WO2020237989A1 - Fast-frequency pulse tig welding system - Google Patents

Abstract

A fast-frequency pulse TIG welding system, comprising a fast-frequency pulse TIG welding power source, the fast-frequency pulse TIG welding power source comprising a main circuit, a control circuit and a man-machine interaction system. The main circuit comprises a power frequency rectifying and filtering module, a pulse current main circuit, a background current main circuit and a high-frequency current switching circuit; the pulse current main circuit comprises a SiC full-bridge inverse current conversion module I, a high-frequency voltage transformation module I and a SiC rectifying and smoothing module I which are sequentially connected; the background current main circuit comprises a SiC full-bridge inverse current conversion module II, a high-frequency voltage transformation module II and a SiC rectifying and smoothing module II which are sequentially connected; the high-frequency current switching circuit comprises a high-frequency switching module and an anti-backfilling module which are sequentially connected; and the SiC full-bridge inverse current conversion module I comprises a SiC power transistor. The welding system has a high inversion frequency, good dynamic characteristics and stability, can reduce the switching loss of a power tube, and can stably output a regular fast-frequency pulse flexible current waveform of 20 kHz or more.

Description

一种快频脉冲TIG焊接***A fast frequency pulse TIG welding system 技术领域Technical field

本发明涉及焊接设备技术领域，更具体地说，涉及一种快频脉冲TIG焊接***。The invention relates to the technical field of welding equipment, and more specifically to a fast-frequency pulse TIG welding system.

背景技术Background technique

在焊接领域中，钨极氩弧焊(简称TIG焊)以电弧稳定、零飞溅、焊接质量高、可焊金属范围广等优点而得到普遍应用。始于上世纪60年代中期的脉冲TIG焊接技术，在传统的直流电弧焊基础上叠加具有一定频率的脉冲电流，峰值电流可使电弧保持稳定，加速母材熔化形成熔池，而基值电流既可控制热量的输入又可维持电弧持续燃烧，使熔池冷却结晶，两者循环交替，形成性能良好的焊缝。有研究表明，在自由电弧的基础上加入高频脉冲电流可提高电弧稳定性，高频周期性变化的电弧压力对熔池的搅拌作用能够破碎枝晶，促进焊接接头的细化晶粒。相关研究人员提出了快频脉冲焊接方法。快频脉冲电流产生的电磁场对电弧进行压缩，可形成与电子束焊类似的集中电弧，改善电弧能量密度和提高电弧挺度，控制在焊接过程热输入量，减低热量影响区而提高焊接质量。In the field of welding, argon tungsten arc welding (TIG welding for short) is widely used for its advantages such as stable arc, zero spatter, high welding quality, and wide range of weldable metals. Pulse TIG welding technology, which started in the mid-1960s, superimposes a pulse current with a certain frequency on the basis of traditional DC arc welding. The peak current can keep the arc stable and accelerate the melting of the base material to form a molten pool. The base current is both The heat input can be controlled and the arc can continue to burn, so that the molten pool is cooled and crystallized. The two cycles alternately to form a weld with good performance. Studies have shown that adding high-frequency pulse current to the free arc can improve the arc stability, and the stirring effect of the arc pressure with high frequency periodically changing on the molten pool can break the dendrites and promote the refined grain of the welded joint. Related researchers have proposed a fast frequency pulse welding method. The electromagnetic field generated by the fast-frequency pulse current compresses the arc, which can form a concentrated arc similar to electron beam welding, improve the arc energy density and increase the arc stiffness, control the heat input in the welding process, reduce the heat affected zone and improve the welding quality.

因此，国内外相继投入到快频脉冲TIG焊接设备的研究中。在快频脉冲TIG焊接***中，焊接电源的质量与焊接电弧的性能密切相关，其不仅要精确地为焊接过程提供能量，还需实现与***其他设备的协同运行。然而，国内的快频脉冲TIG焊接设备的工业化水平同发达国家之间还存在较大的差距。国内快频脉冲焊接电源普遍采用Si基IGBT作为主功率器件，而Si基功率器件的开关性能已接近由其材料性能所决定的理论极限，在一定程度上制约了焊接电源逆变频率、响应速度等几个影响快频脉冲波形调制可靠性的关键指标。另外，由于在快频脉冲波形调制过程加入了高频脉冲电流的调制，会对焊接电源产生强烈电磁干扰，易出现焊接电流不稳定、高频段电弧控制效果差等问题。因此，快频脉冲TIG焊接技术在国内未能受到广泛应用。Therefore, domestic and foreign have invested in the research of fast-frequency pulse TIG welding equipment. In the fast-frequency pulse TIG welding system, the quality of the welding power source is closely related to the performance of the welding arc. It not only needs to accurately provide energy for the welding process, but also needs to achieve coordinated operation with other equipment in the system. However, there is still a big gap between the industrialization level of domestic fast-frequency pulse TIG welding equipment and developed countries. Domestic fast-frequency pulse welding power supplies generally use Si-based IGBTs as main power devices, and the switching performance of Si-based power devices has approached the theoretical limit determined by its material properties, which restricts the inverter frequency and response speed of the welding power supply to a certain extent Wait for several key indicators that affect the reliability of fast frequency pulse waveform modulation. In addition, due to the addition of high-frequency pulse current modulation in the fast-frequency pulse waveform modulation process, it will cause strong electromagnetic interference to the welding power source, which is prone to problems such as unstable welding current and poor high-frequency arc control. Therefore, the fast frequency pulse TIG welding technology has not been widely used in China.

发明概述Summary of the invention

技术问题technical problem

在快频脉冲TIG焊接***中，焊接电源的质量与焊接电弧的性能密切相关，其不仅要精确地为焊接过程提供能量，还需实现与***其他设备的协同运行。然而，国内的快频脉冲TIG焊接设备的工业化水平同发达国家之间还存在较大的差距，焊接电源普遍采用Si基IGBT作为功率变换的主要器件，而传统的Si基功率器件的开关性能已接近其材料性能所决定的理论极限，在一定程度上制约了焊接电源中逆变频率、响应速度等几个影响快频脉冲TIG焊接可靠性的关键指标，使得整机尺寸过大且动特性欠佳。本发明快频脉冲TIG焊接电源的功率开关器件采用了新型的SiC功率开关管，逆变频率高达100kHz，相对比目前较常用的IGBT提高了近十倍，不仅整机尺寸大幅减小，还具有良好的动态响应速度；有利于加强高频段电弧控制效果，稳定输出20kHz的快频脉冲电流波形，焊接过程中波形稳定不失真；快频脉冲TIG焊接电源有极高的能效；由于SiC功率开关管自身的优异性能，其开关损耗和导通损耗均较小，极大地提高了TIG焊接电源的能效。In the fast-frequency pulse TIG welding system, the quality of the welding power source is closely related to the performance of the welding arc. It not only needs to accurately provide energy for the welding process, but also needs to achieve coordinated operation with other equipment in the system. However, there is still a big gap between the industrialization level of domestic fast-frequency pulse TIG welding equipment and developed countries. Welding power sources generally use Si-based IGBTs as the main power conversion devices, while the switching performance of traditional Si-based power devices has been Close to the theoretical limit determined by its material properties, to a certain extent, it restricts the inverter frequency and response speed of the welding power supply and several key indicators that affect the reliability of fast-frequency pulse TIG welding, making the overall size of the machine too large and the dynamic characteristics good. The power switch device of the fast-frequency pulse TIG welding power supply of the present invention adopts a new type of SiC power switch tube, and the inverter frequency is up to 100kHz, which is nearly ten times higher than that of the currently more commonly used IGBT. Not only the size of the whole machine is greatly reduced, but also Good dynamic response speed; help to strengthen the high frequency arc control effect, stably output the 20kHz fast frequency pulse current waveform, the waveform is stable and undistorted during the welding process; the fast frequency pulse TIG welding power supply has extremely high energy efficiency; due to the SiC power switch tube Its own excellent performance, its switching loss and conduction loss are small, greatly improving the energy efficiency of TIG welding power supply.

