Performance of a photovoltaic solar container under Mediterranean and arid climat conditions in Algeria.

Available online at www.sciencedirect.com Energy Procedia 18 (2012 ) 1452 1457 Performance of a photovoltaic solar container under Mediterranean and arid climat conditions in Algeria. M. Laidi, B. Abbad, M.Berdja and M. Chikh. UDES, Solar Equipment Development Unit, FTEER Laboratory National Road No. 11, PO Box 386 Bou-Ismail, 42415, Algeria Abstract This study aims to present the performance of solar container cold storage of perishable goods and food supplied by photovoltaic systems. This system has been tested in Algeria, in two different climate types: Mild along the Mediterranean coast (Bou ismail - Tipaza) and arid - in the Sahara desert (In Guezzam Tammanrasset). The data gathered enabled our team to evaluate pertinent system components and optimize the equipment to specific environments and load requirements. This type of system is suitable for areas lacking electricity supply. Storage capacities are calculated for three consecutive days without a remarquabre rate of solar radiation. Keywords Solar energy, PV-panels, Container. 1. INTRODUCTION With the rapid development of the world economy, the consumption of the fossil fuel has reached peaks in recent years, which gradually leads to price increases in the fossil fuel and decreases in the total stockpile of the fossil fuel because it is not renewable. In spite of the rapid development of the global economy, many people in remote and rural areas in the developing countries are unable to access electricity from the grid. Moreover, health services and living condition are very poor in these areas in part due to the lack of cold storage for drugs and essential vaccines which are needed to be stored in low temperature compartments. It seems difficult to use the normal measures to produce low temperature for the shortage of the suitable power sources in those areas. With the continuous progress in photovoltaic (PV) cell research, costs have been gradually reduced. Solar PV power has been used for lighting in many countries. There are over 3 million homes in the world which are equipped with simple PV lighting systems: typically with a 50 W PV panel and an energy storage device typically a flooded lead-acid battery. [1] However, the demand for the storage of perishable food and essential drugs and vaccines for these families is also gradually increasing in order to improve the quality of life. Furthermore, recent efforts on the development of zero-energy building brings forward the desire for the independent electrical appliances; meanwhile, in many tourism resorts, for example, in the beaches along the California coast, the service of cold beverages cooled by a PV refrigerator is obviously attractive, which overcomes the expense of extending the electric grid network. The production of low temperature for refrigeration by solar energy using vapor compression refrigerator powered by the PV panel holds the advantage of a large low temperature cabinet and a continuous cooling power supply. Two routines for constructing the PV-powered containers are as follows: (1) the container is indirectly powered by the PV panel and (2) the container is directly powered by the PV panel. The main components of the system in the former case include the PV panel, battery bank, inverter, and container; while in the latter case an inverter is unnecessary since a Dc compressor is used in the refrigerator system. 1876-62 2012 Published by Elsevier Ltd. Selection and/or peer review under responsibility of The TerraGreen Society. Open access under CC BY-NC-ND license. doi:.16/j.egypro.2012.05.163

