Compliance Document For NZ Building Code, Clause B1
Compliance Document For NZ Building Code, Clause B1
Compliance Document For NZ Building Code, Clause B1
This Compliance Document is prepared by the Department of Building and Housing. The Department of Building and Housing is a Government Department established under the State Sector Act 1988. Enquiries about the content of this document should be directed to:
Department of Building and Housing PO Box 10-729, Wellington. Telephone 0800 242 243 Fax 04 494 0290 Email: info@dbh.govt.nz Compliance Documents are available from www.dbh.govt.nz
Department of Building and Housing 2011 This Compliance Document is protected by Crown copyright, unless indicated otherwise. The Department of Building and Housing administers the copyright in this document. You may use and reproduce this document for your personal use or for the purposes of your business provided you reproduce the document accurately and not in an inappropriate or misleading context. You may not distribute this document to others or reproduce it for sale or profit. The Department of Building and Housing owns or has licences to use all images and trademarks in this document. You must not use or reproduce images and trademarks featured in this document for any purpose (except as part of an accurate reproduction of this document) unless you first obtain the written permission of the Department of Building and Housing.
Status of Compliance Documents Compliance Documents are prepared by the Department of Building and Housing in accordance with section 22 of the Building Act 2004. A Compliance Document is for use in establishing compliance with the New Zealand Building Code. A person who complies with a Compliance Document will be treated as having complied with the provisions of the Building Code to which the Compliance Document relates. However, a Compliance Document is only one method of complying with the Building Code. There may be alternative ways to comply. Users should make themselves familiar with the preface to the New Zealand Building Code Handbook, which describes the status of Compliance Documents and explains alternative methods of achieving compliance. Defined words (italicised in the text) and classified uses are explained in Clauses A1 and A2 of the Building Code and in the Definitions at the start of this Compliance Document.
Amendment 2
19 August 1994
October 1994 1 December 1995 p. ii, Document History p. ix, References p. 1, 3.1 p. 5, 6.2 p. 50, Index
July 1996 1 December 2000 p. ii, Document History pp. vii and viii, Contents pp. ix xii, Revised References pp. xiii and xiv, Definitions p. 46, 4.3.2 a) i) p. 2, Document Status p. 3, Document History p. 7, References p. 41, 1.7.2 Comment p. 49, 2.2.4 p. 48, 1.9.1 b) i) pp. 14A, Revised B1/VM1 pp. 5 and 6, Revised B1/AS1 pp. 3363, Revised B1/VM4 p. 65, Revised B1/AS4 pp. 6772, Revised Index
Amendment 9
30 September 2010
30 September 2010 30 September 2010 Effective from 19 May 2011 until 31 January 2012 p. 21, B1/VM1 3.1 p. 9, Contents p. 1214, References p. 15, Definitions p. 17, B1/VM1 p. 9, Contents p. 1114, References p. 1722B, B1/VM1 1.0, 2.0, 2.2.9, 2.2.14 C, 5.2, 6.1, 7.1, 8.1, 12.1, 13.0 p. 20, B1/VM1 2.2.14 A to 2.2.14 D pp. 2323C B1/AS1 1.4, 2.0, 3.0, 4.0 p. 48, B1/AS3 1.9.3 p. 84, Index pp. 2324, B1/AS1 1.2, 2.0, 3.0, 4.0, 7.0, 8.0, 9.0 pp. 2734, B1/AS2 pp. 8387, Index
Amendment 11
Note: Page numbers relate to the document at the time of Amendment and may not match page numbers in current document.
Document Status Recent versions of this document, as detailed in the Document History, are approved by the Chief Executive of the Department of Building and Housing. B1 Structure Compliance Document Amendment 11 is the most recent document and is effective from 1 August 2011. B1 Structure Compliance Document Amendment 10 may also be used until 31 January 2012. B1 Structure Compliance Document Amendment 11 supersedes all previous versions from 1 February 2012. People using this Compliance Document should check for amendments on a regular basis. The Department of Building and Housing may amend any part of any Compliance Document at any time. Up-to-date versions of Compliance Documents are available from www.dbh.govt.nz
C l a u s e B1
D E PA R T M E N T O F B U I L D I N G A N D H O U S I N G
July 1992
C lause B 1
July 1992
D E PA R T M E N T O F B U I L D I N G A N D H O U S I N G
C l a u s e B1
D E PA R T M E N T O F B U I L D I N G A N D H O U S I N G
July 1992
Contents
Page References Definitions Verification Method B1/VM1
Amend 4 Dec 2000 Amend 8 Dec 2008
11 15 17 17 17 17
3.0 3.1
23A 23A
4.0 4.1
23C 23C
3.0
Amend 3 Dec 1995
21 21 22 22 22 22 22 22 22 22 22 22A 22A 22A 22A 22A 22A 22A 22B 22B Verification Method B1/VM2 Timber Barriers Acceptable Solution B1/AS2 Timber Barriers 25 27 5.0 5.1 6.0 6.1 6.2 6.3 6.4 7.0 7.1 8.0 9.0 Stucco NZS 4251 Drains AS/NZS 2566.1 AS/NZS 2566.2 AS/NZS 2032 AS/NZS 2033 Glazing NZS 4223 Small Chimneys Timber Barriers 23C 23C 23D 23D 23D 23D 23D 24 24 24 24
Amend 11 Aug 2011 Amend 4 Dec 2000 Amend 10 May 2011 Amend 11 Aug 2011
5.2 5.3 6.0 6.1 7.0 7.1 8.0 8.1 9.0 10.0 10.1
13.1
23 23 23 23
Verification Method B1/VM3 Small Chimneys Acceptable Solution B1/AS3 Small Chimneys
35 37
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Scope 1.0 1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 1.9 2.0 2.1 2.2 Chimney Construction General Chimney wall thickness Foundations Hearths Chimney breasts Reinforcing Chimney restraint Materials and construction Systems to resist horizontal earthquake loadings Solid Fuel Burning Domestic Appliances Chimneys Hearth slab
37 37 37 37 37 41 41 41 41 47 47 49 49 49 51 51 51 52 52 52
66 66 67 67 69 69 70 70 71 71 72 72 72 73 75 76
Appendix A (Informative) A1.0 Site Investigations Appendix B (Informative) B1.0 Serviceability Limit State Deformations (Settlement)
Appendix C (Informative) C1.0 C2.0 C3.0 C4.0 C5.0 C6.0 C7.0 Description of Wall, Limit States and Soil Properties Earth Pressure Coefficients Load Factors and Strength Reduction Factors Notation Loadings Surcharge Pressures at Toe First Ultimate Limit State (short term static foundation bearing failure) Second Ultimate Limit State (short term static foundation sliding failure) Third Ultimate Limit State (short term foundation bearing failure under EQ)
Verification Method B1/VM4 Foundations 1.0 2.0 3.0 3.1 3.2 Scope and limitations General Shallow Foundations General provisions Ultimate and design bearing strength and design bearing pressure Ultimate limit state bearing strength for shallow foundations Ultimate limit state sliding resistance Strength reduction factors Pile Foundations Ultimate vertical strength of single piles Column action Ultimate lateral strength of single piles Pile groups Downdrag Ultimate lateral strength of pile groups Strength reduction factors
C8.0
77
C9.0 52 58 59 59 60 61 63 66 66 66 66
77
3.3 3.4 3.5 4.0 4.1 4.2 4.3 4.4 4.5 4.6
Amend 4 Dec 2000
C10.0 Fourth Ultimate Limit State (short term foundation sliding failure under EQ) C11.0 Fifth Ultimate Limit State (long term foundation bearing failure) C12.0 Sixth Ultimate Limit State (long term foundation sliding failure) C13.0 Comments Acceptable Solution B1/AS4 Foundations (Revised by Amendment 4) Index (Revised by Amendment 4)
78
78
79
80 81
83
4.7
10
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References
For the purposes of New Zealand Building Code compliance, the acceptable New Zealand and other Standards, and other documents referred to in this Compliance Document (primary reference documents) shall be the editions, along with their specific amendments, listed below. Where the primary reference documents refer to other Standards or other documents (secondary reference documents), which in turn may also refer to other Standards or other documents, and so on (lower order reference documents), then the applicable version of these secondary and lower order reference documents shall be the version in effect at the date this Compliance Document was published. Where quoted Standards New Zealand AS/NZS 1170: Structural design actions VM1 1.0, 2.1, 2.2, 5.2, 6.1, 7.1, 8.1 AS1 7.2, 7.3 VM4 2.0, B1.0
Part 0: 2002 Part 1: 2002 Part 2: 2002 Part 3: 2003 NZS 1170: Part 5: 2004
COMMENT
Amend 11 Aug 2011 Amend 8 Dec 2008
General principles Amends: 1, 2, 4 Permanent imposed and other actions Amend: 1 Wind actions Amend: 1 Snow and ice actions Amend: 1 Structural design actions Earthquake actions New Zealand
Amends 10 and 11
The above suite of Structural Design Action Standards, together with their amendments, are referred to collectively as AS/NZS 1170.
VM1 7.1
AS/NZS 1748: 1997 Timber Stress graded Product requirements for mechanically stress-graded timber AS/NZS 2032: 2006 Installation of PVC pipe systems Amend: 1 AS/NZS 2033: 2008 Installation of polyethylene pipe systems Amends 1, 2 AS/NZS 2566: 2002 Buried Flexible pipelines. Part 1: 1998 Structural Design Part 2: 2002 Installation
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Where quoted AS/NZS 2918: 2001 Domestic solid fuel heating appliances installation NZS 3101:Part 1: 2006 Concrete structures standard The design of concrete structures Amend: 1, 2 AS3 3.2.1, 2.2.4 VM1 3.1, 11.1
Design of concrete structures for the storage of liquids. Concrete construction Amend: 1, 2 Methods of test for concrete Tests relating to the determination of strength of concrete Amend: 1, 2 Steel structures standard Steel structures standard Amend: 1, 2
VM1 3.2
VM1 5.1
Timber structures standard Amend: 1, 2 (Applies to building work consented prior to 1 April 2007) Amend: 1, 2, 4 (Applies to building work consented on or after 1 April 2007) Timber framed buildings
AS1 1.4, 3.1, 4.1 AS3 1.1.1, 1.9.1 b), 1.9.2, 1.9.5, 2.2.1 b) VM4 5.3.1 VM1 6.1
Amend 9 Sep 2010 Amend 7 Apr 2007 Amend 11 Aug 2011 Amend 9 Sep 2010
Timber piles and poles for use in building Verification of timber properties Amend: 1 Chemical preservation of round and sawn timber Amend: 1, 2
VM4 5.3.1,
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Where quoted AS/NZS 3725: 2007 Design for installation of buried concrete pipes VM1 11.1
AS/NZS 3869: 1999 Domestic solid fuel burning appliances Design and construction
Amend 9 Sep 2010
AS/NZS 4058: 2007 Pre cast concrete pipes(pressure and non-pressure) NZS 4210: 2001 Code of practice for masonry construction: materials and workmanship Amend: 1 Specification for performance of windows
VM1 12.1
Seismic Performance of Engineering Systems in Buildings Glazing in buildings Glass selection and glazing The selection and installation of manufactured sealed insulating glass units Amend: 1, 2 Human impact safety requirements Wind, dead, snow, and live actions Concrete masonry buildings not requiring specific engineering design Amend: 1
VM1 1.3.1
AS1 7.3 AS1 7.4 AS1 1.4, 2.1 AS3 1.1.1, 1.8.4, 1.9.2, 1.9.5, 2.2.1 b)
NZS 4230: 2004 NZS 4251:Part 1: 2007 NZS 4297: 1998 NZS 4299: 1998 NZS 4402:Part 2: Test 2.2: 1986 Test 2.6: 1986
Design of reinforced concrete masonry structures Amend: 1 Solid plastering Cement plasters for walls, ceilings and soffits Engineering design of earth buildings Earth buildings not requiring specific design Amend: 1 Methods of testing soils for civil engineering purposes. Parts 2, 4 and 5:1986 and 1988 Soil classification tests Determination of liquid limit Determination of the linear shrinkage
VM1 4.0 AS1 5.1 VM1 8.1 AS1 1.4, 4.1 VM1 11.1
Amends 10 and 11
Definitions Definitions
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Where quoted Part 4: Soil compaction tests Test 4.2.3: 1988 Relative densities NZS 4431: 1989 Code of practice for earth fill for residential development Amend: 1 VM4 4.1.1 VM1 10.1
AS/NZS 4671: 2001 Steel Reinforcing Materials Amend: 1 AS/NZS 4680: 2006 Hot-Dip Galvanised (zinc) Coating
SNZ HB 8630: 2004 Tracks and outdoor visitor structures The National Association of Steel Framed Housing Inc (NASH) NASH Standard: Residential and Low Rise Steel Framing Part 1 2010 Design Criteria British Standards Institution BS 8004: 1986 AS 1397: 2001 Code of practice for foundations Steel sheet and strip Hot-dipped zinc-coated or aluminium/zinc-coated
Standards Australia
Amend 9 Sep 2010
AS 2159: 1995
Rules for the design and installation of piling (known as the SAA Piling Code) Amend: 1
VM4 4.0.3
American Society of Testing and Materials ASTM D1143: 1981Test method for piles under static axial compressive load New Zealand Geomechanics Society Guidelines for the field descriptions of soils and rocks in engineering use. Nov 1988 New Zealand Legislation
Amend 8 Dec 2008
VM4 4.0.3
VM1 11.1
VM1 1.0
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Definitions
This is an abbreviated list of definitions for words or terms particularly relevant to this Compliance Document. The definitions for any other italicised words may be found in the New Zealand Building Code Handbook. Adequate Adequate to achieve the objectives of the Building Code. Alter in relation to a building, includes to rebuild, re-erect, repair, enlarge and extend the building. Baluster A post providing the support for the top and bottom rails of a barrier. Boundary joist A joist running along the outer ends of the floor joists.
Amend 7 Apr 2007 Amend 7 Apr 2007
Factor of safety in relation to any building means the ratio of resisting forces to applied forces for a given loading condition. It is generally expressed to two significant figures. Fireplace A space formed by the chimney back, the chimney jambs, and the chimney breast in which fuel is burned for the purpose of heating the room into which it opens. Fixture An article intended to remain permanently attached to and form part of a building. Flue The passage through which the products of combustion are conveyed to the outside. Gather That part of a chimney where the transition from fireplace to stack occurs. Good ground means any soil or rock capable of permanently withstanding an ultimate bearing pressure of 300 kPa (i.e. an allowable bearing pressure of 100 kPa using a factor of safety of 3.0), but excludes: a) Potentially compressible ground such as topsoil, soft soils such as clay which can be moulded easily in the fingers, and uncompacted loose gravel which contains obvious voids, b) Expansive soils being those that have a liquid limit of more than 50% when tested in accordance with NZS 4402 Test 2.2, and a linear shrinkage of more than 15% when tested, from the liquid limit, in accordance with NZS 4402 Test 2.6, and c) Any ground which could forseeably experience movement of 25 mm or greater for any reason including one or a combination of: land instability, ground creep, subsidence, (liquefaction, lateral spread for the Canterbury earthquake region only), seasonal swelling and shrinking, frost heave, changing ground water level, erosion, dissolution of soil in water, and effects of tree roots.
