Part L is a subset of the UK Building Regulations covering requirements and guidelines governing the energy efficiency of buildings. 

  • What changes have been made to Part L? 
  • What does it mean for you?
  • How does Part L fit into the Future Homes Standard? 

This article provides an overview of Part L and the changes to U-value requirements that are likely to affect your project. It is not designed to be an exhaustive or formal guide to the Building Regulations. For specific guidance, consult your architect or building control body.

Norrsken's energy-efficient triple-glazed windows and doors enable effortless compliance with these standards and unlocking a world of benefits from your energy-efficient new home.


What is Approved Document L?

Part L of the Building Regulations sets the minimum energy efficiency standards for new buildings in England and Wales. It focuses on reducing energy consumption and carbon emissions through:

  • Whole building performance: Your entire must be more energy efficient from June 2022 onwards, not just windows and doors.  
  • Fabric efficiency: Better insulation is a priority, and windows, walls and everything in between must meet stricter U-value requirements. 
  • Smarter systems: Part L updates guidance for heating and ventilation systems in new, existing and renovated buildings. 
  • Assessment: Part L uses a new method for assessing whole-building thermal performance, called the Standard Assessment Procedure (SAP).
Homes built to meet Part L standards are more comfortable, cost-effective to run, and environmentally friendly.


How does Part L fit into the Future Homes Standard?

Part L came into effect on June 15th 2022 and lays the foundation for energy-efficient homes in the UK. It sets minimum standards for insulation, windows, and heating systems. The Future Homes Standard builds on this, demanding even stricter performance levels in new build homes from 2025 for a more sustainable future. Think of Part L as the stepping stone, and the FHS as the next level in energy-efficient building to make net zero ready homes.


How do I meet Part L requirements? 

What’s the impact of these benchmarks? 

Part L tackles energy efficiency in new builds with a triple focus:
  • Reducing CO2 emissions (at least 31% lower); 
  • Improving building thermal performance; and 
  • Capping overall energy consumption for year-round comfort. 

It encourages for holistic design, boosting fabric efficiency (better insulation & airtightness) and encouraging efficient heating, smart energy management, and low-carbon sources like heat pumps.

How are Part L target rates met?

These can be achieved by using a combination of 
  • energy efficient building fabric, material and components - like triple-glazed windows and doors, insulation, SIPS panels and having sufficient insulation around pipework; 
  • efficient building services and detailing - for example, specifying airtight detailing with no thermal bridges, MVHR and / or airtight tape; and 
  • low and zero carbon technologies such as on or off-site renewable energy, photovoltaics, air or ground source heat pumps in an appropriate mix. 

How and when are the target rates measured?

The dwelling primary energy rate, dwelling emission rate and dwelling energy efficiency rate must be calculated before work starts, using design values, and once work is completed. 

New dwellings must pass the Standard Assessment Procedure (SAP) test – which measures the overall energy efficiency in your home. SAP will be replaced with the Home Energy Model (HEM) method of assessment in 2025 alongside the Future Homes Standard.

Self-builders can use "notional" U-values (target energy ratings) for windows, doors, etc. Hitting these targets guarantees compliance with new building regulations for a more energy-efficient home.

Fabric Efficiency

Part L tackles energy loss in building fabric through:
  • Strict U-values: Limits heat loss for windows, doors, and other building elements.
  • High insulation: Guides on proper insulation levels for walls, roofs, and floors.
  • Thermal bridge elimination: Focuses on minimizing heat escape points like windows and doors.
  • Airtightness: Reduces uncontrolled air leakage through gaps and cracks.
  • Efficient Services: Encourages well-insulated pipes and ducts for heating, cooling, and hot water.

U-Values - What are the new requirements?

New dwellings (post-June 2022) and replacements for existing homes must meet the efficiency standards outlined in Table 1.1 of Document L (page 12) for walls, floors, roofs, windows, and opaque doors.

