Designing to the Passivhaus standard can at times seem quite daunting and intimidating.  Understanding the basic principles of the strategy is key, to ensure that you can develop your design to meet the standard without being succumbing to abortive work.  This article outlines 10 broad design strategies to follow that will enable you to create a solid foundation from which your design can be developed, increasing your chances of meeting the required Passivhaus Standard.

01 Compact Building Massing

Keeping the surface area of your building to a minimum means that you will minimise heat loss, reducing energy consumption associated with space heating.  This is known as the Form Factor; the ratio of surface area to internal floor area.  The lower the Factor Factor, the more thermally efficient your building will be.  The key point here, is to ensure that the thermal envelope is minimised.  Simple vernacular forms work best.  This does not mean that you have to sacrifice architectural expression however, as this can be articulated via other means out-with the thermal envelope.

02 Location of Unheated Spaces

Co-locate unheated spaces such as stores, bin stores, bike stores.  Better yet, separate them from the thermal envelope altogether.  This way they do not act as a heat sink, drawing energy from the heated building and complicating your Form Factor.  Draw your thermal line and airtightness line around the building at an early stage to manage strategy and detailing, and continue to do so throughout the design process. 

03 Optimise solar gain in the Winter through Orientation

In the northern hemisphere, prioritise dual aspect, south facing facades to optimise solar gain during the winter months.  Anything beyond +/- 30 degrees is no longer considered a south facing façade by the PassivHaus Planning Package (PHPP).  Optimise fenestration and living patterns to take advantage of the path of the sun throughout the day.  Avoid overshadowing from neighbouring buildings and vegetation.  Consider species of vegetation as well as location.  Deciduous trees provide welcome shade in the Summer, whilst allowing solar gain from low angle sun in the Winter.

04 Design Glazing to balance heat gain, heat loss and daylight

Optimise your window design to consider orientation, daylight and summer comfort.  Poorly located, excessively large windows are the biggest cause of summer overheating and excessive heat loss in winter months.  On East/ West orientations, vertical solar shading devices are best, to the South horizontal solar shading devices should be used to control solar heat gain in the summer months.  Minimise heat loss to the north by having smaller windows, whilst taking advantage of solar heat gains via larger windows to the south orientation.  Designed in tandem with appropriate solar shading, this strategy will go a long way to minimise the energy requirement of the building.

05 Detailing of Windows

Optimise glazing to frame ratios to increase the thermal performance of the window by reducing the number of mullions and transoms.  Triple glazing is almost mandatory in the northern hemisphere to achieve the required U-value standards, so budget accordingly.  Windows should be located within the thermal line of the façade to minimise cold bridging and optimise detailing. 

06 Natural Ventilation

Try to design dual aspect rooms and homes allowing rooms to benefit from natural cross ventilation.  Also, consider night time purge ventilation strategies, particularly in bedroom spaces located on upper storeys.  This improves indoor air quality and well-being by optimising user control over their environment.

07 Mechanical Ventilation with Heat Recovery (MVHR)

The core plant in any Passivhaus, a suitably designed and installed MVHR system is fundamental to the successful operation of the building. 

MVHR units provide background ventilation by extracting moist warm air from kitchens and bathrooms, exchanging the heat to incoming cold fresh air, and then supplying the air to the other rooms in the home.  The MVHR unit should be located in a suitably soundproofed room, not more than 2m from the façade.  Design of ductwork and distribution is very important to ensure optimal efficiency of the system.  Designed correctly and in tandem with a highly insulated fabric, the MVHR system can be sufficient to provide the entire space heating requirement for the home, whilst ensuring a high indoor air quality.

08 Fabric First

The Passivhaus standard requires a highly thermally efficient envelope.  It is not prescriptive in how this is met however, allowing designers to consider a multitude of technical options to achieve the desired operational standards.  Accepted ranges of thermal performance  to aim for are as follows;

Ground Floor - 0.08 to 0.10W/m2k

Walls - 0.13 to 0.15W/m2k

Roofs - 0.10 to 0.12W/m2k

Windows - 0.80 W/m2k

External Doors - 1.0 W/m2k

These are stringent requirements and how you intend to achieve these should be carefully considered against design and budget constraints.  Aligned with this strategy is controlling thermal bridging interfaces in the design of the external fabric.  Once again, use your 'thermal line' to identify key interfaces that require attention in design to minimise the effects of thermal bridging.

