2011年11月11日星期五

Update of standards for dial gauges and actual status - November 2011

IMPORTANT UPDATE RELEASE nr. 4 Thread gauges


Actual release (November 2011) includes:

• ISO Metric threads, DIN ISO 1502 (DIN 13)
• ISO Metric threads, ANSI B1.16M
• Metric ISO Trapezoidal threads, DIN 103
• Unified threads and thread gauges, ANSI/ASME B1.1 u. B1.2
• Thread gauges for Unified threads, BS 919 (Part 1)
• Gauges for pipe threads, DIN ISO 228
• Steel conduit threads, DIN 40430, 40431
• Knuckle threads, DIN 405
• Buttress threads and  gauges,  DIN 513 /Factory standard
• Gauges for wire thread inserts for metric threads, DIN 8140
• Gauges for screw threads of Whitworth form, British standard BS 84 / BS 919 (Part 2)
• NPSM pipe threads,  ANSI/ASME 1.20.1
• Aerospace MJ threads, DIN ISO 5855
• Gauges for Metric and Unified thread inserts, Böllhoff factory standard
• Threads for valves and tyres,  DIN 7756 and ETRTO V.7
• Metric threads, NF E 03-152/153 (GE40-010N)
• Unified  threads, CNOMO GE40-008N (PSA, Renault)
• ACME threads, ANSI B1.5 - 1988
• Stub-ACME threads, ANSI B1.8 - 1988
• Buttress threads 7°/45°, ANSI B1.9 - 1973
• Hot-dip galvanized threads, DIN ISO 965:2002

Update of standards for spline gauges and actual status - November 2011

IMPORTANT UPDATE RELEASE nr. 7 spline gauges

Standards for spline gauges


Spline gauges are used for inspection of splined shafts and Involute and straight spline Shafts. Updated formulas include now following standards (November 2011):

DIN 5480 (March 2006)
DIN 5480 (September 1974)
DIN 5481:2005-06
DIN 5481 (January 1952)
DIN 5482 (March 1973)
ANSI B92.1-1996
ANSI B92.2M-1980

Update of standards for verniers and actual status - November 2011

IMPORTANT UPDATE RELEASE nr. 5 Verniers

No significant changes here.

• DIN 862 - 1988
• British Standard BS 887
• French Standard NF E-11-091

Update of standards for spline gauges and actual status - November 2011

IMPORTANT UPDATE RELEASE nr. 7 spline gauges

Standards for spline gauges


Spline gauges are used for inspection of splined shafts and Involute and straight spline Shafts. Updated formulas include now following standards (November 2011):

DIN 5480 (March 2006)
DIN 5480 (September 1974)
DIN 5481:2005-06
DIN 5481 (January 1952)
DIN 5482 (March 1973)
ANSI B92.1-1996
ANSI B92.2M-1980

Update of standards for thread gauges (plugs and rings) and actual status - November 2011

IMPORTANT UPDATE RELEASE nr. 6 Taper thread gauges



A threaded pipe is a pipe with screw-threaded ends for assembly. The threaded pipes used in some plumbing installations for the delivery of gases or fluids under pressure have a threaded section that is slightly conical (in contrast to the cylindrical section commonly found on bolts and leadscrews). The seal provided by a threaded pipe joint depends upon the labyrinth seal created by the threads; upon a positive seal between the threads created by the deformation of the threads when they are tightened to the proper torque; and sometimes on the presence of a sealing coating, such as thread seal tape ("Teflon tape"), or a liquid or paste pipe sealant such as pipe dope. Accurate threads are known as "dry fit" or "dry seal" meaning that no sealant is required for a gas-tight seal. Such threads are needed where the sealant would contaminate or react with the media inside the piping (i.e. oxygen).
Dryseal pipe threads gauges ASME B1.20.5 have been recently added.
Updated formulas include now following standards:

NPT American Standard Pipe Taper Thread
NPSC American Standard Straight Coupling Pipe Thread
NPTR American Standard Taper Railing Pipe Thread
NPSM American Standard Straight Mechanical Pipe Thread
NPSL American Standard Straight Locknut Pipe Thread
NPTF American Standard Pipe Thread Tapered (Dryseal)
BSPP British Standard Pipe Thread Parallel
BSPT British Standard Pipe Thread Tapered

