CN101025359A - Precision electromagnetic mutual inductive thickness-measuring apparatus - Google Patents

Precision electromagnetic mutual inductive thickness-measuring apparatus Download PDF

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Publication number
CN101025359A
CN101025359A CN 200710038547 CN200710038547A CN101025359A CN 101025359 A CN101025359 A CN 101025359A CN 200710038547 CN200710038547 CN 200710038547 CN 200710038547 A CN200710038547 A CN 200710038547A CN 101025359 A CN101025359 A CN 101025359A
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China
Prior art keywords
control panel
thickness
pin
coil
shell
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Granted
Application number
CN 200710038547
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Chinese (zh)
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CN100578138C (en
Inventor
张传忠
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Shenjing Automation Electric Appliance Co Ltd Shanghai
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Shenjing Automation Electric Appliance Co Ltd Shanghai
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Priority to CN200710038547A priority Critical patent/CN100578138C/en
Publication of CN101025359A publication Critical patent/CN101025359A/en
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Publication of CN100578138C publication Critical patent/CN100578138C/en
Expired - Fee Related legal-status Critical Current
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Abstract

The invention relates a kind of accurate magnetoelectricity mutual-induction measuring thickness device. It is consisted of a signal transfer element, a thickness measuring element and a measuring thickness sensor. It is characteristics in that the measuring thickness sensor mentioned previous is consisted of a signal produced loop A, a resonance coil A, a crust, a control panel, a signal produced loop B, a resonance coil B, a gang socket, a item connecting line and a cover board. Connect the resonance coil A with the signal produced loop B forming a axes and then locate in the up-down ends on the upside of shell and the terminals of the two coils connect with the control panel and also the resonance coil A and the resonance B form a axes after connecting together then locate in the left-right terminals on the upside of the crust of which the terminals connect with the control panel. The control panel locates among the underside of crust and the gang socket traverses the cover board by the connecting line connecting with the control panel and the cover board and the crust are fixed. The merit of the invention is the twopenny price so it can replace the overseas production.