问题的解决方案The solution to the problem

技术解决方案Technical solutions

为克服现有技术中的缺点与不足，本发明的目的在于提供一种逆变频率高、具有良好的动特性和稳定性、可降低功率管开关损耗、可稳定输出20kHz及以上的规整快频脉冲柔性电流波形的快频脉冲TIG焊接***。In order to overcome the shortcomings and deficiencies in the prior art, the purpose of the present invention is to provide a regular fast frequency with high inverter frequency, good dynamic characteristics and stability, reduced power tube switching loss, and stable output of 20kHz and above. Fast frequency pulse TIG welding system with pulse flexible current waveform.

为了达到上述目的，本发明通过下述技术方案予以实现：一种快频脉冲TIG焊接***，其特征在于：包括快频脉冲TIG焊接电源；所述快频脉冲TIG焊接电源包括主电路、控制电路和人机交互***；In order to achieve the above objective, the present invention is realized by the following technical solutions: a fast-frequency pulse TIG welding system, characterized in that it includes a fast-frequency pulse TIG welding power source; the fast-frequency pulse TIG welding power source includes a main circuit and a control circuit And human-computer interaction system;

所述主电路包括工频整流滤波模块、脉冲电流主电路、基值电流主电路和高频电流切换电路；所述脉冲电流主电路包括依次连接的SiC全桥逆变换流模块一、高频变压模块一和SiC整流平滑模块一；所述基值电流主电路包括依次连接的SiC全桥逆变换流模块二、高频变压模块二和SiC整流平滑模块二；所述高频电流切换电路包括依次连接的高频切换模块和防反灌模块；所述SiC全桥逆变换流模块一包括SiC功率开关管；The main circuit includes a power frequency rectification filter module, a pulse current main circuit, a base current main circuit, and a high-frequency current switching circuit; the pulse current main circuit includes a SiC full-bridge inverse conversion current module connected in sequence. Voltage module one and SiC rectification and smoothing module one; the base value current main circuit includes a SiC full-bridge inverse conversion module two, a high-frequency transformer module two, and a SiC rectification and smoothing module two connected in sequence; the high-frequency current switching circuit It includes a high-frequency switching module and an anti-reverse irrigation module connected in sequence; the SiC full-bridge reverse conversion current module includes a SiC power switch tube;

其中，三相交流输入电源与工频整流滤波模块连接；工频整流滤波模块分别与SiC全桥逆变换流模块一和SiC全桥逆变换流模块二连接；SiC整流平滑模块一与高频切换模块连接；防反灌模块与外部电弧负载连接；SiC整流平滑模块二与外部电弧负载连接；Among them, the three-phase AC input power supply is connected to the power frequency rectification filter module; the power frequency rectification filter module is connected to the SiC full-bridge inverse conversion flow module 1 and the SiC full-bridge inverse conversion flow module 2; the SiC rectification and smoothing module 1 is connected to high-frequency switching Module connection; anti-reverse irrigation module connected with external arc load; SiC rectifier smoothing module 2 connected with external arc load;

所述控制电路包括ARM最小控制***，以及分别与ARM最小控制***连接的人机交互通信模块、SiC高频驱动电路、切换开关驱动电路和输出电压电流采样反馈电路；其中，SiC高频驱动电路分别与SiC全桥逆变换流模块一和SiC全桥逆变换流模块二连接；切换开关驱动电路与高频切换模块连接；输出电压电流采样反馈电路分别与外部电弧负载、SiC整流平滑模块一和SiC整流平滑模块二连接；人机交互通信模块与人机交互***连接。The control circuit includes an ARM minimum control system, and a human-computer interaction communication module connected to the ARM minimum control system, a SiC high-frequency drive circuit, a switch drive circuit, and an output voltage and current sampling feedback circuit; wherein, the SiC high-frequency drive circuit Connected to SiC full-bridge inverse conversion current module 1 and SiC full-bridge inverse conversion current module 2 respectively; the switch drive circuit is connected to the high-frequency switching module; the output voltage and current sampling feedback circuit is connected to the external arc load and the SiC rectifier smoothing module 1 and SiC rectifying and smoothing module two is connected; the man-machine interactive communication module is connected with the man-machine interactive system.

优选地，所述SiC全桥逆变换流模块一包括SiC功率开关管，是指：SiC全桥逆变换流模块一包括SiC功率开关管M101、SiC功率开关管M102、SiC功率开关管M103和SiC功率开关管M104；所述高频变压模块一包括高频变压器一T101；所述SiC功率开关管M101、SiC功率开关管M102、SiC功率开关管M103和SiC功率开关管M104组成全桥逆变电路，之后通过隔直电容C109与高频变压器一T101的初级连接；所述SiC功率开关管M101、SiC功率开关管M102、SiC功率开关管M103和SiC功率开关管M104分别并联有RC吸收电路一；Preferably, the first SiC full-bridge inverse conversion current module includes SiC power switch tubes, which means: the first SiC full-bridge inverse conversion current module includes SiC power switch tubes M101, SiC power switch tubes M102, SiC power switch tubes M103, and SiC Power switch tube M104; the high-frequency transformer module one includes a high-frequency transformer one T101; the SiC power switch tube M101, SiC power switch tube M102, SiC power switch tube M103 and SiC power switch tube M104 form a full-bridge inverter The circuit is then connected to the primary of a high-frequency transformer T101 through a blocking capacitor C109; the SiC power switch tube M101, SiC power switch tube M102, SiC power switch tube M103, and SiC power switch tube M104 are respectively connected in parallel with an RC absorption circuit 1 ；

所述SiC整流平滑模块一包括整流二极管VD101、整流二极管VD102和电感L101；高频变压器一T101的次级第一输出端通过依次连接的整流二极管VD101和整流二极管VD102与高频变压器一T101的次级第三输出端连接；整流二极管VD101和整流二极管VD102的连接处与电感L101的一端连接；电感L101的另一端与高频变压器一T101的次级第二输出端分别作为脉冲电流主电路的输出端来与高频切换模块连接。The first SiC rectifier and smoothing module includes a rectifier diode VD101, a rectifier diode VD102, and an inductor L101; the secondary first output end of the high-frequency transformer-T101 is connected to the rectifier diode VD101 and the rectifier diode VD102 and the high-frequency transformer-T101 in sequence. The third output terminal of the stage is connected; the connection of the rectifier diode VD101 and the rectifier diode VD102 is connected to one end of the inductor L101; the other end of the inductor L101 and the secondary output terminal of the high-frequency transformer T101 are respectively used as the output of the pulse current main circuit The terminal is connected with the high-frequency switching module.

优选地，所述的SiC功率开关管M101、SiC功率开关管M102、SiC功率开关管M103和SiC功率开关管M104组成全桥逆变电路，之后通过隔直电容C109与高频变压模块一的初级连接；所述SiC功率开关管M101、SiC功率开关管M102、SiC功率开关管M103和SiC功率开关管M104分别并联有RC吸收电路一，是指：Preferably, the SiC power switch tube M101, the SiC power switch tube M102, the SiC power switch tube M103, and the SiC power switch tube M104 form a full-bridge inverter circuit, and then pass through the DC blocking capacitor C109 and the high-frequency transformer module. Primary connection; the SiC power switch tube M101, SiC power switch tube M102, SiC power switch tube M103, and SiC power switch tube M104 are respectively connected in parallel with RC absorption circuit one, which means:

还包括电容C101、电容C102、电容C103、电容C104、电容C109、电阻R101、 电阻R102、电阻R103和电阻R104；It also includes a capacitor C101, a capacitor C102, a capacitor C103, a capacitor C104, a capacitor C109, a resistor R101, a resistor R102, a resistor R103, and a resistor R104;

SiC功率开关管M101和SiC功率开关管M103串联后，与SiC功率开关管M102和SiC功率开关管M104串联形成的电路一起并联到工频整流滤波电路上；电容C101和电阻R101串联后并联到SiC功率开关管M101上；电容C102和电阻R102串联后并联到SiC功率开关管M102上；电容C103和电阻R103串联后并联到SiC功率开关管M103上；电容C104和电阻R104串联后并联到SiC功率开关管M104上；所述SiC功率开关管M101与SiC功率开关管M103的连接处与电容C109串联后与高频变压模块一的初级第一输入端连接；所述SiC功率开关管M102与SiC功率开关管M104的连接处与高频变压模块一的初级第二输入端连接。After the SiC power switch tube M101 and the SiC power switch tube M103 are connected in series, the circuit formed by the series connection of the SiC power switch tube M102 and the SiC power switch tube M104 is connected in parallel to the power frequency rectifier filter circuit; the capacitor C101 and the resistor R101 are connected in parallel to the SiC On the power switch M101; the capacitor C102 and the resistor R102 are connected in series and then connected in parallel to the SiC power switch M102; the capacitor C103 and the resistor R103 are connected in series and then connected in parallel to the SiC power switch M103; the capacitor C104 and the resistor R104 are connected in series and connected in parallel to the SiC power switch On the tube M104; the connection between the SiC power switch tube M101 and the SiC power switch tube M103 is connected in series with the capacitor C109 and then connected to the primary first input terminal of the high frequency transformer module one; the SiC power switch tube M102 and the SiC power The connection of the switch tube M104 is connected with the primary second input terminal of the high-frequency transformer module one.