New builds need windows with a U-value of 1.2 W/m²K or lower. Norrsken's award-winning triple-glazed windows surpass this standard, achieving U-values as low as 0.64 W/m²K for effortless compliance.
Element or system - Reference value for target setting
  • Windows and doors with > 60% glazed area - U = 1.2W/(m²·K)
  • Semi-glazed door (30-60% glazed area) - U = 1.0W/(m²·K)
  • Opaque door (<30% glazed area) - U = 1.0W/(m²·K)
  • Roof windows - U = 1.2W/(m²·K) when in vertical position
  • Rooflights - U = 1.7W/(m²·K) when in horizontal position
  • External walls - U = 0.18W/(m²·K)
  • Party walls - U = 0
  • Floors - U = 0.13W/(m²·K)
  • Roof - U = 0.11W/(m²·K)

Limiting values for replacement elements
  • Windows - U = 1.4W/(m²·K)
  • Rooflight - U = 2.2W/(m²·K)
  • Roof - U = 0.15W/(m²·K)
  • Wall - U = 0.18W/(m²·K)
  • Floor - U = 0.18W/(m²·K)
  • Doors - U = 1.4W/(m²·K)
While Approved Document L sets specific maximum U-values (heat transfer rates) for various building components in both new builds and renovations, it also offers some flexibility.

Individual elements like windows, walls, or roofs don't have to strictly meet these individual limits, as long as the overall energy performance of the entire building (the "notional dwelling") meets the target emission rate. This allows designers to optimise and balance the U-values of different components to find the most efficient and cost-effective solution for each project. 

Replacements (windows, etc.) must meet minimum efficiency values, even if the overall house doesn't. This applies to extensions too, unless thermally separated. 

The total area of windows, roof windows, rooflights and doors in extensions should not exceed the sum of:
i. 25% of the floor area of the extension. 
ii. The total area of any windows and doors which no longer exist or are no longer exposed because of the extension.

While Approved Document L sets specific maximum U-values (heat transfer rates) for various building components in both new builds and renovations, it also offers some flexibility.

Individual elements like windows, walls, or roofs don't have to strictly meet these individual limits, as long as the overall energy performance of the entire building (the "notional dwelling") meets the target emission rate. This allows designers to optimise and balance the U-values of different components to find the most efficient and cost-effective solution for each project.

Why is continuous insulation important?

Gaps in insulation are a key reason heat is lost in buildings, and also cause condensation and mould as cold and damp get in. Part L tackles heat loss by demanding continuous insulation.


Windows and doors should be installed:
  • With minimum tolerance while allowing the item to fit. In renovations, allowance must usually be made for the fact that the structure build up behind the window may not be known so tolerances may be larger.
  • Using fully insulated and continuous cavity closers installed tight to the insulation and cavity apertures. For door units, install perimeter insulation within the threshold zone or use a reinforced cavity closure.
  • In the insulation layer - that is, windows and doors overlap with the inner face of the external wall by a specific amount (30-50mm for windows, 50mm for doors). 

Why install windows overlapping with the insulation layer?
Traditionally, windows and doors were fitted flush with the outside of the wall. This creates thermal bridging and compromises the overall energy efficiency of the building. 

Overlapping windows and doors with the inner face of the external wall provides is optimal for several reasons:
  • Continuous insulation: the window/door unit becomes part of the continuous insulation layer, minimizing gaps and preventing potential heat loss areas. 
  • Airtightness: a proper overlap helps create better airtight seals around the windows and doors, further improving energy performance.
  • Thermal bridge mitigation: it reduces the potential for thermal bridging at the junction between the window or door and the wall.

why eliminate thermal bridges?

Eliminating thermal bridges is a key part of reducing heat losses because they create weak points in the building envelope, where heat can escape more easily than through surrounding areas.



Thermal bridges can create cold spots on interior surfaces, leading to drafts and uneven temperatures. This can cause discomfort for occupants, condensation, mold growth and other moisture-related issues, affecting the building's health and potentially causing damage. Crucially, the heat loss through the bridges can significantly outweigh the benefits of the well-insulated areas in a building's fabric.

What if I’m renovating my home?
For retrofit & renovation work in existing homes, minimise thermal bridges by following construction joint and junction details from a reputable database of independently assessed thermal junction details - the regulations recommend the Local Authority Building Control’s Construction Details library. 

Why is airtightness important?

What is air permeability?
The air permeability of a building is the rate that air passes through cracks or holes in its fabric to the outside. Air leakage from dwellings and air infiltration (cold draughts) accounts for between 25 to 40% of heating costs in the UK (source). More airtight buildings minimise unintended heat loss through gaps and cracks in the building envelope.

How is air permeability measured?
Airtightness in new dwellings is tested by a blower door test, which measures the rate at which air flows through a home or building. If there are many gaps in the home’s structure and seals, warm air is lost and unwanted draughts, mould, condensation and cold spots may occur.

