Presentation is loading. Please wait.

Presentation is loading. Please wait.

Start Presentation November 15, 2012 Convective Mass Flows I In this lecture, we shall begin looking at the problem of convective mass flows. Irreversible.

Published byLaura Dorsey Modified over 8 years ago

Similar presentations

Presentation on theme: "Start Presentation November 15, 2012 Convective Mass Flows I In this lecture, we shall begin looking at the problem of convective mass flows. Irreversible."— Presentation transcript:

1 Start Presentation November 15, 2012 Convective Mass Flows I In this lecture, we shall begin looking at the problem of convective mass flows. Irreversible thermodynamics concerns itself with purely thermal phenomena, as well as the conversion of free energy into heat. In reversible thermodynamics, the situation is complicated by the fact that it often concerns itself with mass flows next to energy flows.

2 Start Presentation November 15, 2012 Table of Contents Mass flow vs. entropy flowMass flow vs. entropy flow Fluid moving through a pipeFluid moving through a pipe Wave equationWave equation Forced flowForced flow Turbines Compressors and pumpsCompressors and pumps Heat flowHeat flow Mass transport lossesMass transport losses

3 Start Presentation November 15, 2012 Mass Flows vs. Entropy Flows Although there exist phenomena that take place purely in the thermal domain, there can be no mass flows that occur without heat flows accompanying them. The problem has to do with the fact that mass flows always carry their volume and stored heat with them. It is therefore not meaningful to consider these quantities independently of each other. The water circulation within Biosphere 2 may serve as an excellent example. The thermal phenomena of the water cycle cannot be properly described without taking into account its mass flow (or at least its volume flow) as well.

4 Start Presentation November 15, 2012 Fluid Moving in a Pipe I We shall start by modeling the flow of fluids (liquids or gases) in a pipe. The pipe can be subdivided into segments of length  x. If more fluid enters a segment than leaves it, the pressure of the fluid in the segment must evidently grow. The fluid is being compressed. q in q out p dp dt = c · ( q in – q out ) p qq C : 1/c

5 Start Presentation November 15, 2012 Fluid Moving in a Pipe II When the pressure at the entrance of a segment is higher that at the exit, the speed of the fluid must increase. This effect is caused by the mechanical nature of the fluid. The pressure is proportional to a force, and the volume is proportional to the mass. Consequently, this is an inductive phenomenon. It describes the inertia of the moving mass. p in p out q dq dt = k · ( p in – p out ) I : 1/k q pp

6 Start Presentation November 15, 2012 Fluid Moving in a Pipe III Consequently, the following bond graph may be proposed:... 010101 0 C I CCC II q i-1 qiqi qiqi pipi p i+1 pipi

7 Start Presentation November 15, 2012 Capacitors and Inductors Although the hydraulic/pneumatic inductor describes the same physical phenomenon as the mechanical inductor, its measurement units are nevertheless different. dp dt  q = C · [C] = [  q] / [dp/dt] = m 3 ·s -1 N·m -2 ·s -1 = m 4 ·s 2 ·kg -1 dq dt  p = L · [L] = [  p] / [dq/dt] = m 3 ·s -2 N·m -2 = kg·m -4  [  L·C ] = s is still a time constant

8 Start Presentation November 15, 2012 The Wave Equation I Any text book of physics teaches us that moving fluid in a pipe satisfies the wave equation. Discretization in space leads to: 2p2p   t 2 = c 2 · 2p2p   x 2 d2pkd2pk d  t 2 = · ( p k+1 – 2 · p k + p k-1 ) c 2 x2x2  d2pkd2pk d  t 2 = p k+1 – 2 · p k + p k-1 c xx ( ) 2 ·

9 Start Presentation November 15, 2012 The Wave Equation II The following replacement circuit comes to mind: C iCiC L i L1 v i-1 v i L i L2 v i+1 v 0 = 0 dv i /dt = i C /C i C = i L1 – i L2 v i-1 – v i = L· di L1 /dt v i – v i+1 = L· di L2 /dt  C·d 2 v i /dt 2 = di C /dt di C /dt = di L1 /dt – di L2 /dt v i-1 – v i = L· di L1 /dt v i – v i+1 = L· di L2 /dt (L · C) · = v i+1 – 2·v i + v i-1  d2vid2vi dt 2  c = xx  L·C

