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ASHRAE - OR-10-010 - CLEAN ROOM EXHAUST ENERGY RECOVERY OPTIMIZATION DESIGN Organization: ASHRAE
Date: 2010-01-01
Description: Therefore, the application of a heat pipe as a heat exchanger in the heat recovery system is not very popular. In semiconductor cleanrooms, therefore, potential energy recovery from the EA is enormous.
AHRI GUIDELINE V SI - CALCULATING THE EFFICIENCY OF ENERGY RECOVERY VENTILATION AND ITS EFFECT ON EFFICIENCY AND SIZING OF BUILDING HVAC SYSTEMS Organization: AHRI
Date: 2011-01-01
Description: This guideline applies to energy recovery ventilation component applications and combinations of energy recovery components with unitary heating, ventilating, and air-conditioning equipment incorporating mechanical ventilation with outside air.
AHRI GUIDELINE V I-P - CALCULATING THE EFFICIENCY OF ENERGY RECOVERY VENTILATION AND ITS EFFECT ON EFFICIENCY AND SIZING OF BUILDING HVAC SYSTEMS Organization: AHRI
Date: 2011-01-01
Description: This guideline applies to energy recovery ventilation component applications and combinations of energy recovery components with unitary heating, ventilating, and air-conditioning equipment incorporating mechanical ventilation with outside air.
ASHRAE 90361 - ADVANCED ENERGY DESIGN GUIDE FOR LARGE HOSPITALS: 50% ENERGY SAVINGS Organization: ASHRAE
Date: 2012-04-01
Description: Space types covered by the Guide include cafeterias, kitchens, and dining facilities; conference, lobby, lounge, and office areas; reception/waiting areas and examination and treatment rooms; clean and soiled workrooms and holding areas; nurse stations, nurseries, patient rooms, corridors and transition spaces, lockers, and restrooms; operating rooms, procedure rooms, recovery rooms, and sterilizer equipment areas; pharmacies, medication rooms, and laboratories; triage, trauma, and emergency rooms; physical therapy and radiology/imaging rooms; and storage, receiving, and mechanical/electrical/telecom rooms.
CSA C837 - MONITORING AND ENERGY PERFORMANCE MEASUREMENTS OF COMPRESSED AIR SYSTEMS - FIRST EDITION; ERRATA: OCTOBER 2016 Organization: CSA
Date: 2016-01-01
Description: Exclusions The Standard is not intended to be used for the following purposes or systems: a) electrically driven single phase compressors; b) bench testing, measurement, or certification of the performance of an air compressor; c) measurement of heat recovery; d) process compressors for gases other than air; e) energy or water measurements for the mechanical cooling of water-cooled air compressors; f) compressors driven by energy sources other than electric motors; and g) compressors that are regulated by transportation standards.
CEN - PREN 15316-1 - HEATING SYSTEMS AND WATER BASED COOLING SYSTEMS IN BUILDINGS - METHOD FOR CALCULATION OF SYSTEM ENERGY REQUIREMENTS AND SYSTEM EFFICIENCIES - PART 1: GENERAL AND ENERGY PERFORMANCE EXPRESSION Organization: CEN
Date: 2014-10-01
Description: The calculation of the system losses of each part of the heating sub-systems is defined in subsequent standards Ventilation systems are not included in this standard (e. g. balanced systems with heat recovery), but if the air is preheated or an air heating system is installed, the systems providing the heat to the AHU (Air Handling Unit) are covered by this standard.
ASHRAE - LO-09-054 - CONDENSATE HARVESTING FROM LARGE DEDICATED OUTSIDE AIR-HANDLING UNITS WITH HEAT RECOVERY Organization: ASHRAE
Date: 2009-01-01
Description: To satisfy ASHRAE 90.1, fan systems that have a design air flow rate of 5000 cfm (2358 L / sec) or greater and have a minimum outside ventilation air flow that is equal to 70% or more of the supply air shall have an energy recovery system with at least 50% recovery effectiveness (ASHRAE, 2004).
DSF/FPREN 15316-1 - ENERGY PERFORMANCE OF BUILDINGS – METHOD FOR CALCULATION OF SYSTEM ENERGY REQUIREMENTS AND SYSTEM EFFICIENCIES – PART 1: GENERAL AND ENERGY PERFORMANCE EXPRESSION, MODULE M3-1, M3-4, M3-9, M8-1, M8-4 Organization: DS
Description: Ventilation systems are not included in this standard (e.g. balanced systems with heat recovery), but if the air is preheated or an air heating system is installed, the systems providing the heat to the AHU (Air Handling Unit) are covered by this standard.
IES AEDG-11 - ADVANCED ENERGY DESIGN GUIDANCE OFFERED FOR LARGE HOSPITALS - TO PURCHASE CALL 1-800-854-7179 USA/CANADA OR 303-397-7956 WORLDWIDE Organization: IES
Date: 2012-01-01
Description: Space types covered include conference, lobby, lounge and office areas; reception/waiting areas and examination and treatment rooms; clean and soiled workrooms; nurse stations, nurseries, patient rooms; operating rooms, procedure rooms, recovery rooms and sterilizer equipment areas; pharmacies and laboratories; triage, trauma and emergency rooms; physical therapy and radiology/imaging rooms; and storage, receiving and mechanical/electrical/telecom rooms.
TAPPI TIP 0416-13 - WATER TREATMENT-RELATED OPPORTUNITIES FOR ENERGY CONSERVATION IN A PAPER MILL POWERHOUSE Organization: TAPPI
Date: 2013-01-01
Description: Even as energy prices have fluctuated widely in recent years, it is always a good operating practice to review powerhouse operations in terms of the efficient use of energy. The three main areas of focus that will be addressed are: Paper Mill Condensate Management Blowdown Heat Recovery Blowdown Rate Adjustment There are certainly other areas of potential energy savings in the paper mill powerhouse that are outside the scope of this TIP.
