Article AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES 15 (2022) 038–041 Contents lists available at http://qu.edu.iq Al-Qadisiyah Journal for Engineering Sciences Journal homepage: http://qu.edu.iq/journaleng/index.php/JQES * Corresponding author. E-mail address: dalyashaker1997@gmail.com(dalya shaker qaid) https://doi.org/10.30772/qjes.v15i1.810 2411-7773/© 2022 University of Al-Qadisiyah. All rights reserved. This work is licensed under a Creative Commons Attribution 4.0 International License. Experimental study of a domestic refrigerator using (SiO2/PAG oil/R- 134a) nano-refrigerant as a replacement for pure R-134a Dalya Shaker Qaid* and Abbas Alwi Sakhir Department of Mechanical Engineering, Collage of Engineering, University of Al-Qadisiyah, Ad-Diwaniyah, Iraq A R T I C L E I N F O Article history: Received 13 March 2022 Received in revised form ….. 2022 Accepted 22 May 2022 Keywords: Vapor compression refrigeration system SiO2 nanoparticels Coefficent of performance Polyalkylene glycol (PAG) R-134a A B S T R A C T This research studies the influence of using SiO2 nano-particles of 50nm in a Vapor Compression Refrigeration System (VCRS), along with Poly-alkylene Glycol (PAG) oil and R-134a mixed to create a nano-refrigerant. The methodology used in this work, the nano-particles were performed in three different concentrations (0.1%, 0.3%, and 0.5%) and mixed with 200ml of PAG oil. A VCR system was built at the mechanical engineering department laboratory in Al-Qadisiyah University. In order to study the Coefficient of Performance (COP) and the consumed energy by the compressor in the two cases of adding the nano- particles and using a pure refrigerant. The paper showed an increase in the system's COP from 2.3 to 2.81 when using a concentration of 0.5% of SiO2/PAG oil/R-134a, increasing the refrigeration effect and decreasing the consumed power. © 2022 University of Al-Qadisiyah. All rights reserved. 1. Introduction The working fluid of a vapor compression refrigeration system (VCRS) changes from liquid to vapor at the heat absorption section (evaporator) and then back to liquid at the heat rejection section (condenser). The Coefficient of Performance is the ratio of the heat absorption section's refrigeration effect to the compressor's work input. COP increases by decreasing the compressor's work input or raising the heat removal rate. Nano-fluids are a new type of heat transfer fluid that emerged due to fast advancements in nanotechnology. Nano-fluids are a unique fluid consisting of a main fluid solution with nano-sized particles (1–100 nm). The Nano-fluids are mixes of the base liquid and Nanoparticles at particular concentrations. Lubricating oil, water, or refrigerant can be used as the main base fluid. CuO, ZrO₂, SiO₂, and other Nanoparticles are combined to create a colloid solution known as Nano-fluid. Nanoparticles have recently been employed in refrigeration systems to increase the COP and dependability of vapor compression refrigeration systems due to their better heat transfer capabilities. It lowered the amount of energy necessary to achieve the cooling effect. K nil Achari, and Dr.Smt.G.Prasanthi [1]. 1.1. Literature survey Kedzierski [2] investigated using (CuO) nanoparticles of 30 nm diameter to 1% and 0.5% volume fractions respectively, suspended in R-134a and Polyolester mixture on a roughened horizontal flat surface to compute the boiling performance. The results showed a 0.5% increase in boiling heat transfer. Ghorbani et al [3] explored experimentally the effect of adding CuO nano-particles in R600a refrigerant. The work was validated with three different working fluids including: Pure R-600a, R-600a-POE oil, and R-600a-oil-CuO with concentrations of 0.5 %, 1 %, and 1.5 %. The results showed an increase in the heat-transfer coefficient by 4.1 %, 8.11 %, and 13.7 %, respectively. Senthilkumar and Praveen [4] experimentally described the method to energy efficiency of refrigeration retorting system’s improvement that used the R600a refrigerant along with CuO nano particles. According to the findings, when CuO-R600a is used at concentrations of 0.1% and 0.5% and 11.83 and 17.88 % of energy was http://qu.edu.iq/ mailto:dalyashaker1997@gmail.com(dalya https://doi.org/10.30772/qjes.v15i1.810 http://creativecommons.org/licenses/by/4.0/ DALYA SHAKER QAID, AND ABBAS ALWI SAKHIR/AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES 15 (2022) 038–041 39 saved, respectively while CuO-R600a had a faster freezing time than the pure R600a. Shashikumar and Mylsamy [5] investigated the performance of nanoparticles with an equivalent nano particle weight ratio and nano- refrigerant replacement fractions of (0.005, 0.01, 0.015% weight proportion) in a VCRS. R134a, was combined with a variety of copper oxide, titanium oxide, silicon oxide, and aluminum oxide compositions (50nm). As a consequence of this investigation, the consumed power was reduced, and the COP of the system was enhanced (2.656 actual COP at 0.015%). It was found that the use of a nano-refrigerant was both ecologically friendly and safe. Kristen