CN1264822A - Arc method for measuring orifice size of molten bath for plasma welding and signal acquisition system - Google Patents
Arc method for measuring orifice size of molten bath for plasma welding and signal acquisition system Download PDFInfo
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- CN1264822A CN1264822A CN 00103235 CN00103235A CN1264822A CN 1264822 A CN1264822 A CN 1264822A CN 00103235 CN00103235 CN 00103235 CN 00103235 A CN00103235 A CN 00103235A CN 1264822 A CN1264822 A CN 1264822A
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- 238000000034 method Methods 0.000 title claims description 29
- 238000003466 welding Methods 0.000 title claims description 22
- 230000002463 transducing effect Effects 0.000 claims description 16
- 238000010891 electric arc Methods 0.000 claims description 9
- 238000000926 separation method Methods 0.000 claims description 8
- 238000006243 chemical reaction Methods 0.000 claims description 7
- 238000012545 processing Methods 0.000 claims description 7
- 230000009466 transformation Effects 0.000 claims description 4
- 238000001514 detection method Methods 0.000 description 10
- 230000035515 penetration Effects 0.000 description 9
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- 238000010586 diagram Methods 0.000 description 4
- RYGMFSIKBFXOCR-UHFFFAOYSA-N Copper Chemical compound [Cu] RYGMFSIKBFXOCR-UHFFFAOYSA-N 0.000 description 3
- 229910052802 copper Inorganic materials 0.000 description 3
- 239000010949 copper Substances 0.000 description 3
- 230000000694 effects Effects 0.000 description 3
- 238000000605 extraction Methods 0.000 description 3
- 238000013480 data collection Methods 0.000 description 2
- 238000009413 insulation Methods 0.000 description 2
- 230000005855 radiation Effects 0.000 description 2
- 238000011160 research Methods 0.000 description 2
- 238000003860 storage Methods 0.000 description 2
- WFKWXMTUELFFGS-UHFFFAOYSA-N tungsten Chemical compound [W] WFKWXMTUELFFGS-UHFFFAOYSA-N 0.000 description 2
- 229910052721 tungsten Inorganic materials 0.000 description 2
- 239000010937 tungsten Substances 0.000 description 2
- 239000000956 alloy Substances 0.000 description 1
- 230000003321 amplification Effects 0.000 description 1
- 239000011324 bead Substances 0.000 description 1
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- 238000005266 casting Methods 0.000 description 1
- 230000003247 decreasing effect Effects 0.000 description 1
- 238000013461 design Methods 0.000 description 1
- 238000011161 development Methods 0.000 description 1
- 238000005516 engineering process Methods 0.000 description 1
- 238000002955 isolation Methods 0.000 description 1
- 238000003199 nucleic acid amplification method Methods 0.000 description 1
- 238000011017 operating method Methods 0.000 description 1
- 238000003908 quality control method Methods 0.000 description 1
- 238000011897 real-time detection Methods 0.000 description 1
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- 238000001228 spectrum Methods 0.000 description 1
- 239000010935 stainless steel Substances 0.000 description 1
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Abstract
A signal acquisition system is used to real-time acquire the voltage and current signals of plasma arc, which are then stored in computer. After said signals are processed, the quantitative sensed signal aboutthe orifice size of molten bath, which can be recognized by machine, is obtained. After the sensed signal is scaled, said orifice size can be rel-time obtained on the basis of the relation between the sensed signal and the orifice size. Its advantages are simple structure, high and feasibility.
Description
The invention belongs to plasma welding Quality Control Technology field.
In the high energy beam current, plasma-arc has advantages such as realizing easy and cheapness, is one of welding method of important structure and alloy material, especially is widely used at aerospace system.Utilize the big characteristics of plasma arc energy density and penetration power, the plasma welding can obtain " keyhole effect " under the suitable parameter condition, as shown in Figure 1, at this moment plasma arc forms an aperture 12 that penetrates workpiece workpiece 10 complete penetrations and by acting on of plasma jet power in the molten bath 11, and aperture is followed plasma arc and moved forward." keyhole effect " is the endemism in the plasma welding, helps the abundant penetration of weld seam.Yet the fluctuation of various condition standards is can hardly be avoided in the actual production process, certainly will influence the stability of orifice size, thereby cause the inconsistent of even weld, and this is more apparent outstanding in precision component processing.For this reason,, the research of real-time detection orifice size of molten bath has been proposed, so that the condition of necessity is provided for the automatic control of accurate penetration according to the needs of modern processing and manufacturing technical development.
