PROJECTS THEMES SUGGESTIONS 2014. Ranque–Hilsch vortex tube: spot cooling device with no moving parts The vortex tube, also known as the Ranque-Hilsch.

Apresentação em tema: "PROJECTS THEMES SUGGESTIONS 2014. Ranque–Hilsch vortex tube: spot cooling device with no moving parts The vortex tube, also known as the Ranque-Hilsch."— Transcrição da apresentação:

1 PROJECTS THEMES SUGGESTIONS 2014

2 Ranque–Hilsch vortex tube: spot cooling device with no moving parts The vortex tube, also known as the Ranque-Hilsch vortex tube, is a mechanical device that separates a compressed gas into hot and cold streams. It has no moving parts. Vortex tubes have lower efficiency than traditional air conditioning equipment. They are commonly used for inexpensive spot cooling, when compressed air is available. Ref #1 Ref #2

3 COAXIAL TURBULENT JETS Turbulent coaxial jets are employed on several industrial processes including combustion chambers, mixing tanks, cooling systems and premixed burners, for example. Project’s objective: compare the numerical results against the experimental jet velocity profiles. Reference

4 Drag Reduction in Cylinders Flow control is a technique that can be used to improve the efficiency of moving objects by changing the airflow over the boundary surface of the structure’s wall, or the free shear flow. Reference (1)(1) Watch mythbuster episode car drag reductioncar drag reduction

5 Flow Past Cylinders: Vortex Shedding Flow over cylindrical bodies shed periodic vortices which change the drag and lift forces. The fluid-cylinder interaction is relevant to mechanical design of structures (Tacoma mov) and mixing applied to chemical reactors, combustion and in heat transfer equipments.Tacoma mov Reference (1)(1) See also TG works of Durante 2013 (2) and Panza 2013 (3)23 See oscillating cylinder (2)2 See elliptical cylinder (5)5 See paired cylinders (6)6

6 Pipeline start up of crude oil transport Oil produced from offshore production platforms can be transported to the mainland either by oil-tanker. When a tanker is chosen to transport the oil, it is necessary to accumulate oil in some form of storage tank such that the oil tanker is not continuously occupied during oil production, and is only needed once sufficient oil has been produced to fill the tanker. Semi-Submersible W.D. 1650m FPSO W.D. 1000m Oil 16 API  12” - 20 km

7 Pipeline start up Initial time: the pipeline is full of oil at 4 o C. One has to specify a pump to work with high pressure at low flow rates at the initial time. But at steady state the flow rate is high and the pressure is low! May be OK for Steady State...but not able to reach it

8 Pipeline start up Use CFD to study the pipeline start up and estimate: The inlet pressure x time for a range of constant flow rates The heat transfer rate for a range of constant flow rates Consider a fixed pressure at the inlet Determine the inlet volume flow rate with time Determine how long it takes to get steady state

9 Carneiro Hidráulico Veja link no globo rural: http://g1.globo.com/economia/agronegocios/noticia/2013/06/bomb a-de-agua-de-facil-execucao-promete-ajudar-o-produtor-rural.html http://g1.globo.com/economia/agronegocios/noticia/2013/06/bomb a-de-agua-de-facil-execucao-promete-ajudar-o-produtor-rural.html Referencias (1) e (2)(1)(2)

10 VACUUM EJECTOR PUMP A steam ejector is a type of pump that uses the Venturi effect of a converging- diverging nozzle to convert the pressure energy of a motive fluid to velocity energy which creates a low pressure zone that draws in and entrains a suction fluid. After passing through the throat of the injector, the mixed fluid expands and the velocity is reduced which results in recompressing the mixed fluids by converting velocity energy back into pressure energy. The motive fluid may be a liquid, steam or any other gas. The entrained suction fluid may be a gas, a liquid, a slurry, or a dust-laden gas stream. (from wikipedia)pumpVenturi effectconverging- diverging nozzlepressurevelocity WATCH YOU TUBE MOVIE Reference (1)(1)