09 Airtightness

Ensuring an airtight building envelope will drive improvements in construction, reduce energy demand caused by air infiltration and draughts, and protect the fabric of your building from premature decay.  There are several ways of creating an airtight building, from application of airtight membranes and tapes, to high performance lining boards.  The key design strategy is to draw an 'airtight line' on plan and in section around the façade, then focus and manage interface details between different systems and penetrations appropriately.  This must be undertaken at an early stage in the design process and followed rigorously through each stage to construction of the building.  Achieving an air change rate of 0.6 ACH is required to meet the Passivhaus standard and to ensure optimisation of the MVHR system.  This is a rigorous level, when compared to current building regulation requirement of 7.0 ACH.

10 Renewables - getting to net zero carbon

By designing the building to meet the Passivhaus standard, you have taken a significant step towards achieving a net zero carbon building. This is because the building envelope is already so energy efficient that only very low levels of space heating are required.  Following a Fabric First approach to achieve the Passivhaus Standard leaves only two more strategic steps to achieve Net Zero Carbon;

• Addressing Domestic hot water demand via solar thermal and/ or heat pump.

• Addressing electrical demand via implementation of a Photovoltaic array.

Following these 10 simple broad steps will ensure that you stand the best chance of achieving the Passivhaus Standard.  You might even get to a Net Zero Carbon home, thus helping in the country's drive towards meeting our 2035 Net Zero Carbon energy targets.  At the very least, if you implement some of the strategies, you will have a building or home that is far more energy efficient than the majority of buildings under construction today.  All that is required is the implementation of a few simple steps.  At Novo, we are happy to assist clients in whatever capacity they require to develop the strategies required to realise an energy efficient building.  Please reach out to us by clicking on the button below if you feel we could be of help.

Whilst the Coronavirus pandemic has shifted our focus from the potential impacts of Climate Change over the last 12 months, it has certainly exposed us to a heightened sense of vulnerability, particularly in Western culture.  Whilst we begin to look forward to a post-pandemic world in 2021, the hope is that this renewed sense of vulnerability in the developed world can be harnessed to embolden us to tackle the even bigger threat of Climate Change.  Below are 5 strategic reasons as to why we consider 2021 to be a very important year in our bid to control our impact upon Climate Change.

Glasgow 2021

In November of this year, the world will gather in Scotland to determine, with legally binding agreements, how we intend on a country by country basis, to cut our carbon emissions to limit global temperature rises to 1.5C above pre-industrial levels.  Currently, we are due to breach this important ceiling within the next 12 years.  Under the Paris 2015 climate accord, participating countries agreed to review emissions every 5 years.  Glasgow 2021 is therefore a globally significant meeting that must be successful if we are to have any chance of avoiding catastrophic Climate Change within the next 2 decades.

Political Context is Changing

Amongst the darkest days of the pandemic in 2020, an important gesture was presented to the World that gave us hope.  Chinese President, Xi Jinping, announced that China aimed to be Cardon Neutral by 2060.  In a single announcement, the world's largest emitter of carbon dioxide, consented to join the world in decarbonising their economy.

China's announcement came on the back of a string of the world's largest economies and carbon emitters promising legally binding net zero carbon commitments.  In June 2019 the UK committed to a carbon neutral economy by 2045, Scotland went one better by committing to this by 2035!  The EU has committed to net zero carbon by 2050.  To date, more than 65% of global emissions, representing 70% of the world's economies, has committed to being carbon neutral by 2050.

Perhaps most significantly of all, last week, President Joe Biden of the United States of America, confirmed the USA's intention to rejoin the Paris Climate Accord of 2015, undoing the damage of the Trump administration's exit from the agreement in 2016.  In one executive order, President Biden turbo charged the potential for what could be achieved in Glasgow at the end of the year.

Cheap Energy

2021 may be the year considered a tipping point; the year that renewables began to make absolute economic sense.  As wind, solar, hydro and battery technology begins to ramp up, so the cost of installation tumbles through economies of scale and technological advancement.  When it comes to building power stations, renewables are now often cheaper than their fossil fuel equivalents.  According to the US Energy Information Administration, half of electricity will be from renewables by 2050.

As this scales, institutional investors will increasingly push their money to these technologies, divesting from fossil fuels.  Like a fly wheel, the transition will only gather pace.  Already we can see the effects of this in the performance of stocks such as Tesla and the collapse of companies such as Exxon.

