Improving the Energy Efficiency of Ethanol Separation through Process Synthesis and Simulation

Haelssig, Jan B.

13 July 2011

Worldwide demand for energy is increasing rapidly, partly driven by dramatic economic growth in developing countries. This growth has sparked concerns over the finite availability of fossil fuels and the impact of their combustion on climate change. Consequently, many recent research efforts have been devoted to the development of renewable fuels and sustainable energy systems. Interest in liquid biofuels, such as ethanol, has been particularly high because these fuels fit into the conventional infrastructure for the transportation sector. Ethanol is a renewable fuel produced through the anaerobic fermentation of sugars obtained from biomass. However, the relatively high energy demand of its production process is a major factor limiting the usefulness of ethanol as a fuel. Due to the dilute nature of the fermentation product stream and the presence of the ethanol-water azeotrope, the separation processes currently used to recover anhydrous ethanol are particularly inefficient. In fact, the ethanol separation processes account for a large fraction of the total process energy demand. In the conventional ethanol separation process, ethanol is recovered using several distillation steps combined with a dehydration process. In this dissertation, a new hybrid pervaporation-distillation system, named Membrane Dephlegmation, was proposed and investigated for use in ethanol recovery. In this process, countercurrent vapour-liquid contacting is carried out on the surface of a pervaporation membrane, leading to a combination of distillation and pervaporation effects. It was intended that this new process would lead to improved economics and energy efficiency for the entire ethanol production process. The Membrane Dephlegmation process was investigated using both numerical and experimental techniques. Multiphase Computational Fluid Dynamics (CFD) was used to study vapour-liquid contacting behaviour in narrow channels and to estimate heat and mass transfer rates. Results from the CFD studies were incorporated into a simplified design model and the Membrane Dephlegmation process was studied numerically. The results indicated that the Membrane Dephlegmation process was more efficient than simple distillation and that the ethanol-water azeotrope could be broken. Subsequently, a pilot-scale experimental system was constructed using commercially available, hydrophilic NaA zeolite membranes. Results obtained from the experimental system confirmed the accuracy of the simulations.

Ethanol Separation

Distillation

Pervaporation

Membrane Dephlegmation

Hybrid Separation Processes

Multiphase CFD

VOF Interface Tracking

DNS of Heat and Mass Transfer

Improving the Energy Efficiency of Ethanol Separation through Process Synthesis and Simulation

Haelssig, Jan B.

13 July 2011

Worldwide demand for energy is increasing rapidly, partly driven by dramatic economic growth in developing countries. This growth has sparked concerns over the finite availability of fossil fuels and the impact of their combustion on climate change. Consequently, many recent research efforts have been devoted to the development of renewable fuels and sustainable energy systems. Interest in liquid biofuels, such as ethanol, has been particularly high because these fuels fit into the conventional infrastructure for the transportation sector. Ethanol is a renewable fuel produced through the anaerobic fermentation of sugars obtained from biomass. However, the relatively high energy demand of its production process is a major factor limiting the usefulness of ethanol as a fuel. Due to the dilute nature of the fermentation product stream and the presence of the ethanol-water azeotrope, the separation processes currently used to recover anhydrous ethanol are particularly inefficient. In fact, the ethanol separation processes account for a large fraction of the total process energy demand. In the conventional ethanol separation process, ethanol is recovered using several distillation steps combined with a dehydration process. In this dissertation, a new hybrid pervaporation-distillation system, named Membrane Dephlegmation, was proposed and investigated for use in ethanol recovery. In this process, countercurrent vapour-liquid contacting is carried out on the surface of a pervaporation membrane, leading to a combination of distillation and pervaporation effects. It was intended that this new process would lead to improved economics and energy efficiency for the entire ethanol production process. The Membrane Dephlegmation process was investigated using both numerical and experimental techniques. Multiphase Computational Fluid Dynamics (CFD) was used to study vapour-liquid contacting behaviour in narrow channels and to estimate heat and mass transfer rates. Results from the CFD studies were incorporated into a simplified design model and the Membrane Dephlegmation process was studied numerically. The results indicated that the Membrane Dephlegmation process was more efficient than simple distillation and that the ethanol-water azeotrope could be broken. Subsequently, a pilot-scale experimental system was constructed using commercially available, hydrophilic NaA zeolite membranes. Results obtained from the experimental system confirmed the accuracy of the simulations.