Amend 4 Dec 2000
Building has the meaning ascribed to it by sections 8 and 9 of the Building Act 2004. Building element Any structural and non-structural component or assembly incorporated into or associated with a building. Included are fixtures, services, drains, permanent mechanical installations for access, glazing, partitions, ceilings and temporary supports. Canterbury earthquake region is the area contained within the boundaries of the Christchurch City Council, the Selwyn District Council and the Waimakariri District Council. Chimney A non-combustible structure which encloses one or more flues, fireplaces or other heating appliances. Chimney back The non-combustible wall forming the back of a fireplace. Chimney base That part of a chimney which houses the fireplace. Chimney jambs The side walls of a fireplace. Combustible See non-combustible. Construct in relation to a building, includes to design, build, erect, prefabricate, and relocate the building. Drain A pipe normally laid below ground level including fittings and equipment and intended to convey foul water or surface water to an outfall.
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COMMENT: Soils (excepting those described in a), b) and c) above) tested with a dynamic cone penetrometer in accordance with NZS 4402 Test 6.5.2, shall be acceptable as good ground for building foundations if penetration resistance is no less than: a) 3 blows per 75 mm at depths no greater than the footing width. b) 2 blows per 75 mm at depths greater than the footing width.
Amend 4 Dec 2000
Specified intended life has the meaning given to it by section 113(3) of the Building Act 2004. Section 113(3) states: (3) In subsection (2), specified intended life, in relation to a building, means the period of time, as stated in an application for a building consent or in the consent itself, for which the building is proposed to be used for its intended use. Strength reduction factor The factor by which the ultimate strength is multiplied to obtain the design strength.
COMMENT: NZS 4203: 1992 uses the terms ideal strength in place of ultimate strength, and dependable strength in place of design strength.
Hearth The insulating floor under the fire and in front and at the sides of the fireplace. Intended use, in relation to a building:
Amend 7 Apr 2007
a) includes any or all of the following: i) any reasonably foreseeable occasional use that is not incompatible with the intended use; ii) normal maintenance; iii) activities undertaken in response to fire or any other reasonably foreseeable emergency; but
Surface water All naturally occurring water, other than sub-surface water, which results from rainfall on the site or water flowing onto the site, including that flowing from a drain, stream, river, lake or sea. Territorial authority (TA) means a city council or district council named in Part 2 of Schedule 2 of the Local Government Act 2002; and a) in relation to land within the district of a territorial authority, or a building on or proposed to be built on any such land, means that territorial authority; and b) in relation to any part of a coastal marine area (within the meaning of the Resource Management Act 1991) that is not within the district of a territorial authority, or a building on or proposed to be built on any such part, means the territorial authority whose district is adjacent to that part. Verification Method means a method by which compliance with the Building Code may be verified.
b) does not include any other maintenance and repairs or rebuilding. Nominal pile width The least width of a pile in side view and is equal to the diameter in round piles. Non-combustible Materials shall be classified as non-combustible or combustible when tested to: AS 1530 Part 1. Other property a) means any land or buildings, or part of any land or buildings, that are i) not held under the same allotment; or ii) not held under the same ownership; and
b) includes a road Sitework means work on a building site, including earthworks, preparatory to or associated with the construction, alteration, demolition or removal of a building.
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1.0
General
1.0.1 The Standards cited in this Verification Method provide a means for the design of structures to meet the performance requirements of New Zealand Building Code Clause B1 Structure. For any particular building or building design, the Verification Method shall consist of AS/NZS 1170 used in conjunction with the relevant cited material standards as modified by this Verification Method. 1.0.2 Modifications to the Standards, necessary for compliance with the New Zealand Building Code, are given against the relevant clause number of each Standard. 1.0.3 Citation of Standards in this Verification Method is subject to the following conditions. a) The citation covers only the scope stated or implicit in each Standard. Aspects outside the scope, when applied to a particular building, are not part of the Verification Method. b) Further limitations, modifications and/or constraints apply to each Standard as noted below. c) Provisions in the cited Standards that are in non-specific or unquantified terms do not form part of the Verification Method. Non-specific or unquantified terms include, but are not limited to, special studies, manufacturers advice and references to methods that are appropriate, adequate, suitable, relevant, satisfactory, acceptable, applicable, or the like.
e) An engineer with relevant experience and skills in structural engineering shall be responsible for interpretation of the requirements of the Standards cited when used for building structure design. A structural engineer who is chartered under the Chartered Professional Engineers of New Zealand Act 2002 would satisfy this requirement.
COMMENT The Standards referenced in this Verification Method relating to building design require the application of specialist engineering knowledge, experience and judgement in their use.
2.0
2.1 The requirements of the AS/NZS 1170 suite of Standards are to be complied with. These comprise: AS/NZS 1170.0: 2002 including Amendments 1, 2 and 4, AS/NZS 1170.1: 2002 including Amendment 1, AS/NZS 1170.2: 2002 including Amendment 1, AS/NZS 1170.3: 2003 including Amendment 1, and NZS 1170.5: 2004.
COMMENT This suite of Standards, together with their amendments, are referred to collectively in this Verification Method as AS/NZS 1170.
2.2 The requirements of AS/NZS 1170 are subject to the following modifications. 2.2.1 Material Standards Where AS/NZS 1170 calls for the use of appropriate material Standards, only those material Standards referenced in this Verification Method B1/VM1 are included. Use of other Standards with AS/NZS 1170 must be treated as an alternative means of verification.
d) Where AS/NZS 1170 is used in combination with other Standards cited in this Verification Method and there are incompatibilities with these other Standards, then the underlying philosophy, general approach, currency of information and methods of AS/NZS 1170 are to take precedence.
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2.2.2 Notes in AS/NZS 1170Notes that relate to clauses, tables or figures of AS/NZS 1170 are part of the Verification Method.
Amend 11 Aug 2011
2.2.5 AS/NZS 1170 Part 0, Clause 5.2 Structural models Delete (a) to (d) in Clause 5.2 and replace with: (a) Static and/or dynamic response. (b) Elastic and/or non-elastic (plastic) response. (c) Geometrically linear and/or geometrically non-linear response. (d) Time-independent and/or time-dependent behaviour.
COMMENT Each of the modelling approaches (a), (b), (c) and (d) allows only one method. This is unnecessarily restrictive since designers may decide to use both approaches for a particular building. Accordingly, or has been replaced with and/or.
COMMENT AS/NZS 1170 makes a general statement that notes are not an integral part of the Standard. However, in many cases the content of the notes makes them an integral part of the interpretation of the Standard. In these cases, the notes have been specifically cited as being part of this Verification Method.
2.2.3 AS/NZS 1170 Part 0, Clause 4.1 General Add the following to the end of the Clause: The combination factors for permanent actions (dead loads) are based on the assumption that they have a coefficient of variation of approximately 10%. Situations where this assumption is not valid are outside the scope of this Verification Method. 2.2.4 AS/NZS 1170 Part 0, Clause 4.2.4 Replace the Clause with the following: The combination of actions for checking strength and stability for the ultimate limit state for fire shall be as follows: (a) During the fire: (i) [G, thermal actions arising from fire, Q] l together with: (ii) a lateral force of 2.5% of (G + CQ) applied as per Clause 6.2.2. (b) After the fire until the building is either repaired or demolished: (i) [G, thermal actions arising from fire, Q ] l together with the more critical of either: (ii) a lateral force of 2.5% of (G + CQ) applied as per Clause 6.2.2. or (iii) a uniformly distributed horizontal face load of 0.5 kPa in any direction. Account shall be taken of the effects of the fire on material properties and the geometry of the structure.
2.2.6 AS/NZS 1170 Part 1, Table 3.2 Replace the entry for R2, Other roofs (i) Structural elements with: R2 Other roofs (i) Structural elements 0.25 1.1 (See Note 1) 2.2.7 AS/NZS 1170 Part 1, Clause 3.6 Barriers In the first paragraph, second sentence, delete top edge or handrail and substitute top edge and rail Delete the second paragraph and substitute: Apply as detailed below the uniformly distributed line loads (kN/m), uniformly distributed loads (kPa) and concentrated loads (kN) given in Table 3.3. For the purposes of applying loads, a rail shall be any handrail or any top rail having a width in plan of greater than 30 mm. The following are separate load cases, and one load at a time, either vertical or horizontal, is to be applied. (a) Line loads (kN/m). Regardless of barrier height, line loads need not be applied more than 1200 mm above the floor (or stair pitch line): (i) For domestic and residential activities, other residential (Row 2 of Table 3.3) For barriers with a rail or rails: apply the horizontal load to the top rail
Amend 8 Dec 2008
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where the top of the barrier is not a rail and where it is less than 200 mm above the top rail, the horizontal load to the top of the barrier may be reduced by 50%, otherwise apply the full horizontal load apply the vertical load to the top of the barrier. For barriers without a rail, apply: the horizontal load at 900 mm above the floor (or stair pitch line) 50% of the horizontal load to the top of the barrier the vertical load to the top of the barrier. (ii) For all types of occupancy other than Row 2 of Table 3.3: apply the loads to the top edge of the barrier and to the top rail where the top of the barrier is not a rail and where it is less than 200 mm above the top rail, the horizontal load to the top of the barrier may be reduced by 50%, otherwise apply the full horizontal load. For all types of occupancy: consider the load as acting over the whole area bounded by the top of the barrier and the floor line for the full length of the barrier distribute this load to the appropriate solid portions of the barrier. (c) Concentrated loads (kN): For all types of occupancy: consider each concentrated load to be distributed over a circular or square area of 2000 mm2 apply concentrated loads so as to produce the most severe effect on the structural element being considered
concentrated loads applied more than 1200 mm above the floor (or stair pitch line) may be reduced by 50% where the barrier infill or balustrade consists of parallel vertical members, less than 100 mm wide and with spaces between them of less than 100 mm, 50% of the concentrated load may be applied to each vertical member.
COMMENT In Table 3.3, external balconies for domestic and residential activities applies to decks, balconies, verandahs and the like of individual houses as well as multi household unit buildings. Such barriers may be required by Clause F4 of the Building Code.
2.2.8 AS/NZS 1170 Part 1, Clause 3.8 Car park Add to the last paragraph of Clause 3.8: The basis for determining the horizontal impact actions on barriers quoted in the Clause, including the assumed deceleration distances, is given in Clause C 3.8 of the Commentary to AS/NZS 1170 Part 1. Different design actions may be derived using Equation C3.8, provided that: (i) The deceleration length applied is based on analysis or tests. (ii) The vehicle mass and associated velocity are not reduced from those quoted in Commentary Clause C3.8. 2.2.9 AS/NZS 1170 Part 1, Appendix B Replace the last paragraph with the following: For the design of outdoor visitor structures as defined in SNZ HB 8630: 2004, the imposed actions must be as given by that publication with references to NZS 4203 replaced by equivalent references to AS/NZS 1170. 2.2.10 AS/NZS 1170 Part 2, Clauses 3.2 and 4.4.3 Add the following at the end of Clauses 3.2 and 4.4.3: Where local wind design information is more onerous than determined by this Standard and is published and required to be used by any territorial authority for its area, this local wind design information shall take precedence over
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the equivalent information in this Standard for the determination of wind actions on buildings. Where such local wind design information is less onerous than that of this Standard, the use of such information is not part of this Verification Method. 2.2.11 AS/NZS 1170 Part 2, Clause 4.3.1 General Add the following to the end of Clause 4.3.1: Account must be taken of combinations of isolated tall buildings placed together that lead to local and overall increases in wind. 2.2.12 AS/NZS 1170 Part 3, Clause 2.1 Add the following at the end of Clause 2.1: Where local snow and ice design information is more onerous than determined by this Standard and is published by any territorial authority for its area, this local snow and ice design information shall take precedence over the equivalent information in this Standard for the determination of snow and ice actions on buildings. Where such local snow and ice design information is less onerous than that of this Standard, the use of such information is not part of this Verification Method. 2.2.13 AS/NZS 1170 Part 3, Clause 5.4.3 Add the following to end of Clause 5.4.3:
Amend 9 Sep 2010
2.2.14A NZS 1170 Part 5, Clause 3.1.4 Add (to the end of Clause 3.1.4): The minimum hazard factor Z (defined in Table 3.3) for the Canterbury earthquake region shall be 0.3. Where factors within this region are greater than 0.3 as provided by NZS 1170 Part 5, then the higher value shall apply.
The hazard factor for Christchurch City, Selwyn District and Waimakariri District shall apply to all structure periods less than 1.5 seconds.
COMMENT: The revised Z factor is intended only for use for the design and assessment of buildings and structures, pending further research. All structures with periods in excess of 1.5 seconds should be subject to specific investigation, pending further research.
For Regions N4 and N5 the minimum value of sg for the ultimate limit state only must be taken as 0.9 kPa. 2.2.14 NZS 1170 Part 5, Clause 1.4 Add the following to the end of the Clause 1.4: Where a special study yields a site-specific uniform risk design spectrum for 500 year return period equivalent to a hazard factor, Z, of less than 0.08, a design spectrum equivalent to at least Z = 0.10 may be adopted and the minimum magnitude 6.5 earthquake need not be considered.
COMMENT: In areas where the uniform risk hazard factor is less than 0.08, the use of a minimum hazard factor Z = 0.13 implies design for earthquakes with extremely low probabilities of occurrence. For some projects in these areas this may involve considerable cost consequences and a reduction in requirements is acceptable when site-specific hazard studies are undertaken.
2.2.14B NZS 1170 Part 5, Table 3.3 Delete row: 102 Christchurch 0.22
Replace with: 102 Delete row: 101 Christchurch 0.3 Akaroa Akaroa 0.16 0.3
2.2.14C NZS 1170 Part 5, Clause 3.1.5 Add (as another paragraph after the last sentence in Clause 3.15): In the Canterbury earthquake region, the risk factor for the serviceability limit state shall not be taken less than Rs = 0.33. 2.2.14D NZS 1170 Part 5, Figure 3.4 Figure 3.4 Hazard factor Z for the South Island is amended as per Paragraph 2.2.14 A above.
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2.2.15 NZS 1170 Part 5, Clause 4.2 Seismic weight and seismic mass After: 0.3 is the earthquake imposed action (live load) combination factor for all other applications add the following: except roofs.