11 Wave Propagation in an Explosion Fundamental study in compressible flow. Interesting to investigate the wall interaction. Also in compressible flow there are the following topics: shock tube and axi-symmetric flow nozzle. (Stadke)

12 Turbulent B.L. over an Elevation Fundamental problem applied to atmospheric phenomena and also to grain transport in form of dunes. (BFC + Turbulent Flow) http://link.springer.com/article/10. 1007%2Fs40430-013-0024-z Ref (1)1 Ref (2) Ref (2a)2a Ref (2b)2b Ref (3)3 Ref (4)4

13 Orifice Plates Flow Meter Orifice plates are used as a flow meter for being simple and relatively cheap. They are the first option for most industrial applications. Objective of the project is to determine de discharge coefficient using CFD. Ref (1)1 Ref (2)2

14 Flow over a Backward-Facing Step A numerical bench mark solution (in Griebel) Ref (1)1 Ref (2)2

15 Flow in a diffuser for water turbine The use of diffusers around of the horizontal-axis water turbines have been widely studied, since the diffuser causes an improvement in the power coefficient of a turbine and are often called Diffuser Augmented Wind Turbines (DAWT’s). Ref (2)2

16 Flow in a diffuser for a wind turbine The use of diffusers around of the horizontal-axis wind turbines have been widely studied, since the diffuser causes an improvement in the power coefficient of a turbine and are often called Diffuser Augmented Wind Turbines (DAWT’s). Ref (1)1

17 Couette Flow Turbulence model test. Flow prediction in a channel where one wall is smooth and the other is rough. Ref (1)1

18 Deslocamento de ar em túneis devido a passagem de trem. A passagem do trem em túneis causa um deslocamento de ar que pode causar um aumento de pressão e arrasto, desconforto para passageiros (trens alta velocidade) e constituir um dos principais mecanismos de renovação de ar em linhas metroviarias (subterrâneas). Este tema deverá ser abordado como uma continuação do trabalho desenvolvido pelo Leonardo e Marcelo (2º Sem 2013).2º Sem 2013

19 Plate Heat Exchanger & Flow over wavy walls Compact heat exchanger composed by parallel plates with groved channels (hering bone) to enhance heat transfer. Applied to the food industry.

20 Flow over wavy walls Separating and attaching regions, friction factor and heat transfer coefficients. References: Stony & Vanka (1997); Rabel (2012)Stony & Vanka (1997)Rabel (2012)

21 Pressure drop and heat transfer in a compact heat exch. friction factor and heat transfer coefficients. Reference: (1), (2)12

22 FLAT PLATE SOLAR PANNEL Acesse Thermopedia Este tema deverá ser abordado como uma continuação do trabalho desenvolvido pelo Ranyer, Mauro e Cassio (projeto 2º Sem 2013).projeto 2º Sem 2013

23 SOLAR CHYMNEY TO ENHANCE NATURAL VENTILATION Veja artigo

24 Solar Chimney to energy production For thermal environmental comfort For energy generation Referências: (1); (2); (3); (4); (5)12345 Este tema deverá ser abordado como uma continuação do trabalho desenvolvido pelo Adriano e Felipe (projeto 1º Sem 2013).projeto 1º Sem 2013

25 Friction factor in pulsatile pipe flow Pulsating flows appear in various areas of engineering and natural sciences. They not only play an important role in the operations of IC engines, pumps, nuclear power systems, etc., but are also of immense interest for better understanding of human breathing or blood flow through arteries and hence, have received considerable attention over the years. Ref (1)1 Ref (2)2 Ref (3)3

26 Also of Interest Automotive: – flow in manifolds, (see (1))1 – car aerodynamic, – brake heating, Environmental: thermal comfort, pollution dispersion Hydrodynamic bearings Flow in ducts: – T branching flows 3D; – L duct with guiding vanes (BFC); – curved duct: friction and heat transfer (see (1))1