Ethanol Separation

Distillation

Pervaporation

Membrane Dephlegmation

Hybrid Separation Processes

Multiphase CFD

VOF Interface Tracking

DNS of Heat and Mass Transfer

Improving the Energy Efficiency of Ethanol Separation through Process Synthesis and Simulation

Haelssig, Jan B.

13 July 2011

Worldwide demand for energy is increasing rapidly, partly driven by dramatic economic growth in developing countries. This growth has sparked concerns over the finite availability of fossil fuels and the impact of their combustion on climate change. Consequently, many recent research efforts have been devoted to the development of renewable fuels and sustainable energy systems. Interest in liquid biofuels, such as ethanol, has been particularly high because these fuels fit into the conventional infrastructure for the transportation sector. Ethanol is a renewable fuel produced through the anaerobic fermentation of sugars obtained from biomass. However, the relatively high energy demand of its production process is a major factor limiting the usefulness of ethanol as a fuel. Due to the dilute nature of the fermentation product stream and the presence of the ethanol-water azeotrope, the separation processes currently used to recover anhydrous ethanol are particularly inefficient. In fact, the ethanol separation processes account for a large fraction of the total process energy demand. In the conventional ethanol separation process, ethanol is recovered using several distillation steps combined with a dehydration process. In this dissertation, a new hybrid pervaporation-distillation system, named Membrane Dephlegmation, was proposed and investigated for use in ethanol recovery. In this process, countercurrent vapour-liquid contacting is carried out on the surface of a pervaporation membrane, leading to a combination of distillation and pervaporation effects. It was intended that this new process would lead to improved economics and energy efficiency for the entire ethanol production process. The Membrane Dephlegmation process was investigated using both numerical and experimental techniques. Multiphase Computational Fluid Dynamics (CFD) was used to study vapour-liquid contacting behaviour in narrow channels and to estimate heat and mass transfer rates. Results from the CFD studies were incorporated into a simplified design model and the Membrane Dephlegmation process was studied numerically. The results indicated that the Membrane Dephlegmation process was more efficient than simple distillation and that the ethanol-water azeotrope could be broken. Subsequently, a pilot-scale experimental system was constructed using commercially available, hydrophilic NaA zeolite membranes. Results obtained from the experimental system confirmed the accuracy of the simulations.

Ethanol Separation

Distillation

Pervaporation

Membrane Dephlegmation

Hybrid Separation Processes

Multiphase CFD

VOF Interface Tracking

DNS of Heat and Mass Transfer

Improving the Energy Efficiency of Ethanol Separation through Process Synthesis and Simulation

Haelssig, Jan B.

January 2011

Worldwide demand for energy is increasing rapidly, partly driven by dramatic economic growth in developing countries. This growth has sparked concerns over the finite availability of fossil fuels and the impact of their combustion on climate change. Consequently, many recent research efforts have been devoted to the development of renewable fuels and sustainable energy systems. Interest in liquid biofuels, such as ethanol, has been particularly high because these fuels fit into the conventional infrastructure for the transportation sector. Ethanol is a renewable fuel produced through the anaerobic fermentation of sugars obtained from biomass. However, the relatively high energy demand of its production process is a major factor limiting the usefulness of ethanol as a fuel. Due to the dilute nature of the fermentation product stream and the presence of the ethanol-water azeotrope, the separation processes currently used to recover anhydrous ethanol are particularly inefficient. In fact, the ethanol separation processes account for a large fraction of the total process energy demand. In the conventional ethanol separation process, ethanol is recovered using several distillation steps combined with a dehydration process. In this dissertation, a new hybrid pervaporation-distillation system, named Membrane Dephlegmation, was proposed and investigated for use in ethanol recovery. In this process, countercurrent vapour-liquid contacting is carried out on the surface of a pervaporation membrane, leading to a combination of distillation and pervaporation effects. It was intended that this new process would lead to improved economics and energy efficiency for the entire ethanol production process. The Membrane Dephlegmation process was investigated using both numerical and experimental techniques. Multiphase Computational Fluid Dynamics (CFD) was used to study vapour-liquid contacting behaviour in narrow channels and to estimate heat and mass transfer rates. Results from the CFD studies were incorporated into a simplified design model and the Membrane Dephlegmation process was studied numerically. The results indicated that the Membrane Dephlegmation process was more efficient than simple distillation and that the ethanol-water azeotrope could be broken. Subsequently, a pilot-scale experimental system was constructed using commercially available, hydrophilic NaA zeolite membranes. Results obtained from the experimental system confirmed the accuracy of the simulations.

