Your search keyword '"cooling"' showing total 1,432 results

1. Performance improvement of an air conditioner by utilizing condensate water from evaporator.

Author

Setyawan, Andriyanto, Badarudin, Apip, and Sunardi, Cecep

Subjects

*EVAPORATORS, *LOW temperatures, *COOLING

Abstract

An experimental investigation of the effect of condenser cooling on the performance of a split-type air conditioner with a nominal cooling capacity of 2.6 kW using refrigerant R410a has been carried out. In this experiment, condensate water from the evaporator was flowed and poured directly into the condenser. Due to its lower temperature, the condenser could give the cooling effect to the condenser. In addition, the evaporation of the condensate water can give additional cooling to the condenser. From this experiment, it reveals that the cooling capacity increases by 1.8%, power consumption decreases by 3.5% and COP increases by 3.4%. [ABSTRACT FROM AUTHOR]

Published

2024

2. Estimation of laminar natural circulation flow based on temperature and geometrical variations of the FASSIP-04 rectangular loop.

Author

Yuliaji, Dwi, Waluyo, Roy, Oktaviandi, Ryan, Septiadi, Wayan Nata, Deendarlianto, Indarto, and Juarsa, Mulya

Subjects

*COOLING systems, *WORKING fluids, *WATERWORKS, *SYSTEM safety, *COOLING

Abstract

The failure of the active cooling system in the accident case of the Fukushima Daiichi nuclear power plant has become a problem in developing a passive cooling system by utilizing the applicable natural laws. The natural circulation flowas the basis of the passive cooling principle is very dependent on the temperature or power parameters, as well as geometric parameters such as the total length of the pipe, diameter, and height difference between the cooling and heating sections. So that the phenomenon of changes in natural circulation flow rates in passive cooling systems based on geometric parameters innuclear reactor safety systems is an essential concern in similar research worldwide. This study aims to analyze changes in natural flow rate with water working fluid in laminar conditions based on geometric parameters with variations in temperaturedifferences on the hot and cold sides using the FASSIP-04 Rectangular Loop design. Research has been carried out using dataanalysis methods based on changes in geometric parameters (boundary conditions, BC) and operational parameters (initial conditions, IC). The analysis is based on 180 the amount of data generated based on calculations. The study shows that only the rectangular loop with a total length of eight meters has the optimum flow rate. The flow rate in the rectangular loop witha pipe diameter of 1 inch with a temperature difference between the cold side and the hot side of 70°C has a natural circulationflow rate of 0.76 m/s. A rectangular loop with a pipe diameter of 2 inches and a temperature difference between the cooler andheater areas of 80°C has a natural circulation flow rate of 0.87 m/s. On a 3-inch diameter loop, the temperature difference between the cold and hot sides is 80°C and has a natural circulation flow rate of 0.89 m/s. The difference in the natural circulation flow rate value based on the diameter of the 1-inch loop against the 2-inch loop is 14%, while the 2-inch loop against the 3-inch loop is 2%. So in this study, increasing the flow rate from a 2-inch diameter loop to a 3-inch loop is not toosignificant. However, a significant increase occurs in a 1-inch loop to a 2-inch loop. [ABSTRACT FROM AUTHOR]

Published

2024

3. Liquid cooling (LC), phase change material cooling (PCMC) and heat pipe cooling (HPC): Comparison and integration of three technologies for thermal management of electric vehicle batteries.

Author

Wang, Yuhan

Subjects

*ELECTRIC vehicle batteries, *PHASE change materials, *HEAT pipes, *THERMAL batteries, *COOLING, *ELECTRIC batteries, *ELECTRIC vehicles

Abstract

The importance of thermal management of batteries and motors is rising as electric vehicles gain popularity. Three crucial technologies for the thermal control of electric car batteries are thoroughly examined in this study: LC, PCMC, and HPC. Each methodology exhibits distinct benefits and is tailored to specific use cases, yet it also presents its set of obstacles and complexities. This paper finds that combining these three technologies can provide a more comprehensive battery thermal management solution. Heat pipes can quickly dissipate heat from hot spots and reduce thermal gradients. Phase change materials can help smooth out temperature fluctuations by absorbing and storing excess heat under high-load conditions. Finally, LC systems can manage the overall heat load by circulating coolant to remove heat from the system and dissipate it into the environment. However, this integrated approach requires careful design and optimization, including consideration of the layout of the components, the heat-generating properties of the different components, and the properties of the selected coolant and phase change materials. Overall, the research in this paper provides valuable insight and opens up new perspectives for understanding and improving battery thermal management in electric vehicles. [ABSTRACT FROM AUTHOR]

Published

2024

4. Condition-based automatic cooling and cleaning system for performance optimization of PV modules.

Author

Jamhour, Atheer, Numan, Ali H., and Hussein, Hashim A.

Subjects

*MATHEMATICAL optimization, *ELECTRIC power, *WATER jets, *COOLING, *JET nozzles

Abstract

This paper presents the design and implementation of automatic cooling and cleaning system (ACCS) for PV modules to optimize the performance of the PV module based on electrical efficiency drop resulting from increased cell temperature at loading and dust accumulation on PV module s surfaces. An increase in PV module temperature causes a linear reduction in its performance, affecting electrical power generation. Pressurized water jets by nozzles are used to cool and clean the front surface of the PV module. The theoretical model of the PV module is verified by MATLAB/Simulink software. The operational performance of ACCS was recorded and analyzed. The experimental results showed before cooling, the maximum power produced by the PV module was 65.31W, while after cooling increased by 73.24W. Also, electrical efficiency yield of before cooling the rate of decreasing efficiency 0.052% per 1℃ while after cooling the efficiency increased by 0.13% for each decrease 1℃. [ABSTRACT FROM AUTHOR]

Published

2024

5. Numerical study of the effect of passive cooling on the performance of photovoltaic panels integrated with thermoelectric generator modules.

Author

Aljibory, Mohammed Wahhab, Hashim, Hasan Talib, and Salbookh, Ali Ajib

Subjects

*THERMOELECTRIC generators, *ELECTRIC power, *HYBRID systems, *ENERGY harvesting, *COOLING, *SOLAR radiation, *BUILDING-integrated photovoltaic systems

Abstract

This research was based on the development of a 3D numerical model to investigate the efficiency of solar energy harvesting using photovoltaic panels combined with thermoelectric generator modules (PV-TEG). The effects of different numbers and distributions of thermoelectric modules when using a passive cooling unit on the performance of PV-TEG system were thus investigated. Seven models of a hybrid system (M1-M7) with different numbers and distributions of TEG items were tested and simulated numerically, and the optimum model performance of the PV-TEG was compared with that of both photovoltaic only and photovoltaic/thermal (PV/T) systems. Based on the results obtained, the optimum model for the hybrid system was determined to be M1. The electrical power of the PV-TE system was also found to be higher than that of the PV only and PV/T systems, by 16.3% and 1.79%, respectively, when exposed to solar radiation of 1,000 W/m2 at an ambient temperature of 25 °C. The average temperature of the PV upper surface for the M1 model PV-TEG was about 47.95 °C, whereas, the average temperature of the PV upper surface for the PV and PV/T systems were 73.3 °C and 46.76 °C, respectively. The theoretical results indicated thus suggest that the effect of passive cooling on the PV-TEG system causes performance to decrease. [ABSTRACT FROM AUTHOR]

Published

2024

6. Cryogenic cooling assisted machining of elastomers – A critical review.

Author

Bagawan, Malikasab, Dundur, Suresh T., Gurani, Rajesh, Shetty, Raviraj, and Hegde, Adithya Lokesh

Subjects

*ELASTOMERS, *SHIPBUILDING, *ELASTIC deformation, *COOLING, *ELASTICITY, *MACHINING

Abstract

Elastomeric materials are broadly used for damping augmentation in variety of applications due to their simple design, low weight density and high reliability and low tensile strength. Generally, the components of elastomers are manufactured in large quantity through injection moulding process. However, when required in small numbers for the specific applications such as aerospace, ship building, biomedical engineering etc and also 000when required in complex shapes and higher accuracy manufacturing elastomeric components through injection moulding process turns out to be an expensive process due to higher initial cost. Under those circumstances machining appears to be a promising process due to its versatility and accuracy. On the other hand machining Elastomers in normal circumstances is not so easy due to high elastic deformation that occurs in the entire workpiece during machining which results in poor product quality. Cryo-cooling assisted machining provide solution to this problem which is nothing but an extended quenching process in the conventional heat treatment cycle in which high elastic property disappears temporarily. The present paper aims at brief literature survey on recent developments in cryogenic machining of elastomers. [ABSTRACT FROM AUTHOR]

Published

2024

7. Performance enhancing of single slope solar still using glass cover cooling.

Author

Faisal, Zahraa A., Hameed, Hassanain Ghani, and Al-Shamkhee, Dhafer Manea H.

