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|a (NhCcYBP)ebc30172485
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|a 9875231
|b IEEE
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|c NhCcYBP
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|a TJ163.2
|b .W55 2022
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|a 621.042
|2 23/eng/20220919
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|a Williams, Albert,
|e author
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| 245 |
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|a Industrial energy systems handbook /
|c Albert Williams.
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| 264 |
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1 |
|a [United States] :
|b River Publishers,
|c [2022]
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| 264 |
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4 |
|c ©2022
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|a 1 online resource.
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|a text
|b txt
|2 rdacontent
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|a computer
|b c
|2 rdamedia
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|a online resource
|b cr
|2 rdacarrier
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|a River Publishers series in energy engineering and systems
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| 505 |
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|a Machine generated contents note:
|g ch. 1
|t Global Energy Situation on Climate Change /
|r Albert Williams --
|g 1.1.
|t Negative Impacts and Forecasts of Climate Change --
|g 1.1.1.
|t Sea levels --
|g 1.1.2.
|t Ocean currents --
|g 1.1.3.
|t Coral reefs --
|g 1.1.4.
|t Ocean acidity --
|g 1.1.5.
|t Wildlife --
|g 1.1.6.
|t Hurricanes --
|g 1.1.7.
|t Floods --
|g 1.1.8.
|t Fires --
|g 1.1.9.
|t Forests --
|g 1.1.10.
|t Droughts --
|g 1.1.11.
|t Human health --
|g 1.1.12.
|t Social cost --
|g 1.2.
|t Positive Global Trends to meet the Goals of the Paris Agreement --
|g 1.2.1.
|t Coal --
|g 1.2.2.
|t Wind --
|g 1.2.3.
|t Solar --
|g 1.2.4.
|t Employment --
|g 1.2.5.
|t Industrial energy efficiency --
|g 1.3.
|t International Protocols and Conventions --
|g 1.3.1.
|t Paris agreement --
|g 1.3.2.
|t Kyoto protocol --
|g 1.3.3.
|t Bessel convention --
|g 1.3.4.
|t Montreal protocol --
|g 1.3.5.
|t Stockholm convention --
|g 1.4.
|t Resources for this Chapter --
|g ch. 2
|t Fundamental Principles of Energy /
|r Louis Lagrange --
|g 2.1.
|t Forms of Energy --
|g 2.1.1.
|t Definition of energy --
|g 2.1.2.
|t Different forms of energy and energy flow important to energy audits --
|g 2.2.
|t Definition of Energy Efficiency --
|g 2.3.
|t Definition of Energy Density --
|g 2.4.
|t Units of Energy --
|g 2.4.1.
|t Calorie --
|g 2.4.2.
|t Joule --
|g 2.4.3.
|t Pascal --
|g 2.4.4.
|t Ampere --
|g 2.4.5.
|t Ampere-hour --
|g 2.4.6.
|t Volt-Ampere --
|g 2.4.7.
|t Kilo Volt-Ampere reactive --
|g 2.4.8.
|t Watt --
|g 2.4.9.
|t Watt-hour --
|g 2.4.10.
|t Kilowatt and gigaWatt --
|g ch. 3
|t Energy Conversion and Efficiency /
|r Louis Lagrange --
|g 3.1.
|t Energy Conversion, Electricity and Energy Efficiency --
|g 3.1.1.
|t Total energy, useful and not useful energy --
|g 3.2.
|t Four Thermodynamic Laws --
|g 3.2.1.
|t Definition and interpretation of thermodynamic law nr 0 --
|g 3.2.2.
|t Definition and interpretation of thermodynamic law nr 1 --
|g 3.2.3.
|t Definition and interpretation of thermodynamic law nr 2 --
|g 3.2.4.
|t Definition and interpretation of thermodynamic law nr 3 --
|g 3.3.
|t Energy Performance Criteria --
|g 3.4.
|t Calculation of Energy Efficiency Performance --
|g 3.4.1.
|t High level benchmarking metrics --
|g 3.4.2.
|t Energy Use Index --
|g 3.4.3.
|t Energy Cost Index --
|g 3.4.4.
|t Productivity metrics --
|g 3.4.5.
