KR19980079934A - Positive charging state detection device for positive charging wire - Google Patents

Abstract

The bridge circuit includes a coil for a test wire and a coil for a reference wire connected in series. The signal processing circuit obtains the flux charge state detection output from the output of the bridge circuit and decreases the detection output caused by the running of the wire under test irrespective of the constant flux charge rate from the output of the wire traveling speed detector for the wire under test. Obtain the correction output corresponding to The signal processing circuit outputs the flux charge state detection output corrected by the correction output. The judging circuit compares the output of the signal processing circuit with the comparison level to determine whether the flux-charged state of the inspected wire is allowed. The flux charge state detection device for flux charge wires includes a bridge circuit, a wire traveling speed detector, a signal processing circuit, and a determination circuit.

Description

Flux charge state detection device for flux charge wire

FIELD OF THE INVENTION

The present invention relates to a flux charge state detection device for detecting a flux charge state of an arc welding flux charge wire by using electromagnetic induction while driving a wire.

Description of the Prior Art

In the arc welding flux filling wire, as shown in Figs. 7A and 7B, which illustrate the cross-sectional shape of the wire, for example, a metal sheath M made of steel sheath, etc., has a flux F inside thereof. It is filled with. 8 is an explanatory view of a wire forming and drawing step in the flux filling wire manufacture. As shown in the figure, the metal base plate M 'formed of thin steel strips continuously fed is formed by the forming roller 51 to form bends on both sides of the base plate in the width direction of the base plate to form a metal shell having a rounded cross section ( The metal sheath M is filled with flux while molding into M). Then, the flux-filled wire shaped into a wire shape is thinned with a drawing machine 52 to obtain a flux-filled wire having a specific diameter. In the wire drawing step following the wire forming drawing step, the flux filling wire is drawn to make a flux filling wire product having a diameter generally in the range of 0.9 mm to 1.6 mm.

The flux filling wire obtained in the wire forming drawing process includes a portion having no flux due to poor wire connection, or a portion having a flux filling rate lower than the reference value (weight percent of the flux relative to the weight of the total wire per unit length). Therefore, it is necessary to detect the absence of flux that adversely affects the quality of the weld and to remove it from the wire product.

Conventional flux filling rate measuring apparatus for measuring flux filling rate of flux filling wire by using electromagnetic induction while driving the wire is used in wire forming and drawing process, including those disclosed in Japanese Patent Application Laid-Open No. 4-15904. This flux filling rate measuring device will be described below.

The relationship between the wall thickness of the metal sheath of the flux filling wire and the flux filling rate will be described first. The flux filling wire tends to expand in the inner diameter direction because its outer diameter is regulated and fresh. The metal sheath becomes thick when a small amount of flux is filled and the metal sheath becomes thin when a large amount of flux is filled, because the sheath is thickened by the flux charged inside. In other words, in the flux filling wire having a specific diameter of wire (outer diameter), the wall thickness of the metal sheath is inversely proportional to the flux filling rate. The metal sheath becomes thicker as the flux filling rate decreases, and the metal sheath becomes thinner as the flux filling rate increases.

As shown in Fig. 9, the conventional flux charge rate measuring apparatus includes an LC oscillation circuit 61 formed of a through-type coil L, capacitors C1 and C2, and a transistor T, and an LC oscillation circuit ( As a DC output voltage (flux charge state detection output) from 61, it includes a rectifier circuit 62 for causing a change in oscillation intensity corresponding to a change in the impedance of the coil L. The inspection head having the coil L is arranged at the inlet side of the winding machine (winding bobbin) 53 of the wire forming and drawing process shown in FIG. For example, the inspection wire running at a speed of several hundred meters per minute is designed to pass through the coil (L). When a high frequency AC current flows through the coil L, an overcurrent occurs in the metal sheath of the inspected wire with electromagnetic induction, and a magnetic field is generated by the overcurrent, thereby changing the impedance of the coil L.

At low flux fill rates, the metal sheath becomes thick and large overcurrents are generated. The impedance of the coil L is substantially lowered and the flux charge state detection output (voltage output from the flux charge rate measuring apparatus) is low. In contrast, at high flux fill rates, the metal sheath becomes thinner. The degree of degradation in the impedance of the coil L is low and the detection output is higher than in the case of low flux charge rate. As described above, the use of electromagnetic induction yields a flux charge rate detection output proportional to the flux charge rate.

