GB/T 39779-2021 (GB/T39779-2021, GBT 39779-2021, GBT39779-2021) & related versions
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Design guidelines for distributed energy system of combined cooling, heating and power
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GB/T 39779-2021: PDF in English (GBT 39779-2021) GB/T 39779-2021
GB
NATIONAL STANDARD OF THE
PEOPLE’S REPUBLIC OF CHINA
ICS 27.010
F 01
Design guidelines for distributed energy system of
combined cooling, heating and power
ISSUED ON: MARCH 09, 2021
IMPLEMENTED ON: OCTOBER 01, 2021
Issued by: State Administration for Market Regulation;
Standardization Administration of the People’s Republic of
China.
Table of Contents
Foreword ... 3
1 Scope ... 4
2 Normative references ... 4
3 Terms and definitions ... 6
4 General rules ... 8
5 Planning and decision-making ... 10
6 Engineering design ... 12
7 Operation management ... 17
Appendix A (Informative) Configuration of the distributed energy system of
combined cooling, heating and power ... 20
Appendix B (Informative) Scope of evaluation content of the distributed energy
system of combined cooling, heating and power ... 22
Appendix C (Informative) General process of distributed energy project
approval and engineering construction ... 24
Appendix D (Informative) Energy-converted standard coal reference
coefficients ... 25
Appendix E (Informative) Various energy-converted equivalent electric
coefficient ... 27
Appendix F (Informative) Energy quality coefficient of common cold and heat
quantity ... 28
Appendix G (Informative) Energy equivalent value of energy-consumed
medium ... 29
References ... 30
Design guidelines for distributed energy system of
combined cooling, heating and power
1 Scope
This Standard specifies the general rules, planning and decision-making,
engineering design, and operation management which are involved in the
design of the distributed energy system of combined cooling, heating and power.
This Standard applies to the distributed energy system of combined cooling,
heating and power, which is based on gas fuels; it also applies to the design of
distributed energy project or distributed energy station of combined cooling,
heating and power, which is based on gas fuels. It can be used as reference for
the distributed energy system of combined cooling, heating and power, which
is based on liquid fuels, under the same technical conditions.
This Standard does not apply to the distributed energy system of combined
cooling, heating and power, which is driven by solid fuels, including renewable
energy, and other non-fossil energy sources.
2 Normative references
The following documents are indispensable for the application of this document.
For dated references, only the dated version applies to this document. For
undated references, the latest edition (including all amendments) applies to this
document.
GB/T 2589-2020, General rules for calculation of the comprehensive energy
consumption
GB 3096, Environmental quality standard for noise
GB 8978, Integrated Wastewater Discharge Standard
GB 10070, Standard of environmental vibration in urban area
GB 12348, Emission standard for industrial enterprises noise at boundary
GB 13271, Emission standard of air pollutants for boiler
GB/T 15316, General principles for monitoring and testing of energy
conservation
GB 50019, Design code for heating ventilation and air conditioning of
industrial buildings
GB 50028, Code for design of city gas engineering
GB 50040, Standard for design of dynamic machine foundation
GB/T 50087, Code for design of noise control of industrial enterprises
GB 50118, Code for design of sound insulation of civil buildings
GB 50365, Standard for operation and management of central air
conditioning system
GB 50736, Design code for heating ventilation and air conditioning of civil
buildings
GB/T 50852, Classification standard of building engineering consultation
GB 51131, Technical code for gas-fired combined cooling, heating and power
engineering
GB/T 51285, Standard for the energy-efficient effect evaluation of building
energy performance contracting
DL/T 5508-2015, Code for design of gas-fired distributed energy station
JG/T 299, Technical specifications of thermal storage equipment for cooling
and heating
NB/T 32015, Technical rule for distributed resources connected to
distribution network
NB/T 42029.5, Code for design of reciprocating internal combustion gas
engine power station - Part 5: Cooling system
3 Terms and definitions
Terms and definitions determined by GB/T 33757.1, GB/T 36160.1-2018, GB/T
36160.2-2018, GB 50365, GB/T 50852, GB/T 34913-2017, GB/T 2589-2020,
GB 51131, and the following ones are applicable to this document.
