BS ISO 15686-4:2014
Current
The latest, up-to-date edition.
Building Construction. Service Life Planning Service Life Planning using Building Information Modelling
Hardcopy , PDF
English
31-01-2014
Foreword
Introduction
1 Scope
2 Normative references
3 Terms and definitions
4 Product definition
5 Product specification and selection
6 Product reference service life
7 Product estimated service life
8 Product impacts
9 Representation of uncertainty
Annex A (normative) - Property set template for
service life
Annex B (normative) - Property set template for
service life context
Annex C (normative) - Property set template for
environmental impact values
Annex D (informative) - Example using data from
Clauses 6 to 9
Bibliography
Gives information and guidance on the use of standards for information exchange for service life planning of buildings and constructed assets and their components as well as the required supporting data.
Committee |
CB/101
|
DevelopmentNote |
Supersedes 13/30278421 DC. (01/2014)
|
DocumentType |
Standard
|
Pages |
46
|
PublisherName |
British Standards Institution
|
Status |
Current
|
Supersedes |
This part of ISO15686 provides information and guidance on the use of standards for information exchange for service life planning of buildings and constructed assets and their components as well as the required supporting data. It provides guidance on structuring information from existing data sources to enable delivery of their information content in a structure that conforms to international standards for information exchange. In particular, reference is made to ISO16739. The Construction Operations Building Information Exchange (COBie) standard for the exchange of facility information in tabular data are used as an alternative representation. COBie is a tabular representation of a handover view of the IFC schema. It is also applicable to the exchange of service life information between categories of design and information management software applications that have standards-based information exchange interfaces including: Building construction Information Modelling (BIM); Computer Aided Facilities Management (CAFM). Excluded from this part of the standard are information exchange using proprietary methods, and processing and analysis of data within individual software applications, though examples are provided. The main target audience is the Information manager who will use the framework to assist in structuring the International, national or project/facility level BIM guidance document. This Standard specifies the structure and representation of service life data. It is focused on key exchange requirements underlying the common transactions. This document may be used for a variety of purposes to achieve and maintain a common understanding within the national and project contexts; to establish the desired outcomes and to define appropriate quality; to identify appropriate management effort and tools; to identify necessary effort and resourcing. Service life planning involves the application of data about elements within a building or constructed assets to enable their design, predicted or estimated service life to be determined and communicated. Buildings are increasingly designed using Building Information Modelling (BIM), an approach that can provide a specification of all the objects in building and how they are aggregated into parts, assemblies and systems. An architect or engineer can define the objects using BIM; it is anticipated that the actor having the service life planning role will apply service life data to these objects and make the data available for other purposes through the use of data exchange standards. Using information exchange standards to describe the structure of service life planning information is important because it normalizes the way in which service life information should be delivered from source to user so that relevant different attributes can be exchanged and a range of software applications can be used to capture the information. 1.1 Process map The process map (see Figure1) shows the key sequence of information exchanges and places the information exchanges in context, identifying the sending and receiving roles. It is based on the process map for design given in ISO15686-1:2011, AnnexB, and the management plan given in ISO15686-3. In summary, ISO15686-2, ISO15686-8, ISO15686-5 and ISO15686-7 define four processes which use service life data. ISO15686-2 (Testing):Product and testing are brought together to obtain the service life characteristics. ISO15686-8 (Prediction):The characteristics are brought into a specific context to obtain a predicted service life. ISO15686-5 (Costing):The predicted or measured service life is used with cost or environmental impact rates to obtain a life cycle cost or assessment. ISO15686-7 (In-use inspection):The context factors are revised to reflect in-use surveys. Figure1 Exchange requirements detailed in this part and their relationship to other parts The process map document covers the determining of the service life of a type of product (during early design stages) and of occurrences of products of a particular type (during later design stages, construction and operation/maintenance). NOTE The data requirements for ISO15686-7 (In-Use inspection)are used in Clause7 and AnnexB. 1.2 Data requirements The determination of service life is undertaken at various times during the design, construction and operation of a project. During the early design stages when product information is aggregated a level such as the whole building or as specifications of whole systems; it is only the design life of a product that can be determined. At the earliest design stages when only product occurrences are defined, design life is estimated at the occurrence level. At later design stages, when individual products are located and these products are designated by type, design life can be indicated for all occurrences at the type level. Similarly, when individual products are identified, it becomes possible to determine a reference service life when a manufacturer/supplier can be identified. As with design life, reference service life can be allocated to the product type level. At later design stages and during construction, when the configuration and location of products has been fully established, it becomes possible to analyse the service life of products according to ‘in use’ conditions. These conditions can vary the reference service life depending on factors such as exposure to weather, aggressiveness of the local environment and other degrading (or upgrading) factors. The result of applying in-use conditions is to define an estimated service life which is simply the length of time of a product occurrence lifecycle. Finally, the condition of a product occurrence can be checked from time to time during the operational stage. From the condition of the product, a residual service life can be assessed. If degradation is more than has been expected, the residual service life is reduced to less than the value that might have been expected from the estimated service life. The overall data requirements for the process are summarized in Figure2. Figure2 The ‘service life planning view’ Clause4 of this part of ISO15686 defines the data requirements to identify the product. Clause5 suggests the data required for the specification/selection of product. Clause6 adds the testing regimen and the key service life metrics. Clause7 adds the context and the predicated estimated service life. Clause8 adds the impacts (to date and predicted) for stages in the life cycle value. Clause9 suggests a representation where uncertainty and ranges of values are relevant. AnnexA provides a formal representation for Service Life definition. AnnexB provides a formal representation for Service Life factors. AnnexC provides a formal representation for Environmental and Economic Impact measures. AnnexD offers example calculations. 