Covid-19

The pandemic has given the world economy the greater economic shock since the great depression of the 1930s, greater even than the financial crisis of 2008.  Interest rates have collapsed, industries and businesses are in free fall .  But in every economic crash there is opportunity.  Cheap interest rates are allowing governments to invest heavily in new green opportunities to decarbonise their economies.  This is an unprecedented opportunity for the world to reprioritise with the burden of our fossil fuel economies weighing slightly less.  Due to Covid-19, we have already suffered the financial shock of decarbonising.  Now is the opportunity to invest in our new carbon neutral economy as we move out of recession.

The Business Case

A cornerstone of Glasgow 2021 will be ensuring that the world's financial structure is motivated to invest in a decarbonised economy.  Mandatory action for business and investors to ensure that their activities and investments are making the necessary steps to decarbonise, to reach net zero, is a must.  The stock market is already beginning to show that the investment culture is changing.  In order to ensure the rate of change required is maintained, this must be legally binding in the financial architecture of world markets.  Glasgow 2021 presents our single opportunity for the next 5 years to make this happen.

The Covid-19 global pandemic has at time of writing cost the lives of in excess of 1 million people in a very short period of time.  It has resulted in the greatest financial shock in living memory, including two world wars.  What it has done is bring us closer together as a world community with a shared purpose and vulnerability.  In 2021 we need to harness this shared purpose and sense of community and use the opportunity as we navigate out of this global crisis, to effectively tackle Climate Change, our greatest challenge yet. 

In November, our small country will once again have the eyes of the world community focused upon it.  We as a nation, have always punched above our weight.  Glasgow 2021 is our opportunity to lead once again and ensure that we do all we can to protect our world from the ravages of Climate Change.

This article is our third in our series discussing Passivhaus 'fabric-first' design principles to improve the energy performance and quality of our buildings.  Focusing on Passivhaus Windows, the article highlights the technical requirements of a Passivhaus Window, design detailing and finally discusses the advantages to health and well being experienced in buildings incorporating such systems.

Windows are by necessity a requirement in any building.  They have to provide as a minimum daylight and to frame views, but they also play a particularly significant role in the energy performance and thermal comfort of a building.  With its emphasis on building comfort, healthy living environments and energy performance, the Passivhaus Standard is particularly demanding when it comes to appropriate specification of glazed elements within your design.

Technical Context

In order to better understand how a Passivhaus Window assists in meeting the standard, it is broken down into various technical performance parameters. 

Solar Gains

Designing to optimise solar heat gain in northern Europe is a fundamental principle of successful Passivhaus design.  Size and orientation of the window on the site are important in this regard and under the control of the designer.  The solar heat gain of the glass (or g-value), a measure of how much heat energy the glass allows to enter the building, is also important.  Passivhaus Windows need to have g-value to suit the building location and climate. In northern Europe, this would typically be 0.5 or higher. 

Losses

Just as gains are important, so are heat energy losses.  The measure of a window's heat loss is its U-value, calculated as an average for the whole window - glass, frame, spacer and installation. 

The glass unit in northern European climates is required to have a u-value of 0.7W/m2K or lower to meet Passivhaus Standards.  In order to achieve this the glazed unit will often be triple glazed and require an inert gas such as Argon or Krypton to be sealed between the panes.  This results in a very heavy window which places particular requirements on the frames and can limit unit size commercially.

The frame is a linear element and as such is given a Psi-value (linear heat transfer coefficient) to determine its thermal performance.  The psi-value required of a certified frame must be at least 0.2 W/mK.  In order to achieve such values, frame manufacturers often use complex thermally broken frames.  Materials used are generally UPVC, Timber or Aluminium. 

The second component in determining the psi-value of the frame is the glass spacer.  This can be vitally important.  In standard double or triple glazed units, often aluminium spacers are used.  However, these are highly thermally conductive causing significant heat losses.  Passivhaus windows therefore often incorporate plastic or composite spacers to counter this.

Finally, careful interface detailing is required between the window and the wall system to ensure that there are no thermal bridges occurring between the window frame and the wall itself.  Consideration of the position of the window relative to the thermal layer of the wall is required to manage this key interface and limit heat transfer through the frame and window reveals.  This is vitally important to ensure condensation does not build up promoting mould growth and damage to the fabric of the building.