优选地，所述SiC全桥逆变换流模块二的电路结构与SiC全桥逆变换流模块一相同；高频变压模块二的电路结构与高频变压模块一相同；SiC整流平滑模块二的电路结构与SiC整流平滑模块一相同。Preferably, the circuit structure of the SiC full-bridge inverse conversion module two is the same as that of the SiC full-bridge inverse conversion module one; the circuit structure of the high-frequency transformer module two is the same as the high-frequency transformer module one; and the SiC rectifier smoothing module two The circuit structure is the same as that of the SiC rectification and smoothing module.

优选地，所述高频切换模块包括调制开关管IGBT Q202和调制开关管IGBT Q201；所述防反灌模块包括整流二极管VD201；所述调制开关管IGBT Q201并联在所述SiC整流平滑模块一上；SiC整流平滑模块一通过依次连接的调制开关管IGBT Q202和整流二极管VD201与外部电弧负载连接；所述调制开关管IGBT Q202并联有尖峰电压吸收模块一；调制开关管IGBT Q201并联有尖峰电压吸收模块二。Preferably, the high-frequency switching module includes a modulation switching tube IGBT Q202 and a modulation switching tube IGBT Q201; the anti-reverse irrigation module includes a rectifier diode VD201; the modulation switching tube IGBT Q201 is connected in parallel to the SiC rectification and smoothing module one SiC rectification and smoothing module one is connected to the external arc load through the modulation switch tube IGBT Q202 and rectifier diode VD201 connected in sequence; the modulation switch tube IGBT Q202 is connected in parallel with a peak voltage absorption module one; the modulation switch tube IGBT Q201 is connected in parallel with peak voltage absorption Module two.

优选地，所述尖峰电压吸收模块一包括电容C202、电阻R202、二极管D204和二极管D203；电阻R202和电容C202并联后与二极管D204串联形成的电路并联到调制开关管IGBT Q202上；二极管D203并联在调制开关管IGBT Q202上；Preferably, the peak voltage absorption module 1 includes a capacitor C202, a resistor R202, a diode D204, and a diode D203; the resistor R202 and the capacitor C202 are connected in parallel and the circuit formed in series with the diode D204 is connected in parallel to the modulation switch IGBT Q202; the diode D203 is connected in parallel Modulation switch tube IGBT Q202;

所述尖峰电压吸收模块二包括电容C201、电阻R201、二极管D202和二极管D201；电阻R201和二极管D202并联后与电容C201串联形成的电路并联到调制开关管IGBT Q201上；二极管D201并联在调制开关管IGBT Q201上。The second peak voltage absorption module includes a capacitor C201, a resistor R201, a diode D202, and a diode D201; the resistor R201 and the diode D202 are connected in parallel with the capacitor C201 to form a circuit connected in parallel to the modulation switch IGBT Q201; the diode D201 is connected in parallel to the modulation switch IGBT Q201 on.

优选地，所述ARM最小控制***通过隔离一与SiC高频驱动电路连接；所述ARM最小控制***通过隔离二与切换开关驱动电路连接。Preferably, the ARM minimum control system is connected to the SiC high frequency drive circuit through isolation one; the ARM minimum control system is connected to the switch drive circuit through isolation two.

优选地，所述ARM最小控制***通过隔离一与SiC高频驱动电路连接，是指：Preferably, the ARM minimum control system is connected to the SiC high-frequency drive circuit through isolation one, which means:

ARM最小控制***通过型号为ISO5451的隔离驱动芯片与SiC高频驱动电路连接，隔离驱动芯片还连接有驱动供电电路一；The ARM minimum control system is connected to the SiC high-frequency drive circuit through the ISO5451 isolation drive chip, and the isolation drive chip is also connected to drive power supply circuit one;

所述SiC高频驱动电路包括电容C304、电容C305、稳压管ZD301、二极管D302、二极管D303、电阻R310、电阻R311、电阻R312和电阻R313；隔离驱动芯片的引脚CLAMP与SiC功率开关管栅极连接；SiC功率开关管栅极通过并联的电阻R313和电容C305接地；隔离驱动芯片的引脚OUT通过电阻R312与SiC功率开关管栅极连接；二极管D303和电阻R311串联后并联在电阻R312上；隔离驱动芯片的引脚OUT通过串联的电阻R310和二极管D302与SiC功率开关管漏极连接；隔离驱动芯片的引脚OUT还通过并联的电容C304和稳压二极管ZD301接地；隔离驱动芯片的引脚DESAT与隔离驱动芯片的引脚OUT连接。The SiC high-frequency drive circuit includes capacitor C304, capacitor C305, Zener tube ZD301, diode D302, diode D303, resistor R310, resistor R311, resistor R312, and resistor R313; the pin CLAMP of the isolation drive chip and the SiC power switch grid Pole connection; the gate of the SiC power switch is connected to the ground through the parallel resistor R313 and the capacitor C305; the pin OUT of the isolation drive chip is connected to the gate of the SiC power switch through the resistor R312; the diode D303 and the resistor R311 are connected in parallel to the resistor R312 in series The pin OUT of the isolation drive chip is connected to the drain of the SiC power switch through the series resistor R310 and diode D302; the pin OUT of the isolation drive chip is also grounded through the parallel capacitor C304 and the Zener diode ZD301; the lead of the isolation drive chip The pin DESAT is connected to the pin OUT of the isolation driver chip.

优选地，所述ARM最小控制***通过隔离二与切换开关驱动电路连接，是指：ARM最小控制***通过光耦隔离芯片与切换开关驱动电路连接；所述切换开关驱动电路包括NPN三极管Q401、NPN三极管Q402、NPN三极管Q404、PNP三极管Q403和驱动供电电路二；Preferably, the ARM minimum control system is connected to the switch drive circuit through isolation two, which means that the ARM minimum control system is connected to the switch drive circuit through an optocoupler isolation chip; the switch drive circuit includes NPN transistors Q401, NPN Transistor Q402, NPN transistor Q404, PNP transistor Q403 and driving power supply circuit two;

光耦隔离芯片的输出端通过依次连接的电阻R402、电阻R403和二极管D402与NPN三极管Q401基极连接；电阻R403并联有电容C401；二极管D402反向并联有二极管D403；电阻R403和二极管D402连接处通过二极管D401与NPN三极管Q401集电极连接；NPN三极管Q401集电极还通过电阻R404与驱动供电电路二正极连接；The output terminal of the optocoupler isolation chip is connected to the base of the NPN transistor Q401 through the resistor R402, the resistor R403 and the diode D402 connected in sequence; the resistor R403 is connected in parallel with the capacitor C401; the diode D402 is connected in reverse parallel with the diode D403; the resistor R403 and the diode D402 are connected The collector of the NPN transistor Q401 is connected through a diode D401; the collector of the NPN transistor Q401 is also connected to the two anodes of the driving power supply circuit through a resistor R404;

电阻R402和电阻R403连接处通过依次连接的电阻R408和二极管D408与NPN三极管Q402基极连接；电阻R408并联有电容C403；二极管D408反向并联有二极管D409；电阻R408和二极管D408连接处通过二极管D407与NPN三极管Q402集电极连接；NPN三极管Q402集电极还通过电阻R409与驱动供电电路二正极连接；NPN三极管Q401发射极和NPN三极管Q402发射极分别与驱动供电电路二负极连接；The connection of the resistor R402 and the resistor R403 is connected to the base of the NPN transistor Q402 through the resistor R408 and the diode D408 connected in turn; the resistor R408 is connected in parallel with the capacitor C403; the diode D408 is connected in reverse parallel with the diode D409; the resistor R408 and the diode D408 are connected through the diode D407 Connect with the collector of the NPN transistor Q402; the collector of the NPN transistor Q402 is also connected to the two positive poles of the driving power supply circuit through a resistor R409; the emitter of the NPN transistor Q401 and the emitter of the NPN transistor Q402 are respectively connected to the second negative pole of the driving power supply circuit;

