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Heating and Air Conditioning I

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Title: Heating and Air Conditioning I


1
Heating and Air Conditioning I
  • Principles of Heating, Ventilating and Air
    Conditioning
  • R.H. Howell, H.J. Sauer, and W.J. Coad
  • ASHRAE, 2005

basic textbook/reference material For ME 421 John
P. Renie Adjunct Professor Spring 2009
2
Chapter 5 Design Conditions
  • This chapter covers the fundamental elements that
    accompany the load calculations for sizing
    heating and cooling systems. This includes the
    estimation of the outside air quantities and the
    evaluation of the overall heat transfer
    coefficient for building components.
  • Basic components of heating and cooling loads
  • Transmission
  • Solar Radiation
  • Lights
  • Power
  • Infiltration (uncontrolled)
  • Fresh Air (controlled)
  • People
  • Appliances
  • Material in and out
  • First four terms include Q
  • Last five includes Q and mwater

3
Chapter 5 Design Conditions
  • General Considerations
  • Knowledge of thermal insulation and thermal
    behavior of materials
  • Flowing fluids carry heat and moisture
  • Heating and cooling include simultaneous transfer
    of heat and mass
  • Humidification and dehumidification depends on
    ventilation and other sources of moisture gain
    and loss.
  • Outdoor Air Load Components
  • Outdoor air flows through building dilute and
    remove indoor air contaminants significant
    portion of total space load
  • Natural infiltration in addition to intentional
    mechanical ventilation
  • Ventilation (both natural and mechanical) versus
    infiltration
  • Air leakage into and out (exfiltration) due to
    pressure difference
  • Modern building usually over pressurized
  • Modern building not desirable to have open
    windows
  • Residence building reliant on infiltration and
    natural ventilation

4
Chapter 5 Design Conditions
  • Outdoor Air Load Components
  • Small exhaust fans code (condensation?)
  • ASHRAE Standard 62 guidance on ventilation and
    indoor air quality
  • Ventilation Rate Procedure
  • Control of six pollutants
  • Outdoor air supply gt minimums (5 cfm per person
    and 0.06 cfm/ft2)
  • Indoor Air Quality Procedure
  • Nine pollutants indoor maintained below standard
    level
  • Subjective (0.5 AC/hr) local codes
  • Terminolgy
  • Air handling unit (AHU) Figure 5-2
  • Return air (ra)
  • Exhaust air (ea)
  • Recirculated air (ca)
  • Outside air (oa) not fresh outside air
    fraction Xoa or percent
  • Mixed air (ma)
  • Supply air (sa)
  • Bypass air (ba)

5
Chapter 5 Design Conditions
6
Chapter 5 Design Conditions
  • Outdoor Air Load Components.
  • Terminolgy
  • Makeup air unit (MAU) all air is outside
  • Outside air
  • Large part of the total space conditioning
    (heating, cooling, humidification, and
    dehumidification) 20 to 40
  • Sensible heating qs Q r cp Dt
  • Latent heating qL Q r hfg DW
  • Dehumidification in summer
  • Humidification in winter
  • Infiltration
  • Air leakage through cracks and interstices around
    windows and doors, and through the floors and
    walls depends on construction, building
    condition
  • Pressure difference between indoor and outdoor
    caused by wind or differences in density
    chimney or stack effect also differences in
    temperature

7
Chapter 5 Design Conditions
  • Outdoor Air Load Components.
  • Estimation of the air infiltration
  • Crack method measured leakage characteristics
    of the building components
  • Air change method (simplicity)
  • Assumption of the number of air changes per hour
    (ACH) that a space experiences
  • Q ACH x VOL/60 where VOL is gross volume of
    space
  • Table 5-1 Change Rates as Function of
    Airtightness
  • Outdoor design temperature
  • Tight/Medium/Loose
  • Figure 5-3 Building Pressure due to Wind Effects
  • Impossible to accurately predict infiltration
    from theory alone because of the many unknowns.
    However, semi-empirical expressions can be used
    to estimate infiltration rate.
  • Leakage function infiltration cause by pressure
    difference
  • Q CD A (2 Dp/r)n
  • Where CD is discharge coefficient (geometry and
    Reynolds number)
  • Dp Dps Dpw Dpp (stack, wind, building
    pressurization)

