K10870 AAFTAB ALAM RAC ME 6TH SEM
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The document presents a student project on experimentally modeling a vortex tube, including its working principle, performance equations, constructional features, applications, and conclusions. The student discusses how compressed air enters the vortex tube tangentially and splits into hot and cold streams without moving parts, and experiments with design parameters to optimize the vortex tube's cooling and heating effects. In conclusion, the vortex tube can provide spot cooling or heating for various applications.
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Study and Analysis of Vortex Tube
International Journal of Engineering and Science Invention (IJESI) is an international journal intended for professionals and researchers in all fields of computer science and electronics. IJESI publishes research articles and reviews within the whole field Engineering Science and Technology, new teaching methods, assessment, validation and the impact of new technologies and it will continue to provide information on the latest trends and developments in this ever-expanding subject. The publications of papers are selected through double peer reviewed to ensure originality, relevance, and readability. The articles published in our journal can be accessed online.
Numerical analysis of flow behaviour and energy seperation
This document summarizes a numerical analysis of flow behavior and energy separation in a vortex tube. It includes an introduction to vortex tubes, objectives of the study, the methodology of modeling the vortex tube in Gambit and analyzing it in Fluent. Results and discussion show profiles of temperature, pressure, velocity variations along the axial direction and with parameters like inlet pressure and number of inlets. The conclusions indicate that temperature separation exists due to a hot peripheral flow and reversing cold inner core flow. Optimization of parameters like inlet pressure and number of inlets was also studied.
Ijri te-03-011 performance testing of vortex tubes with variable parameters
Conventional refrigeration system is a type of refrigeration systems which are costly; noisy, harmful gases released from a machine based on application of this type of system and it is required more maintenance. So, we need to go for unconventional refrigeration systems like vortex tube refrigeration system, which produce less vibrations and which require less maintenance and which are noiseless. It is required for our mechanical engineers to look for enhancing the performance of such vortex tubes. So as a part of my project work, I have chosen various sizes of vortex tubes and test their performances for finding out optimum performance. We will be testing the performance of vortex tubes with different ‘l/d’ ratios and different cold fractions, with different pressures and different nozzle sizes.
Effect of Geometric Modifications on the Performance of Vortex Tube - A Review
This document summarizes research on modifying the geometric parameters of vortex tubes and analyzing their effects on performance. It discusses experiments that studied the impact of factors like cold orifice diameter, number of nozzles, hot end valve angle, and inlet air pressure. The key findings are that there is an optimum cold orifice diameter for maximum energy separation; performance is best with 4 nozzles; larger temperature differences are seen with hot end valve angles of 30-60°; and temperature difference increases with inlet pressure up to 380 kPa. The document reviews several past studies on modifying and analyzing vortex tube design parameters.
A Review of Vortex Tube Refrigeration System
The document discusses the vortex tube refrigeration system. It begins with an abstract that outlines how vortex tubes produce hot and cold air streams from compressed air without affecting the environment. It then reviews the literature on vortex tube design and operation. The key components of the vortex tube are described, including the nozzle, diaphragm, valve, hot and cold sides, and chamber. The document explains how compressed air is tangentially injected into the vortex chamber, creating swirling flows that split into hot and cold streams. It evaluates the advantages and disadvantages of vortex tube systems and their applications in areas requiring compact, reliable cooling like aircraft, spacesuits, and industrial processes.
Rac m ajor
The document summarizes a study of the vortex tube using computational fluid dynamics (CFD) modeling. It discusses the basic workings of the Ranque-Hilsch vortex tube, which uses compressed gas to produce hot and cold air streams without moving parts. The study uses ANSYS Fluent software to build a 3D CFD model of the vortex tube and simulate the temperature separation phenomenon using the k-epsilon turbulence model. The model is meshed and boundary conditions are applied to analyze factors like temperature distribution, energy transfer, and heat dissipation within the vortex tube.
