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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 43, 2015 

A publication of 

The Italian Association 
of Chemical Engineering 
Online at www.aidic.it/cet 

Chief Editors: Sauro Pierucci, Jiří J. Klemeš 
Copyright © 2015, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-34-1; ISSN 2283-9216                                                                               

 

PCM-Cold Storage System: an Innovative Technology for Air 
Conditioning Energy Saving 

Marcello De Falco*a,b, Giacomo Dosec, Alessandro Zaccagninic  
a Faculty of Engineering, University of Rome “Campus Bio-Medico”, via Alvaro del Portillo 21, 00128 – Rome, Italy  
b Upgrading Services S.p.A., via Dante Alighieri 142, 70122 – Bari, Italy 
c Labor S.r.l., via Giacomo Peroni 386, 00131 – Rome, Italy 
marcello.defalco@unicampus.it 
 
 
An innovative solution to store cold energy by means of the solidification latent heat of PCMs is presented. 
The cold storage system is suitable for domestic application (typical in/out primary circuit temperature = 7-
12°C) since it stores cold energy at 5.5°C. The innovative heat exchanger system implemented in the storage 
unit allows the increase of energy charge/release dynamics and, therefore, leads to high power both in charge 
and release phases. 
The 5 kWh prototype developed and tested is illustrated, together with some experimental results, 
demonstrating the technology application potentialities. 

1. Introduction 

Due to the increasing use of air conditioning (AC) in residential and office buildings, the Italian daily electrical 
load curve shows remarkably high peaks during summer months, leading to the shifting of the peak 
consumption from the winter to the summer. 

Developing AC systems, able to flatten the load curve during the summer period and to improve the energy 
conversion efficiency, is crucial to reduce the electricity consumption and the consequent pollutants and 
GHGs emissions, and to protect the electrical grid from overloads. This can be achieved by shifting the power 
consumption needed by the air conditioning units towards off peak hours, integrating thermal storage systems. 
At the moment, several solutions are adopted in large industrial applications, but not in residential air 
conditioning systems.  

Operating in off-peak hours, which would certainly provide benefits at the level of national electrical energy 
distribution, can also increase the performance of air conditioning systems. In fact, during the night, the 
chiller's Coefficient of Performance (COP) increases due to the lower external temperatures. Moreover, thanks 
to the adoption of a storage system, the chiller can operate mostly at constant and optimal power (peak 
shaving concept) instead of following the user requirements profile, leading to a strong enhancement of 
energy efficiency and to a reduction of installed power. All these benefits lead to a potential reduction of 
electricity consumption of 20% and more.  

Among the existing methods to store thermal energy, the ones using Phase Change Materials (PCM) are 
particularly interesting (Mehling, 2008; Regin, 2008; Zalba, 2013; Castell, 2011). These substances store the 
heat through their latent enthalpy, changing the phase from liquid to solid during charging and from solid to 
liquid during releasing. Several PCMs for storage applications have been developed and are available on the 
market at reasonable prices. Moreover, PCMs can offer a high value of heat stored per unit volume 
(approximately 42 kWh/m3). This is 5 to 14 times more than for conventional sensible-heat storage materials 
such as water, masonry or rock. Another quality of PCMs is that they store and provide thermal energy 
maintaining the temperature in their melting range. Eutectic alloys do even maintain the temperature steady 

                                

 
 

 

 
   

                                                  
DOI: 10.3303/CET1543331 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: De Falco M., Dose G., Zaccagnini A., 2015, Pcm-cold storage system: an innovative technology for air conditioning 
energy saving, Chemical Engineering Transactions, 43, 1981-1986  DOI: 10.3303/CET1543331

                                

 
 

 

 
   

                                                  
DOI: 10.3303/CET1543331 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: De Falco M., Dose G., Zaccagnini A., 2015, Pcm-cold storage system: an innovative technology for air conditioning 
energy saving, Chemical Engineering Transactions, 43, 1981-1986  DOI: 10.3303/CET1543331

1981



throughout the whole process. This allows the air conditioning system to run in a nearly steady-state and helps 
remarkably the designer in sizing the heat exchanger of the unit. Due to these benefits and due to the PCMs' 
environmental compatibility, storage systems using Phase Change Materials are the most suitable for 
residential applications.  

In this paper, the possibility of integrating a PCM-based thermal storage unit in a residential air conditioning 
system is explored.  
 
