NCC 2019 Volume One Amendment 1
Classification
Building class 1a Building class 1b Building class 2 Building class 3 Building class 4 Building class 5 Building class 6 Building class 7a Building class 7b Building class 8 Building class 9a Building class 9b Building class 9c Building class 10a Building class 10b Building class 10c

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Classification
Building class 1a Building class 1b Building class 2 Building class 3 Building class 4 Building class 5 Building class 6 Building class 7a Building class 7b Building class 8 Building class 9a Building class 9b Building class 9c Building class 10a Building class 10b Building class 10c
Part J1 Building fabric

Part J1 Building fabric

J1.0 Deemed-to-Satisfy Provisions

(a)

Where a Deemed-to-Satisfy Solution is proposed, Performance RequirementJP1 is satisfied by complying with—

(i)
(ii)
(iii)
(iv)
(v)
(vi)
(vii)
(b)

Where a Performance Solution is proposed, the relevant Performance Requirements must be determined in accordance with A2.2(3) and A2.4(3) as applicable.

Intent

To clarify that JP1 will be satisfied if compliance is achieved with Parts J1 to J8.

See comments for Deemed-to-Satisfy Provisions of J0.0.

J1.1 Application of Part

The Deemed-to-Satisfy Provisions of this Part apply to building elements forming the envelope of a Class 2 to 9 building other than J1.2(e), J1.3, J1.4, J1.5 and J1.6(a) which do not apply to a Class 2 sole-occupancy unit or a Class 4 part of a building.

Intent

To facilitate the efficient use of energy appropriate for Class 2 to 9 buildings that are conditioned or likely to be conditioned.

The Deemed-to-Satisfy Provisions of Part J1 apply to building elements that form part of the envelope, where the envelope separates a conditioned space or habitable room from the exterior of the building or a non-conditioned space. This includes roofs, walls, glazing and floors as per the definition of “fabric”.

Some Class 6, 7, 8 and 9b buildings that are not a conditioned space by definition may be excluded from controls for building fabric. Class 6 and 9b buildings cover a wide range of uses and some could reasonably be expected to be air-conditioned at some time in the future while others may not. For example, it may be unlikely that a school gymnasium will be air-conditioned while classrooms may well be when funds are available. Some States are already retrofitting air-conditioning to schools. Note that the phrase "likely by the intended use of the space to be air-conditioned" is in the definition of a conditioned space.

The external elements of an atrium or solarium that is not a conditioned space may also be excluded. The atrium may be attached to a Class 5 building and would otherwise attract some of the requirements appropriate for a Class 5 building. Again, either there is no energy saving to be made by thermally treating the elements, or the saving is below the minimum threshold and so not cost-effective.

The Deemed-to-Satisfy Provisions of Part J1 do not apply to Class 8 electricity network substations as these buildings are not required to be air-conditioned for the purposes of Section J. See the definition for air-conditioning. The air-conditioning systems of these buildings are instead designed to maintain the efficient operation of sensitive electrical equipment.

J1.2 Thermal construction — general

(a)

Where required, insulation must comply with AS/NZS 4859.1 and be installed so that it—

(i)

abuts or overlaps adjoining insulation other than at supporting members such as studs, noggings, joists, furring channels and the like where the insulation must be against the member; and

(ii)

forms a continuous barrier with ceilings, walls, bulkheads, floors or the like that inherently contribute to the thermal barrier; and

(iii)

does not affect the safe or effective operation of a service or fitting.

(b)

Where required, reflective insulation must be installed with—

(i)

the necessary airspace to achieve the required R-Value between a reflective side of the reflective insulation and a building lining or cladding; and

(ii)

the reflective insulation closely fitted against any penetration, door or window opening; and

(iii)

the reflective insulation adequately supported by framing members; and

(iv)

each adjoining sheet of roll membrane being—

(A)

overlapped not less than 50 mm; or

(B)

taped together.

(c)

Where required, bulk insulation must be installed so that—

(i)

it maintains its position and thickness, other than where it is compressed between cladding and supporting members, water pipes, electrical cabling or the like; and

(ii)

in a ceiling, where there is no bulk insulation or reflective insulation in the wall beneath, it overlaps the wall by not less than 50 mm.

(d)

Roof, ceiling, wall and floor materials, and associated surfaces are deemed to have the thermal properties listed in Specification J1.2.