Once all of the above has been considered, the Passivhaus Planning Package assessment tool (PHPP), will arrive at an Installed U-Value.  In northern Europe, this value is set at 0.85W/m2k. 

Thermal Comfort Context

But what do all these U-values and psi-values actually mean in the real world? 

The thermal performance of a wall is much higher than a window, the window transmitting more heat than the wall.  This can cause three main areas of discomfort for occupants; 

1. Draughts. Not caused by wind or poorly sealed windows, but by temperature differential. Warm air in the room contacts the cold window surface and cools down, sinking to the base of the window. This creates the feeling of a draught. Indeed, this is why radiators are often located below windows.

2. Temperature Asymmetry. If a human experiences a temperature difference of around 4.4 degrees between their head and their feet, then they will feel cold, regardless of the temperature of the room.

3. Heat loss from our body radiating out towards the colder surface of the window will make us feel cold also.

Passivhaus Windows counter the above through their improved performance requirements over 'standard' window units.  A certified Passivhaus Window will only allow a temperature difference of 4.2 degrees cooler than the average internal surface temperature resulting in no draughts, no temperature asymmetry and no excessive heat loss radiating towards the window.  The result?  Improved thermal comfort.

Health Context

The requirements of the Passivhaus Standard also ensures that the window installation promotes a healthy internal environment.  By limiting  thermal bridging and condensation, the risk of mould build growth on window surfaces, so often prevalent in 'standard' constructions, is eliminated.  The high thermal performance of the window coupled with effective interface design, maintains internal surface temperatures and relative humidity at a level that ensures condensation and mould cannot form.  This enhances health and well being for the occupants, but also protects the building fabric, improving durability of components.  

Consideration of a Passivhaus Window for your building whilst expensive, will give unrivalled thermal comfort, reduce energy bills, protect the building fabric and will more than likely, last longer when compared to conventional double glazed systems.  There are many manufacturers now producing Passivhaus compliant systems.  If you would like further assistance in determining whether or not such a system is appropriate for your Project, please simply get in touch by clicking on the button below.

This article is our second in our series discussing Passivhaus 'fabric-first' design principles to improve the energy performance and quality of our buildings.  Focusing on the External Wall, the article highlights the general strategies prevalent today with a focus on Timber Frame Structural solutions, the most popular here in the UK.

Design Principles

The Passivhaus Standard has very stringent requirements with respect to meeting the energy demand of the building when compared to more conventional building standards (Primary Energy Demand of </= 120 kWh/m2.yr and Space Heating Demand </= 15kWh/m2.yr).  In order to meet such demands the thermal performance of the building envelope has to be optimised to achieve the following values;

• U-value of 0.15 W/m2k or less

• Airtightness of 0.6 air changes/ hr @n50 or less

The building envelope therefore must have;

• Very high levels of insulation

• Airtight building fabric

• Windtight building fabric

• Thermal bridge free construction

Within the standard there is no limitation on how these values and criteria can be achieved, allowing creativity in design and multiple building systems to be considered.  By far the most cost effective system for domestic building in Northern Europe however, is Timber Frame Construction.  Within this 'system', the parts themselves are interchangeable, providing the opportunity to choose from a vast array of different elements and components to achieve higher levels of performance and economy.  Such systems are light weight, easy and quick to transport and construct and are robust.  Whilst there are many derivatives of timber frame construction, all are characterised by an internal zone for running services and applied internal wall finishes and an external cladding zone capable of supporting a wide variety of external cladding systems to meet aesthetic and regional requirements.

Broadly speaking, timber frame construction is split into two approaches, open panel construction and closed panel construction.  Open Panel construction relies upon simple open stud framework being erected, then insulated and clad on site.  Closed panel construction optimises the advantages of offsite manufacture, forming modular panels in a factory complete with an enclosed structure, insulation and protective sheathing layers to the internal and external face of the panel.  Open Panel is often slightly cheaper, but Closed Panel construction offers the benefits of improved build quality.