Ethanol Separation

Distillation

Pervaporation

Membrane Dephlegmation

Hybrid Separation Processes

Multiphase CFD

VOF Interface Tracking

DNS of Heat and Mass Transfer

Gas in engine cooling systems : occurrence, effects and mitigation

Woollen, Peter

January 2013

The presence of gas in engine liquid cooling systems can have severe consequences for engine efficiency and life. The presence of stagnant, trapped gases will result in cooling system hotspots, causing gallery wall degradation through thermal stresses, fatigue and eventual cracking. The presence of entrained, transient gases in the coolant flow will act to reduce its bulk thermal properties and the performance of the system s coolant pump; critically the liquid flow rate, which will severely affect heat transfer throughout the engine and its ancillaries. The hold-up of gas in the pump s impeller may cause the dynamic seal to run dry, without lubrication or cooling. This poses both an immediate failure threat should the seal overheat and rubber components melt and a long term failure threat from intermittent quench cooling, which causes deposit formation on sealing faces acting to abrade and reduce seal quality. Bubbles in the coolant flow will also act as nucleation sites for cavitation growth. This will reduce the Net Positive Suction Head available (NPSHA) in the coolant flow, exacerbating cavitation and its damaging effects in locations such as the cylinder cooling liners and the pump s impeller. This thesis has analysed the occurrence of trapped gas (air) during the coolant filling process, its behaviour and break-up at engine start, the two-phase character of the coolant flow these processes generate and the effects it has on coolant pump performance. Optical and parametric data has been acquired in each of these studies, providing an understanding of the physical processes occurring, key variables and a means of validating numerical (CFD) code of integral processes. From the fundamental understanding each study has provided design rules, guidelines and validated tools have been developed, helping cooling system designers minimise the occurrence of trapped air during coolant filling, promote its breakup at engine start and to minimise its negative effects in the centrifugal coolant pump. It was concluded that whilst ideally the prevention of cooling system gases should be achieved at source, they are often unavoidable. This is due to the cost implications of finding a cylinder head gasket capable of completely sealing in-cylinder combustion pressures, the regular use of nucleate boiling regimes for engine cooling and the need to design cooling channel geometries to cool engine components and not necessarily to avoid fill entrapped air. Using the provided rules and models, it may be ensured stagnant air is minimised at source and avoided whilst an engine is running. However, to abate the effects of entrained gases in the coolant pump through redesign is undesirable due to the negative effects such changes have on a pump s efficiency and cavitation characteristics. It was concluded that the best solution to entrained gases, unavoidable at source, is to remove them from the coolant flow entirely using phase separation device(s).

621.43

Optimizing hydraulic reservoirs using euler-eulerlagrange multiphase cfd simulation

Muttenthaler, Lukas, Manhartsgruber, Bernhard

25 June 2020

Well working hydraulic systems need clean hydraulic oil. Therefore, the system must ensure the separation of molecular, gaseous, liquid and solid contaminations. The key element of the separation of contaminants is the hydraulic reservoir. Solid particles are a major source of maintenance costs and machine downtime. Thus, an Euler-Euler-Lagrange multiphase CFD model to predict the transport of solid particles in hydraulic reservoirs was developed. The CFD model identifies and predicts the particle accumulation areas and is used to train port-to-port transfer functions, which can be used in system models to simulate the long-term contamination levels of hydraulic systems. The experimental detection of dynamic particle contamination levels and particle accumulation areas validate and confirm the CFD and the system model. Both models in combination allow for parameter and design studies to improve the fluid management of hydraulic reservoirs.

info:eu-repo/classification/ddc/620

ddc:620

CFD on Open Wet Cutch to Reduce Drag Losses / CFD av våta kopplingar för minskade förluster