(e)

The required Total R-Value and Total System U-Value, including allowance for thermal bridging, must be—

(i)

calculated in accordance with AS/NZS 4859.2 for a roof or floor; or

(ii)

determined in accordance with Specification J1.5a for wall-glazing construction; or

(iii)

determined in accordance with Specification J1.6 or Section 3.5 of CIBSE Guide A for soil or sub-floor spaces.

Intent

To outline the general requirements to insulate a building’s fabric and the inherent thermal properties of roof, ceiling, wall and floor materials.

Testing

J1.2(a) requires that insulation must be tested and labelled in accordance with AS/NZS 4859.1.

Installation

Care should be taken when installing insulation to ensure a continuous envelope between a conditioned space and either the outside environment or a non-conditioned space.

Insulation is to be fitted tightly to each side of framing members but need not be continuous over the framing member. The insulation requirements in J1.3, J1.5 and J1.6 are calculated for parts of the roof, walls or floor that are clear of any framing members. The means of achieving the required total R-Value must be in accordance with J1.2(e).

The provisions also state that the installation of insulation should not interfere with the safety or performance of domestic services and fittings such as heating flues, recessed light fittings, transformers for low voltage lighting, gas appliances and general plumbing and electrical components. This includes providing appropriate clearance as detailed in relevant legislation and referenced standards such as for electrical, gas and fuel oil installations. Low voltage lighting transformers should not be covered by insulation and be mounted above the insulation rather than on the ceiling. Expert advice may also be needed on how much bulk insulation can be placed over electrical wiring.

Note that the addition of insulation to other building elements may alter the fire properties of those elements. Re-testing or re-appraisal of these elements may be required.

Airspace adjoining reflective insulation

For reflective insulation to achieve its tested R-Value, the airspace adjoining the insulation needs to be a certain width. This width varies depending on the particular type of reflective insulation and the R-Value to be achieved.

Where the width of airspace is to be achieved in a wall cavity or the like, care should be taken to ensure compliance with all other applicable BCA provisions. For example, the provisions relating to weatherproofing masonry may require a greater width of cavity.

Compression of bulk insulation

The R-Value of bulk insulation is reduced if it is compressed. The allocated space for bulk insulation is therefore to allow the insulation to be installed so that it maintains its correct thickness unless exempted such as at wall studs. This is particularly relevant to wall and cathedral ceiling framing whose members can only accommodate a limited thickness of insulation. In some instances, larger framing members or thinner insulation material, may be necessary to ensure that the insulation achieves its required R-Value.

Artificial cooling

Artificial cooling of buildings in some climates can cause condensation to form inside the layers of the building envelope. Such condensation can cause significant structural or cosmetic damage to the envelope before it is detected. Associated mould growth may also create health risks to the occupants. Effective control of condensation is a complex issue. In some locations a fully sealed vapour barrier may need to be installed on the more humid, or generally warmer, side of the insulation.

Thermal bridging

A thermal bridge, also called a cold bridge or heat bridge, is an area or component of the fabric which has higher thermal conductivity than the surrounding materials, creating a path of least resistance for heat transfer. Thermal bridges can significantly reduce the thermal performance of a facade, increasing energy use from a building’s heating and cooling systems. If not accounted for, they can also cause unwanted condensation and comfort issues in a building. In line with the existing requirements of AS/NZS 4859.1, J1.2(e) specifies that the means of achieving the required Total R-Value must be determined in accordance with AS/NZS 4859.2. This Standard comprises a calculation method that takes into account the impact of thermal bridges on the thermal performances of a facade. Depending on the extent of the thermal bridges within a facade, extra insulation may need to be added, or thermal breaks installed in order for a facade to be compliant.

J1.3 Roof and ceiling construction

(a)

A roof or ceiling must achieve a Total R-Value greater than or equal to—

(i)

in climate zones 1, 2, 3, 4 and 5, R3.7 for a downward direction of heat flow; and

(ii)

in climate zone 6, R3.2 for a downward direction of heat flow; and

(iii)

in climate zone 7, R3.7 for an upward direction of heat flow; and

(iv)

in climate zone 8, R4.8 for an upward direction of heat flow.

(b)

In climate zones 1, 2, 3, 4, 5, 6 and 7, the solar absorptance of the upper surface of a roof must be not more than 0.45.

