Martina Arata of Sturgis Carbon Profiling explores ways in which the hospitality industry can meet guest expectations while delivering low-carbon hotels

Whole-life carbon: Hotels

01 / Introduction

Sturgis Carbon Profiling鈥檚 research into the hospitality industry with The Portman Estate and Z Hotels has revealed that the methods used to tackle energy use in hotels may soon not be enough.

The hospitality industry has implemented most of the significant measures available to reduce the energy demand in hotels. However, despite its best endeavours, returns are becoming incresingly marginal. Any further gains will be to the detriment of the guests鈥 comfort, something that is unpalatable in the hospitality industry.

In this article we illustrate the different approaches to reducing the carbon footprint, analysing measures that are already implemented by most hotels and the results achieved. Subsequently, we will demonstrate how a series of less invasive options can be introduced. These will leave the guests unaware of the reduction in carbon emissions and keep satisfaction high.

Recent research that we have conducted in central London has revealed that a complete rethink of accommodation could be the solution. By focusing on space redistribution, easily maintained finishes and specification of carbon-saving options at the design stage, this research suggests that there is potential to reduce the carbon footprint by 68% without costing hotels a penny.

Whole-life carbon assessment: A brief recap

British Standard BS EN 15978 identifies four stages in the life of a building - product manufacture, construction, in-use and end-of-life. More detailed sub-categories pinpoint specific sources of 鈥渃arbon鈥 (expressed here in kg CO2e to refer to a wider range of emissions that damage the atmosphere).

  • The first stage encompasses the extraction of raw materials, their transport to a point of manufacture and the process of transforming them into construction products.
  • The second involves transporting construction products to site and the on-site processes involved in assembling them into a building.
  • The third stage includes maintenance, repair, replacement and refurbishment of the building, as well as the use of energy and water during its occupation.
  • In the final stage, the building is deconstructed and its redundant components transported off site, processed and disposed of.

At each stage, whole-life carbon analysis can identify solutions with lower carbon impacts, delivering considerable savings overall.

Broadly, the term 鈥渆mbodied鈥漴efers to carbon produced during manufacturing, construction and maintenance of a building, while 鈥渙perational鈥 identifies the carbon emitted by heating, cooling and generally running the building.

02 / Scenarios

Scenario A - benchmark

The baseline study is a three-storey newly built hotel, with reinforced concrete structure and aluminium rainscreen cladding. It has approximately 80 bedrooms, most of which are double. It is estimated that the average room is 21-25m2 and the occupancy rate is 80%.

Scenario B - operational only focus

This scenario represents the mainstream approach to reducing carbon emissions, as presently undertaken by the hospitality industry. It includes low-emission light bulbs, high-pressure low water usage showers, key activated power to guest rooms and 鈥淪witching on to Switching off鈥 programme, which is designed to raise awareness of energy use in the workplace.

Figure 1: Scenarios A and B

Scenario C - efficient hospitality concept

This approach has been developed in conjunction with Z Hotels and is based on a reduction of maintenance and increase in efficiency of design and space. The driving concept behind it is the increase in density of hotels, with the reduction of the individual unit from 20-25m2 to 16m2. While maintaining a luxury finish, this is delivered via modular design. The space is saved by better organisation and suitable bespoke furniture to fit a more compact layout. Furthermore, the specification targets more durable, less maintenance-intensive materials, as well as focusing on the construction of the building itself.

Figure 2: Scenario C

03 / Efficiency of design in hospitality

Design

A brand new hotel should take into consideration some simple measures to reduce the embodied carbon emissions of the building. These, if considered at design stage, will not compromise the final result - and as we have demonstrated on various projects need not influence the overall cost either. However, they can save a considerable amount of carbon over the life of the building. The embodied carbon of a typical new build accounts for about 40% of the overall emissions. A 30% carbon reduction can be achieved through strategies such as the use of natural materials for cladding or insulation, higher recycled content for specified metal components and plasterboard, or changing the type of aggregate in the concrete (such as regraded aggregates from demolition sites).

Maintenance

The continued maintenance and refitting that a hotel undergoes throughout its life produces as many emissions as operational energy. For example, walls are repainted every three-to-six months, carpets in hallways and common areas are changed every 18 months, and there is a stream of broken furniture to be replaced, linen to be renewed and lights to be swapped. Once again, through design and specification of durable materials, the cost of maintenance in carbon terms can be almost halved. For high passage areas, such as the reception and lobby, stone floor finishes provide aesthetic benefits, are relatively easy to maintain and very durable and individual tiles can be replaced easily with minimal disruption. In some areas, such as bedrooms, stone floors are not an option. Engineered hardwood finishes can be a viable choice, with a 10-15 year guarantee of durability for most products. Where carpet is desired, specifying recycled felt underlay could have a significant impact in reducing carbon emissions without compromising the look.

