Geometrical Product Specifications(GPS) - Acceptance and reverification tests for coordinate measuring machines(CMM) - Part 2: CMMs used for measuring size
other information
Release date:1997-06-06
drafter:Li Xiaopei, Wang Zhengqiang, Wang Jin, Zhang Heng, Gao Guoping, Zhu Xijing, Tang Yumin, Yu Jiping
Drafting unit:China Machinery Productivity Promotion Center of China Academy of Mechanical Science, China National Institute of Metrology, Hexagon Measurement Technology (Qingdao) Co., Ltd.
Focal point unit:National Technical Committee for Standardization of Product Dimensions and Geometry Specifications
Proposing unit:National Technical Committee for Standardization of Product Dimensions and Geometry Specifications
Publishing department:General Administration of Quality Supervision, Inspection and Quarantine of the People's Republic of China Standardization Administration of China
competent authority:National Standardization Administration
Some standard content:
1CS 17.040.30
National Standard of the People's Republic of China
GB/T 16857.2—2006/1ISO 10360-2:2001 replaces GB/T16857.2—1997
Geometrical Product Specifications (GPS)
Acceptance and reverification tests for coordinate measuring machines (CMM) -Part 2: CMMs used for measuring size(ISO 10360-2 :2001, IDT)
2006-07-19 Issued
General Administration of Quality Supervision, Inspection and Quarantine of the People's Republic of China Standardization Administration of China
Tested by you
2007-02-01 Implementation
Resonance of the People's Republic of China
National Standard
Product Geometric Technical Specification (GPS)
Acceptance and re-inspection of coordinate measuring machines Part 2: Coordinate measuring machines for measuring dimensions (:137 1 16857. 2-2006/150 10390-2:2901*
Published by China Standards Press
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GB/T 16857.2--2006/ISO 10360-2:2001 G13/T16857≤*Product Geometry Specification (GPS) Coordinate Measuring Machines - Acceptance Testing and Recheck Testing" is divided into six parts: Part 1: Vocabulary; Part 2: Coordinate Measuring Machines for Measuring Layer Dimensions; Part 3: Coordinate Measuring Machines with the Axis of the Rotating Table as the Fourth Axis; Part 4: Coordinate Measuring Machines Used in Scanning Measurement Mode; Part 5: Coordinate Measuring Machines Using Multi-Probe Probing Systems; Part 6: Evaluation of the Error of the Calculated Gaussian Pseudo-element This part is Part 2 of 13/T16857
This part is equivalent to the international standard ISC)1C360-2?2001%Product Geometry Specification (GFS) Acceptance Testing and Recheck Testing of Coordinate Measuring Machines (CMM) - Part 2: Coordinate Measuring Machines for Measuring Dimensions" (English version). This part is a reprint of 15010360-2.2001. For ease of use, this part has been modified as follows: a) "this part of 15010360" is changed to "this part of GB/T 16857"; b) the decimal point \,\ is used instead of "\" as a decimal point; the prefix of the international standard is deleted.
In addition, in normative documents, the corresponding international standard is replaced by the Chinese standard adopting the international standard. This part replaces GB/T 16857.21997 "Coordinate metrology Part 2 Performance evaluation of coordinate measuring machines". This part is a revision of the original (13/T16857.21997 "Coordinate metrology Part 2 Performance evaluation of coordinate measuring machines". 6857.21997 has the following major changes: the name of the standard "Coordinate metrology Part 2: Performance evaluation of coordinate measuring machines" has been changed to "Product geometrical technical specifications (S) a) Acceptance testing and retesting of coordinate measuring machines Part 2: Coordinate measuring machines for measuring rulers": the terms and definitions established in the relevant standards are clarified to be used in this part, and the 10 terms and definitions in the "Definitions" of the original standard are confirmed. The code R for detection error is changed to P14253-1:1998)GB/T 18780.12002
(1S0 146G0-1:J999,IDT)
Production island geometry scene This specification (CPS load elements
Part 1: Basic terms and definitions
JJF1001-2998 General metrology evaluation and determination 3 Terms and definitions
G13/T16857.1, CB/T18779.1, GB/T18780.1 and JJ11001 The correct terms and definitions apply to this part of GB/T16857.