NPN三极管Q401集电极通过依次连接的电阻R405和二极管D405与PNP三极管Q403基极连接；电阻R405并联有电容C402；二极管C405反向并联有二极管D404；电阻R405和二极管D405连接处通过二极管D406与PNP三极管Q403集电极连接 ；PNP三极管Q403基极通过电阻R406与驱动供电电路二正极连接；PNP三极管Q403发射极通过电阻R407与驱动供电电路二正极连接；The collector of the NPN transistor Q401 is connected to the base of the PNP transistor Q403 through the resistor R405 and the diode D405 connected in sequence; the resistor R405 is connected in parallel with the capacitor C402; the diode C405 is connected in reverse parallel with the diode D404; the resistor R405 and the diode D405 are connected to the PNP through the diode D406 The collector of the transistor Q403 is connected; the base of the PNP transistor Q403 is connected to the two positive poles of the drive power supply circuit through a resistor R406; the emitter of the PNP transistor Q403 is connected to the two positive poles of the drive power supply circuit through a resistor R407;

NPN三极管Q402集电极通过依次连接的电阻R410和二极管D411与NPN三极管Q404基极连接；电阻R410并联有电容C404；二极管D411反向并联有二极管D412；电阻R410和二极管D411连接处通过二极管D410与NPN三极管Q404集电极连接；NPN三极管Q404集电极与PNP三极管Q403集电极连接；NPN三极管Q404发射极通过电阻R411与驱动供电电路二负极连接；NPN三极管Q404集电极通过电阻R412与驱动供电电路二负极连接；NPN三极管Q404集电极与高频切换模块连接。The collector of the NPN transistor Q402 is connected to the base of the NPN transistor Q404 through the resistor R410 and the diode D411 connected in sequence; the resistor R410 is connected in parallel with the capacitor C404; the diode D411 is connected in reverse parallel with the diode D412; the resistor R410 and the diode D411 are connected through the diode D410 and NPN The collector of the transistor Q404 is connected; the collector of the NPN transistor Q404 is connected to the collector of the PNP transistor Q403; the emitter of the NPN transistor Q404 is connected to the second negative electrode of the driving power supply circuit through the resistor R411; the collector of the NPN transistor Q404 is connected to the second negative electrode of the driving power supply circuit through the resistor R412 ; The collector of the NPN transistor Q404 is connected to the high-frequency switching module.

优选地，还包括工业机器人、送丝机、焊枪、送气装置和夹具；所述工业机器人和送丝机分别与ARM最小控制***连接；所述夹具分别与工业机器人和焊枪连接；所述快频脉冲TIG焊接电源还与送气装置连接；所述焊枪还分别与送气装置和送丝机连接。Preferably, it further includes an industrial robot, a wire feeder, a welding gun, an air supply device, and a fixture; the industrial robot and the wire feeder are respectively connected to the ARM minimum control system; the fixture is respectively connected to the industrial robot and the welding torch; the fast frequency The pulse TIG welding power source is also connected with an air supply device; the welding gun is also connected with an air supply device and a wire feeder respectively.

发明的有益效果The beneficial effects of the invention

有益效果Beneficial effect

与现有技术相比，本发明具有如下优点与有益效果：Compared with the prior art, the present invention has the following advantages and beneficial effects:

1、与传统脉冲TIG焊接***相比，本发明快频脉冲TIG焊接电源的功率开关器件采用了新型的SiC功率开关管，逆变频率高达100kHz及以上，相对比目前较常用的IGBT提高了近十倍，不仅整机尺寸大幅减小，还具有良好的动态响应速度；有利于加强高频段电弧控制效果，稳定输出20kHz的快频脉冲电流波形，焊接过程中波形稳定不失真；1. Compared with the traditional pulsed TIG welding system, the power switch device of the fast-frequency pulsed TIG welding power supply of the present invention adopts a new type of SiC power switch tube, and the inverter frequency is as high as 100kHz and above, which is nearly improved compared to the more commonly used IGBT. Ten times, not only the size of the whole machine is greatly reduced, but also has a good dynamic response speed; it is helpful to strengthen the high frequency arc control effect, and stably output the 20kHz fast frequency pulse current waveform, and the waveform is stable without distortion during the welding process;

2、本发明中，快频脉冲TIG焊接电源有极高的能效；由于SiC功率开关管自身的优异性能，其开关损耗和导通损耗均较小，极大地提高了TIG焊接电源的能效；2. In the present invention, the fast frequency pulse TIG welding power source has extremely high energy efficiency; due to the excellent performance of the SiC power switch tube itself, its switching loss and conduction loss are small, which greatly improves the energy efficiency of the TIG welding power source;

3、本发明中，高频电流切换电路既能够有效地吸收高频脉冲电流调制过程产生的尖脉冲过电压，又不会破坏快频脉冲电流基本波形，结构简单，成本低，可靠性高；3. In the present invention, the high-frequency current switching circuit can effectively absorb the spike overvoltage generated by the high-frequency pulse current modulation process without destroying the basic waveform of the fast-frequency pulse current, with simple structure, low cost and high reliability;

4、本发明采样隔离方式实现ARM最小控制***与SiC高频驱动电路，以及AR M最小控制***与切换开关驱动电路连接；具有多种保护功能，在有效驱动开关管的同时可防止开关管发生损坏；可抑制SiC功率开关管驱动过程中出现瞬态电压和瞬态电流过高、产生电磁干扰的问题，防止产生电压尖峰而引起误触发，具有良好的驱动效果；4. The sampling isolation method of the present invention realizes the ARM minimum control system and the SiC high frequency drive circuit, and the ARM minimum control system is connected with the switch drive circuit; it has multiple protection functions, which can effectively drive the switch tube while preventing the occurrence of the switch tube Damage; it can suppress the transient voltage and transient current excessively high and electromagnetic interference in the driving process of the SiC power switch tube, and prevent the voltage spike from causing false triggering, and has a good driving effect;

5、本发明快频脉冲TIG焊接***结合了高频逆变、数字自动控制等技术，以及将***各部分通过CAN总线进行协同运行，使得***的集成度更高，控制更为精确。5. The fast-frequency pulse TIG welding system of the present invention combines high-frequency inverter, digital automatic control and other technologies, as well as coordinated operation of various parts of the system through the CAN bus, which makes the system more integrated and more precise in control.

对附图的简要说明Brief description of the drawings

附图说明Description of the drawings

图1是本发明快频脉冲TIG焊接***的***框图；Figure 1 is a system block diagram of the fast frequency pulse TIG welding system of the present invention;

图2是本发明快频脉冲TIG焊接***中快频脉冲TIG焊接电源的结构示意图；2 is a schematic diagram of the structure of the fast-frequency pulse TIG welding power source in the fast-frequency pulse TIG welding system of the present invention;

图3是本发明快频脉冲TIG焊接***中快频脉冲TIG焊接电源的主电路的电路图；Figure 3 is a circuit diagram of the main circuit of the fast pulse TIG welding power supply in the fast pulse TIG welding system of the present invention;

图4是本发明快频脉冲TIG焊接***中快频脉冲TIG焊接电源的SiC高频驱动电路的电路图；4 is a circuit diagram of the SiC high frequency drive circuit of the fast pulse TIG welding power source in the fast pulse TIG welding system of the present invention;

图5是本发明快频脉冲TIG焊接***中快频脉冲TIG焊接电源的切换开关驱动电路的电路图；Fig. 5 is a circuit diagram of the switch drive circuit of the fast pulse TIG welding power supply in the fast pulse TIG welding system of the present invention;

图6是本发明快频脉冲TIG焊接***中快频脉冲TIG焊接电源的输出电压电流采样反馈电路的电路图；6 is a circuit diagram of the output voltage and current sampling feedback circuit of the fast pulse TIG welding power supply in the fast pulse TIG welding system of the present invention;

图7是本发明快频脉冲TIG焊接***中送丝机的结构框图。Fig. 7 is a structural block diagram of the wire feeder in the fast-frequency pulse TIG welding system of the present invention.

