AIR FLOW IN DUCTS Shaharin Anwar Sulaiman

Slides:



Advertisements
Similar presentations
AIR DISTRIBUTION (Additional information. Also see Chapter 18) General The proper delivery of air for heating, cooling, or ventilation is a crucial part.
Advertisements

Fluid Mechanics.
Heating Systems Forced Air Systems.
Proper Vent Sizing 4 Natural Draft Furnaces 4 Fan Assisted Furnace 4 Common Vent Systems.
SUPPLY DUCT SYSTEMS (Additional information. Read sections 18.4, 18.5, & 18.6) General –The supply duct system conveys conditioned air from an AHU to the.
Experiment 8 : Minor Losses
Service Delivery 3 Hydraulics. Aim To ensure students can explain the principles of obtaining and delivering water.
Heating and Air Conditioning I
Nonmetallic ducts (Additional information) –Fiberglass (also see section 18.5) Made of glass wool insulating material in which the stranded fiber wool.
Objectives Finish with ducts and fans Define project topics.
Local Exhaust Hoods. 2 Introduction:  Designed to capture and remove harmful emissions from various processes prior to their escape into the workplace.
Trevor Thompson Senior Project II Vermont Technical College Spring 2011.
System Effects Presented by: Joe Brooks, AMCA International, Inc. AMCA International Technical Seminar 2009.
Pipeline Hydraulics.
ARCH-4372/6372 HVAC Distribution & Sizing HVAC Distribution Systems
Announcement Course Exam October 11 th (Tuesday) In class: 90 minutes long Examples are posted on the course website.
MECH 221 FLUID MECHANICS (Fall 06/07) Chapter 9: FLOWS IN PIPE
Closure of Kern’s Method
CBE 150A – Transport Spring Semester 2014 Friction Losses Flow through Conduits Incompressible Flow.
Pump Basics. Centrifugal Pumps From the Center of a Circle RADIAL DIRECTION To the Outside of a Circle A machine for moving fluid by accelerating the.
Kern Method of SHELL-AND-TUBE HEAT EXCHANGER Analysis
Installing & Maintaining Irrigation Systems Ms. Gripshover Landscaping Unit 15.
Basic Hydraulics Irrigation.
(material to be checked with local legislation)
Learning, our way Exercise Water pipe, Pump and Cooling Tower Selection.
AIR QUANTITY REQUIRED TO TRANSFER HEAT IN A FORCED AIR SYSTEM In all four mechanical systems considered, the transfer of heat, either by taking it out.
Water piping design.
NSTX TF Bundle & Center Stack Curing Oven Mike Viola Joe Rushinski Frank Jones April 14, 2003.
Basics Air Flow Basics -Air is invisible -Everyone assumes adequate airflow -Frequently airflow is 30%-50% low -Cooling – 400 CFM per ton -Heating.
Chapter 12: Fans and Building Air Distribution
Pumps and Lift Stations. Background Fluid Moving Equipment Fluids are moved through flow systems using pumps, fans, blowers, and compressors. Such devices.
SIZING PNEUMATIC SYSTEMS. Introduction Pneumatic systems are sized to meet output power requirements. The air distribution system is sized to carry the.
CE 3372 Water Systems Design
Example (a) What head is supplied to the turbine when Q = 8 ft3/s?
General Energy Equation. Chapter Objectives Identify the conditions under which energy losses occur in fluid flow systems. Identify the means by which.
Drafts and Duct System Sizing
Lesson 23 HEAD LOSS DEFINE the terms head loss, frictional loss, and minor losses. DETERMINE friction factors for various flow situations using the Moody.
HVACR416 - Design Air Distribution Part 2. Air Ducts Air carriers that deliver air to conditioned space. Originally hot air ducts were thin, tinned sheet.
AIR FLOW IN DUCTS Shaharin Anwar Sulaiman
Introduction to Energy Management
CE 3372 Water Systems Design
Objectives Airflow in Ducts Fluid dynamic review Duct Design.
3.4 Equal friction method This method of sizing is used for supply, exhaust and return air duct system and employs the same friction lose per foot of length.
Objectives Describe room distribution basics Select diffusers
Parametric Study of Turbine Cascades P M V Subbarao Professor Mechanical Engineering Department Identification of New design Variables.……
Objectives Finish with Duct Design Review the design procedure and explain the theoretical background Diffuser Selection Answer question related to the.
AIR CONDITIONING (COOLING) UNIT 37 AIR DISTRIBUTION AND BALANCE
Plenum Plenum design is based on Equal Static Pressure using Static Regain Most duct systems are designed to maintain Equal Friction or Equal Velocity.
Chapter 10: Flows, Pumps, and Piping Design
Lesson 1 Friction Chart Primer 1.3 Friction Chart.
Objectives Finish heat exchangers Air Distribution Systems
Part 15 Technician’s Guide & Workbook for Duct Diagnostics and Repair.
Chapter 6 technology institute of HAVC from usst INDUSTRIAL VENTILATION TUTORIAL 王丽慧.
6.5 Recommended Velocity Of Flow In Pipe And Tubing.
Maria’s Restaurant Lesson 21 Appendix C Duct Design
Chapter 16B: FANS AND SYSTEM EFFECTS
Design of Cold Water Networks
MECH 8250 – Building Systems Winter 2015
Pipe Components, Piping System.
Chapter 16B: FANS AND SYSTEM EFFECTS
Unico Installation Rules
Pumps and Lift Stations
HW4 Problem (Use TITUS Square Ceiling MCD diffuser
Find: Q gal min 1,600 1,800 2,000 2,200 Δh pipe entrance fresh water h
Objectives - Learn about fans and fan curves
Objectives Finish with Heat Exchangers
Objectives Duct Design AND Diffuser Selection.
Objectives Discuss Rotary Heat Exchangers
Objectives Air Distribution Systems Duct design HW4.
Copyright Materials This educational activity is protected by U.S. and International copyright laws. Reproduction, distribution, display, and use of.
Presentation transcript:

AIR FLOW IN DUCTS Shaharin Anwar Sulaiman Now that you can size equipment, the next task would be to design the air distribution system. Shaharin Anwar Sulaiman

Duct design objectives Occupant comfort Proper air distribution Economical heating and cooling system operation Economical duct installation

Supply duct systems Supply ducts deliver air to the spaces that are to be conditioned. The two most common supply duct systems for residences are: The trunk and branch system and The radial system

SUPPLY DUCT CONFIGURATIONS

Content Friction losses in: round ducts rectangular ducts (aspect ratio) inlet / outlet of fans fittings Duct sizing methods: Equal Friction Method Static Regain Method

FRICTION LOSSES FROM AIR FLOW IN DUCTS Like piping, for convenience pressure loss due to friction for air flow is available in a chart (Fig. 8.21). Chart is however meant for straight round duct. The chart assumes clean galvanised steel material with about 40 joints per 100 ft, with air at standard conditions.

FRICTION LOSSES FROM AIR FLOW IN DUCTS See Fig. 8.21 It’s quite similar to Fig. 8.13, 8.14, 8.15 used for piping

EQUIVALENT ROUND DUCT SIZES For rectangular duct, need to do a conversion by referring to the chart for equivalent round duct sizes.

EQUIVALENT ROUND DUCT SIZES For rectangular duct, need to do a conversion by referring to the chart for equivalent round duct sizes. Can also use ductulator.

FRICTION LOSSES FROM AIR FLOW IN DUCTS Example-1: A 10” diameter round galvanised duct 200’ long has 150 cfm of air flowing through it. What is the pressure loss due to friction? What is the air velocity in the duct? Refer to Fig. 8.21: At 150 cfm and 10 in diameter, the friction loss is 0.015 ft. w per 100 feet. Therefore for 200 ft pipe: Hf = 0.015/100’ x 200’ = 0.03 ft.w Velocity = ?

FRICTION LOSSES FROM AIR FLOW IN DUCTS Example-2: If the previous duct were to be replaced with a rectangular type, what would be the size if the maximum duct height is limited to 8” ? Refer to Fig. 8.23: Let the vertical scale at 8”, then the horizontal ones read 10.8”. Square CS cannot be obtained. Therefore size is 8” x 10.8”

ASPECT RATIO It may be thought that equivalent round duct will have the same cross-sectional area as the rectangular duct for the same friction loss. However, actually for same friction loss, rectangular duct will have greater cross-sectional area. Because of the rectangle shape that has greater ratio of surface to cross-section, the flow experiences more friction. This is related to Aspect Ratio (AR). Aspect Ratio (AR) is the ratio of the two adjacent sides - height over width or vice versa.

ASPECT RATIO The higher the aspect ratio, the worse the friction loss. As a general rule, the AR of rectangular ducts should be kept as low as possible to minimise friction losses and save energy. Higher AR also means more material for ducting. The best option is to have square duct. But that is not always possible due to limited ceiling space.

DUCT FITTINGS Like in pipes, pressure loss also occurs in duct fittings. Duct fittings could be elbow, tee, transition, and dampers. Similar to piping system, the equivalent length could be used. Another option is the use of loss coefficient method.

DUCT FITTINGS For loss coefficient method, the following equation is used: The values for loss coefficients can be found in Table 8.4 - 8.8.

Example 8.22 & 8.23: own reading DUCT FITTINGS Notice that answers are not accurately written. Hf = 0.035 in both examples.

(Static pressure regain) DUCT FITTINGS Example 8.23 also shows the SPR (Static pressure regain) SPR: When velocity decrease, due to change in ducting size, there will be an increase in the static pressure

System Effect Loss. Own reading (Sec. 8.14) PRESSURE LOSS AT FAN INLET & OUTLET System Effect Loss. Own reading (Sec. 8.14)

DUCT SYSTEM PRESSURE LOSS In piping system, the pressure loss must be calculated to properly size the pump. Likewise, in duct, the duct pressure losses must be determined to identify the proper fan capacity.

DUCT SYSTEM PRESSURE LOSS System total pressure loss the total pressure loss through the duct path that has the largest pressure losses. Fan 700cfm 300 cfm 500 cfm

DUCT SYSTEM PRESSURE LOSS In analysing duct pressure losses, total pressure loss is preferred to static pressure loss. It gives clearer picture of the total pressure available at any point in the duct. Identification of total pressure loss is quite similar to the piping system (fluid mechs); i.e. everything must be included, including the filter. Go through examples 8.25 & 8.26.