M. Laidi et al. / Energy Procedia 18 ( 2012 ) 1452 1457 1453 Kattakayam and Srinivasan [2, 3] investigated the performance of the domestic refrigerator coupled by the inverters to the battery bank and PV panel. Emphasis was put on the power supply system and thermal performance characteristics of the refrigerator. Toure and Fassinou [4] investigated the performance of a threecompartment PV-powered refrigerator, mainly focusing on the cold storage and autonomous performance of the system. Kaplanis and Papanastasiou [5] reported a study of the modification of a conventional refrigerator to a PV-powered one, and the performance tests were carried out either via the battery or directly via the PV panel. Blas et al. [6] reported the construction of a refrigeration system for the storage of milk powered by PV panels, which was equipped with two separate compressors driven by dc motors. The batteries in the system were used only for the control unit and not for the powering, and the autonomy of the system was achieved by the cold storage of the ice and cold water produced by the PV energy throughout the daytime. Nagaraju et al. [7-12] studied the performance of a PV-powered cold store plant and it was demonstrated that the system can be cooled down to 2 C with a maximum heat load of 2350 W. Many societies in the word constructed solar container powered by only a PV panel or with wind and tested in many countries over the word. The normal operation of the PV-powered container system is actually highly dependent on the climatic conditions; however, no information about this has been addressed in the former research. In the present investigation, a container of 1.5 m3 (1.2 1.055 1.255 mm) powered by the PV panel is modified locally fabricated. In order to have the test of the refrigerator, an experimental setup was built up and the field tests were carried out. The analysis of the applicability of the PV powered container to different regions with typical climatic characteristics is also conducted and discussed. 2. EXPERIMENTAL SETUP AND MEASUREMENT TECHNIQUE Schematic of the PV-container system is presented in Figure 1. It is composed of four parts; i) the cooling unit (container), ii) the energy production unit ( PV panels), iii) the energy control unit, and iv) the energy storage unit (the Solar lead acid battery bank: battery: 550Ah Solar OPzS C120-2V). PV-container system works with an input voltage of 220 V and alternative current (AC). R134a refrigerant was used in the container. Energy demand of PV-container system was provided by two units photovoltaic panels (DC 24V-150W) each one has seven panels connected in parallel (2S 7P). Photovoltaic panels were selected by polycrystalline type due to high efficiency. Panel specifications for standard test conditions are given in Table 1 (Photovoltaic module catalogue). Panel standard test conditions are: Irradiance of 00 W/m2, air mass of 1.5 (AM) and module temperature of 25 C. Solar control unit regulates the DC output of the PV panel, and supplies energy to the battery bank. It prevents battery over-charge and full discharge. Battery bank consists of two units 550 Ah -24 V dry-type batteries connected in parallel. Fig.1 Schematic of the PV-container system, The power of the compressor is 380 Watt; it means a consumption of about 4460 Wh/Day. The evaporator used in our case is GC4040/16 type; it is regulated to keep the temperature inside the container between 3 and 9. The

1454 M. Laidi et al. / Energy Procedia 18 ( 2012 ) 1452 1457 inverter is a TOP CLASS 22/24; it converts the DC 24V to AC 230V-and provides a perfect sinusoidal current with a capacity of 2kVA. The controller TriStar TS-45 Morningstar is designed to regulate the load; it incorporates three functions to charge the batteries with high reliability, to regulate the load or the bypass, it operates according to a choice of three modes of operation. The figure shows some pictures of container during realization Fig. 2 Different manufacturing steps of the container. 3. RESULTS AND DISCUSSION In this study, experimental study for operation state of the container under different load and without load was performed in 2011 to determine the daily and long-term behaviors of the PV-container systems during some typical days in summer and winter and in two different climate types: Mild along the Mediterranean coast (Bou ismail - Tipaza) and arid - in the Sahara desert (In Guezzam Tammanrasset).. In all the experiments, the inside temperature of refrigerator was set between 4 and 8 C. Some results obtained during experimental measurements are presented subsequently. The Following figure shows the daily variation of the global radiation under the climate of Bou Ismail measured by a pyranometer type CIMEL 5.31 V/ W/m and were obtained with a tilted orientation 36 degrees south. 1200 Global radiation on tilted surface (W/m 2 ) 00 800 600 400 200 0 18:00 22:00 02:00 06:00 :00 14:00 18:00 22:00 02:00 06:00 :00 14:00 18:00 22:00 02:00 Time, March 16-17 th, 2011 Fig. 3 Daily variation of the global radiation

M. Laidi et al. / Energy Procedia 18 ( 2012 ) 1452 1457 1455 22 20 Running current of the system Recievd current by the batteries Recived current by the field N 1 (7 panels) Recived current by the field N 2 (7 panels) 18 16 14 Current, (Amps) 12 8 6 4 2 0 00:00:00 00:01:00 00:02:00 00:03:00 00:04:00 00:05:00 00:06:00 00:06:00 00:07:00 00:08:00 00:09:00 Time, 26/04/2011 00::00 00:11:00 00:12:00 00:13:00 00:14:00 00:14:00 Fig. 4 Nocturnal variation of the current When there is no sunlight, the system is powered from batteries. The container works with an average current equal to 4 Ampere but the current aspired by the Battery Park equal to 18.5 amps. The latter is used to power the two regulators, the inverter and the container. In the opposite case or container is stopped, the battery delivers a low current of 0.7 amps to power the LEDs and the array of temperature control in the container. 25 Running Current of the system Recieved current by batteries Recieved current by the fiels N 1 (7 Panels) Recieved current by the fiels N 2 (7 Panels) 20 Current, (Amps) 15 5 0 11:57:00 12:08:00 12:22:00 12:32:00 12:43:00 12:55:00 Time, 26/03/2011 13:05:00 13:16:00 13:30:00 13:40:00 Fig. 5 Variation of diurnal current