Vortex tube
The vortex tube is a device that separates a gas flow into hot and cold exits without moving parts. High pressure gas enters tangentially through nozzles, creating a swirling vortex. There are two types - uniform and counter flow - which differ in exit placement. In operation, the gas separates into inner and outer layers with different temperatures due to centrifugal forces. The inner layer exits cold and the outer layer exits hot. Vortex tubes provide simple cooling with no refrigerants but have low efficiency. Potential applications include industries needing simultaneous hot and cold air.
main
This document describes the fabrication of a vortex tube using PVC. It was created by five students as their final year project at JNTUA College of Engineering in Pulivendula, India. The vortex tube separates compressed air into hot and cold streams without any moving parts. It has various applications in areas like cooling suits, refrigeration, aviation, and more. The students' project involved designing and building a PVC vortex tube, collecting experimental data on temperature separation at different pressure levels, and analyzing the thermodynamic processes involved.
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Study and Analysis of Vortex Tube
International Journal of Engineering and Science Invention (IJESI) is an international journal intended for professionals and researchers in all fields of computer science and electronics. IJESI publishes research articles and reviews within the whole field Engineering Science and Technology, new teaching methods, assessment, validation and the impact of new technologies and it will continue to provide information on the latest trends and developments in this ever-expanding subject. The publications of papers are selected through double peer reviewed to ensure originality, relevance, and readability. The articles published in our journal can be accessed online.
Numerical analysis of flow behaviour and energy seperation
This document summarizes a numerical analysis of flow behavior and energy separation in a vortex tube. It includes an introduction to vortex tubes, objectives of the study, the methodology of modeling the vortex tube in Gambit and analyzing it in Fluent. Results and discussion show profiles of temperature, pressure, velocity variations along the axial direction and with parameters like inlet pressure and number of inlets. The conclusions indicate that temperature separation exists due to a hot peripheral flow and reversing cold inner core flow. Optimization of parameters like inlet pressure and number of inlets was also studied.
Ijri te-03-011 performance testing of vortex tubes with variable parameters
Conventional refrigeration system is a type of refrigeration systems which are costly; noisy, harmful gases released from a machine based on application of this type of system and it is required more maintenance. So, we need to go for unconventional refrigeration systems like vortex tube refrigeration system, which produce less vibrations and which require less maintenance and which are noiseless. It is required for our mechanical engineers to look for enhancing the performance of such vortex tubes. So as a part of my project work, I have chosen various sizes of vortex tubes and test their performances for finding out optimum performance. We will be testing the performance of vortex tubes with different ‘l/d’ ratios and different cold fractions, with different pressures and different nozzle sizes.
Effect of Geometric Modifications on the Performance of Vortex Tube - A Review
This document summarizes research on modifying the geometric parameters of vortex tubes and analyzing their effects on performance. It discusses experiments that studied the impact of factors like cold orifice diameter, number of nozzles, hot end valve angle, and inlet air pressure. The key findings are that there is an optimum cold orifice diameter for maximum energy separation; performance is best with 4 nozzles; larger temperature differences are seen with hot end valve angles of 30-60°; and temperature difference increases with inlet pressure up to 380 kPa. The document reviews several past studies on modifying and analyzing vortex tube design parameters.
A Review of Vortex Tube Refrigeration System
The document discusses the vortex tube refrigeration system. It begins with an abstract that outlines how vortex tubes produce hot and cold air streams from compressed air without affecting the environment. It then reviews the literature on vortex tube design and operation. The key components of the vortex tube are described, including the nozzle, diaphragm, valve, hot and cold sides, and chamber. The document explains how compressed air is tangentially injected into the vortex chamber, creating swirling flows that split into hot and cold streams. It evaluates the advantages and disadvantages of vortex tube systems and their applications in areas requiring compact, reliable cooling like aircraft, spacesuits, and industrial processes.
Rac m ajor
The document summarizes a study of the vortex tube using computational fluid dynamics (CFD) modeling. It discusses the basic workings of the Ranque-Hilsch vortex tube, which uses compressed gas to produce hot and cold air streams without moving parts. The study uses ANSYS Fluent software to build a 3D CFD model of the vortex tube and simulate the temperature separation phenomenon using the k-epsilon turbulence model. The model is meshed and boundary conditions are applied to analyze factors like temperature distribution, energy transfer, and heat dissipation within the vortex tube.
