BS 5250:2021
$215.11
Management of moisture in buildings. Code of practice
| Published By | Publication Date | Number of Pages |
| BSI | 2021 | 178 |
This British Standard gives recommendations for the management of moisture in buildings using an integrated and pragmatic approach. This includes the management of moisture risk from interstitial and surface condensation, from too high or too low internal relative humidity, and from rain penetration or high levels of ground water. It covers all states of water as gas, liquid and solid, and the interactions between these states. It describes the principal sources of moisture in buildings, its transportation and deposition and provides recommendations and guidance on how to manage those risks during the assessment, design, construction and operation of buildings.
This British Standard does not cover measures specifically dealing with flooding and escape of water. These are dealt with in BS 85500.
This British Standard is intended for use by designers, builders and users of any class of building. This standard gives guidance on risks of all sorts from high moisture levels, whether in the building fabric or in indoor air, which can endanger the health and well‑being of building occupants and the integrity of the building fabric.
This British Standard is relevant to buildings of all types, whatever their form, construction and occupancy, both new and existing, and both domestic and non-domestic, except for buildings used for storage at sub-zero temperatures.
PDF Catalog
| PDF Pages | PDF Title |
|---|---|
| 7 | Foreword |
| 9 | Introduction |
| 12 | Section 1: General 1 Scope 2 Normative references |
| 13 | 3 Terms, definitions and abbreviated terms 3.1 Terms and definitions |
| 16 | 3.2 Abbreviated terms |
| 17 | Section 2: Design and guidance to avoid moisture related problems 4 Design to avoid moisture related problems 4.1 Assessing the likelihood of condensation |
| 18 | 4.2 Methods of assessment |
| 19 | 4.3 Internal climate |
| 20 | 4.4 External climate (condensation risk) |
| 21 | 4.5 The external envelope |
| 24 | 4.6 Alterations and extensions to buildings 5 Guidance for builders and owners |
| 25 | 6 Remedial works 6.1 Actions to manage moisture risk 6.2 Heating 6.3 Ventilation |
| 26 | Section 3: Design principles – Building services 7 Application of design principles – Heating 7.1 General 7.2 Warm air heating |
| 27 | 7.3 Electric storage heaters 7.4 Unflued oil and gas heaters 7.5 Heating controls |
| 28 | 8 Application of design principles – Occupied space ventilation 8.1 General |
| 29 | 8.2 Natural ventilation |
| 30 | 8.3 Continuous mechanical ventilation |
| 31 | 8.4 Cooker hood (range hood) |
| 32 | 8.5 Purge ventilation 8.6 Drying rooms/cupboards 8.7 Dehumidifiers |
| 33 | Section 4: Design principles – fabric details 9 Application of design principles – junctions 9.1 Heat loss and surface temperatures |
| 34 | 9.2 Principles for reducing the effects of thermal bridging 10 Application of design principles – Floors 10.1 General |
| 35 | Figure 1 — Key to the figures 10.2 Categories of floors |
| 36 | Table 1 — Summary of floor constructions 10.3 Groundbearing floors with DPM |
| 37 | Figure 2 — Connective/systemic effects for groundbearing floors |
| 39 | Figure 3 — Insulation above concrete slab Figure 4 — Insulation below concrete slab 10.4 Groundbearing floor without DPM, with or without insulation either above or below the floor slab/tiles |
| 42 | Figure 5 — Existing groundbearing floors either without DPM or without insulation above or below the floor 10.5 Suspended floors |
| 44 | Figure 6 — Connective/systemic effects for suspended floors |
| 46 | Figure 7 — Suspended concrete floor with insulation above the floor slab Figure 8 — Suspended concrete floor with insulation below the floor slab |
| 47 | Figure 9 — Suspended timber floor with insulation above the joists Figure 10 — Suspended timber floor with insulation between the joists |
| 48 | Figure 11 — Timber suspended floor with a soffit of high vapour resistance 10.6 Basements |
| 51 | 11 Application of design principles – Walls 11.1 General |
| 52 | Table 2 — Checklist for design principles – Walls |
| 58 | Figure 12 — Key to the figures 11.2 Categories of walls Table 3 — Index of wall types |
| 59 | 11.3 Masonry walls |
| 64 | Figure 13 — Solid traditional masonry wall – areas to inspect |
| 66 | Figure 14 — Existing solid masonry wall with external wall insulation – window details Figure 15 — Existing solid masonry wall with external wall insulation – wall-roof |
| 67 | Figure 16 — Existing solid masonry wall with external wall insulation – parapet detail Figure 17 — Existing solid masonry wall – external insulation [Example of below damp‑proofing course (DPC) or joist ends] |
| 68 | Figure 18 — Solid masonry wall – external insulation Figure 19 — External wall insulation to roof – detail |
| 69 | Figure 20 — External wall insulation at window – detail Figure 21 — External wall insulation to ground level – detail |
| 70 | Figure 22 — Recessed window head – detail |
| 71 | Figure 23 — Existing solid masonry wall with internal wall insulations – key considerations before and during installation |
| 73 | Figure 24 — Solid masonry wall – internal insulation at window – reducing thermal bridging Figure 25 — Solid masonry wall – internal insulation at joists – reducing thermal bridging |