发明实施例Invention embodiment

本发明的实施方式Embodiments of the invention

下面结合附图与具体实施方式对本发明作进一步详细的描述。The present invention will be further described in detail below in conjunction with the drawings and specific embodiments.

实施例Example

本实施例一种快频脉冲TIG焊接***，其结构如图1至图7所示，包括快频脉冲TIG焊接电源，还包括工业机器人、送丝机、焊枪、送气装置和夹具；工业机器人和送丝机分别与ARM最小控制***连接；夹具分别与工业机器人和焊枪连接；快频脉冲TIG焊接电源还与送气装置连接；焊枪还分别与送气装置和送丝机连 接。A fast-frequency pulse TIG welding system of this embodiment has a structure as shown in Figures 1 to 7, including a fast-frequency pulse TIG welding power source, and also includes an industrial robot, a wire feeder, a welding gun, an air supply device and a fixture; an industrial robot and The wire feeders are respectively connected to the ARM minimum control system; the fixtures are respectively connected to the industrial robot and the welding torch; the fast frequency pulse TIG welding power source is also connected to the air supply device; the welding torch is also connected to the air supply device and the wire feeder respectively.

工业机器人作为执行机构，用于夹持焊枪按既定路径进行焊接操作。送丝机用于实现焊丝送给速度的精确无级调节以及送丝方式的多样化，保证焊丝的送入能与焊接工艺及参数完美配合。送气装置用于提供保护气。夹具用于实现焊接工件的固定与变位以及使焊枪和工业机器人相连等功能。Industrial robots are used as actuators to clamp the welding torch to perform welding operations according to the established path. The wire feeder is used to realize the precise stepless adjustment of the wire feeding speed and the diversification of wire feeding methods to ensure that the feeding of the wire can be perfectly matched with the welding process and parameters. The air supply device is used to provide protective gas. The fixture is used to realize the function of fixing and displacing the welding workpiece and connecting the welding gun with the industrial robot.

快频脉冲TIG焊接电源包括主电路、控制电路和人机交互***。The fast frequency pulse TIG welding power source includes the main circuit, control circuit and human-computer interaction system.

主电路包括工频整流滤波模块、脉冲电流主电路、基值电流主电路和高频电流切换电路。脉冲电流主电路和基值电流主电路主要用于为电弧提供能量，高频电流切换电路用于调制高频电流，而控制电路用于实现SiC功率开关管和调制开关管IGBT驱动信号的发生、采样电流的闭环调节、故障保护、与***其他部分的协同通信以及人机交互等功能。The main circuit includes a power frequency rectifier filter module, a pulse current main circuit, a base current main circuit and a high frequency current switching circuit. The pulse current main circuit and the base current main circuit are mainly used to provide energy for the arc, the high-frequency current switching circuit is used to modulate the high-frequency current, and the control circuit is used to realize the generation of the SiC power switch tube and the modulation switch tube IGBT drive signal, Functions such as closed-loop adjustment of sampling current, fault protection, cooperative communication with other parts of the system, and human-computer interaction.

脉冲电流主电路包括依次连接的SiC全桥逆变换流模块一、高频变压模块一和SiC整流平滑模块一；基值电流主电路包括依次连接的SiC全桥逆变换流模块二、高频变压模块二和SiC整流平滑模块二；高频电流切换电路包括依次连接的高频切换模块和防反灌模块；SiC全桥逆变换流模块一包括SiC功率开关管；高频切换模块包括IGBT开关管；The pulse current main circuit includes the SiC full-bridge inverse conversion module 1, the high-frequency transformer module, and the SiC rectifier smoothing module 1, which are connected in sequence; the base current main circuit includes the SiC full-bridge inverse conversion module, which is connected in sequence. Transformer module two and SiC rectification and smoothing module two; high-frequency current switching circuit includes a high-frequency switching module and an anti-reverse injection module connected in sequence; SiC full-bridge reverse conversion current module one includes SiC power switch tube; high-frequency switching module includes IGBT turning tube;

其中，三相交流输入电源与工频整流滤波模块连接；工频整流滤波模块分别与SiC全桥逆变换流模块一和SiC全桥逆变换流模块二连接；SiC整流平滑模块一与高频切换模块连接；防反灌模块与外部电弧负载连接；SiC整流平滑模块二与外部电弧负载连接；Among them, the three-phase AC input power supply is connected to the power frequency rectification filter module; the power frequency rectification filter module is connected to the SiC full-bridge inverse conversion flow module 1 and the SiC full-bridge inverse conversion flow module 2; the SiC rectification and smoothing module 1 is connected to high-frequency switching Module connection; anti-reverse irrigation module connected with external arc load; SiC rectifier smoothing module 2 connected with external arc load;

控制电路包括ARM最小控制***，以及分别与ARM最小控制***连接的人机交互通信模块、SiC高频驱动电路、切换开关驱动电路和输出电压电流采样反馈电路；其中，SiC高频驱动电路分别与SiC全桥逆变换流模块一和SiC全桥逆变换流模块二连接；切换开关驱动电路与高频切换模块连接；输出电压电流采样反馈电路分别与外部电弧负载、SiC整流平滑模块一和SiC整流平滑模块二连接；人机交互通信模块与人机交互***连接。The control circuit includes the ARM minimum control system, and the human-computer interaction communication module connected to the ARM minimum control system, SiC high-frequency drive circuit, switch drive circuit, and output voltage and current sampling feedback circuit. Among them, the SiC high-frequency drive circuit is connected with SiC full-bridge inverse conversion current module 1 and SiC full-bridge inverse conversion current module 2 are connected; the switch drive circuit is connected to the high-frequency switching module; the output voltage and current sampling feedback circuit is connected to the external arc load, SiC rectification and smoothing module 1 and SiC rectifier respectively The smoothing module two is connected; the man-machine interactive communication module is connected with the man-machine interactive system.

ARM最小控制***采用32位的高速ARM微处理器，其产生三组全数字PWM控制信号，分别作用于脉冲电流主电路、基值电流主电路以及高频电流切换电路 ；ARM最小控制***的UART通信接口电路与人机交互***相连，ARM最小控制***的CAN通信接口电路与CAN总线相连，完成***各部分相互间的协同运行。继电器模块主要用于气阀的开启和关闭。The ARM minimum control system uses a 32-bit high-speed ARM microprocessor, which generates three sets of all-digital PWM control signals, which act on the pulse current main circuit, the base current main circuit and the high-frequency current switching circuit respectively; the UART of the ARM minimum control system The communication interface circuit is connected with the human-computer interaction system, and the CAN communication interface circuit of the ARM minimum control system is connected with the CAN bus to complete the coordinated operation of each part of the system. The relay module is mainly used to open and close the air valve.

SiC全桥逆变换流模块一包括SiC功率开关管M101、SiC功率开关管M102、SiC功率开关管M103和SiC功率开关管M104；所述高频变压模块一包括高频变压器一T101；所述SiC功率开关管M101、SiC功率开关管M102、SiC功率开关管M103和SiC功率开关管M104组成全桥逆变电路，之后通过隔直电容C109与高频变压器一T101的初级连接；所述SiC功率开关管M101、SiC功率开关管M102、SiC功率开关管M103和SiC功率开关管M104分别并联有RC吸收电路一；The first SiC full-bridge inverse conversion module includes SiC power switch tube M101, SiC power switch tube M102, SiC power switch tube M103, and SiC power switch tube M104; the first high-frequency transformation module includes a high-frequency transformer one T101; SiC power switch tube M101, SiC power switch tube M102, SiC power switch tube M103, and SiC power switch tube M104 form a full-bridge inverter circuit, which is then connected to the primary of a high-frequency transformer T101 through a DC blocking capacitor C109; the SiC power Switch tube M101, SiC power switch tube M102, SiC power switch tube M103 and SiC power switch tube M104 are respectively connected in parallel with RC absorption circuit one;