8
Chapter 5 Design Conditions
  • Outdoor Air Load Components

9
Chapter 5 Design Conditions
  • Outdoor Air Load Components

10
Chapter 5 Design Conditions
  • Outdoor Air Load Components.
  • Estimation of the air infiltration
  • Stack effect occurs when air densities are
    different on the inside and outside of the
    building density decreases with increasing
    temperature
  • Winter lower outside temperature at higher
    pressure than inside
  • Summer cooler air inside air infiltrates at
    top and flows downward
  • Neutral axis
  • Dps 0.52 pb h (1/To) (1/Ti) where pb is
    barometric pressure
  • Wind velocity effect (velocity pressure)
  • Dpw 0.5 Cp r Vw2
  • Figure 5-5 gives average pressure coefficients
    for tall buildings
  • Building pressurization depends on design and
    operation of the HVAC system.
  • Positive pressurization causes less infiltration
    from stack and wind effects
  • Looking at crack coefficient equation - Q K A
    (Dp)n
  • With A is wall area and K is leakage coefficient
  • Table 5-2 Curtain Wall Leakage Coefficients
    Figure 5-6
  • Tight (K 0.22), Average (K 0.66), and Loose
    (K 1.30)

11
Chapter 5 Design Conditions
  • Outdoor Air Load Components

12
Chapter 5 Design Conditions
  • Outdoor Air Load Components

13
Chapter 5 Design Conditions
  • Outdoor Air Load Components

14
Chapter 5 Design Conditions
  • Outdoor Air Load Components

15
Chapter 5 Design Conditions
  • Outdoor Air Load Components.
  • Estimation of the air infiltration
  • Typical infiltrations values for North America
    residential housing varies by order of
    magnitude
  • Figure 5-7 Histogram of Infiltration Values New
    Construction
  • Figure 5-8 Histogram of Infiltration Values
    Low-Income Construction
  • Commercial building envelops are thought to be
    nearly airtight.
  • At 0.30 in water 0.1 to 0.6 ACH
  • Regression equation for rate (I ACH) based on
    Dt and V
  • I K1 K2 Dt K3 V
  • Not appropriate for simulations
  • Multi-cell modeling complexity
  • Residential single zone effective leakage area
    at 0.016 inch water
  • Q AL (CS Dt CW V2)0.5
  • Cw based on shielding class (Table 5-4) wind
    coefficient Table 5-6
  • Cs values based on number of stories (Table 5-5)
    stack coefficient
  • Commercial doors different characteristics
    swinging door Figure 5-9
  • Figure 5-10 through 5-14 different styles, with
    traffic, etc.

16
Chapter 5 Design Conditions
  • Outdoor Air Load Components

17
Chapter 5 Design Conditions
  • Outdoor Air Load Components

18
Chapter 5 Design Conditions
  • Outdoor Air Load Components

19
Chapter 5 Design Conditions
  • Outdoor Air Load Components

20
Chapter 5 Design Conditions
  • Outdoor Air Load Components.
  • Ventilation Air
  • Acceptable Indoor Air Quality (IAQ) debated for
    years
  • Control of moisture, carbon dioxide, odors,
    tobacco smoke
  • Additional pollutants not generated by occupants
    Table 5-7
  • Ventilation rate procedure meet outside air
    quality standards Table 5-8
  • Ventilation effectiveness ability to remove
    internally generated pollutants
  • See Table 5-9 Minimum Ventilation Rates in
    Breathing Zone
  • Indoor air quality procedure amount of outdoor
    air ay be reduced by recirculating air which
    offending contaminates have been removed or
    converted to less objectionable forms
  • Figure 5-15
  • Nomenclature (C contaminant concentration, Fr
    reduction factor, N contaminate generation
    rate, R recirculation rate)
  • Filter placement
  • Variable air volume (VAV) systems
  • See Figure 5-16 for required outdoor air with
    recirculation and filtration.
  • See Example 5-3 Chicago fast-food cafeteria