3.1
Distributed energy system of combined cooling, heating and power
Energy quality utilization ratio
The percentage OF the sum of the output equivalent electric quantity and
cooling (heating) quantity of the distributed energy system of combined cooling,
heating and power AND the sum of the input equivalent gas or liquid fuel heat
quantity and other energies.
Note 1: This term takes into account the difference in energy grade and quality,
which is different from 3.4 energy utilization ratio.
Note 2: Refer to the "second boundary" in Figure A.1 for the calculation
boundary.
3.6
Commissioning
The working procedures and methods that perform a whole-process
management through testing adjusting and balancing, performance verification,
acceptance and seasonal working condition verification of the distributed
energy system of combined cooling, heating and power, so as to ensure the
realization of the design intent and the satisfaction of the actual use
requirements of users.
4 General rules
4.1 The design of distributed energy system of combined cooling, heating and
power shall mainly consider:
a) Guaranteed supply of energy (gas);
b) Reasonable site selection and establishment;
c) Efficient and energy-saving system;
d) Economic operation;
e) Environmental protection.
4.2 The design activities of the distributed energy system of combined cooling,
heating and power should include planning and decision-making, engineering
design and operation management; the design content generally includes
feasibility study, engineering design, and project evaluation and assessment.
For preparation of each stage, see GB/T 50852, or refer to the contents of the
municipal public engineering design documentation depth regulations and the
constructional engineering design documentation depth regulations, but not
limited to the feasibility study of the project.
establishment and engineering construction of the distributed energy project
can be found in Appendix C.
5.2 The earlier stage of a distributed energy project is the planning and
decision-making stage; a feasibility study of the project shall be compiled
according to the requirements of 4.2 according to the complexity of the project.
5.3 For the feasibility study of the project, refer to Appendix B for the
assessment of the earlier decision-making stage, which includes:
a) This stage is a qualitative assessment, which shall perform analysis of the
technology and energy efficiency of the distributed energy system of
combined cooling, heating and power;
b) The assessment is based on the matching of project supply and demand,
energy saving rate, energy utilization ratio, environmental and social
impact, and supplemented by economic indicators;
c) The assessment shall meet the content requirements of 4.6 and be
calculated in accordance with GB/T 33757.1 and GB/T 36160.1-2018;
d) The assessment should refer to the "first boundary" in Figure A.1 to make
a preliminary estimate of the types and quantities of energy supply and
demand.
5.4 The distributed energy station of combined cooling, heating and power
(hereinafter referred to as "distributed energy station") shall be set up close to
users; the site planning and building requirements shall comply with the
relevant regulations of GB 50016 and DL/T 5508-2015.
5.5 The distributed energy system of combined cooling, heating and power shall
be designed in accordance with the requirements of the preliminary
environmental impact assessment; the environmental protection planning and
design of the distributed energy project shall meet but not limited to the following
requirements:
a) The exhaust gas emission and chimney setting shall meet the
requirements of GB 13271;
b) The noise value of the distributed energy station shall meet the
requirements of GB 3096, GB 12348, and GB 22337;
c) The environmental vibration of the distributed energy station shall meet
the requirements of GB 10070;
d) The discharged water quality shall meet the requirements of GB 8978 and
GB/T 31962.
6.2.1 The cooling, heating, and power design loads of the distributed energy
system of combined cooling, heating and power shall be implemented as
follows:
a) The design load shall include the design day calculation load and the
hourly load throughout the year; the cooling and heating loads include
building load and technical load;
b) The design load of each stage of the project: estimation shall be adopted
in the earlier-stage planning stage; calculation shall be adopted in the mid-
term design stage; actual measurement shall be adopted in the later-stage
operation stage;
c) For the design load, give priority to adopt or refer to the measured data;
then, obtain it by calculation. For the calculation of the cooling and heating
load, see GB 50736;
d) For the design load analysis of the distributed energy system of combined
cooling, heating and power, see DL/T 5508-2015.
