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Chapter 7 Heating and Heat Management. How comfortable are you?. What temperature is comfortable? How does humidity affect comfort?. Heat. Heat Energy imparted into molecules Heat Quantity British thermal units (BTU) Measurement in the US and a few other English-speaking countries
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Chapter 7 Heating and Heat Management
How comfortable are you? • What temperature is comfortable? • How does humidity affect comfort?
Heat • Heat • Energy imparted into molecules • Heat Quantity • British thermal units (BTU) • Measurement in the US and a few other English-speaking countries • Watt: used throughout the rest of the world • Heat Quality • Temperature • Fahrenheit • This scale is the most common in both the United States and other English speaking nations • Celsius: used throughout the rest of the world
Products or Matter • Can exist in 1 of 3 energy states • Solid – lowest energy state, molecules closest together • Liquid • Gas – molecules furthest apart • Application • We can change from one state to another • This adds or removes heat energy • This heats or cools!
Heat and Temperature • Temperature • used to control heat input • controls heat energy costs
Types of Heat • Sensible heat • increases the product temperature with out bringing about change of state. • molecules vibrate faster as they absorb energy. • Measured with a thermometer. • Amount of change depends on • Thermal property • Specific heat • Weight • Latent heat • heat necessary to bring about change of state in a product (the product’s freezing or melting point). • Example: from a solid to a liquid. • Latent heat is a product critical temperature.
Heat Transfer • Definition: • Heat-energy moves from hot to cold • Varies by: • difference in temperatures • surface area • material conductivity • Ex: insulation lowers conductivity, slowing transfer • Transfer examples: • increase the heat transfer by cooking food • reduce the rate of heat transfer by slowing down the rate of heat loss from a building during winter.
Heat Transfer • 3 methods of heat transfer • Conduction • occurs within solids, or from one solid to another when the two • Requires direct contact • Thermal energy imparted to a molecule causes it to vibrate. This molecule vibrates against the second molecule and in turn the first molecule imparts energy to the second and a chain reaction develops. • Convection • this process involves the movement of heat between two bodies or surfaces • not in contact • separated by a fluid such as water, oil, air or steam • Radiation • heat that is transferred from a hot surface (body) to a cold surface (body) not in contact, by electromagnetic waves (equivalent to radio and television waves). • (in most cases all three methods occur at the same time)
Heat Transfer • Thermal Conductivity • Should be as low as possible • Measured in resistance (R-Value) • So you want a high r-value • Is more insulation better? • Considerations • Heating costs • Cooling costs • Insulation costs • Use of facility • Local weather conditions
Heat Transfer • U-Value • is the inverse of R-value • U = 1 / R • U-Value is the rate of heat flow • E-Value • Emissivity, or ability to block in windows • Ability to reflect
Insulation and Heat Transfer • Rate of building heat loss depends… • construction techniques and materials. • amount of thermal insulation. • in the past, low-cost heat resources did not usually provide economic incentives to add additional insulation. • older properties may be lacking. • currently, higher heating costs make costly insulation feasible investments. • Insulation • now universally accepted as an excellent energy-management tool and is vital in helping manage a building’s heating system.
Types of Heating Systems • By Energy Source • Gas • SNG, LPG, LNG • Oil • Coal • Steam • Electricity • Solar
Types of Heating Systems • By Process Method • Water • Hot water baseboards • Convectors • Radiant • In floors, walls, ceilings • Or, water heating forced air in a plenun Single pipe systems Double-pipe system
Types of Heating Systems • By Process Method • Steam • Radiators • Plenums heating forced air • Forced Air • Electric • Fireplaces • Gas Heaters
Managing Building Heating Systems • The costs within our control • Building construction and insulation; • Vital in designing a property • Specific to geographic location • Building temperature • Since the 1960s an average property keeps the inside temperature at 65 degrees F in the winter and 72 F in the summer.
Managing Building Heating Systems • The costs within our Control • Energy Selection • Determine future energy costs • Also consider environmental costs • There are three primary building heat fuels currently being used in most properties; • Oil, natural gas, and electricity. • Secondary building heat resources • used less frequently or in conjunction with primary fuels • steam, solar energy, LPG, and coal
Managing Building Heating Systems • Heating system selection factors: • Fuel availability • Fuel storage requirements • Heat recovery capabilities • Temperature and moisture quality • Fuel conservation efficiency • Pollution standards • System cost • Hazard potential and insurance • Availability of new systems • Employees skill requirements • Flexibility • Building code requirements • Fixed and variable system cost • usually related and must be analyzed by management when a heating system is selected.
Managing Heating Systems • Heat Control Networks • Thermostat • Most commonly used heat control network • Bimetallic or digital • Senses the temperature at its location • Compares this temperature to a specified temperature or setting • Computer heat system control • A computer controls each room’s temperature by the settings that are put in place but the management team. • Interfaces with property management system • Gaining popularity • Note: find your automatic shut-off valves.
Geothermal Heat Pump Systems http://geoheat.oit.edu/bulletin/bull28-2/art1.pdf