Condensers.

Slides:

Advertisements

Similar presentations

Analysis of heat exchangers: Use of the log mean temperature Difference LMTD Method: Q= (m cp ∆T) h = (m cp ∆T) c Q= U A F∆T lm A=N װ DL ∆ T lm = ∆T l.

Advertisements

Quiz – An organic liquid enters a in. ID horizontal steel tube, 3.5 ft long, at a rate of 5000 lb/hr. You are given that the specific.

ChemE 260 Phase Equilibrium and Thermodynamic Data Tables April 1, 2005 Dr. William Baratuci Senior Lecturer Chemical Engineering Department University.

Design Clues for STHE as Condenser P M V Subbarao Professor Mechanical Engineering Department I I T Delhi Guidance to Handle Huge Variation in Thermo-

Condensation and Boiling  Until now, we have been considering convection heat transfer in homogeneous single-phase ( HSP ) systems  Boiling and condensation,

MOLLIER DIAGRAM.

Psychrometrics.

Matter and Energy.

Chapter 4.2: Flow Across a Tube Bundle Heat Exchanger (Tube Bank)

Chapter 2: Overall Heat Transfer Coefficient

Heat transfer to fluids without phase change

Jennifer Tansey 12/15/11. Introduction / Background A common type of condenser used in steam plants is a horizontal, two- pass condenser Steam enters.

Jennifer Tansey 10/20/11. Introduction / Background A common type of condenser used in steam plants is a horizontal, two- pass condenser Steam enters.

Jennifer Tansey 11/11/11. Introduction / Background A common type of condenser used in steam plants is a horizontal, two- pass condenser Steam enters.

Jennifer Tansey 9/29/11. Introduction / Background A common type of condenser used in steam plants is a horizontal, two- pass condenser Steam enters the.

Evaporation Downstream Processing Short Course May 2007 Kevin Street Gavin Duffy.

STHE as Closed Feed water Heater

Heat Exchangers with Cross Flow past Cylinders P M V Subbarao Professor Mechanical Engineering Department I I T Delhi Another Common Industrial Application!!!

PM3125: Lectures 13 to 15 Content of Lectures 13 to 17: Evaporation:

HEAT EXCHANGERS Day 2.

Design of Condensers/Condensing Zones

Recent Advances in Condensation on Tube Banks P M V Subbarao Professor Mechanical Engineering Department I I T Delhi Reduce the Degree of Over Design!!!

Heat transfer equipments:

Prof. R. Shanthini 05 June 2012 Content of Lectures 13 to 18: Evaporation: -Factors affecting evaporation -Evaporators -Film evaporators -Single effect.

PM3125 Content of Lectures 1 to 6: Heat transfer: Source of heat

THERMAL ANALYSIS OF SHELL AND TUBE HEAT EXCHANGER

Shell and Tube Heat Exchangers

Temperature Driving Force Concentric Pipe Heat Exchangers

Flow Inside Heat Exchangers

Steam Condenser II Prof. Osama El Masry

PM3125: Lectures 10 to 12 Content of Lectures 10 to 12: Heat transfer:

Example 4: Estimate the requirements of steam and heat transfer surface, and the evaporating temperatures in each effect, for a triple effect evaporator.

The First Law of Thermodynamics

Partial Evaporation Example 1/31/2007. Shell and Tube Heat Exchanger.

STEAM TURBINE POWER CYCLES. The vast majority of electrical generating plants are variations of vapour power plants in which water is the working fluid.

Boiling Heat Transfer Source:

So Far: Conservation of Mass and Energy Pressure Drop in Pipes Flow Measurement Instruments Flow Control (Valves) Types of Pumps and Pump Sizing This Week:

Boiling and condensation

Production of ethanol From syngas Design presentation Done by: SARA BADER AL- SAFI Supervised by: Prof. M. fahim.

Design and construction We need to seek a design that Achieve the goal of the project which should be : compact effective So we need to know types of heat.