|t Energy efficiency rating, seasonal and integrated --
|g 3.4.6.
|t System performance metrics --
|g 3.4.7.
|t Typical System Performance Indexes --
|g 3.5.
|t Calculation of Point of Use (PoU) costs --
|g 3.5.1.
|t Energy conservation and energy conversion (energy flow) --
|g 3.5.2.
|t Heat flow and heat loss --
|g 3.5.3.
|t Mass-and energy-balance --
|g 3.5.4.
|t Energy demand --
|g ch. 4
|t Fundamentals of Electrical Energy /
|r Louis Lagrange --
|g 4.1.
|t Electrical Power and Electrical Power Quality --
|g 4.2.
|t Electrical Voltage --
|g 4.3.
|t Electrical Current --
|g 4.4.
|t Electrical Power --
|g 4.5.
|t Demand --
|g 4.6.
|t Types of Current Flow --
|g 4.7.
|t Direct Current --
|g 4.8.
|t Batteries --
|g 4.9.
|t Alternating Current --
|g 4.10.
|t Different Types of Loads --
|g 4.10.1.
|t Electrical circuitry --
|g 4.10.2.
|t Resistive loads --
|g 4.10.3.
|t Inductive loads --
|g 4.10.4.
|t Capacitive loads --
|g 4.11.
|t Electrical Power Factor --
|g 4.11.1.
|t Lower utility fees --
|g 4.11.2.
|t Power factor penalty is eliminated --
|g 4.11.3.
|t Increase voltage levels in the electric system and distribution system --
|g 4.11.4.
|t Power factor correction in linear loads --
|g 4.11.5.
|t Power factor correction in non-linear loads --
|g 4.11.6.
|t Passive power factor correction (PFC) --
|g 4.11.7.
|t Active power factor correction --
|g 4.11.8.
|t Dynamic power factor correction --
|g 4.12.
|t Demand Management --
|g 4.13.
|t Load Factor --
|g 4.14.
|t Load Shifting --
|g 4.14.1.
|t Demand response --
|g 4.14.2.
|t Dynamic demand --
|g 4.15.
|t Load Shedding --
|g 4.16.
|t Total Harmonic Distortion (THD) --
|g 4.16.1.
|t THD voltage --
|g 4.16.2.
|t Harmonic voltage distortions --
|g 4.16.3.
|t Harmonic current distortion --
|g 4.17.
|t Problems with Harmonics --
|g 4.18.
|t Measuring Electrical Energy Consumption --
|g 4.18.1.
|t Calculating power, energy and power factor in alternating current circuits --
|g 4.18.2.
|t Calculate power, voltage, current and power factor in AC circuits --
|g 4.18.3.
|t Voltage --
|g 4.18.4.
|t Current --
|g 4.18.5.
|t Power --
|g 4.19.
|t Methods to Correct the Power Factor --
|g 4.20.
|t Calculating Energy Efficiency for Electrical Equipment --
|g 4.21.
|t Uninterruptible Power Supply --
|g ch. 5
|t Fundamentals of Thermal Energy /
|r Albert Williams --
|g 5.1.
|t Types of Thermal Energy: Sensible and Latent --
|g 5.2.
|t Concept of Useful Thermal Energy --
|g 5.3.
|t Temperature --
|g 5.4.
|t Pressure --
|g 5.5.
|t Phase Changes --
|g 5.5.1.
|t Evaporation --
|g 5.5.2.
|t Condensation --
|g 5.5.3.
|t Steam --
|g 5.5.4.
|t Moist air and humidity --
|g 5.6.
|t Psychrometric Charts --
|g 5.6.1.
|t Air temperature --
|g 5.6.2.
|t Relative humidity --
|g 5.6.3.
|t Mean radiant temperature --
|g 5.6.4.
|t Air flow movement --
|g 5.6.5.
|t Infiltration loads in buildings --
|g 5.7.
|t Calculating Thermal Energy --
|g 5.7.1.
|t Heat loss calculations --
|g 5.8.
|t Energy Efficiency Measures in Thermal Processes --
|g ch. 6
|t Energy Management Systems and Industrial Energy Audits /
|r Yolanda de Lange --
|g 6.1.