SA J1.3(c)

Intent

To clarify the minimum Total R-Value that is to be achieved by a roof or ceiling, according to the building classification and climate zone in which it is located.

J1.3 covers roofs, including their ceilings, and any ceiling that is part of an intermediate floor being part of the building's envelope, or where there is no ceiling.

J1.3(a) details the insulation properties and minimum Total R-Value required of a roof or ceiling.

Part or all of this may be provided by the roof construction itself and any inherent insulating property of the roof and airspaces reduces the amount of insulation needed.

Where the ceiling space below the roof is used as the return air plenum, it is considered part of the conditioned space. In this instance, the envelope boundary for the roof and ceiling construction is located at the roof.

The direction of heat flow stated should not be taken as the only direction in which any insulating properties operate but it is a statement of the prominent direction for that particular climate zone. It is assumed that materials, be they construction materials or insulating materials, will also have insulating properties in the other direction. For a residential building, the night time direction is important as the building is most likely to be occupied at that time and the outside temperature likely to be the lowest of the day.

The Total R-Value in J1.3(a) is dependent on the climate zone.

As with walls, the effect of thermal bridging must be taken into account when determining if the minimum R-Value of a roof has been achieved. In some cases, thermal breaks will be necessary to achieve compliance.

A thermal break may be provided by materials such as timber or expanded polystyrene strips, plywood or bulk insulation. Reflective insulation alone is not suitable for use as a thermal break because it requires an adjoining airspace to achieve the specified R-Value.

The weight of roof or ceiling insulation needs to be considered in the selection of plasterboard, plasterboard fixings and building framing.

There may be instances where there is a loss of ceiling insulation because of downlights, fans and other penetrations. In these circumstances it is the responsibility of designers to determine how they will achieve the required Total R-Value given the construction of the roof and the penetrations.

Details of the Total R-Values of typical constructions are provided in this Guide.

Typical construction

The Total R-Value of the basic roof and ceiling has been determined by adding together the material R-Values of the outdoor air film, roof cladding, roof airspace, ceiling sheet lining and internal air film.

The Total R-Value of the roof and ceiling materials may need to be adjusted if other building elements, such as sarking, are to also be installed.

Note that it should not be assumed that these figures are representative of all construction scenarios. For example the spacing of framing members, the presence of roof lights or the specific type of frame could all affect the actual Total R-Value by creating thermal bridging between elements or by compressing insulation. If following a Deemed-to-Satisfy compliance pathway, the code requires in J1.2(e) that AS/NZ 4859.2 be used to calculate the Total R-Value of a building's envelope.

Insulation can be installed in the roof, the ceiling, or a combination of both, provided the required thermal performance is achieved and other aspects of the building’s integrity are not compromised. It should be noted that the thermal performance of the roof may vary depending on the position of the insulation, the climatic conditions, the design of the building and the way in which it is operated. For example, although not recognised in the values, insulation installed under the roof, rather than on the ceiling, in a building with a large roof space in a cold climate, or when a room is being air-conditioned, may be less effective because of the additional volume of roof airspace that would need to be heated or cooled.

For a material that is not listed as an item in the figure below, other than air, the R-Value may be determined by dividing the thickness of the item in metres by the thermal conductivity in W/m.K (typical values are described in Specification J1.2).

There are a number of different insulation products that may be used to achieve the minimum added R-Value. Care should be taken to ensure that the choice made is appropriate for the construction and climate conditions. For instance, in some climate zones, an impermeable insulation sheet needs to be installed with due consideration of condensation and associated interaction with adjoining building materials.

Roof construction description

Item

Item description

R-Value unventilated

R-Value ventilated

Up

Down

Up

Down

  1. Roof 15° to 45° pitch
    • Horizontal ceiling
    • Metal cladding

1.

Outdoor air film (7 m/s)

0.04

0.04

0.04

0.04

2.

Metal cladding

0.00

0.00

0.00

0.00

3.

Roof airspace (non-reflective)

0.18

0.28

0.00

0.46

4.

Plasterboard gypsum (10 mm, 880 kg/m3)

0.06

0.06

0.06

0.06

5.