Vortex tube
The vortex tube is a device that separates a gas flow into hot and cold exits without moving parts. High pressure gas enters tangentially through nozzles, creating a swirling vortex. There are two types - uniform and counter flow - which differ in exit placement. In operation, the gas separates into inner and outer layers with different temperatures due to centrifugal forces. The inner layer exits cold and the outer layer exits hot. Vortex tubes provide simple cooling with no refrigerants but have low efficiency. Potential applications include industries needing simultaneous hot and cold air.
main
This document describes the fabrication of a vortex tube using PVC. It was created by five students as their final year project at JNTUA College of Engineering in Pulivendula, India. The vortex tube separates compressed air into hot and cold streams without any moving parts. It has various applications in areas like cooling suits, refrigeration, aviation, and more. The students' project involved designing and building a PVC vortex tube, collecting experimental data on temperature separation at different pressure levels, and analyzing the thermodynamic processes involved.
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Vortex flow tube
The document reports on the design and fabrication of a vortex flow tube. It describes how compressed air is passed through a nozzle to create a vortex flow that separates into hot and cold streams. Two types of vortex tubes are defined: uniform and counter flow. An experimental setup was created using PVC pipes with nozzles and valves. Testing resulted in a small temperature difference between exits, likely due to air leakage and inability to create tangential flow. Advantages and applications of vortex tubes are discussed.
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Vortex tube refrigeration uses compressed air and has no moving parts. Air is passed through a nozzle into a chamber where it spins creating hot and cold streams. The cold air exits through a diaphragm hole while the hot air exits through a valve. Steam jet refrigeration uses steam expanded through nozzles to lower pressure and boil water below 100C for refrigeration. High pressure steam enters nozzles and flash chamber, lowering pressure and evaporating water to decrease temperature before chilled water is circulated for use. Both systems have advantages of simplicity and flexibility but limited capacity and efficiency.
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K10945 rac gajendra meena
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2. The effectiveness and exergy loss of the heat exchanger were calculated for parallel and counter flow arrangements. The average effectiveness was found to be 48% higher and exergy loss 33% lower in the counter flow arrangement compared to the parallel flow arrangement.
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This document is a project synopsis for designing and fabricating a vortex tube to cool a high-speed motorized spindle. It was created by four project associates and is under the guidance of Dr. K C Devendrappa. The synopsis includes sections on literature survey, objectives, methodology, advantages and disadvantages, and applications. It discusses using a vortex tube, which has no moving parts, to separate compressed air into hot and cold streams in order to cool a motorized spindle shaft.
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The document summarizes a major assignment presentation on CFD analysis of a vortex tube for refrigeration and air conditioning. It includes an introduction to vortex tubes and their working principle, objectives of analyzing flow parameters and temperature separation, a literature review of previous studies, modeling of a vortex tube with specific dimensions, results and discussion of temperature, pressure, and velocity distributions, applications of vortex tubes, advantages, and conclusions. The presentation aims to optimize design parameters like aspect ratio, number of inlets, and pressures to improve temperature separation performance.
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The actual vapor compression cycle differs from the theoretical cycle in several ways that cause losses. In the actual cycle, the refrigerant leaves the evaporator as superheated vapor, compression is neither isentropic nor polytropic, and the refrigerant enters the expansion valve in a subcooled liquid state. Pressure drops also occur in the evaporator and condenser. Deviations from the theoretical cycle increase the required compressor work and can decrease the coefficient of performance. Changes in suction and discharge pressures also affect the refrigerating capacity and cost.
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This document presents a design and analysis of a vortex tube refrigeration system. It begins with an abstract that describes how vortex tube systems can provide cooling in an environmentally-friendly way compared to conventional refrigeration. It then provides details of the design parameters that were analyzed, including the materials, dimensions, and modeling of the vortex tube using CATIA software. A mesh analysis and thermal transient analysis was performed using ANSYS to study temperature drop and heat flux. The analysis showed this can provide a better approximation than experimental data alone. Finally, it concludes the design and analysis demonstrated the utility of different materials for vortex tubes and their potential for further development of sustainable refrigeration technologies.
Components of Vapor Compression Refrigeration System
This document discusses the key components of a vapor compression refrigeration system:
1) The evaporator where refrigerant absorbs heat and evaporates, cooling the air flowing through it.
2) The compressor which compresses the vapor from the evaporator.
3) The condenser where the high pressure vapor is cooled and condensed to a liquid.
4) The expansion valve which controls the flow of liquid refrigerant into the evaporator.
It also covers types of each component and their functions, as well as the environmental effects of refrigerant emissions.