Open Panel Construction

In order to meet the stringent thermal requirements of the Passivhaus Standard,  open panel systems will typically be constructed from 184mm deep timber studs, supplemented by additional thermal layers of insulation placed externally or internally to alleviate thermal bridging through the timber studs impacting upon the overall U-value of the assembly.  This allows a wide use of insulation material to be considered, dependent upon cost, performance and environmental strategy.  A typical assembly comprises the following; 

• External cladding zone

• Windtight, breather membrane

• OSB Sheathing board

• 184mm timber studs at 600mm centres

• Insulation infill

• Airtight and vapour control layer (membrane or board)

• Supplementary thermal insulation layer

• Service void

• Internal wall finish 

Advantages

• Low cost

• Leveraging common construction skills

• Versatile

• Medium speed of construction

• Flexibility in design

Disadvantages

• Highly dependent on site supervision

• Required build quality hard to achieve

• Slow erection times when compared to other methods

Closed Panel Construction

Optimising the advantages of offsite manufacturing techniques, closed panel construction is becoming increasingly popular.  Broadly speaking there are three types of system used.   

Closed Panel System 01

Essentially an offsite version of an open panel system, many suppliers now offer what can be considered an entry level closed panel system.  Typically the panel is supplied with both external and internal sheathing boards fitted with the panel being fully insulated.  In some cases external cladding rails and finishes can also be applied subject to logistical constraints.  These systems can also take advantage of manufactured I-Joists replacing the traditional 184mm stud.  These can provide a deeper wall, increasing insulation and reducing thermal bridging through the stud.

Closed Panel System 02

Another way of increasing the levels of insulation beyond a standard 184mm stud whilst also minimising thermal bridging through the structural timber elements of the wall is via a split-stud or twin stud wall.  In this construction, two lines of studs 90mm wide are placed tied together at intermediate heights of 600mm vertically.  This allows any depth of wall to be constructed to achieve the required thermal performance of the construction.  Other advantages include optimising the integration of intermediate floors and roofs to minimise thermal bridging and improve the thermal performance of the entire structure.  Beyond the structural layer, the system shares the same characteristics of other timber frame systems.

Closed Panel System 03

The final closed panel system is a Structural insulated Panels Systems or SIPS for short.  SIPS panels comprise high density EPS or Foam insulation and timber studs sandwiched between two layers of sheathing board, typically OSB board.  The result is a composite panel of high strength and thermal performance capable of large spans.  These panels are able to be used as walls, roofs and even floor cassettes.  Manufactured under factory conditions, the panels are quick and easy to transport and erect on site, achieving wind and watertight status very quickly.  They are best suited to modularised simple forms, their efficiencies quickly compromised when more complicated forms are desired.

Advantages

• Speed of construction on site is high

• Whole façade option

• Improved build quality

• Modular build

• Building performance generally improved

Disadvantages

• Can be costly

• Specialist structural input required

• Supplier choice scarce

• Can be inflexible due to modular build strategy

• Can require specialist erection team

In June of 2019 the UK became the first major economy in the world to commit to producing net zero greenhouse gas emissions by 2050.  Enshrined in Law this means that all industries, including construction, must operate at net zero carbon by 2050.  Indeed in Scotland, the devolved administration has committed to a date of 2045.  Some cities such as Edinburgh and London, have even more aggressive targets of 2030 in mind.  To meet these targets the built environment, in particular our homes, will have a continuing requirement to meet increasing energy efficiency targets.  The net result of this will be a continued drive towards off site manufacturing techniques such as the ones described in this article, to ensure post occupancy energy performance targets are met. 

The above systems are all capable of providing an energy efficient façade and are becoming increasingly popular in the UK, in particular in the Self-Build Home sector.  Choice is available.  All are capable of delivering a building performing to the Passivhaus Standard.  Choice will be dependent upon a combination of factors including cost, speed of construction, technical expertise of your team and complexity of design.

If you have found the above article useful and would like to understand more about the Passivhaus Standard, we would encourage you to read the other articles in our blog available at www.novo-design.co.uk/blog.  Alternatively you can join our mailing list below.

This article is the first in a series discussing how integrating Passivhaus ‘fabric first’ principles vastly improves the energy performance and quality of our buildings. Focusing on foundation design, the article highlights the three broad design strategies employed to optimise the thermal performance of the building.

Context

As energy performance goals begin to rise, the potential for heat loss through the base of buildings has come in to sharp focus.  Concrete basement walls, stem walls and slab edges can no longer be left exposed to winter air or frozen soil near the surface compounding thermal bridging, causing significant condensation and mould growth at key interfaces.  Infiltration of cold air up through suspended floors has also been identified as a problem.

