An examination of UKCIP02 and UKCP09 solar radiation data sets for the UK climate related to their use in building design

The climate is changing, both globally and in the UK. To adapt effectively, engineers and planners need as much information as possible on how the climate will evolve. The UK Climate Impacts Programme (UKCIP) provided this in 2002 with UKCIP02 and the latest data UKCP09, which provides data to a resolution of 5 km square grids over the UK. Data sets from these were used in this study along with the historical measured data for three locations — Bracknell (London), Manchester and Edinburgh — to analyse critically the likely changes that may occur in the key climate variables, that is temperature, sunshine duration and solar irradiation. These parameters have an important bearing on the design and function of buildings and building services. Sunshine duration is the main variable that is used to obtain solar radiation in the UKCP09 5 km grid data. For the grids containing Bracknell, Manchester and Edinburgh, most of the UKCP09 data sets for the years 2050 and 2080 showed abnormally elongated sunshine duration, that is from sunrise to sunset, for clear days. In contrast, the latest historic measured data sets indicate only a third of the above sunshine duration. Note that the latter data are used in cooling load design calculations and for the generation of sol-air temperatures.1 Of particular note was the anomalous occurrence in UKCP09 of late evening sunshine duration. For Bracknell and Edinburgh, the sunshine duration at hour ending 20 and beyond showed substantial amount of predicted sunshine. As a result of this work, corrective action has been proposed for UKCP09 data. Furthermore, a very significant increase was also noted in solar irradiation for UKCP09. For the historic measured data for Bracknell, the clear day noon irradiation is 818 Wh/m 2. For the UKCP09 grid containing Bracknell the 2080 High Emission scenario data gives an average value of 1002 Wh/m2, an increase of 23%. The same trend occurs for Edinburgh, (a present value of 789 Wh/m 2 and the predicted value of 948 Wh/m2, an increase of 20%). Note that compounded with presently found increase of 4—5°C increase for the above locations, the substantial increase in irradiation will have a much more pronounced increase in the cooling load of buildings. An evaluation of the change in the character of solar radiation was also undertaken. This was done by noting the change in the diffuse fraction of global irradiation. For Bracknell and Edinburgh historic data and UKCP09 data 2080 High Emission data set show a drastic decrease, respectively from 0.37 to 0.13 and from 0.33 to 0.14. Diffuse fraction may be used as an indicator of the prevailing sky clarity. If the predictions come true a drastic decrease in the diffuse fraction of this magnitude signifies a radical shift in the character of solar climate for the future. The current solar climate of Bracknell is known for its above average turbidity, the latter stemming from the following factors: inland location, high-density housing, proximity to Heathrow airport and M25 London orbital motorway. Whether such an extreme shift in the sky clarity will occur within a matter of 60—70 years is open to discussion. Practical applications: To adapt effectively against the challenge posed by climate change engineers need to know the extent to which the basic climate variables such as temperature and solar radiation will change. This work has used basic data from the UKCP09 project to analyse the extent of the above change with respect to the basic and other derived data. It was shown that for Scottish and English locations a temperature rise of up to 4—5°C may occur between the present age and the year 2080 for High Emission scenario. It was also shown that the corresponding irradiation strength may increase around 22%. Furthermore, it was also found that if these predictions come true then a drastic decrease in the diffuse fraction of irradiation will produce a radical shift in the character of solar climate. The resulting higher proportion of beam irradiation will have to be handled with care in design of overhangs and other shading contraptions to prevent an excessive increase in cooling load of buildings.

[1]  Hayley J. Fowler,et al.  Downscaling transient climate change using a Neyman- Scott Rectangular Pulses stochastic rainfall model , 2010 .

[2]  Tariq Muneer,et al.  Evaluation of a New Photodiode Sensor for Measuring Global and Diffuse Irradiance, and Sunshine Duration , 2003 .

[3]  P. Stott,et al.  Human contribution to the European heatwave of 2003 , 2004, Nature.

[4]  Glenis,et al.  UK Climate Projections science report: Projections of future daily climate for the UK from the Weather Generator , 2009 .

[5]  Tariq Muneer,et al.  Quality control of solar radiation and sunshine measurements – lessons learnt from processing worldwide databases , 2002 .

[6]  C. Harpham,et al.  A daily weather generator for use in climate change studies , 2007, Environ. Model. Softw..

[7]  M. Hulme,et al.  Climate Change Scenarios for the United Kingdom Scientific Report 1998 , 1998 .

[8]  Chris Kilsby,et al.  A space‐time Neyman‐Scott model of rainfall: Empirical analysis of extremes , 2002 .

[9]  T. Muneer Solar radiation and daylight models , 2004 .

[10]  M. Blackburn,et al.  Factors contributing to the summer 2003 European heatwave , 2004 .

[11]  Mike Hulme,et al.  Climate Change Scenarios for the United Kingdom , 1998 .

[12]  H. Wanner,et al.  European Seasonal and Annual Temperature Variability, Trends, and Extremes Since 1500 , 2004, Science.

[13]  Jn Hacker,et al.  Constructing design weather data for future climates , 2005 .

[14]  D. Lüthi,et al.  The role of increasing temperature variability in European summer heatwaves , 2004, Nature.

[15]  Hayley J. Fowler,et al.  Regional climate model data used within the SWURVE project – 1: projected changes in seasonal patterns and estimation of PET , 2007 .