Bartelt et al [6] investigated the CuO nano-particles to see how they affect the flow-boiling of an (R134a/POE oil) mixture in a plane tube. Along with synthetic-ester and copper oxide nano-particles dissolved in the mix at 4% concentration. The heat-transfer coefficient improved by 42 to 82 % when utilizing a nano-lubricant mass fraction of 1% compared to a refrigerant-oil combination that without nano- particles. When the mass fraction was increased to 2%, the heat-transfer coefficient enhanced by 50% to 101 %. Gill et al [7] investigated the energy and exergy characteristic of a household refrigeration system. Employing R134a, and the Liquefied Petroleum Gas refrigerants with various oils (Polyester, Mineral oil, and TiO₂, SiO₂, and Al₂O₃ nanoparticles dispersed in mineral oil). Among the evaluated nano-lubricants, the household refrigerator employing LPG refrigerant at 40 g charge with TiO2-MO (0.2 g/L TiO2) lubricant exhibited the greatest COP and second lowest efficiency (56.32 % and 47.06 %, respectively, greater than R134a/POE). With the least energy and exergy performance analysis of the domestic refrigerator. Henderson et al [8] quantified the effect of using nanoparticles like SiO₂/CuO on the flow-boiling of pure R134a and R134a/POE-oil mixes throughout mass-fluxes between 100 kg/m²s and 400 kg/m²s. The results showed using SiO₂ nanoparticles with R-134a, the heat-transfer coefficient decreased by up to 55 %. When CuO nanoparticles were utilized with an R-134a/Polyester mixture, the heat-transfer coefficient rose by 100 %. Bandgar et al [9] determined which type of lubricating oil performs best with SiO₂ nanoparticles with Polyester (POE) oil, and Mineral oil in the refrigeration field, at concentrations of 0.5%, 1%, and 1.5%. When a mixture of Mineral-oil and 0.5% Silica nano-particles were used with R- 134a refrigerant, resulted an enhancement in the freezing time and a reduction of power consumption by 13.89. Nano lubricants can help to save energy while also raising the Coefficient of Performance (COP) by 12.16 %. The present research studies the possibility of SiO₂ nanoparticles to improve vapor compression refrigeration system performance when used at different concentrations (0.1 %, 0.3 %, and 0.5 %) with an R-134a refrigeration gas and PAG oil. A nano-refrigerant of SiO₂ nanoparticles (50nm) blended with 200ml of refrigeration oil and refrigerant gas was pumped into the system. The goal of this study is to compare the power consumption and coefficient of performance of working with a pure refrigerant vs working with a nano-refrigerant. 2. Experimental setup This part deals with the process of construction the vapor compression refrigeration system, preparing, and charging of the nano-lubricant. The main components of the test rig are: Table 1. Components of test rig Figure 1. Components of test rig Figure 2. Vapor compression refrigeration system test rig Along with the nano-fluid preparation and charging devices: • Mechanical stirrer • Ultra-sonic device • Nano-fluid injector Nomenclature: Cpw specific heat of water (J/ kg .K) Ei Readings input of the energy meter (kwh) COP coefficient of performance Ρ density of pure water (g/m³) D diameter of the tank water (m) Mw Mass of water in the tank (g) H height of the tank water (m) dT Temperature difference (C◦) Eo Readings output of the energy meter (kwh) RE Refrigeration effect (KJ) Component Details Compressor Reciprocating compressor with a single-cylinder capacity of 120 W. Condenser Pipe of 6.35 mm diameter and 8 meters. Filter drier Capillary tube Evaporator Evaporator's surface area: 0.152 m² Material: copper Energy meter Pressure gauge Two at the inlet (low pressure gauge) and outlet (high pressure gauge) of the compressor. Temperature sensor Five Thermocouples Type k sensors for different locations. 40 DALYA SHAKER QAID, AND ABBAS ALWI SAKHIR /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES 15 (2022) 038–041 2.1. Nano-fluids Preparation and charging method Nanoparticles are not immediately injected inside the refrigeration system. Instead, they must be thoroughly mixed in the lubricating oil. In general, there are two methods for preparing nanofluids: one-step and two-step procedures. The two-step technique was chosen for this study. In the present case, the lubrication oil was PAG oil. SiO2 nano-particles were blended with lubricating oil according to refrigerant quantity. Stir for 2-3 hours to ensure appropriate mixing of nano-particles with lubricating oil. The nanoparticles are then stabilized in an ultrasonicate and fed into the refrigeration system through a compressor using a nano injector device after thoroughly mixing or completely disseminating in lubricating oil. Table 2. Thermo-physical properties of SiO2 Thermo-physical properties SiO2 Specific heat capacity (J/kg.K) 745 Density (kg/m³) 2220 Thermal conductivity (W/m.K) 1.4 (a ) (b) (c) Figure 3. SiO2 / PAG oil preparation procedure: a) mechanical stir, b) ultra-sonic device, c) Nano-fluid injector 3. Results and discussions This part shows the results of the coefficient of