Significative updates have been made here, especially or MJ threads, often referred to as “J” threads, mainly used in the aerospace industry, and dryseal thread B1.20.5, the full list at today (November 2011) of supported standards is:

Pipe threads for tubes and fittings BS21:1985
Pipe threads ANSI/ASME B1.20.1-1983 (NPT)
Pipe threads ISO 7/2 - 1982(E)
Pipe threads ISO 7/2:2000 (EN 10226:2005)
Pipe threads DIN 2999
Whitworth pipe threads DIN 3858/Factory standard
Pipe threads DIN 158
Gas valve threads DIN 477
Dryseal pipe threads ASME B1.20.5
Taper pipe threads JIS B 0253 -1985
ISO metric threads DIN ISO 965:1998
Trapezoidical threads DIN 103:1997
Thread tapes according to DIN 802
Unified threads ANSI/ASME B1.1-1989(R2001)/B1.2
Unified threads ANSI/ASME B1.1-2003 / ASME B1.2
UNJ Aerospace threads ISO 3161:1999 (ASME B1.15)
Pipe threads according to ISO 228:2000
Steel conduit threads DIN 40431:1972
Whitworth threads acc.BS 84:2007, BS 919-2:2007
Pipe threads according to DIN 259 (old)
Metrical HELICOIL threads BOELLHOFF standard
Knuckle threads according to DIN 405:1997
Unified threads ANSI B1.1-1989/BS 919-1:2007
Unified threads ANSI B1.1-2003/BS 919-1:2007
Buttress threads DIN 513/Factory standard
MJ threads DIN ISO 5855 : 2009
Bolt (external) screw thread for transition fits tol. zone (DIN 13, part 51)
Unified HELICOIL threads Boellhoff standard
Unified HELICOIL threads MS 33537-1994
NPSM Cyl.pipe threads ANSI/ASME B1.20.1-1983 (2001)
NPSF Cyl. Dryseal Pipe Threads ANSI B1.20.3-1976
Threads for valves DIN 7756 - February 1979
Threads for valves ETRTO V.7 - 1999
Gages for ISO metric threads ANSI B1.16-M
Gages for ISO metric threads BS919-3:2007
Metric M screw threads NF E 03-152/153
Unified threads French standard CNOMO GE40-008N
ACME screw threads ASME/ANSI B1.5-1997
Stub ACME screw threads ASME/ANSI B1.8-1988
Buttress Threads 7 deg. 45 deg. ANSI B1.9-1973
Metric thread inserts  DIN 8140:1999
Galvanized threads DIN ISO 965 (Parts 4,5):2002
Thread setting gauges DIN 2241
Threads for bicycles DIN 79012:1960
Thread gauges according to "VW Norm 13003"
Thread gauges according DIN 11 (old standard, still common)
Gas cylinder connections DIN 477 (Part 1)
Thread gauges according Swiss Standard NIHS 60-30
ACME threads with clearance for rail vehicles DIN 263:2000
Buttress threads DIN 20401:1984 / Factory standard
Cycle threads "BSC" BS 811:1950 / BS 919-2:2007

Update of standards for thread gauges (plugs and rings) and actual status - November 2011

IMPORTANT UPDATE RELEASE nr. 6 Taper thread gauges



A threaded pipe is a pipe with screw-threaded ends for assembly. The threaded pipes used in some plumbing installations for the delivery of gases or fluids under pressure have a threaded section that is slightly conical (in contrast to the cylindrical section commonly found on bolts and leadscrews). The seal provided by a threaded pipe joint depends upon the labyrinth seal created by the threads; upon a positive seal between the threads created by the deformation of the threads when they are tightened to the proper torque; and sometimes on the presence of a sealing coating, such as thread seal tape ("Teflon tape"), or a liquid or paste pipe sealant such as pipe dope. Accurate threads are known as "dry fit" or "dry seal" meaning that no sealant is required for a gas-tight seal. Such threads are needed where the sealant would contaminate or react with the media inside the piping (i.e. oxygen).
Dryseal pipe threads gauges ASME B1.20.5 have been recently added.
Updated formulas include now following standards:

NPT American Standard Pipe Taper Thread
NPSC American Standard Straight Coupling Pipe Thread
NPTR American Standard Taper Railing Pipe Thread
NPSM American Standard Straight Mechanical Pipe Thread
NPSL American Standard Straight Locknut Pipe Thread
NPTF American Standard Pipe Thread Tapered (Dryseal)
BSPP British Standard Pipe Thread Parallel
BSPT British Standard Pipe Thread Tapered

Significative updates have been made here, especially or MJ threads, often referred to as “J” threads, mainly used in the aerospace industry, and dryseal thread B1.20.5, the full list at today (November 2011) of supported standards is:

Pipe threads for tubes and fittings BS21:1985
Pipe threads ANSI/ASME B1.20.1-1983 (NPT)
Pipe threads ISO 7/2 - 1982(E)
Pipe threads ISO 7/2:2000 (EN 10226:2005)
Pipe threads DIN 2999
Whitworth pipe threads DIN 3858/Factory standard
Pipe threads DIN 158
Gas valve threads DIN 477
Dryseal pipe threads ASME B1.20.5
Taper pipe threads JIS B 0253 -1985
ISO metric threads DIN ISO 965:1998
Trapezoidical threads DIN 103:1997
Thread tapes according to DIN 802
Unified threads ANSI/ASME B1.1-1989(R2001)/B1.2
Unified threads ANSI/ASME B1.1-2003 / ASME B1.2
UNJ Aerospace threads ISO 3161:1999 (ASME B1.15)
Pipe threads according to ISO 228:2000
Steel conduit threads DIN 40431:1972
Whitworth threads acc.BS 84:2007, BS 919-2:2007
Pipe threads according to DIN 259 (old)
Metrical HELICOIL threads BOELLHOFF standard
Knuckle threads according to DIN 405:1997
Unified threads ANSI B1.1-1989/BS 919-1:2007
Unified threads ANSI B1.1-2003/BS 919-1:2007
Buttress threads DIN 513/Factory standard
MJ threads DIN ISO 5855 : 2009
Bolt (external) screw thread for transition fits tol. zone (DIN 13, part 51)
Unified HELICOIL threads Boellhoff standard
Unified HELICOIL threads MS 33537-1994
NPSM Cyl.pipe threads ANSI/ASME B1.20.1-1983 (2001)
NPSF Cyl. Dryseal Pipe Threads ANSI B1.20.3-1976
Threads for valves DIN 7756 - February 1979
Threads for valves ETRTO V.7 - 1999
Gages for ISO metric threads ANSI B1.16-M
Gages for ISO metric threads BS919-3:2007
Metric M screw threads NF E 03-152/153
Unified threads French standard CNOMO GE40-008N
ACME screw threads ASME/ANSI B1.5-1997
Stub ACME screw threads ASME/ANSI B1.8-1988
Buttress Threads 7 deg. 45 deg. ANSI B1.9-1973
Metric thread inserts  DIN 8140:1999
Galvanized threads DIN ISO 965 (Parts 4,5):2002
Thread setting gauges DIN 2241
Threads for bicycles DIN 79012:1960
Thread gauges according to "VW Norm 13003"
Thread gauges according DIN 11 (old standard, still common)
Gas cylinder connections DIN 477 (Part 1)
Thread gauges according Swiss Standard NIHS 60-30
ACME threads with clearance for rail vehicles DIN 263:2000
Buttress threads DIN 20401:1984 / Factory standard
Cycle threads "BSC" BS 811:1950 / BS 919-2:2007

Update of standards for spline gauges and actual status - November 2011

IMPORTANT UPDATE RELEASE nr. 7 spline gauges

Standards for spline gauges


Spline gauges are used for inspection of splined shafts and Involute and straight spline Shafts. Updated formulas include now following standards (November 2011):

DIN 5480 (March 2006)
DIN 5480 (September 1974)
DIN 5481:2005-06
DIN 5481 (January 1952)
DIN 5482 (March 1973)
ANSI B92.1-1996
ANSI B92.2M-1980

Update of standards for dial gauges and actual status - November 2011

IMPORTANT UPDATE RELEASE nr. 4 Thread gauges


Actual release (November 2011) includes:

• ISO Metric threads, DIN ISO 1502 (DIN 13)
• ISO Metric threads, ANSI B1.16M
• Metric ISO Trapezoidal threads, DIN 103
• Unified threads and thread gauges, ANSI/ASME B1.1 u. B1.2
• Thread gauges for Unified threads, BS 919 (Part 1)
• Gauges for pipe threads, DIN ISO 228
• Steel conduit threads, DIN 40430, 40431
• Knuckle threads, DIN 405
• Buttress threads and  gauges,  DIN 513 /Factory standard
• Gauges for wire thread inserts for metric threads, DIN 8140
• Gauges for screw threads of Whitworth form, British standard BS 84 / BS 919 (Part 2)
• NPSM pipe threads,  ANSI/ASME 1.20.1
• Aerospace MJ threads, DIN ISO 5855
• Gauges for Metric and Unified thread inserts, Böllhoff factory standard
• Threads for valves and tyres,  DIN 7756 and ETRTO V.7
• Metric threads, NF E 03-152/153 (GE40-010N)
• Unified  threads, CNOMO GE40-008N (PSA, Renault)
• ACME threads, ANSI B1.5 - 1988
• Stub-ACME threads, ANSI B1.8 - 1988
• Buttress threads 7°/45°, ANSI B1.9 - 1973
• Hot-dip galvanized threads, DIN ISO 965:2002

Update of standards for plain gauges and actual status - November 2011

IMPORTANT UPDATE RELEASE nr. 3 Plain gauges

New releases have ben made for DIN 2250-1 and BS 969, as well as for Volkswagen standard.

Actual release (November 2011) includes:

• DIN-ISO 286 – 1
• DIN-ISO 286 – 2
• French Standard NF E 02-202 (GE40-001N)
• Master rings, BS 4064 : 1966
• Master rings BS 4065 : 1966
• Master rings, French Standard  NF E 11-011
• ISO 286-2 (js2)
• DIN ISO 286 (DIN 7150:2007)
• DIN 2250-1 : October 2008
• BS 969:2008
• ANSI/ASME B89.1.6M - 1984
• BS 4064 (Metric) : 1966
• BS 4065 (Inch) : 1966
• NF E 02-202 (GE40-001N)
• NF E 11-011
• VW 190206
• VW 193260

Update of standards for dial gauges and actual status - November 2011

IMPORTANT UPDATE RELEASE nr. 2 Dial gauges

No changes for DIN 878 (Oct 1983), DIN 879 (Jun 1999), DIN 2270 (1985) (Germany), UNI 4180, UNI 9954 (Italy),  IS : 2967 (India) or NF-E-11 (France).
New standards have been defined for inductive gauges and for edge finder gauges. Recent added formulas for calculations of dial gauges refer to:

New standards (India) for dial gauges IS : 2092-1983 and lever dial gauges IS : 11498-1985
New standards have been defined for edge  finding gauges.
New standard for digital gauges NF E11-056 (France)
NF XP E11-53 digital (France)
India IS : 2092-1983
India IS : 11498-1985
United States ASME/ANSI B89.1.10M - 2001
Japan JIS B7503
Japan JMAS 2001
Korea KS B5206
Korea JIS B7533
Korea KS B5238

A new procedure defines the maximum tolerance admitted every 10 divisions. Before it was only for 1, 5 graduation, 50% of one revolution and 100% of one revolution.
A new procedure contains evaluation and tolerancing of both sensitivity and  linearity in the measuring range.
In particular, there is now a limitation of the linearity, after adjustment of sensitivity.
ANSI/ASME introduced repeatibiliy check at 25%, 50% and 75% of measuring range, and a set of tolerances after the 1.turn, between 2 and 10 turns,  between 10 and 20 turns, and for more than 20 turns.
Analysis of deviation is performed, in both directions (positive or negative deviation) after one turn, after two turns, between 2 and 10 turns, between 10 and 20 turns, and for more than 20 turns.

Korean norms introduces a set of tolerances for short or long range, and a specific related tolerance for T neighboring.  Also the increment for short and long range is standardized.