Duraisamy, Rimmie

January 2017

As the need for highly efficient transmission systems increase, it is imperative to have lower fuel consumption levels. Hence, it becomes crucial to investigate and understand reasons behind various losses occurring within the system. Clutches and gears contribute to the major losses within a transmission system. In this thesis project, the drag losses in disengaged wet clutch is studied and efforts have been made to come up with solutions to reduce these losses. Computational Fluid Dynamics (CFD) is used as tool to understand the oil flow in the clutch system. The thesis tasks focused on: - Better understanding of flow physics and oil inlet to the clutch pack - Design and analysis of groove patterns to reduce drag loss - Understand the effect of rotation of clutch discs on groove functionality - Development of a multiphase CFD model with realistic boundary conditions for clutch analysis Initially, the entire clutch pack is modelled to study the oil flow and estimate the amount of oil that is being pumped into the individual gaps between the steel plates and friction discs. To analyze different groove patterns, the clutch model was simplified and only the gap having higher mass flow rate has been considered for simulation. A background study has been done to understand the effect of different clutch parameters on drag losses. Based on the understanding from the literature study, two groove patterns- inclined grooves and waffle grooves have been designed and analyzed in this thesis work. A simplified model with periodic boundary condition and a complete single disc model have been set up and simulated to compare the two groove patterns. To reduce the computational time, at first, a periodic model is set up for groove study. Due to numerical instability observed in the results obtained by using model with periodic boundary condition, the complete single disc model is used for further groove study and comparison. To understand the effect of rotation on grooves, two models have been set up, one with stationary grooves and the other with rotating grooves. While performing the simulations, the temperature and the oil properties have been considered constant. As there were no test results available, the CFD results could not be validated. Convective heat transfer coefficient is estimated to compare the cooling effect of different grooves. An optimal groove pattern would be the one that dissipates oil faster and efficiently out of the clutch pack, and at the same time has better cooling effect. From the results obtained, the inclined grooves were more efficient than waffle grooves in dissipating oil and reducing drag losses. On the other hand, waffle grooves have higher convective heat transfer coefficient when compared to inclined grooves and are better for cooling. / På grund av de ökande kraven på transmissionssystemen är det av stort intresse att även öka deras verkningsgrad för att uppnå lägre bränsleförbrukning. Det blir då viktigt att förstå orsakerna bakom de förluster som uppstår inom systemet. Kopplingar och växlar bidrar till de största förlusterna inom ett transmissionssystem. I denna avhandling studeras strömningsförlusterna i en frånkopplad våtkoppling och försök görs att hitta lösningar för att minska dessa förluster. Computational Fluid Dynamics (numeriska flödesberäkningar) används som ett verktyg för att förstå oljeflödet i kopplingssystemet. Avhandlingens fokus ligger på följande områden: - Förbättra förståelsen för flödesfysik och oljetillförsel till kopplingspaketet - Design och analys av spårmönster för att minska strömningsförluster - Förstå effekten av kopplingsskivornas rotation på spårens funktion - Utveckling av en flerfas CFD-modell med realistiska randvillkor för kopplingsanalys Först modelleras hela kopplingspaketet för att studera oljeflödet och beräkna mängden olja som pumpas in i mellanrummen mellan stålplattorna och friktionsskivorna. För att analysera olika spårmönster förenklades kopplingsmodellen och endast det mellanrum med högst massflödeshastighet har beaktats för simulering. En bakgrundsstudie har gjorts för att förstå effekten av olika parametrar på strömningsförlusterna. Baserat på förståelsen från litteraturstudien har två spårmönster – lutande spår och våffelspår, utformats och analyserats i detta arbete. En nedskalad periodisk modell och en komplett enkelskivsmodell har skapats och simulerats för att jämföra de två spårmönstren. För att minska beräkningstiderna för simuleringarna, användes en periodisk modell för spårgeometristudien. På grund av numerisk instabilitet som observerades i resultaten från den periodiska modellen används den kompletta enkla skivmodellen för ytterligare analys och jämförelse. För att förstå rotationseffekten på spåren har två modeller upprättats, en med stationära spår och en med roterande spår. Under simuleringen har temperaturen och oljeegenskaperna antagits vara konstanta. Eftersom det inte fanns några testresultat tillgängliga kunde CFD-resultaten inte verifieras. Den konvektiva värmeöverföringskoefficienten uppskattades för att kunna jämföra hur kylförmågan påverkas av olika spårgeometrier.  Ett optimalt spårmönster bör utformas sådant att det minskar förlusterna genom att skingra oljan snabbt och effektivt i hela kopplingspaketet, och samtidigt ger en bättre kylningseffekt. Enligt de erhållna resultaten var de lutande spåren effektivare än våffelspår i att skingra olja och reducera strömningsförluster. Å andra sidan ger spår med våffelmönster en högre konvektiv värmeöverföringskoefficient jämfört med lutande spår och därmed förbättrad kylförmåga.

transmission

clutch

multiphase CFD

grooves

oil dissipation

drag losses

transmission

koppling

Multifas-CFD

spårmönster

undanträngning av oljan

strömningsförluster

Engineering and Technology

Teknik och teknologier

Computational Modeling of A Williams Cross Flow Turbine

Pokhrel, Sajjan

January 2017

No description available.