|t Energy Management Systems (EnMS) --
|g 6.1.1.
|t Overview --
|g 6.1.2.
|t Energy performance indicators --
|g 6.1.3.
|t Calculation of energy efficiency performance --
|g 6.1.4.
|t High level benchmarking metrics --
|g 6.2.
|t Industrial Energy Audits --
|g 6.2.1.
|t types of energy audits --
|g 6.2.2.
|t energy audit process --
|g ch. 7
|t Instrumentation and Control /
|r Albert Williams --
|g 7.1.
|t Need for Automated Control --
|g 7.2.
|t Control Components --
|g 7.2.1.
|t Switches --
|g 7.2.2.
|t Sensors --
|g 7.2.3.
|t Transducers --
|g 7.2.4.
|t Controllers --
|g 7.2.5.
|t Control loops --
|g 7.2.6.
|t Control devices --
|g 7.3.
|t Control Modes --
|g 7.3.1.
|t On/Off control --
|g 7.3.2.
|t Floating control --
|g 7.3.3.
|t Proportional only control (P) --
|g 7.3.4.
|t Proportional-plus-integral control (PI) --
|g 7.3.5.
|t Proportional-integral-derivative control (PID) --
|g 7.4.
|t Sensor Types --
|g 7.4.1.
|t Thermostats --
|g 7.4.2.
|t Electric meter --
|g 7.4.3.
|t Smoke sensors/detectors --
|g 7.4.4.
|t Light sensors --
|g 7.4.5.
|t Occupancy sensors --
|g 7.4.6.
|t Carbon dioxide sensors --
|g 7.4.7.
|t Carbon monoxide sensors --
|g 7.5.
|t Principles of Efficiency with Control and Control Applications --
|g 7.5.1.
|t Efficiency through control --
|g 7.5.2.
|t Efficiency through control applications --
|g ch. 8
|t Energy Investigation Support Tools /
|r Albert Williams --
|g 8.1.
|t Measurement of Power --
|g 8.2.
|t Measurement of Temperature --
|g 8.3.
|t Measurement of Pressure --
|g 8.4.
|t Measurement of Humidity --
|g 8.5.
|t Measurement of Heat Capacity and Heat Storage --
|g 8.6.
|t Combustion Measurement --
|g 8.7.
|t Measurements of Air Velocity --
|g 8.8.
|t Measurements of Flow --
|g 8.9.
|t Measurements of Compressed Air Systems --
|g 8.9.1.
|t Compressed air flow measurements --
|g 8.9.2.
|t Leak detection in compressed air system --
|g ch. 9
|t Fuels, Furnaces, and Fired Equipment /
|r Albert Williams --
|g 9.1.
|t Fuel Fired Systems --
|g 9.2.
|t Fuels --
|g 9.2.1.
|t Properties of solid fuels --
|g 9.2.2.
|t Properties of liquid fuels (Oil) --
|g 9.2.1.
|t Properties of gaseous fuels --
|g 9.3.
|t Combustion --
|g 9.3.1.
|t Combustion of carbon --
|g 9.3.2.
|t Combustion air requirement --
|g 9.4.
|t Optimizing Combustion Conditions --
|g 9.5.
|t Fuel Fired Equipment and Applications --
|g 9.5.1.
|t Furnaces --
|g 9.5.2.
|t Dryers --
|g 9.5.3.
|t Kilns --
|g 9.6.
|t Flue Gas and Other Losses in Process Furnaces, Dryers and Kilns --
|g 9.7.
|t Burners --
|g 9.7.1.
|t Liquid fuel combustion --
|g 9.7.2.
|t Pressure jet burners --
|g 9.7.3.
|t Rotary cup burners --
|g 9.7.4.
|t Air blast burners --
|g 9.7.5.
|t Common problems in burners --
|g 9.8.
|t Thermal Efficiencies --
|g 9.9.
|t Air Pollution Control - Process and Equipment --
|g 9.9.1.
|t Greenhouse gas effect --
|g 9.9.2.
|t Acid rain --
|g 9.9.3.
|t Ground level ozone --
|g 9.9.4.
|t Reduction of pollutant emissions from combustion process --
|g 9.9.5.