Subjects

*SOLAR stills, *WATER use, *COOLING, *GLASS, *COOLING systems

Abstract

The use of a water spray system as the glass cover cooling of single slope solar still was experimentally investigated as an attempt to enhance the daily productivity of solar still. The cooling water was sprayed in a pulse form for 30 sec while the time between any two successive pulses was altered as 5 minutes, 10 minutes, 20 minutes, and 30 minutes, respectively. the present work also considered the form of continuous cooling water spray. The collected result highlighted that the daily productivity of conventional single slope solar still enhanced by 10%, 14%, 27%, 17.5%, as single slope solar integrated with a cooling system of (30 sec/ 30 min), (30 sec/ 20 min), (30 sec/ 10 min), and (30 sec/ 5 min), respectively. Where the best pulse timing was (30 sec/ 10 min) since any farther increment induces a negative influence on the daily output of the conventional single slope solar still. [ABSTRACT FROM AUTHOR]

Published

2024

8. Investigation of porous cooling in the ventilation apparatus of a rolling stock brake disc.

Author

Yaitskov, I. A., Polyakov, P. A., and Litvinov, A. E.

Subjects

*THERMAL boundary layer, *AIR flow, *DISC brakes, *BOUNDARY layer (Aerodynamics), *COOLING, *AUTOMOBILE brakes, *ROLLING stock

Abstract

Based on the study, it can be concluded that the use of porous cooling in the form of separate inserts into the finned ventilation apparatus will be an additional source of heat removal from heated surfaces. The use of porous inserts reduces the thermal boundary layer of the air flow of the brake disc ventilation ducts. This is ensured by an additional change of air masses in the boundary layer rather than using a solid impermeable rib of the ventilation apparatus. After theoretical studies of the parameters of porous cooling, mathematical modeling of the parameters of influence on the efficiency of porous cooling and air flow rate when passing through the porous inserts was carried out. With an increase in the length of the porous insert, the efficiency of porous cooling and the flow rate of the air flow through the porous insert decreased. The intensity of the decrease was determined by the flow regime of the air flow in the thermal boundary layer and the order of the value of the air flow rate. [ABSTRACT FROM AUTHOR]

Published

2023

9. Numerical study on multi-effect and multi-stage NH3/H2O absorption chillers for negative cooling in SHIP systems.

Author

Aste, Fabio and Phan, Hai Trieu

Subjects

*GREENHOUSE gases, *SOLAR air conditioning, *PLATE heat exchangers, *SOLAR heating, *COOLING, *MASS transfer

Abstract

Solar Heat for Industrial Processes (SHIP) is a growing-interest concept in the context of the reduction of both energy consumption and greenhouse gases emissions. As industry often needs cooling power at negative temperatures, solar-fuelled NH3/H2O absorption systems can be employed for this task. In the context of the FriendSHIP European project, different innovative solutions are investigated for cooling production at -20°C and -40°C from 100-250°C solar heat. The first proposition concerns a GAX (Generator-Absorber heat eXchange) cycle based on Plate Heat Exchangers (PHE). This innovative design improves heat and mass transfers, thus performance. In addition, manufacturing costs decrease, as the needed components are standardized and available in the market. Two variants are simulated on EES (Engineer Equation Solver) for -20°C and -40°C cooling production. Other absorption cycles are modified to fit PHEs, in particular the pressure-staged cycle, the vapour-exchange cycle and the Semi-GAX cycle. They all are two-stage cycles and are simulated for -40°C cooling production only. The numerical comparison allows identifying the best solutions for the SHIP integration, giving an overview on the operating temperature ranges for each cycle. In particular, the following results are obtained. At ambient temperature TAMB = 20°C and below, the GAX cycle is the most performing one. It shows a maximum Coefficient of Performance (COP) of 0.53 for a cold production TE,OUT = -20°C (+27% compared to the single-stage cycle), and a COP of 0.36 at TE,OUT = -40°C (+60% than the single-stage cycle). For TAMB > 30°C, the pressure-staged cycle with GAX is the preferable one, as it can be operated with COP>0.15 at TAMB up to 50°C. The Semi-GAX cycle seems the most adapted to operation at low heat source temperature, being able to operate down to 80°C with COP>0.20. [ABSTRACT FROM AUTHOR]

Published

2023

10. Complex configurations of partial cooling with recompression Brayton cycles using s-CO2 mixtures.

Author

Tafur-Escanta, Paul, Valencia-Chapi, Robert, Coco-Enríquez, Luis, and Muñoz-Antón, Javier

Subjects

*BRAYTON cycle, *SUPERCRITICAL carbon dioxide, *WORKING fluids, *SUPERCRITICAL fluid extraction, *COOLING, *PLANT performance, *FACTORY design & construction

Abstract

This work evaluates the impact of using supercritical carbon dioxide mixtures (s-CO2/COS, s CO2/H2S, s-CO2/NH3, and s-CO2/SO2) as a working fluid carried out Brayton s-CO2 power cycles. Some complex configurations were studied: partial cooling with recompression without reheating (PCRC), partial cooling with recompression and reheating (PCRC RH), partial cooling with recompression and two reheatings (PCRC 2RH), and partial cooling with recompression and three reheatings (PCRC 3RH). The design parameters evaluated are the solar plant performance at the design point, the pinch point in the heat recuperators, and total conductance (UAtotal) with values between 5 – 20 [MW/K]. This analysis is complemented by studying the effects of the compressor inlet temperature (CIT) variation in each configuration. Interesting results are obtained from this work; the mixtures containing COS and H2S provide better efficiency from a CIT = 55 °C compared to the pure s-CO2 fluid in PCRC configuration. While in the PCRC-RH and PCRC-2RH configurations, this occurs at a compressor inlet temperature higher than 57 °C. Finally, in the PCRC-3RH configuration, the efficiency is only slightly better when the CIT is 60 °C. [ABSTRACT FROM AUTHOR]

Published

2023

11. Numerical investigation of mixed convection in a tilted multi-vented cavity filled with nanofluid considering different positions of the outlet port.

Author

Arroub, I., Bahlaoui, A., Belhouideg, S., Raji, A., and Hasnaoui, M.