所述SiC整流平滑模块一包括整流二极管VD101、整流二极管VD102和电感L101；高频变压器一T101的次级第一输出端通过依次连接的整流二极管VD101和整流二极管VD102与高频变压器一T101的次级第三输出端连接；整流二极管VD101和整流二极管VD102的连接处与电感L101的一端连接；电感L101的另一端与高频变压器一T101的次级第二输出端分别作为脉冲电流主电路的输出端来与高频切换模块连接。具体地说，还包括电容C101、电容C102、电容C103、电容C104、电容C109、电阻R101、电阻R102、电阻R103和电阻R104；The first SiC rectifier and smoothing module includes a rectifier diode VD101, a rectifier diode VD102, and an inductor L101; the secondary first output end of the high-frequency transformer-T101 is connected to the rectifier diode VD101 and the rectifier diode VD102 and the high-frequency transformer-T101 in sequence. The third output terminal of the stage is connected; the connection of the rectifier diode VD101 and the rectifier diode VD102 is connected to one end of the inductor L101; the other end of the inductor L101 and the secondary output terminal of the high-frequency transformer T101 are respectively used as the output of the pulse current main circuit The terminal is connected with the high-frequency switching module. Specifically, it also includes a capacitor C101, a capacitor C102, a capacitor C103, a capacitor C104, a capacitor C109, a resistor R101, a resistor R102, a resistor R103, and a resistor R104;

SiC功率开关管M101和SiC功率开关管M103串联后，与SiC功率开关管M102和SiC功率开关管M104串联形成的电路一起并联到工频整流滤波电路上；电容C101和电阻R101串联后并联到SiC功率开关管M101上；电容C102和电阻R102串联后并联到SiC功率开关管M102上；电容C103和电阻R103串联后并联到SiC功率开关管M103上；电容C104和电阻R104串联后并联到SiC功率开关管M104上；所述SiC功率开关管M101与SiC功率开关管M103的连接处与电容C109串联后与高频变压模块一的初级第一输入端连接；所述SiC功率开关管M102与SiC功率开关管M104的连接处与高频变压模块一的初级第二输入端连接。After the SiC power switch tube M101 and the SiC power switch tube M103 are connected in series, the circuit formed by the series connection of the SiC power switch tube M102 and the SiC power switch tube M104 is connected in parallel to the power frequency rectifier filter circuit; the capacitor C101 and the resistor R101 are connected in parallel to the SiC On the power switch M101; the capacitor C102 and the resistor R102 are connected in series and then connected in parallel to the SiC power switch M102; the capacitor C103 and the resistor R103 are connected in series and then connected in parallel to the SiC power switch M103; the capacitor C104 and the resistor R104 are connected in series and connected in parallel to the SiC power switch On the tube M104; the connection between the SiC power switch tube M101 and the SiC power switch tube M103 is connected in series with the capacitor C109 and then connected to the primary first input terminal of the high frequency transformer module one; the SiC power switch tube M102 and the SiC power The connection of the switch tube M104 is connected with the primary second input terminal of the high-frequency transformer module one.

在基值电流主电路中，SiC全桥逆变换流模块二的电路结构与SiC全桥逆变换流模块一相同；高频变压模块二的电路结构与高频变压模块一相同；SiC整流平滑 模块二的电路结构与SiC整流平滑模块一相同。基值电流主电路的结构和原理与脉冲电流主电路相同。用于驱动SiC全桥逆变换流模块一的SiC高频驱动电路和用于驱动SiC全桥逆变换流模块二的SiC高频驱动电路结构相同，仅仅是输出驱动波形和时序不同；驱动波形和时序可采用现有方式。In the base current main circuit, the circuit structure of SiC full-bridge inverse conversion module two is the same as that of SiC full-bridge inverse conversion module one; the circuit structure of high-frequency transformer module two is the same as that of high-frequency transformer module one; SiC rectifier The circuit structure of smoothing module two is the same as that of SiC rectifying and smoothing module one. The structure and principle of the base current main circuit are the same as the pulse current main circuit. The SiC high-frequency drive circuit used to drive the SiC full-bridge inverse conversion flow module 1 and the SiC high-frequency drive circuit used to drive the SiC full-bridge inverse conversion flow module 2 have the same structure, but the output drive waveforms and timings are different; the drive waveforms and The timing can adopt existing methods.

主电路的工作原理是：通过交流输入电源接入工频整流滤波模块转换成平滑的直流电；直流电经由脉冲电流主电路的SiC全桥逆变换流模块一，两路互补带死区的PWM信号控制对角的两个SiC功率开关管同时高频开通或者关断，将直流电转换为高频交流电；之后经过高频变压模块一进行电气隔离、变压和功率传递；经过SiC整流平滑模块二转变成低压平滑的直流电输入到高频切换模块，两路互补无死区的PWM信号控制两个调制开关管IGBT以20kHz频率交替开通关断，将直流电转换为高频电流，经过防反灌模块后与基值电流主电路输出的基值直流电流叠加，叠加产生的快频脉冲电流输出到外部电弧负载。The working principle of the main circuit is: the AC input power is connected to the power frequency rectifier filter module and converted into a smooth DC; the DC power is controlled by the SiC full-bridge inverse conversion module of the pulse current main circuit. One and two complementary PWM signals with dead zone The two diagonal SiC power switch tubes are turned on or off at the same time at high frequency to convert direct current into high frequency alternating current; after that, they are electrically isolated, transformed and transmitted through high-frequency transformer module one; they are transformed through SiC rectifier smoothing module two. The low-voltage and smooth DC power is input to the high-frequency switching module. The two complementary PWM signals without dead zone control the two modulation switch IGBTs to turn on and off alternately at a frequency of 20kHz, which converts the DC power into a high-frequency current. After passing through the anti-reverse injection module It is superimposed with the base DC current output by the base current main circuit, and the superimposed fast-frequency pulse current is output to the external arc load.

高频切换模块包括调制开关管IGBT Q202和调制开关管IGBT Q201；所述防反灌模块包括整流二极管VD201；所述调制开关管IGBT Q201并联在所述SiC整流平滑模块一上；SiC整流平滑模块一通过依次连接的调制开关管IGBT Q202和整流二极管VD201与外部电弧负载连接；所述调制开关管IGBT Q202并联有尖峰电压吸收模块一；调制开关管IGBT Q201并联有尖峰电压吸收模块二。The high-frequency switching module includes a modulation switching tube IGBT Q202 and a modulation switching tube IGBT Q201; the anti-backflow module includes a rectifier diode VD201; the modulation switching tube IGBT Q201 is connected in parallel to the SiC rectification and smoothing module one; SiC rectification and smoothing module One is connected to an external arc load through the modulation switch tube IGBT Q202 and the rectifier diode VD201 connected in sequence; the modulation switch tube IGBT Q202 is connected in parallel with a peak voltage absorption module one; the modulation switch tube IGBT Q201 is connected in parallel with a peak voltage absorption module two.

尖峰电压吸收模块一包括电容C202、电阻R202、二极管D204和二极管D203；电阻R202和电容C202并联后与二极管D204串联形成的电路并联到调制开关管IGBT Q202上；二极管D203并联在调制开关管IGBT Q202上；Peak voltage absorption module one includes capacitor C202, resistor R202, diode D204 and diode D203; resistor R202 and capacitor C202 are connected in parallel with diode D204 to form a circuit connected in series with modulation switch IGBT Q202; diode D203 is connected in parallel with modulation switch IGBT Q202 on;

所述尖峰电压吸收模块二包括电容C201、电阻R201、二极管D202和二极管D201；电阻R201和二极管D202并联后与电容C201串联形成的电路并联到调制开关管IGBT Q201上；二极管D201并联在调制开关管IGBT Q201上。The second peak voltage absorption module includes a capacitor C201, a resistor R201, a diode D202, and a diode D201; the resistor R201 and the diode D202 are connected in parallel with the capacitor C201 to form a circuit connected in parallel to the modulation switch IGBT Q201; the diode D201 is connected in parallel to the modulation switch IGBT Q201 on.

