GB1584671A – Method of magnetic inspection and apparatus therefor
– Google Patents
GB1584671A – Method of magnetic inspection and apparatus therefor
– Google Patents
Method of magnetic inspection and apparatus therefor
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Publication number
GB1584671A
GB1584671A
GB23393/77A
GB2339377A
GB1584671A
GB 1584671 A
GB1584671 A
GB 1584671A
GB 23393/77 A
GB23393/77 A
GB 23393/77A
GB 2339377 A
GB2339377 A
GB 2339377A
GB 1584671 A
GB1584671 A
GB 1584671A
Authority
GB
United Kingdom
Prior art keywords
alternating
direct current
current
pulsed
workpiece
Prior art date
1976-06-04
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired
Application number
GB23393/77A
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Babcock and Wilcox Co
Original Assignee
Babcock and Wilcox Co
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
1976-06-04
Filing date
1977-06-02
Publication date
1981-02-18
1977-06-02
Application filed by Babcock and Wilcox Co
filed
Critical
Babcock and Wilcox Co
1981-02-18
Publication of GB1584671A
publication
Critical
patent/GB1584671A/en
Status
Expired
legal-status
Critical
Current
Links
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Classifications
G—PHYSICS
G01—MEASURING; TESTING
G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
G01N27/00—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
G01N27/72—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating magnetic variables
G01N27/82—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating magnetic variables for investigating the presence of flaws
G01N27/83—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating magnetic variables for investigating the presence of flaws by investigating stray magnetic fields
G01N27/84—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating magnetic variables for investigating the presence of flaws by investigating stray magnetic fields by applying magnetic powder or magnetic ink
G—PHYSICS
G01—MEASURING; TESTING
G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
G01N27/00—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
G01N27/72—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating magnetic variables
Description
PATENT SPECIFICATION ( 11) 1 584 671
( 21) Application No 23393/77 ( 22) Filed 2 Jun1977 ( 19)( “C’ ( 31) Convention Application No 693021 ( 32) Filed 4 Jun 1976 in a ( 33) United States of America (US) X ( 44) Complete Specification Published 18 Feb 1981 n ( 51) INT CL 3 GO O N 27/84 ( 52) Index at Acceptance Gi N 19 B 2 G 6 19 H 1 A 19 H 1 X ( 72) Inventors: AMOS EARL HOLT WILLIAM EUGENE LAWRIE ALBERT STINGEL BIRKS ( 54) IMPROVEMENTS IN METHOD OF MAGNETIC INSPECTION AND APPARATUS THEREFOR ( 71) We, THE BABCOCK & WILCOX COMPANY, a corporation organised under the laws of the State of Delaware, United States of America, of 161, East 42nd Street, New York, New York, 10017, United States of America, do hereby declare the invention for which we pray that a patent may be granted to us, and the method by which it is to be
performed, to be particularly described in and by the following statement: 5
This invention relates to a method of magnetically inspecting ferromagnetic workpieces and apparatus therefore and, more particularly, the utilisation of magnetic particles influenced by electro-magnetically induced magnetic fields in the workpiece to indicate the existence of defects, such as flaws, cracks, inclusions or discontinuities, in the workpiece.
The defects distort the induced magnetic field in the ferromagnetic test material producing 10 a leakage field external to the test material and also creating opposing magnetic polarities across the defects which, among other things, will attract an accumulation of magnetic particles applied to the surface of the material if the magnetic field perturbation is of sufficient strength to penetrate the surface of the material.
According to the present invention -a method of magnetically inspecting ferromagnetic 15 workpieces including the steps of depositing magnetic particles on the workpiece; subjecting the workpiece to pulsed alternating and pulsed direct current magnetic fields either in a simultaneous or sequential manner; adjusting the relative strengths and durations of the pulsed alternating and pulsed direct current magnetic fields; and examining the particles on the workpiece for perturbations of the alternating and direct current magnetic fields 20
The invention also includes apparatus for magnetically inspecting ferromagnetic workpieces having magnetic particles deposited thereon including a magnetizable yoke dispersed on the workpiece; a magnetizing coil wound about the yoke; an alternating current circuit for delivering alternating current a direct current circuit including a rectifier for converting alternating current to direct current and delivering direct current, the alternating and direct 25 current circuits being connected in parallel to a common source of alternating current, each circuit including an adjustable output transformer for regulating current input to the magnetizing coil, the alternating and direct current circuits including filters to prevent passage therethrough of direct and alternating currents respectively, and adjustable time delay relays for producing pulsed alternating and pulsed direct currents for delivery to the mag 30 netizing coil, and for regulating the relative strengths and durations of pulsing of the alternating and direct currents delivered to the magnetizing coil.