What’s the limit on air permeability?
The notional dwelling specification for air permeability is 5.0m³/(h·m²) @ 50Pa. However, the maximum (worst allowable) air permeability allowed in new dwellings under part L is 8.0m³/(h·m²) @ 50Pa, a reduction from the previous limit of 10m³/(h·m²) @ 50 Pa. 

Air permeability is used to calculate all three critical measurements for Part L: the dwelling primary energy rate, CO2 emission rate and fabric efficiency rate - so compliance with airtightness is particularly important for new dwellings. Air pressure tests should be performed following the guidance in CIBSE’s TM23, the approved method for air testing. 


What are the new standards for heating systems in new homes?

Approved Document L encourages the use of low-carbon heating technologies like heat pumps (air source or ground source) to replace traditional gas boilers. It also promotes highly efficient boilers and hot water systems with good controls to minimise energy consumption, and provides guidance on insulating pipework in heating systems to prevent heat wastage. 

When a boiler or hot water storage system is replaced in an existing home, any accessible pipes should be insulated to prevent heat wastage. Insulation thicknesses should follow Table 4.4 found on page 31 of Approved Document L. 


What are the new standards for fixed building services?

Approved Document L sets standards for the energy efficiency of fixed building services such as lighting, cooling, and pumps. It promotes smart controls and monitoring systems to optimise energy usage.

For each building service type, there is system specific guidance set out in Section 6 of Approved Document L, which starts on page 39 of the document. 

When replacing any of these fixed services, the new system should meet or exceed the efficiency guidelines set out in Section 6 of the document. If the new system uses a different fuel to the previous service, it should produce no more CO2 per kWh of heat and have a primary energy demand per kWh of heat not higher than the appliance being replaced. 

What is the new guidance for on-site electricity generation?

Renewable energy sources and high-efficiency alternatives are encouraged, if they are technically, environmentally and economically feasible.

Where renewable technologies - such as a wind turbine or photovoltaic array - are used on-site, they should be an appropriate size for the site, infrastructure provisions and the on-site demands and installed to allow efficient operation without user intervention. 

When renewable technologies are replaced, the new system should produce at least as much electricity as the original system, unless it can be demonstrated that the new system is more efficient or appropriate (e.g. better suited to the property’s energy demands).

What about unique or specific types of building?

Listed & Historic Buildings
Work to listed buildings, monuments and those in conservation areas should comply with the energy efficiency and U-value requirements unless doing so would alter the building’s character or appearance in an unacceptable way. 

New extensions to historic and traditional dwellings should follow the energy efficiency requirements as far as possible if the extension needs to match the external appearance of the existing building. The energy efficiency of historic dwellings themselves should be improved only if doing so won’t damage or cause long-term deterioration of the building’s fabric or fittings - for example wattle and daub, cob or stone and lime rendered constructions. 

How do Part L and Part F of the building regulations interact?

Part L increases the energy efficiency of buildings by imposing requirements to achieve optimum airtightness. Part F imposes minimum requirements for ventilation to mitigate the negative effect of increased airtightness on ventilation and inhabitants’ health.

If possible, aim to install Mechanical Ventilation with Heat Recovery (MVHR) as a more efficient, airtight alternative to trickle vents for ventilation. 

Trickle vents will make a building less airtight and energy efficient than if MVHR is used because they do not have a heat exchange system. This is likely to lower the building’s overall SAP performance. Approved Document L offers guidance on natural ventilation strategies and the use of mechanical ventilation with heat recovery (MVHR) systems.

Norrsken: Triple Glazing for Energy Efficient Homes of the future


The Future Homes Standard is here. Part L is revolutionising new builds in England, lowering carbon emissions, prioritising eco-friendly heating, and boasting superior comfort. Norrsken windows and doors make it easy to achieve with:

  • Unmatched Energy EfficiencyNorrsken's bespoke alu-clad timber windows and doors surpass Part L and Future Homes requirements with ultra-low U-values for exceptional thermal performance. Combining airtight design, expert craftsmanship, and stunning aesthetics, they elevate your home in every way.  
  • Effortless Compliance: Build with confidence – our windows ensure effortless compliance with the new standard.
  • Sustainable Future: Invest in a greener tomorrow with windows that minimize carbon footprint.
  • Industry-leading service: Norrsken is known for exceptional customer service, providing dedicated support throughout your project, from initial consultation to installation and beyond. Read our outstanding reviews here.

Don't settle for the minimum. Build a future-proof dream home with Norrsken. Contact us today. 

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