In answering such design challenges, designers proposed insulating the building perimeter down to a sufficient depth that the temperature differential between the soil and the foundation system was no longer considered a problem.  Alternatively, insulation could be extended out horizontally from the building perimeter just below grade level.  This protects the soil mass directly under the building perimeter from heat loss to the surface.  Combination of these techniques is still in use today.

To meet Passivhaus standards in harsh climates such as those experienced in central and northern Europe, it is necessary to completely isolate the foundation system from thermal contact with the soil.  In addition, perimeter drainage systems are required to reduce fluid pressure against such foundation systems as well as protecting the integrity of embedded barriers and materials within the system from soil that would otherwise be saturated with water.

Design Strategy

The core design challenge is to maintain thermal isolation between the structure and grade whilst transferring loads from the building via walls and columns to the foundation.  The most straight forward approach is to surround the entire  foundation in insulating material.  This approach allows the mass of the foundation to hold the building down assisting detailing with all connections to the slab within the thermal envelope.  It also has the added benefit of the slab acting as a thermal store for the building, enabling internal temperatures to be regulated more easily.  Design challenges present themselves at interfaces with door openings and external landscaping, but these can be easily resolved via simple flashings and appropriate detailing to protect the integrity of the exposed insulation at the slab edge.  There are numerous systems like this on the market presently from suppliers such as Kore Insulation and Isoquick.

A second strategy available for consideration is more of a hybrid of traditional strip foundations and the insulated slab outlined above.  In this strategy, a conventional strip foundation, common in the UK, is installed with insulation extending down both sides of the sleeper wall (whether cast concrete or concrete block on a footing).  This does not eliminate thermal conductivity through the base of the footing, but it does reduce thermal losses at the key interface with the ground floor.  This option is popular as it is familiar with traditional foundation practices and can reduce concrete quantities.  However, interfaces with other systems such as membranes and fixings are more complicated and difficult to control.

Where large amounts of concrete are considered undesirable or not possible for logistical or financial reasons, suspended timber ground floors with a ventilated air space below to control moisture from the ground are still possible to meet Passivhaus standards.  With similar design challenges presented by the hybrid solution outlined above, care should also be given to maintaining integrity of the membrane and perimeter insulation at the interface with the required ventilation slots to promote airflow to the subfloor.  This adds construction complexity, but if executed well, can provide a robust lightweight ground floor construction that performs well.  Care should also be taken to ensure infiltration of cold air from the subfloor is eradicated through the inclusion of an airtight layer of appropriate board or membrane.

The three broad strategies outlined above if executed correctly, will provide a sound thermal bridge free foundation from which to realise your Passivhaus building.  It is important to understand that the foundation is the first area where the thermal integrity and, by extension energy use, of the building is challenged.  It is vitally important that clear dialogue of the building's energy strategy is communicated to the design team, in particular, the Structural Engineer and Architect, to ensure that all the hard work undertaken in the design and performance of the Superstructure is not lost at the key interface with the ground.

If you have found the above article useful and would like to understand more about the Passivhaus Standard, we would encourage you to read the other articles in our blog available at www.novo-design.co.uk/blog.  Alternatively you can join our mailing list below.

This article focuses on concise responses to 5 frequently asked questions that I get asked about the Passive House Standard.

What is passive about Passive House?

Passivhaus is a building design strategy targeted at achieving specific stringent energy performance standards.  The result is a Passive House that requires very little energy to maintain a constant pleasant internal environment within which to live.  In this sense, such dwellings and commercial buildings can be considered 'passive' as they need very little active heating or cooling to remain habitable by virtue of their design.  This is predominantly achieved via the implementation of intelligent design and execution on site, high insulation levels, high performance windows and doors and efficient heat recovery systems.  A good analogy is a cave, cool in summer and warm in winter.

Why build airtight?  Don't buildings need to 'breathe'?

Conventional building methods are susceptible to high levels of air infiltration, perceived in the worst cases as draughts.  Whilst this provides 'ventilation' it is uncontrolled, uncomfortable, leading to high heat energy loads and poor air quality indoors.  This often necessitates the opening of windows regularly for extended periods to 'get some fresh air'.  An airtight building envelope gives the occupant ultimate control of the ventilation of the building, eliminating draughts and reducing the heat load on the building significantly.  It also protects the building structure, preventing condensation build up and resultant mould growth.  The mechanical ventilation system in an airtight building can deliver clean fresh air to rooms where it is needed and remove moisture laden air where it is not needed.  It can also recover waste heat from this air and reuse it within the building, reducing heat load demand further.