K10945 rac gajendra meena
Thank you for the presentation on vortex tubes. I appreciate you sharing the working principle, performance equations, advantages/disadvantages, constructional features, applications, and conclusions. Please let me know if you have any other questions.
Design plate heat exchangers
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A plate heat exchanger is proposed to cool methanol using brackish water. The initial design requires 97 plates with 48 channels per pass to achieve a heat duty of 4340 kW and overall heat transfer coefficient of 1754 W/m^2°C. Increasing the channels to 60 plates achieves the required coefficient of 1600 W/m^2°C with 121 plates. The pressure drops are estimated to be 0.16 bar for methanol and 0.78 bar for water.
AN EXPERIMENTAL STUDY OF EXERGY IN A CORRUGATED PLATE HEAT EXCHANGER
In the present work an attempt has been made to investigate the performance of a 3 channel 1-1 pass, corrugated plate heat exchanger. The plates had sinusoidal wavy surfaces with corrugation angle of 450. Hot water at different inlet temperature ranging from 400C to 600C was made to flow in the central channel to get cooled by water in the outer channels.
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Performance evaluation and optimization of air preheater in thermal power plant
This document summarizes a study on optimizing the performance of an air preheater at a thermal power plant in India. The study evaluated the performance of a Ljungstrom air preheater (model LAP 13494/2200) before and after adjusting radial sector plate clearances. Key findings include:
- Performance metrics like air leakage, gas side efficiency, and X-ratio were calculated from temperature and gas composition measurements taken at the air preheater inlet and outlet.
- Adjusting the radial sector plate clearances helped reduce air leakage and improve the air preheater's gas side efficiency.
Technical Module - PHE
This document discusses plate heat exchangers. It describes how plate heat exchangers work using thin corrugated plates to induce turbulence and transfer heat. It explains that plate heat exchangers have higher heat transfer coefficients and more compact sizes than shell-and-tube exchangers. The document also classifies plate heat exchangers as gasketed, brazed, or welded and discusses how to optimize the design of a plate heat exchanger to match the required thermal length and available pressure drop.
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2. The effectiveness and exergy loss of the heat exchanger were calculated for parallel and counter flow arrangements. The average effectiveness was found to be 48% higher and exergy loss 33% lower in the counter flow arrangement compared to the parallel flow arrangement.
3. Maximum heat transfer was observed at the highest hot fluid inlet temperature of 70°C, being 5% greater in the parallel flow arrangement. However, the non-dimensional exergy loss and log mean temperature difference were both lower in the
vortex tube
This document is a project synopsis for designing and fabricating a vortex tube to cool a high-speed motorized spindle. It was created by four project associates and is under the guidance of Dr. K C Devendrappa. The synopsis includes sections on literature survey, objectives, methodology, advantages and disadvantages, and applications. It discusses using a vortex tube, which has no moving parts, to separate compressed air into hot and cold streams in order to cool a motorized spindle shaft.
Vortex Tube Refrigeration
Vortex Tubes are devices that work on a standard compressed air supply. Air enters the vortex tube and is literally split into two parts cold air at one end, and hot air at the other all without any moving parts. Vortex Tubes have an adjustable valve at the hot end which controls the volume of the air flow, and the temperature exiting at the cold end. By adjusting the valve, you control the cold fraction which is the percentage of total input compressed air that exits the cold end of the Vortex Tube. Our Vortex Tubes may also be supplied with a fixed preset cold fraction instead of an adjustable valve. Inside is the interchangeable brass generator which can alter the air used in the Vortex Tube, and control the temperature ranges you wish to have at the cold and hot ends. There are several ranges of generators for compressed air capacity. There are also two basic types of generators one to produce the extreme cold temperatures maximum cold temperature out called the C generator and one type to produce the maximum amount of cooling maximum refrigeration called the H generator . N. Harshavardhan Guptha | Rajiv Gandhi "Vortex Tube Refrigeration" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-5 | Issue-4 , June 2021, URL: https://www.ijtsrd.compapers/ijtsrd42468.pdf Paper URL: https://www.ijtsrd.comphysics/other/42468/vortex-tube-refrigeration/n-harshavardhan-guptha
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K10888 ramratan malav (refrigeration & air conditioning)
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AN EXPERIMENTAL STUDY OF EXERGY IN A CORRUGATED PLATE HEAT EXCHANGER
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Design and analysis of plate heat exchanger with co2 and r134a as working f
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IRJET- Performance Improvement of PCM Assisted Heat Pipe
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- 1. CAREER POINT UNIVERSITY KOTA Presented By Aaftab Alam U.I.D: K10870 Branch:Mechanical Sem./Year:6th/3rd Presentation On Experimental Modeling OF Vortex Tube Presented to Mr.Aditya Mishra Assistant professor of mechanical department
- 2. Table Of Content • Introduction • Working Principle • Performance Equation • Advantage/Disadvantage • Constructional Feature • Application • Conclusion
- 3. Introduction • Vortex tube is a simple device, which can cause energy separation. • It consists of nozzle, vortex chamber, separating cold plate, hot valve, hot and cold end tube without any moving parts. • In the vortex tube, when works, the compressed gaseous fluid expands in the nozzle, then enters vortex tube tangentially with high speed, by means of whirl, • The inlet gas splits in low pressure hot and cold temperature streams, one of which, the peripheral gas, has a higher temperature than the initial gas, while the other, the central flow, has a lower temperature.