4 Metrological characteristics requirements
4.1 Indication error of dimensional measurement
The indication error of the coordinate measuring machine size measurement shall not exceed the indication error of the coordinate measuring machine size measurement. Maximum allowable indication error MPH: G/T16857.2---2006/ES010360-2:2001 Maximum allowable indication error MPEE of coordinate measuring machine dimensional measurement, for acceptance inspection, specified by the manufacturer;
Re-inspection inspection, specified by the user
Coordinate measuring machine dimensional measurement indication error E Maximum allowable indication error MPE of coordinate measuring machine dimensional measurement, expressed in "micrometers".
4.2 Detection error
The detection error P shall not exceed the maximum allowable detection error MPE. Maximum allowable detection error MPE: for acceptance inspection, specified by the manufacturer:
Re-inspection inspection, specified by the user: | |tt||Detection; The user specifies,
Detection error I\ Maximum allowable detection error MPE. The unit is "micrometer". 4.3 Environmental conditions
Environmental factors that affect the measurement, such as temperature conditions, air humidity and the allowable limits of vibration of the installation site, are specified by the manufacturer for acceptance testing;
Re-testing, by the user.
For acceptance testing or re-testing, the user can freely choose environmental conditions within the specified limits. 4.4 Detection system
Suitable for M, the detection system configuration (probe, probe extension rod, probe orientation, detection system configuration, etc.) limits are specified for: acceptance testing, by the manufacturer Manufacturer's regulations;
…· Single center gauge box in re-test
For acceptance test or re-test, the user can freely choose the configuration of the detection system components within the specified limited range. The error of the shape of the probe needle affects the measurement result and shall be taken into account when passing or failing the standard inspection. 4.5 Operating conditions
When carrying out the tests specified in Chapter 5 of this part, the coordinate measuring machine shall be operated according to the procedures specified in the manufacturer's operating instructions: in particular, the following listed in the manufacturer's operating instructions shall be followed: a) coordinate measuring machine start-up/heating cycle, b) detection system configuration:
c) cleaning procedures of the probe tip and standard ball; d) detection system calibration.
Before calibrating the detection system, the probe needle and standard ball should be cleaned to remove any residual material that may affect the measurement or detection results. 5 Acceptance test and re-test
Acceptance test shall be completed in accordance with the manufacturer's specifications and procedures; re-test shall be completed in accordance with the manufacturer's specifications and procedures. 5.2 Detection error
5.2.1 The principle of the detection error evaluation method is to determine whether the measurement performance of the coordinate measuring machine is within the specified maximum allowable detection error MP by measuring the distance variation from the center of the Gaussian fitting ball to the measuring point. 5.2.2 Measuring equipment
5.2.2.1 Detection ball (diameter not less than 1 cm and not more than 50 cm) The detection ball is equipped with the coordinate measuring machine. The standard used for calibration of the detection system cannot be used for this test. The shape of the detection ball needs to be calibrated, because the shape error will affect the test result. When the test is qualified or not in accordance with the existing standards, it should be taken into account. 2
TB/T16857.2—2006/ISO 10360-2:2001 The test ball shall be placed in a different position from the standard ball used for calibration of the detection system. 5.2.3 Procedure
5.2.3.1 The user shall freely select the position of the probe and the installation position of the test ball within a defined range. It is recommended that the probe be oriented in a manner not to be parallel to any axis of the CMM. NOTE: The orientation of the probe and the choice of mounting position of the test ball can affect the test results. 5.2.3.2 Configure and calibrate the probing system in accordance with the manufacturer's procedures (see 4.4 and 4.5). 5.2.3.3 Position the test ball in accordance with 5.2.2. The test ball should be mounted in a fixed position to minimize errors due to offset. Test the product and record 25 points: the points should be as evenly distributed as possible on the half of the test ball. The position of each point should be determined by the user. 5.2.3.4. According to the regulations, the following detection points are proposed (see Figure 1): - 1 point at the virtual point of the detection ball (determined by the orientation of the probe axis); 22.5 points below the pole (equally spaced); - 8 points 45 below the pole and 22.5 points relative to the previous group (equally spaced); 67.\ below the pole and 22.5\ points relative to the previous group (equally spaced); 50 below the pole (i.e. on the spherical surface that bisects the sphere) and 8 points 22.5 points relative to the previous group (equally spaced). 226
Pole.