1.3 IFC support for service life planning IFC contains support for a wide range of building and construction topics. The information needed for service life planning and related topics is supported by specific objects (entity types) in the schema (e.g. an object handling functional measures\'), but also as general objects handling the technical performance of building components and systems, property information (e.g. material) about the building components, information about needed measures of care and maintenance etc. There are several concepts captured in the IFC schema that are relevant to service life planning and that can be applied in a specific subset (view) of the IFC schema about service life planning. These include the following. See Table1. Table1 Concepts in IFC relevant to service life and impact assessment Ideas in the IFC schema Purpose Service lifeService life factors Can be applied to any physical object either as a single occurrence or an aggregation or assembly of physical objects acting as a single object. A service life can have one or more related service life factors according to the ISO15686 factor method.The term ‘physical object is used here to identify the difference between an object that has physical existence as opposed to an abstract object such as a cost or constraint. Material A material definition can be related to a physical object Impact One or many economic or environmental impacts can be associated with physical product or process objects. Impacts are associated to specific stages in the life cycle. Condition The current condition of physical objects can be determined by applying one or more condition criteria. Condition can be determined using either subjective assessment (e.g. condition on a scale from 1 to 10 where 10 is good and 1 is bad) or by objective assessment using measured values. Quantity sets IFC has a capability to associate measured quantities (for example count, distance or weight measures) to an object where it is not possible to measure that quantity from the representation used or were there are specific national rules that need to be applied for quantity measurement. Property sets Properties are additional attributes that can be defined and captured in an IFC model. Properties are typically grouped into named collections called property sets. Property sets can be used as a basis for storing external data or for delivering data from an external data source.
Standards | Relationship |
ISO 15686-4:2014 | Identical |
14/30294759 DC : 0 | BS 8541-6 - LIBRARY OBJECTS FOR ARCHITECTURE, ENGINEERING AND CONSTRUCTION - PART 6: PRODUCT AND FACILITY DECLARATIONS - CODE OF PRACTICE |
BS 8541-6:2015 | Library objects for architecture, engineering and construction Product and facility declarations. Code of practice |
BS PAS 1192-5(2015) : 2015 | SPECIFICATION FOR SECURITY-MINDED BUILDING INFORMATION MODELLING, DIGITAL BUILT ENVIRONMENTS AND SMART ASSET MANAGEMENT |
ISO 15686-8:2008 | Buildings and constructed assets — Service-life planning — Part 8: Reference service life and service-life estimation |
ISO 29481-1:2016 | Building information models — Information delivery manual — Part 1: Methodology and format |
ISO 15686-5:2017 | Buildings and constructed assets — Service life planning — Part 5: Life-cycle costing |
ISO 16739:2013 | Industry Foundation Classes (IFC) for data sharing in the construction and facility management industries |
ISO 21929-1:2011 | Sustainability in building construction — Sustainability indicators — Part 1: Framework for the development of indicators and a core set of indicators for buildings |
ISO 12006-3:2007 | Building construction — Organization of information about construction works — Part 3: Framework for object-oriented information |
ISO 10303-28:2007 | Industrial automation systems and integration — Product data representation and exchange — Part 28: Implementation methods: XML representations of EXPRESS schemas and data, using XML schemas |
ISO 14024:1999 | Environmental labels and declarations Type I environmental labelling Principles and procedures |
EN 15804:2012 | Sustainability of construction works - Environmental product declarations - Core rules for the product category of construction products |
ISO 14021:2016 | Environmental labels and declarations — Self-declared environmental claims (Type II environmental labelling) |
ISO 15686-2:2012 | Buildings and constructed assets — Service life planning — Part 2: Service life prediction procedures |
ISO 15686-7:2017 | Buildings and constructed assets — Service life planning — Part 7: Performance evaluation for feedback of service life data from practice |
ISO 21930:2017 | Sustainability in buildings and civil engineering works — Core rules for environmental product declarations of construction products and services |
ISO 10303-11:2004 | Industrial automation systems and integration — Product data representation and exchange — Part 11: Description methods: The EXPRESS language reference manual |
ISO 14044:2006 | Environmental management Life cycle assessment Requirements and guidelines |
EN 15942:2011 | Sustainability of construction works - Environmental product declarations - Communication format business-to-business |
ISO 6241:1984 | Performance standards in building Principles for their preparation and factors to be considered |
ISO 14020:2000 | Environmental labels and declarations — General principles |
ISO 15686-1:2011 | Buildings and constructed assets — Service life planning — Part 1: General principles and framework |
ISO 10303-21:2002 | Industrial automation systems and integration Product data representation and exchange Part 21: Implementation methods: Clear text encoding of the exchange structure |
ISO 14025:2006 | Environmental labels and declarations — Type III environmental declarations — Principles and procedures |
ISO 21931-1:2010 | Sustainability in building construction Framework for methods of assessment of the environmental performance of construction works Part 1: Buildings |
ISO 14040:2006 | Environmental management Life cycle assessment Principles and framework |
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