Presentation is loading. Please wait.

Presentation is loading. Please wait.

Important variables Water: Air: Conversion:

Similar presentations


Presentation on theme: "Important variables Water: Air: Conversion:"— Presentation transcript:

1 Important variables Water: Air: Conversion:
- Use ASHRAE tables I gave you: - You can fine them online (be careful, not all online converters are correct)

2 Objective Finish cooling & energy storage systems
Define Building Zones Learn about air handling and water distribution systems

3 Absorption Cycle Water is typical refrigerant
Strong vacuum - ~0.116 psi or MPa Boiling point of water? Differences from vapor compression No compressor Chemical (e.g. LiBr - hygroscopic) Absorbs water vapor turns it into a liquid Regenerated by removing water Requires heat

4 Absorption Cycle Strong vacuum Refrigerant: water Absorber: lithium bromide Replace compressor

5

6 Evaporative Cooling Wet media/water spray – direct
Raise absolute humidity, lowers temperature of conditioned air Cooling tower – indirect Cools through a heat exchanger Lowers temperature, does not affect absolute humidity Can directly cool air in cold weather

7 Evaporative Cooling

8 Convert Cooling machine (DX machine) to heat pumps
Compressor Cooling Sorption cooling Evaporative cooling DX machine Chiller Evaporative Chiller Air Cooled Condenser Water Cooled Condenser Convert Cooling machine (DX machine) to heat pumps

9 Daily distribution of cooling load

10 Thermal Storage Make ice/chilled water at times of low demand or low energy prices Store water in insulated container Can be used to reduce overall demand Water can be used as secondary water source for fire protection Ice/snow

11 Thermal Storage

12 Thermal storage

13 Ventilation Air-flow in Buildings

14 Zones In building How to define the zone in building
Based on cooling/heating load requirement Based on ventilation requirement Based on use of buildings – different apartments deferent zones

15 Air Handling Units (AHU) Control of air Systems
Provide conditioned air Heating, cooling, humidification, dehumidification Ventilation Provide fresh air, remove contaminated air

16 Air Handling Unit (AHU)
Roof top AHU Gas/Electric Heater to building Fan air from building fresh air Evaporator filter mixing AHU schematic Exhaust From room Return fan flow control dampers Supply fan Compressor and Condenser Fresh air To room Outdoor air hot water cool water

17 Air Handling Units (AHS)
Equipment For AHU: Fans Cooling and heating coils Combustion heat exchangers Filtration Dampers, controls, mixing valves Humidification: steam/spray Dehumidification: cooling coil/desiccant Noise control

18 Control of air Systems Vary temperature, constant flow
Constant temperature, vary flow Vary temperature, vary flow

19 How does a residential thermostat work?
Calculates difference between actual temperature and required temperature and adjusts furnace/AC output accordingly Measures temperature continuously and turns equipment on and off when temperature is different from set point temperature Measures temperature continuously and turns equipment on and off when temperature is outside of specified bounds Calculates difference between actual temperature and required temperature and adjusts the velocity of the fan (flow-rate) accordingly

20 Constant Temperature, Variable Volume
On-off systems Residential and small commercial Vary volume by turning system on and off

21 Constant Air Volume Single zone constant air volume
Fan always runs Vary temperature of air in response to space thermostat Single zone constant air volume with reheat Often used for precise humidity control Multizone constant air volume with reheat Good humidity control, flexible Not very efficient

22 Constant Volume – temperature control
Proportional control or Proportional Integral control Thermostat measure: ΔT = T set point – T zone air Send the signal to the valve of cooling/heating coil

23 Multizone constant air volume with reheat
55°F 62°F Require less cooling

24 Variable Air Volume Single zone VAV Multizone VAV Can also use reheat
Varies air flow based on room thermostat Multizone VAV Central chilled air supply Zone thermostats control flow to each zone Can also use reheat Still need to provide adequate air flow for ventilation and for comfort Smaller energy penalty than CAV

25 VAV terminal

26 Multizone VAV 55°F Vary the flow

27 Dual-Duct Systems Can be VAV or CAV
Two plenums with chilled air and heated air Zone thermostats control ratio Separate duct for each zone

28 Reading Assignment Tao and Janis Chapter 3 Chapter 6 (from 6.1 to 6.7)
Sections: (including ) Chapter 6 (from 6.1 to 6.7)

29 Homework Assignment 4 Table 1 Results of cooling load calculation and required amount of fresh air for ventilation Zone 1 Zone 2 Zone 3 Whole building Sensible cooling load for zone Time when the max cooling load appear 41000 Btu/h at 4 PM 45000 Btu/h at 6 PM 27000 Btu/h at 8 AM 92000 Btu/h Sensible cooling load for critical hour for whole building (6 PM) 37000 Btu/h 9000 Btu/h Latent cooling load (internal sources + infiltration) 5400 Btu/h 5200 Btu/h 16000 Btu/h Required amount of fresh air based on number of occupants 240 CFM (12 occupants) 520 CFM (26 occupants) 1000 CFM (50 occupants)

30 Homework Assignment 4 Supply air 55°F Recirculation air 76°F
Fresh air (Dallas, TX) DBT=102°F


Download ppt "Important variables Water: Air: Conversion:"

Similar presentations


Ads by Google