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ASME PTC 1
General Instructions Performance Test Codes
Organization:
ASME - ASME International
Year: 2011
Abstract: SCOPE AND ORGANIZATION OF PTCs
Most ASME PTCs are applicable to a specified type of equipment defined by the Code. Theremay be several subcategories of equipment covered by a single code. Types of equipment to which PTCs apply can be classified into five broad categories.
– power production
– combustion and heat transfer
– fluid handling
– emission
– instruments, apparatus, and other supplemental documents
The quantities that characterize performance are defined in each code for the equipment within its scope. Absolute performance characteristics determined by adherence to a PTC can be evaluated as compared to design or predicted characteristics, to previous test results, or they can be used to benchmark or ascertain performance at a particular time.
Some PTCs are written as general documents for reference in support of the equipment PTCs. These can be considered as technical reference material for the equipment codes. Three types of reference codes exist.
The first type covers instrumentation used in the measurement of thermodynamic or process fluid parameters, such as pressure, temperature, flow, and shaft power. Such individual codes referring to process or thermodynamic quantities are known as Performance Test Code Instruments and Apparatus Supplements.
They are supplementary to the information on mandatory instrumentation requirements contained in the equipment codes. Instrumentation information in equipment test codes supersedes the information given in these supplements, but otherwise these supplements should be incorporated by reference in equipment test codes where deemed appropriate by the committee.
The second type covers guidance and reference information. It currently consists of PTC 1, General Instructions, and PTC 2, Definitions and Values. PTC 2 contains standards for terms, units, values of constants, and technical nomenclature.
The third type addresses how to analyze the uncertainties associated with measurement of all primary parameters to develop overall test uncertainty.
DEFINITION AND PURPOSE
ASME Performance Test Codes (PTCs) provide uniform rules and procedures for the planning, preparation, execution, and reporting of performance test results. Test results provide numerical characteristics to the performance of equipment, systems, and plants being tested. Throughout ASME PTC 1, when the term "equipment" is used with reference to the object of a performance test, it can refer to specific equipment, systems, or to entire plants.
Most ASME PTCs are applicable to a specified type of equipment defined by the Code. Theremay be several subcategories of equipment covered by a single code. Types of equipment to which PTCs apply can be classified into five broad categories.
– power production
– combustion and heat transfer
– fluid handling
– emission
– instruments, apparatus, and other supplemental documents
The quantities that characterize performance are defined in each code for the equipment within its scope. Absolute performance characteristics determined by adherence to a PTC can be evaluated as compared to design or predicted characteristics, to previous test results, or they can be used to benchmark or ascertain performance at a particular time.
Some PTCs are written as general documents for reference in support of the equipment PTCs. These can be considered as technical reference material for the equipment codes. Three types of reference codes exist.
The first type covers instrumentation used in the measurement of thermodynamic or process fluid parameters, such as pressure, temperature, flow, and shaft power. Such individual codes referring to process or thermodynamic quantities are known as Performance Test Code Instruments and Apparatus Supplements.
They are supplementary to the information on mandatory instrumentation requirements contained in the equipment codes. Instrumentation information in equipment test codes supersedes the information given in these supplements, but otherwise these supplements should be incorporated by reference in equipment test codes where deemed appropriate by the committee.
The second type covers guidance and reference information. It currently consists of PTC 1, General Instructions, and PTC 2, Definitions and Values. PTC 2 contains standards for terms, units, values of constants, and technical nomenclature.
The third type addresses how to analyze the uncertainties associated with measurement of all primary parameters to develop overall test uncertainty.
DEFINITION AND PURPOSE
ASME Performance Test Codes (PTCs) provide uniform rules and procedures for the planning, preparation, execution, and reporting of performance test results. Test results provide numerical characteristics to the performance of equipment, systems, and plants being tested. Throughout ASME PTC 1, when the term "equipment" is used with reference to the object of a performance test, it can refer to specific equipment, systems, or to entire plants.
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| contributor author | ASME - ASME International | |
| date accessioned | 2017-09-04T18:24:26Z | |
| date available | 2017-09-04T18:24:26Z | |
| date copyright | 2011.12.23 | |
| date issued | 2011 | |
| identifier other | IGRHUEAAAAAAAAAA.pdf | |
| identifier uri | http://yse.yabesh.ir/std;query=autho162sAF679D4049A961598F1EFDEC014A0Facilities%114ngineering%20Command%22/handle/yse/206808 | |
| description abstract | SCOPE AND ORGANIZATION OF PTCs Most ASME PTCs are applicable to a specified type of equipment defined by the Code. Theremay be several subcategories of equipment covered by a single code. Types of equipment to which PTCs apply can be classified into five broad categories. – power production – combustion and heat transfer – fluid handling – emission – instruments, apparatus, and other supplemental documents The quantities that characterize performance are defined in each code for the equipment within its scope. Absolute performance characteristics determined by adherence to a PTC can be evaluated as compared to design or predicted characteristics, to previous test results, or they can be used to benchmark or ascertain performance at a particular time. Some PTCs are written as general documents for reference in support of the equipment PTCs. These can be considered as technical reference material for the equipment codes. Three types of reference codes exist. The first type covers instrumentation used in the measurement of thermodynamic or process fluid parameters, such as pressure, temperature, flow, and shaft power. Such individual codes referring to process or thermodynamic quantities are known as Performance Test Code Instruments and Apparatus Supplements. They are supplementary to the information on mandatory instrumentation requirements contained in the equipment codes. Instrumentation information in equipment test codes supersedes the information given in these supplements, but otherwise these supplements should be incorporated by reference in equipment test codes where deemed appropriate by the committee. The second type covers guidance and reference information. It currently consists of PTC 1, General Instructions, and PTC 2, Definitions and Values. PTC 2 contains standards for terms, units, values of constants, and technical nomenclature. The third type addresses how to analyze the uncertainties associated with measurement of all primary parameters to develop overall test uncertainty. DEFINITION AND PURPOSE ASME Performance Test Codes (PTCs) provide uniform rules and procedures for the planning, preparation, execution, and reporting of performance test results. Test results provide numerical characteristics to the performance of equipment, systems, and plants being tested. Throughout ASME PTC 1, when the term "equipment" is used with reference to the object of a performance test, it can refer to specific equipment, systems, or to entire plants. | |
| language | English | |
| title | ASME PTC 1 | num |
| title | General Instructions Performance Test Codes | en |
| type | standard | |
| page | 28 | |
| status | Active | |
| tree | ASME - ASME International:;2011 | |
| contenttype | fulltext |