Actual release (November 2011) includes:

• Dial gauges, DIN 878 - 1983
• Dial indicators, DIN 879 - 1999
• Dial test indicators, DIN 2270 - 1985
• Dial gauges,  ASME/ANSI B89.1.10M
• Dial gauges, French Standard NF E 011-50
• Dial test indicators, French Standard XP E 11-053 : 2000
• Dial gauges, Japanese Standard JIS B 7503-1992
• Dial gauges, British Standard BS 907-1965
• Dial test indicators, British Standard BS 2795-1981
• Dial gauges and Test indicators, Australian Standard AS 2103
• Dial gauges (0.01 mm Graduation), Korean Standard KS B 5206-1984
• Dial gauges (0.001 mm Grad.), Korean Standard KS B 5207-1984
• Dial test indicators, Korean  Standard KS B 5238-1976

Update of standards for micrometers and actual status - November 2011

IMPORTANT UPDATE RELEASES

There have been recently updates in calibration standards, involving different types of length measuring instruments, such as:

1. micrometers
2. dial gauges
3. plain gauges (bth plug and ring gauges)
4. parallel thread gauges (bth plug and ring gauges)
5. verniers
6. taper thread gauges
7. spline gauges

It is important to update the calibration procedures used by calibration labs and metrology departments, if in-site calibration is performed.
Let's have a look here at the most relevant changes.

These BS standard have been reviewed.
previous standard BS 870:1950, new release is BS 870:2008
previous standard BS 6468:1984, new release is  BS 6468:2008
previous standard BS 959:1950,  new release is BS 959:2008

The BS update also refers to extensions according to following standards:

previous standard BS 870:1950, new release is BS 870:2008
previous standard BS 6468:1984, new release is BS 870:2008
previous standard BS 959:1950, new release is BS 959:2008

Following standards for extensions have been added, they were not previously included:

DIN 863-1:1999
DIN 863-2:1999
IS:2967-1983(1998)
DIN 863-2:1999
NF E 11-090 (December 1993)
NF E 11-097 (February 1998)

Actual release (November 2011) includes:

• Micrometers (any type), DIN 863 – 1999 (Part 1-4)
• External micrometers, British Standard BS 870-2008 (has been updated)
• Internal micrometers, British Standard BS 959-2008 (has been updated)
• Depth micrometers, British Standard BS 6468-2008 (has been updated)
• Micrometer heads, British Standard BS 1734 : 1951
• Micrometers (any type), Federal Specification (USA) GGG-C105 C–1987
• External micrometers, Australian Standard AS 2102
• Internal micrometers, Australian Standard AS 2101 : 1978

2011年6月15日星期三

Feanor paper at Airtec 2001 Conference - Frankfurt 2-4 November 2011



6th International Conference “Supply on the wings” 

The International „Conference Supply on the wings“ takes place for the sixth time, November 2 - 4, 2011 in conjunction with AIRTEC. Chairman of the conference is also this year Professor Dr Ing. Richard Degenhardt, Private University of Applied Sciences PFH), Göttingen and German Aerospace Center (DLR). 
This year the future-oriented specialised conference for the aerospace supply chain is under the title "Aerospace - The global innovation driven" and will be again an optimal combination of lectures from industry and science and thus connecting practice and science in a perfect way. It offers excellent opportunities to exchange intensively knowledge, experience and information and to network with renowned experts from industry, governmental institutions, research centres, scientific institutions and universities from the international aerospace sector.
Feanor contribution refers to NDT technology for frame structures with X-Ray diffraction. The purpose of shot peening (blasting) process is the induction of residual compression stress on the surface of components subject to fatigue loads. This is obtained impacting a surface with shots (round metallic, glass, or ceramic particles) with a force sufficient to create plastic deformation. It is similar to sandblasting, except that it operates by the mechanism of plasticity rather than abrasion. This process has been used for many years on special steel automotive (shift gears, connecting rods and suspension components) and aerospace components, in Titanium alloys and light alloy steel.
The characterization of the shot peening process is defined by specific parameters, according to legislation, such as the intensity (expressed in Almen), the diameter of the particles and the degree of coverage. When used on components made of a material different from the Almen specimen (steel), the stress field in the component structure cannot be easily estimated. In that particular case we rely on bibliography for the definition of the process parameters. By use of X-ray diffraction with a new type of instrument, the authors were able to measure the real tensile stress induced by shot peening, carried out with two different parameters on aeronautical structural components in Aluminum alloys.

