Low Carbon Schools

ICAX supplied Interseasonal Heat Transfer to Howe Dell School in Hatfield and was involved in this project – to build a demonstration eco school – from inception.

Two of the directors of ICAX Ltd are CABE enablers for schools and have been involved in advising the UK government on construction of new schools with a low carbon footprint.

Everyone is now keen to construct new schools with a low carbon footprint and there are a number of different approaches that can be taken to reduce carbon consumption in new schools.

Energy Demands

The main energy demands from schools come from winter heating, summer cooling and electricity for lighting and computing. Part of these demands can be reduced by constructing well insulated buildings, sensitive use of natural lighting and careful control of electric lighting, heating and ventilation. These techniques can also be used to provide a sense of space and contribute to a comfortable internal environment conducive to learning.

Solar Thermal Panels

Solar panels for providing hot water offer a well developed technology with a low capital cost and a low running costs, but schools do not generally need a high volume of hot water.

Biomass Boilers

Biomass boilers are considered for heating because of their low initial capital cost (before considering the space needed for the boiler, the hoppers and access needs). However, such systems require on-going management and regular maintenance (over the whole life of the building). They need a good local supply of biomass fuel and can raise health and safely issues in the regular delivery of fuel to a school site.

Because biomass boilers take time to heat up and cool down they are best suited to continuous operation: this is not a perfect match for schools which are not generally occupied in holidays, at weekends or even in the evenings. A number of sustainability issues have also been raised recently in relation to using biofuels, so you will want to check that your source of fuel is local, reliable and not diverting resources from other sustainable objectives.

Biomass boilers are not able to contribute to the cooling needs that come with a well insulated modern building: this has become a critical issue in the first batch of BSF schools.

Ground Source Energy

A ground source heat pump can be used to provide heating. This option has strong merits where it can be designed into a new school building. There will be higher initial capital costs than the standard solution of providing heat from a gas boiler – or an oil boiler where no piped gas is available – but a Ground Source Heat Pump will deliver the ongoing benefit of lower running costs, provided the GSHP is matched to a well insulated building designed to use underfloor heating. This derives from the ability of a heat pump to extract more heat from the ground than the electrical energy involved in doing so.

Overheating Risks

There is, however, a potential difficulty inherent in providing a well insulated new building: a good design for retaining heat in winter can lead to excessive temperatures in summer – the examination season.

Building Bulletin 101

Recommendations for schools from the Department for Education (Building Bulletin 101) require that the internal temperature should never exceed 32°C and that there should be a maximum of only 120 hours a year where the temperature exceeds 28°C. There is also a need to hold internal temperatures to no more than 5°C above the external temperature. The ventilation requirements of Building Bulletin 87 also need to be met. It is very difficult to achieve these requirements with natural ventilation. This forces many architects to consider air conditioning in spite of budgetary constraints and all the adverse implications for running costs and further carbon emissions.

Alternative Approach

There is, luckily, an alternative approach which can help both with heating in winter and cooling in summer. This involves using ThermalBanks to store heat from the time it is plentiful (in summer) to the time when heat is needed (in winter). Equally a ThermalBank can store cold when it is in abundant supply (in winter) to the time when it is needed (in exams). At last there is a renewable way – an affordable way – of providing cooling to schools in the exam season.

ThermalBanks are an integral part of an Interseasonal Heat Transfer system that can solve both winter heating needs and summer cooling needs – and do both with a low carbon footprint. Instead of solving each problem separately at a high carbon cost, Interseasonal Heat Transfer can solve both problems together. IHT balances the excess temperatures of each season with the extreme differences collected and stored from six months earlier.

Lateral Approach – Integrating Renewables

IHT takes advantage of the merits of Heat Pumps to meet the needs of schools by performing a delicate temperature balancing act over the year, instead of fighting each need separately. This lateral approach saves money and saves carbon emissions.

IHT™ can save over 50% of carbon emissions compared to using a gas boiler for heating.

IHT™ can save over 80% of carbon emissions compared to using standard air conditioning and chillers for cooling.

Education for Sustainable Development

A further advantage of using Interseasonal Heat Transfer is exploited fully at Howe Dell School, where the building itself is used as an example of Education for Sustainable Development. See TES article. This is as a key part of the curriculum in teaching children to husband natural resources and respect the environment we live in. The children of Howe Dell were involved in and engaged in the design of their new school building from the start. Many of the materials used in its construction were locally sourced or make use of re-cycled materials. The Howe Dell eco-squad is very proud of the fact that its environmental principles have been extended to include the re-cycling of the heat in sunshine itself.


See: Howe Dell School | Suffolk One Sixth Form College

See also: Renewable Heat

See also: Renewable Cooling

See also: Natural Cooling

See also: Heat Recovery

See also: Renewable Heat Incentive

See also: How ground source heat pumps work

See also: Rechargeable Heat Battery