Subjects

*NANOFLUIDS, *HEAT transfer, *HARBORS, *NANOFLUIDICS, *COOLING, *NANOPARTICLES

Abstract

The present study deals with numerical investigation of mixed convection of Al2O3-water nanofluid with consideration of variable properties inside a rectangular inclined multi-vented cavity heated from one side. Effects of variations of volume fraction of nanoparticles and the positions of outlet port of the cavity on flow and temperature field and rate of heat transfer are studied. The obtained results show that the existence of nanoparticles in the base fluid leads to a significant heat transfer increase. Moreover, a better cooling inside the cavity was found by a displacement of the outlet port from the left to the right of wall. [ABSTRACT FROM AUTHOR]

Published

2023

12. Calculation of the bending capacity of steel sheets with a yield strength gradient.

Author

Pronina, Yulia, Maksimov, Alexander, Peglivanova, Maria, and Kabrits, Sergey

Subjects

*SHEET steel, *BENDING moment, *AUSTENITIC steel, *PLASTICS, *MICROPLATES, *COOLING, *BENDING strength

Abstract

The problem of plane strain pure bending of a plate made of a linearly elastic–perfectly plastic material with a through-the-thickness gradient of strength properties and tension-compression asymmetry is considered. The gradient of strength properties was produced by accelerated one-sided cooling of the plates made of A32 ship steel from the austenitic temperatures. The purpose of the present work was to analyze the effect of various approximations of the strength gradient on the accuracy of determining the critical bending moment corresponding to the complete yielding of the sheets. [ABSTRACT FROM AUTHOR]

Published

2023

13. Mechanical testing of spherical tank workpiece made from Ti-6Al-4V by wire-based additive manufacturing.

Author

Kalashnikov, K. N. and Kalashnikova, T. A.

Subjects

*ELECTRON beam furnaces, *ELECTRIC furnaces, *STRENGTH of materials, *TENSILE tests, *ELECTRON beams, *TITANIUM, *COOLING, *TITANIUM powder

Abstract

In this paper, the study of titanium high-pressure spherical tank billets produced by wire-based electron beam additive manufacturing was carried out. The billets were produced with no active cooling. The macro- and microstructure of the billet material in the "as-built" state was investigated, and static tensile tests were performed to determine the mechanical properties. The studies showed that the thermal conditions of the 3D-printing process of such products lead to a significant decrease in the material strength compared to the target values for the Ti-6Al-4V alloy. [ABSTRACT FROM AUTHOR]

Published

2023

14. Design and development of battery thermal management using immersion cooling.

Author

Meshram, Shreyash M. and Mane, Yogesh

Subjects

*THERMAL batteries, *LITHIUM cells, *LITHIUM-ion batteries, *BATTERY management systems, *LIQUID dielectrics, *COOLING

Abstract

Lithium-ion batteries has promising future in electric vehicles and storage of electricity. The two main issues with these batteries are the charging time and the heating problems. When we vary the discharging and charging rate of the battery, the temperature also increases/decreases respectively. Battery thermal management has a crucial role of maintaining life-cycle and performance of.battery. A battery thermal management system ensures thermal repeatability and prevents thermal runaway of battery. The paper presents the results derived from the experimentation undertaken with this purpose. An experiment was performed on Lithium-ion 18650 battery cells, which are charged with 2 C charging rate which are cooled with immersion cooling via dielectric fluid. The use of this BTMS ensures the thermal runaway is minimized and all the cells are cooled uniformly, which make sure that all the cells are working under desirable conditions. The simulation was verified with experimentally. [ABSTRACT FROM AUTHOR]

Published

2023

15. Device for measuring humidity during grain cooling.

Author

Mukimov, Z. M.

Subjects

*HUMIDITY control, *HUMIDITY, *MANUFACTURING processes, *COOLING, *CEREAL products

Abstract

In the article under consideration, the state of hydrothermal grain processing in industrial conditions is analyzed, certain requirements are imposed on the selection of the method and design of instrumentation for grain moisture control, as well as their high measurement accuracy. The importance of choosing the optimal humidity parameter of the object of study is shown, based on the analysis and evaluation of the accuracy of the dielkometric method of measuring humidity, the basic requirements for the design of humidity control devices, devices of increased accuracy and reliability, allowing to synthesize an electric capacitive model of the primary measuring transducer, are formulated. Recommendations for the synthesis of a measuring device for grain and products of their processing in industrial conditions are given. [ABSTRACT FROM AUTHOR]

Published

2023

16. Integration of Earth-air heat exchanger in buildings review for theoretical researches.

Author

Salem, Hadeel Haitham and Hashem, Alaa Liaq

Subjects

*HEAT exchangers, *VENTILATION, *HEATING, *COOLING

Abstract

Earth-to-air heat exchangers (EAHE) are passive technologies used to cool and heat buildings. This paper aims to review published research on this topic. The review has structured into several sections that focused on the use of numerical evaluation of the performance of the earth tube heat exchanger in the ventilation of the buildings. The review also dealt with the results of studies that concentrated on the heat exchanger performance within different burial depths, the impact of soil, climate characteristics on the heat exchanger performance, and the effect of the merging mechanism adopted with the building (direct or with the cooling and heating systems attached to it). Finally, the paper reviewed the final conclusions reached by the researchers. [ABSTRACT FROM AUTHOR]

Published

2023

17. The effect of adding heatsink cooling with concentrator on increasing photovoltaic performance.

Author

Arifin, Z., Baharuddin, M. L., Juwana, W. E., Suyitno, Tjahjana, D. D. D. P., Muqoffa, M., and Prasetyo, S. D.

Subjects

*SOLAR energy, *SOLAR concentrators, *MAXIMUM power point trackers, *SOLAR panels, *HEAT transfer, *ELECTRICAL energy, *COOLING

Abstract

Solar energy is utilized by converting it to electrical energy using solar photovoltaic (PV). Solar energy is absorbed and converted by PV up to 30%. The remaining energy is wasted in the form of heat which raises the surface temperature and causes damage to the solar photovoltaic. So that it can affect the performance produced by solar photovoltaic. Lowering the temperature of solar photovoltaic using a heatsink as a heat transfer medium. The effectiveness of the heatsink is influenced by the air flow so as to facilitate heat transfer. Therefore, the study conducted experiments with the addition of an air concentrator to be installed as a support for heatsink performance in the solar photovoltaic cooling process. The addition of a concentrator at the peak intensity of the solar panel can reduce the working temperature by 4.8°C. Solar panels with concentrators can increase the maximum power value by 1.45 W and efficiency by 0.38% higher than panels without concentrators. [ABSTRACT FROM AUTHOR]

Published

2023

18. Lithium-ion cylinder battery power cooling: A review.

Author

Avista, Zeluyvenca, Ubaidillah, Yaningsih, Indri, and Prabowo, Aditya Rio

Subjects

*LITHIUM cells, *LITHIUM-ion batteries, *BATTERY management systems, *TEMPERATURE distribution, *COOLING, *ELECTRIC vehicles

Abstract

Electric vehicles (EVs) are an environmentally friendly energy source. One EV application uses Lithium-ion (Li-ion) battery cells. In practice, li-ion operation generates heat which will burden battery performance. Therefore, this review paper will discuss the battery thermal management system (BTMS). There are several methods of BTMS, but this paper review will only focus on air-cooled and liquid-cooled BTMS, where it is still rare to find a comparison of these two cooling methods. The goal is to know about the best cooling method. The results show that liquid-cooled BTMS is superior in uniform temperature distribution but is more complex, and fluid leakage can occur. In comparison, air-cooled BTMS has the advantage of a more accessible system, but the temperature distribution between batteries is less even. [ABSTRACT FROM AUTHOR]

Published

2023

19. Experimental study of performance AC split retrofitting R32 to R290.

Author

Ulum, Rizka, Fajar, Berkah, Utomo, Tony Suryo, and Ridwan

Subjects

*PERFORMANCE theory, *RETROFITTING, *REFRIGERANTS, *COOLING

Abstract

Nowadays, split air conditioners used by the public use refrigerants that are not yet environmentally friendly, one of which is refrigerant R32. The original R32 split air conditioner with a 1 PK cooling capacity was replaced with an refrigerant R290. This study aims to test the performance of refrigerant R290 compared to refrigerant R32. The mass of R290 that is charged to the split AC is 60% with an ambient temperature of 30°C at room temperatures of 23 C, 25 C, and 27 C. With another ambient temperature of 35°C at room temperatures of 25 C and 27 C. The power consumption of R290 is 35% decrease from that of R32. The cooling capacity of R290 has decreased by 33.15% from that of R32. For the COP value, R290 was a decrease 20.01% from R32. The results obtained show that the performance of the refrigerant R290 has not been maximized to replace refrigerant R32. [ABSTRACT FROM AUTHOR]

Published

2023

20. Optimization studies of fresh cooling water network in ammonia manufacturing plant.

Author

Al Shamakhi, Khalid Abdullah, Lakkimsetty, Nageswara Rao, Shaik, Feroz, and Varghese, M. J.