When the flux charging state of the flux charging wire is detected by the use of electromagnetic induction, the inspected wire is driven with respect to the coil. The coil impedance is smaller than when the wire under test is stopped, and the flux charge state detection output (output voltage) decreases almost in inverse proportion to the running speed of the wire under test even though the flux charge rate does not change.

In the wire forming and drawing process, the running speed of the inspected wire passing through the coil gradually increased obliquely after the start of wire production as shown in FIG. 10A and reached a constant speed after the running increase time t of about 20 to 30 seconds. The flux charge state detection output of the conventional measuring device changes as shown by the solid line in FIG. 10B irrespective of the constant flux charge rate. It is not clear why the detection output decreases with the running of the wire under test (regardless of the constant flux filling rate) (and the reason why the slope of the output drop changes during the period t as indicated by the solid line in Fig. 10b), It may also depend on the tension on the wire under test. In FIG. 10B, the dotted line shows the detection output of the flux free portion of the wire under test.

If a conventional flux charge rate measuring device is used for the wire forming wire process, and the method is used to compare the flux charge state detection output with the comparison level set above and the detection output is less than the comparison level, it is determined that the portion without flux is found. As shown in Fig. 10B, it is so small during the driving increase time t that the portion without flux at the driving increase time t cannot be detected.

1 is a view showing the electrical configuration of the flux charge state detection apparatus according to an embodiment of the present invention.

FIG. 2 shows the voltage waveform obtained at each point when a portion having sufficient flux of the wire to be inspected passes through the coil for inspection wire of the flux-charge state detecting apparatus shown in FIG. 1.

FIG. 3 shows the voltage waveform obtained at each point when a portion having no flux of the inspected wire passes through the coil for inspected wire of the flux-charge state detecting device shown in FIG.

4A and 4B are views for explaining the operation of the flux charge state detection output correction circuit shown in FIG.

5A and 5B are diagrams for explaining the output of the signal processing circuit shown in FIG.

6A and 6B are voltage waveforms for explaining the operation of the determination circuit shown in FIG.

7A and 7B are cross-sectional views of the flux filling wire.

FIG. 8 shows a forming and stretching process of a wire for producing a flux filling wire. FIG.

9 is a general view of a conventional flux fill factor measuring apparatus.

10A and 10B are diagrams for explaining a decrease in the flux charge state detection output caused by the running of the wire under test.

Summary of the Invention

The present invention has been made to solve the above problems. Therefore, the object of the present invention is to detect the flux charging state of the flux filling wire by using the electromagnetic induction while the wire is running, and to increase the running time of the inspected wire at the start of the wire manufacturing and the restart of the wire manufacturing after the poor connection of the wire. A flux charge state detection device capable of reliably detecting a flux charge state is provided.

The object of the present invention is to provide a flux charge state detection device for a flux charge wire that detects a flux charge state of an arc welding flux charge wire by using electromagnetic induction while the wire is running. Inspection wire coils; A coil for the reference wire in which the reference wire appropriately filled with flux is in a stationary state; A bridge circuit in which a coil for a test wire and a coil for a reference wire are connected in series to form two of four surfaces of a bridge circuit, and a connection point between the two coils is used as an output terminal to the ground point and AC current flows; A wire traveling speed detector for detecting a traveling speed of the wire under test and outputting a traveling speed signal; The flux charge state detection output corresponding to the difference between the impedance of the coil for the reference wire and the impedance of the coil for the inspection wire varying with the flux charging state is obtained from the signal output from the bridge circuit and caused by the running of the inspection wire. A signal processing circuit which obtains a correction output corresponding to a decrease in the flux charge state detection output from the output of the wire traveling speed detector and outputs the flux charge state detection output corrected by the correction output; And a judging circuit for comparing the output of the signal processing circuit with the set comparison level to determine whether the flux-charged state of the inspected wire is permitted.

In a flux charge state detecting apparatus for flux charge wires, the signal processing circuit includes a phase adjusting circuit for obtaining a signal having a phase changed from a phase of an AC excitation voltage signal applied to a bridge circuit; A phase discriminating circuit for discriminating the phase of the signal output from the bridge circuit using the signal output from the phase adjusting circuit and merely obtaining a flux charged state detection output corresponding to the flux charged state of the inspected wire; And a flux that is proportional to the output of the received wire traveling speed detector and has a gradient that changes slowly after one transition point of the broken line within the traveling increase time of the inspected wire as a correction output to the flux charge state detection output. The state detection output correction circuit may be included.

