VAV DESIGN FOR IMPROVED INDOOR AIR QUALITY. “Air conditioning is the control of the humidity of air by either increasing or decreasing its moisture content.

Slides:



Advertisements
Similar presentations
Chapter 3. HVAC Delivery Systems
Advertisements

AIR DISTRIBUTION (Additional information. Also see Chapter 18) General The proper delivery of air for heating, cooling, or ventilation is a crucial part.
Environmental Controls I/IG Lecture 14 Mechanical System Space Requirements Mechanical System Exchange Loops HVAC Systems Lecture 14 Mechanical System.
100% Outside Air and Dehumidification Management
TYPES OF MECHANICAL SYSTEMS
HVAC 101 The Basics of Heating, Ventilation and Air Conditioning
The Role of Controls for Indoor Air Quality Kent W. Peterson, PE, Fellow ASHRAE P2S Engineering, Inc. Mid Columbia ASHRAE Chapter.
Components of HVAC System
Heating and Air Conditioning I
Introduction Enthalpy Wheel
HVAC Equipment Supplement. AIR-HANDLING UNIT (AHU) AHU DAMPERS COORDINATED FOR AIR- SIDE ECONOMIZER OPERATION.
Gas – Vapor Mixtures & Air – Conditioning
1 Meeting ASHRAE Fundamentals, Standard 55 & 62.1 with Chilled Beams Displacement Ventilation.
Industrial Ventilation - A major control measure Dr. AA, UTM.
AIR DISTRIBUTION & LOCALIZED EXHAUST INTRODUCTION AIR DISTRIBUTION LOCALIZED EXHAUST SAMPLE QUESTIONS.
HVAC Systems Overview HVAC Overview - # 1 Tom Lawrence
Announcement Course Exam October 6 th (Thursday) In class: 90 minutes long Examples are posted on the course website.
Active beams versus VAV with Reheat Analysis of May 2013 ASHRAE Journal article Ken Loudermilk Vice President, Technology & Developement.
Objectives Finish with Multizone Systems
Lecture Objectives: Model processes in AHU –Use eQUEST predefined models –Use detail modeling Define your topics for your final project.
AIR CONDITIONING SYSTEMS 1. All Air Systems An all-Air System is defined as a system providing complete sensible and latent cooling capacity in the cold.
Refrigeration and Heat Pump Systems Refrigeration systems: To cool a refrigerated space or to maintain the temperature of a space below that of the surroundings.
Evaporators For Air Conditioning
PSU Building Thermal and Mechanical Systems Laboratory Environment A/E Kurt M. Shank, M.S. & Stanley A. Mumma, Ph.D., P.E. College of Engineering Department.
Lecture Objectives: Model HVAC Systems –HW3 Asignemnet Learn about eQUEST software –How to conduct parametric analysis of building envelope.
Lecture Objectives: Model processes in AHU –Use eQUEST predefined models –Use detail modeling Define your topics for your final project.
Conditioning of Moist Air
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.
Important variables Water: Air: Conversion:
Announcements Midterm Project Prepare groups of 3 to 4 students You can submit the list at the end of next class Midterm Exam 03/09/10 - In class Exam:
Lecture Objectives: Finish with HVAC Systems Discuss Final Project.
Chapter 11: Space Air Diffusion Conditioned air is normally supplied to air outlets at velocities much higher than would be acceptable in the occupied.
A Trane Air Conditioning Clinic Psychrometry Air Conditioning Clinic TRG-TRC001-EN © American Standard Inc
World Health Organization
HEATING AND COOLING SYSTEMS
Introduction to Energy Management. Week/Lesson 7 HVAC System Types.
Announcement Course Exam November 3rd In class: 90 minutes long Examples will be posted on the course website.
Introduction to Energy Management. Week/Lesson 13 Control Strategies for Occupant Comfort.
Lecture Objectives: Discuss the exam problems Answer question about HW 3 and Final Project Assignments Building-System-Plant connection –HVAC Systems.
Final Project Format and Deliverables Examples
Final Project I need your proposal about the final project! It should include –Title –Group members –Objective –Short description –Methodology –Expected.
A New (Rational) Way To Condition Air (and Save Energy) AEE, Philadelphia February 18 th 2016 Andrew Mongar, President, AirGreen LLC.
HCB 3-Chap 19B: All-Air_Multizone_Reddy1 Chapter 19B: ALL-AIR SYSTEMS FOR MULTIPLE SPACES Agami Reddy (July 2016) 1)CAV terminal reheat 2)CAV multizone.
Space Air Diffusion. Fundamentals  Objectives – thermal comfort and indoor air quality – even space air conditions – acceptable air cleanliness – acceptable.
HCB 3-Chap 19A: All-Air Systems_Single Zone 1 Chapter 19A: ALL-AIR SYSTEMS: SINGLE ZONE AND SINGLE DUCT Agami Reddy (July 2016) 1)Introduction and common.
Design & Analysis of Psychrometric Processes Various ways of Generating A Comfort… BY P M V Subbarao Associate Professor Mechanical Engineering Department.
Maria’s Restaurant Chapter 2 Section 9
Lecture Objectives: Discuss HW3 parts d) & e) Learn about HVAC systems
Objectives Finish analysis of most common HVAC Systems
Thermal mass dynamics 1.00 Heat absorption
HVAC Basics Arkan Arzesh HVAC – Heating, Ventilation, Air-conditioning.
Lecture Objectives: Answer questions related to HW 4
Lecture Objectives: Discuss HW3 parts d) & e) Learn about HVAC systems
Lecture Objectives: Answer questions related to HW 4
CHAPTER 3 VENTILATION.
Roof Top Unit Overview (MAGNUM)
HCB 3-Chap 19A: All-Air Systems_Single Zone
Psychrometry & Air-conditioning
VAV DESIGN FOR IMPROVED INDOOR AIR QUALITY
Course Name: Air-conditioning: Introduction Prof. A. D. Kale
Air Conditioning System-1
Lecture Objectives: Discuss HW4 parts
FBE03: Building Construction & Science
Psychrometric Properties of Moist Air
Follow-ups from Classes 8 and 9
Announcements Exam 1 Next Class (Thursday, March 14th):
Objective Revie the Cooling Cycle Learn about air distribution systems
Maria’s Restaurant Chapter 2 Section 9
Presentation transcript:

VAV DESIGN FOR IMPROVED INDOOR AIR QUALITY

“Air conditioning is the control of the humidity of air by either increasing or decreasing its moisture content. Added to the control of humidity is the control of temperature by either heating or cooling the air, the purification of the air by washing or filtering the air, and the control of air motion and ventilation.” Willis H. Carrier

1.COMPLETE AND PERFECT MIXING OCCURS BETWEEN ALL OF THE ROOM AIR AND THE SUPPLY AIR 2.THE RETURN AIR IS LEAVING THE ROOM AT THE TEMPERATURE OF THE ROOM 3.THE INTRODUCTION OF THE SUPPLY AIR GENERATES AN ACCEPTABLE AMBIENT AIR VELOCITY IN THE ROOM 4.EITHER THE FLOW RATE (CFM) OR THE DT OR SOME COMBINATION OF BOTH CAN BE VARIED TO SPAN THE ENTIRE RANGE OF CAPACITY REQUIREMENTS 5. ADEQUATE VENTILATION AIR MUST BE CIRCULATED THROUGH THE SPACE AT ALL TIMES TO REMOVE THE CONTAMINENTS

q = CFM (1.08) (t r - t s )

HEAT-COOL-OFF DUAL STREAM REHEAT

DUAL STREAM q s = CFM (1.08) (t r - t s ) CONSTANT CFM, VARIABLE DT EXAMPLES: DOUBLE DUCT MULTIZONE

TERMINAL REHEAT q s = CFM (1.08) (t r - t s ) CONSTANT CFM, VARIABLE DT

VARIABLE AIR VOLUME (VAV) q s = CFM (1.08) (t r - t s ) VARIABLE CFM, CONSTANT DT

Poor mixing of supply air Inadequate ambient air circulation Dumping Reduced ventilation rates as load decreases

The dehumidification of the outdoor ventilation air and the space can be separated from the space temperature control The ventilation supply need not be integrated with the space temperature control The Economizer System is an option

RULES 1.The building envelope must be well defined and must be secure from any opportunity for mass air flow at conditions different from the indoors and must prevent migration of water vapor due to vapor pressure difference 2.The envelope itself must prevent vapor migration by use of continuous vapor barriers properly located 3.The point at which outdoor air is introduced into the space must be well defined 4.No air should be introduced into the space at moisture conditions different from those desired in the space

1.The conditioned makeup or ventilation air can be supplied to and distributed to the space in a separate duct and distribution system, or 2.The makeup air can be introduced into the return side of the recirculating units 3.There could be a single makeup air unit for a building with multiple recirculating units, or 4.There could be a makeup air unit for each recirculating unit

Cost Load dynamics Occupancy patterns Ratio of Outdoor Air to Recirculated Air

1.In warm humid climates the age-old problem of poor part-load humidity control in the spaces was solved, and 2.The major sources of indoor air quality problems are eliminated. These are a)Uncontrolled microbial growth b)Poor air circulation and mixing c)Inadequate ventilation air quantities

DESIGN GUIDELINES 1.UNDERSTAND THE LOAD AND DESIGN THE SYSTEM TO SERVE THE ANTICIPATED LOAD PLATEAUS 2.CONTROL THE BUILDING AT ALL TIMES 3.PROVIDE A SEPARATE MINIMUM VENTILATION AIR CONDITIONING SYSTEM OR UNIT (PARTICULARLY WITH DIRECT EXPANSION)

4.USE THE SIMPLEST BUT HIGHEST QUALITY VAV TERMINAL POSSIBLE 5.USE FAN POWERED TERMINALS SPARINGLY 6.DESIGN AN AIR DISTRIBUTION SYSTEM THAT WILL PROVIDE EFFECTIVE MIXING WITHOUT DUMPING, DOWN TO THE MINIMUM COOLING LOAD THE SYSTEM WILL EVER SEE ON AN OCCUPIED CYCLE, OR THE MINIMUM DICTATED BY THE EFFECTIVE PERFORMANCE

7.BELOW THE MINIMUM PERFORMANCE QUANTITY, IF THE LOAD CONTINUES TO DROP, REHEAT IS NECESSARY 8.RESET THE COLD DECK IF THIS CAN BE DONE WITH OUT ADDING TOO MUCH COMPLEXITY 9.DESIGN THE AIR HANDLING SYSTEM FOR THE LOWEST TOTAL PRESSSURE THAT IS ECONOMICALLY FEASIBLE (TRY TO HOLD THE UPPER LIMIT AT 4” w.c.)

10.DON’T DEPEND ON DIRECT DIGITAL CONTROL TO SOLVE PROBLEMS THAT THE DESIGNER DOESN’T UNDERSTAND