10 Start Presentation November 15, 2012 The Wave Equation III A chain of such links indeed corresponds to the proposed bond graph: C LLLL C C... 0 C 1 I 0 C 0 C 0 C 1 I 1 I

11 Start Presentation November 15, 2012 The Forced Flow I A forced flow can first be conceptualized as a modulated flow source.... 0 C 1 I 0 C 0 C 0 C 1 I Sf q qq What happens with the energy at the interrupted chain? As the flows to the left and to the right are identical (mass conservation), it makes sense to unite the two flow sources.

12 Start Presentation November 15, 2012 The Forced Flow II... 0 C 1 I 0 C 0 C 0 C 1 I Sf q qq p1p1 p2p2 Unfortunately, there is a small problem: the energy conservation is violated! Se A flow cannot be forced without adding energy to the system. It seems that we need to look at this problem a little more carefully...

13 Start Presentation November 15, 2012 The Turbine I We shall check what happens, when the blade of a turbine is placed in the path of a flow that occurs for reasons external to the model. The pressure difference on the two sides of the blade generates a resulting force that produces a torque in the turbine. The generated torque is proportional to the pressure difference, and consequently, we recognize the effects of a bond-graphic transformer at work. If the turbine is designed optimally, the pressure difference is fully converted to a torque, i.e., no hydraulic energy is left to be stored in an inductor.

14 Start Presentation November 15, 2012 The Turbine II... 010101 0 C I CCC TFI qiqi pipi p i+1 pipi qiqi qiqi  1I :J R :B The pressure difference  p i leads to a torque . This in turn generates an angular velocity  at the turbine, which induces a flow q i back on the hydraulic side.

15 Start Presentation November 15, 2012 Compressors and Pumps I Cause and effect can also be reversed. We can generate a torque at the turbine by means of a DC-motor sitting on the same axle. The turbine together with the motor is now called either compressor or pump. This device induces a flow q i on the hydraulic side, which causes a corresponding pressure difference.

16 Start Presentation November 15, 2012 water pipe compressor / pump DC-motor Compressors and Pumps II... 010101 0 CICCC TF I qiqi pipi p i+1 pipi qiqi qiqi   1 I :J R :B Se 1 I :L a R :R a GY u uiui mm  The DC-motor together with the pump replace the non-linear (modulated) flow source that had been postulated earlier.

17 Start Presentation November 15, 2012 Heat Flow I We have meanwhile understood, how the mass flow needs to be modeled. However, the transported mass always carries its own heat along. When modeling thermal phenomena, it is therefore important, to correctly represent these heat flows, which are not of a dissipative nature. S. Storage V, S q Heat flow Mass flow S. S = V q  S. = (S/V) · q

18 Start Presentation November 15, 2012 Heat Flow II The resulting heat flow can indeed be represented as a non- linear (modulated) flow source.... 010101 0 C I CCC TFI qiqi pipi p i+1 pipi qiqi qiqi C th 0... Sf0 0 0 C th S/V qiqi SiSi. SiSi. S ix. TiTi T i+1 The energy conservation law is not violated here, since entropy is not conserved.

19 Start Presentation November 15, 2012 Mass Transport Losses Fluid transports are in reality always associated with losses due to friction.... 010101 0 C I CCC TFI qiqi pipi p i+1 pipi qiqi qiqi C th 0... Sf0 0 0 C th S/V qiqi SiSi. SiSi. S ix. TiTi T i+1 S/V RS

20 Start Presentation November 15, 2012 Conclusions We have meanwhile understood that the cause of convective heat flows is to be found in the mass transport. The mass transport is captured by the wave equation, whereby forced flows (pumps, compressors) replace the inductors at the locations of flow-forcing devices. The heat flow is a consequence of the mass flow, and may be modeled using non-linear (modulated) internal flow sources. Frictional losses can be added to the model afterwards where and when needed.