Convection: Internal Flow ( )

Equipment Design Designed by Eman A. Khajah. Outline Design of Heater. Design of Stripper.

Submitted by: Abhimanyu. C. Menon

Dr. Owen Clarkin School of Mechanical & Manufacturing Engineering Summary of Energy Topics Chapter 1: Thermodynamics / Energy Introduction Chapter 2: Systems.

Heat Transfer by Convection

Date of download: 6/9/2016 Copyright © ASME. All rights reserved. From: Condensation on a Horizontal Wire-Wrapped Tube J. Heat Transfer. 2005;127(11):

Example The internal energy of a closed system can be increased by adding heat or doing work. In the following example, 1 kg of saturated liquid water.

RIVERA, ALYSSA A. 5ChE-C. Evaporation..  Evaporation is basically a separation step which uses heat transfer to separate products presenting differences.

Chapter 12B: PROPERTY TABLES, REFRIGERATION CYCLES AND HX 1) Boiling of pure substances: water and steam tables 2) Refrigerant tables 3) Binary mixtures.

1 Chapter 5 Mass and Energy Analysis of Control Volumes.

Date of download: 10/2/2017 Copyright © ASME. All rights reserved.

Introduction to Food Engineering

Introduction to Food Engineering

Introduction to Food Engineering

Conservation of Mass and Energy

Power and Refrigeration Systems

ES 211: Thermodynamics Tutorial 5 & 6

Compound Vapour Compression Refrigeration Systems

Chapter 5 The First Law of Thermodynamics for Opened Systems

1) 1.1) 1.2) Another relation for critical flux.

Heat-transfer Equipment

Heat Exchangers Heat Exchangers.

Chapter Seven: Entropy

Example 1 The internal energy of a closed system can be increased by adding heat or doing work. In the following example, 1 kg of saturated liquid water.

Condensation and Boiling

Steam traps Applications and Recommendations

Asst. Prof. Dr. Hayder Mohammad Jaffal

12. Heat Exchangers Chemical engineering 170.

“THERMODYNAMIC AND HEAT TRANSFER”

Heat Transfer Correlations for Internal Flow

Presentation transcript:

Condensers

Introduction

Condenser configurations

Types of Condensation

Film condensation Physical properties The physical properties of the condensate for use in the following equations are evaluated at the average condensate film temperature: the mean of the condensing temperature and the tube-wall temperature.

Condensation Outside a Single Horizontal Tube

Condensation Outside a Bundle of Horizontal Tubes If the number of tubes is , then the mean heat transfer coefficient for the bundle is:

Condensation Inside and Outside Vertical Tubes

Or, we can use the following figure

Example Estimate the heat transfer coefficient for steam condensing on the outside, and on the inside, of a 25mm o.d., 21mm i.d. vertical tube 3.66m long. The steam condensate rate is 0.015 kg/s per tube, and condensation takes place at 3 bar. The steam will flow down the tube.

Collection of properties

Condensation outside the tube Calculate the tube loading Calculate the Reynolds Number of film Using figure 12.45, estimate the heat transfer coefficient

Condensation inside the tube

Example : Design a condenser for the following duty: 45,000 kg/h of mixed light hydrocarbon vapors to be condensed. The condenser to operate at 10 bar. The vapor will enter the condenser saturated at 60 C, and the condensation will be complete at 45 C. The average molecular weight of the vapors is 52. The enthalpy of the vapor is 596.5 kJ/kg and the condensate 247.0 kJ/kg. Cooling water is available at 30 C, and the temperature rise is to be limited to 10 C. Plant standards require tubes of 20mm o.d., 16.8mm i.d., 4.88m (16 ft) long, of admiralty brass. The vapors are to be totally condensed and no subcooling is required.

Solution Only the thermal design will be done. The physical properties of the mixture will be taken as the mean of those for n-propane (MW 44) and n-butane (MW 58), at the average temperature.