Subjects

*FRESH water, *HEAT of formation, *HEAT exchangers, *HEATING load, *FACTORIES, *COOLING, *AMMONIA, *POLYMER networks

Abstract

The heat exchanger network system is an important part of the process industry. Closed-loop fresh cooling water heat exchanger network in ammonia manufacturing plant is used for the cooling of process fluids. From commission stage to the present operation stage, the heat loads in various heat exchangers of fresh cooling water network system got varied in the ammonia manufacturing plant. Some heat exchangers were overloaded and some running at sub cooled below the process requirements. An optimization study was carried out on fresh cooling water network system to fix the heat load distribution across the network system. The process-side heat duty was calculated by using the heat of formation for each component at the inlet and outlet of individual heat exchanger. The calculated heat duty values were compared with the values obtained from Aspen HYSYS simulation modeling techniques. The total flow required through the whole network can be reduced by 3000 m3/h without affecting the production of the plant and approximately $ 65000-130000 can be saved per year. [ABSTRACT FROM AUTHOR]

Published

2023

21. The effect of natural convection on the cooling of the energy inverter.

Author

Hrabovský, Peter, Kolková, Zuzana, Belány, Pavol, Kantová, Nikola Čajová, and Matušov, Jozef

Subjects

*NATURAL heat convection, *COOLING, *HEAT transfer, *HEAT of formation, *POWER semiconductors

Abstract

This article focuses on methods of cooling and dissipating thermal energy from electrical components installed in electric vehicles, control centers, information technology, space projects and others. The aim is to research the heat dissipation and the formation of temperature fields of a semiconductor power component installed in closed or tight spaces. The method of cooling the components is based on the method of heat transfer and the cooling technology used. For the design of cooling, it is necessary to know the location and position of the examined component, as well as the possibility of heat dissipation. This introductory part of the heat transfer theory defines the already known methods of heat transfer, on the basis of which the design of the cooling capacity is defined. [ABSTRACT FROM AUTHOR]

Published

2023

22. Using LM35 sensor based on Arduino Uno R3 for Newton cooling process analysis of coffee solution.

Author

Ohoiwutun, Madonna Maria Monalisa, Latununuwe, Altje, Huliselan, Estevanus Kristian, and Manuhutu, Fredrik

Subjects

*COFFEE processing, *COOLING, *TEMPERATURE sensors, *DETECTORS, *ELECTRONIC data processing

Abstract

The aim of this study is to determine the effect of dissolved coffee concentration on the cooling process and to calculate the value of the cooling constant for each coffee solution. During the cooling process, dissolved coffee temperatures are monitored using a temperature sensor that has been linked to the computer through Arduino Uno R3. The dissolved coffee temperature scor e at a 1 minute range will be read on IDE Arduino software and monitored through PLX-DAQ software. Based on the data of the cooling process in the dissolved coffee, the concentration of the dissolved does not affect the cooling process, but it does affect the value of cooling constant. The values of Newton's cooling constant of the dissolved coffee at concentration 6%, 7.67% and 10% are 22.24 x 10−3 s−1, 22.22 x 10−3 s−1, 20.11 x 10−3 s−1, respectively. These results indicate that Newton's cooling constant decreases as the concentration of the solution increases. [ABSTRACT FROM AUTHOR]

Published

2023

23. A comparative study of flood cooling and minimum quantity lubrication for an eco-efficient turning.

Author

Amli, Wafiy, Ali, Mohammad Yeakub, Mazid, Abdul Md, Ya'akub, Seri Rahayu, Singh, Ramesh, Ibrahim, Zunaidi, and Hamid, Azlina Diyanah

Subjects

*LUBRICATION & lubricants, *CHEMICAL vapor deposition, *MILD steel, *SURFACE roughness, *COOLING, *TUNGSTEN carbide

Abstract

This research is made to investigate the effectiveness of Minimum Quantity Lubrication (MQL) over flood-cooling lubrication in lathe turning operation on a 1-inch-thick mild steel rod. The cutting tool used for this operation was a tungsten carbide Chemical Vapor Deposition (CVD) coating. Two results needed to be determined; surface roughness value and chip formations. These were carried out using an orthogonal array (OA), and the analysis of variance (ANOVA). The experiment was carried out using cutting speeds of 460, 750 and 1250 rpm and feed rates of 0.2, 0.4 and 0.8 mm/rev. The depth of cut was maintained at 0.125 mm throughout the whole experiment. It was observed that cutting speed and feed rate have significant effect on surface roughness. In terms of chips produced from the turning operation, there were more discontinuous chips being obtained in flood-cooling conditions than in MQL conditions. In comparison, more segmented chips were produced in MQL conditions. The optimum process parameter setting of the experimental design was obtained, with high cutting speed and low feed rate in both MQL and flood-cooling lubrication. [ABSTRACT FROM AUTHOR]

Published

2023

24. CFD analysis of cross-cut heat sink for electronic cooling.

Author

Nguyen, Duy Tue

Subjects

*HEAT sinks, *TEMPERATURE distribution, *THERMAL resistance, *NATURAL heat convection, *COOLING, *ELECTRONIC equipment

Abstract

The advancement in electronic fields make devices smaller but has high heat flux. Therefore, heat dissipation for electronic devices plays a significant role to ensure their safe and good performance. The heat dissipation components including the heat sink, fans eliminate the heat of electronic devices as soon as possible, or else chips will be damaged, malfunction, sort lifetime by overheating. However, it is difficult to predict its operating temperature. Therefore, the CFD based method has been popularly applied in this field to optimise the design, save time and display the temperature distribution of the electronic device. In this paper, a real cross-cut heat sink's dimension was obtained, and then its model was developed by Inventor software. After that, a CFD based investigation was conducted to evaluate its thermal performance. The simulation was carried out with different powers and air velocity as well as at two rotation angles such as:0o and 90o clockwise around X-axis to evaluate the operation parameters. The results show that this heat sink could be applied for electronic devices with a power lower than 6 W without the fan. The heat sink's thermal resistance can be reduced with the increase of air velocity. Even, the temperature of the 10W chip can go down from 87.5oC to 65oC when the velocity increases from 0 m/s to 0.25 m/s. Furthermore, at a 90o clockwise angle, chip temperature under natural convection is somewhat lower than that at a 0o angle. [ABSTRACT FROM AUTHOR]

Published

2022

25. Internal air temperature diversions in summer period in the case of a residential building.

Author

Csáky, Imre

Subjects

*ATMOSPHERIC temperature, *AIR conditioning, *ENGINEERING standards, *BUILDING design & construction, *HOME energy use, *COOLING

Abstract

In recent years around Europe several investigations, measurements were carried out in order to reduce the buildings energy need, but the energy need for cooling, still shows a growing curve. In relation to residential buildings different standards has distinct requirements for internal/operative temperature. To assure the required air temperature and comfort different types of air conditioning systems are installed in buildings. Therefore, in many countries especially in summer period the power networks are strongly overloaded. The internal air temperature in a residential building through two different summer periods was measured. In the first period the internal air temperature was measured without residential ventilation and air conditioning system. In the next summer period measurements were accomplished with residential ventilation and air conditioning system. The indoor air temperature variation was calculated using the EN ISO 13790 standard's methodology, values obtained from the measurements were compared with the analytical values. The theoretical values were used in the case of summer, hot and torrid days for heavy construction buildings. Certainly, the indoor air temperature variation and the energy need for cooling was analysed for one residential building. [ABSTRACT FROM AUTHOR]

Published

2021

26. Analysis on different types of spot cooling systems using best worst method.

Author

Haqqani, Mohammed Hameeduddin, Azizuddin, Mohammed, Qarnain, Syed Shuibul, and Bathrinath, S.