Indoor air film (still air)

0.11

0.16

0.11

0.16

Total R-Value

0.39

0.54

0.21

0.72

guide_J13a_2019.svg

Roof construction description

Item

Item description

R-Value unventilated

R-Value ventilated

Up

Down

Up

Down

  1. Roof 15° to 45° pitch
    • Horizontal ceiling
    • Clay tiles 19 mm

1.

Outdoor air film (7 m/s)

0.04

0.04

0.04

0.04

2.

Roof tile, clay or concrete (1922 kg/m3)

0.02

0.02

0.02

0.02

3.

Roof airspace (non-reflective)

0.18

0.28

0.00

0.46

4.

Plasterboard gypsum (10 mm, 880 kg/m3)

0.06

0.06

0.06

0.06

5.

Indoor air film (still air)

0.11

0.16

0.11

0.16

Total R-Value

0.41

0.56

0.23

0.74

guide_J13b_2019.svg

Roof construction description

Item

Item description

R-Value unventilated

Up

Down

  1. Cathedral ceiling 15° to 45° pitch
    • 10 mm plaster on top of rafters
    • Metal external cladding

1.

Outdoor air film (7 m/s)

0.04

0.04

2.

Metal cladding

0.00

0.00

3.

Roof airspace (30 mm to 100 mm, non-reflective)

0.15

0.18

4.

Plasterboard gypsum (10 mm, 880 kg/m3)

0.06

0.06

5.

Indoor air film (still air)

0.11

0.16

Total R-Value

0.36

0.42

guide_J13c_2019.svg

Roof construction description

Item

Item description

R-Value unventilated

Up

Down

  1. Cathedral ceiling 15° to 45° pitch
    • 10 mm plaster on top of rafters
    • Tiles external cladding

1.

Outdoor air film (7 m/s)

0.04

0.04

2.

Roof tile, clay or concrete (1922 kg/m3)

0.02

0.02

3.

Roof airspace (30 mm to 100 mm, non-reflective)

0.15

0.18

4.

Plasterboard gypsum (10 mm, 880 kg/m3)

0.06

0.06

5.

Indoor air film (still air)

0.11

0.16

Total R-Value

0.38

0.44

guide_J13d_2019.svg

Roof construction description

Item

Item description

R-Value unventilated

Up

Down

  1. Skillion roof less than 5° pitch
    • 10 mm plaster below rafters
    • Metal external cladding

1.

Outdoor air film (7 m/s)

0.04

0.04

2.

Metal cladding

0.00

0.00

3.

Roof airspace (100 mm to 300 mm, non-reflective)

0.15

0.22

4.

Plasterboard gypsum (10 mm, 880 kg/m3)

0.06

0.06

5.

Indoor air film (still air)

0.11

0.16

Total R-Value

0.36

0.48

guide_J13e_2019.svg

Roof construction description

Item

Item description

R-Value unventilated

Up

Down

  1. Skillion roof 5° to 15° pitch
    • 10 mm plaster on top of rafters
    • Metal external cladding

1.

Outdoor air film (7 m/s)

0.04

0.04

2.

Metal cladding

0.00

0.00

3.

Roof airspace (30 mm to 100 mm, non-reflective)

0.15

0.21

4.

Plasterboard gypsum (10 mm, 880 kg/m3)

0.06

0.06

5.

Indoor air film (still air)

0.11

0.16

Total R-Value

0.36

0.47

guide_J13f_2019.svg

Roof construction description

Item

Item description

R-Value unventilated

Up

Down

  1. 100 mm solid concrete roof to 5°
    • 10 mm plaster, suspended ceiling
    • Applied external waterproof membrane

1.

Outdoor air film (7 m/s)

0.04

0.04

2.

Waterproof membrane, rubber synthetic (4 mm, 961 kg/m3)

0.03

0.03

3.

Solid concrete (100 mm, 2400 kg/m3)

0.07

0.07

4.

Ceiling airspace (100 mm to 300 mm, non-reflective)

0.15

0.22

5.

Plasterboard, gypsum (10 mm, 880 kg/m3)

0.06

0.06

6.

Indoor air film (still air)

0.11

0.16

Total R-Value

0.46

0.58

guide_J13g_2019.svg

Notes:

  1. The R-Value of an item, other than an airspace, air film or air cavity, may be increased in proportion to the increased thickness of the item.
  2. The Total R-Value of a form of construction may be increased by the amount that the R-Value of an individual item is increased, except where the item is thermally bridged.
  3. Where an airspace is filled, the R-Value listed for the airspace must be deducted from the Total R-Value of the roof construction.
  4. For information on a roof space that is considered to be ventilated, see Specification J1.2 Clause 2(d).