Figure 1 Target contact point
5,2. 4. Calculation of test results
Use all 25 measured values to calculate the Gaussian pseudo-golden sphere, and calculate the Gaussian radial distance R from each of the 25 measured values. Calculate the detection error P3
G3/T 16857.2—2006/110360-2:20015.3 Size
5. 3. 1 The principle of the dimension evaluation method is to verify whether the measurement capability of the coordinate measuring machine is within the specified maximum allowable indication error MPE range of the coordinate measuring machine dimension measurement: it is evaluated by comparing the calibration value of 5 physical standards of different sizes with the indication value. In the measurement space of the coordinate measuring machine, the physical standard of the dimension is placed in 7 different positions and orientations, and each is measured 3 times, with a total of 105 measurements.
5.3.2 Measuring equipment
5.3.2.1 The maximum length of the physical standard of the dimension (it is recommended to use a set of measuring steps with a step size of (B/D 6093)) is at least 66% of the diagonal of the coordinate measuring machine measurement space, and its minimum length should not be less than 30 The length of each water standard shall be calibrated and the uncertainty of calibration shall be taken into account when the standard is met or qualified. 5.3.3 Procedure
Use the same product in a specified range and at random to select different positions and orientations of the standard. 5.3.3.1
The choice of position and orientation affects the test procedure 5.3.3.2 Configure and calibrate the detection system according to the manufacturer's specifications (4.4 and 4.5). 5.3.3.3 Perform reciprocating measurements in all 7 different positions and orientations: Bidirectional measurements in any of the 7 positions and orientations: || tt||For the actual measurement,
when it is inspected according to the specification or fails,
the method is introduced
5.3.4 The testing room
calculates the error of each measurement value of 105 times and sends it to the relevant computer
If the coordinate measurement system is repaired, the indication error and system error of the physical object are recommended to be corrected. It is allowed to use the computer to make temperature quality or
take the physical measurement of the physical object to make the temperature correction kinetic energy call thank the situation in the room is called the drawing as GB/T 162-- 2002
value) diagram.
6 Inspection and testing according to specifications
Testing
If the following conditions are met, the performance of the coordinate measuring machine used for the measurement is passed by the method
three measurements: Only the difference between the true values of the physical standard of the dimension inward or inward (the specific size of the specific position and direction)
the manufacturer does not
teach you the total error (E
) indicated by the red PE table in the coordinate measuring machine software when the whole measured is measured. The error of the coordinate measuring machine dimension measurement is not greater than the maximum allowable value error MPE of the coordinate measuring machine dimension measurement avoided by the manufacturer;
- The detection reading error P is greater than the maximum allowable control measurement uncertainty specified by the manufacturer. The measurement uncertainty shall be calculated according to GB/T.8779.1. Among the 35 groups of dimension measurements (5.3.17 different positions and directions, 5 different physical dimensional markers), at most 5 groups are allowed, and one of the indications of three repeated measurements is outside the qualified area. In addition to the qualified (according to GB3/T13779.1), each such scale shall be re-measured 15 times in the corresponding position and direction. If the indication errors of all coordinate measuring machine dimension measurements obtained in 1) re-measurement are within the qualified area (according to GB/T18779.1).1) The performance of the coordinate measuring machine is passed before the test.
6.2 Hydrogen inspection
If the following conditions are met, the performance of the coordinate measuring machine used for measurement is passed: GR/I16857.2-2006/IS0 10360-2:2001 "The estimated error of the coordinate measuring machine dimension measurement is not greater than the maximum allowable indication error MIE: specified by the user;
The detection error P is not greater than the maximum allowable detection error MPHP specified by the user: Re-inspection and testing shall be carried out according to (B/T18779.1 Calculated measurement uncertainty 35 groups of dimensional measurements (according to 5.3.1.7 different positions and 5 different dimensional physical standards) There are at most 5 groups, and 3 of the repeated values of the indication error of the coordinate measuring machine size measurement are allowed to have 1 outside the standard area. Right: Qualified area (according to GB/T1877 9.1) Each such scale is re-measured 10 times in the corresponding position and direction. If the error of all the coordinate measuring machine 8-inch measurements obtained after 10 re-measurements is within the qualified area (according to G13/T18779.1), the performance of the coordinate measuring machine is passed.