The invention will now be described, by way of example, with reference to the accompanying partly diagrammatic and schematic drawings, in which:Figure 1 is a partly block diagram of a circuit for inducing magnetic fields together with 35 representations of the electrical current flowing at locations in the circuit on a time base; Figure 2 is a perspective elevation of a magnetic yoke in an operating position on a portion of a workpiece indicating magnetic field lines; and
Figures 3 A, 3 B and 3 C are sectional elevations of three typical workpieces indicating direct current induced magnetic fields therein, cross-section hatching being omitted for 40 clarity.
Referring to Figure 1, a magnetic induction yoke 10 is energisable by means of a coil 12 through two parallel circuits, separate portions of which are shown by arrows 14 and 16 respectively, which are connected to an alternating power supply (not shown) such as 120 volts 60 hertz or 240 volts 50 hertz by means of power supply leads 18 The sub-circuit 14, 45 2 1,584,671 2 or alternating current portion of the circuit, includes a variable transofmer 20 connected on a primary side to the leads 18 and on a secondary side 20 A to a direct current filter 24 The parallel sub-circuit 16, or direct current portion of the circuit, also includes a variable transformer 22 connected on a primary side to the leads 18 and on a secondary side 22 A to an alternating current filter consisting of a rectifier or diode 26 in series with a reactance or 5 choke 28 The parallel sub-circuits 14 and 16 are connected across terminals 25, 27 to the coil 12 would on the yoke 10 Thus the induced magnetic field of yoke 10 results from the algebraic summation of the magnetic fields induced by the alternating current of circuit 14 and the square wave rectified current of circuit 16 the relative values of which are adjustable by means of the variable transformers 20 and 22 respectively Thus, increasing the 10 direct current induced magnetic field does not also increase the induced alternating current magnetic field.
In order to obtain the maximum effects of both the alternating current and direct current induced magnetic fields, standard electrical adjustable time delay relays 30 and 32 are provided in each sub-circuit 14 and 16 respectively, such as Potter and Brumfield, Type 15
CKB-70010, to control the pulse rate and duration of the pulse in the subcircuits Thus, a typical waveform for the sub-circuit 14, is indicated at 64 and a typical waveform for the sub-circuit 16 is indicated at 66 and the algebraic summation of these pulses as they are applied to the coil 12 in phase is indicated at 68 It will be appreciated that, alternatively the pulses may be arranged wholly or partly out of phase 20 Current flowing through the coil 12 wound on the yoke 10 creates a magnetic field within the yoke and induces a magnetic field 40 (Figure 2) in a workpiece 50 (Figure 2) placed across the ends of the yoke IOA and l OB Defects in the material cause perturbations or distortions of the magnetic field and create magnetic poles on either side thereof which are detectable in a variety of ways Figure 3 A illustrates a typical workpiece 50 A in section 25 having no defects and an induced magnetic field 40 A associated therein Similarly, Figure
3 B illustrates a typical workpiece 50 B having a surface defect 55 and indicates the magnetic field perturbation 4 OB’ of the indiced magnetic field 40 B In like manner, Figure 3 c illustrates a typical workpiece 50 c having a subsurface defect 56 and indicates the perturbation 40 c’ of the induced magnetic field 40 c It is to be noted that the perturbation 40 c’ associated 30 with the subsurface defect 56 may not penetrate the surface of the workpiece 50 c if the induced magnetic field 40 c is not of sufficient strength or if the defect is substantially below the surface of the workpiece Accordingly, if the perturbations 40 c’ do not extend through the surface of the workpiece 50 c magnetic inspection, by means of magnetic particles dusted onto the surface of the tested workpiece may not indicate the defect That is, the magnetic 35 particles will not be influenced by the magnetic perturbations 40 c’ However, the defects in the test material across the yoke 10 are exposed to a pulsating direct current magnetic field and sequentially or simultaneously exposed to a pulsating alternating current magnetic field Moreover, the pulsating magnetic fields significantly influence the response of the magnetic particles to a deep subsurface defect or perturbed magnetic field thereof 40
In operation, the yoke 10 is placed in contact with a workpiece under test and an alternating supply source is connected to the leads 18 Magnetic powder particles placed or dusted upon the test material between the ends IOA and l OB of the yoke are then exposed to the induced pulsating magnetic fields By proper adjustment of the rate and duration of each current, a small leakage field from a defect deep below the surface of the material is 45 detected by the magnetic particles due to the high mobility created therein by the pulsating alternating current portion of the induced magnetic field Furthermore, since the direct current magnetic field holds the magnetic particles stationary and the alternating current magnetic field induces a mobility to the particles, the pulsating direct current and alternating current magnetic fields influences the particles such that they, in effect, “walk” along 50 the test material in a pulsed dynamic manner For example, a direct current perturbed magnetic field due to a defect holds the particles and a subsequent or simultaneous alternating current magnetic field mobilizes the remaining particles Thereafter, if the direct current pulse ceases the alternating current field if still “on” mobilizes all the particles Subsequently a second direct current pulse or a residual direct current magnetic field will perturb 55 the field at the defect which will hold the magnetic particles influenced thereby In effect, a dynamic or moving picture of the defect is created and is readily recognized thereby.