J1.4 Roof lights

Roof lights must have—

(a)

a total area of not more than 5% of the floor area of the room or space served; and

(b)

transparent and translucent elements, including any imperforate ceiling diffuser, with a combined performance of—

(i)

for Total system SHGC, in accordance with Table J1.4; and

(ii)

for Total system U-Value, not more than U3.9.

Table J1.4 Roof lights - Total system SHGC

Roof light shaft index Note 1

Total area of roof lights up to 3.5% of the floor area of the room or space

Total area of roof lights more than 3.5% and up to 5% of the floor area of the room or space

< 1.0

≤ 0.45

≤ 0.29

≥ 1.0 to < 2.5

≤ 0.51

≤ 0.33

≥ 2.5

≤ 0.76

≤ 0.49

Notes to Table J1.4 :

  1. The roof light shaft index is determined by measuring the distance from the centre of the shaft at the roof to the centre of the shaft at the ceiling level and dividing it by the average internal dimension of the shaft opening at the ceiling level (or the diameter for a circular shaft) in the same units of measurement.
  2. The area of a roof light is the area of the roof opening that allows light to enter the building. The total area of roof lights is the combined area for all roof lights serving the room or space.
Intent

To specify requirements for roof lights and provide a reasonable distribution of the roof lights.

J1.4 has values for Total System SHGC and Total System U-Values, which are expressed in accordance with the Australian Fenestration Rating Council (AFRC) protocol.

The provisions of J1.4(a) require roof lights that form part of the envelope, other than of a sole-occupancy unit of a Class 2 building or a Class 4 part of a building, comply with Table J1.4.

The size of roof lights is limited to no more than 5% of the floor area of the space served in order to ensure that the thermal performance of a roof is not compromised to too great an extent. Larger roof lights will need to achieve compliance through a Verification Method or as a Performance Solution.

Table J1.4 provides the Total System SHGC requirements that satisfy J1.4(a).

J1.5 Walls and glazing

(a)

The Total System U-Value of wall-glazing construction must not be greater than—

(i)

for a Class 2 common area, a Class 5, 6, 7, 8 or 9b building or a Class 9a building other than a ward area, U2.0; and

(ii)

for a Class 3 or 9c building or a Class 9a ward area

(A)

in climate zones 1, 3, 4, 6 or 7, U1.1; or

(B)

in climate zones 2 or 5, U2.0; or

(C)

in climate zone 8, U0.9.

(b)

The Total System U-Value of display glazing must not be greater than U5.8.

(c)

The Total System U-Value of wall-glazing construction must be calculated in accordance with Specification J1.5a .

(d)

Wall components of a wall-glazing construction must achieve a minimum Total R-Value of—

(i)

where the wall is less than 80% of the area of the wall-glazing construction, R1.0; or

(ii)

where the wall is 80% or more of the area of the wall-glazing construction, the value specified in Table J1.5a.

Table J1.5a Minimum wall Total R-Value - Wall area 80% or more of wall-glazing construction area

Climate zone

Class 2 common area, Class 5, 6, 7, 8 or 9b building or a Class 9c building other than a ward area

Class 3 or 9c building or Class 9a ward area

1

2.4

3.3

2

1.4

1.4

3

1.4

3.3

4

1.4

2.8

5

1.4

1.4

6

1.4

2.8

7

1.4

2.8

8

1.4

3.8

(e)

The solar admittance of externally facing wall-glazing construction must not be greater than—

(i)

for a Class 2 common area, a Class 5, 6, 7, 8 or 9b building or a Class 9a building other than a ward area, the values specified in Table J1.5b; and

(ii)

for a Class 3 or 9c building or a Class 9a ward area, the values specified in Table J1.5c.

(f)

The solar admittance of a wall-glazing construction must be calculated in accordance with Specification J1.5a .

(g)

The Total system SHGC of display glazing must not be greater than 0.81 divided by the applicable shading factor specified in Clause 7 of Specification J1.5a.