In Figure 1, the integration of the thermal storage unit in a chiller-users system is shown. The valves system 
allows the energy tank to work in three different configurations: charge, mixed release and pure release. While 
charging, the unit is in series with the chiller and the user is excluded from the circuit. All the cooling energy 
produced by the chiller is stored by the solidification of the PCM. Once the system is charged, the thermal 
energy stored can be released through the melting of the PCM, using two configurations: pure release and 
mixed release. In the first one, the users are supplied by the thermal energy released by the tank, while the 
chiller is turned off. Only a storage system which employs PCM can operate in this configuration while 
maintaining a nearly-steady state. In fact, the operating temperatures in the heat exchanger of the unit are 
constrained in a narrow domain determined by the melting range of the adopted phase-changing alloy. This 
allows to run the AC plant without showing sensible spreads in the inlet/outlet temperatures of the users.  In 
the case of the mixed release configuration, the cold water flow is produced by both the chiller and the storage 
unit, working in parallel.  
 

 
 

Figure 1: Plant scheme of a heat storage unit integrated in a chiller-users air conditioning system. 
 
The technological solution for cold storage described in this work presents an innovative solution to optimize 
the heat exchange between the PCM and the water stream of the chiller circuit, as reported by De Falco 
(2014). The solution has been implemented in a 5 kWhcold prototype (refer to Figure 2), described in the 
following and experimentally validated. Some experimental results, obtained during a first testing phase, are 
reported. 

2. Prototype description 

2.1 Analysis of the system operation 

The cold storage unit presented in this work is composed by a tank that contains a heterogeneous mixture of 
distilled water and PCM in which a coaxial heat exchanger is immersed (refer to Figure 3). The functioning of 
the system is based on the natural separation between the two liquid substances in solution and, therefore, 
the PCM adopted has to be water-immiscible and must have a density lower than 1 kg/lt. The water available 
at the bottom of the tank is suctioned by a feed pump and sent in the inner tube of the coaxial heat exchanger, 
then it is fed at the top of the tank (secondary circuit) by nozzles and drops down for gravity (the density of the 

1982



water is higher than the density of PCM). The external flow in the coil comes instead from the chiller-users 
circuit (primary circuit). 
The total heat exchange is composed of two contributions. The first one consists of the thermal flow 
exchanged by the water drops generated by the nozzles and the PCM volume; the second one takes place 
outside the coaxial exchanger and it is due to the heat that flows between the external tube of the coil and the 
PCM volume in which is immersed. Such a technological solution allows to reduce the size of the heat 
exchanger, with a lower pressure loss and unit cost.  
 

  

Figure 2 – 5 kWhcold prototype for cold storage by means of PCM 

2.2 Selection of the PCM 

In order to meet the thermal requirements needed in the different configurations of the plant, the adopted PCM 
melting range is bound to respect the following limitations. During the charging phase of the system, the 
cooled water produced by the chiller enters in the external tube of the coil and then must have a lower 
temperature of the PCM-water mixture. Similarly, while releasing, the heterogeneous solution has to be colder 
than the warm water flow that comes from the users. Therefore, after choosing appropriate temperature 
gradients in the exchanger, the melting range of the PCM is subject to the following relation: 
 

happhmcappc TTTTT __ Δ+<Δ<Δ+    (1) 
 
where: 

 is the temperature of the cold water produced by the chiller in the charging phase; 
 is the temperature of the water returning from the users in the releasing phase; ∆ _  is the fixed temperature gradient of the heat exchanger in the charging phase; ∆ _  is the fixed temperature gradient of the heat exchanger in the releasing phase; ∆  is the melting range of the PCM. 

 
Assuming approach temperatures of 4°C and inlet temperatures in the heat exchanger of 1°C during the 
charge and 12°C during the release, the melting range of the PCM has to be between 5°C and 8°C. The 
narrowness of this domain suggests to adopt a eutectic alloy as heat storage material. In the prototype, the 
PCM packed in the storage system has a constant melting temperature equal to 5.5°C. 

3. Experimental results 

During the experiments phase, the cold storage system had a capacity of 5 kWhcold, referred to the cold stored 
by the latent enthalpy. Each test was conducted until reaching the full charge or release of the energy. 

3.1 Charge test 

For this test, the chiller is required to provide at 0°C the ethylene glycol based water solution that flows in the 
primary circuit. The storage system starts in condition of total discharge; the PCM is in a liquid phase and has 
a temperature higher than its melting point. In Figure 4, the dynamic trends of the thermal power exchanged 
by the water flows of the primary and secondary circuit are shown. In the first minutes of the test, the unit 
reaches the solidification conditions and the thermal power presents peak values due to the high temperature 
differences and high overall heat transfer coefficient. After the PCM starts changing phase, the heat transfer 

1983



begins to decrease, due to the thermal resistance offered by the forming solid mass. However, the 
technological solution adopted in the prototype, which includes an inner circuit that increases the heat 
exchanger capacity, allows to partially overcome this drawback. In fact, at the end of the test, the thermal 
power exchanged between the primary and secondary circuits amounts to 75% of the total power absorbed by 
the storage unit. 
 