Download ppt "Start Presentation November 15, 2012 Convective Mass Flows I In this lecture, we shall begin looking at the problem of convective mass flows. Irreversible."

Similar presentations

Air Conditioners. Introductory Question If you operate a window air conditioner on a table in the middle of a room, the average temperature in the room.

Air Conditioners. Introductory Question If you operate a window air conditioner on a table in the middle of a room, the average temperature in the room.
Start Presentation November 22, 2012 Convective Mass Flows II In todays lecture, we shall perform a number of thought experiments that will help us deepen.

Start Presentation November 22, 2012 Convective Mass Flows II In todays lecture, we shall perform a number of thought experiments that will help us deepen.
Dale E. Gary Wenda Cao NJIT Physics Department

Dale E. Gary Wenda Cao NJIT Physics Department
Start Presentation October 11, 2012 Thermodynamics Until now, we have ignored the thermal domain. However, it is fundamental for the understanding of physics.

Start Presentation October 11, 2012 Thermodynamics Until now, we have ignored the thermal domain. However, it is fundamental for the understanding of physics.
Integration Relation for Control Volume

Integration Relation for Control Volume
Chapter 4 Mass and Energy Analysis of Control Volumes (Open Systems)

Chapter 4 Mass and Energy Analysis of Control Volumes (Open Systems)
THERMODYNAMICS II INTRODUCTION TO NAVAL ENGINEERING.

THERMODYNAMICS II INTRODUCTION TO NAVAL ENGINEERING.
Advanced Thermodynamics Note 6 Applications of Thermodynamics to Flow Processes Lecturer: 郭修伯.

Advanced Thermodynamics Note 6 Applications of Thermodynamics to Flow Processes Lecturer: 郭修伯.
Chapter 7 Entropy (Continue).

Chapter 7 Entropy (Continue).
Example: Exercise (Pump)

Example: Exercise (Pump)
Entropy Cengel & Boles, Chapter 6 ME 152.

Entropy Cengel & Boles, Chapter 6 ME 152.
Exergy: A Measure of Work Potential Study Guide in PowerPoint

Exergy: A Measure of Work Potential Study Guide in PowerPoint
Flow of mechanically incompressible, but thermally expansible viscous fluids A. Mikelic, A. Fasano, A. Farina Montecatini, Sept. 9 - 17.

Flow of mechanically incompressible, but thermally expansible viscous fluids A. Mikelic, A. Fasano, A. Farina Montecatini, Sept
ES 202 Fluid and Thermal Systems Lecture 18: Making the Connection (1/23/2003)

ES 202 Fluid and Thermal Systems Lecture 18: Making the Connection (1/23/2003)
Chapter 7 Continued Entropy: A Measure of Disorder Study Guide in PowerPoint to accompany Thermodynamics: An Engineering Approach, 5th edition.

Chapter 7 Continued Entropy: A Measure of Disorder Study Guide in PowerPoint to accompany Thermodynamics: An Engineering Approach, 5th edition.
ES 202 Fluid and Thermal Systems Lecture 7: Mechanical Energy Balance (12/16/2002)

ES 202 Fluid and Thermal Systems Lecture 7: Mechanical Energy Balance (12/16/2002)
Entropy and the Second Law of Thermodynamics

Entropy and the Second Law of Thermodynamics
Lecture B Electrical circuits, power supplies and passive circuit elements.

Lecture B Electrical circuits, power supplies and passive circuit elements.
Instructional Design Document Steam Turbine. Applied Thermodynamics To study and understand the process of steam flow in impulse and reaction turbine.

Instructional Design Document Steam Turbine. Applied Thermodynamics To study and understand the process of steam flow in impulse and reaction turbine.
Thermodynamics I Chapter 6 Entropy Mohsin Mohd Sies Fakulti Kejuruteraan Mekanikal, Universiti Teknologi Malaysia.

Thermodynamics I Chapter 6 Entropy Mohsin Mohd Sies Fakulti Kejuruteraan Mekanikal, Universiti Teknologi Malaysia.

Similar presentations

Ads by Google