ASHRAE - LV-11-C065 - MEASURES FOR MAINTAINING LOW ENERGY USE IN COMMERCIAL BUILDINGS OVER THEIR LIFE-CYCLE Organization: ASHRAE
Date: 2011-01-01
Description: With additional resources being made available under the Recovery Act funding, new tools are emerging to allow monitoring and control of energy use. This paper outlines various qualitative and quantitative measures that can be practiced to improve and sustain performance of all building systems and infrastructure elements.
SMACNA HVAC COMM MANU - HVAC SYSTEMS COMMISSIONING MANUAL - SECOND EDITION Organization: SMACNA
Date: 2013-01-01
Description: First, HVAC systems are among the most complex and interconnected of building service systems. Second, considerable energy is consumed in HVAC systems. Inefficient operation increases operating cost.
SAE/TP - 2008-01-2052 - DEVELOPMENT AND DESIGN OF A LOW TEMPERATURE SOLID WASTE OXIDATION AND WATER RECOVERY SYSTEM Organization: SAE/TP
Date: 2008-06-29
Description: An ozone recycle loop was recently added to the system, which significantly increased the waste oxidation rates. The reactor operating conditions were then optimized using the design of experiments technique to maximize the waste oxidation rate.
API SPEC 16D - SPECIFICATION FOR CONTROL SYSTEMS FOR DRILLING WELL CONTROL EQUIPMENT AND CONTROL SYSTEMS FOR DIVERTER EQUIPMENT - SECOND EDITION; EFFECTIVE JANUARY 2005 Organization: API
Date: 2004-07-01
Description: They include acoustic control systems, ROV (Remotely Operated Vehicle) operated control systems and LMRP recovery systems. For surface control systems, a reserve supply of pressurized nitrogen gas can serve as a backup means to operate functions in the event that the pump system power supply is lost.
CSA P.10 - PERFORMANCE OF INTEGRATED MECHANICAL SYSTEMS FOR RESIDENTIAL HEATING AND VENTILATION - FIRST EDITION Organization: CSA
Date: 2007-03-01
Description: This Standard describes the test procedures, apparatus, and calculations required to determine the performance, capacities, energy consumption, and overall efficiency of residential gas-fired integrated mechanical systems that perform all of the following functions: (a) space heating; (b) potable water heating; (c) ventilation with heat recovery; and (d) air circulation and distribution of fresh air Note: For the purposes of this Standard, integrated mechanical systems are divided into three types (see Clause 6.1.2).
CENELEC - EN 62282-3-200 - FUEL CELL TECHNOLOGIES - PART 3-200: STATIONARY FUEL CELL POWER SYSTEMS - PERFORMANCE TEST METHODS Organization: CENELEC
Date: 2016-03-01
Description: However, a common system diagram and boundary has been defined for evaluation of the fuel cell power system The following conditions are considered in order to determine the system boundary of the fuel cell power system: – all energy recovery systems are included within the system boundary; – all kinds of electric energy storage devices are considered outside the system boundary; – calculation of the heating value of the input fuel (such as natural gas, propane gas and pure hydrogen gas, etc.) is based on the conditions of the fuel at the boundary of the fuel cell power system.
IEC 62282-3-200 - FUEL CELL TECHNOLOGIES – PART 3-200: STATIONARY FUEL CELL POWER SYSTEMS – PERFORMANCE TEST METHODS - EDITION 2.0 Organization: IEC
Date: 2015-11-01
Description: The following conditions are considered in order to determine the system boundary of the fuel cell power system: – all energy recovery systems are included within the system boundary; – all kinds of electric energy storage devices are considered outside the system boundary; – calculation of the heating value of the input fuel (such as natural gas, propane gas and pure hydrogen gas, etc.) is based on the conditions of the fuel at the boundary of the fuel cell power system.
CEI EN 62282-3-200 - FUEL CELL TECHNOLOGIES PART 3-200: STATIONARY FUEL CELL POWER SYSTEMS - PERFORMANCE TEST METHODS Organization: CEI
Date: 2012-07-01
Description: The following conditions are considered in order to determine the test boundary of the fuel cell power system: – all energy recovery systems are included within the test boundary; – all kinds of electric energy storage devices are considered outside the test boundary; – calculation of the heating value of the input fuel (such as natural gas, propane gas and pure hydrogen gas, etc.) is based on the conditions of the fuel at the boundary of the fuel cell power system.
DS/EN 62282-3-2 - FUEL CELL TECHNOLOGIES - PART 3-2: STATIONARY FUEL CELL POWER SYSTEMS - PERFORMANCE TEST METHODS Organization: DS
Date: 2006-08-28
Description: The following conditions are considered in order to determine the test boundary of the fuel cell power system. - All energy recovery systems are included within the test boundary. - Calculation of the heating value of the input fuel (such as natural gas, propane gas, and pure hydrogen gas, etc.) is based on the conditions of the fuel at the boundary of the fuel cell power system.
IEC 62282-3-2 - FUEL CELL TECHNOLOGIES – PART 3-2: STATIONARY FUEL CELL POWER SYSTEMS – PERFORMANCE TEST METHODS - EDITION 1.0 Organization: IEC
Date: 2006-03-01
Description: The following conditions are considered in order to determine the test boundary of the fuel cell power system. – All energy recovery systems are included within the test boundary.

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