Geothermal Heat Pumps (GHPs) are an

Geothermal Heat Pumps (GHPs) are an attractive type of technology for the heating and cooling of buildings,
which should be promoted in smart city planning in order to improve the air quality in the urban environment.
According to Saner et al. [1], a reduction of up to 90% of CO
2
emissions can be achieved, compared to methane
boilers. From the economic viewpoint, these plants require a larger investment compared to the other heating and
cooling technologies, which is usually recovered in less than 10 years by the reduction of the maintenance costs [2].
In Italy, the cost effectiveness of GHPs is still hampered by the high cost of electricity, and methane is the most
adopted fuel for heating; however, this niche market is growing, especially for large size installations [3]. InThe recently developed concept of nearly Zero-Energy Building
(nZEB) introduced by the recast directive on the Energy Performance
of Buildings (EPBD) [1] combined with the 20–20–20 target
objective [2] are considered important challenges linked to energy
consumption reduction, particularly with regard to the construction
sector that accounts for nearly 40% of total energy use. The
potential of improving energy efficiency in this sector is high in
view of the old uninsulated buildings and plants.
The major problem with exploiting renewable energy sources
and waste energy is the difficulty in conserving heat for long peri-
ods of time. In the past, attention has been focused on improving
the single components used to exploit renewable energy or waste
heat. Improving storage efficiency over long time periods, especially
when renewable energy sources need to be preserved, is currently
considered a major challenge. In this respect, the most
widespread small- to large-scale renewable technologies concern
solar energy. Some examples of these technologies are solar thermal
plants that produce heat to provide warmth for buildings or
domestic hot water, as well as hybrid desiccant cooling systems
and solar-driven absorption plants. The most widespread solar collectors
are the flat-plate and evacuated tube type; the latter are
used to reach high temperatures or to reduce the area of the solar
field. While other kinds of collectors can be found on the market,
their use is limited to special applications. The unglazed type, for
example, is used to heat swimming pools; the concentric tube collectors,
parabolic trough solar collectors, and solar parabolic dish
collectors are all used for power plant systems. order to
foster a greater use of GHPs, it is necessary to know the most suitable areas for the installation of Borehole Heat
Exchangers (BHEs) or Ground Water Heat Pumps (GWHPs), and to avoid installing these plants where they are not
convenient. The rational planning of shallow geothermal installations requires the knowledge of those site-specific
properties that strongly influence their efficiency, like the thermal conductivity of the soil, groundwater flow,
ground temperature etc. Several projects on the mapping of the shallow geothermal potentiality have therefore been
conducted in recent years. Gemelli et al. [2] developed a regional model for the Marche region (Central Italy) by
combining geological and climatic data. The suitability for GHPs of 4 regions of Southern Italy (Campania, Apulia,
Calabria, Sicily) was mapped considering both the heating and cooling operating modes and carrying out an
extensive campaign of in situ measurement of the thermal properties of the ground [4]. Fewer projects have focused
on GWHPs, since these plants are usually installed for large size applications and need a thorough site
characterization, which cannot conveniently be performed on a large scale [5].
These and other studies represented the basis for the ongoing project of mapping the geothermal potentiality of
the Province of Cuneo, in North-Western Italy, which is summarized in this paper. The work started with the
collection of available data for the characterization of the subsoil and hydrogeology of the territory surveyed, on its
climate and on technical obstacles like landslides, polluted sites etc. The data were processed to produce maps of the
most important parameters that affect the efficiency of shallow geothermal plants and to give an indication of their
convenience in some of the most important settlements of the Province.