The flux charge state detection device according to the present invention includes a wire traveling speed detector for detecting a traveling speed of the wire to be inspected. The correction output (see Fig. 4b) corresponding to the decrease in flux charge state detection output caused by the running of the wire under test is obtained from the output of the wire traveling speed detector (see Fig. 4a) and obtained from the output signal of the bridge circuit. Flux charge state detection output (indicated by the dotted line in Fig. 5A) and corrected for the decrease in the detection output caused by the running itself of the inspected wire irrespective of the constant flux charge rate (solid line in Fig. 5A). Is obtained). As shown in Fig. 5B, since the corrected flux charge state detection output sent from the signal processing circuit is compared with the comparison level set above, the flux is increased even at the time of increasing the running time of the inspected wire at the start of wire manufacture or at the restart of manufacture after a poor wire connection. The state of charge is reliably detected.

In the flux charge state detecting device according to the present invention, a flux free wire is used as a reference sample disposed in the coil for the reference wire in a stationary state, but a reference wire suitably filled with flux is used. If a flux free wire is used, it is necessary to manufacture a flux filled wire that includes a flux free portion in the same production lot as the wire under test and to find a flux free portion. It takes a lot of time to produce a flux-free wire. In contrast, since the reference wire can be manufactured in the same production rat as the wire under test, it is easy to obtain the shape of the reference wire almost identical to the shape of the wire under test. The difference in shape between the wire under test and the reference wire causes a signal that acts with a different noise than the signal corresponding to the flux charging state.

As described above, according to the flux charge state detection device for flux charge wire of the present invention, it uses the electromagnetic induction while the wire is running to detect the flux charge state of the flux charge wire, because the flux charge state detection output is the wire under test. Obtained from a signal output from a bridge circuit having a coil for it; Regardless of the constant flux filling rate, a correction output corresponding to a decrease in the flux charge state detection output caused by the running of the wire under test is also obtained from the output of the wire traveling speed detector for the wire under test. The deterioration amount is corrected by this correction output, and the flux charge state is reliably detected even at the time of increasing the running time of the inspected wire at the start of wire manufacture or at restart of manufacture after a poor wire contact.

Description of the Preferred Embodiments

Embodiments of the present invention will be described below with reference to the drawings. 1 is a view showing the electrical configuration of the flux charge state detection apparatus according to an embodiment of the present invention.

Fig. 1 shows a passing type for the reference wire 2 in which the pass-through coil 4 for the inspection wire 1 through which the inspection wire 1 passes and the reference wire 2 suitably filled with flux are stationary. Coil 5 is shown. An inspection head (not shown) including these coils 4 and 5 is disposed at the inlet side of the winder 53 in the wire forming and drawing step shown in FIG.

The bridge circuit 3 is formed of a coil for inspection wire 4 composed of two adjacent surfaces connected in series, a coil for reference wire 5, and resistors 6 and 7 constituting the remaining two adjacent surfaces. do. In this embodiment, the oscillator 8 provides an AC current of 10 kHz to the bridge circuit 3. In the bridge circuit 3, the connection point between the coils 4 and 5 is used as the output terminal to the ground point and the output terminal allows the outer surface of the bridge to be connected to the transistor amplification circuit 12 of the phase discriminating circuit 11. . A bias circuit (not shown) applies a bias voltage so that the output of the bridge circuit 3 has a positive value (see 2 in FIG. 2 and 2 in FIG. 3). The wire traveling speed detector 18 detects the traveling speed of the wire under test 1 and outputs a traveling speed signal. In this embodiment, the detector is formed of a DC type speed generator. It is provided in the roller (not shown) which detects the wire traveling speed arrange | positioned in the position just before a test head by the wire entrance side.