Can you open the windows in a Passive House?

One word.  Yes!  In conventional buildings, occupants often open windows to get 'fresh air' and remove stale indoor air.  In a Passive House, airtightness and the mechanical ventilation system ensure that indoor air quality is maintained continuously, regardless of the temperature outside.  The result is that occupants in a Passive House are less likely to want to open windows.  Nevertheless, they can  if they wish.  An added benefit, is that the filters installed in the mechanical ventilation system remove pollutants, VOCs and pollen from the incoming air, improving the health of occupants.

What is so special about Passive House windows?

Conventional buildings today, tend to have double glazed windows with one or two seals.  This often leads to large temperature differentials at the window, cold draughty frames and condensation in poorly ventilated buildings.  In cool temperate climates, such as the UK, Passive House windows tend to be triple glazed, with thermally broken frames and often with three seals.  Such high quality windows let more of the sun's heat energy in (solar gain) than is let out in the winter months.  The temperature differential at the window between indoors and outdoors is far less, resulting in no condensation or feelings of draughts.  Orientation of the windows must be optimised to take advantage of these solar gains and protection measures considered to avoid overheating in summer.  Even in the UK, a poorly designed Passive House can lead to overheating in Summer months if protection from solar gain is not considered during this time.

How comfortable are Passive Houses in Summer?

Due to their high thermal mass and high levels of insulation, Passive Houses protect their occupants from hot summer conditions by keeping outdoor heat from entering the building.  The high thermal mass of such buildings acts like a cave, storing heat slowly during the day and dissipating it at night.  As alluded to above, careful design of window orientation and solar shading devices is often implemented to reduce overheating caused by solar gain.  Indeed, the Passive House standard requires that the indoor temperature of the building does not exceed 25 deg C for more than 10% of the year.  In the summer months the ventilation system often is switched to a summer-bypass which disengages the heat recovery option, enabling further control of the indoor temperatures.  In essence, when optimised, the design strategy supports a comfortable summer environment indoors.

In closing the Passivhaus Standard is a simple uncomplicated design strategy that ensures a well built, low energy home that is comfortable and healthy to live in.  There are many more questions that we get asked, so if you have any please do get in touch and we would be happy to answer them. 

If you have found the above article useful and would like to understand more about the Passivhaus Standard, we would encourage you to read the other articles in our blog available at www.novo-design.co.uk/blog.  Alternatively you can join our mailing list below.

Building Information Modelling, or BIM for short, is rapidly gaining traction in the construction industry, but what exactly is it?  This article provides a brief explanation of BIM for our clients, outlining how Novo is integrating the processes and tools into our workflow to provide our clients with an improved optimised service and experience.

BIM is simply a process for creating and managing information on your construction project across the project life cycle, from design inception, to construction, to management of the building in-use.  One of the key outputs of the process is the Building Information Model, a digital entity describing every aspect of the built asset.  The model is not simply a 3D computer generated model, but rather should be considered as a 5D coordinated repository of information assembled collaboratively, updated and coordinated by all members of the team throughout the project life cycle.

At Novo we have been using BIM software for nearly a decade.  However, it is only in the last 2 years that we have really started to ramp up integration with other members of the design team.  BIM enables us to bring together all of the information about every component of a building, in one place.  This makes it possible for anyone to access that information for any purpose, e.g. to integrate different aspects of the design more effectively.  In this way, the risk of mistakes or discrepancies is reduced, and abortive costs minimised.

BIM data can be used to illustrate the entire building life-cycle, from inception and design to demolition and materials reuse.  Spaces, systems, products and sequences can be shown in relative scale to each other and, in turn, relative to the entire project.  And by signalling conflict detection BIM prevents errors creeping in at the various stages of development/ construction.  We also use it for thermal modelling of the building, to inform and optimise our design solutions to provide a low energy use solution. 

Our two principle tools that we utilise in our BIM workflow are Archicad and NBS Chorus, our computer aided design software and specification software.  These tools integrate seamlessly with each other to create a digital model rich in data and interoperability for the design team to utilise.  The model enables us to produce a comprehensive set of coordinated information in real time.  It assists us with design explanation, detailing, thermal modelling, coordination, cost control and construction sequencing.  At project handover it provides the client with a detailed digital record of all aspects of the building allowing them to manage and maintain the asset appropriately.