- 4. Working Principle • The working principle of the vortex tube is as shown in fig. Compressible fluid is tangentially introduced into the vortex tube through the nozzles. • Due to the cylindrical structure of the tube and depending on its inlet pressure and speed, leads a circular movement inside the vortex tube at high speeds. • A pressure difference between the tube wall is lower than the speed at the tube center, because of the effects of wall friction. • As a result, fluid in the center region transfers energy to the fluid at the tube wall. The cooled fluid leaves the tube by moving against the main flow direction after a stagnation point, whereas the heated fluid leaves the tube in the main direction. The RHVT is widely used for both cooling and heating purpose
- 5. PERFORMANCE EQUATIONS FOR VORTEX TUBE • The performance of the vortex tube is marked by cooling effect (ΔTc) and heating effect (ΔTh) which is defined as follows- • Adding equations (1) and (2), the total temperature difference is obtained as the in the following: • Fo • For isentropic process-
- 6. • Where P1, P2, γ are the inlet air pressure, the atmospheric pressure and the specific heat ratio, respectively. As the air flows into the vortex tube, the expansion in isentropic process occurs. The isentropic efficiency can be written as follow: • The vortex tube can be considered as both a cooling and a heating. The efficiency of a cooling can be expressed in terms of coefficient of performance (COP) explained as follows:
- 7. Advantage/Disadvantage • Advantage: • simple • no moving parts • no electricity or chemical • small and lightweight • low cost • maintenance free • instant cold air • temperature adjustable. • No Likage • Disadvantage: • low thermal efficiency • Limited Capacity • Low C.O.P
- 8. CONSTRUCTIONAL FEATURES There are two design features associated with a vortex tube, namely, maximum temperature drop vortex tube design for producing small quantity of air with very low temperatures and maximum cooling effect vortex tube design for producing large quantity of air with moderate temperatures. • These two design considerations have been used in study for increasing the heat transfer rate during forward motion for swirl air and reversed flow of axial air . • The parameters investigated in the study, to understand their inter- relationships and their effect on the performance of the vortex tube are • Nozzle diameter • Cold orifice diameter • Length of the tube • Area at the hot end • The material for cold end (inlet cap) is MS, while the hot end is manufactured in Brass for its good thermal conductivity and rest of part are manufactured in mild steel for reducing its overall cost and machining cost.
- 9. Application • Cooling electronics control • Cooling machining operation • Cooling soldered part • Cooling heat seal • Cooling enviromental chamber
- 10. CONCLUSION • The maximum temperature difference of 27°C is obtained in cold end side while 18°C is obtained in hot end side. • With increase in inlet pressure, COP, cooling effect and isentropic efficiency of the vortex tube increases. Maximum COP and Maximum isentropic efficiency obtained is 0.376 and 23% respectively. • At 5 bar inlet pressure, 45° valve and 90° valve give the best result. • The result with helical convergent nozzle is with divergent tube is compared with literature available and it is found that results are in good agreement with previous work. • Hence, vortex tube can be used for any type of spot cooling or spot heating application
- 11. Reference • Google • www.seminar.com • Wekipedia