| 77 | Figure 26 — Cavity masonry wall – insulation at junction with window frames Figure 27 — Cavity masonry wall – insulation at junction with roof (Example of eaves and continuous insulation) |
| 78 | 11.4 Framed walls |
| 81 | Figure 28 — Framed wall – external insulation |
| 82 | Figure 29 — Framed wall – lintel and sill |
| 83 | Figure 30 — Framed wall – junction with bearing floor |
| 84 | Figure 31 — Framed wall – junction with roof – continuous insulation |
| 85 | Figure 32 — Framed wall – internal insulation |
| 86 | Figure 33 — Framed wall – internal sheathing – thermal insulation between and to the inside of the structural framing Figure 34 — Framed wall – external sheathing – thermal insulation between and to the inside of the structural framing |
| 87 | Figure 35 — Framed wall – external sheathing – thermal insulation between the framing and on the outside of the sheathing |
| 90 | 11.5 Structural insulated panel systems (SIPS): walls |
| 92 | 11.6 Cladding systems |
| 94 | Figure 36 — Cladding systems – Integral thermal insulation – Prefabricated |
| 95 | Figure 37 — Cladding systems – Integral thermal insulation – Built in situ |
| 97 | Figure 38 — Closed joint rainscreen cladding |
| 98 | Figure 39 — Open joint rainscreen cladding 11.7 Cavity trays and weep holes |
| 100 | 11.8 Openings in walls 12 Application of design principles – Roofs 12.1 General |
| 101 | Figure 40 — Key to the figures 12.2 Categories of roofs |
| 103 | Figure 41 — Roofs categorized by position of the insulation 12.3 Methods for assessing moisture risks in roofs |
| 104 | Table 4 — Calculation methods for different roof types |
| 105 | 12.4 Design considerations |
| 108 | 12.5 Cold pitched roofs |
| 112 | Figure 42 — Cold pitched roof – LR underlay – Air permeable outer weatherproof covering Figure 43 — Cold pitched roof – LR underlay – Air impermeable outer weatherproof covering |
| 113 | Table 5 — Minimum free area of openings for loft-space ventilation |
| 114 | 12.6 Warm pitched roofs |
| 116 | Figure 44 — Warm pitched roof with HR underlay – Any roof covering |
| 117 | Figure 45 — Warm pitched roof with LR underlay and air permeable outer weatherproof covering Figure 46 — Warm pitched roof with LR underlay and air impermeable outer weatherproof covering |
| 118 | 12.7 Hybrid pitched roofs Figure 47 — Routing insulation and AVCL in a hybrid pitched roof to achieve continuity – insulation follows slope of roof and horizontal ceiling |
| 119 | Figure 48 — Routing insulation and AVCL in a hybrid pitched roof to achieve continuity – insulation follows horizontal ceiling, vertical wall and slope of roof 12.8 Flat roofs |
| 121 | Figure 49 — Cold flat roof – roof deck |
| 122 | Figure 50 — Warm flat roof – roof deck Figure 51 — Warm flat roof – roof slab |
| 123 | Figure 52 — Inverted flat roof – roof deck Figure 53 — Inverted flat roof – roof slab |
| 124 | Figure 54 — Cold pitched roof with flat roof apex 12.9 Self-supporting sheeted metal |
| 127 | Figure 55 — Site-assembled metal roof |
| 128 | Figure 56 — Composite metal roof 12.10 Structural insulated panel systems (SIPS): pitched roofs and flat roofs |
| 131 | 12.11 Openings in roofs 12.12 Refurbishment |
| 133 | Section 5: Condensation risk 13 Calculating condensation risk 13.1 Mould growth and surface condensation |
| 134 | 13.2 Assessment methods |
| 136 | Table 6 — Monthly mean temperature and relative humidity for interstitial condensation calculations Table 7 — Corrections to monthly mean temperatures and relative humidities to create condensation risk years with various return periods |
| 138 | Table 8 — Example of the calculation of estimated ground temperatures |
| 139 | Table 9 — Moisture production rates in housing Table 10 — Typical moisture production rates from fuels |
| 140 | Table 11 — Typical moisture generation rates for household activities |
| 141 | Figure 57 — Variation of internal humidity classes with external temperature Table 12 — Internal humidity classes: building types and limiting relative humidities at T3 = 0 °C |
| 142 | 13.3 Calculation of condensation risk in a cold pitched roof with thermal insulation applied on a horizontal ceiling |
| 143 | Annex A (informative) Guidance for designers and builders: a whole‑building approach |
| 148 | Annex B (informative) Properties of materials |
| 149 | Table B.1 — Thermal conductivity and vapour resistivity of building materials |
| 152 | Table B.2 — Vapour resistances of thin membranes and foils |
| 153 | Table B.3 — Thermal resistance, in m2K/W, unventilated cavities 5 mm and 25 mm wide with high emissivity surfaces |
| 154 | Table B.4 — Thermal resistance of roof spaces Table B.5 — Thermal resistances of surfaces |
| 155 | Table B.6 — Factors for converting permeance units to µg/N·s Annex C (informative) Diagnosis of dampness problems |
| 162 | Annex D (informative) Moisture in buildings |
| 165 | Table D.1 — Effect of condensate on impermeable surfaces Annex E (informative) Guidance for builders |
| 167 | Annex F (informative) Guidance for occupiers on how to avoid damaging condensation |
| 169 | Annex G (informative) The temperature and moisture content of air |
| 170 | Figure G.1 — Psychrometric chart showing the derivation of relative humidity from temperature and vapour pressure |
| 173 | Bibliography |
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