3.0 Concrete
3.1 NZS 3101: Part 1 subject to the following modifications: a) Replace clause 4.8 External walls that could collapse outward in fire with: 4.8 External walls that could collapse inwards or outwards in fire 4.8.1 Application This clause applies to external walls which could collapse inwards or outwards from a building as a result of internal fire exposure. All such walls shall: (a) Be attached to the building structure by steel connections; (b) Be restrained by these connections, when subject to fire, from inwards or outward movement of the wall relative to the building structure; and (c) Comply with the appropriate provisions of this Standard for walls. 4.8.2 Forces on connections The connections between each wall and the supporting structure shall be designed to resist all anticipated forces. In the absence of a detailed analysis, the connections shall be designed to resist the largest of: (a) The force resulting from applying Clause 2.2.4 of Verification Method B1/VM1; (b) for walls fixed to a flexible structure of unprotected steel, the force required to develop the nominal flexural strength of the wall at its base; (c) for walls fixed to a rigid structure such as reinforced concrete columns or protected steel columns or another wall at right angles, the force required to develop the nominal flexural strength of the wall at mid-height. b) Amend Clause 9.3.9.4.13 Minimum area of shear reinforcement In Clause 9.3.9.4.13 c) delete the words after 750 mm and substitute and the depth of the precast unit is equal to or less than 300 mm.
E = 0.0 is the earthquake imposed action (live load) combination factor for roofs.
2.2.16 NZS 1170 Part 5, Sections 5 and 6 Time history analysis Time history analysis is not part of this Verification Method.
COMMENT: Time history analysis is a highly specialised method of assessing structural response to earthquakes. It requires many detailed and interdependent assumptions to be made in relation to the nature of earthquake shaking and its propagation from the source, the properties of the building site and the detailed characteristics of the building and its structural elements. AS/NZS 1170 outlines the steps for time history analysis in some detail, but the applicability of each step needs to be evaluated on a building-by-building basis. More importantly, the output of the analysis needs to be examined carefully in each particular context. Time history analysis can be an acceptable aid to verifying compliance with structural requirements provided that: It is carried out by specialists with in-depth experience in applying the technique. The output of the analysis and the viability of the resulting structural design are reviewed by an independent team experienced in both analysis and design.
2.2.17 NZS 1170 Part 5, Clause 5.2.2.3, equation 5.2(4) Delete equation 5.2(4) and replace with: 5.2(4) C (T) = C (T) Sp
d
k 2.2.18 NZS 1170 Part 5, Clause 6.1.4.1 Requirement for modelling Delete the last sentence of the first paragraph and replace with: The model shall include representation of the diaphragms flexibility.
Amend 8 Dec 2008
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c) Amend Clause 18.7.4 Floor or roof members supported by bearing on a seating Add to the end of Clause 18.7.4 (g)(ii) add an additional sentence:
Erratum 1 Sep 2010
The details given by C18.6.7(e) may be applied to hollow-core units where the depth of the precast unit is equal to or less than 300 mm. 3.2 NZS 3106
f) The extent of the review to be undertaken shall be nominated by the design engineer, taking into account those materials and workmanship factors which are likely to influence the ability of the finished construction to perform in the predicted manner. g) At the end of the first paragraph of Appendix A add the words Unless noted otherwise a document referred to below shall be the version of that document current at the date of issue of this Standard or if amendments are cited to this Standard in the References pages of Compliance Document B1 at the latest date of those amendments. h) Appendix B shall be read as normative with shoulds changed to shalls. 5.3 NASH Standard Residential and Lowrise Steel Framing Part 1: Design Criteria.
Amend 11 Aug 2011
5.0 Steel
5.1 NZS 3404: Part 1
Amend 9 Sep 2010 Amend 8 Dec 2008
5.2 AS/NZS 4600 subject to the following modifications: a) Actions must be determined in accordance with AS/NZS 1170. All references to NZS 4203 are replaced by equivalent references to AS/NZS 1170. b) The term normative identifies a mandatory requirement for compliance with this Standard. c) The term informative identifies information provided for guidance or background which may be of interest to the Standards users. Informative provisions do not form part of the mandatory requirements of the Standard. d) Where this Standard has provisions that are in non-specific or unquantified terms then these do not form part of the Verification Method and the proposed details must be submitted to the territorial authority for approval as part of the building consent application. This includes, but is not limited to, special studies and manufacturers advice. e) All stages of construction of a structure or part of a structure to which this Standard is applied shall be adequately reviewed by a person who, on the basis of experience or qualifications, is competent to undertake the review.
6.0 Timber
6.1 NZS 3603 subject to the following modifications: a) Actions must be determined in accordance with AS/NZS 1170. All references to NZS 4203 are replaced by equivalent references to AS/NZS 1170. b) Delete Clause 2.2.1.2 and replace with: Machine stress-grading shall be in accordance with AS/NZS 1748 as modified by NZS 3622. Machine stress-graded timber shall have its properties verified, and be identified, in accordance with the requirements of NZS 3622.
Amend 11 Aug 2011 Amend 11 Aug 2011
7.0 Aluminium
7.1 AS/NZS 1664.1 subject to the following modifications: a) Actions must be determined in accordance with AS/NZS 1170. All references to NZS 4203 are replaced by equivalent references to AS/NZS 1170. b) The terms capacity factor and strength limit state are to be read as strength reduction factor and ultimate limit state respectively.
Amend 11 Aug 2011
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c) Where this Standard has provisions that are in non-specific or unquantified terms then these do not form part of the Verification Method and the proposed details must be submitted to the territorial authority for approval as part of the building consent application. This includes, but is not limited to, special studies and manufacturers advice. d) All stages of construction of a structure or part of a structure to which this Standard is applied shall be adequately reviewed by a person who, on the basis of experience or qualifications, is competent to undertake the review. e) The extent of the review to be undertaken shall be nominated by the design engineer, taking into account those materials and workmanship factors which are likely to influence the ability of the finished construction to perform in the predicted manner. f) Clause 1.2 to read MATERIALS This Standard applies to aluminium alloys listed in Table 3.3(A) that comply with AS 1734, AS 1865, AS 1866, AS 1867 and AS 2748.1.
Amend 8 Dec 2008
10.0 Siteworks 10.1 NZS 4431 11.0 Drains 11.1 AS/NZS 3725 subject to the following modifications:
Clause 3 Add to the list of reference documents: NZS 3101 The design of concrete structures. NZS 4402 Methods of testing soils for civil engineering purposes: Tests 2.4, 2.8, 4.1.1, 4.2.1, 4.2.2, 4.2.3 and 5.1.1. New Zealand Geomechanics Society, Guidelines for the field description of soils and rocks in engineering use. Clause 4 In the paragraph headed (c) Select fill, after the words given in Table 1 add or the New Zealand Geomechanics Society Guidelines. Clause 5 In definition of Pt, replace AS 4058 with AS/NZS 4058 Clause 6.4 Replace the word may with shall. Delete the words Superimposed concentrated dead loads should be avoided. Clause 6.5.3.1 Delete the words The appropriate road vehicle loading shall be specified by the relevant highway authority or owner. Clause 6.5.3.2.2.2 Replace the word may with shall. Clause 6.5.4.3 Delete the words unless otherwise specified by the Relevant Authority.
g) At the end of the first paragraph of Clause 1.4 add the words Unless noted otherwise a document referred to below shall be the version of that document current at the date of issue of this Standard or if amendments are cited to this Standard in the References pages of Compliance Document B1 at the latest date of those amendments.
Clause 6.5.5 Delete the first words For and after the words for aircraft types add the words is outside the scope of this Standard but... Clause 7 Replace the word should with shall.
Amend 9 Sep 2010
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Foundations
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Clause 10.3 After the words the test load add or proof load. Appendix A Delete Normative and replace with Informative Appendix B Delete Normative and replace with Informative
12.0 Windows
12.1 NZS 4211 subject to the following modification: References to air leakage, water leakage and operational effectiveness of opening sashes in NZS 4211, are non-structural considerations and do not apply to this Compliance Document.
Amend 11 Aug 2011
The component risk factor Rc shall be determined from the Standard but shall not be less than 0.33.
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2.1.4 NZS 4229, Table 4.1 Earthquake zones Delete: Christchurch and Lyttelton Earthquake zone B.
Replace with: Christchurch and Lyttelton Earthquake zone A.
2.0
Masonry
2.1.1 NZS 4229, Paragraph 1.3 Definitions Add (in the definition for Good Ground): (liquefaction, lateral spread for the Canterbury earthquake region only) after subsidence in subparagraph (c). 2.1.2 NZS 4229, Clause 4.2.1 Earthquake zones Add (as another paragraph to the end of this clause):
The Canterbury earthquake region shall be treated as Earthquake zone A for the purpose of determining the earthquake bracing demand.
2.1.7 NZS 4229, Clause 7.8.5.2 Delete: Clause 7.8.5.2 2.1.8 NZS 4229, Clause 7.8.5.3 Delete: Clause 7.8.5.3 2.1.9 NZS 4229, New Clause Add: New Clause 7.8.5.5 Free Joints.
At free joints, slab reinforcement shall be terminated and there shall be no bonding between vertical concrete faces (prevented by using building paper or a bituminous coating). R12 dowel bars 600 mm long shall be placed at 300 mm centres along the free joint and lapped 300 mm with slab reinforcement on both sides of the joint. All dowel bars on one side of the joint shall have a bond breaker applied, e.g. by wrapping dowel bars for 300 mm with petrolatum tape. Joint dowel bars must be installed in a single plane, in true alignment and parallel.
2.1.3 NZS 4229, Figure 4.1 Earthquake zones On the map shown in NZS 4229 Figure 4.1 Earthquake zones, the area within the Canterbury earthquake region shall be interpreted as Earthquake zone A.
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2.1.10 NZS 4229 Foundations in the Canterbury earthquake region only where good ground has not been established
COMMENTS: 1. Foundations for houses built on ground that has the potential for liquefaction or lateral spread are outside the scope of B1/AS1. 2. Foundation designs for houses built in areas that have the potential for liquefaction, as defined by the Christchurch City Council, the Selwyn District Council and the Waimakariri District Council, may be in accordance with the Departments Guidance on house repairs and reconstruction following the Canterbury earthquake as amended from time to time (refer to www.dbh.govt.nz). Note: The foundation options provided in the guidance do not apply in areas: (a) where there is the potential for lateral spreading of greater than 50 mm over the property and not protected by perimeter ground treatment, or (b) where there has been severe ground damage during the 2010/11 earthquakes. This is in areas where the crust (the distance between the ground surface and the water table) is thin, generally occurring in low-lying coastal and estuarine areas. Further guidance is being developed and will be released following additional research. Foundation designs for houses built in areas (a) and (b), as defined by the Christchurch City Council, the Selwyn District Council and the Waimakariri District Council, need to be specifically designed following appropriate geotechnical investigations.
3.1.2 NZS 3604 Section 5 Bracing Design Make the following amendments: Amend Figure 5.4, Earthquake zones, so that all the area within the Christchurch City Council boundary is within Zone 2. Amend Figure 5.4 Earthquake zones, so that the lowest zone within the Selwyn or Waimakariri District Council boundaries is within Zone 2. Areas within Selwyn District that are designated as Zone 1 in NZS 3604 shall become Zone 2. 3.1.3 NZS 3604 Clause 7.5.2.3 Delete: Clause 7.5.2.3
Replace with: Clause 7.5.2.3 The combined foundation and edge details shall be constructed as shown in Figures 7.13(B), 7.14(B) or (C) (and Figures 7.15(B) and 7.16(B) or (C) for foundations supporting a masonry veneer).
Amend 11 Aug 2011
3.1.4 NZS 3604 Figure 7.13 Delete: Figure 7.13(A) Foundation edge details In situ concrete Dimensions & reinforcing for single storey.
Amend title of Figure 7.13(B) to Dimensions & reinforcing for 1 or 2 storeys.
3.0
Timber
3.1.5 NZS 3604 Figure 7.14 Delete: Figure 7.14(A) Foundation edge details Concrete masonry Single storey
Amend title of Figure 7.14(B) to 1 or 2 storeys, and add a note: for a single storey foundation, 15 Series masonry may be used and the minimum footing width may be 190 mm.
COMMENT: Unreinforced and untied slab to footing single storey option removed.
3.1.1 NZS 3604 Paragraph 1.3 Definitions Add (in the definition for Good Ground): (liquefaction, lateral spread for the Canterbury earthquake region only) after subsidence in subparagraph (c).
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A cceptable S olution B 1/ A S 1
3.1.6 NZS 3604 Figure 7.15 Delete: Figure 7.15(A) Masonry veneer foundation edge details Dimensions and reinforcement for single storeys.
COMMENT: Unreinforced and untied slab to footing single storey options removed.
3.1.13 NZS 3604 New Clause Add new: Clause 7.5.8.8 Free Joints.
At free joints, slab reinforcement shall be terminated and there shall be no bonding between vertical concrete faces (prevented by using building paper or a bituminous coating). R12 dowel bars 600 mm long shall be placed at 300 mm centres along the free joint and lapped 300 mm with slab reinforcement on both sides of the joint. All dowel bars on one side of the joint shall have a bond breaker applied, e.g. by wrapping dowel bars for 300 mm with petrolatum tape. Joint dowel bars must be installed in a single plane, in true alignment and parallel.
3.1.7 NZS 3604 Figure 7.16 Delete: Figure 7.16 (A) Masonry veneer foundation edge details Concrete masonry Single storey.
COMMENT: Unreinforced and untied slab to footing single storey option removed.
3.1.14 NZS 3604 Foundations in the Canterbury earthquake region only where good ground has not been established
COMMENT: 1. Foundations for houses built on ground that has the potential for liquefaction or lateral spread are outside the scope of B1/AS1. 2. Foundation designs for houses built in areas that have the potential for liquefaction, as defined by the Christchurch City Council, the Selwyn District Council and the Waimakariri District Council, may be in accordance with the Departments Guidance on house repairs and reconstruction following the Canterbury earthquakeas amended from time to time (refer to www.dbh.govt.nz). Note: The foundation options provided in the guidance do not apply in areas: (a) where there is the potential for lateral spreading of greater than 50 mm over the property and not protected by perimeter ground treatment, or (b) where there has been severe ground damage during the 2010/11 earthquakes. This is in areas where the crust (the distance between the ground surface and the water table) is thin, generally occurring in low-lying coastal and estuarine areas. Further guidance is being developed and will be released following additional research. Foundation designs for houses built in areas (a) and (b), as defined by the Christchurch City Council, the Selwyn District Council and the Waimakariri District Council, need to be specifically designed following appropriate geotechnical investigations.
3.1.10 NZS 3604 Clause 7.5.8.6.2 Delete: Clause 7.5.8.6.2 3.1.11 NZS 3604 Figure 7.18 Delete title: Figure 7.18 Irregular slab (plan view) (see 7.5.8.6.2)
Replace with: Figure 7.18 Irregular slab (plan view) (see 7.5.8.6.4).