7 Application
7.1 Acceptance test
When the supplier and the customer sign a purchase contract:
Maintenance contract
Repair contract
Renovation and upgrading.
Under the circumstances:
GB/T 168 stipulates the maximum allowable indication reading E and the maximum
test.
The supplier is allowed to use MP to measure the maximum measurement position and
7. 2 Re-inspection and testing In the internal quality assurance system of the enterprise, the coordinate measuring machine size measurement can be used to measure the maximum allowable error MPE and MPF agreed upon by the supplier and the headquarters. Re-inspection and testing is used to verify the performance of the coordinate measuring machine. In the internal quality assurance system of the enterprise, simplified re-inspection and testing can be used regularly to check and verify that the coordinate measuring machine meets the two maximum allowable errors MPE and MPF. Probability of rechecking
This part of GE/T16857 See the wide rechecking standard, which can be simplified by reducing the number of measurements performed (see except A). o:
CB/T16857.2-2006/IS010360-2:2001A.1 Intermediate inspection of coordinate measuring machines
(Informative annex)
Intermediate inspection set
It is recommended to conduct regular inspections of non-coordinate measuring machines between periodic rechecks: The inspection intervals should be determined according to the environmental conditions and the required performance of the measurement:
After any major event that affects the performance of the coordinate measuring machine, the machine should be inspected immediately. It is recommended to measure the representative dimensions of physical standards other than physical dimensional standards. The measurement should be carried out immediately after the performance test; the position and orientation of these artificial standards should be recorded and can be reproduced later. According to the measuring task of the measuring machine in use, the most suitable special test piece that can reflect the typical geometric shape elements among the following commonly used data is selected: the test piece has stable dimensions, solid mechanical structure, and has surface roughness that does not significantly affect the measurement uncertainty; a ball platewwW.bzxz.Net
hole:
ball end:
hole;
"can measure the coordinates of the fixed standard ball with the indirect kinematics of the probe needle and ball as the formula: · Annular artificial standard (such as ring gauge)
The material of the artificial standard has a similar A.2 The mid-range inspection of the probe is carried out according to the procedure and calculations specified in 5.2. Since the probing error will vary with the various probe configurations used in practice (e.g. multiple probes and probe extensions), it is recommended that regular inspections be carried out between cycles. The same procedure and calculations can be used for the mid-range inspection of the probe for the same tools as specified in 5.3 Appendix B (Informative Appendix) GB/T16857.2—2006/1SO 10360-2:2001 Position in GS matrix mode
For detailed description of PS matrix mode, please refer to G3/Z203082006. B.1 Information about this part of GB/T16857 and its application This part of GB/T16857 specifies the acceptance test for verifying the coordinate measurement performance of the measuring ruler specified by the manufacturer. This part also specifies the re-testing of the performance of the coordinate measuring machine used to measure dimensions. 3.2 Position in GPS matrix mode
This part of GB/T16857 belongs to the GPS general standard, which affects (size, distance in the GPS general standard matrix) , radius, angle, shape, direction, position, run-out and link 5 of the quasi-standard chain, as shown in Figure B. GPS comprehensive standard
GPS general standard
Following ring number
B.3 related standards
! Shape independent of datum
Shape related to the ancestor
Shape independent of the base
Surface shape related to the base
Circular run-out
Total run-out
Roughness wheel
Waviness profile
Original wheel trace
Surface defect
Related standards are the standards involved in the standard chain shown in Figure 13.1. G/T 16857.2—2006/1SO 10360-2:2001 References ISO 1.0360-3:2000 Product geometry specification (GPS) Coordinate measuring machine acceptance test and recheck test Part 31: Coordinate measuring machine with the axis of the rotary table as the fourth axis GB/T 16857.4 2003 Product geometry specification (GPS) Coordinate measuring machine acceptance test and recheck test Part 27: In-scan measurement Coordinate measuring machine used in mode (ISO10360-4: 20U0, IDT) GB/T16857.5-2004 Technical specification for product geometry (GPS) Acceptance test and re-inspection of coordinate measuring machines 3