|t Energy efficiency improvements --
|g 9.9.6.
|t Refinement to the combustion process --
|g 9.9.7.
|t Flue gas treatment --
|g 9.9.8.
|t Fuel switching --
|g 9.10.
|t Energy Efficiency Measures --
|g 9.10.1.
|t Maintain proper burner adjustment --
|g 9.10.2.
|t Check excess air and combustibles in the flue gas --
|g 9.10.3.
|t Keep heat exchange surfaces clean --
|g 9.10.4.
|t Replace/Repair missing and damaged insulation --
|g 9.10.5.
|t Check furnace pressure regularly --
|g 9.10.6.
|t Schedule production to operate furnaces at or near maximum output --
|g 9.10.7.
|t Replace damaged furnace doors or covers --
|g 9.10.8.
|t Install adequate monitoring instrumentation --
|g 9.10.9.
|t Recover heat from equipment cooling water --
|g 9.10.10.
|t Install a heat exchanger in the flue gas outlet --
|g ch. 10
|t Heat Exchange Systems /
|r Albert Williams --
|g 10.1.
|t Concepts of Conduction, Convection and Radiation --
|g 10.1.1.
|t Conduction --
|g 10.1.2.
|t Convection --
|g 10.1.3.
|t Thermal radiation --
|g 10.2.
|t Specific Heat Capacity --
|g 10.3.
|t Insulation --
|g 10.3.1.
|t Heat loss through a wall --
|g 10.3.2.
|t Heat loss from a pipe --
|g 10.3.3.
|t Heat loss from an industrial freezer --
|g 10.3.4.
|t Insulating materials --
|g 10.3.5.
|t Protective coverings and finishes --
|g 10.3.6.
|t Accessories --
|g 10.3.7.
|t Insulation energy efficiency measures --
|g 10.3.8.
|t Vapor loss from open processing tanks --
|g 10.4.
|t Heat Recovery with Heat Exchangers --
|g 10.4.1.
|t Shell and tube --
|g 10.4.2.
|t Plate and frame --
|g 10.4.3.
|t Heat wheel --
|g 10.4.4.
|t Heat pipes --
|g 10.4.5.
|t Run around system --
|g 10.4.6.
|t Plate or Baffle type heat exchanger --
|g 10.4.7.
|t Heat pumps --
|g 10.4.8.
|t Waste heat boilers --
|g 10.4.9.
|t Recuperators --
|g 10.4.10.
|t Heat recovery ventilation systems --
|g 10.4.11.
|t Mechanical and natural ventilation --
|g ch. 11
|t Steam Systems /
|r Albert Williams --
|g 11.1.
|t Generation --
|g 11.1.1.
|t Steam --
|g 11.1.2.
|t Sensible heat and latent heat --
|g 11.1.3.
|t Steam quality --
|g 11.1.4.
|t Superheated steam --
|g 11.1.5.
|t Example of the effects of increasing surface area --
|g 11.1.6.
|t Boiler types --
|g 11.1.7.
|t Combustion losses --
|g 11.1.8.
|t Blowdown losses --
|
| 505 |
0 |
0 |
|a Contents note continued:
|g 11.1.9.
|t Feedwater treatment --
|g 11.1.10.
|t Condensate tanks --
|g 11.1.11.
|t Flash tanks --
|g 11.1.12.
|t Flash steam heat recovery --
|g 11.2.
|t Distribution --
|g 11.2.1.
|t Condensate return --
|g 11.2.2.
|t Steam leaks --
|g 11.2.3.
|t Insulation --
|g 11.2.4.
|t Steam pressure --
|g 11.2.5.
|t Steam pipes --
|g 11.2.6.
|t Heat transfer from steam --
|g 11.2.7.
|t Steam traps --
|g 11.2.8.
|t Routine maintenance of traps --
|g 11.3.
|t End-Use --
|g 11.4.
|t Energy Efficiency Measures --
|g 11.4.1.
|t Boiler house -- Operation opportunities --
|g 11.4.2.
|t Boiler house -- Maintenance opportunities --
|g 11.4.3.
|t Boiler house -- Retrofit opportunities --
|g 11.4.4.