6.2.2 The design and configuration options of the distributed energy system of
combined cooling, heating and power are as follows:
a) For the power subsystem, see Appendix A, Appendix B, and Appendix C
in GB/T 36160.2-2018;
b) For the refrigeration and heating subsystem, see Appendix B and
Appendix C in GB/T 36160.1-2018;
c) Refer to Figure A.2. for the cold storage and heat storage system.
6.2.3 For the distributed energy system of combined cooling, heating and power,
determine the form and capacity of the cold storage and heat storage system
according to the capacity of the power generation system, user load
characteristics, local peak and valley electricity price policies, and economical
efficiency of investment and operation.
6.2.4 In order to maximize the use of exhaust heat, efficient use of energy, and
convenient management, the design shall provide the annual operation strategy
and operation mode of the distributed energy system of combined cooling,
heating and power, as well as guiding the operation and commissioning of the
project in the later period.
6.2.5 For the preliminary design and construction drawing design, refer to
Appendix B for the design of the distributed energy system of combined cooling,
heating and power, to perform the following analysis and evaluation:
6.4.1 The power generation system of the distributed energy system of
combined cooling, heating and power is composed of gas turbine or internal
combustion engine, steam turbine, exhaust-heat recovery boiler, generator and
auxiliary equipment. For specific parameter requirements and forms, see GB/T
36160.2-2018.
6.4.2 The choice of the form and capacity of the prime mover shall take into
account factors such as project characteristics, load characteristics, noise,
nitrogen oxide emission concentration, and economic efficiency.
6.4.3 The power generation system design shall comply with the relevant
regulations of GB/T 36160.2-2018, GB 51131 and DL/T 5508-2015.
6.5 Refrigeration and heating system
6.5.1 The refrigeration and heating system of the distributed energy system of
combined cooling, heating and power is composed of electric refrigeration and
heating system, exhaust-heat refrigeration and heating system, exhaust-heat
recovery boiler and auxiliary equipment. For specific parameter requirements
and forms, see GB/T 36160.1-2018.
6.5.2 The exhaust-heat utilization system shall follow the design principles of
temperature matching and gradient utilization; the selection of the refrigeration
and heating system shall comprehensively consider factors such as project
characteristics, load characteristics, energy quality coefficient of the output
medium, and economic efficiency.
6.5.3 The application equipment of the refrigeration and heating system shall
be determined according to the prime mover's exhaust heat parameters. The
exhaust heat shall be used when the exhaust gas temperature is ≥120 °C and
the cooling water temperature is ≥75 °C. The energy efficiency of the selected
refrigeration and heating equipment shall meet the requirements of GB 19577
and GB 29540.
6.5.4 The prime mover and the refrigeration and heating equipment shall adopt
a one-to-one configuration; for micro gas turbines and internal combustion
engine generator sets with a small unit capacity, a many-to-one form can be
used, and the same model of modular combination should be used for the
generator sets.
6.5.5 The design of the refrigeration and heating system shall still comply with
the relevant regulations of GB/T 36160.1-2018, GB 50019 and GB 50736.
6.6 Monitoring and control system
7 Operation management
7.1 General provisions
7.1.1 The distributed energy system of combined cooling, heating and power
shall strengthen operation management and standardize project evaluation to
achieve efficient operation of the system.
7.1.2 The operation management strategy, control and use methods, operation
instructions, and settings of different working conditions of the distributed
energy system of combined cooling, heating and power shall be used as
technical data management, which should be entrusted to professional
institutions to study and formulate.
7.1.3 The distributed energy project shall undergo special system adjustment,
which includes six stages, namely project establishment, data collection,
inspection and testing, analysis and diagnosis, rectification implementation, and
effect verification.
7.1.4 The distributed energy system of combined cooling, heating and power
shall develop comprehensive, safe and reliable emergency management
measures for accidents. For key parts which are of high temperature, high
pressure, inflammable and explosive, and prone to emergencies, risk analysis
and safety evaluation shall be carried out in advance, and emergency plans
and long-term preventive emergency measures shall be formulated.