Whole-life carbon: Hotels

Money should be spent on features that will contribute to the wow-factor without being worn or in regular need of replacement - for instance chandeliers or art features in the lobby. Hotels do not need to be spartan to be low carbon.

Space

The most important concept to explore is space distribution, with high density achieved through well-planned rooms and an efficient back of house. Z Hotels has been rethinking the hotel model, with compact layouts in central locations that maintain the high quality expected by guests, reducing cost per stay and ensuring high occupancy rates.

Retrofitting

Although the current scenarios refer to newly built hotels, the core concepts can be applied to retrofitting and refurbishing, including for most of London鈥檚 central hotels. This is being put into practice by The Portman Estate鈥檚 refurbishment of several listed hotels on Gloucester Place. Sturgis Carbon Profiling assessed the proposals, and is supporting the design team in reducing embodied carbon, in addition to a reorganisation of space based on the Z Hotels concept.

04 / Findings

Figure 3: Comparison of scenarios per squared metre

Figure 4: Comparison of scenarios per person per night

The graphs above shows considerable differences between the whole-life carbon of the three scenarios. The most pertinent findings are as follows:

  • The average hotel costs more in energy and heating over 60 years than it does to be built. Maybe for most this is not such a surprising fact. Less obvious perhaps is that constant maintenance and refurbishment of the hotel costs approximately 拢120,000 every year - equivalent to the utility bill of an average dwelling over 100 years.
  • When applying energy demand reduction measures to the benchmark scenario, we obtain an 11% decrease in carbon emissions for the whole building over its entire lifespan. This relies on the options being applied correctly and staff and guests following the sustainable plan put forward by the hotel鈥檚 management.
  • If the embodied carbon of the building is tackled as well, a reduction of 25% can be achieved, at no expense to the guests鈥 comfort and without the involvement of staff, as it would be inherent to the building鈥檚 fabric.
  • When changing the unit of measurement from square metre to occupant, a drastic decrease in carbon emissions becomes apparent between the benchmark and the 鈥渆fficient hospitality鈥 scenario. Consumption per guest per night falls from 14kg CO2e per person per night to 5.5kg CO2e.
  • Hotels that only address the reduction of operational emissions risk compromising the comfort of guests, which is the primary concern of the hospitality industry. Basic green programmes, which include items such as low-energy light bulbs, key card systems to switch off the power in unused rooms and aerated showers to reduce water demand, are laudable, but represent only a fraction of potential savings.

Key measures for 鈥榚fficient hospitality鈥

  • High proportion of ground granulated blast furnace slag for concrete elements
  • High recycled content for steel rebar (98%)
  • Plastic reusable formwork
  • Timber partitions
  • Recycled carpet underlay
  • Engineered hardwood flooring
  • Improved airtightness
  • Veneered panelling to walls

Whole-life carbon: Hotels

05 / Conclusions

In light of the findings above it is clear that a radical rethinking of design, density and materials is necessary to tackle the pressing need to reduce carbon emissions.

  • A better subdivision of spaces as shown in the 鈥渆fficient hospitality鈥濃 scenario can achieve a 68% reduction in carbon emissions, compared with the benchmark, and 58% compared to the 鈥渙perational only focus鈥 approach. Economy of space focusing on maximising the space available for guestrooms and minimising back of house can shift back the focus on guests and comfort while still addressing carbon reduction.
  • Investment in more suitable and durable materials can reduce maintenance costs noticeably, as well as saving about half of the carbon emissions for internal fit-out over the lifespan of the building.
  • Consideration given to carbon reduction at the early stages of design and construction - applicable to retrofitting as well as new build - can influence the embodied carbon emissions favourably sooner and enable a suitable design without compromises.

The hospitality industry has made progress in addressing carbon emissions, but it is clear that the focus at the minute only goes so far, and that time and effort would be more efficiently spent pursuing alternative design philosophies.

Key benefits

  • The 鈥渆fficient hospitality鈥 scenario achieves a reduction of 68% in carbon emissions per person per night - equivalent to the production of a case of wine.
  • From the benchmark to the efficient hospitality scenario, there is a saving of 8,500 tonnes of CO2 over 60 years. If every hotel built in London in the past year had implemented low embodied carbon measures, almost half a million tonnes of CO2 would have been saved.
  • On average, the efficient design approach can create 50% more rooms per hotel.

Figure 5: Maintenance cycle over 60 years

The chart above plots yearly carbon emissions over the building鈥檚 assumed 60-year life cycle. There is a reasonably constant level of emissions arising from operational and maintenance impacts, while peaks correspond to embodied carbon expenditure from replacement and refurbishment. The trend of emissions reducing over time reflects projected grid decarbonisation.

06 / Acknowledgements

We would like to thank Michael Jones from The Portman Estate and Bev King from Z Hotels for their assistance and advice in preparing this article, as well as Christina Stuart and Gareth Roberts of Sturgis Carbon Profiling