The phase adjusting circuit 10 obtains a signal having a phase changed from the phase of the AC excitation voltage signal applied to the bridge circuit 3. The phase discriminating circuit 11 discriminates the phase of the signal output from the bridge circuit 3 using the signal output from the phase adjusting circuit 10. That is, the phase discriminating circuit 11 removes the signal generated by the temperature change of the wire under test 1 from the signal output from the bridge circuit 3 by the temperature change of the wire under test, so as to match the impedance of the coil 5 for the reference wire. The flux charge state detection output (output voltage) corresponding to the difference in the impedance of the coil for inspection wire 4 that varies depending on the flux charge state is obtained. The flux charge state detection output correcting circuit 17 is used in accordance with the output of the wire traveling speed detector 18 to correct the detection output for the degradation caused by the traveling itself of the inspected wire 1 irrespective of the constant charging rate. The correction output is output by adding to the detection output of the flux charging state.

As shown in Fig. 1, the phase discriminating circuit 11 includes a transistor amplifying circuit 12 and a phase adjusting circuit 10 having a transistor Q1 (not shown) to which a signal output from the bridge circuit 3 is input. A transistor switching circuit 13, two from the phase adjusting circuit 10, having a transistor Q2 (not shown) which is operated when receiving one of the two signal outputs from the transistor Q1 and connected in series with the transistor Q1; Transistor switching circuit 14, an operational amplifier (not shown), which operates when a signal output having a phase different from that of the signal output is received and has a transistor Q3 (not shown) connected in series with transistor Q1. ), A signal corresponding to the signal output from the bridge circuit 3 when the transistor Q2 is ON is input to the positive input terminal through the resistor R1 and from the bridge circuit 3 when the transistor Q3 is ON. Corresponds to signal output Is provided with a differential amplifier circuit 15 through which a signal is input to the negative input terminal through a resistor R2, and a voltage bias circuit 16 for applying a positive bias voltage to the positive input terminal of the differential amplifier circuit 15. have.

The signal processing circuit 9 is composed of a phase adjusting circuit 10, a phase discriminating circuit 11, and a correction circuit 17. In the signal processing circuit 9, the flux charge state detection output is obtained from the signal output from the bridge circuit 3, and the correction output corresponding to the decrease in the detection output caused by the running itself of the wire under test 1 is wired. The flux charge state detection output obtained according to the output of the traveling speed detector 18 and corrected by the correction output is output.

In addition, there is a determination circuit 19 for judging whether the flux-charged state of the inspected wire 1 is permitted by comparing the output of the signal processing circuit 9 with the set comparison level, and the portion without the flux is the inspected wire. An alarm circuit 20, in which a lamp is lit or ringed to inform an alarm when it is found in (1), and a recorder 21 such as a pen recorder for recording the output of the signal processing circuit 9 is shown.

The operation of the flux charge state detection device having the above structure will be described below with reference to the drawings. FIG. 2 shows the voltage waveform obtained at each point when a portion having sufficient flux of the inspected wire passes through the coil for inspected wire of the flux-charge state detecting apparatus shown in FIG. FIG. 3 shows the voltage waveform obtained at each point when a portion having no flux of the inspected wire passes through the coil for inspected wire of the flux charge state detecting apparatus shown in FIG.

The AC excitation sine voltage signal (10 kHz in this embodiment) shown in ① in FIG. 2 and ① in FIG. 3 is applied from the oscillator 8 to the bridge circuit 3 as well as the phase control circuit 10. The phase adjusting circuit 10 is a square wave signal having a phase advanced 90 degrees from the phase of the AC excitation voltage signal applied to the bridge circuit 3, as shown in 3 and 3 in FIG. As shown in ④ of FIG. 3, a square wave signal having a phase delayed 90 degrees from the phase of the AC excitation voltage signal is generated and applied to the phase discriminating circuit 11.

How the phase discrimination circuit 11 operates when a portion having sufficient flux of the wire to be inspected passes through the coil 4 for wires to be inspected will be described below with reference to FIGS. 1 and 2. The output signal of the bridge circuit 3 shown in 2 in FIG. 2 has the same phase as the AC excitation voltage signal shown in 1 in FIG. In the phase discriminating circuit 11, the output signal of the bridge circuit 3 is input to the base of the transistor Q1 of the transistor amplifying circuit 12. The square wave signal shown by 3 in FIG. 2 is input to the base of the transistor Q2 of the transistor switching circuit 13. The square waveform signal shown in ④ of FIG. 2 is input to the base of the transistor Q3 of the transistor switching circuit 14.