At present both at home and abroad plasma welding deliver a child produce with research in adopt back side photoelectric detection method, the back side contacts conductive method, back side sound detection method, front lighting Zymography and positive CCD camera method to detect the molten bath state of boring a hole, can just carry out the detection of orifice size of molten bath but wherein have only back side photoelectric detection method to contact conductive method with the back side, whether other method can only be used for sensing molten bath aperture at present and exist slightly.Back side photoelectric detection method is to utilize the various photoelectric devices 21 that are placed in workpiece 20 back sides to detect the arc light radiation of the plasma flame flow 22 of passing aperture shown in Fig. 2 a, and the arc light radiation intensity is directly proportional with the size of molten bath aperture.Back side contact conductive method is shown in Fig. 2 b, be that a copper drafting board 23 is placed on workpiece 24 back sides and keeps certain distance with workpiece, when the molten bath aperture exists, passing the plasma flame flow 25 of aperture gets on the copper drafting board 23, because plasma flame flow has conductive characteristic, so with on the resistance R that copper drafting board 23 links to each other electric current will be arranged, an end U of rectifier then.Output will be arranged, and its size is proportional to the size in molten hole.The greatest drawback of these two kinds of detection methods is that sensor must be placed in back of work, and this makes it apply the restriction that is subjected to workpiece and working condition, and promptly the accessibility of sensor is very poor.
The objective of the invention is to for overcoming the weak point of prior art, propose a kind of detection method of from plasma electric arc voltage and flame current signal, extracting the orifice size of molten bath transducing signal.Effectively the size of sensing molten bath aperture can be the plasma of realizing cut deal and welds the feedback information that the automatic control of accurate penetration provides necessity.And system architecture is simple, accessibility is good, practicality is cheap, promotes the use of easily.
The arc method for measuring of a kind of orifice size of molten bath for plasma welding that the present invention proposes is characterized in that, may further comprise the steps:
1) at first utilize signal acquiring system that plasma electric arc voltage u (t)/flame current signal i (t) is gathered and be stored into computing machine in real time;
2) arc voltage/flame current signal of gathering is processed processing, obtaining can be for the quantitative orifice size of molten bath transducing signal pff (t) of machine recognition;
3) specifically demarcate pff (t) signal, according to the size of the real-time sensing of the proportionate relationship of pff signal and orifice size of molten bath molten bath hole dimension.
The method that said arc voltage/flame current signal to collection is processed processing comprises:
1) gets one section arc voltage signal u (t) (t=t
1~t
2)/flame current signal i (t) (t=t
1~t
2), at first right
It carries out the FFT conversion and the transformation results delivery is obtained | U (f) |/| I (f) |;
2) any one frequency separation search among following two frequency separation f=19kHz~20kHz and f=2.5kHz~3.5kHz then | U (f) |/| I (f) | in this interval maximal value, during maximal value | U (f) |/| I (f) | pairing frequency f is this interval transducing signal pff;
3) adopt above method in the whole time period, to handle u (t) or i (t) can get pff (t).
Principle of the present invention is because penetration degree of perforation when constantly changing along with the carrying out of welding process, will inevitably the article on plasma arc shape and behavior exert an influence, therefore just might extract relevant information from electric arc feeds back degree of perforation.
Method of the present invention realizes principle as shown in Figure 3.At first utilize signal acquiring system that plasma electric arc voltage u (t)/flame current signal i (t) is gathered and be stored into computing machine in real time reliably.Arc voltage and flame current signal itself can not be as transducing signal and directly in order to detect the size of molten bath aperture, but arc signal is carrying the characteristic information that can reflect the molten bath degree of perforation, this characteristic information is handled by the processing of the transducing signal extracting method-pff algorithm of the present invention's exploitation, and just having obtained can be for the quantitative orifice size of molten bath transducing signal pff of machine recognition.Concrete demarcate the pff signal after, according to the proportionate relationship of pff signal and the orifice size of molten bath size of sensing molten bath hole dimension in real time just.Orifice size of molten bath transducing signal extraction algorithm is a gordian technique of the present invention, is that the mode by software realizes on computers.Below introduce the implementation method of signal acquiring system and transducing signal extraction algorithm.
Plasma electric arc voltage of the present invention/flame current signal acquiring system is made up of voltage sensor/current sensor, low-pass filter circuit, data collecting card, computing machine and relevant interface, as shown in Figure 4, among the figure, arc voltage/flame current signal is at first introduced the input end of voltage sensor/current sensor, the input end of the output termination low-pass filter circuit of voltage sensor/current sensor, the input terminal of the output termination data collecting card of low-pass filter circuit, data collecting card directly inserts the associated socket of computing machine.Wherein, arc voltage signal is directly by drawing between welding gun tungsten electrode 40 and the workpiece 41, the high-frequency high-voltage signal that voltage sensor/current sensor produces when isolating the welding striking, low-pass filter circuit filtering high-frequency interferencing signal, data collecting card is finished signals collecting, analog to digital conversion in conjunction with the data collection application of the present invention's exploitation, and utilizes the interface of capture card and computing machine to realize the storage of signal in computing machine.