Subjects

*WAREHOUSES, *COOLING systems, *OZONE layer depletion, *REFRIGERANTS, *COOLING

Abstract

Spot cooling is the process of directing a stream of cool air into a designated equipment or a group of people. Using Air as a natural refrigerant in the Spot cooling application brings in fresh air into the building and cools the area. The method of cooling are many, but sustainability is the biggest concern of this industry. The available refrigerants in the market are either effecting ODP (Ozone Depletion Potential) or GWP (Global Warming Potential). The only way out is to introduce sustainable and natural refrigerants. The Hypothesis which is brought into this research is to study the different types of spot cooling techniques available in the industry and challenge it with natural Air as a refrigerant. Sustainability is a paramount importance of our existence. This paper brings in the aspect of using natural refrigerants in comparison with currently used Freon's. This paper tries to introduce spot cooling comparison for basic industrial application and warehouse. Usually in the industry machinist and some times even the machine is not cooled for different reasons. If the cooling is provided both the machinist and machine will have better productivity and performance output. The paper puts light on different ways of spot cooling and the parameters important of the application. Best Worst Method has been applied using industrial expert opinion was taken into consideration. The results were a well-defined application for industrial use for cooling machine is established. Which can act as reference for other researchers to follow. All industrial facilities, warehouses and areas where production work takes place can apply the result of this research paper. [ABSTRACT FROM AUTHOR]

Published

2021

27. Study of the design of an earth-to-air heat exchanger for low energy air cooling and heating of a school in desert climate.

Author

Mahach, Hassan, Benhamou, Brahim, Choukairy, Khadija, Kaoutar, Khallaki, and Kadiri, Mly Saddik

Subjects

*HEAT exchangers, *SCHOOL environment, *COOLING, *EXPERIMENTAL design, *ENTHALPY, *PIPE

Abstract

This work aims at designing two Earth to Air Heat Exchangers (EAHX) for air cooling and heating of a primary school in Arfoud city Morocco, which is located in the South-East of Morocco and characterized by a desert climate. The school is constituted of two independent buildings. The Earth to Air Heat Exchangers should supply cool or warm air at a temperature of around 26°C and 20°C respectively. A total airflow rate of around 2000 m3/h is required for each building. The objective here is to identify the best EAHX parameters combination based on these requirements. For this purpose, a parametric study is performed using the well-validated TYPE 460 of TRNSYS software. Intermittent operation mode from 7 am to 6 pm during the school days (Monday to Saturday) is considered. The identification of the best combinations of the EAHX parameters is based on maximum and minimum EAHX exit temperature for cooling and heating purpose respectively, total cooling and heating capacity and the total pressure drop of the air inside the pipes. It was found that the best EAHX parameters combination is constituted of 4 pipes of 100 m length and 0.195 m internal diameter each buried at 5.7 m depth and operated at 4.63 m/s air velocity. [ABSTRACT FROM AUTHOR]

Published

2020

28. Heat transfer performance in a tilted cavity submitted to external flow of nanofluid.

Author

Arroub, I., Bahlaoui, A., Belhouideg, S., Raji, A., Hasnaoui, M., Choukairy, Khadija, Kaoutar, Khallaki, and Kadiri, Mly Saddik

Subjects

*NANOFLUIDS, *HEAT transfer, *NATURAL heat convection, *NANOFLUIDICS, *COOLING

Abstract

This work is focused on the numerical modeling of steady laminar mixed convection flow in a Ventilated inclined enclosure filled with water-Al2O3 nanofluid and heated from one side. A parametric study is conducted and a set of graphical results is presented and discussed to illustrate the effects of volume fraction of the nanoparticles (0 ≤ ϕ ≤ 0.05), aspect ratio of the cavity (0.5 ≤ A ≤ 4) and mode of imposed external flow (injection or suction) on the flow and heat transfer characteristics. The obtained results showed that the presence of nanoparticles increases the heat transfer and the mean temperature within the cavity. In addition, a better cooling inside the cavity was found for a rectangular enclosure (A = 2). [ABSTRACT FROM AUTHOR]

Published

2020

29. Design of smart container in refrigerator for convenience usage.

Author

Mani, Purusothaman, Santhoshkumar, A., Kumar, K. Manoj, Siva, R., Gnanamani, Senthilkumar, Janarthanam, Hemanandh, Ponnappan, Venkatesan Sorakka, Sasipraba, T, Subramaniam, Prakash, Jayaprabakar, J, Joy, Nivin, Anish, M, Ganesan, S, and Kavitha, K R

Subjects

*REFRIGERATORS, *CONTAINERS, *COOLING, *HOUSEHOLDS, *SMART power grids

Abstract

Now a days everyone has a refrigerator in their home for the purpose to store foods, medicines and eatables etc. Some foods based on its property we can directly use after we taken out from the refrigerator. But under some conditions we can't use the products directly from the refrigerator so we need to bring the product into room temperature for better usage. If not done so some medical issues are being raised so to avoid this, we have a solution smart container in refrigerator which does the de-cooling in the refrigerator itself no need to keep it in temperature and this is a remotely operable from anywhere using IOT. This must be done in an efficient manner and the approach to solve this aspect is discussed further. The following we made cad design for the smart container. Before manufacturing we need the visual proof whether it is suitable are not to our daily household use the factor considered is the refrigerator temperature and the environmental temperature. Under this condition we are going to calculate the time. How long it will take to cool the container. The whole analysis is made in computational manner using the ANSYS software. The final verified result shows the time taken to cool the container is 14 seconds. The analysis result for time taken to de cool the container is 19.5 sec. According to the ANSYS report 20 iterations are need to make the calculation of the time. This will give the better and expected results. [ABSTRACT FROM AUTHOR]

Published

2020

30. Cold thermal energy storage (cTES) for water consumption reduction and performances increase of condenser cooling - WASCOP project.

Author

Bruch, Arnaud, Bourdon, Delphine, Blaise, Anthony, Dumas, Christophe, and Richter, Christoph

Subjects

*HEAT storage, *WATER consumption, *CONDENSERS (Vapors & gases), *COOLING, *COOLING systems

Abstract

The WASCOP (Water Saving for Concentrated Solar Power) project is an EU project dedicated to water saving in CSP power plants. Among the different technologies and aspects considered in the project, the concept of cold thermal energy storage (cTES) has been developed. cTES is considered in addition to the cooling system and used when ambient temperature is too high and may lead to turbine efficiency and electricity production reductions. In these conditions, heat from the condenser is partially stored in the cTES and evacuated trough the available cooler when ambient temperature is lower, typically during the night. A prototype of cTES has been built in the CEA site of Cadarache. Experimental results are presented and shows the relevancy of the test loop and of the cTES concept. [ABSTRACT FROM AUTHOR]

Published

2020

31. Cloudiness characterization in seville using ceilometer measurements.

Author

Larrañeta, Miguel, Pérez-Gallego, Alberto, Silva-Pérez, Manuel. A., Lillo-Bravo, Isidoro, and Richter, Christoph

Subjects

*CLOUDINESS, *CEILOMETER, *DISTRIBUTION (Probability theory), *TIME series analysis, *COOLING, *SOLAR radiation, *FAILURE mode & effects analysis