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4.0
Amend 11 Aug 2011
Earth Buildings
4.1.5 NZS 4299 Foundations in the Canterbury earthquake region only where good ground has not been established
COMMENT: 1. Foundations for houses built on ground that has the potential for liquefaction or lateral spread are outside the scope of B1/AS1. 2. Foundation designs for houses built in areas that have the potential for liquefaction, as defined by the Christchurch City Council, the Selwyn District Council and the Waimakariri District Council, may be in accordance with the Departments Guidance on house repairs and reconstruction following the Canterbury earthquake as amended from time to time (refer to www.dbh.govt.nz). Note: The foundation options provided in the guidance do not apply in areas: (a) where there is the potential for lateral spreading of greater than 50 mm over the property and not protected by perimeter ground treatment, or (b) where there has been severe ground damage during the 2010/11 earthquakes. This is in areas where the crust (the distance between the ground surface and the water table) is thin, generally occurring in low-lying coastal and estuarine areas. Further guidance is being developed and will be released following additional research. Foundation designs for houses built in areas (a) and (b), as defined by the Christchurch City Council, the Selwyn District Council and the Waimakariri District Council, need to be specifically designed following appropriate geotechnical investigations.
4.1.1 NZS 4299, Paragraph 1.3 Definitions Add (in the definition for Good Ground): (liquefaction, lateral spread for the Canterbury earthquake region only) after subsidence in subparagraph (c). 4.1.2 NZS 4299, Clause 2.3 Earthquake zones Add to the end of Clause 2.3:
The earthquake zone factor > 0.6 shall apply to the Canterbury earthquake region.
4.1.3 NZS 4299, Figure 2.1 Earthquake zones On the map shown in NZS 4299 Figure 2.1 Earthquake zones, the Canterbury earthquake region shall be interpreted as having an earthquake zone factor of > 0.6. 4.1.4 NZS 4299, Clause 4.8.6. Delete: Clause 4.8.6
Replace with: Clause 4.8.6 The thickness and reinforcement and detail of concrete slabs shall comply with the requirements of NZS 3604 as modified in B1/AS1 Paragraph 3.1.
5.0 5.1
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A cceptable S olution B 1/ A S 1
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7.0
Glazing
7.1 NZS 4223.1 subject to the following modifications: Clause 1.2(e) Reword to read: For framed, unframed, and partly framed glass assemblies in buildings up to 10 m high, glass shall be selected in accordance with section 5.
7.3.4 NZS 4223: Part 3 Clause 312.3 Structural balustrades and fences Delete Clause 312.3 Replace with: Clause 312.3. Where glass is used as a structural member, toughened safety glass shall be used. The thickness used shall be determined in accordance with AS/NZS 1170 as modified by B1/VM1. 7.3.5 NZS 4223: Part 3 Section 313 Stairwells and Porches Delete Clause 313.1 Replace with: Glazing in stairways within 2000 mm horizontally or vertically, from any part of a stairway or landing shall be Grade A safety glass in accordance with Table 3.1. Stairways include stairwells, landings and porches and comprise at least two risers. All glazing in stairways protecting a fall of 1000 mm or more shall also meet the barrier requirements of AS/NZS 1170 as modified by B1/VM1. 7.3.6 Table 3.7 Glazing protecting a difference in level in any building. Delete Table 3.7 7.3.7 Table 3.8 Unframed or partly framed balustrades and fences. Delete Table 3.8 Appendix 3.E
Delete Appendix 3.E Replace with: Refer to NZS 4223 Part 1 Section 5.4
7.2
NZS 4223.2
7.2.1 201 Selection and installation of sash and frames Delete Clause 201.1 (b) Replace with: Clause 201.1(b). They must allow for contraction and expansion of the building and comply with relevant clauses of AS/NZS 1170 and NZS 4223.1 section 3.5.
7.3
NZS 4223.3
7.3.1 Related documents, New Zealand Standards Delete NZS 4203: 1992 General structural design and design loadings for buildings Replace with: AS/NZS 1170 Structural Design Actions. 7.3.2 Clause 310.1 Delete Clause 310.1 Replace with: Glazing used in any building in situations that require protection for occupants from falling 1000 mm or more from the floor level shall meet the barrier requirements of AS/NZS 1170 as modified by B1/VM1. 7.3.3 NZS 4223: Part 3 Clause 312.2 Unframed or partly framed balustrades and fences Delete Clause 312.2 (a) and (b) Replace with: Unframed and partly framed balustrade systems shall be designed in accordance with AS/NZS 1170 as modified by B1/VM1.
7.4 8.0
9.0
Timber Barriers
Amend 11 Aug 2011
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1.0 1.1
1.2
1.1.1 Type The acceptable solutions described in this document are for chimneys built of brickwork, concrete or precast pumice concrete, that are connected to timber frame or masonry buildings complying with NZS 3604 or NZS 4229. 1.1.2 Height The height of any chimney measured from the top of the chimney foundation slab to the top of the chimney stack shall not exceed 9 m. Chimneys shall not cantilever more than 2.4 m above the fixing at roof level (refer Paragraph 1.7). 1.1.3 Size The width (measured along the building line) and depth (measured perpendicular to the building line) shall not exceed: a) For the foundation and chimney base precast pumice concrete brickwork or concrete 1600 mm wide x 1050 mm deep 1200 mm wide x 1050 mm deep 500 mm wide x 500 mm deep 1200 mm wide x 680 mm deep 1200 mm wide x 700 mm deep
1.2.1 Chimney wall thicknesses shall be no less than: a) Brick single skin (see Figure 2) double skin (see Figure 3) b) Concrete c) Precast pumice concrete 155 mm 245 mm 170 mm 85 mm
These thicknesses apply to the chimney stack, gather and chimney base.
1.3
Foundations
1.3.1 Chimneys shall be built on a foundation comprising walls and slab for suspended floors (see Figure 1(a)), or on a thickened slab for floor slabs on ground (see Figure 1(b)). 1.3.2 The chimney foundation slab shall be constructed in reinforced concrete, founded on good ground, and have: a) A thickness of no less than 200 mm, and be placed at a depth of no less than 300 mm below surrounding ground level. b) Reinforcement as shown in Figure 1. c) D12 starters at 400 mm maximum centres, to match vertical steel locations in the chimney. 1.3.3 The chimney foundation walls shall be 150 mm thick reinforced concrete, 190 mm thick concrete masonry, or brick construction complying with Figures 2 or 3. Vertical and horizontal reinforcing steel shall be as given in Paragraph 1.6.
b) For a brick chimney stack single skin (see Figure 2) double skin (see Figure 3) c) For a concrete or precast pumice concrete chimney stack
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Figure 1:
Chimney Foundation Paragraphs 1.3.1, 1.3.2 b) and 1.4.1, and Figures 2, 3, 4 and 5
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Figure 2:
Brick Chimney with Liner Paragraphs 1.1.3 b), 1.2.1 a), 1.3.3, 1.6.1, 1.7.2, 1.7.5 and 1.7.6
B1AS3FIG2.dwg 030401
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Figure 3:
Brick Chimney Without Liner Paragraphs 1.1.3 b), 1.2.1 a), 1.3.3, 1.6.1, 1.7.2, 1.7.5 and 1.7.6
B1AS3FIG3.dwg 030401
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1.4
Hearths
1.4.1 Hearth slabs shall be of concrete no less than 75 mm thick, reinforced with D10 bars located centrally at 225 mm centres each way. See Figure 1.
1.6.2 Bars which do not extend for the full height of the chimney shall be stopped in the gather: a) In reinforced concrete and brick, by continuing these bars through to the far face of the gather and terminating with a 200 mm leg. b) In precast pumice concrete, by anchoring the last 200 mm of the bar in a high strength cementitious grout. (See Figure 5.) Refer Paragraph 1.8.3 g) for grout details.
1.5
Chimney breasts
1.5.1 The widths of openings in chimney breasts, and their supporting lintels, shall comply with Table 1.
Table 1:
Chimney Breast Openings and Lintels Paragraph 1.5.1 and Figure 4 Lintel reinforcing 65 x 10 mm m.s. flat or 80 x 60 x 5 mm m.s. angle Two D10 rods D12 upper rod D16 lower rod Two D10 rods
1.7
Chimney restraint
1.7.1 Chimneys which are not constructed integrally with the building shall be secured by floor and roof brackets. An acceptable alternative for brick and precast pumice concrete chimneys is that they be restrained by a roof tie used in conjunction with closely spaced wall ties. (Refer Paragraphs 1.7.5 to 1.7.16.) 1.7.2 Where a packer (see Figures 2, 3, 6 and 7(b)) is shown between the chimney and building it shall be: a) Concrete, brick, steel (angle, channel or Z section), or any insulating material which has a long term operating temperature of no less than 150C, b) Secured in place to prevent it dislodging, and c) Capable of withstanding a compressive force of 10 kN without shortening by more than 1.5 mm.
COMMENT: C/AS1 Part 9 requires a 50 mm separation between the chimney and any combustible material. Where the chimney fixing described does not prevent the chimney moving within this gap, a packer is shown.
Amend 5 Jul 2001
Horizontal reinforcing rods to concrete and precast pumice are to be placed one above the other at a spacing of 75 mm, and have R6 ties at 150 mm maximum centres.
1.6
Reinforcing
1.6.1 Reinforcing of foundation walls, chimney bases (including the gathers) and chimney stacks (see Figures 2 to 5 inclusive) shall comprise: a) D12 bars at 400 mm maximum centres vertically. Laps in bars shall be no less than 300 mm. b) R6 bars at 200 mm centres horizontally. These will be in the form of closed stirrups in the stack and U bars elsewhere. c) Double horizontal reinforcing at any change in direction of the vertical steel (e.g. at the gather/stack intersection).
1.7.3 Floor and roof brackets The brackets shall comprise a 50 mm x 4 mm hot dip galvanised steel strap placed around the chimney. Each leg of the strap shall be horizontal and shall be bolted to the joists with three M12 bolts at 75 mm centres as shown in Figure 6.
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Figure 4:
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Figure 5:
Reinforcing Details Precast Pumice Concrete Chimney Paragraphs 1.6.1 and 1.6.2 b)
B1AS3FIG5.dwg 030401
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1.7.4 Brackets shall be located so that the distance between the top of the chimney foundation slab and the first bracket, and the distance between adjacent brackets does not exceed 3.0 m. Where a chimney foundation wall is integral with a building foundation wall, then the height to the first bracket may be measured from the top of the building foundation wall. 1.7.5 Alternative fixing using roof tie and closely spaced wall ties This alternative chimney fixing shall apply only from the gather to roof level. It requires that either the top of the chimney foundation slab or a floor bracket complying with Paragraph 1.7.3 be located within a distance of 2.5 m below the first of the closely spaced wall ties. (See Figures 2 and 3.) If the latter applies, the chimney below this bracket shall be fixed by floor brackets spaced in accordance with Paragraph 1.7.4. 1.7.6 Brick chimneys Brick chimneys shall be restrained at roof level by a zinc coated 50 x 1.0 mm mild steel U strap used in conjunction with closely spaced wall ties. The strap shall be: a) Cast into the grout and wrap around the reinforcing steel (see Figures 2 and 3), b) Placed at no more than 20 from the horizontal, c) Used in conjunction with a packer (complying with Paragraph 1.7.2) placed at the same level, and d) Fixed with twelve 30 x 3.15 mm galvanised nails to roof or ceiling framing. 1.7.7 Wall ties (see Figure 7(a)) shall be located in mortar joints at 225 mm maximum centres up each side of the chimney, except that pairs of ties shall be used for chimneys wider than 600 mm. 1.7.8 Wall ties shall be constructed from either 4 mm diameter galvanised bar or 25 x 1.5 mm zinc coated steel strip capable of withstanding a load of 1.2 kN without elongating or shortening by more than 1.5 mm.
1.7.9 Where zinc coating of components is required it shall be no less than 300 g/m2 in accordance with AS 1397. 1.7.10 Nails used to fix straps to roof or ceiling framing shall be spaced at no less than 35 mm in Radiata Pine, and 70 mm in other timbers. 1.7.11 Acceptable alternatives to the cast-in U strap are: a) Any proprietary bracing strip system of equal durability to the U strap described in Paragraph 1.7.6, and capable of carrying a seismic force of 12 kN without elongating by more than 1.5 mm, or b) A cast-in hot dip galvanised, deformed 6.0 mm reinforcing bar bent to a U shape, with each end fixed to the roof or ceiling framing with six 50 x 4.0 mm galvanised fencing staples. 1.7.12 The U strap or either of the acceptable alternatives may be wrapped around the outside of the chimney rather than be cast-in, provided that if strap is used it shall be painted with a zinc rich primer. 1.7.13 Precast pumice concrete chimneys Precast pumice concrete chimneys shall be restrained at roof level either by a 50 x 1 mm U strap wrapped around the chimney, or by a hot dip galvanised deformed 6 mm reinforcing bar placed into the grout around the reinforcing steel, together with either fixing brackets or fixing ties (see Figure 7(b)). Straps and bars shall satisfy the relevant requirements of Paragraphs 1.7.6 to 1.7.12. 1.7.14 Fixing brackets (see Figure 7(b)) shall be made from 5.0 mm thick mild steel angle and drilled with: a) A 50 mm diameter hole to suit the reinforcing duct location, and b) A 14 mm diameter hole for the 12 mm diameter coach screw fixing to the double stud. 1.7.15 Fixing brackets shall be located in mortar joints between the units, and be spaced at no less than 480 mm centres for stacks up to 600 mm wide, and no less than 320 mm centres for stacks wider than 600 mm.
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Figure 6:
Chimney Restraint Floor and Roof Brackets Drawn for Roof Restraint Paragraphs 1.7.2 and 1.7.3
B1AS3FIG6.dwg 030401
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Figure 7:
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1.7.16 Fixing ties shall comprise 4 mm galvanised wire hairpins, which are hooked behind the reinforcing ducts and secured to the required adjacent double studding with four heavy duty fencing staples. The ties shall be located in mortar joints between the units and be at no less than 320 mm centres for stacks up to 600 mm wide, and no less than 160 mm centres for stacks wider than 600 mm.
g) Have ducts filled with grout complying with NZS 4210, except over the last 200 mm where bars are anchored in the gather (refer Paragraph 1.6.2 b)). At these locations a non-shrinking cement-based grout, which attains a minimum compressive strength of 30 MPa at 7 days, shall be used. 1.8.4 Concrete masonry Concrete masonry construction for chimney foundation walls shall conform to the relevant sections of NZS 4229. 1.8.5 Reinforcing steel Reinforcing used in chimneys is to conform to AS/NZS 4671, and shall: a) For brick, be embedded centrally in the thickness of the grout, b) For in-situ concrete, have cover to the steel in accordance with NZS 3109, c) For precast pumice concrete, be placed with grout in the preformed ducts in the units. 1.8.6 Hot dip galvanising Hot dip galvanising shall comply with AS/NZS 4680.