Description

A kind of precision electromagnetic mutual inductive thickness-measuring apparatus
Technical field
The present invention relates to a kind of precision electromagnetic mutual inductive thickness-measuring apparatus, relate in particular on a kind of assembling machine that can be installed in printing bookbinding, in process of production when the signature of different-thickness is sneaked into to its measuring thickness device of differentiating and rejecting, belong to the measuring thickness device technical field.
Background technology
Switzerland protects electronics corporation of alliance (Baumer electric) and produces precision electromagnetic mutual induction measuring thickness device, is installed in specially on the assembling machine of printing bookbinding.
At present domestic this equipment of will installing on the assembling machine of printing bookbinding must import, but electronics corporation of Switzerland guarantor alliance does not provide the sample and the technical parameter of this device senses device, and prices are rather stiff.The applicant is according to its its 26S Proteasome Structure and Function of function analysis.
This measuring thickness device is made up of three parts:
1. sensor
The plastic housing structure is rectangle, and the position of bar magnet and action show when only adjusting scarce card with a LED lamp;
2. reflectogauge
Whole reflectogauge is passive, is made up of signal transfer part and thickness induction part;
3. measure the thickness element
Ferrite bar.
In use the shortcoming of Bao Luing is as follows:
1) thickness data of this sensor acquisition dependence peripheral control unit computing machine carries out analysis and judgement, must improve the outer computer travelling speed so in process of production, the cost of hardware is improved, and the synchronous signal data line is connected the antijamming capability that greatly reduces sensor between the two;
2) because sensor can not be made measurement result to data, and causing itself is not an independently detecting unit, be sensor fault or peripheral control unit fault just in case detection has misoperation, user just to be difficult to judge, bring difficulty for the service of dealing with problems arising from an accident;
3) the electrical equipment cost control needs 15-18 cover sensor and 5-6 cover peripheral control unit and equip a streamline in the general domestic streamline about 15%, if by import then occupy the several times of a domestic streamline cost;
4) generally use pressure roller directly to contact paper at present, method is the degree varies sample of upspringing that makes pressure roller because of the difference of paper sheet thickness, cause be connected on the pressure roller near switch and the detection of measuring iron plate apart from respective change takes place, export different analog quantitys and measure paper thickness, the as easy as rolling off a log in process of production paper printing ink that is subjected to of pressure roller, paper scrap, staining of dust, often the size of its accumulation has surpassed the thickness of general thin paper or the accuracy rating of setting, cause the saltus step of pressure roller at measurement point, cause and produce misoperation in the production run again and again, even energy measurement is thin not obedient, can only measure scarce card and two opening, not have the effect of the wrong card of detection, consumers' opinions is very big.
Summary of the invention
The purpose of this invention is to provide a kind of global design and be fit to national conditions, cheap, the precision electromagnetic mutual inductive thickness-measuring apparatus of alternative external product.
For realizing above purpose, technical scheme of the present invention provides a kind of precision electromagnetic mutual inductive thickness-measuring apparatus, form by signal transmitting element, thickness measure element and thickness measurement sensor, the signal transmitting element is connected with the thickness measure element, the spacing L of being separated by between thickness measurement sensor and the signal transmitting element is 0.7mm-1mm, it is characterized in that
Described signal transmitting element is made up of electric capacity, printing forme, transmission inductive coil, two bar magnets and shell, electric capacity is connected with printing forme, be located at a side in the shell, two bar magnets are in angled being located at of level and transmit in the inductive coil, and are located at the opposite side in the shell.
Described thickness measure element is made up of housing, bar magnet, support and thickness inductive coil, and the bar magnet that can move in the thickness inductive coil is fixed on the support, and the thickness inductive coil is located in the housing.
Described thickness measurement sensor is by signal generation loop A, resonance coil A, shell, control panel, signal generation coil B, resonance coil B, gang socket, connecting line, lid is formed, signal generation loop A is connected the back and becomes an axis to be located at the upper and lower side of shell upside with signal generation coil B, two coil terminals are connected with control panel, resonance coil A with also become after resonance coil B is connected an axis be located at the shell upside about end. its two coil terminals is connected with control panel, the control panel level is located in the middle of the downside of shell, gang socket is passed lid by connecting line and is connected with control panel, and lid is fixed with shell.