Abstract

Laser Ceilometers make use of the elastic LIDAR by emitting signals vertically in the atmosphere and analyzing the profile of the backscattered signal to detect clouds and calculate cloud-base height [1]. Due to the high temporal and vertical resolution, the data provided by the ceilometer is rather useful for solar radiation forecasting or assessing the potential of night radiative cooling of a fluid. To characterize cloudiness, we calculated the cloud occurrence and frequency distribution of cloud-base height in Seville, in a similar way to [2]. Furthermore, we analyze the backscatter signal to obtain a time series, with hourly resolution, of estimated cloud depth and cloud optical thickness that would be useful to determine the effects of clouds on solar radiation and night radiative cooling. [ABSTRACT FROM AUTHOR]

Published

2020

32. Magnetic measurements in small aperture of indirect cooling wiggler.

Author

Khrushchev, S., Kanonik, P., Lev, V., Mezentsev, N., Safronov, A., Shkaruba, V., Tsukanov, V., Volkov, A., Zorin, A., Knyazev, Boris, and Vinokurov, Nikolay

Subjects

*MAGNETIC measurements, *SYSTEMS design, *WIRE, *COOLING

Abstract

Several last superconducting wigglers fabricated at BINP have indirect cooling. They all have a small aperture of cryogenic temperature. This feature makes measurement quite a complicated task. A magnetic measurement system designed especially for one of such wigglers is described in this article. Results of magnetic measurements both with a Hall probe and by the stretched wire method are also presented. [ABSTRACT FROM AUTHOR]

Published

2020

33. Effects of sub-cooler on cooling performance of air conditioning system with natural refrigerant R290.

Author

Cakraditya, Gavin, Yudhi, Fathurrahman, Yatim, Ardiyansyah, Purnama, Budi, Nugraha, Dewanta Arya, and Anwar, Fuad

Subjects

*AIR conditioning, *COOLING systems, *ENERGY consumption, *COOLING loads (Mechanical engineering), *REFRIGERANTS, *HYDROCHLOROFLUOROCARBONS, *COOLING

Abstract

Correspond with population growth, Indonesia's energy consumption has been increasing for the past decade. In the last few years, the demand for energy increases by 7.1% every year. The highest energy consumption for a building is in the cooling sector. Much research has been conducted to increase the performance of cooling equipment to reduce their energy consumption. Past research found that hydrocarbon (R290), a natural refrigerant, has higher performance than the most commonly used refrigerant in Indonesia. Furthermore, the hydrocarbon is environmentally friendly, unlike HCFC and HCF. This research is designed to analyze the effects of sub-cooler on the performance of R290 chiller used in an auditorium air conditioning system, and the results show that there is an increase on COP by 6.9% when using sub-cooler on medium part cooling load operation. [ABSTRACT FROM AUTHOR]

Published

2020

34. Numerical Investigation of Conjugate Heat Transfer in a Straight Cooling Channel.

Author

Chen, S., Fukuda, K., Barron, R. M., and Balachandar, R.

Subjects

*HEAT transfer in turbulent flow, *HEAT transfer, *SOLID-liquid interfaces, *TURBULENT heat transfer, *SHEARING force, *COOLING

Abstract

To accurately predict the cooling performance of internal cooling channels, it is critical to properly model the heat transfer mechanism near the solid-liquid interfaces. In this study, a single straight cooling pipe is used to study the modelling of the heat transfer at the solid-liquid interface. Two turbulence models and two inlet flow conditions have been applied and compared. A mesh independence study has also been conducted. Results show that the inlet flow condition does not have a significant impact on the prediction of the overall cooling performance. It has been shown that both the Realizable k-ε and Shear Stress Transport k-ω turbulence models have the capability to accurately simulate both the turbulent flow and the convective heat transfer. Numerical results have been compared with experiments to ensure the validity of the numerical model. This study addresses fundamental modelling issues of importance for a subsequent numerical investigation of the cooling performance of conformal cooling channels in injection molds. [ABSTRACT FROM AUTHOR]

Published

2020

35. Relevance of condensation temperature determination for marine vapour-compression refrigeration system with a composite cooling of condensation unit.

Author

Fot, A. N., Yusha, V. L., Myshlyavtsev, Alexander V, Likholobov, Vladimir A, and Yusha, Vladimir L

Subjects

*COOLING, *AIR-cooled condensers, *REFRIGERATION & refrigerating machinery, *WATER temperature, *TEMPERATURE, *CONDENSERS (Vapors & gases), *EVAPORATIVE cooling, *CONDENSATION

Abstract

The temperatures of the condensers' cooling media (water and air) can vary in a wide range depending on the ship's route. For example, on the route from Odessa to Hopen (Norway), the water temperature changes in the range from 18 ° C to -2 ° C, and air does from 20 ° C to -13 ° C (according to the data for April 13, 2018). Therefore, the well-known recommendations for determining the condensation temperature in the existing calculation methods cannot be applied to a refrigeration unit with composite cooling condensers because they provide different condensation temperature values. To determine the condensation temperature and study the operation of the marine refrigeration unit with composite cooling, a technical-and-economic calculation methodology has been developed. This methodology includes the calculation peculiarities of the composite condenser cooling, the cost of the main refrigeration equipment, the electricity cost and climate data for the ship's route. This method solves the problem of determining the condensation temperature to calculate the condensers and compressors of a marine refrigeration unit. The paper shows the results of the parametric analysis performed for a marine refrigerating unit for the route Odessa – Hopen. The recommended design value for the condensation temperature was 27°C (which corresponds to a pressure of 1066 kPa). It has been proven that the condensation temperature can be precisely determined for a composite condenser cooling at constantly changing cooling medium temperatures, while the technical-and-economic parameters of the refrigerating unit will be optimal. New design values of condensing pressures (temperatures) are obtained to calculate and select heat-exchange surfaces of refrigerating unit's condensers. [ABSTRACT FROM AUTHOR]

Published

2020

36. Energy efficiency analysis of a combined cooling system with night radiative cooling.

Author

Tsoy, A. P., Baranenko, A. V., Granovsky, A. S., Tsoy, D. A., Dzhamasheva, R. A., Myshlyavtsev, Alexander V, Likholobov, Vladimir A, and Yusha, Vladimir L

Subjects

*COOLING systems, *ENERGY consumption, *PHASE transitions, *COOLING, *RADIATORS

Abstract

Evaluation of energy efficiency of a combined cooling system that uses night radiative cooling together with refrigerating machine, with accumulation of cold without a phase transition and the supply of liquid coolant (propylene glycol) to the air cooler was performed based on the results of computer simulation. In the cooling system located in Kostanay (Kazakhstan), there are radiators (12 m2) that cool the coolant at night, as well as a conventional vapor compression refrigerating machine with a reciprocating compressor. The cooling system is used to maintain air temperature at the level of 0 ± 1 °C in a small refrigeration chamber (36 m3) with a low value of heat emission from stored products and the absence of other operational heat influx. It was found that 78.8 days a year, the cooling system can maintain the required temperature due to the operation of radiators without turning on the refrigerating machine. This saves 242 kWh of electricity. Thus, the combined refrigeration system provides 7.6% reduced energy consumption, and also reduces physical deterioration of the refrigerating machine compressor for the annual cycle, which should reduce the financial costs for operating the refrigeration warehouse. [ABSTRACT FROM AUTHOR]

Published

2020

37. Performance enhancement of a biomass-fuelled GT based integrated power and cooling plant by inlet air cooling.

Author

Chattopadhyay, Suman, Ghosh, Sudip, Gao, Xiao-Zhi, Ghadai, Ranjan Kumar, Kalita, Kana, Shivakoti, Ishwer, Kilickap, Erol, Kundu, Tanmoy, and Das, Soham

Subjects

*EPIPHYTES, *POWER plants, *COOLING, *WASTE heat, *PLANT performance, *GAS power plants