Table J1.5b Maximum wall-glazing construction solar admittance - Class 2 common area, Class 5, 6, 7, 8 or 9b building or Class 9a building other than a ward area

Climate zone

Eastern aspect solar admittance

Northern aspect solar admittance

Southern aspect solar admittance

Western aspect solar admittance

1

0.12

0.12

0.12

0.12

2

0.13

0.13

0.13

0.13

3

0.16

0.16

0.16

0.16

4

0.13

0.13

0.13

0.13

5

0.13

0.13

0.13

0.13

6

0.13

0.13

0.13

0.13

7

0.13

0.13

0.13

0.13

8

0.2

0.2

0.42

0.36

Table J1.5c Maximum wall-glazing construction solar admittance - Class 3 or 9c building or Class 9a ward area

Climate zone

Eastern aspect solar admittance

Northern aspect solar admittance

Southern aspect solar admittance

Western aspect solar admittance

1

0.07

0.07

0.10

0.07

2

0.10

0.10

0.10

0.10

3

0.07

0.07

0.07

0.07

4

0.07

0.07

0.07

0.07

5

0.10

0.10

0.10

0.10

6

0.07

0.07

0.07

0.07

7

0.07

0.07

0.08

0.07

8

0.08

0.08

0.08

0.08

Intent

To specify the requirements for walls and windows, both external and internal, that are a part of the envelope.

J1.5(a) contains the basic Total System U-Values and Total R-Values that need to be achieved by wall-glazing construction forming the envelope of a building. Importantly, this applies to both external and internal wall-glazing construction that form part of the building envelope. J1.5(e) contains the basic solar admittance values that must not be exceeded by externally-facing wall-glazing construction. Importantly, this subclause only applies to external wall-glazing construction forming part of the building envelope.

There are two calculation methods for determining compliance with the Total System U-Value and solar admittance requirements inJ1.5(a)and (e). The first method involves assessing wall-glazing construction facing a single aspect (or direction). The second method involves assessing together the wall-glazing construction facing multiple aspects. These methods are detailed in Specification J1.5a.

J1.6 Floors

(a)

A floor must achieve the Total R-Value specified in Table J1.6.

(b)

A floor must be insulated around the vertical edge of its perimeter with insulation having an R-Value greater than or equal to 1.0 when the floor—

(i)

is a concrete slab-on-ground in climate zone 8; or

(ii)

has an in-slab or in-screed heating or cooling system, except where used solely in a bathroom, amenity area or the like.

(c)

Insulation required by (b) for a concrete slab-on-ground must—

(i)

be water resistant; and

(ii)

be continuous from the adjacent finished ground level—

(A)

to a depth not less than 300 mm; or

(B)

for the full depth of the vertical edge of the concrete slab-on-ground.

Table J1.6 Floors - Minimum Total R-Value

Location

Climate zone 1 — upwards heat flow

Climate zones 2 and 3 — upwards and downwards heat flow

Climate zone s 4, 5, 6 and 7 — downwards heat flow

Climate zone 8 — downwards heat flow

A floor without an in-slab heating or cooling system

2.0

2.0

2.0

3.5

A floor with an in-slab heating or cooling system

3.25

3.25

3.25

4.75

Note to Table J1.6: For the purpose of calculating the Total R-Value of a floor, the sub-floor and soil R-Value must be calculated in accordance with Specification J1.6 or Section 3.5 of CIBSE Guide A.

Intent

To outline the minimum insulation requirements for suspended floors and concrete slabs on ground.

For a floor that is part of the building envelope other than a sole-occupancy unit in a Class 2 building or Class 4 part of a building, the required Total R-Values are in Table J1.6. For the purposes of calculating the Total R-Value of a floor, the R-Value attributable to an in-slab or in-screed heating or cooling system is not included.

J1.6(b) and (c) apply to all concrete slab on ground floors including those in sole-occupancy units in a Class 2 building, or Class 4 part of a building as described in J0.1.

J1.6(b) requires all floors with an embedded in-slab or in-screed heating or cooling system to have additional insulation installed around the vertical edge of the perimeter. This provision aims to limit heat loss or gain through the perimeter of the slab.

Regarding the installation of slab edge insulation in J1.6(c), care should be taken to ensure that the insulation is compatible with the type of termite management system selected.