Alternative Energy

Energy

Engineering

Environmental Justice

Environmental Law

Environmental Management

Mechanical Engineering

Non Powered Dams

Cross Flow Water Turbine

CFD

Multiphase CFD analysis

k-omega turbulence model

Numerical Methods for Modeling Dynamic Features Related to Solid Body Motion, Cavitation, and Fluid Inertia in Hydraulic Machines

Zubin U Mistry (17125369)

12 March 2024

<p dir="ltr">Positive displacement machines are used in various industries spanning the power spectrum, from industrial robotics to heavy construction equipment to aviation. These machines should be highly efficient, compact, and reliable. It is very advantageous for designers to use virtual simulations to design and improve the performance of these units as they significantly reduce cost and downtime. The recent trends of electrification and the goal to increase power density force these units to work at higher pressures and higher rotational speeds while maintaining their efficiencies and reliability. This push means that the simulation models need to advance to account for various aspects during the operation of these machines. </p><p dir="ltr">These machines typically have several bodies in relative motion with each other. Quantifying these motions and solving for their effect on the fluid enclosed are vital as they influence the machine's performance. The push towards higher rotational speeds introduces unwanted cavitation and aeration in these units. To model these effects, keeping the design evaluation time low is key for a designer. The lumped parameter approach offers the benefit of computational speed, but a major drawback that comes along with it is that it typically assumes fluid inertia to be negligible. These effects cannot be ignored, as quantifying and making design considerations to negate these effects can be beneficial. Therefore, this thesis addresses these key challenges of cavitation dynamics, body dynamics, and accounting for fluid inertia effects using a lumped parameter formulation.</p><p dir="ltr">To account for dynamics features related to cavitation, this thesis proposes a novel approach combining the two types of cavitation, i.e., gaseous and vaporous, by considering that both vapor and undissolved gas co-occupy a spherical bubble. The size of the spherical bubble is solved using the Rayleigh-Plesset equation, and the transfer of gas through the bubble interface is solved using Henry's Law and diffusion of the dissolved gas in the liquid. These equations are coupled with a novel pressure derivative equation. To account for body dynamics, this thesis introduces a novel approach for solving the positions of the bodies of a hydraulic machine while introducing new methods to solve contact dynamics and the application of Elasto Hydrodynamic Lubrication (EHL) friction at those contact locations. This thesis also proposes strategies to account for fluid inertia effects in a lumped parameter-based approach, taking as a reference an External Gear Machine. This thesis proposes a method to study the effects of fluid inertia on the pressurization and depressurization of the tooth space volumes of these units. The approach is based on considering the fluid inertia in the pressurization grooves and inside the control volumes with a peculiar sub-division. Further, frequency-dependent friction is also modeled to provide realistic damping of the fluid inside these channels.</p><p dir="ltr">To show the validity of the proposed dynamic cavitation model, the instantaneous pressure of a closed fluid volume undergoing expansion/compression is compared with multiple experimental sources, showing an improvement in accuracy compared to existing models. This modeling is then further applied to a gerotor machine and validated with experiments. Integrating this modeling technique with current displacement chamber simulation can further improve the understanding of cavitation in hydraulic systems. Formulations for body dynamics are tested on a prototype Gerotor and Vane unit. For both gerotor and vane units, comparisons of simulation results to experimental results for various dynamic quantities, such as pressure ripple, volumetric, and hydromechanical efficiency for multiple operating conditions, have been done. Extensive validation is performed for the case of gerotors where shaft torque ripple and the motion of the outer gear is experimentally validated. The thesis also comments on the distribution of the different torque loss contributions. The model for fluid inertia effects has been validated by comparing the lumped parameter model with a full three-dimensional Navier Stokes solver. The quantities compared, such as tooth space volume pressures and outlet volumetric flow rate, show a good match between the two approaches for varying operating speeds. A comparison with the experiments supports the modeling approach as well. The thesis also discusses which operating conditions and geometries play a significant role that governs the necessity to model such fluid inertia effects in the first place.</p>

Hydrodynamics and hydraulic engineering

Turbulent flows

Solid mechanics

gerotor pumps

Contact Dynamics

fluid dynamics modelling

Vane Pump

External Gear Machine

fluid inertia

Elasto hydrodynamic film thickness

lubricating interface

hydraulic machine

cavitation and bubble formation

Multiphase CFD

multibody dynamics (MBD)