by EEFIT, Earthquake Engineering
Field Investigation Team (EEFIT) Reports (Online) Available at:
http://www.istructe.org/knowledge/EEFIT/Documents/eefit-chilereport.
pdf (Accessed: 9 November 2011).
[36] EEFIT (2011) The MW9.0 Tohoku Earthquake and Tsunami of 11th
March 2011: A Field Report by EEFIT, Earthquake Engineering Field
Investigation Team (EEFIT) Reports (Online) Available at:
http://www.istructe.org/knowledge/EEFIT/Documents/field-reporttohoku-
japan-11-march-2011.pdf (Accessed: 13 December 2011).
[37] Clifton, C., Bruneau, M., Fussell, A., Leon and MacRae, G. (2011) Steel
Building Damage from the Christchurch Earthquake Series of 2010 and
2011: Technical Report, Canterbury Earthquakes Royal Commission
Document Library (Online) Available at:
http://canterbury.royalcommission.govt.nz/documents-bykey/
20111104.759 (Accessed: 6 March 2012).
[38] Kam, W.Y. (2011) Preliminary Report from the Christchurch 22 Feb.
2011 6.3MW Earthquake: Pre-1970s RC and RCM Buildings, and
Precast Staircase Damage, NZSEE Structural Database, (Online)
Available at: http://db.nzsee.org.nz:8080/documents/43301/b274721ed91a-
424c-b8bb-fd51a99d0954 (Accessed: 6 March 2012).
[39] Kam, W.Y. and Pampanin, S. (2011) ‘The Seismic Performance of RC
Buildings in the 22 February 2011 Christchurch Earthquake,’ Structural
Concrete, Volume 12 (Issue 4): Pages 223-233.
[40] NZSEE and RSNZ (2011) The Canterbury Earthquakes: Scientific
Answers to Critical Questions, New Zealand Society for Earthquake
Engineering (NZSEE) and Royal Society of New Zealand (RSNZ)
(Online) Available at: http://www.nzsee.org.nz/ (Accessed: 6 March
2012).
[41] EEFIT (2009) The L’Aquila, Italy Earthquake of 6 April 2009:A
Preliminary Field Report by EEFIT, Earthquake Engineering Field
Investigation Team (EEFIT) Reports (Online) Available at:
http://www.istructe.org/webtest/files/b8/b8df351b-a28b-4375-9d5a-
20afd9be569b.pdf(Accessed: 10 December 2014).
@article{"International Journal of Architectural, Civil and Construction Sciences:69510", author = "Abid I. Abu-Tair and Gavin M. Wilde and John M. Kinuthia", title = "Urban Search and Rescue and Rapid Field Assessment of Damaged and Collapsed Building Structures", abstract = "Urban Search and Rescue (USAR) is a functional
capability that has been developed to allow the United Kingdom Fire
and Rescue Service to deal with ‘major incidents’ primarily involving
structural collapse. The nature of the work undertaken by USAR
means that staying out of a damaged or collapsed building structure is
not usually an option for search and rescue personnel. As a result
there is always a risk that they themselves could become victims. For
this paper, a systematic and investigative review using desk research
was undertaken to explore the role which structural engineering can
play in assisting search and rescue personnel to conduct structural
assessments when in the field. The focus is on how search and rescue
personnel can assess damaged and collapsed building structures, not
just in terms of structural damage that may been countered, but also
in relation to structural stability. Natural disasters, accidental
emergencies, acts of terrorism and other extreme events can vary
significantly in nature and ferocity, and can cause a wide variety of
damage to building structures. It is not possible or, even realistic, to
provide search and rescue personnel with definitive guidelines and
procedures to assess damaged and collapsed building structures as
there are too many variables to consider. However, understanding
what implications damage may have upon the structural stability of a
building structure will enable search and rescue personnel to better judge
and quantify risk from a life-safety standpoint. It is intended that this
will allow search and rescue personnel to make informed decisions
and ensure every effort is made to mitigate risk, so that they
themselves do not become victims.
", keywords = "Damaged and collapsed building structures, life
safety, quantifying risk, search and rescue personnel, structural
assessments in the field.", volume = "9", number = "4", pages = "419-11", }