Part 5, Verification of coordinate measuring machines using probe detection systems (ISO10360-5: 2000.IDT) [4]
Technical specification for product geometry (GS) General thermal planning (ISO/T! 4633:95, MOD) GB2 20398--2006
Copyright exclusive infringement must be investigated
Book number: 15506:1-28722
G8/T16857.2-2006
Yun bottle Ti jar 17h fine wall pin tendon species year supervision wax
1002-7-09801 05/9002-229891 1/402 Re-inspection and testing In the internal quality assurance system of the enterprise, the coordinate measuring machine size measurement can be used to measure the maximum allowable error MPE and MPF of the coordinate measuring machine agreed upon by the department and the teaching staff. The MPE and MPF can be used in the coordinate performance inspection and the MPE specified by the user can be used. Re-inspection and testing is used for measurement within the enterprise. In the internal quality assurance system of the enterprise, simplified re-inspection and testing can be used regularly to check and verify that the measuring machine meets the two maximum allowable errors MPE and MPF of the coordinate measuring machine. The probability of exceeding the specified requirements is GE/T 16857. This part of the re-inspection test can be simplified by reducing the number of measurements performed (see except A). o:
CB/T16857.2-2006/IS010360-2:2001A.1 Intermediate inspection of coordinate measuring machine
(Informative attachment)
Intermediate inspection set
It is recommended to conduct regular inspection of non-coordinate measuring machine between periodic re-inspections: The inspection interval should be determined according to the environmental conditions and the required performance of the measured object:
After any major event that affects the performance of the coordinate measuring machine, the machine should be inspected immediately. It is recommended to measure the representative dimensions of physical standards other than the physical dimensional standards. The measurement should be carried out immediately after the performance test; the position and orientation of these artificial standards should be recorded and can be reproduced later. According to the measuring task of the measuring machine in use, the most suitable special test piece that can reflect the typical geometric shape elements among the following commonly used data is selected: the test piece has stable dimensions, solid mechanical structure, and has surface roughness that does not significantly affect the measurement uncertainty; a ball plate
hole:
ball end:
hole;
"can measure the coordinates of the fixed standard ball with the indirect kinematics of the probe needle and ball as the formula: · Annular artificial standard (such as ring gauge)
The material of the artificial standard has a similar A.2 The mid-range inspection of the probe is carried out according to the procedure and calculations specified in 5.2. Since the probing error will vary with the various probe configurations used in practice (e.g. multiple probes and probe extensions), it is recommended that regular inspections be carried out between cycles. The same procedure and calculations can be used for the mid-range inspection of the probe for the same tools as specified in 5.3 Appendix B (Informative Appendix) GB/T16857.2—2006/1SO 10360-2:2001 Position in GS matrix mode
For detailed description of PS matrix mode, please refer to G3/Z203082006. B.1 Information about this part of GB/T16857 and its application This part of GB/T16857 specifies the acceptance test for verifying the coordinate measurement performance of the measuring ruler specified by the manufacturer. This part also specifies the re-testing of the performance of the coordinate measuring machine used to measure dimensions. 3.2 Position in GPS matrix mode
This part of GB/T16857 belongs to the GPS general standard, which affects (size, distance in the GPS general standard matrix) , radius, angle, shape, direction, position, run-out and link 5 of the quasi-standard chain, as shown in Figure B. GPS comprehensive standard
GPS general standard
Following ring number
B.3 related standards
! Shape independent of the datum
Shape related to the ancestor
Shape independent of the base
Surface shape related to the base
Circular run-out
Total run-out
Roughness wheel
Waviness profile
Original wheel trace
Surface defect