Accordingly, the “walking” of the magnetic particles across the surface of the test material is produced by the combined alternating current and direct current induced pulsed magnetic fields whether simultaneously or sequentially applied That is even when the alternating 60 current is only applied during the “off” time of the direct current sequentially, or only during the “on” time of the direct current simultaneously “walking” of the particles is produced by the direct and residual direct current induced magnetic fields and the skin effect of the surface alternating magnetic field.
The magnetic inspection method and device or apparatus of this invention was tested on 65 1,584,671 two test plates having carefully measured defects “holes” therein (see Table 1) versus a like yoke influenced by ( 1) alternating current alone and ( 2) direct current alone Using only the alternating current or direct current magnetizing setup, holes Nos 7 and 8 were detected in test plate #1 and hole No 3 in test plate #2 was the deepest defect detectable Whereas, the device of this invention detected holes Nos 7 and 8 and the deeper holes Nos 5 and 6 of test plate #1; and also, detected holes numbered 1 through 5 of the test plate #2 Accordingly, the device and method of this invention provided a 60 % increase in deep defect detection; and, also provided a dynamic visual defect indication, “walking” of the particles, not provided by other methods.
TABLE 1.
PLATE #1 0312 ” ( 794 mm) 0312 ” ( 794 mm) 0312 ” ( 794 mm) 0312 ” ( 794 mm) 0312 ” ( 794 mm) 0312 ” ( 794 mm) 0312 ” ( 794 mm) 0312 ” ( 794 mm) 000 ” 1.098 ” 118 ” 1.012 ” 395 ” 992 ” 985 ” 1.067 ” Hole Length (L) (Drill Broke) ( 27 9 mm) (Drill Broke) ( 25 7 mm) ( 10 2 mm) ( 25 2 mm) ( 25 O mm) ( 27 1 mm) Below Surface Hole Depth 052 ” ( 1 32 mm) 046 ” ( 1 17 mm) 038 ” ( 0 97 mm) ” ( 0 89 mm) 024 ” ( 0 61 mm) 021 ” ( 0 53 mm) 012 ” ( 0 31 mm) Where (“) indicates inches and (mm) indicates millimeters.
PLATE #2 Hole No.
Hole Diameters 1 0625 ” ( 1 587 mm) 2 0625 ” ( 1 587 mm) 3 0625 ” ( 1 587 mm) 4 0625 ” ( 1 587 mm) 0625 ” ( 1 587 mm) 6 0625 ” ( 1 587 mm) 7 0625 ” ( 1 587 mm) 8 0625 ” ( 1 587 mm) 1.010 ” 1.013 ” 1.006 ” 98 1 ” 1.003 ” 990 ” 984 ” 988 ” Hole Length (L) ( 25 6 mm) ( 25 7 mm) ( 25 4 mm) ( 25 0 mm) ( 25 4 mm) ( 25 2 mm) ( 25 0 mm) ( 25 1 mm) Below Surface Hole Depth ” ( 0 25 mm) ” ( 0 63 mm) ” ( 1 02 mm) 054 ” ( 1 37 mm) 072 ” ( 1 83 mm) 086 ” ( 2 18 mm) 101 “( 2 57 mm) 147 ” ( 3 74 mm) Further, in the preferred embodiment of this invention it is found that the reactance (X) of the choke, inductor 28, should be greater than 10 times the impedance (Z) of the yoke, i.e.
XL > 10 Zyoke and that the reactance of the filter or capacitor 24 should be less than one tenth of the impedance of the yoke i e.
Xc < Z yoke In passing it should be noted that the impedance (Z) is a measure of the total opposition to current flow in an alternating current circuit, usually represented in complex notation as Z = R + i X, where R is ohmic resistance and X is the opposition caused by inductance of capacitance in an alternating current circuit.
In addition, another embodiment of the invention includes a capacitor 40 (shown in phantom in Figure 1) connected at one end between the cathode 26 A and the choke 28 and Hole No.