Amend 9 Sep 2010
1.8
1.8.1 Brickwork Brick chimney construction shall conform to the relevant sections of NZS 4210. 1.8.2 Concrete Chimneys, foundations and hearth slabs of reinforced concrete, shall comply with the relevant clauses of NZS 3109 for ordinary grade concrete. 1.8.3 Precast pumice concrete Pumice concrete units for use in precast chimneys shall: a) Have pumice aggregate which: i) is free of combustible and organic matter, and ii) has a maximum aggregate size of no greater than 19 mm, with at least 40% but not more than 60% of the aggregate retained by a 4.75 mm standard test sieve, and b) Have a mix ratio by volume of no more than five parts of mixed pumice aggregate to one part of cement, c) Have a compressive strength of no less than 7 MPa at 28 days when cured and tested in accordance with NZS 3112: Part 2, d) After adequate curing, be air dried and kept under cover during storage, transport and on the site, e) Be laid dry. (Work left unfinished should be protected from rain.) f) Be joined with mortar which complies with NZS 4210, and
1.9
1.9.1 The bracing described in Paragraphs 1.9.2 to 1.9.6 shall be provided in those buildings where one or more of the following apply: a) The area of the room containing the chimney exceeds 24 m2, b) The length of the wall on which the chimney is located exceeds 3.5 m between supporting braced walls which are perpendicular to it. This length may be increased to 6.5 m where the wall is supported, at each floor level and at the roof or ceiling level, by either a structural diaphragm which conforms with the relevant requiements of NZS 3604 or by dragon ties. The dragon ties shall:
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i) consist of a continuous length of 100 x 50 mm timber fixed in accordance with NZS 3604 clauses 8.3.3.3 and 8.3.3.4, ii) be run as a pair, with one dragon tie going from the wall on which the chimney is located, back to each of the supporting braced walls. The enclosed angle between the wall on which the chimney is located and each dragon tie shall be 60, and iii) be located no more than 1.5 m out from each supporting braced wall. c) The floor area on any level of the building, for a given chimney type (see Table 2), is less than: i) 50 m2 for chimney Type 1, ii) 75 m2 for chimney Types 2, 3 and 4, iii) 150 m2 for chimney Types 5, 6 and 7. 1.9.2 The building supporting the chimney shall contain bracing elements to resist earthquake loads from the chimney. These loads are applied at roof level and at each floor to which the chimney is connected. The bracing elements necessary are additional to those required by NZS 3604 or NZS 4229.
1.9.3 The number of bracing units to be provided for each chimney connection (see Paragraph 1.9.4) is given in Table 2. The number of bracing units to be provided at any level shall be the sum of the bracing units required at each of the chimney connections above the level being considered. The earthquake bracing units at roof and floor connections required for chimneys constructed in accordance with B1/AS3 shall be determined for the Canterbury earthquake region from Table 2 for Earthquake zone A.
COMMENT: As an example: for a standard precast pumice concrete chimney in a two storey building in Zone A, that is connected to the building by a roof bracket and by floor brackets at ground and first floor, the number of bracing units required are: Location Just below roof level Just below first floor level Just below ground floor level Bracing units required 60 60 + (60% of 60) = 96 60 + (60% of 60) + 60 = 156
1.9.4 A chimney shall be considered as connected to the building when: a) At roof level: it is held either by a roof bracket or by a roof tie, b) At ground floor level: it is held by a floor bracket or the chimney base is integral with the building foundation wall,
Table 2:
Bracing Units Required for Each Chimney Connection to Resist Earthquake Loadings Paragraphs 1.9.1c) and 1.9.3 Number of bracing units required at the roof connection and at each floor connection according to earthquake zone: (See Note 1) Zone A 60 110 90 130 240 210 390 Zone B 50 90 70 100 200 170 320 Zone C 40 70 60 80 160 140 260
Chimney construction
Type
Stack Precast pumice standard large Brick single skin double skin Concrete
Note:
Base 1600 x 1050 1600 x 1050 1200 x 1050 1200 x 1050 1200 x 1050 1200 x 1050 1200 x 1050
1 2 3 4 5 6 7
500 x 400 1100 x 400 500 x 500 590 x 590 1200 x 680 590 x 590 1200 x 700
1. The number of bracing units required at floor connections other than the ground floor shall be taken as 60% of the value given in the table.
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c) At an intermediate floor level: it is held either by a floor bracket or by closely spaced wall ties spanning the floor. 1.9.5 For earthquake ground movement in the direction perpendicular to the wall on which the chimney is located, structural diaphragms shall be provided at roof/ceiling level and at each floor level to which the chimney is connected. The diaphragms shall comply with all relevant clauses of NZS 3604 and NZS 4229. 1.9.6 For earthquake in the direction parallel to the wall on which the chimney is located, the bracing units required as determined from Paragraph 1.9.3 shall be provided solely by that wall.
2.2.3 Hearth slabs on concrete floors shall be secured in position by four D10 starter rods. The rods shall be located in each corner of the hearth slab and they shall terminate each end with standard hooks complying with NZS 3109. Spread of fire 2.2.4 Paragraphs 2.2.1 to 2.2.3 provide an acceptable structural solution, but depending on the particular installation, different hearth dimensions may be necessary to meet the spread of fire requirements of NZBC Clause C1.3.2. Hearth slabs for solid fuel burning appliances shall comply with AS/NZS 2918.
Amend 2 Aug 1994
2.0
2.1
2.1.1 Chimneys for solid fuel burning appliances shall comply with Paragraph 1.0 or with the relevant sections of AS/NZS 3869 and AS/NZS 2918 for sheetmetal chimneys.
2.2
Hearth slab
2.2.1 Solid fuel burning domestic appliances weighing no more than 130 kg shall be supported on a 65 mm thick hearth slab that is: a) Reinforced with 665 mesh, or D10 rods at 300 mm centres each way, placed centrally in the slab thickness, b) Supported on a timber or concrete floor, or integral with a concrete floor. (The floor supporting the hearth slab shall comply with NZS 3604 or NZS 4229 as appropriate), and c) Comprised of ordinary grade concrete complying with the relevant clauses of NZS 3109. 2.2.2 Hearth slabs on a timber floor shall be held in position by supporting members on all four sides of the hearth. These members shall each be held by four screws with a minimum shank diameter of 4.88 mm that penetrate the floor framing by 50 mm.
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1.0
COMMENT: Saturated sands may be subject to liquefaction during earthquake loading and sensitive clays exhibit a rapid decrease in undrained shear strength once the peak strength has been mobilised. The design of foundations on these materials needs special considerations which are not covered in this verification method.
1.0.1 This document covers the ultimate limit state design of foundations, including those of earth retaining structures. Methods are given for determining ultimate bearing and lateral sliding strengths. 1.0.2 This document does not describe a means of determining the value of the soil parameters used in the document (e.g. cI, fI and su). The derivation of these parameters, which must be based on the most adverse moisture and groundwater conditions likely to occur, is outside of the scope of this verification method.
COMMENT: Appendix A contains information on the types of investigations that may need to be conducted to determine the soil parameters.
1.0.6 This document shall not be used for foundations subject to continuous vibration.
COMMENT: Although this document covers foundations subject to vibration from earthquake loading it does not cover those applications where foundations are subject to continuous vibration such as from the operation of certain machinery.
1.0.7 The Comments and Informative Appendices of this document provide comment, background or general information but do not form part of this verification method.
COMMENT: Appendix C contains a worked example showing how some of the provisions of this document are used.
1.0.3 Serviceability limit state deformations are not covered in this document. The determination of such deformations and their acceptability to the design in question needs to be considered but is outside the scope of this document.
COMMENT: Appendix B contains information which may be of assistance in designing for serviceability limit state deformations. It is intended that design provisions to cover serviceability limit state deformations be added to the document in the future.
2.0
General
2.0.1 Foundations must be designed for the load combinations given in AS/NZS 1170 Part 0, as amended by B1/VM1. Strength reduction factors given in this document must be used to determine the design strength of the foundation. The design loadings must not cause the foundations design strength to be exceeded. 2.0.2 The design procedures of this document must be performed by a person who, on the basis of experience or qualifications, is competent to apply them. 2.0.3 The building's foundation elements or the elements of earth retaining structures shall be designed in accordance with the appropriate material Standards, as given in B1/VM1. 2.0.4 Foundations may be shallow or deep. A shallow foundation is one in which the
1.0.4 This document assumes general ground or slope stability and provides methods only for ensuring against local failure of the foundation. Overall ground stability needs to be verified before this document can be applied; this is outside the scope of this verification method. 1.0.5 This document must not be used to design foundations on loose sands, saturated dense sands or on cohesive soils having a sensitivity greater than 4.
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depth from the ground surface to the underside of the foundation is less than five times the width of the foundation. All other foundations are considered to be deep. 2.0.5 In assigning values for soil parameters the worst groundwater condition shall be considered.
COMMENT: For cohesive soils the fully saturated condition will generally give the lowest strength and stiffness.
foundation is beneath the zone of soil affected by shrinking and swelling caused by seasonal weather changes, and the root systems of nearby trees and shrubs. 3.1.3 Consideration shall be given to the possibility of any surcharge adjacent to a shallow foundation being removed during the life of the foundation, so reducing the available ultimate bearing strength. 3.1.4 Foundations subject to moment loading shall not be proportioned such that the point of application of the reaction force on the underside of the foundation is closer to the edge than B/6, for a rectangular foundation, or r/2, for a circular foundation.
2.0.6 Foundation strength for cohesive soil depends on loading duration and whether consolidation can occur. For this reason the distinction is made between short term (e.g. initial load application, earthquake actions or wind gusts) and long term loading (e.g. permanent loads such as foundation dead load). For the short term case no consolidation occurs and the calculations shall be in terms of undrained shear strength (i.e. shear strength of the soil su) and total stress. For long term loading, full consolidation occurs and the calculations shall be in terms of drained shear strength and effective stress (i.e. soil parameters being cohesion, cI , and the angle of shearing resistance fI ). 2.0.7 For cohesionless soils consolidation occurs very quickly so drained strength shall be used in all cases. 2.0.8 Supervision and verification of soil parameters Design assumptions and soil parameters shall be verified during construction. The designer shall nominate what supervision, including verification of soil parameters, will be undertaken during the construction period.
3.2
3.2.1 The design bearing pressure qd shall be determined by dividing the design vertical forces (derived from combinations of factored vertical loads) by the effective area of the foundation. See Paragraph 3.3 for notation and the definition of effective area. 3.2.2 The ultimate bearing strength qu is that pressure, exerted on the ground by the building foundation, which causes the ground to fail by mobilisation of all available shear strength. It shall be evaluated using the provisions of Paragraph 3.3. 3.2.3 The design bearing strength qdbs shall be determined by multiplying the ultimate bearing strength by the appropriate strength reduction factor (see Paragraph 3.5.1). 3.2.4 The design bearing pressure shall not exceed the design bearing strength.
3.0 3.1
Shallow Foundations 3.3 General Provisions Ultimate limit state bearing strength for shallow foundations
3.1.1 The ultimate bearing strength shall be based on the most adverse moisture and groundwater conditions likely to occur. 3.1.2 Founding depths in clay soils known to exhibit swelling and shrinking behaviour shall be chosen so that the underside of the
3.3.1 The procedures specified in the following text apply to foundations of any size. The formulae are limited to soil profiles that for a depth beneath the underside of the foundation of at least two times the foundation width can be represented with single values for the density, angle of shearing
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of application of the design vertical foundation load V (m). Y the distance from the edge of the foundation, along the y axis, to the point of application of the design vertical foundation load V (m). the distance from the edge of a circular foundation, along the z axis, to the point of application of the design vertical foundation load V (m). cohesion (kPa).
I
effective foundation area (m ). For a rectangular foundation AI = BI LI . For a circular foundation see Figure 2. foundation breadth (m). the smaller of 2(X + eb ) and 2(B X e b ) (see Figure 1) (m). minimum horizontal distance from the edge of the underside of the foundation to the face of an adjacent downward slope (m). depth to the underside of the foundation (m). design horizontal load, the resultant of the factored horizontal forces applied to the foundation (kN). unfactored horizontal foundation load (kN). foundation length (m). the smaller of 2(Y + el ) and 2(L Y el ) (see Figure 1) (m). design moment applied about an axis parallel to the breadth direction of the foundation (kNm). design moment applied to a circular footing (kNm). design moment applied about an axis parallel to the length direction of the foundation (kNm). bearing strength factors. ultimate lateral resistance derived from passive earth pressure (kN). reaction on underside of foundation = qd AI (kN). ultimate shear strength between the base of the foundation and the ground (kN). design factored vertical foundation load (kN). unfactored vertical foundation load (kN). effective design factored vertical load = V uf AI (kN). the distance from the edge of the foundation, along the x axis, to the point z y q qI qd qu
qdbs
B BI De
c c eb ec el
effective stress cohesion (kPa). Ml / V (positive when R is further along the x axis than V, see Figure 1) (m). Mc / V (positive when R is further along the z axis than V, see Figure 2) (m). M b /V (positive when R is further along the y axis than V, see Figure 1) (m). vertical total stress in ground adjacent to the foundation at depth Df (kPa). vertical effective stress (sI v) in ground adjacent to the foundation at depth Df (kPa). design bearing pressure = V/AI (kPa). ultimate bearing strength (kPa). design bearing strength = Fbcqu (kPa). radius of a circular foundation (m). undrained shear strength (kPa). pore water pressure at a given position in the soil profile (kPa). pore water pressure at depth Df (kPa). axis through design vertical foundation load V in direction of foundation breadth. The axis starts at the foundation edge and is positive in the direction towards V. axis through design vertical foundation load V in direction of foundation length. The axis starts at the foundation edge and is positive in the direction towards V. axis through the centre of a circular foundation and the design vertical foundation load V. The axis starts at the foundation edge and is positive in the direction towards V.
Df H
Huf L LI Mb
Mc Ml
r su u uf x
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g gI
soil unit weight (kN/m3). soil unit weight required for effective stress analysis for soil beneath the water table = g gw (kN/m3). g when the water table is deeper than 2B beneath the underside of the foundation and gI when the water table is above this. water unit weight (kN/m ). strength reduction factor for bearing strength (see Paragraph 3.5.1).
3
qu = cI lcslcdlcilcg Nc + qI lqslqdlqilqgNq + 1/2gI BI lgslgdlgilggNg The bearing strength factors are obtained from Figure 3 or the following equations: f Nq = eptanftan2 45 + 2
gw Fbc
where e is the mathematical constant = 2.7183 Nc = (Nq 1 )cotf for f > 0, but has a value of 5.14 for f = 0 Ng = 2(Nq 1)tanf The l factors in the above equation are: a) Shape factors: lcs, lqs and lgs where: BI lcs = 1 + __ LI
Fpp strength reduction factor for resistance derived from passive earth pressure (see Paragraph 3.5.1). Fsl f fI sI v strength reduction factor for sliding resistance (see Paragraph 3.5.1). angle of shearing resistance (degrees). effective stress angle of shearing resistance (degrees). vertical effective stress at a given depth in the soil profile = SgiTi u where gi is the unit weight and Ti is the thickness of the ith soil layer above the depth at which sI v is required (kPa). slope, below horizontal, of the ground adjacent to the edge of the foundation (degrees).