|t Steam distribution system opportunities --
|g 11.4.5.
|t End-use equipment opportunities --
|g ch. 12
|t Motors and Drives /
|r Eustace Njeru --
|g 12.1.
|t Electric Motor Types --
|g 12.1.1.
|t Direct-Current motors (DC) --
|g 12.1.2.
|t Synchronous motors --
|g 12.1.3.
|t Induction motors --
|g 12.2.
|t Motor Nameplate Data --
|g 12.2.1.
|t Kworhp --
|g 12.2.2.
|t Service factor --
|g 12.2.3.
|t Efficiency --
|g 12.2.4.
|t Amps --
|g 12.2.5.
|t Volts --
|g 12.2.6.
|t Slip --
|g 12.2.7.
|t RPM motor speed --
|g 12.2.8.
|t Motor pole --
|g 12.2.9.
|t Hertz --
|g 12.2.10.
|t Duty --
|g 12.2.11.
|t Bearings --
|g 12.2.12.
|t Temperature --
|g 12.3.
|t Torque --
|g 12.4.
|t Power --
|g 12.5.
|t Motor Losses --
|g 12.5.1.
|t Core loss --
|g 12.5.2.
|t Stator and rotor resistance (I2R) Loss --
|g 12.5.3.
|t Friction and windage loss --
|g 12.5.4.
|t Stray load loss --
|g 12.6.
|t Motor Efficiency --
|g 12.6.1.
|t Energy efficient motors --
|g 12.7.
|t Motor Loads --
|g 12.8.
|t Motor Rewinding --
|g 12.9.
|t Motor Protection --
|g 12.9.1.
|t Overcurrent protection --
|g 12.9.2.
|t Overload protection --
|g 12.9.3.
|t Other protection --
|g 12.10.
|t Electric Motor Standards Compared to Actual Measurement --
|g 12.11.
|t Energy Efficiency Measures --
|g 12.11.1.
|t Motor load scheduling --
|g 12.11.2.
|t Motor drive maintenance and alignment --
|g 12.11.3.
|t Motor power factor correction --
|g 12.11.4.
|t Balance motor phase voltages --
|g 12.11.5.
|t Energy efficient motors --
|g 12.11.6.
|t Cost implications of motor replacement versus maintenance --
|g ch. 13
|t Fan Systems /
|r Albert Williams --
|g 13.1.
|t Fan Types --
|g 13.1.1.
|t Centrifugal fans --
|g 13.1.2.
|t Axial fans --
|g 13.2.
|t Fan Performance --
|g 13.2.1.
|t Airflow measurement --
|g 13.2.2.
|t Pressure measurements --
|g 13.2.3.
|t Fan power requirement --
|g 13.2.4.
|t Fan performance curves --
|g 13.2.5.
|t Density consideration --
|g 13.2.6.
|t Fan laws --
|g 13.3.
|t Flow Control --
|g 13.3.1.
|t System effect factors --
|g 13.4.
|t Energy Efficiency Opportunities --
|g 13.4.1.
|t Maintenance opportunities --
|g 13.4.2.
|t Low cost opportunities --
|g 13.4.3.
|t Retrofit opportunities --
|g ch. 14
|t Pump Systems /
|r Albert Williams --
|g 14.1.
|t Pump Types --
|g 14.1.1.
|t Centrifugal pumps --
|g 14.1.2.
|t Positive displacement pumps --
|g 14.2.
|t Pump System Fluid Relationships --
|g 14.2.1.
|t Friction head --
|g 14.2.2.
|t Velocity head --
|g 14.2.3.
|t Static head --
|g 14.3.
|t Pump Performance Characteristics --
|g 14.3.1.
|t Pump and system performance curves --
|g 14.3.2.
|t Pump power requirements --
|g 14.3.3.
|t Multiple pump systems --
|g 14.3.4.
|t Cavitation and NPSH --
|g 14.4.
|t Pump Maintenance --
|g 14.4.1.
|t Packing glands --
|g 14.4.2.
|t Mechanical seals --
|g 14.5.
|t Energy Efficiency Measures --
|g 14.5.1.
|t Housekeeping - Maintenance --
|g 14.5.2.