Abstract

This study explores the possible performance enhancement of a biomass-fuelled GT based integrated power and cooling plant by employing inlet air cooling for the compressor. The waste heat of the power plant is used to run a cooling plant operating on NH3-H2O based VAR cycle. A portion of the cooling effect is used to reduce the air temperature to 10 °C at the compressor inlet. Results suggest that the GT system efficiency improves by 2-3% with consequent nominal reduction of cooling effect by about 1-2%. The overall exergetic performance of the plant improves by 1-2% compared to a similar plant without inlet air cooling. The improvement in performances are marginal for lower value of pressure ratio but shows better result for higher value of pressure ratio. The price of electricity is found to be 0.083 USD/kWh. The estimated payback period of the plant is obtained as 12.66 years. This plant is found to be economically beneficial when compared to a similar plant without inlet air cooling. [ABSTRACT FROM AUTHOR]

Published

2020

38. Numerical Study of Hydrogen Absorption in a Metal Hydride Tank Embedded with multiple U-Shaped Cooling Channel.

Author

Lewis, Swaraj Dominic, Chippar, Purushothama, and Deb, Anindya

Subjects

*HYDRIDES, *HYDROGEN content of metals, *COOLING, *HEAT transfer, *MASS transfer, *COOLANTS

Abstract

In the present paper, a three-dimensional hydrogen absorption model is applied to a cylindrical LaNi5 hydride bed embedded with multiple U-shaped cooling channels having fins fitted in different orientations. Four number of cooling channels are placed radially at equal distances to achieve uniform heat removal from the bed. The fins are fixed to the coolant channel in transverse and radial directions. The fins volumetrically collect heat from the bed and deliver to the coolant channels. Three metal hydride bed cases are numerically studied, they are with: only coolant channels - case 1, coolant channels fitted with transverse fins - case 2 and coolant channels with transverse and radial fins - case 3. From the simulation results, it is revealed that the presence of fins in the coolant channels significantly improves the heat transfer and hydrogen absorption rate in the bed. The hydrogen absorption in the bed approaches 90% of saturation in 998 s, 867 s and 656 s for case 1, 2 and 3, respectively. Detailed multi-dimensional contours of temperature and hydrogen to metal ratio distributions in the bed are presented for different cases. This study provides a better understanding of heat and mass transfer during the hydrogen absorption in a metal hydride bed. [ABSTRACT FROM AUTHOR]

Published

2020

39. Effect of surface radiation on the transient cooling of heat sources under forced convection - A numerical study.

Author

Patil, Naveen G. and Hotta, Tapano Kumar

Subjects

*COOLING, *RADIATION, *HEAT, *SWITCHING power supplies, *HEAT transfer, *FORCED convection

Abstract

The cooling of electronic gadgets is the biggest challenge in recent years. The selection of innovative cooling techniques leads to the improvement in reliability and performance of electronic systems. Hence, the present study deals with the 3-D numerical modeling and simulation of seven high power protruding heat sources mounted on an SMPS (Switch Mode Power Supply) board using ANSYS FLUENT (R-16) under transient heat transfer mode. The heat sources are cooled under air medium using a velocity of 15 m/s and the heat dissipation rate is 10 W/cm². The objective is to study the surface radiation effect on the cooling of these heat sources under forced convection and to analyze the heating and cooling cycle of the heat sources. Four different surface conditions (Ꜫ = 0.90, Non-metallic paint), (Ꜫ = 0.86, Gray surface, Ꜫ = 0.8, Steel oxidised paint) and (Ꜫ = 0.65, Fe-Cast surface) are considered to analyze the radiation effect and the values are compared with respect to the polished surface (Ꜫ = 0.1). It has been concluded that the surface radiation reduces the temperature of the heat sources by 18 to 25% and helps in better cooling. The time taken for both charging (heating) and discharging (cooling) of the heat sources are also reported for the above emissivity values, and it has been found that charging (heating) takes more time as compare to discharging (cooling) of the heat sources. To generalize the problem, a correlation is put forward for the non-dimensional temperature excess (θ) of the heat sources in terms of their surface emissivity (Ꜫ) and cooling rate (time). [ABSTRACT FROM AUTHOR]

Published

2020

40. Performance Analysis on The Design of The Energy Conversion System of The Indonesia Experimental Power Reactor.

Author

Irianto, Ign. Djoko, Dibyo, Sukmanto, Sriyono, Salimy, Djati H., Kusumastuti, Rahayu, Pujiastuti, Endiah, and Pancoko, Marliyadi

Subjects

*ENERGY conversion, *HEAT, *STEAM generators, *THERMAL efficiency, *VAPOR pressure, *COOLING

Abstract

A non-commercial power reactor with the thermal power of 10 MW is being designed based on a hightemperature gas-cooled (HTGR) reactor called the Experimental Power Reactor (RDE). RDE is designed to generate electricity and to supply thermal energy for experimental purposes. The energy conversion system in the RDE design is designed in cogeneration configuration with a Rankine cycle. The outlet temperature at the reactor design is 700 °C and the outlet temperature in the design of the steam generator outlet is 530 °C. Performance parameters for the design of RDE energy conversion systems are expressed with thermal efficiency parameters and energy utilization factors. To support and complement the RDE design especially the design of energy conversion systems, research is needed relating to the performance parameters of energy conversion systems. This research aims to calculate and analyze the optimal parameters of thermal efficiency and energy utilization factors in the design of the RDE energy conversion system. The calculation and analysis of cooling thermodynamic parameters and coolant system performance parameters of RDE are performed by simulation using ChemCad. The results showed that at 90 bar vapor pressure and cooling mass flow rate of 3.3 kg/s, the highest thermal efficiency is 29.21%. [ABSTRACT FROM AUTHOR]

Published

2019

41. Testing the Cooling Capacity of Two Small-Size Microthrottle Heat Exchange Devices.

Author

Zherdev, A., Tsiganov, D., Burkov, I., Pushkarev, A., and Shakurov, A.

Subjects

*THERMOSTAT, *HEAT, *EXCHANGE, *DRUG delivery devices, *COOLING

Abstract

Microthrottle heat-exchange devices as part of microcryogenic technology systems are used to solve the problems of thermostatic control and cooling of sensors, devices, as well as in medicine. Today, design of such heatexchange devices in a small-size housing with a diameter of about 1.5 mm was developed. The present work using experimental data and calculation considers issues of cooling dynamics and capacity when using such devices in pairs. Results of this study could be used in designing the arrangement of groups of microthrottle heat exchange devices close to heat sources. [ABSTRACT FROM AUTHOR]

Published

2019

42. Defect Formation in the Process of Copper-Titanium Polymetals Manufacturing by an Electron-Beam Method.

Author

Chumaevskii, A. V., Gusarova, A. V., and Khoroshko, E. S.

Subjects

*MANUFACTURING processes, *TITANIUM powder, *ELECTRON beams, *FIBERS, *COOLING

Abstract

The defects forming during the manufacturing of polymetallic samples of the "copper-titanium" system are investigated. The samples were obtained by simultaneous wire feeding into the molten bath. A number of factors causing the formation of various macrostructural defects related to the heterogeneity of the sample cooling and its components, insufficient temperature for the filament melting or excessive temperature of the substrate heating have been revealed. The formation of cracks, pores, unmelted particles of copper filament and inhomogeneities in the distribution of polymetallic components was found. [ABSTRACT FROM AUTHOR]

Published

2019

43. Tracking Simulation of the Bunched Beam Stochastic Cooling.

Author

Gorelyshev, Ivan and Sidorin, Аnatoly

Subjects

*COOLING, *EQUATIONS

Abstract

Mapping equation for the bunched beam stochastic cooling is formulated. For the NICA project parameters, the obtained result is compared with analytical description. According to the results the preferable stochastic cooling method for the NICA collider is clarified. [ABSTRACT FROM AUTHOR]

Published

2019

44. Numerical study of solar thermal combi system to enhance the passive cooling of PV module.

Author

Raj, Ankit, Arunachala, U. C., Bhagat, Keshav Kumar, Kalani, Neha, and Yadav, Prasoon

Subjects

*COOLING, *AIR flow, *SOLAR radiation, *SURFACE temperature, *OFFICE buildings, *SOLAR houses, *SOLAR thermal energy

Abstract

Photovoltaic panels exhibits lower conversion efficiency due to increased surface temperature. Hence the thermal management of panel is important which can be active or passive in nature. However, passive methods are gaining importance due to its inherent advantages. In the present CFD study, the degree of panel cooling is analyzed by optimizing various geometrical parameters of the solar thermal combi system. The optimized geometry yielded air flow rate of 0.034 kg/s which can cool the PV panel by 5°C when exposed to solar radiation level of 800 W/m2. This cooling rate is further validated through experiment. As the solar thermal combi system does air heating and panel cooling processes simultaneously, the overall system efficiency is better and is cost effective compared to two individual units. [ABSTRACT FROM AUTHOR]

Published

2019

45. Sustainable Cooling Technologies for Building Sector.

Author

Kesavan, M., Chidambaram, La., and Velraj, R.