Below be the algorithm flow that from the spectrum information of arc voltage/flame current signal, extracts orifice size of molten bath transducing signal pff, as shown in Figure 5:
Get one section arc voltage u (t) (t=t
1~t
2)/flame current signal i (t) (t=t
1~t
2), at first it is carried out the FFT conversion and the transformation results delivery is obtained | U (f) |/| I (f) |, then respectively in following two frequency separation f=19kHz~20kHz and f=2.5kHz~3.5kHz search | U (f) |/| I (f) | in this interval maximal value, during maximal value | U (f) |/| I (f) | pairing frequency f is this interval transducing signal pff.Adopt above method in the whole time period, to handle u (t)/i (t) and can get pff (t).
The Pff value is along with the increase of orifice size of molten bath increasing or decreasing gradually.According to the dull characteristics of pff signal, can concern the hole dimension size in real-time sensing molten bath according to the quantitative ratio of pff signal and orifice size of molten bath by after concrete the demarcation.
The present invention can select for use one as the signal source of extracting transducing signal from arc voltage and flame current signal arbitrarily, and can choose one wantonly from frequency separation f=19kHz~20kHz and f=2.5kHz~3.5kHz and extract the pff signal.When frequency separation is identical, adopt arc voltage still be the flame current signal result that extracts pff as signal source be consistent.
Detection method of the present invention is the size of sensing molten bath aperture effectively, can be the plasma of realizing cut deal and welds the feedback information that the automatic control of accurate penetration provides necessity.This method is applicable to the inverter type welder to be the plasma welding termination process of thermal source, owing to directly utilized electric arc as sensor source signal, therefore has advantages such as system architecture is simple, accessibility good, practical cheapness, promotes the use of in the actual production manufacturing easily.
Brief Description Of Drawings:
Fig. 1 obtains " keyhole effect " synoptic diagram under the suitable parameter condition for plasma welding is connected on.
Fig. 2 is the welding pool orifice size detection method synoptic diagram of prior art.Wherein, Fig. 2 a is a back side photoelectric detection method, and Fig. 2 b is a back side contact conductive method.
Fig. 3 is that method of the present invention realizes theory diagram.
Fig. 4 is plasma electric arc voltage of the present invention/flame current signal acquiring system structural representation.
Fig. 5 is a transducing signal pff extraction algorithm FB(flow block) of the present invention.
Fig. 6 is the low-pass filter circuit schematic diagram of embodiments of the invention.Among the figure, I is an arc voltage ratio amplifying circuit, and II is a flame current ratio amplifying circuit, and III is the arc voltage low-pass filter circuit, and IV is the flame current low-pass filter circuit.
Fig. 7 is the pff algorithm software realization flow figure of present embodiment.
Fig. 8 a is the gradient thickness Workpiece structure figure of present embodiment,
Fig. 8 b is that the back of weld of Fig. 8 a correspondence is shaped,
Transducing signal pff (t) curve map of Fig. 8 c for obtaining from workpiece shown in Fig. 8 a.
The arc method for measuring and the signal acquiring system embodiment of a kind of orifice size of molten bath for plasma welding of the present invention's design are described with reference to the accompanying drawings as follows:
Consider the variation of conditions such as radiating condition in the actual production, thickness of workpiece and welding conditions, adopt the workpiece of gradient thickness, the workpiece thickness is 8mm, thinnest part is 3mm, welding conditions are set are the thick 6mm of the workpiece place penetration of be able to boring a hole, use inverter type welder on stainless steel work-piece, to weld.The back of weld shaping of gradient thickness workpiece and correspondence thereof shown in Fig. 8 a and Fig. 8 b, can see that back bead grows out of nothing respectively, and gradually by thin chap, obviously the molten bath has experienced the process of changing from small to big to degree of perforation from puncherless.
The signal acquiring system of present embodiment is made up of the interface and the computing machine of voltage/current sensor, filtering amplitude limiter circuit, data collecting card, computing machine, as shown in Figure 4.Arc voltage signal is directly by drawing between welding gun tungsten electrode 40 and the workpiece 41.Arc voltage/flame current signal at first passes through the buffer action of voltage/current sensor, voltage/current sensor is selected magnetic balance type voltage/current sensor " the sea KV100A of section "/" the sea KT200A of section " for use, its former limit circuit and secondary circuit insulation, insulation voltage is the 6000V effective value, the high-frequency high-voltage signal in the time of can effectively isolating the welding striking; Introduce low-pass filter circuit as shown in Figure 6 through the arc signal after isolating by input connector 1, signal is at first decayed shown in II among I/ Fig. 6 among Fig. 6 by the ratio amplifying circuit, to offset the amplification of filtering circuit to signal, pass through the voltage-controlled active low-pass filter circuit filtering of second order high-frequency interferencing signal then shown in III, IV among Fig. 6, the cutoff frequency of filtering circuit is 10kHz, last signal is exported to data collecting card by the output connector, and whole low-pass filter circuit is powered by input connector 2 by D.C. regulated power supply; Arrive data collecting card reliably through isolation and filtered arc voltage/flame current signal, data collecting card is selected " PCI-9118HG " for use, 12 of precision, picking rate 330kHz, each image data capacity can reach 64M, data collecting card is finished signals collecting in conjunction with the data collection application of the present invention's exploitation, analog to digital conversion, and utilize the interface of capture card and computing machine to realize the storage of signal in computing machine.