Hole Diameters 1 2 3 4 6 7 1,584,671 at the other end to the terminal portion of coil 12, to ensure direct current flow in the circuit 16 for all phase combinations of the transformers 20 and 22.
It will be appreciated that, if desired, the method of the invention may be performed using a direct current source in place of the transformer 22 and the rectifier 26 of the sub-circuit 16 5
Claims (4)
WHAT WE CLAIM IS:-
1 A method of magnetically inspecting ferromagnetic workpieces including the steps of depositing magnetic particles on the workpiece; subjecting the workpiece to pulsed alternating and pulsed direct current magnetic fields either in a simultaneous or sequential manner; adjusting the relative strengths and durations of the pulsed alternating and pulsed 10 direct current magnetic fields; and examining the particles on the workpiece for perturbations of the alternating and direct current magnetic fields.
2 Apparatus for magnetically inspecting ferromagnetic workpieces having magnetic particles deposited thereon including a magnetizable yoke disposed on the workpiece; a magnetizing coil wound about the yoke; an alternating current circuit for delivering alter 15 nating current a direct current circuit including a rectifier for converting alternating current to direct current and delivering direct current the alternating and direct current the alternating and direct current circuits being connected in parallel to a common source of alternating current, each circuit including an adjustable output transformer for regulating current input to the magnetizing coil, the alternating and direct current circuits including filters to prevent 20 passage therethrough of direct and alternating currents respectively, and adjustable time delays relays for producing pulsed alternating and pulsed direct currents for delivery to the magnetizing coil and regulating the relative strengths and durations of pulsing of the alternating and direct currents delivered to the magnetizing coil.
3 Apparatus for magnetically inspecting ferromagnetic workpieces as claimed in Claim 25 2 wherein the direct current circuit includes a capacitor having one end connected between the filter and the rectifier and the other end connected between the transformer and the magnetizing coil to ensure direct current flow through the circuit for all phase combinations of said transformers.
4 Apparatus for magnetically inspecting ferro-magnetic workpieces, arranged and 30 adapted to operate substantially as hereinbefore described with reference to the accompanying drawings.
Agent for the Applicants, D.O LEWIS, Chartered Patent Agent 35 Printed for Her Majesty's Stationery Office, by Croydon Printing Company Limited, Croydon, Surrey, 1981.
Published by The Patent Office, 25 Southampton Buildings, London, WC 2 A l AY, from which copies may be obtained.
GB23393/77A
1976-06-04
1977-06-02
Method of magnetic inspection and apparatus therefor
Expired
GB1584671A
(en)
Applications Claiming Priority (1)
Application Number
Priority Date
Filing Date
Title
US05/693,021
US4058762A
(en)
1976-06-04
1976-06-04
Method and apparatus for magnetic inspection through adjustable pulsed alternating and direct current magnetic fields
Publications (1)
Publication Number
Publication Date
GB1584671A
true
GB1584671A
(en)
1981-02-18
Family
ID=24782990
Family Applications (1)
Application Number
Title
Priority Date
Filing Date
GB23393/77A
Expired
GB1584671A
(en)
1976-06-04
1977-06-02
Method of magnetic inspection and apparatus therefor
Country Status (15)
Country
Link
US
(1)
US4058762A
(en)
JP
(1)
JPS5316685A
(en)
AU
(1)
AU512325B2
(en)
BE
(1)
BE855396A
(en)
CA
(1)
CA1096941A
(en)
DE
(1)
DE2725306B2
(en)
DK
(1)
DK247377A
(en)
FI
(1)
FI62906C
(en)
FR
(1)
FR2353851A1
(en)
GB
(1)
GB1584671A
(en)
IN
(1)
IN148533B
(en)
IT
(1)
IT1077222B
(en)
NL
(1)
NL7706147A
(en)
NO
(1)
NO771923L
(en)
SE
(1)
SE7706471L
(en)
Families Citing this family (11)
* Cited by examiner, † Cited by third party
Publication number
Priority date
Publication date
Assignee
Title
SU1499209A1
(en)
*
1986-07-02
1989-08-07
Белорусский Политехнический Институт
Magnetizing device for magnetographic check of articles
DE4034751A1
(en)
*
1990-10-30
1991-05-23
Michael Schulz
Magnetic crack testing of bore soffit(s) accessible from one side only - applying fluorescent powder to make defects visible under magnetisation
US6316845B1
(en)
1999-11-05
2001-11-13
Parker Research Corporation
Battery powered AC electromagnetic yoke for magnetic particle inspection
US20080258719A1
(en)
*
2007-04-18
2008-10-23
The University Of Houston
Apparatus and methods for ferromagnetic wall inspection of tubulars
DE102007024060A1
(en)
*
2007-05-22
2008-11-27
Illinois Tool Works Inc., Glenview
Apparatus and method for test equipment control
DE102007024058A1
(en)
*
2007-05-22
2008-11-27
Illinois Tool Works Inc., Glenview
Apparatus and method for test equipment control
DE102008048592B4
(en)
*
2008-09-23
2010-08-26
Mr-Chemie Gmbh
Adjustable hand magnet
UA117542C2
(en)
2017-06-16
2018-08-10
Олександр Григорович Калениченко
SYSTEM FOR DETERMINATION OF ELECTROMAGNETIC FIELD AND MATERIAL STRUCTURE AND METHOD FOR DETERMINING ELECTROMAGNETIC FIELD AND MATERIAL MATERIAL
US11307173B1
(en)
2019-08-20
2022-04-19
Scan Systems Corp.
