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Objectives. Review thermodynamics - Solve thermodynamic problems and use properties in equations, tables and diagrams. Systems: Heating. Make heat (furnace, boiler, solar, etc.) Distribute heat within building (pipes, ducts, fans, pumps)
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Objectives • Review thermodynamics - Solve thermodynamic problems and use properties in equations, tables and diagrams
Systems: Heating • Make heat (furnace, boiler, solar, etc.) • Distribute heat within building (pipes, ducts, fans, pumps) • Exchange heat with air (coils, strip heat, radiators, convectors, diffusers) • Controls (thermostat, valves, dampers)
Systems: Cooling • Absorb heat from building (evaporator or chilled water coil) • Reject heat to outside (condenser) • Refrigeration cycle components (expansion valve, compressor, concentrator, absorber, refrigerant) • Distribute cooling within building (pipes, ducts, fans, pumps) • Exchange cooling with air (coils, radiant panels, convectors, diffusers) • Controls (thermostat, valves, dampers, reheat)
Systems: Ventilation • Fresh air intake (dampers, economizer, heat exchangers, primary treatment) • Air exhaust (dampers, heat exchangers) • Distribute fresh air within building (ducts, fans) • Air treatment (filters, etc.) • Controls (thermostat, CO2 and other occupancy sensors, humidistats, valves, dampers)
Systems: Other • Auxiliary systems (i.e. venting of combustion gasses) • Condensate drainage/return • Dehumidification (desiccant, cooling coil) • Humidification (steam, ultrasonic humidifier) • Energy management systems
Drain Pain • Removes moisture condensed from air stream Cooling coil • Heat transfer from air to refrigerant • Extended surface coil Condenser Expansion valve Controls Compressor
Heating coil • Heat transfer from fluid to air Heat pump Furnace Boiler Electric resistance Controls
Blower • Overcome pressure drop of system Adds heat to air stream Makes noise Potential hazard Performs differently at different conditions (air flow and pressure drop)
Duct system (piping for hydronic systems) • Distribute conditioned air • Remove air from space Provides ventilation Makes noise Affects comfort Affects indoor air quality
Diffusers • Distribute conditioned air within room Provides ventilation Makes noise Affects comfort Affects indoor air quality
Dampers • Change airflow amounts Controls outside air fraction Affects building security
Filter • Removes pollutants • Protects equipment Imposes substantial pressure drop Requires Maintenance
Controls • Makes everything work Temperature Pressure (drop) Air velocity Volumetric flow Relative humidity Enthalpy Electrical Current Electrical cost Fault detection
Review • Basic units • Thermodynamics processes in HVAC systems
Heat Units • Heat = energy transferred because of a temperature difference • Btu = energy required to raise 1 lbm of water 1 °F • kJ • Specific heat (heat per unit mass) • Btu/(lbm∙°F), kJ/(kg∙°C) • For gasses, two relevant quantities cv and cp • Basic equation (2.10) Q = mcΔt Q = heat transfer (Btu, kJ) m = mass (kg, lbm) c = specific heat Δt = temperature difference
Sensible vs. latent heat • Sensible heat Q = mcΔt • Latent heat is associate with change of phase at constant temperature • Latent heat of vaporization, hfg • Latent heat of fusion, hfi • hfg for water (100 °C, 1 atm) = 1220 Btu/lbm • hfi for ice (0 °C, 1 atm) = 144 Btu/lbm
Work, Energy, and Power • Work is energy transferred from system to surroundings when a force acts through a distance • ft∙lbf or N∙m (note units of energy) • Power is the time rate of work performance • Btu/hr or W • Unit conversions in Handouts • 1 ton = 12,000 Btu/hr (HVAC specific)
Where does 1 ton come from? • 1 ton = 2000 lbm • Energy released when 2000 lbm of ice melts • = 2000 lbm × 144 BTU/lbm = 288 kBTU • Process is assumed to take 1 day (24 hours) • 1 ton of air conditioning = 12 kBTU/hr • Note that it is a unit of power (energy/time)
Thermodynamic Laws • First law? • Second law? • Implications for HVAC • Need a refrigeration machine (and external energy) to make energy flow from cold to hot • Literature for Thermodynamics Review: • Fundamentals of Thermal-Fluid Sciences -Yunus A. Cengel, Robert H. Turner, Yunus Cengel, Robert Turner • or any thermodynamics book
Internal Energy and Enthalpy • 1st law says energy is neither created or destroyed • So, we must be able to store energy • Internal energy (u) is all energy stored • Molecular vibration, rotation, etc. • Formal definition in statistical thermodynamics • Enthalpy • Total energy • We track this term in HVAC analysis • h = u + Pv or H=U+PV h = enthalpy (J/kg, Btu/lbm) P = Pressure (Pa, psi) v = specific volume (m3/kg, ft3/lbm)
Second law In any cyclic process the entropy will either increase or remain the same. Entropy • Not directly measurable • Mathematical construct or • Note difference between s and S • Entropy can be used as a condition for equilibrium S = entropy (J/K, BTU/°R) Q = heat (J, BTU) T = absolute temperature (K, °R)
T-s diagrams • dH = TdS + VdP (general property equation) • Area under T-s curve is change in specific energy – under what condition?
Ideal gas law • Pv = RT or PV = nRT • R is a constant for a given fluid • For perfect gasses • Δu = cvΔt • Δh = cpΔt • cp - cv= R M = molecular weight (g/mol, lbm/mol) P = pressure (Pa, psi) V = volume (m3, ft3) v = specific volume (m3/kg, ft3/lbm) T = absolute temperature (K, °R) t = temperature (C, °F) u = internal energy (J/kg, Btu, lbm) h = enthalpy (J/kg, Btu/lbm) n = number of moles (mol)
Mixtures of Perfect Gasses • m = mx my • V = Vx Vy • T = Tx Ty • P = Px Py • Assume air is an ideal gas • -70 °C to 80 °C (-100 °F to 180 °F) PxV = mx Rx∙T PyV = my Ry∙T What is ideal gas law for mixture? m = mass (g, lbm) P = pressure (Pa, psi) V = volume (m3, ft3) R = material specific gas constant T = absolute temperature (K, °R)
Mass-Weighted Averages • Quality, x, is mg/(mf + mg) • Vapor mass fraction • φ= v or h or s in expressions below • φ = φf + x φfg • φ = (1- x) φf + x φg s = entropy (J/K/kg, BTU/°R/lbm) m = mass (g, lbm) h = enthalpy (J/kg, Btu/lbm) v = specific volume (m3/kg) Subscripts f and g refer to saturated liquid and vapor states and fg is the difference between the two
Properties of water • Water, water vapor (steam), ice • Properties of water and steam (pg 675 – 685) • Alternative - ASHRAE Fundamentals ch. 6