The positive input terminal voltage (voltage at the point ⑤) input to the positive input terminal of the differential amplifier circuit 15 through the resistor R1 and a smoothing circuit (not shown) has a waveform shown in ⑤ in FIG. The negative input terminal voltage (voltage at the point ⑥) input to the negative input terminal of the differential amplifier circuit 15 through the resistor R2 has a waveform shown in ⑥ in FIG.

As a result, the voltage difference between the points ⑤ and ⑥ of the phase discrimination circuit 11 has a zero average voltage as indicated by the solid line at the bottom of FIG. Since the voltage bias circuit 16 applies the positive bias voltage Eb to the positive input terminal of the differential amplifier circuit 15, the differential amplifier circuit 15 is in a flux-charged state as indicated by the dotted line at the bottom of FIG. The positive DC voltage e ₁ is output as the detection output. Signal output from the differential amplification circuit 15 because a smoothing circuit (not shown) is provided between the positive input terminal and the resistor R1 of the differential amplifier circuit 15 and between the negative input terminal and the resistor R2. Actually has a linear voltage with a small ripple. As described above, the flux charge state detection output is obtained when the portion having sufficient flux of the wire under test 1 passes through the coil 4 for wire under test.

How the phase discrimination circuit 11 operates when the flux-free portion of the wire under test 1 passes through the coil 4 for the wire under test will be described below with reference to FIGS. 1 and 3. The output signal of the bridge circuit 3 shown in 2 in FIG. 3 has a phase (the same phase as the square wave signal shown in 3 in FIG. 3) 90 degrees from the phase of the AC excitation voltage signal shown in 1 in FIG. The positive input terminal voltage (voltage at point ⑤ of circuit 11) of differential amplifier circuit 15 has a waveform shown in ⑤ in FIG. The negative input terminal voltage (voltage at the point 6) of the operational amplifier A1 has a waveform shown in 6 in FIG.

As a result, the voltage difference between the points ⑤ and ⑥ of the phase discrimination circuit 11 has a negative average voltage as indicated by the solid line at the bottom of FIG. Since the positive bias voltage Eb is applied to the voltage difference, the differential amplifier circuit 15 outputs a positive DC voltage e ₂ smaller than e ₁ as the flux charge state detection output as indicated by the dotted line at the bottom of FIG. . As described above, when the flux-free portion of the wire to be inspected passes through the coil 4 for wires to be inspected, the phase discriminating circuit 11 is lower than the output when the portion having sufficient flux passes through the coil. Outputs a positive DC voltage.

The flux charge state detection output correction circuit 17 for inputting a correction voltage to the positive input terminal of the differential amplifier circuit 15 of the phase discriminating circuit 11 will be described next. Wire running speed detection roller (not shown) disposed at the inlet side of the wire just before the wire 4 to be inspected at the inlet side of the wire during the wire forming and drawing process after the wire manufacturing starts drawing the wire. When it reaches, the wire traveling speed detector 18 installed on the roller outputs a voltage corresponding to the traveling speed of the inspected wire 1 shown in Fig. 4A to the correction circuit 17, and the traveling speed is about 20 to 30 seconds. A steady steady speed is reached after increasing time t.

In order to correct the flux charge state detection output for the decrease caused by the running itself of the inspected wire 1 as described above, the correction circuit 17 outputs a correction output to the positive input terminal of the differential amplifier circuit 15. The output is proportional to the output of the wire traveling speed detector 18, and as shown in Fig. 4B, the gradient varies from ΔE1 to ΔE2 as a broken line within the running increase time t of the wire under test 1. Have The broken line characteristic shown in FIG. 4B is realized by the use of a resistor and a zener diode, for example. In Fig. 10B, the flux charge state detection output without correction is approximated by a broken line at the running increase time t. More precisely, it is expressed as a quadratic function curve that can be approximated by a line. Therefore, the correction circuit 17 may be formed as a function calculation circuit and may be made to output a signal which increases in the quadratic function curve at the driving increase time t as a correction output for the output of the wire traveling speed detector 18.

As described above, the signal processing circuit 9 detects the corrected flux charge state indicated by solid lines in FIGS. 5A and 5B, in which the detected output degradation caused by the running of the inspected wire 1 is corrected irrespective of the constant flux charge rate. Generate the output.