Subjects

*HUMAN comfort, *ENVIRONMENTAL degradation, *SUSTAINABLE buildings, *COOLING

Abstract

Buildings and activities in buildings contribute to a major share of global environmental degradation. Hence the incorporation of sustainable technologies in domestic building cooling is the urgent need of the hour. Passive and energy efficient active building cooling methods are closely linked to human comfort of the residents by reducing the heat gains, maintaining the thermal balance and removing the internal heat from buildings. A comprehensive study focussing on sustainable building cooling technologies for building sector is presented in this paper. [ABSTRACT FROM AUTHOR]

Published

2019

46. Thermal Integrity Modelling Using Finite-Element, Finite- Volume, and Algebraic Topological Methods.

Author

Shaji, Athul and Sankaran, Krishnaswamy

Subjects

*INTEGRITY, *ELECTRONIC equipment, *COOLING

Abstract

We study thermal integrity problem and design solutions for heat sinks used in electronic devices. We discuss modelling challenges using finite-element, finite-volume, and algebraic topological methods. We demonstrate the suitability of algebraic topological method for modelling multiphysics (electro-thermal) problems using the case of radiative and convective cooling in heat sinks. [ABSTRACT FROM AUTHOR]

Published

2019

47. Cold Thermal Energy Storage cTES for Optimized Cooling of CSP Power Plant Power Block – WASCOP Project.

Author

Bruch, Arnaud, Bourdon, Delphine, Camus, Adrien, Dumas, Christophe, and Chouvel-Saye, Alexandre

Subjects

*SOLAR power plants, *HEAT storage, *POWER plants, *COOLING, *SOLAR energy, *TURBINE efficiency, *LOW temperatures

Abstract

The WASCOP (Water Saving for Concentrated Solar Power) project is an EU project dedicated to water saving in CSP power plants. Among the different technologies and aspects considered in the project, the concept of cold thermal energy storage (cTES) has been developed. cTES is considered in addition to the cooling system and used when ambient temperature is too high and may lead to turbine efficiency and electricity production reductions. In these conditions, heat from the condenser is partially stored in the cTES and evacuated trough the available cooler when ambient temperature is lower, typically during the night. A prototype of cTES has been built in the CEA site of Cadarache. Preliminary commissioning has been performed. Final commissioning is expected to be done before Spring 2019 and experimental tests will be made during Summer 2019. [ABSTRACT FROM AUTHOR]

Published

2019

48. Evaluation of controlled cooling for seeded batch crystallization incorporating dissolution.

Author

Adnan, Siti Zubaidah, Saleh, Suriyati, and Abdul Samad, Noor Asma Fazli

Subjects

*CRYSTALLIZATION, *PROCESS optimization, *COOLING, *PARTICULATE matter, *POTASSIUM nitrate, *SEMICONDUCTORS

Abstract

Crystallization is an essential solid-liquid separation technique which is widely used in the industry such as in pharmaceuticals, pigments, food, plastics, semi-conductors and others due to its capability to produce high quality of crystals. The final specification of the crystal product usually is given in terms of crystal size distribution (CSD), shape and purity. However achieving the target CSD for the case of batch seeded cooling crystallization is always a challenge due to the limited control on the production of fine crystals. Generally crystallization process is controlled to be operated in the metastable zone where the crystal particles will grow until the end of the operation. If the crystallization process is operated beyond the metastable concentration, excessive nucleation is expected due to the high supersaturation. As a consequence the target crystal product is able to achieve but there is unnecessary amount of fine crystals by the end of the operation. This unnecessary nucleation can be reduced by incorporating the crystallization process with dissolution phenomena where the temperature of the solution is controlled so that the solution is operated in the undersaturated condition. This condition is enabling the grown crystal particles to dissolve back into solution. Thus reducing the amount of fine crystals in the overall CSD. Therefore the objective of this study is to develop and evaluate controlled cooling for batch seeded crystallization of potassium nitrate incorporating dissolution phenomena. The mathematical model for potassium nitrate crystallization is developed and simulated in MATLAB software where it is validated against experimental data. The optimization algorithm is then developed in order to determine the set-point trajectory for closed­ loop control. Based on this optimal trajectory a closed-loop control is proposed to maintain the crystallization operation at its set-point using two types of controller which consists of Proportional (P) and Proportional-Integral (PI) controllers. Two important criteria are measured in the closed-loop simulation which are the performance of PI controller to follow the given set-point trajectory and the achievement of target CSD. Based on the closed-loop control it is shown that the PI control is more superior than P control by maintaining the operation at its set-point and successfully achieved the desired CSD. In addition the production of fines particle is greatly reduced indicating this new optimal trajectory is capable of producing the target CSD and minimizes the effects of nucleation. [ABSTRACT FROM AUTHOR]

Published

2019

49. Asymmetric natural convection flow in three dimensional attic space.

Author

Cui Huimin, Xu Feng, Suvash, C. Saha, and Liu Qingkuan

Subjects

*NATURAL heat convection, *RAYLEIGH number, *SPACE, *COOLING, *COMPUTER simulation

Abstract

Natural convection in an attic space with top cooling is investigated by three dimensional numerical simulation for a wide range of Rayleigh numbers. The numerical results show the development of natural convection flow in attic space. Three stages: an initial stage, a transitional stage and a fully developed stage are involved. At higher Rayleigh numbers, the flow in the attic space is three dimensional and asymmetry with respect to geometric symmetry plane. The critical Rayleigh number for asymmetric flow is found. [ABSTRACT FROM AUTHOR]

Published

2019

50. Numerical Study of Pin-fin Cooling on Gas Turbine Blades.

Author

Effendy, Marwan, Yufeng Yao, Sugati, Daru, and Tjahjono, Tri

Subjects

*GAS turbine blades, *COOLING, *DISCHARGE coefficient, *HEAT transfer, *ADIABATIC flow

Abstract

This paper describes a numerical study of internal pin-fin cooling performance of a trailing-edge cutback configuration for gas turbine blade. The study was performed at two steps: first, to validate simulation results from an existing TE cutback cooling with staggered pin-fin arrays inside the cooling passage against experimental measurements. Three structured meshes were used for grid convergence and to evaluate film-cooling effectiveness and discharge coefficient; second, to investigate the pin-fin cooling performance with various blowing ratios. Simulations were performed by keeping the same initial and boundary conditions as the corresponding experiment. The results show that validation can be considered acceptable by keeping quality grid and its resolution in near wall regions. Both computational data of the adiabatic film-cooling effectiveness and the discharge coefficient are in fairly good agreement with the test data. The pin-fin array has important roles to promote flow turbulence activity inside the cooling passage, in addition to increase surface areas for heat transfer. Hence the turbulence intensity is more pronounced due to the existence of the pin-fin and it is concomitant with the coolant flow inside the wedge-shaped duct. [ABSTRACT FROM AUTHOR]

Published

2019