21
Chapter 5 Design Conditions
  • Outdoor Air Load Components

22
Chapter 5 Design Conditions
  • Outdoor Air Load Components

23
Chapter 5 Design Conditions
  • Outdoor Air Load Components

24
Chapter 5 Design Conditions
  • Outdoor Air Load Components

25
Chapter 5 Design Conditions
  • Outdoor Air Load Components

26
Chapter 5 Design Conditions
  • Outdoor Air Load Components

27
Chapter 5 Design Conditions
  • Outdoor Air Load Components

28
Chapter 5 Design Conditions
  • Outdoor Air Load Components

29
Chapter 5 Design Conditions
  • Outdoor Air Load Components

30
Chapter 5 Design Conditions
  • Outdoor Air Load Components

31
Chapter 5 Design Conditions
  • Outdoor Air Load Components - Example

32
Chapter 5 Design Conditions
  • Outdoor Air Load Components - Example

33
Chapter 5 Design Conditions
  • Heat Transfer Coefficients
  • Modes of heat transfer (driven by DT)
  • Conduction transfer of heat through molecular
    motion
  • Convection enhancement of conduction through
    motion
  • Radiation electromagnetic radiation between
    surfaces at DT
  • U-Factor or R-value resistance to flow of
    energy
  • Thermal resistance of building materials (Table
    5-11)
  • Apparent thermal conductivity

34
Chapter 5 Design Conditions
  • Heat Transfer Coefficients
  • Calculation of U requires
  • Apparent thermal conductivity and thickness of
    material
  • Thermal conductance of non-homogeneous material
  • Surface conductance of surfaces
  • Conductance of air spaces
  • Surface Conductance
  • Combined effects of radiation, convection, and
    conduction
  • Surface properties (reflectivity, emissivity,
    roughness)
  • Geometry, viewing angles,
  • Flow behavior, etc.
  • Other factors
  • Workmanship
  • Air-tightness
  • Irregular areas, shading
  • Shrinkage, settling, compression,etc.

35
Chapter 5 Design Conditions
  • R-Values - materials

36
Chapter 5 Design Conditions
  • Surface Conductances and Resistances

37
Chapter 5 Design Conditions
  • Emittance Values of Surfaces and Airspaces

38
Chapter 5 Design Conditions
  • Thermal Resistances of Plane Airspaces

39
Chapter 5 Design Conditions
  • Thermal Properties of Common Building Materials
    (pgs. 123-127)

40
Chapter 5 Design Conditions
  • Determining U-factors
  • Total resistance (both conductances and air film)
    U 1/Rtot
  • Parallel heat paths
  • Add the U factors (on a percentage basis)
  • Unequal areas (pitched roof and ceiling areas)
  • Windows and doors - Tables 5-16 and 5-17

41
Chapter 5 Design Conditions
  • Determining U-factors

42
Chapter 5 Design Conditions
  • Determining U-factors fenestration products

43
Chapter 5 Design Conditions
  • Determining U-factors - Doors

44
Chapter 5 Design Conditions
  • The Overall Thermal Transmittance

45
Chapter 5 Design Conditions
  • Calculating Surface Temperatures
  • Voltage divider network due to resistances
    driving DT
  • Account for temperature effect on the resistance
    of material
  • Look at example of structure wall

46
Chapter 5 Design Conditions
  • Calculating Surface Temperatures

47
Chapter 5 Design Conditions
  • Example 5-3 Determining Uoverall

48
Chapter 5 Design Conditions
  • Example 5-5 Determining Uoverall

49
Chapter 5 Design Conditions
  • Example 5-5 Determining Uoverall

50
Chapter 5 Design Conditions
  • Example 5-5 Determining Uoverall

51
Chapter 5 Design Conditions
  • Example 5-5 Determining Uoverall
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