Described control panel control panel power unit, control panel sender unit, control panel signal amplifier and control panel microcomputer data processing circuit are formed, the control panel power unit is connected control panel microcomputer data processing circuit with control panel microcomputer data processing circuit and is connected with the control panel sender unit, and the control panel sender unit is connected with the control panel signal amplifier.
The present invention utilizes magnetic mutual inductance principle to invent magnetoelectricity mutual induction pick-up unit, adopts A/F convert light coupled apparatus, finishes the process that is transformed into frequency signal from analog quantity with the simplest mode, makes the MICROCOMPUTER PROCESSING method in the sensor become more simple.
The present invention makes sensor become essentially independent detection and judging unit, built-in microcomputer is used respectively normally the comparative result of current detection paper and normal paper, lack card, thick card, 4 kinds of LED of thin card represent, make the user can judge guilty culprit ground easily, sensor has the microcomputer of oneself can not only intelligently handle internal data, has improved the stability that detects, reliability, also improve the outer computer travelling speed greatly, strengthened the antijamming capability of sensor output simultaneously.
Advantage of the present invention is:
1. sensor and reflectogauge are to carry out signal by certain space length to transmit mutually, thickness measuring induction part and paper are contactless, even the therefore externally interference of environment and stain down and can both keep its long-term accuracy of detection, it allows tested paper thickness in the 20um-2mm scope, even under the speed of gathering leaves of a book of per hour 7800 commentaries on classics, also can tell the rate of change of tested paper sheet thickness ± 30% and ± 50%, correctly undesirable thick card, thin card and scarce obedient signal be transmitted out;
2. the present invention is not subjected to external disturbance, has guaranteed the stable and linear of check point data, and repeatable accuracy can ideally adapt to high speed detection, has guaranteed the precision of thickness measuring, has avoided the misoperation in the production run effectively, has played the effect that detects wrong card;
3. the microcomputer of sensor internal setting calculates immediately, revises the thickness data of gathering, and guarantees the correctness of final output data, has realized that sensor intelligent is integrated;
4. the sensor control panel is provided with 5 LED lamps, the result who represents current detection respectively is normal card or lacks card or thick card or thin card, also have 1 lamp to be used for being provided with the initial position of thickness measure element, the method for expressing of these lamps makes fault judgement become more humane;
5. reduced production cost.
Description of drawings
Fig. 1 is a kind of precision electromagnetic mutual inductive thickness-measuring apparatus structural representation;
Fig. 2 is a signal transmitting element structural representation;
Fig. 3 is a thickness measure component structure synoptic diagram;
Fig. 4 is the thickness measurement sensor structural representation;
Fig. 5 is the control panel circuit diagram;
Fig. 6 is a program flow diagram of the present invention.
Embodiment
The invention will be further described below in conjunction with drawings and Examples.
Embodiment
As shown in Figure 1, be a kind of precision electromagnetic mutual inductive thickness-measuring apparatus structural representation, described a kind of precision electromagnetic mutual inductive thickness-measuring apparatus is made up of signal transmitting element 1, thickness measure element 2 and thickness measurement sensor 3, signal transmitting element 1 is connected with thickness measure element 2, and the spacing L of being separated by between thickness measurement sensor 3 and the signal transmitting element 1 is 0.7mm.
As shown in Figure 2, be signal transmitting element structural representation, described signal transmitting element 1 by electric capacity 4, printing forme 5, transmit inductive coil 6, two bar magnets 7 and shell 8 and form, electric capacity 4 is connected with printing forme 5, be located at a side in the shell 8, two bar magnets 7 are in level angle and are located in the transmission inductive coil 6, and are located at the opposite side in the shell 8.
As shown in Figure 3, be thickness measure component structure synoptic diagram, described thickness measure element 2 is made up of housing 9, bar magnet 10, support 11 and thickness inductive coil 12, and the bar magnet 10 that can move in thickness inductive coil 12 is fixed on the support 11, and thickness inductive coil 12 is located in the housing 9.
As shown in Figure 4, be the thickness measurement sensor structural representation, described thickness measurement sensor 3 is by signal generation loop A 13, resonance coil A14, shell 15, control panel 16, signal generation coil B17, resonance coil B18, gang socket 19, connecting line 20, lid 21 is formed, signal generation loop A 13 is connected the back and becomes an axis to be installed in the upper and lower side of shell upside with signal generation coil B17, two coil terminals are connected with control panel 16, resonance coil A14 with also become after resonance coil B18 is connected an axis be installed in shell 15 upsides about end. its two coil terminals is connected with control panel 16, control panel 16 levels are located in the middle of the downside of shell 15, gang socket 19 is passed by connecting line 20 and is covered 21 and be connected with control panel 16, and lid 21 is fixing with shell 15.