27 1Estudo da distribuição de ar numa sala (auditório do DE) 2Estudo da distribuição de ar no interior de um veículo 3Determinar o arrasto e sustentação num NACA 0012 – 2D, perfil SELIG 1223 4Determinar o arrasto num automóvel, simulação 2D (caminhão, camionete, mini-baja, eco-car, formula SAE) 5Deslocamento de ar em túneis devido ao deslocamento dos trens. Estudar o aumento no arrasto, o aumento de pressão. 6Dispersão de gases, transiente. 7Medição de vazão utilizando placas com orifícios. 8Bocal de uma turbina hidráulica tipo Pelton. 9Escoamento compressível sub-sonico e supersonico em um bocal convergente-divergente 1Escoamento num tubo curvo 90. 1Transferência de calor num feixe de tubos: escoamento cruzado em arranjo triangular – comparação com dados da literatura 1Resfriamento de discos rotativos por jatos de ar – aplicação em freios automotivos 1Transferência de calor num tubo aletado – comparação com dados da literatura. 1Escoamento em bifurcações tipo T – branching flows 1Sustentação e distribuição de ar num Hover-Craft. 1Força num amortecedor hidráulico 1Mancal hidrodinâmico incluindo dissipação térmica 1Chaminé Solar para gerar energia: http://thefraserdomain.typepad.com/energy/2005/06/about_solar_tow.html http://thefraserdomain.typepad.com/energy/2005/06/about_solar_tow.html 1Escoamento induzido pela corrente de gás que impacta normalmente a uma parede (impinging jet) ( arquivo ) arquivo ) 2Escoamento transiente em um canal com superfície livre (tema geral aplicado a imundações de rios e quebra de barragens) método HOL. 2Velocidade de deslocamento de uma bolha alongada dentro de uma tubulação preenchida com líquido, HOL. 2Escoamento de óleo com resfriamento. Problema de relaminarização e pico de pressão. (veja arquivo)veja arquivo)

28 THESE ARE PROJECTS’ THEMES ALREADY DONE BY PREVIOUS YEAR STUDENTS OR IN I.C. AND OR T.G. THEMES NO LONGER AVAILIABLE

29 Thermal conduction in composite materials COMMONLY USED POLYMER materials such as polyethylene (PE), polypropylene (PP), polyvinyl chloride (PVC) or polyamide are good electrical and thermal insulators. Recent applications of polymers as heat sinks in electronic packaging require new composites with relatively high thermal conductivity. Improved thermal conductivity in polymers may be achieved either by molecular orientation or by the addition of conductive fillers.

30 Supersonic Nozzle The purpose of this project is to simulate the operation of a converging-diverging nozzle, perhaps the most important and basic piece of engineering hardware associated with propulsion and the high speed flow of gases. This device was invented by Carl de Laval toward the end of the l9th century and is thus often referred to as the 'de Laval' nozzle. This project explores the compressible aerodynamics assessing the flow through this type of nozzle at a range of conditions.

31 Shark-skin Drag Reduction (Turbulence) See review work of BRIAN DEAN AND BHARAT BHUSHAN Also visit: http://www.csi.tu- darmstadt.de/institute/dcc/forschung_7/skinfriction/index. en.jsphttp://www.csi.tu- darmstadt.de/institute/dcc/forschung_7/skinfriction/index. en.jsp

32 Flow in the Wake of a Taylor Bubble Study of slug flow has application in oil production. The flow in the wake is still poorly understood. The knowledge on the wake flow allow the development of accurate pressure drop model. Objective: model the wake flow numerically.

33 Design of a flush film height sensor Using a conduction heat transfer analog design a capacitive sensor capable to measure liquid film height. The sensor consists of two parallel strips of metal flush to the wall. Coney – conductance probe Ceccio – conductance probe

34 Turbulent Jet Impinging Turbulent jets impinging onto a rough surface are a simple and effective means of promoting the heating or cooling of surfaces. In fact, the number of applications an impinging jet encounters in nature and technology is impressively high. The vertical take-off of aircrafts, the cooling of electronic instruments and the tempering and shaping of glass name only a few of numerous applications.