Low depth geothermal heat exchangers can be efficiently used as a heat sink for building energy produced during summer. If annual average ambient temperatures are low enough, direct cooling of a building is possible. Alternatively the heat exchangers can replace cooling towers in combination with active cooling systems. In the current work, the performance of vertical and horizontal geothermal heat exchangers implemented in two office building climatisation projects is evaluated. A main result of the performance analysis is that the ground coupled heat exchangers have good coefficients of performance ranging from 13 to 20 as average annual ratios of cold produced to electricity used. Best performance is reached, if the ground cooling system is used to cool down high temperature ambient air. The maximum heat dissipation per meter of ground heat exchanger measured was lower than planned and varied between 8 W m(-1) for the low depth horizontal heat exchangers up to 25 W m(-1) for the vertical heat exchangers. The experimental results were used to validate a numerical simulation model, which was then used to study the influence of soil parameters and inlet temperatures to the ground heat exchangers. The power dissipation varies by +/- 30% depending on the soil conductivity. The heat conductivity of vertical tube filling material influences performance by another +/- 30% for different materials. Depending on the inlet temperature level to the ground heat exchanger, the dissipated power increases from 2 W m(-1) for direct cooling applications at 20 degrees C up to 52 W m(-1) for cooling tower substitutions at 40 degrees C. This directly influences the cooling costs, which vary between 0.12 and 2.8 k is an element of W h(-1). As a result of the work, planning and operation recommendations for the optimal choice of ground coupled heat exchangers for office building cooling can be given. (c) 2008 Elsevier Ltd. All rights reserved.