PA ratio for insulation - Revision history

Designing Buildings at 11:41, 7 November 2016

2016-11-07T11:41:33Z

Designing Buildings: moved PA ratio to PA ratio for insulation

2016-11-07T11:37:23Z

moved PA ratio to PA ratio for insulation

← Older revision

Revision as of 11:37, 7 November 2016

Designing Buildings: Created page with "U-values (sometimes referred to as heat transfer coefficients or thermal transmittances) are used to measure how effective elements of a buildings fabric are as insulators. That ..."

2016-11-07T11:36:40Z

Created page with "U-values (sometimes referred to as heat transfer coefficients or thermal transmittances) are used to measure how effective elements of a buildings fabric are as insulators. That ..."

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U-values (sometimes referred to as heat transfer coefficients or thermal transmittances) are used to measure how effective elements of a buildings fabric are as insulators. That is, how effective they are at preventing heat from transmitting between the inside and the outside of a building.

The lower the U-value of an element of a building's fabric, the more slowly heat is able to transmit through it, and so the better it performs as an insulator.

U-values are measured in watts per square metre per degree Kelvin (W/m²K). So for example, if we consider a double glazed window with a U-value of 2.8, for every degree difference in temperature between the inside and outside of the window, 2.8 watts will be transmitted every square meter.

However, the situation for ground floors is more complicated than other building elements.

The ground floor is not generally exposed to the weather, but faces, or sits above the ground. Unlike external conditions, the ground has a relatively constant temperature, typically 8 - 11° C in the UK. As a result, the thermal performance of the ground floor is dependent not only on the amount of insulation, but also the shape of the perimeter and the overall area covered, as these determine the extent to which the floor is influenced by external conditions.

The smaller the floor and the greater the length of the perimeter exposed to the outside, the poorer its thermal performance and so the more insulation will be required to comply with the building regulations. So a domestic building may need to have the whole of the ground floor insulated, while a large commercially building may only require insulation at the perimeter of the floor.

The PA ratio (perimeter area ratio, or P/A ratio) is a measure of the degree to which the perimeter of the floor is exposed:

PA = exposed perimeter / floor area.

The lower the PA ratio, the better the thermal performance of the floor.

The floor area is calculated from the internal surfaces of the external walls, and includes all heated spaces, but not unheated spaces that are outside of the insulated body of the building. Exposed perimeters include perimeters that connect to unheated spaces outside of the insulated body of the building.

The PA ratio, in combination with the information about the construction of the floor (which will determine its U Value) can be used to calculate the amount and thickness of insulation required to comply with the building regulations.

Some insulation manufacturers provide tables or calculating tools that can be used to determine the amount of insulation required for a given floor type and PA ratio.

= Find out more =

=== Related articles on Designing Buildings Wiki ===

* Cavity wall insulation.
* Conventions for calculating linear thermal transmittance and temperature factors.
* Computational fluid dynamics.
* Floor insulation.
* Heat transfer.
* Insulation specification.
* Limiting fabric parameters.
* R-value.
* Roof insulation.
* Solid wall insulation.
* Standard Assessment Procedure SAP.
* U value.
* U-value conventions in practice: Worked examples using BR 443.

[[Category:Standards_/_measurements]]

← Older revision		Revision as of 11:41, 7 November 2016
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−	U-values ~~(sometimes referred to as heat transfer coefficients or thermal transmittances)~~ are used to measure how effective elements of a buildings fabric are as insulators. That is, how effective they are at preventing heat from transmitting between the inside and the outside of a building.	+	U-values are used to measure how effective elements of a buildings fabric are as insulators. That is, how effective they are at preventing heat from transmitting between the inside and the outside of a building. The lower the U-value of an element of a building's fabric, the more slowly heat is able to transmit through it, and so the better it performs as an insulator.
−		+
−	The lower the U-value of an element of a building's fabric, the more slowly heat is able to transmit through it, and so the better it performs as an insulator.	+

	U-values are measured in watts per square metre per degree Kelvin (W/m²K). So for example, if we consider a double glazed window with a U-value of 2.8, for every degree difference in temperature between the inside and outside of the window, 2.8 watts will be transmitted every square meter.		U-values are measured in watts per square metre per degree Kelvin (W/m²K). So for example, if we consider a double glazed window with a U-value of 2.8, for every degree difference in temperature between the inside and outside of the window, 2.8 watts will be transmitted every square meter.

−	However, the situation for ground floors is more complicated than ~~other building elements~~.	+	However, the situation for ground floors is more complicated than this.

−	The ground floor is not generally exposed to the weather, but faces, or sits above the ground. Unlike external conditions, the ground has a relatively constant temperature, typically 8 - 11° C in the UK. As a result, the thermal performance of the ground floor is dependent ~~not only~~ on ~~the amount of insulation, but also~~ the shape of ~~the~~ perimeter and the overall area ~~covered~~, as these determine the extent to which the floor is ~~influenced by~~ external conditions.	+	The ground floor is not generally exposed to the weather, but faces, or sits above the ground. Unlike external conditions, the ground has a relatively constant temperature, typically 8 - 11° C in the UK. As a result, the thermal performance of the ground floor is dependent on the shape of its perimeter and the overall area it covers, as these determine the extent to which the floor is exposed to external conditions.

−	The smaller the floor and the greater the length of the perimeter exposed to the outside, the poorer its thermal performance and so the more insulation will be required to comply with the building regulations. So a domestic building may need to have the whole of the ground floor insulated, while a ~~large commercially~~ building may only require insulation at the perimeter of the floor.	+	The smaller the floor and the greater the length of the perimeter exposed to the outside, the poorer its thermal performance and so the more insulation will be required to comply with the building regulations. So a domestic building may need to have the whole of the ground floor insulated, while a larger commercial building may only require insulation at the perimeter of the floor.

	The PA ratio (perimeter area ratio, or P/A ratio) is a measure of the degree to which the perimeter of the floor is exposed:		The PA ratio (perimeter area ratio, or P/A ratio) is a measure of the degree to which the perimeter of the floor is exposed:

−	PA = exposed perimeter / floor area.	+	PA = exposed perimeter (m) / floor area (m²).

	The lower the PA ratio, the better the thermal performance of the floor.		The lower the PA ratio, the better the thermal performance of the floor.

−	The floor area is calculated from the internal surfaces of the external walls, and includes all heated spaces, but not unheated spaces that are outside of the insulated body of the building. Exposed perimeters include perimeters that connect to unheated spaces outside of the insulated body of the building.	+	The floor area is calculated from the internal surfaces of the external walls, and includes all heated spaces, but not unheated spaces that are outside of the insulated body of the building. Exposed perimeters include external perimeters and perimeters that connect to unheated spaces outside of the insulated body of the building.

−	The PA ratio, in combination with ~~the~~ information about the construction of the floor (which will determine its U Value) can be used to calculate the amount and thickness of insulation required to comply with the building regulations.	+	The PA ratio, in combination with information about the construction of the floor (which will determine its U Value) can be used to calculate the amount and thickness of insulation required to comply with the building regulations.

	Some insulation manufacturers provide tables or calculating tools that can be used to determine the amount of insulation required for a given floor type and PA ratio.		Some insulation manufacturers provide tables or calculating tools that can be used to determine the amount of insulation required for a given floor type and PA ratio.
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	* U-value conventions in practice: Worked examples using BR 443.		* U-value conventions in practice: Worked examples using BR 443.

−		+	[[Category:Standards_/_measurements]] [[Category:DCN_Standard]]
−		+
−	[[Category:Standards_/_measurements]]	+