performance, power consumption, and refrigeration effect when using different concentrations of nano-refrigerant. Compare it with the pure R-134a refrigerant. (a) (b) Figure 4.COP and different volume fractions of SiO2 nanoparticles when temperature of water inside the evaporator is: (a) 40C◦ ; (b) 50C◦ Fig. 4 shows that when using pure R-134a refrigerant with PAG oil, COP of the system was 2.3. However with the addition of different concentration of SiO2 nanoparticles, the coefficient of performance increases to 2.81 at a concentration of 0.5%. The COP of the system increased by 18.14% at concentration of 0.5%. (a) (b) Figure 5. Power consumption and different concentrations of SiO2 nanoparticles when temperature of water inside the evaporator is: (a) 40C◦; (b) 50C◦ DALYA SHAKER QAID, AND ABBAS ALWI SAKHIR/AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES 15 (2022) 038–041 41 Fig. 5 shows that when using pure R-134a refrigerant with PAG oil, the power consumed by the compressor was 608.69 KJ. However with using nano-refrigerant, this value was reduced to 567.22 KJ at a concentration 0.5% Figure 6. Refrigeration effect and different concentrations of SiO2 nanoparticles at different temperature of water inside the evaporator Fig. 6 shows that when using pure R-134a refrigerant with PAG oil, the refrigeration effect was 1850 KJ. However, with using nano-refrigerant, it had been increased to 2062 KJ at a concentration of 0.5%. 4. Equations a. Mass of water m= 𝜌.v , g (1) b. Volume of water tank V=π/4D² h , mᶟ (2) c. Refrigeration effect RE=mw cpw dT , KJ (3) d. Power input to compressor P= (E𝒐-Ei).3600 , KJ (4) e. Coefficient of performance COP= 𝒎𝒘 𝒄𝒑𝒘 𝒅𝑻 (𝑬𝒐−𝑬𝒊).𝟑𝟔𝟎𝟎 (5) 5. Conclusion The current work, showed an overall improvement in the VCRS when using different concentrations of SiO2/PAG oil/R-134a nano-refrigerant, because of the nanoparticles thermo-physical properties. In the present work the size of nanoparticles (SiO2) that has been used 50 nm at three concentrations (0.1%, 0.3%, and 0.5%), with three temperatures of water in the evaporator (40C◦, 50C◦, and 60C◦). The observations of this work are the following: 1) Increment in the refrigeration effect, where RE was 1850 KJ in the case of pure refrigerant (R-134a), while increased to 2062 KJ at a concentration of 0.5%. The refrigeration effect maximum increase was at concentration of 0.5% by 12.2%. 2) Reduction in the consumed power, where it was 608.69 KJ in the case of pure refrigerant (R-134a), while decreased to 567.22 KJ at a concentration of 0.5%. The consumed power maximum decrease was at concentration of 0.5% by 6.81%. 3) Increment in the coefficient of performance, where COP was 2.3 in the case of pure refrigerant (R-134a), while increased to 2.81 at a concentration of 0.5%. The COP maximum increase was at concentration of 0.5% by 18.14%. 6. Recommendations The science of nanotechnology is still a new science on the scene, which would greatly increase the efficiency of refrigeration systems. Therefore, my advice to the next researcher is to search for new types of nanoparticles in order to use them in the refrigeration system so that there are more and broader studies on the subject. And also to find solutions to the problems of sedimentation and instability in these materials, in order to use the refrigeration system by adding nanomaterials in reality. Acknowledgements A special thanks to the Department of Mechanical Engineering at Al- Qadisiyah University, for their help and cooperation in the process of using their laboratories for the experimental works. REFERENCES [1] K nil Achari, and Dr.Smt.G.Prasanthi "Performance improvement of VCR system using SiO2 nano powder with polyolester oil and mineral oil as lubricant" Internation Journal for Science and Advance Research In Technology, 3.10 (2017): 2395-1052 [2] Kedzierski, Mark A. "Effect of CuO nanoparticle concentration on R134a/lubricant pool-boiling heat transfer." Journal of Heat Transfer 131.4 (2009). [3] Ghorbani, Babak, et al. "Experimental investigation of condensation heat transfer of R600a/POE/CuO nano-refrigerant in flattened tubes." International Communications in Heat and Mass Transfer 88 (2017): 236-244. [4] Senthilkumara, A., and R. Praveenb. "Performance analysis of a domestic refrigerator using cuo–r600a nano–refrigerant as working fluid." Journal of Chemical and Pharmaceutical Sciences ISSN 974 (2015): 2115. [5] Satheshkumar, G., and K. Mylsamy. "WITHDRAWN: Exergy Analysis for Hybrid Nano-Refrigerants, R134a with Al2O3, CuO, TiO2 and SiO2." (2020): 100043. [6] Bartelt, Kristen, et al. "Flow-boiling of R-134a/POE/CuO nanofluids in a horizontal tube." (2008). [7] Gill, Jatinder, et al. "Energetic and exergetic analysis of a domestic refrigerator system with LPG as a replacement for R134a refrigerant, using POE lubricant and mineral oil based TiO2-, SiO2-and Al2O3-lubricants." International journal of refrigeration 91 (2018): 122-135. [8] Henderson, Kristen, et al. "Flow-boiling heat transfer of R-134a-based nanofluids in a horizontal tube." 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