|t Retrofit opportunities --
|g ch. 15
|t Compressed Air Systems /
|r Albert Williams --
|g 15.1.
|t Supply Side --
|g 15.1.1.
|t Specific power for various compressor types --
|g 15.1.2.
|t Positive displacement compressors --
|g 15.1.3.
|t Dynamic compressors --
|g 15.1.4.
|t Compressor lubrication --
|g 15.1.5.
|t Inlet air temperature --
|g 15.1.6.
|t Inlet air pressure --
|g 15.1.7.
|t Compressor control --
|g 15.1.8.
|t Individual compressor control --
|g 15.1.9.
|t Multiple compressor control --
|g 15.1.10.
|t Sizing --
|g 15.1.11.
|t Compressor scheduling --
|g 15.1.12.
|t Heat recovery --
|g 15.1.13.
|t Maintenance --
|g 15.1.14.
|t Compressor package --
|g 15.1.15.
|t Supply side energy efficiency measures --
|g 15.2.
|t Distribution and Treatment --
|g 15.2.1.
|t Distribution main --
|g 15.2.2.
|t Condensate drain traps --
|g 15.2.3.
|t Air quality --
|g 15.2.4.
|t Condensate --
|g 15.2.5.
|t Distribution piping --
|g 15.2.6.
|t Desiccant dryers --
|g 15.2.7.
|t Heat of compression dryers --
|g 15.2.8.
|t Deliquescent (Absorption) dryers --
|g 15.2.9.
|t Refrigeration dryers --
|g 15.2.10.
|t Dryer installation --
|g 15.2.11.
|t Dryer sizing --
|g 15.2.12.
|t Filters --
|g 15.2.13.
|t Storage --
|g 15.2.14.
|t System isolation --
|g 15.2.15.
|t Distribution and treatment energy efficiency measures --
|g 15.3.
|t Demand Side --
|g 15.3.1.
|t Leakages --
|g 15.3.2.
|t Inappropriate use --
|g 15.3.3.
|t System operating pressure --
|g 15.3.4.
|t Artificial demand --
|g 15.3.5.
|t Perceived high pressure demands --
|g 15.3.6.
|t High volume intermittent demand events --
|g 15.3.7.
|t Demand side energy efficiency measures --
|g 15.4.
|t Compressed Air Systems Assessments --
|g 15.4.1.
|t Leakage assessment --
|g 15.4.2.
|t End users assessment --
|g 15.4.3.
|t Distribution assessment --
|g 15.4.4.
|t Air treatment assessment --
|g 15.4.5.
|t Compressor room assessment --
|g 15.4.6.
|t Demand profile --
|g 15.4.7.
|t Pressure profile --
|g ch. 16
|t Large Scale Cooling and Industrial Refrigeration Systems /
|r Albert Williams --
|g 16.1.
|t Refrigerants --
|g 16.1.1.
|t Desirable refrigerant characteristics --
|g 16.2.
|t Vapor Compression Refrigeration Cycle --
|g 16.2.1.
|t Coefficient of performance --
|g 16.2.2.
|t Practical considerations for vapor compression refrigeration systems --
|g 16.3.
|t Absorption Cycle --
|g 16.4.
|t Refrigeration System Components --
|g 16.4.1.
|t Refrigerant compressors --
|g 16.4.2.
|t Evaporators --
|g 16.4.3.
|t Throttling devices --
|g 16.4.4.
|t Condensers --
|g 16.4.5.
|t Heat rejection equipment --
|g 16.5.
|t Industrial Refrigeration Applications in Food Industry --
|g 16.5.1.
|t Still air or blast freezing --
|g 16.5.2.
|t Cryogenic freezing --
|g 16.5.3.
|t Plate freezing --
|g 16.5.4.
|t Scraped surface freezing --
|g 16.6.
|t Energy Efficiency Ratios --
|g 16.7.
|t Sensible and Latent Heat --
|g 16.7.1.
|t Sensible heat --
|g 16.7.2.
|t Latent heat --
|g 16.8.
|t Energy Efficiency Measures for CR Systems.
|
| 533 |
|
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|a Electronic reproduction.
|b Ann Arbor, MI
|n Available via World Wide Web.
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