6A and 6B show voltage waveforms used for explaining the operation of the judgment circuit 19 shown in FIG. The signal processing circuit 9 sends the corrected flux charge state detection output shown in Fig. 6A to the determination circuit 19. In the present embodiment, the judging circuit 19 includes a comparison amplifier formed of a capacitor and a resistor and used as a comparator (not shown) which differentiates the output of the signal processing circuit 9 and a comparator.

In the judging circuit 19, the differentiator outputs a differential pulse when the output of the signal processing circuit 9 falls. The comparison amplifier compares the differential pulse with the comparison value R set above as the comparison level (see Fig. 6B). When the differential pulse indicating the degree of degradation of the output of the signal processing circuit 9 is larger than the reference value R, a portion without flux is found in the wire to be inspected 1 and the portion is applied to the coil 4 for the wire to be inspected. The alarm circuit 20 generates an alarm by determining that it has reached. The end of the portion without flux can be recognized from the comparison result between the reference value R and the differential pulse output at the increasing edge of the separated output of the signal processing circuit 9 as shown in FIG. 6B. In this comparison, the beginning and end of the portion without flux are displayed. The part can be removed from the wire under test 1, for example, in a wire rewinding process. In this embodiment, the judging circuit 19 is provided with a differentiator to more reliably detect the flux charging state. The judging circuit is made so that the differentiator is omitted and the comparison amplifier compares the reference value with the output of the signal processing circuit 9. The output of the signal processing circuit 9 is also sent to the recorder 21 for recording.

As described above, the flux charge state detection device reliably detects the flux charge state even at the increased time t of the inspected wire at the start of wire manufacture in the wire forming and drawing process or at the restart of manufacture after a poor wire connection.

As described above, according to the flux charge state detection device of the flux charge wire according to the present invention, in the device for detecting the flux charge state of the flux charge wire using an electromagnetic induction phenomenon while driving the wire, The flux charge state detection output is derived from the output signal of the bridge circuit with the coil, while the flux itself is generated by the running itself of the inspected wire generated despite the constant flux charge rate based on the output of the wire traveling speed detector of the inspected wire. Since the correction output corresponding to the decrease in the flux charge state detection output is obtained and the decrease in the detection output is compensated by the correction output, the inspection wire travels at the beginning of wire manufacture or start of manufacture after disconnection of the wire. Even in the increase time, it is possible to assure the good and bad of the flux charge state. It can detect, and it can surely eliminate inflow of a defective wire to a product.

Claims (2)

A flux charge state detection device for flux charge wires for detecting the flux charge state of an arc welding flux charge wire using electromagnetic induction while the wire is running: A coil for inspected wire through which the inspected wire traveling passes; A coil for reference wire in which the reference wire properly filled with flux is in a stationary state; A bridge circuit in which the coil for a test wire and the coil for a reference wire are connected in series to form two of four surfaces of a bridge circuit, and a connection point between the two coils is used as an output terminal to the ground point and AC current flows; A wire traveling speed detector for detecting a traveling speed of the wire to be inspected and outputting a traveling speed signal; From the signal output from the bridge circuit, a flux charge state detection output corresponding to a difference between the impedance of the coil for wire and the impedance of the wire to be inspected that varies with the flux charge state is obtained, and the output of the wire traveling speed detector A signal processing circuit for obtaining a correction output corresponding to a decrease in the flux charge state detection output caused by the running itself of the inspected wire and outputting the flux charge state detection output corrected by this correction output; And a determination circuit for determining whether or not to allow the flux charging state of the inspected wire by comparing the output of the signal processing circuit with the set comparison level. The signal processing circuit of claim 1, wherein the signal processing circuit comprises: a phase adjusting circuit for obtaining a signal having a phase changed from a phase of an AC excitation voltage signal applied to the bridge circuit; A phase discriminating circuit for discriminating the phase of the signal output from the bridge circuit using the signal output from the phase adjusting circuit and merely obtaining a flux charge state detection output corresponding to the flux charge state of the inspected wire; And flux charging for output as a correction output having a gradient which is proportional to the output of the wire traveling speed detector received in addition to the flux charge state detection output and has a slowly varying gradient after one transition point of the broken line within the driving increase time of the inspected wire. A flux charge state detection device for a flux charge wire, comprising a state detection output correction circuit.