2011年5月20日星期五

International Metrology Day 20 May 2011

International Metrology Day 20 May 2011. Feanor OÜ awarded in in Metrology Forum (Moskow VVC) for ‘Research and Development on Software for Calibration and Metrology’

Today 20 May 2011 is the International Metrology Day and there was no better way to celebrate it than by receiving an official recognition by the Federal Agency of Technology and Metrology of the Ministry of Production of the Russian Federation.
The award acknowledges Feanor OU for ‘Research and Development on Software for Calibration and Metrology’ and was presented to Feanor CEO Luca Giorgio Bochese by the Ministry of Production of the Russian Federation, during the International Metrology  Symposium held in Moskow VVC from 16 to 19 May.


There are a number of projects we are involved in at the moment, including measurement of special gears (elliptical), improvement of calibration for large machine tools and CMM (coordinate measuring machines), NDT (non-destructive) inspection equipment for applications in chemical equipment, nuclear facilities, shipbuilding (high pressures) and aerospace (extremely low pressures). This award is the second recognition, after VTTV Omsk in 2009, we ever received in Russia, and confirms that our research and our products have a good chance to contribute to the modernization and continuous improvement of the metrological and technical infrastructure in high precision local manufacturing companies. 

The forum was a success, particularly because of the high level contacts we have generated and fostered with Stankin Institute, Rostest, ROSATOM SNIIP, RUSNANO (Nanotechnology), VNIIM (Metrology Institute) and a number of Technical Universities and Metrology Institutes in different countries and regions, including Kazakhstan, Kazan, Ukraine, Tomsk, Novosibirsk. 

2011年4月9日星期六

Innovation in Measurement of Residual Stress

Feanor recently developed a portable and compact X-ray diffractometer for XRD, which allows residual stress measurement on-the-field.
XRD (X-Ray Diffraction) technique for residual stress measurement is a technique still known and used in university laboratories.
A particular application on inspection of a welding on a petrochemical reactor will be the subject of a scientific paper, being presented at 7th International Symposium on Precision Engineering Measurements and Instrumentation ( ISPEMI2011), held by the School of Instrument Science and Opto-electronic Engineering of Hefei University of Technology, China http://ispemi.hfut.edu.cn


Fig.1: Diffractometer

The device measures X-ray diffraction generated by electrons inside the anticathode atoms when hit by a flow of high speed electrons, identifying peaks of intensity related to wavelengths related to the anticathode atoms. As an example, if a chrome anticathode is hit with a band of electrons, having energy above the threshold value, it will emit characteristic X rays with a wavelength of about 0.229 nm. A cobalt anticathode will emit a characteristic radiation with a wavelength of about 0.179 nm. When the material irradiated is crystalline, as in the case of metals, the waves diffused will interfere with each other giving a diffraction spectrum.
These re-emitted wave fields interfere with each other either constructively or destructively (overlapping waves either add together to produce stronger peaks or subtract from each other to some degree), producing a diffraction pattern on a detector. The resulting wave interference pattern is the basis of diffraction analysis, called 'Bragg diffraction', and using the related Bragg's Law we are able to relate this information to the tensile stress field of the crystalline structure of the inspected material.










Fig.2: Bragg’s interference

The picture shows the evaluation of inside tensile stress on a welded joint, on a petrochemical reactor, to inspect and verify the effect of the heat treatment. After heat treatment, the surfaces had been sand blasted before painting. The sand blasting process modified and induced a residual stress on the surface, different from the inside. For this reason it was necessary to remove the modified layer using an electrochemical etching, in order to inspect the stress field at different layers without inducing any modification. 













Fig. 3: Testing the petrochemical reactor surface near the welding joint

The paper shows how X-Ray diffraction can be used as non destructive technology to evaluate the impact of stress relief after heat treatment on large surfaces, when not feasible or possible to extract a sample for testing. Well, strictly speaking and according to picture 4, it cannot be considered as 100% non destructive, but its impact is anyway much less invasive, compared to other traditional systems (hole drilling).


Fig. 4: Final lookout of the inspected surface
  
This new equipment will also participate in the competition within the 7th Moskow  International Forum and Metrology Symposium (MetrolExpo) in May 2011, under the category 'Quality Mark for diagnostics and non-destructive equipment' http://www.metrol.expoprom.ru/en/