Typical construction

The figure below outlines the thermal performance of some of the more common forms of floor construction. For a material that is not listed in the figure below, other than air, the material R-Value may be determined by dividing the thickness of the item in metres by the thermal conductivity in W/m.K (typical values are described in Specification J1.2).

For the purposes of calculating the Total R-Value of a floor, the R-Value attributable to an in-slab or in-screed heating or cooling system is not included.

Note that it should not be assumed that these figures are representative of all construction scenarios. For example the spacing of stumps, or the specific type of frame could all affect the actual Total R-Value by creating thermal bridging between elements or by compressing insulation. If following a Deemed-to-Satisfy compliance pathway, Total R-Value must be calculated using the methods prescribed in AS/NZS 4859.2 to properly account for these effects.

Floor construction description

Item

Item description

R-Value

Up

Down

  1. Timber internal floor, 10 mm internal plaster

1.

Indoor air film (still air)

0.11

0.16

2.

Particleboard flooring (19 mm, 640 kg/m3)

0.15

0.15

3.

Floor airspace, 100 mm to 300 mm (non-reflective)

0.15

0.22

4.

Plasterboard, gypsum (10 mm, 880 kg/m3)

0.06

0.06

5.

Indoor air film (still air)

0.11

0.16

Total R-Value

0.58

0.75

guide_J16a_2019.svg

Floor construction description

Item

Item description

R-Value

Up

Down

  1. Timber, suspended ground floor, open subfloor

1.

Indoor air film (still air)

0.11

0.16

2.

Particleboard flooring (19 mm, 640 kg/m3)

0.15

0.15

3.

Outdoor air film (still air)

0.04

0.04

Total R-Value

0.30

0.35

guide_J16b_2019.svg

Floor construction description

Item

Item description

R-Value

Up

Down

  1. Solid concrete suspended slab

1.

Indoor air film (still air)

0.11

0.16

2.

Solid concrete (150 mm, 2400 kg/m3)

0.10

0.10

3.

Outdoor air film (still air)

0.04

0.04

Total R-Value

0.25

0.30

guide_J16c_2019.svg

Floor construction description

Item

Item description

R-Value

Up

Down

  1. 150 mm hollow-core concrete planks

1.

Indoor air film (still air)

0.11

0.16

2.

Concrete topping (60 mm, 2,400 kg/m3)

0.04

0.04

3.

Hollow-core concrete planks (150 mm, 1,680 kg/m3, 30% cores)

0.14

0.14

4.

Outdoor air film (7 m/s)

0.04

0.04

Total R-Value

0.33

0.38

guide_J16d_2019.svg

Floor construction description

Item

Item description

R-Value

Up

Down

  1. 100 mm solid concrete slab-on-ground

1.

Indoor air film (still air)

0.11

0.16

2.

Solid concrete (100 mm, 2400 kg/m3)

0.07

0.07

3.

Ground thermal resistance

-

-

Total R-Value

0.18

0.23

guide_J16E_2019.svg

Floor construction description

Item

Item description

R-Value

Up

Down

  1. 150 mm solid concrete slab-on-ground

1.

Indoor air film (still air)

0.11

0.16

2.

Solid concrete (150 mm, 2400 kg/m3)

0.10

0.10

3.

Ground thermal resistance

-

-

Total R-Value

0.21

0.26

guide_J16F_2019.svg

Notes:

  1. The R-Value of an item, other than an airspace, air film or air cavity, may be increased in proportion to the increased thickness of the item.
  2. The Total R-Value of a form of construction maybe increased by the amount that an individual item is increased.
  3. For floor types located on soil or over a sub-floor space, the Total R-Value should be calculated in accordance with Specification J1.6 or Section 3.5 of CIBSE Guide A.
  4. Where a reflective building membrane is attached beneath the floor with a 100 mm reflective airspace, add R0.38 for heat flow up and R1.14 for heat flow down.
  5. The addition of 10 mm of render to the ceiling of a suspended internal concrete floor will increase the Total R-Value by 0.02.
  6. Solid concrete slab includes concrete beam and infill floors and concrete precast permanent formwork panels. For the purposes of calculating the Total R-Value of a floor, the R-Value attributable to an in-slab or in-screed heating or cooling system is ignored.
  7. Where an airspace is filled,the R-Value listed for the airspace must be deducted from the Total R-Value of the floor construction.