As shown in Figure 5, be the control panel circuit diagram, described control panel 16 is made up of control panel power unit, control panel sender unit, control panel signal amplifier and control panel microcomputer data processing circuit, and it consists of:
Described control panel power unit is by 1 diode D1,3 resistance R 1, R2, R3,6 electrochemical capacitor C1-C6, and 3 stabilivolt V1-V3 form.
1 pin of diode D1 is connected with working power V+, 2 pin of diode D1 respectively with resistance R 1, R2, the end of R3 connects, the other end of resistance R 1 then is connected with the positive pole of electrochemical capacitor C1 with the 1 pin series connection of stabilivolt V1 again, the other end of resistance R 2 also is connected with the positive pole of electrochemical capacitor C3 with the 1 pin series connection of stabilivolt V2 again, the other end of resistance R 3 is connected with the positive pole of electrochemical capacitor C5 with the 1 pin series connection of stabilivolt V3 again, 2 pin of stabilivolt V1 respectively with electrochemical capacitor C1, the 0V that connects working power after the negative pole of C2 connects again, 2 pin of same stabilivolt V2 respectively with electrochemical capacitor C3, the 0V that also connects working power after the negative pole of C4 connects, 2 pin of stabilivolt V3 then respectively with electrochemical capacitor C5, the 0V that also connects working power after the negative pole of C6 connects, 3 pin of stabilivolt V1 and the anodal internal work voltage V1 that is connected back output control panel of electrochemical capacitor C2,3 pin of stabilivolt V2 and the anodal internal work voltage V2 that is connected back output control panel of electrochemical capacitor C4,3 pin of stabilivolt V3 and the anodal internal work voltage V3 that is connected back output control panel of electrochemical capacitor C6.
Described control panel sender unit is by 5,8 resistance R 4-R11 of 1 integrated circuit (IC), 3 capacitor C 8-C10, and 1 transistor Q1,1 coil L3 forms.
1 of integrated circuit (IC) 5,2 pin are connected with 2 pin of resistance R 11 after connecting again, 3 of integrated circuit (IC) 5,5,6 pin are connected with 2 pin of resistance R 12 after connecting again, 4 pin of integrated circuit (IC) 5 are connected with 2 pin of 2 pin of resistance R 10 and capacitor C 10,1 pin of resistance R 11 then, 1 pin of resistance R 10 and 1 pin of capacitor C 10 all link together, 7 pin of integrated circuit (IC) 5 meet the 0V of power supply, and be connected with 2 pin of the integrated circuit (IC) 3 of control panel microcomputer data processing, 2 pin of capacitor C 9 respectively with 2 pin of resistance R 8,1 pin of resistance R 9 connects, 2 pin of resistance R 9 meet the 0V of power supply, 1 pin of resistance R 8 then respectively with 8 of integrated circuit (IC) 5,2 pin of 9 pin and resistance R 7 link together, 1 pin of resistance R 7 then is connected with 11 pin of integrated circuit (IC) 5 and 1 pin of R6,10 of integrated circuit (IC) 5,12,13 pin are connected to each other, 14 pin of integrated circuit (IC) 5 meet voltage V1,14 pin of while with the integrated circuit (IC) 3 of control panel signal amplifier are connected, above-mentioned connection is formed signal generating circuit around integrated circuit (IC) 5, make the signal of the 11 pin output certain frequency of integrated circuit (IC) 5, Q1 amplifies by transistor. and 2 pin of resistance R 6 are connected with transistor Q1 base stage, transistor Q1 collector meets power supply V1,1 pin of transistor Q1 emitter connecting resistance R5, resistance R 5 pin defeated 5 go out to by resistance R 4, capacitor C 8, the signal generator sensing coil that coil L3 composes in parallel, a termination voltage 0V in parallel, 2 pin of other end connecting resistance R5. send to signal by the signal generator coil and transmit inductive coil.
Described control panel signal amplifier is by 1 integrated circuit (IC) 6,5 resistance R 12, R14, R16-R18,2 potentiometer R13, R19,4 capacitor C 11-C14,1 light emitting diode D3,1 diode D2 and 1 coil L4 form the resonance signal amplifying circuit.
Capacitor C 11, coil L4 forms resonant frequency circuit, absorption signal transmits the signal that inductive coil passes over, capacitor C 11, one termination voltage 0V of coil L4 parallel connection, 1 pin of other end connecting resistance R12, be connected to 13 pin of integrated circuit (IC) 6 by 2 pin of capacitor C 12,1 pin of resistance R 17,2 pin of potentiometer R13, be connected to 12 pin of integrated circuit (IC) 6 by 2 pin of resistance R 17,3 pin of potentiometer R13 are connected to signal on 1 pin of capacitor C 14,2 pin of capacitor C 14 respectively with 11 pin of integrated circuit (IC) 6,1 pin of resistance R 16 connects, by 2 pin of resistance R 16 and the positive pole that is connected process diode D2 of 10 pin of integrated circuit (IC) 6, be connected to 2 pin of resistance R 14 from the negative pole of diode D2,1 pin of R14 is connected with capacitor C 13 with parallel resistor R12 on the one hand, connect 1 of integrated circuit (IC) 6 on the other hand, 3,5 pin. 2 of integrated circuit (IC) 6,4,6 pin connect back and resistance R 18, potentiometer R19, light emitting diode D3 series connection, wherein 2 of potentiometer R19,3 pin are connected with light emitting diode D3 is anodal, and light emitting diode D3 negative pole meets 0V.