1456 M. Laidi et al. / Energy Procedia 18 ( 2012 ) 1452 1457 When it is sunny, the current delivered by the two fields is sufficient to supply the container and also stored in the batteries. The temperature inside the chamber ranges from 4-8 C, opening the door causes the increase of the temperature in the room. 16 Variation of the room temperature 14 Temperature, C 12 8 6 4 09:53:29 :13:26 :44:22 11:04:19 11:24:16 11:44:14 12:04:11 12:27:02 Local time: In Guezzam, 11/04/2011 12:47:00 Fig. 6 Variation of the room (container) temperature. This figure shows the smooth functioning of the compressor. Temperature, ( C) 28 26 24 22 20 18 16 14 12 8 6 4 2 Ambient Water (load of 200 Kg) Room 08:24 AM :48 AM 01:12 PM 03:36 PM 06:00 PM 08:24 PM :48 PM 01:12 AM 03:36 AM Hours, 20-21 Februry, 2011 06:00 AM 08:24 AM :48 AM 01:12 PM Fig.7 refrigeration of the load

M. Laidi et al. / Energy Procedia 18 ( 2012 ) 1452 1457 1457 4. CONCLUSION In this study, a PV-powered container system has been established to investigate experimentally its daily and seasonal operating performance. The PV-container system is independent of the local electricity network. Operation of this system under Algeria climatic conditions is continuously observed. During the daily operation of the container system, the parameters affecting the system capacity and performance were determined experimentally. The following findings were obtained from experimental study: 1. Positive temperature can be maintained in the container 4-8 C while average indoor and outdoor temperature. 2. During the daily period, the highest energy amount produced by PV panels is recorded between 11:00 and 14:00. 3. Under Algeria local conditions for a typical hot day in May2011, energy consumption amount of refrigerator was determined to be 4464 Wh/day. 4. Energy balance of the refrigerator and PV system has been provided. The operating costs of this system were reduced due to operating lower power. 5. The energy required for refrigerator is provided by photovoltaic power, clean energy source. There is no negative impact of the electrical energy generation by PV panel on the environment. It can be seen from results of this study that, the use of PV-refrigerator system is suitable for applications in different sector fields, required the low and medium cooling capacity. Such small-scale stand-alone system can suitably be used in many rural regions where electricity is unreliable or non-existent but refrigeration is continuously critical. 5. REFRENCES [1] R. E. Foster, L. Estrada, and D. Bergeron, ISES Solar World Congress, Adelaide, Australia, 2001 [2] T. A. Kattakayam and K. Srinivasan, International Journal of Refrigeration 23, 190 (2000). [3] T. A. Kattakayam and K. Srinivasan, Sol. Energy 56, 543 (1996). [4] S. Toure and W. F. Fassinou, Renewable Energy 17, 587 (1999). [5] S. Kaplanis and N. Papanastasiou, Renewable Energy 31, 771(2006). [6] J. Nagaraju, K. Vikash, and M. V. Murthy Krishna, Int. J. Energy Res. 25, 389 (2001). [7] Solar Energy Engineering: Processes and Systems, Book. ISBN 978-0-12-374501-9. [8] RETScreen International, Logiciel d'analyse de projets sur les énergies propres, http://www.retscreen.net/fr/home.php. [9] WHO. (1988) Standard Equipment Specifications and Test Procedures. Expanded Program on Immunization. Tech. Series, No. 5, World Health Organisation, Geneva. [] Z.M. Salameh, Performance analysis of a PV powered health clinic with single stage dual priority regulator. IEEE Trans. on Energy Conversion 6, pp. 586-593, (1994). [11] G. Loois, T. C. J., Van der Weiden, K. J. and Hockstr, Technical set-up and use of PV diesel systems for houseboats and barges. Solar Energy Materials and Solar Cells 35, pp.487-496, (1994). [12] B. McNelis. Photovoltaics for developing countries. In Application of Photovoltaic (Edited by Hill R.), pp. 39-91. Adam-Hilger, Bristol. (1989).