BI __ lqs = 1 + _ I L
3.3.2 Ultimate bearing strength The general expression for the ultimate bearing strength for a shallow foundation subject to vertical, shear, and moment loading is: qu = clcslcdlcilcgNc + qlqslqdlqilqgNq + 1/2GBI lgslgdlgilggNg For undrained analysis (f = 0) use the following form of the general equation: qu = sulcslcdlcilcg Nc + lqgq For drained analysis use the following form of the general equation:
BI __ lgs = 1 0.4 _ I L
( )( ) ( ) ( )
Nq _ _ Nc tanf
b) Depth factors: lcd, lqd and lgd where: Df for f = 0 and __ < 1: _ BI
( ) ( )
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Figure 1:
Bearing Strength Stress Block for a Shallow Rectangular Foundation Subject to Vertical Load and Moment Paragraph 3.3.1
V X x X + eb
R B
B - X - eb
B L' B' V
R Ml X Mb el Y L
eb
Notes: 1. Section (a) above drawn through foundation width. Section through foundation length similar. 2. B' is the smaller of 2(X + e b) and 2(B - X - e b). Similarly L' is the smaller of 2(Y + e )l and 2(L - Y - e ). l 3. M can be applied anywhere on the foundation and does not have to be applied at the location of V.
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Figure 2:
Effective Foundation Area for a Circular Foundation Subject to Vertical Load and Moment Paragraph 3.3.1
B'
2r
L' Mc
ec
Notes Notes: Effective area A' shall be represented by an equivalent rectangle of length L' and breadth B', where:
Amend 8 Dec 2008
-1
-1
A'
0.25
L' =
A'
r - e c- Z r
otherwise
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(1 lqd) Nq tanf
( )
-1
Nq 1
( )
Df __ , _ l B
For horizontal ground lcg = lqg = lgg = 1 For inclined ground, the permitted slope (angle v below the horizontal) depends on soil angle of shearing resistance f and the distance De between the foundation and the slope face:, where f > 0 (drained analysis) _ v shall not be > f where f = 0 (undrained analysis) v shall not be > 45 The ground inclination factors shall be: for De < 2B _ lcg = lqg = lgg = 1 for De < 2B lcg = 1 v(1 De / 2B)/150 lqg = lgg = (1 tan(v(1 De /2B))) 3.3.3 Local shear For sands with relative densities less than 40% and clays having liquidity indices greater than 0.7, the bearing strength shall be evaluated using 0.67c for cohesion and tan-1(0.67tanf) for the angle of shearing resistance.
COMMENT: The formulae in Paragraph 3.3.2 assume a general shear failure of the soil but for the soils specified in this Paragraph a local shear failure is likely.
2
for all cases lgd = 1 c) Load inclination factors: lci, lqi and lgi where: for f = 0 H lci = 0.5 1 +l 1 ___ AI su lqi = 1 for f > 0 for horizontal loading parallel to LI Huf lqi = lgi = 1 ____________ ____ I I I (Vuf + A c cotf ) lqiNq 1 lci = _______ Nq 1 for horizontal loading parallel to BI 0.7Huf lqi = 1_ ______________ Vuf + AIcI cotfI
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Figure 3:
3.4
3.4.1 When the loading is not normal to the foundation base, foundations shall be checked for failure by sliding. 3.4.2 The ultimate sliding resistance shall comprise the sum of the ultimate sliding strength between the base of the foundation and the ground, and any available passive earth pressure in the direction of sliding at the side of the foundation. 3.4.3 Passive earth pressure shall not be considered if: a) For foundations in clay soils, it is possible that the clay could shrink away from the vertical faces of the foundation, or
b) The possibility exists that the soil in front of the foundation may be removed by erosion or by building or landscaping work in the future. 3.4.4 For drained conditions, the ultimate sliding strength shall be: S = cI AI + VI tandI The value of dI shall be taken as the angle of shearing resistance (fI ) of the foundation soil for cast-in-situ concrete foundations and 0.67fI for smooth precast foundations. 3.4.5 For undrained conditions, the ultimate sliding strength shall be: S = AI su
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3.4.6 Design sliding resistance The design horizontal load H shall not exceed the design sliding resistance, that is: H < FsIS + Fpp Pp _
3.5
3.5.1 Strength reduction factors to be applied to shallow foundation design shall be within the range given in Table 1. The designer shall nominate in the design the strength reduction factors chosen along with substantiation as to why the values chosen are considered appropriate. The values chosen shall be to the approval of the territorial authority.
COMMENT: The value of the strength reduction factor used in design will depend on the designers knowledge of the site and the investigations undertaken. As a guide the lower end of the range will generally be appropriate when a limited site investigation is undertaken, average geotechnical properties are used, published correlations are used to obtain design parameters or there will be minimal construction control. The upper end of the range will generally be appropriate when a comprehensive site investigation and laboratory testing is undertaken, geotechnical properties are chosen conservatively, site specific correlations are used for design parameters and there will be careful construction control.
4.0.2 Using geotechnical calculation, the ultimate axial compressive pile strength is the sum of the ultimate pile point-bearing resistance and the shaft resistance. 4.0.3 When determined by static load testing, the ultimate axial compressive pile strength shall be taken as no more than that load which produces a penetration or pile settlement of 0.1 times the: a) Nominal pile width for driven piles, b) Bell diameter for belled piles, c) Estimated minimum bulb diameter for bulbed piles. Suitable procedures for static load testing are described in AS 2159 Section 8, ASTM D1143 and BS 8004 Section 7.5. 4.0.4 The design pile vertical or lateral strength of a single pile or pile group shall be determined by multiplying the ultimate strength by the appropriate strength reduction factor (see Paragraph 4.7.1). The design strength shall be greater than the applied factored loads.
4.0
Pile Foundations
4.0.1 The ultimate axial compressive pile strength for a single pile shall be determined using either or both of the following methods:
Table 1:
Strength Reduction Factors for Shallow Foundation Design Paragraph 3.5.1 Strength reduction factor range
Load combination For bearing (Fbc) and passive earth pressure (Fpp): Load combinations involving earthquake overstrength All other load combinations For sliding (Fsl): All load combinations, including earthquake overstrength
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4.1
Rd V1 VB VG Vbu Vsu Vu W ca
relative density as measured in accordance with Test 4.2.3 of NZS 4402. ultimate strength of an individual pile in the group (kN). ultimate strength of the block of soil enclosed within the pile group (kN). ultimate strength of the group (kN). ultimate base resistance (kN). ultimate shaft resistance (kN). vertical pile strength (kN). pile weight (part of the dead load) (kN). the undrained adhesion (total stress) at the soil/shaft interface in a clay soil, or the adhesion at the boundary of a pile group = su (kPa). drained (effective stress) adhesion at the soil/shaft interface in a cohesive soil, or the adhesion at the boundary of a pile group (kPa). for a free head pile, the distance above the ground surface at which the horizontal shear is applied (= M/H); and for a restrained head pile, the distance above the ground surface at which the restraint is applied (m). length of pile shaft assumed to be unsupported in cohesive soil = 1.5Ds (m).
4.1.1 Notation Ab BG C Db Ds H Hu Ko width (between pile extremities) of a pile group (m). circumference of the pile shaft (m). diameter of the pile base (m). diameter of the pile shaft (m). design horizontal load applied to the pile head (factored applied loads) (kN). ultimate lateral strength of a pile (kN). the coefficient of earth pressure at rest = 1 sinfI for loose sand and normally consolidated clay, and (1 sinfI ) OCR for over-consolidated soils. coefficient of passive earth pressure = (1 + sinfI )/(1 sinfI ). factor that expresses the horizontal effective stress at the pile/soil interface in terms of the vertical effective stress (see Table 2). length of the pile shaft (m). length (between pile extremities) of a pile group (m). design moment applied to the pile head (factored applied moments) (kNm).
cI a
Kp Ks
L LG M
fo
Mult ultimate moment strength of the pile shaft (kNm). OCR over-consolidation ratio being the previous maximum effective stress/current effective stress.
gc, gl, gs position along the pile shaft at which yielding occurs for piles in overconsolidated clay, normally consolidated clay, and sand respectively (m). n number of piles in the group.
Table 2:
Values of dI and Ks for Pile Shafts Paragraphs 4.1.1 and 4.1.4 b) and c)
dI
Pile material
20 3f /4
I I
2f /3
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vertical stress in the soil at a depth equal to the base of the pile shaft, total stress for undrained analysis and effective stress for drained analysis (kPa). undrained shear strength (kPa). strength reduction factor for pile strength (for both vertical and lateral strength) (see Paragraph 4.7.1). adhesion factor (see Figure 5). unit weight of the soil in which the pile is embedded, chosen to give the total stresses for undrained loading in cohesive soil and effective stresses for drained loading (gI beneath the water table) (kN/m3). g when the water table is deeper than 2B beneath the underside of the foundation and gI when the water table is above this. drained angle of shearing resistance at the soil/shaft interface (see Table 2) (degrees). angle of shearing resistance (degrees). effective stress angle of shearing resistance (degrees). rate of increase in undrained shear strength with depth (kPa/m).
Vbu = (9cI + qI Nq + 0.6 Db GNg) Ab The values of Nq are taken from Figure 4 and Ng from Figure 3. 4.1.4 Shaft resistance a) For undrained loading of piles in cohesive soils: Vsu = (ca)average CL where ca = su and values for are given in Figure 5 for both driven and bored piles. b) For drained loading of piles in cohesive soils: Vsu = {(cI a)average + (s I vKotandI )average} CL The value of dI is taken from Table 2. c) For drained loading of driven piles in cohesionless soils: Vsu = (s I vKstandI )average CL Values for Ks are given in Table 2.
su Fpc
dI
f fI x
4.2
Column action
4.2.1 Piles which stand unbraced in ground, water, or other material incapable of providing lateral support, shall be designed as columns. 4.2.2 For a column partly embedded in the ground, the effective length is dependent upon the position of end restraint, which in turn is dependent upon the nature of the ground. End restraint shall be assumed at a depth of no less than: a) 3 times the nominal pile width in very stiff soil. (For clays an undrained shear strength greater than or equal to 100 kPa, and for sands a relative density greater than or equal to 50% shall be regarded as very stiff soil.) b) 6 times the nominal pile width in firm soil. (For clays an undrained shear strength between 50 and 100 kPa, and for sands a relative density between 30 and 50% shall be regarded as stiff soil.) c) 9 times the nominal pile width in other soil conditions.
( )average the average value of the parameter in the brackets taken over the length of the pile shaft. 4.1.2 Vertical strength The vertical pile strength is: Vu = Vsu + Vbu 4.1.3 Base resistance The undrained base resistance of piles in cohesive soil is: Vbu = (9su + q) A b The drained base resistance, when the soil is sufficiently uniform to be represented by single values of cI , fI , su and g for a distance of three pile shaft diameters above and below the pile base, shall be:
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Figure 4:
Figure 5:
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4.3
Hu = 9suDs
____________ __ ____________
4.3.1 In the following paragraphs the terms free head and restrained head pile are used. Free head piles are classified as short and long. Restrained head piles are classified as short, intermediate and long. These terms are explained as follows: a) A free head pile has no restriction against head rotation when lateral displacement occurs. For a short free head pile the magnitude of the maximum bending moment in the embedded shaft is less than the ultimate moment strength of the pile shaft, and the ultimate strength is controlled by the embedment length of the pile shaft. The strength of a long free head pile is controlled by the ultimate moment strength of the pile shaft and not by the embedded length. b) For a restrained head pile subject to lateral displacement, the head rotation is constrained at the pile head by a fixing moment. A short pile is one in which the head moment and the maximum pile shaft moment are less than the ultimate moment strength of the pile section. For an intermediate length restrained head pile the head moment is equal to the ultimate strength of the pile shaft and elsewhere the shaft moments are less than Mult. For a long restrained head pile the head moment and the maximum pile shaft moment each have a magnitude of Mult. 4.3.2 Undrained lateral strength of piles in cohesive soil having a constant undrained shear strength with depth a) Free head piles i) short free head piles The ultimate lateral strength of a short free head pile is given by:
The location, measured from the ground surface, of the maximum pile shaft moment is: Hu gc = _______ + fo 9suDs The maximum moment in the pile shaft is: Hu Mmax = Hu f + fo + _______ 18suDs
If Mmax is greater than Mult the strength must be evaluated as for a long free head pile. ii) long free head piles The ultimate lateral strength of a long free head pile ______________ Hu = 3suDs 2Mult 9(f + fo)2 + _____ 3(f + fo) suDs
The location of the maximum pile shaft moment (Mult) is obtained from the same equation as for the short pile. b) Restrained head piles i) short restrained head piles The ultimate lateral strength of a short restrained head pile is: Hu = 9suDs (L fo) The pile head moment is: Mmax = 0.5Hu (L + 2f + fo) If Mmax is greater than Mult then the intermediate length case, ii) below, is appropriate.
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ii) intermediate restrained head piles The ultimate lateral strength of an intermediate length restrained head pile is: 4Mult (L + 2f + fo)2 + (L fo)2 + ____ 9suDs (L + 2f + fo)] The location, measured from the ground surface, of the maximum pile shaft moment is: Hu gc = + fo 9suDs The pile shaft moment at this depth is: Hu Mmax = Hu _______ + f + fo Mult 18suDs If Mmax calculated from this equation is greater than Mult then the long case, iii) below, is appropriate. iii) long restrained head piles The ultimate lateral strength of a long restrained head pile is: 4Mult ____ 9suDs
The rate of increase in undrained shear strength with depth is denoted by x (kPa/m). a) Long free head pile The ultimate lateral strength of a long free head pile is obtained by solving: 2 Hu _ 3 2Hu ___ + f M = 0 ult 9Dsx
Hu = 9suDs
The location, measured from the ground surface, of the maximum pile shaft moment (Mult) is: gI = 2Hu ____ 9Dsx
b) Restrained head pile i) intermediate restrained head piles The ultimate lateral strength of an intermediate length restrained head pile is: 3DsL x Mult Hu = _______ + ____ 2(f + L) f+L The location of the maximum pile shaft moment (Mult) is obtained from the same equation as for the long free head pile. The pile shaft moment at this depth is: 2 Mmax = Hu __ 3 2Hu _____ + f M ult 9Dsx
3
Hu = 9suDs
(f + fo)2 +
(f + fo)
The location of the maximum pile shaft (Mult) is obtained from the same equation as for the intermediate length pile. 4.3.3 Undrained lateral strength of piles in normally consolidated cohesive soil Normally consolidated cohesive soils have a linear increase in undrained shear strength with depth, starting with a value of zero at ground surface level.
COMMENT: Only the long free head pile and intermediate and long restrained head piles are considered. Short piles are not normally used in such material.