Described control panel microcomputer data processing is by 6 integrated circuit (IC) 1, IC2, IC3, IC4, IC7, IC8,10 resistance R 20-R29, and 2 capacitor C 15, C16,1 electrochemical capacitor C17,1 quartz crystal oscillator, 1 transistor Q2, AN1 button, 5 light emitting diodes are formed the microcomputer data processing circuit.
Form the conversion of A/F simulation and frequency by above-mentioned light emitting diode D3 and the described integrated circuit (IC) 4 of this circuit, 1 of integrated circuit (IC) 4,2,3,4,7 pin are connected to each other 0V, 8 pin of integrated circuit (IC) 4 meet voltage V2,5 of integrated circuit (IC) 4,6 pin respectively with 19 of integrated circuit (IC) 2,18 pin connect, 2 of integrated circuit (IC) 2,3 pin are the precision setting data line, 7 pin of integrated circuit (IC) 2 are reading order data line, 8 pin of integrated circuit (IC) 2 are for finishing the order data line, 11 pin of integrated circuit (IC) 2 are the order control line, 12 pin of integrated circuit (IC) 2 are data 0 control lines, connect 2 pin of R25,1 pin of resistance R 25 meets power supply V2,13 pin of integrated circuit (IC) 2 are data 1 control lines, connect 2 pin of R26 simultaneously, 1 pin of R26 meets power supply V2,4 pin of integrated circuit (IC) 2,5 pin are connected with quartz crystal oscillator respectively, pin connects 1 pin of capacitor C 15,2 pin of capacitor C 15 connect capacitor C 15 1 pin and with 1 of integrated circuit (IC) 4,2,3,3 of 4 pin and integrated circuit (IC) 3,4 pin, 2 pin of resistance R 29 connect, 2 pin of quartz crystal oscillator connect 2 pin of capacitor C 16,1 pin of the 1 pin difference connecting resistance R29 of integrated circuit (IC) 2 and the negative pole of electrochemical capacitor C17, the positive pole of resistance electrochemical capacitor C17 meets power supply V2,9 pin of integrated circuit (IC) 2 are connected with 6 pin of integrated circuit (IC) 3,1 of integrated circuit (IC) 3,2,5,7 pin meet power supply V3,3 of integrated circuit (IC) 2,4,8 pin meet 0V, the log-on data line connects 1 pin of integrated circuit (IC) 8, the base stage of 2 pin of integrated circuit (IC) 8 and resistance R 28 series connection transistor Q2, transistor Q2 emitter meets 0V, transistor Q2 collector connects 2 pin of integrated circuit (IC) 7 and 2 pin of resistance R 27 respectively, 1 pin of resistance R 27 meets power supply V2,1 pin of integrated circuit (IC) 7 connects 17 pin of AN1 button 1 pin and integrated circuit (IC) 2 respectively, AN1 button 2 pin meet 0V, 14 of integrated circuit (IC) 2,15,16 pin respectively with 14 of integrated circuit (IC) 1,12,11 pin, 7 pin of integrated circuit (IC) 1 are data command line in place, 13 pin of integrated circuit (IC) 1 meet 0V, 10 of integrated circuit (IC) 1,16 pin meet power supply V2,15 of integrated circuit (IC) 1,1,2,3,4 pin are the output line negative pole of sending and receiving optical diode D4-D8 respectively, the positive pole of light emitting diode D4-D8 is connected with 1 pin of resistance R 20-R24 respectively, 2 pin of resistance R 20-R24 are connected to each other and meet power supply V2, and light emitting diode D4-D8 shows the state that thickness detects.
Fig. 6 is a program flow diagram of the present invention, during use, thickness measurement sensor 3 is fixed on the frame of printing bookbinding assembling machine, signal transmitting element 1, thickness measure element 2 is separately fixed at the signature of mechanical main shaft and stings on the paper wheel, the shell of signal transmitting element 1 and thickness measurement sensor 3 upside heads are at a distance of 0.7-1.0mm, and make circular motion along certain track, transmit inductive coil 6 and the interior signal generation loop A 13 of thickness measurement sensor 3 upside heads like this, signal generation coil B17 and resonance loop A 14, resonance coil B18 forms the magnetic induction of regulation, rotate a circle and gather a secondary data in the working point, and the displacement of bar magnet in the thickness inductive coil in the thickness measure element depended in the variation of data volume.Thickness measure element 2 is made mechanical attachment with the pawl axle of stinging that signature is stung on the paper wheel, ferrite bar 10 is along with the signature thickness produces the telescopic change in thickness inductive coil 12 on its base, the magnetic field intensity of thickness induction part also produces corresponding variation thus, and be delivered to this quantitative change on the transmission inductive coil 6 of signal transmitting element 1 by connecting line, at this moment with thickness measure element 2 at a distance of thickness measurement sensor 3 its inductive coils of 0.7mm through the inductive coil of signal transfer part the time by the variation of space acquisition to magnetic field intensity. thickness measurement sensor 3 carries out qualitative comparative analysis by the electronic component amplification after A/F changes the microcomputer of giving in the thickness measurement sensor 3 with faint stable variable signal, last measurement result shows with LED and exports to peripheral control unit by attachment plug and handle, sensor control panel 16 is provided with 5 LED lamps, the result who represents current detection respectively is normal card or lacks card or thick card or thin card, also has 1 lamp to be used for being provided with the initial position of thickness measure element.