 

Figure 3: Layout of the thermal storage unit 

In Figures 5 and 6, it is shown the inlet/outlet temperature trends over time of respectively the external and 
internal water flow of the coil. We observe temperatures slightly below the melting range of the PCM, due to a 
decreasing of the heat exchange between the PCM and the water fed to the tank. In fact, the forming solid 
mass obstructs the water from reaching some portion of the liquid heat storage material and, in this way, the 
stream leaving the heat exchanger will cool the same piece of matter over and over, resulting in the 
subcooling of the solidified PCM. Consequently, the water is in contact with a solid mass that has a 
temperature lower than the melting point, and therefore the heat exchange decreases due to the lower 
temperature difference between the substances.  Nevertheless, this can be easily avoided adopting an 
appropriate method of water diffusion (e.g. dynamic nozzles). 

Table 1:  Mean values during solidification of plotted operating parameters 

T_EST_IN T_EST_OUT T_INT_IN T_INT_OUT P_EST P_INT 
0.091°C 2.430°C 3.833°C 2.649°C 1.684 kW 1.086 kW 

 
 

 

Figure 4: Trends over time of the thermal power exchanged by the primary (P_EST) and secondary (P_INT) 
circuit water flows. 

1984



 

Figure 5: Inlet/outlet temperature trends over time of the external water flow of the coil. 

 

Figure 6: Inlet/outlet temperature trends over time of the inner water flow of the coil. 

3.2 Release test 

The results shown in Figures 7-9 concern a mixed release test conducted in environmental condition at 26°C. 
In Figure 7, it is plotted the trends over time of the cooling power released by the storage unit and consumed 
by the user. The gap between these two curves represents the power delivered by the chiller. We can see that 
the storage system provides a good part of the whole cooling power requirement: on average 28.7% of the 
total, with a peak of 54.2% at the beginning of the test. During the release we observe, similarly to the 
previous case, a slight reduction of the power delivered by the storage unit, due to the decrease of the 
temperature difference in the coaxial heat exchanger (Figure 8). This is a consequence of the inhomogeneity 
of melting in the PCM. As before, this drawback can be easily overcome adopting an appropriate method of 
water diffusion, capable of spreading evenly the water reinserted in the tank. For the sake of completeness, 
the inlet/outlet temperature profiles of the user are shown in Figure 9. 

Table 2:  Mean values during fusion of plotted operating parameters 

T_COAX_IN T_COAX_OUT T_USER_IN T_USER_OUT P_COAX P_USER 
12.16°C 8.003°C 7.551°C 12.14°C 1.245 kW 4.337 kW 

 

 

Figure 7: Trends over time of the cooling power delivered by the storage unit (P_COAX) and consumed by the 
user (P_USER). 

1985



 

Figure 8: Inlet/outlet temperature profiles of the primary circuit in the coaxial heat exchanger. 

 

Figure 9: Inlet/outlet temperature profiles of the user. 

4. Conclusions 

An innovative solution to store cold energy by means of the solidification latent heat of PCMs is presented in 
this work. The cold storage system is suitable for domestic application (typical in/out primary circuit 
temperature = 7-12°C) since it is able to store cold energy at 5.5°C. The heat exchanger system implemented 
in the storage unit allows the increase of energy charge/release dynamics, exploiting the immiscibility between 
the PCM and a stream of water fed into the tank by means of nozzles, and the heat exchanging between the 
chiller primary circuit water stream and the secondary circuit water stream, suctioned by a pump from the tank, 
then sent to the heat exchanger and finally fed to the nozzles. By this technology, the charge/release phases 
are much quicker and, consequently, the charge/release thermal power is higher. 
The test campaign performed on a 5 kWhcold prototype has demonstrated the potentialities of the proposed 
solution, which is patent pending. A second design phase is required in order to improve the integration 
between the storage system and the chiller. 
 
 
References 
Castell A., Belusko M., Bruno F., Cabeza L.F., 2011, Maximisation of heat transfer in a coil in tank PCM cold 

storage system, Applied Energy, 88, 4120-4127. 
De Falco M., Zaccagnini A., 2014, Sistema di stoccaggio di energia frigorifera o termica mediante materiali a 

cambio di fase (PCM), Italian patent n. RM2014 A000500 
Mehling H, Cabeza L.F., 2008, Heat and Cold Storage with PCM – An up to date introduction into basics and 

applications, Springer, New York. 
Regin A.F., Solanki S.C., Saini J.S., 2008, Heat transfer characteristics of thermal energy storage system 

using PCM capsules: A review, Renewable and Sustainable Energy Reviews, 12, 2438–2458. 
Zalba B., Marın J. M., Cabeza L.F., Mehling H., 2003, Review on thermal energy storage with phase change: 

materials, heat transfer analysis and applications, Applied Thermal Engineering, 23, 251–283. 
 
 
 
 

1986