7.1.5 The operation and management of the distributed energy system of
combined cooling, heating and power shall comply with relevant regulations in
GB 50365, GB/T 51131, GB/T 17981-2007, GB/T 36160.1-2018, GB/T
36160.2-2018, and GB/T 33757.1.
7.2 Operation evaluation
7.2.1 After the distributed energy system of combined cooling, heating and
power has been in stable operation for at least one year (including at least a
complete refrigeration season and a complete heating season), refer to Figure
1 and Appendix B for the following measurements, verifications, and
evaluations:
a) For the evaluation results of 6.2.5 in the design stage, perform evaluation
and review in the operation stage, to verify whether the performance
meets the indicator requirements of 4.6;
b) According to the annual cooling, heating, power supply and power
consumption and fuel consumption of the distributed energy system of
the exhaust-heat utilization ratio is lower than 75% for a long time, the operation
mode shall be optimized and adjusted.
7.3.3 The fuel supply and power generation system shall be inspected,
maintained and tested regularly to ensure normal and effective operation.
7.4 Personnel and management
7.4.1 The operation of the distributed energy system of combined cooling,
heating and power shall have professional operation and management
personnel; the personnel shall be complete; the technical level shall be
reasonable; they shall have relevant professional knowledge such as safety,
health, and energy saving.
7.4.2 Operation management personnel shall undergo professional training and
shall be employed after passing the assessment; the employing department
shall establish and improve the personnel training and assessment system, and
shall keep relevant files.
7.4.3 The operation management department shall establish the energy
management system of the enterprise according to GB/T 23331; formulate the
energy management system according to GB/T 15587; formulate and improve
the target parameters suitable for the distributed energy system of combined
cooling, heating and power according to GB/T 36713.
7.4.4 Public institutions shall establish an energy management system and
energy management evaluation indicators for the distributed energy system of
combined cooling, heating and power in accordance with GB/T 32019 and GB/T
30260.
7.4.5 For the distributed energy system of combined cooling, heating and power
that is under the energy conservation monitoring, relevant measures for energy
conservation monitoring shall be formulated in accordance with GB/T 15316.
7.4.6 The distributed energy system of combined cooling, heating and power
should be managed through building information models, smart equipment
emergency management models, asset management databases, and
equipment maintenance and repair databases.
......
Standard ID | GB/T 39779-2021 (GB/T39779-2021) | Description (Translated English) | Design guidelines for distributed energy system of combined cooling, heating and power | Sector / Industry | National Standard (Recommended) | Classification of Chinese Standard | F01 | Classification of International Standard | 27.010 | Word Count Estimation | 22,258 | Date of Issue | 2021-03-09 | Date of Implementation | 2021-10-01 | Drafting Organization | China Architecture Northwest Design and Research Institute Co., Ltd., Yuanda Energy Utilization Management Co., Ltd., Yuanda Air Conditioning Co., Ltd., China National Institute of Standardization, Tsinghua University, East China Architectural Design and Research Institute Co., Ltd., China Zhongyuan International Engineering Co., Ltd., Beijing Architectural Design Research Institute Co., Ltd., Architectural Design Institute of South China University of Technology, China Power Engineering Consulting Group Northwest Electric Power Design Institute Co., Ltd., China Hydropower and Water Conservancy Planning and Design Institute, China State Construction Design Group Co., Ltd., Zhejiang University Architectural Design and Research Institute Co., Ltd., China Machinery China United Engineering Co., Ltd., Qingdao University of Technology, Ebara Cooling and Heating System (China) Co., Ltd., Institute of Engineering Thermophysics, Chinese Academy of Sciences, China Resources Gas (Zhengzhou) Municipal Design and Research Institute Co., Ltd., Northwest Survey and Design Research Institute of China Power Construction Corporation , | Administrative Organization | National Energy System Standardization Technical Committee (SAC/TC 459) | Regulation (derived from) | National Standard Announcement No. 3 of 2021 | Proposing organization | National Energy System Standardization Technical Committee (SAC/TC 459) | Issuing agency(ies) | State Administration for Market Regulation, National Standardization Administration |
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