Individual cooling systemsIn this s

Individual cooling systems
In this section, a brief recent state of the art of the most common systems in hybrid cooling for building use is described.

2.1. Vapor Compression cooling system (VCC)

VCC is the most commonly used cooling system due to the high COP obtained [14], the application over a large temperature range (from −40 °C to 7° [15]) and the wide variety of refrigerant types [16]. However, the great dependence of VCC on electrical energy and the high power consumption are the major drawbacks that make the use of such a system undesirable, especially in countries that suffer a shortage in the electricity generation. Therefore, different methods were investigated in order to mitigate these problems. Incorporating a mechanical sub-cooling loop to the VCC cycle is an energy saving method that was investigated in the literature ([17], [18] and [19]). Ling et al. [20] found that an energy saving of about 30% and a reduction in the compressor size were noted when they studied the method of separated sensible and latent cooling using two parallel VCC. A total cost reduction greater than 10% was observed using a VCC with an ice storage tank [21]. Several works studied the possibility of using renewable energy with VCC. Wang et al. ([22] and [23]) modeled and tested an ORC -driven by waste heat- combined with a VCC. They found that about half of the waste heat is converted into cooling. Otanicar et al. [24] noted that the capital investment of solar electric cooling system is expected to be the lowest in 2030, and it will be the most environmentally friendly since it has lower projected CO2 emission values. In addition, the use of a geothermal heat exchanger as a heat rejection system for VCC led to a great reduction in cost and power ([25] and [26]).

2.2. Absorption cooling system (ABSC)

Thermally driven ABSC is one of alternative solution that reduces the cooling electricity demand by shifting to gas, oil, solar etc.[27]. The COP of a single-effect ABSC is still low compared to that of VCC [28]. However, the performance of an ABSC could be improved by using multi-stage generator and different heat source temperatures [29]. According to Elsafty and Al-Daini [30], the total cost of a double-effect ABSC located in Alexandria, Egypt is lower than that of a single-effect ABSC and VCC. A passive system or diffusion-absorption system is an absorption cycle without mechanical pump and thus zero electrical energy consumption [31]. In this system, the pressure difference is compensated by circulating an inert gas (H, He, NH3, etc.) between the evaporator and the absorber. Solar absorption cooling is widely investigated in the literature. A solar fraction of 100% could be achieved using a high efficiency flat plate collector or evacuated tube collector to drive the generator of ABSC [32]. As in VCC, the ground cooling is used to eliminate the heat of condensation and absorption, and to reduce the energy consumption of cooling towers. An energy saving greater than 30%, a great reduction in CO2 emissions and water consumption were noted when the cooling tower is replaced by a shallow geothermal system [33]. Eicker et al. [34] compared three different heat rejection systems (dry, wet and geothermal) used in a solar ABSC. They found that the grater electric COP was obtained using geothermal heat rejection system. On the other hand, geothermal energy provided by sedimentary basins could offer the heat energy required for heat-driven sorption cooling systems in some cases [35].

2.3. Adsorption cooling system (ADSC)

arimella et al. [67] analyzed the performance of a cascaded absorption-vapor compression cooling system where the absorption cycle is driven by waste heat. They found that the system exhibits high COP and energy consumption reduction over a wide range of temperature. They also compared the cascaded cycle to a two-stage VCC. Deng et al. [68] studied a solar hybrid cascaded absorption-vapor compression cooling system. When the inlet temperature of the generator is less than 80 °C, the cooling system works as a conventional VCC. Kairouani and Nehdi [69] studied the possibility of using geothermal energy to drive an absorption cycle cascaded with a conventional VCC. Hwang [70] analyzed the performance of a waste heat driven absorption-vapor compression refrigeration system integrated with a micro-turbine. The cooling produced by ABSC is used either to sub-cool the liquid leaving the condenser of VCC or to pre-cool the condenser and the micro-turbine air. The cascaded system with pre-cooling of the intake air of the micro-turbine showed the best results in energy saving. Seyfouri and Ameri [71] studied a combined heat and power system. The VCC working at low stage is driven by the micro-turbine whereas the resulting waste heat is used to drive the generator of ABSC working at high temperature stage. They presented different configurations of cascaded absorption- vapor compression cooling systems