在高频电流切换电路中，由脉冲电流主电路输出的低压直流电输入到调制开关管IGBT Q201与调制开关管IGBT Q202构成的高频切换模块，两路互补无死区的PWM信号控制调制开关管IGBT Q201与调制开关管IGBT Q202以20kHz或更高的频率交替开通关断，将直流电转换为高频电流，经过防反灌模块后与基值电流主电路输出的低压直流电叠加， 叠加产生的快频脉冲电流输出到外部电弧负载；尖峰电压吸收模块一和尖峰电压吸收模块二对调制高频电流过程产生的尖峰电压进行吸收；整流二极管VD201防止基值电流主电路输出的直流电通过高频电流切换电路内阻反灌回脉冲电流主电路，避免影响电源的精确输出控制。In the high-frequency current switching circuit, the low-voltage DC output from the pulse current main circuit is input to the high-frequency switching module composed of the modulation switch IGBT Q201 and the modulation switch IGBT Q202, and two complementary PWM signals without dead zone control the modulation switch. The IGBT Q201 and the modulation switch IGBT Q202 are turned on and off alternately at a frequency of 20kHz or higher to convert the direct current into a high-frequency current. After passing through the anti-reverse injection module, it is superimposed with the low-voltage direct current output by the base current main circuit. The frequency pulse current is output to the external arc load; the peak voltage absorption module 1 and the peak voltage absorption module 2 absorb the peak voltage generated in the process of modulating the high frequency current; the rectifier diode VD201 prevents the DC output from the main circuit of the base current from being switched by the high frequency current The internal resistance of the circuit recharges the main circuit of pulse current to avoid affecting the precise output control of the power supply.

ARM最小控制***通过隔离一与SiC高频驱动电路连接。The ARM minimum control system is connected to the SiC high-frequency drive circuit through isolation one.

具体地说，ARM最小控制***通过型号为ISO5451的隔离驱动芯片与SiC高频驱动电路连接，隔离驱动芯片还连接有驱动供电电路一；Specifically, the ARM minimum control system is connected to the SiC high-frequency drive circuit through the ISO5451 isolation drive chip, and the isolation drive chip is also connected to the drive power supply circuit one;

SiC高频驱动电路包括电容C304、电容C305、稳压管ZD301、二极管D302、二极管D303、电阻R310、电阻R311、电阻R312和电阻R313；隔离驱动芯片的引脚CLAMP与SiC功率开关管栅极连接；SiC功率开关管栅极通过并联的电阻R313和电容C305接地；隔离驱动芯片的引脚OUT通过电阻R312与SiC功率开关管栅极连接；二极管D303和电阻R311串联后并联在电阻R312上；隔离驱动芯片的引脚OUT通过串联的电阻R310和二极管D302与SiC功率开关管漏极连接；隔离驱动芯片的引脚OUT还通过并联的电容C304和稳压二极管ZD301接地；隔离驱动芯片的引脚DESAT与隔离驱动芯片的引脚OUT连接。SiC high-frequency drive circuit includes capacitor C304, capacitor C305, Zener tube ZD301, diode D302, diode D303, resistor R310, resistor R311, resistor R312 and resistor R313; the pin CLAMP of the isolation drive chip is connected to the gate of the SiC power switch tube The gate of the SiC power switch is connected to the ground through the parallel resistor R313 and the capacitor C305; the pin OUT of the isolation drive chip is connected to the gate of the SiC power switch through the resistor R312; the diode D303 and the resistor R311 are connected in parallel to the resistor R312 in series; isolation The pin OUT of the driver chip is connected to the drain of the SiC power switch through the series resistor R310 and diode D302; the pin OUT of the isolation driver chip is also grounded through the parallel capacitor C304 and the Zener diode ZD301; the pin DESAT of the isolation driver chip Connect to the pin OUT of the isolation driver chip.

ARM最小控制***通过隔离二与切换开关驱动电路连接。具体地说，ARM最小控制***通过光耦隔离芯片与切换开关驱动电路连接；所述切换开关驱动电路包括NPN三极管Q401、NPN三极管Q402、NPN三极管Q404、PNP三极管Q403和驱动供电电路二；The ARM minimum control system is connected to the switch drive circuit through isolation two. Specifically, the ARM minimum control system is connected to the switch drive circuit through the optocoupler isolation chip; the switch drive circuit includes NPN transistor Q401, NPN transistor Q402, NPN transistor Q404, PNP transistor Q403 and driving power supply circuit two;

光耦隔离芯片的输出端通过依次连接的电阻R402、电阻R403和二极管D402与NPN三极管Q401基极连接；电阻R403并联有电容C401；二极管D402反向并联有二极管D403；电阻R403和二极管D402连接处通过二极管D401与NPN三极管Q401集电极连接；NPN三极管Q401集电极还通过电阻R404与驱动供电电路二正极连接；The output terminal of the optocoupler isolation chip is connected to the base of the NPN transistor Q401 through the resistor R402, the resistor R403 and the diode D402 connected in sequence; the resistor R403 is connected in parallel with the capacitor C401; the diode D402 is connected in reverse parallel with the diode D403; the resistor R403 and the diode D402 are connected The collector of the NPN transistor Q401 is connected through a diode D401; the collector of the NPN transistor Q401 is also connected to the two anodes of the driving power supply circuit through a resistor R404;

电阻R402和电阻R403连接处通过依次连接的电阻R408和二极管D408与NPN三极管Q402基极连接；电阻R408并联有电容C403；二极管D408反向并联有二极管D409；电阻R408和二极管D408连接处通过二极管D407与NPN三极管Q402集电极连接；NPN三极管Q402集电极还通过电阻R409与驱动供电电路二正极连接； NPN三极管Q401发射极和NPN三极管Q402发射极分别与驱动供电电路二负极连接；The connection of the resistor R402 and the resistor R403 is connected to the base of the NPN transistor Q402 through the resistor R408 and the diode D408 connected in turn; the resistor R408 is connected in parallel with the capacitor C403; the diode D408 is connected in reverse parallel with the diode D409; the resistor R408 and the diode D408 are connected through the diode D407 Connect with the collector of the NPN transistor Q402; the collector of the NPN transistor Q402 is also connected to the two positive poles of the driving power supply circuit through a resistor R409; the emitter of the NPN transistor Q401 and the emitter of the NPN transistor Q402 are respectively connected to the second negative pole of the driving power supply circuit;

NPN三极管Q401集电极通过依次连接的电阻R405和二极管D405与PNP三极管Q403基极连接；电阻R405并联有电容C402；二极管C405反向并联有二极管D404；电阻R405和二极管D405连接处通过二极管D406与PNP三极管Q403集电极连接；PNP三极管Q403基极通过电阻R406与驱动供电电路二正极连接；PNP三极管Q403发射极通过电阻R407与驱动供电电路二正极连接；The collector of the NPN transistor Q401 is connected to the base of the PNP transistor Q403 through the resistor R405 and the diode D405 connected in sequence; the resistor R405 is connected in parallel with the capacitor C402; the diode C405 is connected in reverse parallel with the diode D404; the resistor R405 and the diode D405 are connected to the PNP through the diode D406 The collector of the transistor Q403 is connected; the base of the PNP transistor Q403 is connected to the two positive poles of the drive power supply circuit through a resistor R406; the emitter of the PNP transistor Q403 is connected to the two positive poles of the drive power supply circuit through a resistor R407;

NPN三极管Q402集电极通过依次连接的电阻R410和二极管D411与NPN三极管Q404基极连接；电阻R410并联有电容C404；二极管D411反向并联有二极管D412；电阻R410和二极管D411连接处通过二极管D410与NPN三极管Q404集电极连接；NPN三极管Q404集电极与PNP三极管Q403集电极连接；NPN三极管Q404发射极通过电阻R411与驱动供电电路二负极连接；NPN三极管Q404集电极通过电阻R412与驱动供电电路二负极连接；NPN三极管Q404集电极与高频切换模块连接。The collector of the NPN transistor Q402 is connected to the base of the NPN transistor Q404 through the resistor R410 and the diode D411 connected in sequence; the resistor R410 is connected in parallel with the capacitor C404; the diode D411 is connected in reverse parallel with the diode D412; the resistor R410 and the diode D411 are connected through the diode D410 and NPN The collector of the transistor Q404 is connected; the collector of the NPN transistor Q404 is connected to the collector of the PNP transistor Q403; the emitter of the NPN transistor Q404 is connected to the second negative electrode of the driving power supply circuit through the resistor R411; the collector of the NPN transistor Q404 is connected to the second negative electrode of the driving power supply circuit through the resistor R412 ; The collector of the NPN transistor Q404 is connected to the high-frequency switching module.