Related standards are the standard stalls involved in the standard chain shown in Figure 13.1. G/T 16857.2—2006/1SO 10360-2:2001 References ISO 1.0360-3:2000 Product geometry specification (GPS) Coordinate measuring machine acceptance test and recheck test Part 31: Coordinate measuring machine with the axis of the rotary table as the fourth axis GB/T 16857.4 2003 Product geometry specification (GPS) Coordinate measuring machine acceptance test and recheck test Part 27: In-scan measurement Coordinate measuring machine used in mode (ISO10360-4: 20U0, IDT) GB/T16857.5-2004 Technical specification for product geometry (GPS) Acceptance test and re-inspection of coordinate measuring machines 3
Part 5, Verification of coordinate measuring machines using probe detection systems (ISO10360-5: 2000.IDT) [4]
Technical specification for product geometry (GS) General thermal planning (ISO/T! 4633:95, MOD) GB2 20398--2006
Copyright exclusive infringement must be investigated
Book number: 15506:1-28722
G8/T16857.2-2006
Yun bottle Ti jar 17h fine wall pin tendon species year supervision wax
1002-7-09801 05/9002-229891 1/402 Re-inspection and testing In the internal quality assurance system of the enterprise, the coordinate measuring machine size measurement can be used to measure the maximum allowable error MPE and MPF of the coordinate measuring machine agreed upon by the department and the teaching staff. The MPE and MPF can be used in the coordinate performance inspection and the MPE specified by the user can be used. Re-inspection and testing is used for measurement within the enterprise. In the internal quality assurance system of the enterprise, simplified re-inspection and testing can be used regularly to check and verify that the measuring machine meets the two maximum allowable errors MPE and MPF of the coordinate measuring machine. The probability of exceeding the specified requirements is GE/T 16857. This part of the re-inspection test can be simplified by reducing the number of measurements performed (see except A). o:
CB/T16857.2-2006/IS010360-2:2001A.1 Intermediate inspection of coordinate measuring machine
(Informative attachment)
Intermediate inspection set
It is recommended to conduct regular inspection of non-coordinate measuring machine between periodic re-inspections: The inspection interval should be determined according to the environmental conditions and the required performance of the measured object:
After any major event that affects the performance of the coordinate measuring machine, the machine should be inspected immediately. It is recommended to measure the representative dimensions of physical standards other than the physical dimensional standards. The measurement should be carried out immediately after the performance test; the position and orientation of these artificial standards should be recorded and can be reproduced later. According to the measuring task of the measuring machine in use, the most suitable special test piece that can reflect the typical geometric shape elements among the following commonly used data is selected: the test piece has stable dimensions, solid mechanical structure, and has surface roughness that does not significantly affect the measurement uncertainty; a ball plate
hole:
ball end:
hole;
"can measure the coordinates of the fixed standard ball with the indirect kinematics of the probe needle and ball as the formula: · Annular artificial standard (such as ring gauge)
The material of the artificial standard has a similar A.2 The mid-range inspection of the probe is carried out according to the procedure and calculations specified in 5.2. Since the probing error will vary with the various probe configurations used in practice (e.g. multiple probes and probe extensions), it is recommended that regular inspections be carried out between cycles. The same procedure and calculations can be used for the mid-range inspection of the probe for the same tools as specified in 5.3 Appendix B (Informative Appendix) GB/T16857.2—2006/1SO 10360-2:2001 Position in GS matrix mode
For detailed description of PS matrix mode, please refer to G3/Z203082006. B.1 Information about this part of GB/T16857 and its application This part of GB/T16857 specifies the acceptance test for verifying the coordinate measurement performance of the measuring ruler specified by the manufacturer. This part also specifies the re-testing of the performance of the coordinate measuring machine used to measure dimensions. 3.2 Position in GPS matrix mode
This part of GB/T16857 belongs to the GPS general standard, which affects (size, distance in the GPS general standard matrix) , radius, angle, shape, direction, position, run-out and link 5 of the quasi-standard chain, as shown in Figure B. GPS comprehensive standard
GPS general standard
Following ring number
B.3 related standards
! Shape independent of the datum
Shape related to the ancestor
