Objectives
• Discus final project
• Load calculation
Final ProjectGroup 1:
Heather SmithTommy BealesMatt Leos
Group 2:
Patrick Gorman
Kenny Greaves
Matt McCarthy
Group 3:
Sarah Johnson
Jocelyn Citty
Tobias Nilsson
Group 4:
Zaid Arzate
Brian Burcham
Justin Barrett
Group 5:
Nick Williams
Stephen Mathai
Kevin Carbonnier
Group 6:
Marcus Allen
Josh Atkins
Matt Larson
Group 7:
Stephen Fridley
Shahrukh Gaziani
Margaret Lawson
Group 8:
Marwa Zaatari
Megan Gunther
Elena Nirlo
Group 9:
Gregory Arcangeli
Andrew Hoisington
Adam Keeling
Individual projects
Neil Woodson
Wesley Cole
Sami Kolahdoozan
Gautam Salhotra
Project topics1) VAV system design
•Fresh air requirements and recirculation rate calculation
•Selection of zonal and central HVAC components based on cooling and heating load components • For zones: VAV boxes, reheaters, reheater plumbing
• For whole system: AHU and components, chiller & cooling tower, boiler, and electric power requirement
•Control description – sequence of operation
•Heat recovery system and or economizers
2) DOAS system design
•Fresh air requirement and split between air and hydronic loads (sensible and latent cooling loads)
•Selection of zonal and central HVAC components based on cooling and heating load components • For zones: fan coils and plumbing
• For whole system: AHU and components, chiller & cooling tower, boiler, and electric power requirement
•Control description – sequence of operation
•Heat recovery system and or economizers
Project topics3) Cooling systems and distribution
•Air cooled condenser vs. water cooled condenser (energy performance analysis)
•Design of plumbing systems for campus and pumping stations
•Control of centralized system
•Saving with variable speed pumps
4) Duct Design (in Revit)
•- Diffuser selection, design of local and central duct system components
•- Spacing issues and difference between round and square ducts
•- Difference between manual calculation and calculation by Revit (for a section of the duct system)
•- Balancing and fan selection
•- Life cycle analysis and optimization (fan power consumption vs. system cost)
DOAS with multi-split systems
Fresh air?
DOAS fresh air configurations
DOAS fresh air configurations
Cooling and Heating Loads (For Project)
»Zone orientation
Commercial building
Cooling and Heating Loads (For Project)
»Cooling and heating load for each zone and whole building:
»Fresh air requirement based on number of occupants:
»To provide acceptable IAQ in the building, ventilation
» system supply minimal amount of
»fresh air is in all spaces (except plenums)
»that produce 0.2 ACH.
Cooling Load Calculation
• Mostly computer based
• Handouts for manual calculation• http://www.ce.utexas.edu/prof/Novoselac/classes/ARE346N/Handouts/heatloss_table_2008.doc
• http://www.ce.utexas.edu/prof/Novoselac/classes/ARE346N/Handouts/ASHRAE_%20Gains_Calculation_Tables.doc
Heat Recovery Sensible and Enthalpy wheel
EconomizerEconomizer (fresh air volume flow rate control)
»mixing
»damper
»fresh
» air
»T & RH sensors
»recirc.
» air
»Controlled device is damper
» - Damper for the air
» - Valve for the liquids
Economizer – cooling regime
How to control the fresh air volume flow rate?
»% fresh air
»Minimum for
» ventilation
»100%
»If TOA < Tset-point → Supply more fresh air than the minimum required
»The question is how much?
»Open the damper for the fresh air
»and compare the Troom with the Tset-point .
»Open till you get the Troom = Tset-point
»If you have 100% fresh air and your
» still need cooling use cooling coil.
»What are the priorities:
» - Control the dampers and then the cooling coils or
» - Control the valves of cooling coil and then the dampers ?
»Defend by SEQUENCE OF OERATION
» the set of operation which HVAC designer provides to the automatic control engineer
Economizer – cooling regime
»Example of SEQUENCE OF OERATIONS:
»If TOA < Tset-point open the fresh air damper the maximum position
»Then, if Tindoor air < Tset-point start closing the cooling coil valve
»If cooling coil valve is closed and T indoor air < Tset-point start closing the damper
» till you get T indoor air = T set-point
»
»Other variations are possible
Desiccant wheel
»Figure 3 – A desiccant-based cooling system combined with regenerative heat exchanger, vapor compression cooling, and evaporative
humidifier (hybrid system).