Claims (2)

1. a precision electromagnetic mutual inductive thickness-measuring apparatus is characterized in that, is made of signal transmitting element (1) and thickness measure element signal transmitting element (1), thickness measure element (2) and thickness measurement sensor (3)
(2) connect, the spacing L of being separated by between thickness measurement sensor (3) and the signal transmitting element (1) is 0.7mm-1mm, it is characterized in that,
Described signal transmitting element (1) is made up of electric capacity (4), printing forme (5), transmission inductive coil (6), two bar magnets (7) and shell (8), electric capacity (4) is connected with printing forme (5), be located at a side in the shell (8), two bar magnets (7) are in level angle and are located in the transmission inductive coil (6), and are located at the opposite side in the shell (8).
Described thickness measure element (2) is made up of housing (9), bar magnet (10), support (11) and thickness inductive coil (12), the bar magnet (10) that can move in thickness inductive coil (12) is fixed on the support (11), and thickness inductive coil (12) is located in the housing (9).
Described thickness measurement sensor (3) is by signal generation loop A (13), resonance coil A (14), shell (15), control panel (16), signal generation coil B (17), resonance coil B (18), gang socket (19), connecting line (20), lid (21) is formed, signal generation loop A (13) is connected the back and becomes an axis to be located at the upper and lower side of shell upside with signal generation coil B (17), two coil terminals are connected with control panel (16), resonance coil A (14) with also become after resonance coil B (18) is connected an axis be located at shell (15) upside about end. its two coil terminals is connected with control panel (16), control panel (16) level is located in the middle of the downside of shell (15), gang socket (19) is passed lid (21) by connecting line (20) and is connected with control panel (16), and lid (21) is fixing with shell (15).
2. a kind of precision electromagnetic mutual inductive thickness-measuring apparatus according to claim 1, it is characterized in that, described control panel (16) is made up of control panel power unit, control panel sender unit, control panel signal amplifier and control panel microcomputer data processing circuit, the control panel power unit is connected with control panel sender unit, control panel signal amplifier and control panel microcomputer data processing circuit respectively, control panel microcomputer data processing circuit is connected with the control panel sender unit, and the control panel sender unit is connected with the control panel signal amplifier.
CN200710038547A 2007-03-28 2007-03-28 Precision electromagnetic mutual inductive thickness-measuring apparatus Expired - Fee Related CN100578138C (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN200710038547A CN100578138C (en) 2007-03-28 2007-03-28 Precision electromagnetic mutual inductive thickness-measuring apparatus

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Application Number Priority Date Filing Date Title
CN200710038547A CN100578138C (en) 2007-03-28 2007-03-28 Precision electromagnetic mutual inductive thickness-measuring apparatus

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CN101025359A true CN101025359A (en) 2007-08-29
CN100578138C CN100578138C (en) 2010-01-06

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN116601452A (en) * 2020-12-11 2023-08-15 Abb瑞士股份有限公司 Pulsed eddy current system

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB8432438D0 (en) * 1984-12-21 1985-02-06 De La Rue Syst Sensing sheets

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN116601452A (en) * 2020-12-11 2023-08-15 Abb瑞士股份有限公司 Pulsed eddy current system

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