Advantages for the Client

• Improved design decision making through 3d modelling

• Reduced costs by managing and minimising errors in the digital environment first

• Reduced in-use energy costs through innovative thermal modelling

• Cost certainty at each stage of the design process

• Better management of the building during occupancy

To date, due to cost of implementation, BIM has generally been reserved for larger projects.  In our Studio, we are certainly convinced that the early implementation of BIM into our workflow on smaller projects has greatly improved the quality of our service for our Clients.  In some ways this is innovative on such a small scale, however we are excited by the possibilities that it promises.  Moving forward it is our intention to rollout live interactive cost modelling to provide  increased cost certainty on projects.  With each component having an identifiable cost, quantities and cost management will be greatly improved for our clients.  Further development will also look at closing the gap between design model and site construction and assembly, exploring the possibilities of off-site manufacture.  In this way we look forward to having a greater influence on control of quality and performance of the final built asset.

All of our new projects will be integrating BIM protocols. If you feel that your project could benefit from this innovative tool we would love to assist in any way that we can, just contact us below.

Innovation costs associated with early Passivhaus projects are now reducing as the methodology has become more widely adopted.  This article discusses the findings of a recent study to determine exactly what building to the Passivhaus Standard costs.  It will highlight the principle areas of cost in a Passivhaus, and focus on key design and project management strategies to follow to minimise the cost of your dream home.

Generally speaking in the UK, the cost for a new build, architect-designed bespoke home will be in the region of £1,650 - £1,800 per square metre.  This does not include land acquisition costs or professional fees.  Therefore, a typical 4 bedroom house of 150 square metres will cost in the region of £250k to £270k.  This will get you a 'standard' specification home built to UK Building Regulations.

But what are the costs of wanting to build a home that is better for the Environment, a so called EcoHome.  We have written previously about the Passivhaus Standard, a voluntary building standard that ensures a highly energy efficient building via a fabric first approach.  In 2019 the Passivhaus Trust published a report into Passivhaus Construction Costs.  This study confirmed that there has been a consistent trend in Passivhaus costs reducing in the last 10 years.  As of 2018, best practice costs were only 8% higher when set against comparable homes built to minimum Building Regulation standards.  Indeed the report concludes that at scale, such costs could be reduced to a 4% premium.  

What exactly drives this additional capital cost?  The Passivhaus standard does not rely on fancy bolt on eco technologies to minimise energy use, rather it focuses on an energy efficient fabric, focused design strategies and exceptional build quality.  Due to this costs will increase when compared to 'standard' construction.  The practical reasons why a Passivhaus will cost more than a traditionally built house are;

• There is often more insulation being used in floors, walls and roof.

• Windows and Doors are of a higher specification, typically triple glazed.

• The ventilation strategy often relies on mechanical ventilation with heat recovery (MVHR)

• Addressing the required Airtightness requires additional semi skilled labour and products.

By investing a little extra in the above however, you can take advantage of significant benefits such as;

• Simpler mechanical infrastructure due to reduced heating requirement

• The home will use less energy, reducing fuel bills and carbon emissions, making you more energy secure

• The home will be healthier, more comfortable with little temperature variation.

• The higher build quality will lead to lower maintenance costs.

• Your home will be worth more. As energy use becomes more and more important in the housing market, prices will begin to reflect running costs.

The PHT study of 2019 also had several key findings in regard to assisting future adopters of the Passivhaus Standard manage the cost of their Project.  Strategically their findings focused on design and early buy-in from the construction team.  The top 10 ways to minimise costs were;

1. Passivhaus needs to be part of the initial brief before a design is conceived.

2. Employ experienced Certified Passivhaus Designers

3. Keep it simple

4. Ventilation design and coordination is important

5. Consider summer comfort, even in the UK! Do not underestimate this.

6. Airtightness is key.

7. Work with a team that 'get it'.

8. It is more than just design. Construction is just as important.

9. Collaboration

10. Appoint a certifier early if you wish your project to be officially certified.

 If the above article is of interest and you would like to know more, or if you feel that we could assist you with your new home, we would be happy to help. Just click on the button below to contact us.