If Mmax calculated from this equation is greater than Mult then the long case, ii) below, is appropriate. ii) long restrained head piles The ultimate lateral strength of a long restrained head pile is obtained by solving:
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b) Restrained head piles __ Hu 2 3 2Hu ______ + f 2M = 0 ult 9Dsx i) short restrained head piles The ultimate lateral strength of a short restrained head pile is: Hu = 1.5KpDsL2g The magnitude of the maximum pile head moment is:
The location of the maximum pile shaft moment is obtained from the same equation as for the long free head pile. 4.3.4 Drained lateral strength of piles in cohesionless soil a) Free head piles i) short free head piles The ultimate lateral strength of a short free head pile is:
3
2 Mmax = Hu _ L + f 3
( )
If Mmax is greater than Mult then the intermediate length case, ii) below, is appropriate. ii) intermediate restrained head piles The ultimate lateral strength of an intermediate length restrained head pile is:
3
KpDsL g Hu = ________ 2(f + L) The location, measured from the ground surface, of the maximum pile shaft moment is: 2Hu ______ 3KpgDs
gs =
The location, measured from the ground surface, of the maximum pile shaft moment is:
Mmax
_ = Hu 2 3
gs =
ii) long free head piles The ultimate lateral strength of a long free head pile is obtained by solving the following equation: 2 Hu _ 3 2Hu _______ + f M = 0 ult 3KpDsg
2 Mmax = Hu _ 3
The location of the maximum pile shaft moment (Mult) is obtained from the same equation as for the short pile.
If Mmax calculated from this equation is greater than Mult then the long case, iii) below, is appropriate.
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iii) long restrained head piles The ultimate lateral strength of a long restrained head pile is obtained by solving: 2 Hu __ 3 2Hu ______ + f 2M = 0 ult 3KpDsg
4.6
The location of the maximum pile shaft moment is obtained from the same equation as is used for the intermediate length case.
4.6.1 If piles are spaced at centre to centre intervals of less than 4.0 times the nominal pile width, the ultimate lateral pile strength shall be reduced. The reduced value shall be calculated as a percentage of the ultimate lateral pile strength for an isolated pile by linear interpolation between the two values given in Table 3.
4.7
4.4
Pile groups
4.4.1 Ultimate vertical strength of pile groups The undrained vertical strength of a pile group considered as a single block in a cohesive soil is: VB = (9su + q) BG LG + 2 (BG + LG) L (ca)average The drained strength of a pile group considered as a single block of soil is given by: VB = (cI + qI Nq + 0.6 BG GNg) BG LG + 2 (BG + LG) L {(cI a)average + (sI v Ko tandI )average } The ultimate vertical strength of the group is determined from: 1 1 1 __ = ____ + ____ 2 2 2 2 n V1 VB VG 4.4.2 If only part of an embedded friction pile length is in satisfactory material, the surface area calculated as providing frictional resistance shall be limited to the surface areas in contact with that material.
4.7.1 Strength reduction factors for design of ultimate vertical and lateral strengths in pile foundations shall be within the range given in Table 4. The designer shall nominate in the design the strength reduction factors chosen along with substantiation as to why the values chosen are considered appropriate. The values chosen shall be to the approval of the territorial authority.
COMMENT: The value of the strength reduction factor used in design will depend on the designers knowledge of the site and the investigations undertaken. As a guide the lower end of the range will generally be appropriate when a limited site investigation is undertaken, average geotechnical properties are used, published correlations are used to obtain design parameters or there will be minimal construction control. The upper end of the range will generally be appropriate when a comprehensive site investigation and laboratory testing is undertaken, geotechnical properties are chosen conservatively, site specific correlations are used for design parameters and there will be careful construction control.
5.0 5.1
4.5
Downdrag
4.5.1 Downdrag may be generated when a pile shaft passes through a compressible soil layer. Downdrag shall be considered as dead load applied to the parts of the pile below the compressible layer. It shall be added to the imposed loadings and factored accordingly.
5.1.1 Precast concrete piles, including prestressed piles, shall withstand without damage or significant cracking, the stresses arising from manufacture, handling and transportation, in addition to those arising from driving and imposed loadings.
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5.1.2 Belled bases of cast-in-situ concrete piles shall be no less than 100 mm thick at the edge of the required base and, unless the bell is reinforced, the conical surfaces shall slope at an angle from the horizontal of no less than 60. 5.2 Steel piles 5.2.1 The design of steel piles shall be based on the nett steel section after deducting an appropriate thickness for future loss by corrosion. This verification method does not describe a means of determining the amount of corrosion and proposals must be submitted to the territorial authority for approval.
COMMENT: The amount deducted needs to take account of the aggressiveness of the soil. Further guidance can be found in AS 2159 Section 6.3 or the HERA Design and Construction Bulletin No 46.
5.2.2 Allowance for corrosion loss need not be made for steel encased in concrete provided cover to the steel is no less than: a) 30 mm for prestressed concrete, b) 50 mm for precast concrete, c) 75 mm for cast-in-situ concrete.
5.3
Timber piles
5.3.1 Timber piles shall comply with NZS 3605 or NZS 3603 as applicable, and be naturally durable or treated to the appropriate hazard level as recommended by NZS 3640. 5.3.1.1 NZS 3605 shall be subject to the following modification: Clause 4.2.4.1 after limitations for add the word verified
Amend 9 Sep 2010
Table 3:
Closely Spaced Piles, Design Lateral Resistance Paragraph 4.6.1 % of isolated pile lateral resistance 100 25
Pile spacing 4.0 x nominal pile width 1.0 x nominal pile width (palisade type wall)
Table 4:
Strength Reduction Factors for Deep Foundation Design Paragraph 4.7.1 Range of values of Fpc 0.65 0.70 0.45 0.40 0.45 0.80 0.85 0.90 0.65 0.55 0.55 0.90
Method of assessment of ultimate geotechnical strength for load combinations not involving earthquake overstrength Static load testing to failure Static proof (not to failure) load testing Static analysis using CPT (Cone Penetrometer Test) data Static analysis using SPT (Standard Penetrometer Test) data in cohesionless soils Static analysis using laboratory data for cohesive soils Method of assessment of ultimate geotechnical strength for load combinations including earthquake overstrength
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Appendix A (Informative)
A1.0 Site Investigation A1.1 General
A1.1.1 No specific site investigation procedures are given in this document. The following information is provided for guidance only. A1.1.2 The ground conditions at the building site should be investigated to the extent considered necessary, by a person with appropriate expertise and experience, to provide essential site data for design of the proposed building. Both preliminary and detailed investigations may need to be undertaken.
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A ppendix B B 1/V M4
Appendix B (Informative)
B1.0 Serviceability Limit State Deformations (Settlement)
B1.0.1 No specific method is given for determining foundation settlement. The following information is provided for guidance only. B1.0.2 Foundation design should limit the probable maximum differential settlement over a horizontal distance of 6 m to no more than 25 mm under serviceability limit state load combinations of AS/NZS 1170 Part 0, unless the structure is specifically designed to prevent damage under a greater settlement. B1.0.3 The basis for analysing settlement should be stated in the design. The analysis shall pay due consideration to: a) Size, shape and depth of the foundations, b) Proximity and influence of proposed and existing foundations, c) Variability of the ground, d) The presence of compressive or expansive materials, e) Rate of consolidation, f) Groundwater level, g) Extent of fill placed and ground removed when constructing the foundation, and h) Likelihood of liquefaction, internal erosion, soil collapse or other special feature.
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Short term analysis (both for the initial static loading of the foundation and the earthquake loading) is performed in terms of total stress and uses the undrained shear strength (su) of the clay whilst the long term analysis is done using effective stresses and uses the strength parameters cI and fI for the clay (see Paragraph 2.0.6). The thrust from the sand backfill is based on effective stresses and is the same for all cases (see Paragraph 2.0.7).
Figure C1:
Wall Details and Soil Properties for the Short Term, Long Term, and Earthquake Loading Cases
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A ppendix C B 1/V M4
C4.0 Notation
The notation in Figure C2 is used to identify the weights and active thrusts on the wall, whilst in Figure C3 the actions on the foundation are shown.
Figure C2:
Ws
Wbf
Pav
Pah = H hpa
Pav Pah
Pa
Wf
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Figure C3:
For static loading: H = P ah_static For EQ loading: H = Pah_EQ + H inertia e X H V R Pp qd B' B (Pp passive soil strength in front of the foundation, if present, contributes to the sliding strength.) (R = q d B') hpa
C5.0 Loadings
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A ppendix C B 1/V M4
Factor EQ active thrusts and find location of resultant: Factored EQ active thrust . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .57.60 x 1 + 10.80 x 1 Take moments about heel to get location of active thrust (m ) hpa_EQ = (38.40/3.0 + 10.80 x 0.5 + 19.20 x 0.6) x 4/68.40 Horizontal component of EQ thrust (kN/m) . . . . . . . . . . . . . . . . Pah_EQ = 68.40 x cos15 Vertical component of EQ thrust (kN/m) . . . . . . . . . . . . . . . . . . Pav_EQ = 68.40 x sin15 = = = = 68.40 1.74 66.07 17.70
Figure C4:
18.55
+
37.09
10.43
P ah_EQ = 66.07
1.74
C5.2 Weights (load factor 1.0) and resultant vertical forces on the wall
Weight of wall stem . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Ws = 3.6 x 0.3 x 25 Weight of wall foundation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Wf = 2.65 x 0.4 x 25 Weight of backfill above the heel of the wall. . . . . . . . . . . . . . . . Wbf = 3.6 x 1.35 x 16 Vertical force from surcharge above heel . . . . . . . . . . . . . . . . . . . . . Wsur = 3.5 x 1.35 Static vertical force on foundation (kN/m) V = V_static = 18.88 + 27.00 + 26.50 + 77.76 + 4.73 EQ vertical force on foundation (kh = 0.2 and kv = 0) (kN/m) V = VEQ = 17.71 + 27.00 + 26.50 + 77.76 + 4.73 = = = = 27.00 26.50 77.76 4.73
= 154.87 = 153.69
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Figure C5:
Weights of the Wall Components, Horizontal 0.20g Inertia Forces and the Location of the Resultant Inertia Force
15.55
H inertia = 27.20kN
26.50
5.30
h inertia = 1.87m
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A ppendix C B 1/V M4
C7.0 First Ultimate Limit State (short term static foundation bearing failure)
Find X (location of V) by taking moments about heel. Moment of the vertical forces: (77.76 x 1.35/2 + 4.73 x 1.35/2 + 27.00 x (1.35 + 0.15) + 26.50 x 2.65/2) = 131.29 X = 131.29/154.87 = 0.848 Eccentricity: e = 70.47 x 1.44/154.87 = 0.655 BI 1 = 2 x (0.848 + 0.655) = 3.01 BI 2 = 2 x (2.65 0.848 0.655) = 2.29 BI is the smaller of BI 1 and BI 2: . BI = 2.29 (Distance from R to foundation edge = BI /2 = 1.15 > B/6 . . ok (Paragraph 3.1.4)) Design bearing pressure: qd = V/BI = 154.87/2.29 = 67.6 kPa Determine ultimate bearing strength qu = sulcslcdlcilcgNc + lqgq For this case f = 0, so Nc = 5.14. lcs shall be taken as 1.0 as foundation is assumed to be long compared to its width. Also lcg = lqg = 1.0 as the foundation is horizontal. Thus we need only to evaluate lcd and lci. lcd = 1 + 0.4 x Df /BI = 1 + 0.4 x 0.4/2.29 = 1.07 lci = 0.5(1 + =(1 H/BI su)) = 0.5 x (1 + =(1 70.47/2.29 x 75)) = 0.88 qu = suNclcdlci + q = 75 x 5.14 x 1.07 x 0.88 + 7.2 = 370.19 qdbs = quFbc = 370.19 x 0.45 = 166.6 qd = 67.6 Thus OK as qdbs > qd
Figure C6:
Wall and Foundation Loads for the First and Second Ultimate Limit States
Vstatic = 154.87 kN
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C8.0 Second Ultimate Limit State (short term static foundation sliding failure)
The design sliding resistance is derived from the shear strength on the base and the passive resistance from the clay in front of the embedded part. Ultimate shear strength: Passive resistance: Design sliding resistance: S = su BI = 75 x 2.29 = 171.75 Pp = 2 su Tf + 0.5 gclayTf2 where Tf is the foundation thickness = 2 x 75 x 0.4 + 0.5 x 18 x 0.42 = 61.44 SFsl + PpFpp = 171.75 x 0.8 + 61.44 x 0.45 = 165.1 H = 70.5 Thus OK as SFsl + PpFpp > H
C9.0 Third Ultimate Limit State (short term foundation bearing failure under EQ)
Find X (location of V) by taking moments of vertical forces about heel. Moment, as for the first ultimate limit state = 131.29 X = 131.29/153.69 = 0.854 To get eccentricity we need to add the moment of the horizontal inertia forces to that of the lateral thrust from the backfill: e B1 BI 2
I
= (66.07 x 1.74 + 27.20 x 1.87)/153.69 = 1.079 = 2 x (0.854 + 1.079) = 3.87 = 2 x (2.65 0.854 1.079) = 1.43 . = 1.43 (Distance from R to foundation edge = BI /2 = 0.72 > B/6 . . ok (Paragraph 3.1.4)
BI is the smaller of BI 1 and BI 2: BI Design bearing pressure: qd = V/BI = 153.69/1.43 = 107.46 kPa
Figure C7:
Wall and Foundation Loads for the Third and Fourth Ultimate Limit States
e 1.079
VEQ = 153.69 kN Pah_EQ = 66.07 kN h inertia = 1.87m Hinertia = 27.20 kN h pa_EQ = 1.74m
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A ppendix C B 1/V M4
Determine ultimate bearing strength: For this case f = 0, so Nc = 5.14. lcs shall be taken as 1.0 as foundation is assumed to be long compared to its width. Also lcg = lqg = 1.0 as the foundation is horizontal. Thus we need only to evaluate lcd and lci. lcd lci qu
dbs
= 1 + 0.4 x Df/BI = 1 + 0.4 x 0.4/1.43 = 1.11 = 0.5(1 + (1 H/BI su)) = 0.5 x (1 + (1 93.29/1.43 x 75)) = 0.68 = suNclcdlci + q = 75 x 5.14 x 1.11 x 0.68 + 7.2 = 298.17 = quFbc = 298.17 x 0.45 = 134.2 qd = 107.5 Thus OK as qdbs > qd
C10.0 Fourth Ultimate Limit State (short term foundation sliding failure under EQ)
The design sliding resistance is derived from the shear strength on the base and the passive resistance from the clay in front of the embedded part. Ultimate shear strength: Passive resistance: Design sliding resistance: S = su BI = 75 x 1.43 = 107.25 Pp = 2 su Tf + 0.5 gclayTf2 = 2 x 75 x 0.4 + 0.5 x 18 x 0.42 = 61.44 SF sl + PpF pp = 107.25 x 0.8 + 61.44 x 0.45 = 113.5 H = 93.3 Thus OK as SF sl + PpF pp > H
C11.0 Fifth Ultimate Limit State (long term foundation bearing failure)
For this case we work in terms of effective stress. The strength parameters for the clay become: cI = 12.5 kPa and fI = 25 . Furthermore the water table is at the ground surface in front of the wall so the buoyant density (18 9.81 = 8.2 kN/m3) controls the effective stresses.