Shape independent of the base
Surface shape related to the base
Circular run-out
Total run-out
Roughness wheel
Waviness profile
Original wheel trace
Surface defect
Related standards are the standard stalls involved in the standard chain shown in Figure 13.1. G/T 16857.2—2006/1SO 10360-2:2001 References ISO 1.0360-3:2000 Product geometry specification (GPS) Coordinate measuring machine acceptance test and recheck test Part 31: Coordinate measuring machine with the axis of the rotary table as the fourth axis GB/T 16857.4 2003 Product geometry specification (GPS) Coordinate measuring machine acceptance test and recheck test Part 27: In-scan measurement Coordinate measuring machine used in mode (ISO10360-4: 20U0, IDT) GB/T16857.5-2004 Technical specification for product geometry (GPS) Acceptance test and re-inspection of coordinate measuring machines 3
Part 5, Verification of coordinate measuring machines using probe detection systems (ISO10360-5: 2000.IDT) [4]
Technical specification for product geometry (GS) General thermal planning (ISO/T! 4633:95, MOD) GB2 20398--2006
Copyright exclusive infringement must be investigated
Book number: 15506:1-28722
G8/T16857.2-2006
Yun bottle Ti jar 17h fine wall pin tendon species year supervision wax
1002-7-09801 05/9002-229891 1/402 Position in GPS matrix mode
This part of GB/T16857 belongs to GPS general standard, which affects (in GPS general standard matrix, size, distance, radius, angle, shape, direction, position, run-out and link 5 of quasi-standard chain, as shown in Figure B. GPS comprehensive standard
GPS general standard
Follow-up ring number
B.3 Related standards
! Shape not related to datum
Shape related to ancestor
Shape not related to base
Surface shape related to base
Circular run-out
Total run-out
Roughness wheel
Waviness profile
Original wheel track
Surface defect
Related standards are the standard stalls involved in the standard chain shown in Figure 13.1. G/T 16857.2—2006/1SO 10360-2:2001 References ISO 1.0360-3:2000 Product geometry specification (GPS) Acceptance test and recheck test of coordinate measuring machines Part 31: Coordinate measuring machines with the axis of the rotary table as the fourth axis GB/T 16857.4 2003 Product geometry specification (GPS) Acceptance test and recheck test of coordinate measuring machines Part 27: Coordinate measuring machines used in scanning measurement mode Measuring machine (ISO10360-4: 2000, IDT) GB/T16857.5-2004 Technical specification for product geometry (GPS) Acceptance test and re-test of coordinate measuring machine 3
Part 5, Verification of measuring machine using probe detection system (ISO10360-5: 2000. IDT) [4]
Technical specification for product geometry (GS) General thermal design (ISO/T! 4633: 95, MOD) GB2 20398--2006
Copyright exclusive infringement must be investigated
Book number: 15506: 1-28722
G8/T16857.2-2006
Yunping Ti Can 17h fine wall pin tendon species year supervision wax
1002-7-09801 05/9002-229891 1/402 Position in GPS matrix mode
This part of GB/T16857 belongs to GPS general standard, which affects (in GPS general standard matrix, size, distance, radius, angle, shape, direction, position, run-out and link 5 of quasi-standard chain, as shown in Figure B. GPS comprehensive standard
GPS general standard
Follow-up ring number
B.3 Related standards
! Shape not related to datum
Shape related to ancestor
Shape not related to base
Surface shape related to base
Circular run-out
Total run-out
Roughness wheel
Waviness profile
Original wheel track
Surface defect
Related standards are the standard stalls involved in the standard chain shown in Figure 13.1. G/T 16857.2—2006/1SO 10360-2:2001 References ISO 1.0360-3:2000 Product geometry specification (GPS) Acceptance test and recheck test of coordinate measuring machines Part 31: Coordinate measuring machines with the axis of the rotary table as the fourth axis GB/T 16857.4 2003 Product geometry specification (GPS) Acceptance test and recheck test of coordinate measuring machines Part 27: Coordinate measuring machines used in scanning measurement mode Measuring machine (ISO10360-4: 2000, IDT) GB/T16857.5-2004 Technical specification for product geometry (GPS) Acceptance test and re-test of coordinate measuring machine 3
Part 5, Verification of measuring machine using probe detection system (ISO10360-5: 2000. IDT) [4]
Technical specification for product geometry (GS) General thermal design (ISO/T! 4633: 95, MOD) GB2 20398--2006
Copyright exclusive infringement must be investigated
Book number: 15506: 1-28722
G8/T16857.2-2006
Yunping Ti Can 17h fine wall pin tendon species year supervision wax
1002-7-09801 05/9002-229891 1/40
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