The method concrete steps of present embodiment are: at first with the sample frequency of 40kHz the arc voltage in the welding process/flame current signal is gathered computing machine in real time by the signal acquiring system of present embodiment.Adopting pff algorithm shown in Figure 5 that the arc voltage/flame current signal that deposits in the computing machine is handled subsequently, is that the interval f=2.5k of signal source and selecting frequency~3.5k extracts the pff signal with the flame current at this.Fig. 7 is the software realization flow figure of present embodiment, its operating procedure is: at first call in the flame current signal i (t) that collects from computing machine, getting nfft=8192 data point according to the time sequencing of welding then from i (t), to constitute a length be 8192 data segment utemp.Calculate the average of this data segment flame current signal, the flame current signal that deducts after the average is idm, and this step is that signal is done pre-service before the FFT conversion.Idm is done the FFT conversion and the transformation results delivery is obtained | I (f) |, then seek at frequency separation f=2.5k~3.5k | I (f) | in this interval maximal value, during maximal value | I (f) | pairing frequency f is the pff value of this section flame current signal.Obtain casting out after the pff value delay=500 point of data segment utemp section head, order inserts 500 new data to reconstitute a length is 8192 data segment from i (t) again, judge whether to have finished predefined calculation times k then, be whether j value (being set to 1 when program begins) equals k, if " be not equal to " then the j value increases by 1, repeat above computing; If " equaling " then withdraws from circular treatment, obtained transducing signal pff (t) this moment shown in Fig. 8 c, and horizontal ordinate is the time among Fig. 8 c, and unit is s, and ordinate is the amplitude of pff signal, and unit is Hz.Realize that with software the programmed environment of above algorithm is Matlab 5.01.
Set the orifice size of molten bath threshold interval, when pff value was arranged in interval 3150Hz~3180Hz, the judgement molten bath was puncherless not penetration state; When the pff value is positioned at 3000Hz~3060Hz when interval, judge that the molten bath aperture is excessive; And the pff orifice size has good corresponding quantitative ratio relation in 3060Hz~3150Hz interval, according to this proportionate relationship pff signal size of sensing molten bath hole dimension in real time just.
Claims (3)
1, a kind of arc method for measuring of orifice size of molten bath for plasma welding is characterized in that, may further comprise the steps:
1) at first utilize signal acquiring system that plasma electric arc voltage u (t)/flame current signal i (t) is gathered and be stored into computing machine in real time;
2) arc voltage/flame current signal of gathering is processed processing, obtaining can be for the quantitative orifice size of molten bath transducing signal pff (t) of machine recognition;
3) specifically demarcate pff (t) signal, concern the size of real-time sensing molten bath hole dimension according to the quantitative ratio of pff signal and orifice size of molten bath.
2, arc method for measuring as claimed in claim 1 is characterized in that, the method that said arc voltage/flame current signal to collection is processed processing comprises:
1) gets one section arc voltage signal u (t) (t=t
1~t
2)/flame current signal i (t) (t=t
1~t
2), at first it is carried out the FFT conversion and the transformation results delivery is obtained | U (f) |/| I (f) |;
2) any one frequency separation search among following two frequency separation f=19kHz~20kHz and f=2.5kHz~3.5kHz then | U (f) |/| I (f) | in this interval maximal value, during maximal value | U (f) |/| I (f) | pairing frequency f is this interval transducing signal pff;
3) adopt above method in the whole time period, to handle u (t) or i (t) can get pff (t).
3, the plasma electric arc voltage/flame current signal acquiring system in a kind of method according to claim 1 is made up of voltage sensor/current sensor, low-pass filter circuit, data collecting card, computing machine and relevant interface, wherein, arc voltage/flame current signal is introduced the input end of voltage sensor/current sensor, the input end of the output termination low-pass filter circuit of voltage sensor/current sensor, the input terminal of the output termination data collecting card of low-pass filter circuit, data collecting card directly inserts the associated socket of computing machine.
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CN 00103235 CN1111721C (en) | 2000-03-17 | 2000-03-17 | Arc method for measuring orifice size of molten bath for plasma welding and signal acquisition system |
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CN1264822A true CN1264822A (en) | 2000-08-30 |
CN1111721C CN1111721C (en) | 2003-06-18 |
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