o
Figure C8:
Wall and Foundation Loads for the Fifth and Sixth Ultimate Llimit States
e 0.703
Vdrained = 144.48 kN
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In addition there is a small positive water pressure acting on the underside of the wall which reduces the vertical load applied to the foundation. u = 0.4 x 9.81 = 3.92 and Vdrained = 154.87 3.92 x 2.65 = 144.48 This has the effect of changing slightly X and e, hence BI and qd. We have from the first ultimate limit state the moment about the heel of the wall of the vertical forces = 131.29 kNm per metre length of the wall, so: X = (131.29 3.92 x 2.65 x 2.65/2)/144.48 = 0.813 Eccentricity of load:
I
B = 2 x (2.65 0.813 0.703) = 2.27 Design bearing pressure: qd = Vdrained /BI = 144.5/2.27 = 63.7 kPa o For f equal to 25 the bearing capacity factors are: Nc = 21, Nq = 11 and Ng = 9. Determine ultimate bearing strength: qu_drained = cI lcslcdlci lcgNc + qI lqslqdlqilqgNq + 0.5BI gI lgslgdlgilggNg Shape factors lcs, lqs and lgs shall be taken as 1.0 as foundation is assumed to be long compared to its width. Also ground inclination factors lcg,lqg and lgg = 1.0 as the foundation is horizontal. Thus we need only to evaluate depth and load inclination factors. Depth factors: lqd lcd lgd = 1 + 2tanfI (1 sinfI )2(Df /B) = 1 + 2tan(25)(1 sin(25))2(0.4/2.27) = 1.05 = lqd (1 lqd)/NqtanfI = 1.05 (1 1.05)/11tan(25) = 1.04 =1 = (1 0.7H/(Vdrained + cI BI cotfI ))3 = (1 0.7 x 70.47/(144.48 + 12.5 x 2.27 x cot(25)))3 = 0.46 = (lqiNq 1)/(Nq 1) = 0.40 = (1 H/(Vdrained + cI BI cotfI ))3 = (1 70.47/(144.48 + 12.5 x 2.27 x cot(25)))3 = 0.28 = cI Nclcdlci + qI Nqlqdlqi + 0.5BI gI Nglgdlgi = 12.5 x 21 x 1.04 x 0.40 + 3.3 x 11 x 1.05 x 0.46 + 0.5 x 9 x 2.27 x 8.2 x 1 x 0.31 = 152.70 qdbs_drained = qu_drainedFbc = 152.70 x 0.45 = 68.7 qd = 63.7 Thus OK as qdbs_drained > q d
C12.0 Sixth Ultimate Limit State (long term foundation sliding failure)
The design sliding strength is derived from the sliding resistance on the base and the passive resistance from the clay in front of the embedded part. Sliding resistance: Passive resistance: Sdrained = cI BI + VdrainedtanfI = 12.5 x 2.27 + 144.48 x tan(25) = 95.75 Pp_drained = 0.5KpgI Tf2 + 2cI Tf Kp = 0.5 x 3.5 x 8.2 x 0.42 + 2 x 12.5 x 0.4 x H = 70.5 3.5 = 21.00
Design sliding strength: SFsl + PpFpp = 95.75 x 0.8 + 21.00 x 0.45 = 86.05 Thus OK as SFsl + PpFpp > H
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A ppendix C B 1/V M4
C13.0 Comments
The above calculations reveal that, for static loading, it is the long term case that is critical. Also for the short term cases the sliding strength derived from passive earth pressure in front of the embedded foundation is significant. If the horizontal earthquake acceleration is increased much above 0.2g the third ultimate limit state becomes the limiting case as bearing failure is initiated. However, as explained in clauses 4.11.2.4 and C4.11.2.4 of NZS 4402: 1992, controlled sliding and tilting of the foundation during the passage of an earthquake is possible if the resulting post-earthquake permanent displacements are acceptable. The procedures and criteria for this approach are beyond the scope of this document.
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(Revised by Amendment 4)
All references to Verification Methods and Acceptable Solutions are preceded by VM or AS respectively.
Buildings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.9.2, 1.9.4 building elements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 2.0.3 earth buildings. . . . . . . . . . . . . . . . . . . . . . . . . . . . .VM1 8.0, AS1 4.0 masonry buildings . . . . . . . . . . . . . . . . . . . . . . . . .AS1 2.0, AS3 1.1.1 timber framed buildings . . . . . . . . . . . . . . . . . . . .AS1 3.0, AS3 1.1.1
Chimneys. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .AS1 1.2, 8.0, AS3 2.1 bracing units . . . . . . . . . . . . . . . . . . . . . AS3 1.9, 1.9.3, 1.9.6, Table 2 brick chimneys . . . . . . . AS3 1.1, 1.1.3 a) b), 1.2.1 a), 1.6.2 a), 1.7.1, 1.7.6, 1.8.1, 1.8.5 a), Figures 2, 3, 4, 7, Table 1 cantilever height . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.1.2 chimney bases . . . . . . . . . . . . . . . . . . . . AS3 1.1.3 a), 1.6.1, 1.9.4 b) chimney breasts . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.5, Table 1 chimney depth . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.1.3 chimney height . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.1.2 chimney liners . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.1.4 chimney lintels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .AS3 Table 1 chimney materials . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.8 chimney stacks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.1.2, 1.6.1 chimney wall thicknesses . . . . . . . . . . . . . . . . . . . . . . . AS3 1.2, 1.2.1 chimney width. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.1.3 concrete chimneys . . . . . . . . . . . . . AS3 1.1.1, 1.1.3 a) c), 1.2.1 b) c), . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1.6.2 a) b), 1.7.1, 1.7.13, 1.8.2, . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.8.5 b), Figures 4, 5, Table 1 concrete masonry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.8.4 floor brackets . .AS3 1.7.1, 1.7.3, 1.7.4, 1.7.5, 1.8.4, 1.9.4 b) c), Figure 6 foundations . . . . . . . . . . . . . . . . AS3 1.1.2, 1.1.3 a), 1.3, 1.3.1, 1.3.2, 1.3.3, 1.7.4, 1.7.5, 1.8.4, Figure 1 foundation slabs. . . . . . . . . . . . . . . . AS3 1.1.2, 1.3.2, 1.7.4, 1.7.5 gathers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.6.1, 1.6.2, 1.7.5 packers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.7.2, 1.7.6 c) precast pumice concrete chimneys . . . . . . . . . AS3 1.1.1, 1.1.3 a) c), 1.2.1 c), 1.6.2 b), 1.7.1, 1.7.13, 1.8.3, 1.8.3 c), 1.8.5 c), Figures 5, 7, Table 1 compressive strength . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.8.3 c) construction of . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.8.3 restraint . . . . . . . . . . . . . . . . . . . . AS3 1.7, 1.7.1, 1.7.13, Figures 6, 7 roof brackets . . . . . . . . . . . . . . . . . . .AS3 1.7.1, 1.7.3, 1.7.4, Figure 6 roof ties . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.7.5 structural diaphragms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.9.5
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Chimneys (continued) wall ties . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.7.5, 1.7.7, 1.7.8 closely spaced wall ties . . . . . . . . . . . . . . . . . . . AS3 1.7.5, 1.9.4 c) Concealed works . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .VM4 A1.2.1 b) Concrete . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . see Design, concrete Design aluminium . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM1 7.0 concrete . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM1 3.0 concrete masonry . . . . . . . . . . . . . . . . .VM1 4.0, AS1 2.0, AS3 1.3.3 drains. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . see Drains earth building. . . . . . . . . . . . . . . . . . . . . . . . . . . . . .VM1 8.0, AS1 4.0 foundations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . see Foundations loadings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM1 2.0 earthquake . . . . . . . . . . . VM1 1.0, 2.0, AS1 1.4, AS3 1.9, Table 2 limit state . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM1 2.0, 7.1
siteworks. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM1 10.0 steel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM1 5.0 strength reduction factor. . . . . . . . .VM4 2.0.1, 3.5.1, 4.7, Tables 1, 4 structural design actions Standards . . . . . . . . . . . . . . . . . . . VM1 2.0 timber . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .VM1 6.0, AS1 3.0 windows . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . see Windows Drains. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .VM1 11.0, AS1 6.0 Earth retaining structures . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 2.0.3
Foundations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM1 9.0, VM4 design parameters continuous vibration. . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 1.0.6 depth . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 2.0.4 ground stability. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 1.0.4 long-term loading . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 2.0.6 short-term loading . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 2.0.6 serviceability deformations . . . . . . . . . . . VM4 1.0.3, Appendix B
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Foundations (continued) pile foundations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 4.0 belled piles . . . . . . . . . . . . . . . . . . . . . . . . . . . .VM4 4.0.3 b), 5.1.2 bulbed piles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 4.0.3 c) concrete piles cast-in-situ. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 3.4.4 precast . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 3.4.4, 5.1.1 downdrag . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 4.5 nominal width . . . . . . . . . . . . . . . . . . . . . . . VM4 4.0.3, 4.2, 4.6.1 notation . . . . . . . . . . . . . . . . . . . . . . VM4 4.1.1, Figure 5, Table 2 pile driving . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 5.1.1 pile driving formula . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 4.0.1 pile groups design pile lateral strength . . . . . . . . . . . . . . . . . . . . VM4 4.0.4 design pile vertical strength . . . . . . . . . . . . . . . . . . . VM4 4.0.4 ultimate lateral strength . . . . . . . . . . . . . . . VM4 4.6.1, Table 3 ultimate vertical strength . . . . . . . . . . . . . . . . . . . . . VM4 4.4.1 single piles base resistance. . . . . . . . . . . . . . . . . . VM4 4.1.3, Figures 3, 4 column action design . . . . . . . . . . . . . . . . . . . . . . . . . VM4 4.2 design pile vertical strength . . . . . . . . . . . . . . . . . . . VM4 4.0.4 design pile lateral strength . . . . . . . . . . . . . . . . . . . . VM4 4.0.4 lateral strength . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 4.3 drained cohesionless soil . . . . . . . . . . . . . . . . . . VM4 4.3.4 free head pile. . . . . . . . . . . . VM4 4.3.2 a), 4.3.3 a), 4.3.4 a) restrained head pile . . . . . . .VM4 4.3.2 b), 4.3.3 b), 4.3.4 b) undrained cohesive soil . . . . . . . . . . . . . . . . . . . . VM4 4.3.2 undrained consolidated soil . . . . . . . . . . . . . . . . . VM4 4.3.3 shaft resistance . . . . . . . . . . . . . VM4 4.1.4, Figure 5, Table 2 ultimate axial compression . . . . . . . . . .VM4 4.0.1, 4.0.2, 4.0.3 vertical strength . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 4.1.2 strength reduction factors . . . . . . . . . . . . . . . . . .VM4 4.7, Table 4 types concrete . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 5.1.1, 5.1.2 steel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 5.2.1, 5.2.2 timber . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 5.3 shallow foundations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 3.0 concrete slab-on-ground . . . . . . . . . . . AS1 2.1, 3.1, 4.1, AS3 1.3 design bearing pressure . . . . . . . . . . . . . . . . . . . VM4 3.2.1, 3.2.4 design bearing strength . . . . . . . . . . . . . . . . . . . . . . . . . VM4 3.2.3 design sliding resistance . . . . . . . . . . . . . . . . . . . . . . . . VM4 3.4.6 local shear . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 3.3.3 moment loading . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 3.1.4 notation . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 3.3.1, Figures 1, 2 soils . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 3.1.2, 3.4.3 strength reduction factors . . . . . . . . . . . . . . . . . .VM4 3.5, Table 1 surcharge . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 3.1.3 ultimate bearing strength. . . . . . VM4 3.1.1, 3.2.2, 3.3.2, Figure 3 ultimate sliding resistance . . . . . . . . . . . . . . . . . . . . . . . VM4 3.4.2 ultimate sliding strength . . . . . . . . . . . . . . . . . . . VM4 3.4.4, 3.4.5 see also Chimneys, foundations
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Ground good ground . . . . . . . . . . . . . . . . . . . . . .AS1 2.1, 3.1, 4.1, AS3 1.3.2 Ground conditions . . . . . . . . . . . . . . . . . . . . . . VM4 1.0.2, Appendix A Ground water . . . . . . . . . . . . . . . . . . . . . . VM4 1.0.2, Appendices A, B conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 1.0.2 seasonal changes . . . . . . . . . . . . . . . . . . . . . . . . . . . . .VM4 A1.2.1 e) tidal changes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .VM4 A1.2.1 e) Hearths . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.4, 2.2, 2.2.1, 2.2.2, 2.2.3 hearth slabs. . . . . . . . . . . . . . . . . . . . . . . .AS3 2.2, 2.2.1, 2.2.2, 2.2.3
Hot dip galvanising . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.8.6 Landslip . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .VM4 A1.2.1 a) Loadings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .see Design, loadings
Masonry. . . . . . . . . . . . . . . . . . . . . . . . . . see Design, concrete masonry Materials . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS3 1.8 chimneys. . . . . . . . . . . . . . . . . . . . . see Chimneys, chimney material Standards . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM1 1.0 Piles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . see Foundations
Reinforcing steel. . . . . . . AS1 2.1, 3.1, AS3 1.3.2 b) c), 1.4, 1.6, 1.6.1, 1.6.2, 1.8.5, 2.2.1 a), Table 1 Seismic resistance of engineering systems . . . . . . . . . . . . VM1 13.0 Settlement . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 4.0.3, Appendix B differential settlement. . . . . . . . . . . . . . . . . . . . . . . . . . . .VM4 B1.0.2 factors affecting settlement . . . . . . . . . . . . . . . . . . . . . . .VM4 B1.0.3 Site characteristics. . . . . . . . . . . . . . . . . . . . . . . . . . . .VM4 Appendix A Site investigations . . . . . . . . . . . . . . . . . VM4 3.5.1, 4.7.1, Appendix A detailed investigations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 A1.3 preliminary investigations . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 A1.2 recording information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 A1.4 Siteworks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . see Design, siteworks Slope stability. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM4 1.0.4 Small chimneys . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . see Chimneys Soil properties . . . . . . . . . . . . . . . VM4 1.0.5, 2.0.6, 2.0.7, Appendix A Soil shrinkage and expansion. . . . . . . . . . .VM4 3.1.2, 3.4.3, A1.2.1 a) Soils adverse moisture conditions . . . . . . . . . . . . . . . . . . . . . . . . VM4 1.0.2
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Solid fuel burning domestic appliances. . . . . . . . . . . . . . . . . . AS3 2.0 Steel. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . see Design, steel Stucco . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS1 5.0 Subsidence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .VM4 A1.2.1 a) Timber . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . see Design, timber Timber barriers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AS2 1.0
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