Apparatus, systems, and methods for inspection of tubular goods
US11402352B1
(en)
2019-08-20
2022-08-02
Scan Systems Corp.
Apparatus, systems, and methods for inspecting tubulars employing flexible inspection shoes
US11402351B1
(en)
2019-08-20
2022-08-02
Scan Systems Corp.
Apparatus, systems, and methods for discriminate high-speed inspection of tubulars
Family Cites Families (4)
* Cited by examiner, † Cited by third party
Publication number
Priority date
Publication date
Assignee
Title
CA447838A
(en)
*
1948-04-13
Magnaflux Corporation
Method of and apparatus for magnetic testing
US1782462A
(en)
*
1925-07-06
1930-11-25
Firm Neufeldt & Kuhnke Betr Sg
Arrangement for testing magnetizable objects
US1910770A
(en)
*
1928-02-27
1933-05-23
Kinsley Carl
Magnetic testing of masses
US3378762A
(en)
*
1967-07-05
1968-04-16
Phillip J. Parker
Magnetic particle inspection probe with adjustable probe legs and self-contained circuitry for a.c. or d.c. testing
1976
1976-06-04
US
US05/693,021
patent/US4058762A/en
not_active
Expired - Lifetime
1977
1977-06-01
IN
IN825/CAL/77A
patent/IN148533B/en
unknown
1977-06-01
JP
JP6339077A
patent/JPS5316685A/en
active
Pending
1977-06-01
NO
NO771923A
patent/NO771923L/en
unknown
1977-06-02
SE
SE7706471A
patent/SE7706471L/en
not_active
Application Discontinuation
1977-06-02
CA
CA279,740A
patent/CA1096941A/en
not_active
Expired
1977-06-02
GB
GB23393/77A
patent/GB1584671A/en
not_active
Expired
1977-06-03
BE
BE178202A
patent/BE855396A/en
unknown
1977-06-03
DK
DK247377A
patent/DK247377A/en
unknown
1977-06-03
IT
IT24366/77A
patent/IT1077222B/en
active
1977-06-03
AU
AU25817/77A
patent/AU512325B2/en
not_active
Expired
1977-06-03
NL
NL7706147A
patent/NL7706147A/en
not_active
Application Discontinuation
1977-06-03
FR
FR7716980A
patent/FR2353851A1/en
active
Granted
1977-06-03
FI
FI771785A
patent/FI62906C/en
not_active
IP Right Cessation
1977-06-04
DE
DE2725306A
patent/DE2725306B2/en
not_active
Withdrawn
Also Published As
Publication number
Publication date
IN148533B
(en)
1981-03-28
FR2353851B1
(en)
1981-12-18
JPS5316685A
(en)
1978-02-15
SE7706471L
(en)
1977-12-05
US4058762A
(en)
1977-11-15
DE2725306B2
(en)
1979-06-28
FI771785A
(en)
1977-12-05
NO771923L
(en)
1977-12-06
FR2353851A1
(en)
1977-12-30
CA1096941A
(en)
1981-03-03
BE855396A
(en)
1977-12-05
IT1077222B
(en)
1985-05-04
AU2581777A
(en)
1978-12-07
DE2725306A1
(en)
1977-12-08
NL7706147A
(en)
1977-12-06
AU512325B2
(en)
1980-10-02
DK247377A
(en)
1977-12-05
FI62906B
(en)
1982-11-30
FI62906C
(en)
1983-03-10
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Legal Events
Date
Code
Title
Description
1981-05-07
PS
Patent sealed [section 19, patents act 1949]
1984-02-08
PCNP
Patent ceased through non-payment of renewal fee
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