控制***与调制开关管驱动电路之间采用选用光耦隔离式驱动，光耦采用IGBT或者MOSFET专用的高速光耦HCPL-3120，开关延迟时间在0.3us左右，有着小的体积、高的开关速度以及较强的抗冲击能力，足以满足驱动设计要求。由于调制开关管驱动电路产生两路互补且不带死区的驱动电信号，两路调制IGBT开关管的栅极驱动电路结构相同，截取其中一路，隔离光耦后接一个由两个MOSFET组成的半桥拓扑结构，最后输出+15V/-7V电压来驱动调制IGBT开关管。该设置的好处是：具有体积小、开关速度高以及抗冲击能力强的优点，满足驱动设计要求。The control system and the modulation switch tube drive circuit are driven by optocoupler isolation. The optocoupler uses IGBT or MOSFET high-speed optocoupler HCPL-3120, the switching delay time is about 0.3us, and it has a small size and high switching speed. And strong impact resistance, enough to meet the drive design requirements. Since the modulation switch tube drive circuit generates two complementary drive electric signals without dead zone, the gate drive circuits of the two modulation IGBT switch tubes have the same structure. One of them is intercepted, and the optocoupler is isolated and then connected to one composed of two MOSFETs. Half-bridge topology structure, and finally output +15V/-7V voltage to drive and modulate IGBT switch tube. The advantages of this setting are: it has the advantages of small size, high switching speed and strong impact resistance, which meets the requirements of drive design.

输出电压电流采样反馈电路分别用于采集脉冲电流主电路和基值电流主电路输出电压电流。如图5所示，输出电压电流采样反馈电路包括型号为HAS 200-P的200A电流霍尔传感器、由型号为AD629的差动放大器及其***电路构成的集成差动放大电路、由型号为OP177的芯片及其***电路构成的低通滤波电路；所述电流霍尔传感器、集成差动放大电路、低通滤波电路依次连接。The output voltage and current sampling feedback circuit is used to collect the output voltage and current of the pulse current main circuit and the base current main circuit. As shown in Figure 5, the output voltage and current sampling feedback circuit includes a 200A current Hall sensor with model HAS 200-P, an integrated differential amplifier circuit composed of a differential amplifier with model AD629 and its peripheral circuits, and an integrated differential amplifier circuit with model OP177 A low-pass filter circuit composed of a chip and its peripheral circuits; the current Hall sensor, integrated differential amplifier circuit, and low-pass filter circuit are connected in sequence.

电流霍尔传感器转换回来的测量电压值需要经过电阻R501和R502分压，然后 连接到集成差分放大电路，其中U501为具有低失调、低增益误差漂移和高共模抑制比的差动放大器AD629，放大倍数为1。再通过KRC有源低通滤波器进行滤波，本专利采用通带内更为平坦的巴特沃兹滤波器作为模型，其中U502为高精度和低零漂的运算放大器OP177，U502结合外部电阻电容R503、R504、C505和C506数值匹配。The measured voltage value converted by the current Hall sensor needs to be divided by resistors R501 and R502, and then connected to the integrated differential amplifier circuit. U501 is a differential amplifier AD629 with low offset, low gain error drift and high common mode rejection ratio. The magnification is 1. KRC active low-pass filter is used for filtering. This patent uses a flatter Butterworth filter in the pass band as a model. U502 is a high-precision and low zero-drift operational amplifier OP177, and U502 is combined with an external resistor capacitor R503 , R504, C505 and C506 match numerically.

脉冲电流主电路和基值电流主电路中，SiC功率开关管按照预设的时序快速导通与关闭，实现高频直流交流转变；高频切换模块的两个调制开关管IGBT以20kHz或更高的频率交替开关，实现高频脉冲电流的调制两路并联的脉冲电流主电路和基值电流主电路的输出电压电流采样反馈独立控制；通过在脉冲电流主电路和基值电流主电路的输出端分别采集输出电流电压并进行信号调理，与预设值进行比较之后，改变SiC功率开关管的导通与关断时间，实现占空比调节，获得所需的波形输出，完成闭环控制。In the main circuit of pulse current and the main circuit of base value current, the SiC power switch is quickly turned on and off according to the preset time sequence to achieve high-frequency DC and AC conversion; the two modulation switch IGBTs of the high-frequency switch module are operated at 20kHz or higher The frequency is switched alternately to realize the modulation of high-frequency pulse current. The output voltage and current sampling and feedback of the two parallel pulse current main circuits and the base current main circuit are independently controlled; through the output terminals of the pulse current main circuit and the base current main circuit Collect the output current and voltage separately and perform signal conditioning. After comparing with the preset value, change the turn-on and turn-off time of the SiC power switch to realize the duty cycle adjustment, obtain the required waveform output, and complete the closed-loop control.

送丝机包括电机、夹紧轮、固定支架和送丝控制***。送丝控制***包括供电模块、ARM微处理器、电机半桥驱动电路、电压采样反馈电路和数字控制面板。半桥驱动电路可采用现有技术，例如采用中国发明《一种智能型弧焊机器人潜水送丝机》(公开号：103706927B)中详细公开的送丝驱动电路。所述半桥驱动电路主要由2个N沟道型场效应管Q1和场效应管Q2构成的半桥电路、驱动芯片IR2110、光耦PC817、继电器K1、稳压芯片L7815以及其他***电路连接构成。驱动芯片采用的型号为IR2110，并通过继电器K1与光耦PC817构成的换向电路实现电机的正转、反转的转换。其中，电机两端与连接器P1相连，两路互补的带死区PWM信号分别输入至驱动芯片IR2110。Inversion换向端保持为高电平，继电器保持在正转端，当PWMH为高电平，PWML为低电平时，由于电容C2和C3、二极管D1组成的自举电路的作用，此时场效应管Q1可靠导通，场效应管Q2关断，电机正负两端短接于24V，处于急停状态；当PWMH为低电平，PWL为高电平时，场效应管Q2导通，场效应管Q1关断，此时电机两端电压为+24V，电机处于正转状态。当Inversion换向端保持为低电平时，光耦PC817的三极管导通，继电器保持在反转端，当PWMH为高电平，PWML为低电平时，场效应管Q1导通，场效应管Q2关断，此时电机两端电压为+24V，电机处于反转状态；当PWM L为高电平，PWMH为低电平时，电机正负两端短接于24V，处于急停状态。因此，通过控制Inversion换向端的高低电平，可以实现脉动送丝，而通过控制PWMH和PWML的占空比，就可以控制送丝的速度，这两者相结合，就可以方便的实现匀速送丝、变速送丝以及脉动送丝等三种送丝模式。The wire feeder includes a motor, a clamping wheel, a fixed bracket and a wire feed control system. The wire feeding control system includes power supply module, ARM microprocessor, motor half-bridge drive circuit, voltage sampling feedback circuit and digital control panel. The half-bridge drive circuit can use the existing technology, for example, the wire feed drive circuit disclosed in detail in the Chinese invention "An Intelligent Arc Welding Robot Submersible Wire Feeder" (Publication No. 103706927B). The half-bridge drive circuit is mainly composed of a half-bridge circuit composed of two N-channel FETs Q1 and FETs Q2, a driver chip IR2110, an optocoupler PC817, a relay K1, a voltage regulator chip L7815, and other peripheral circuit connections. . The driver chip adopts the model IR2110, and realizes the forward and reverse conversion of the motor through the commutation circuit formed by the relay K1 and the optocoupler PC817. Among them, the two ends of the motor are connected to the connector P1, and two complementary PWM signals with dead zone are respectively input to the driver chip IR2110. The Inversion commutation end is maintained at high level, and the relay is maintained at the forward end. When PWMH is high and PWML is low, due to the bootstrap circuit composed of capacitors C2 and C3 and diode D1, the field effect The tube Q1 is turned on reliably, the field effect tube Q2 is turned off, the positive and negative ends of the motor are shorted to 24V, in an emergency stop state; when PWMH is low and PWL is high, the field effect tube Q2 is turned on, and the field effect The tube Q1 is turned off. At this time, the voltage across the motor is +24V, and the motor is in a forward rotation state. When the Inversion commutation end is kept at low level, the transistor of the optocoupler PC817 is turned on, and the relay is kept at the inversion end. When PWMH is high and PWML is low, the FET Q1 is turned on and the FET Q2 is turned on. When the motor is turned off, the voltage across the motor is +24V and the motor is in the reverse state; when PWM L is high and PWMH is low, the positive and negative ends of the motor are shorted to 24V, and the motor is in emergency stop state. Therefore, by controlling the high and low levels of the Inversion commutation end, pulsating wire feeding can be realized, and by controlling the duty ratio of PWMH and PWML, the wire feeding speed can be controlled. The combination of the two can easily realize uniform speed feeding. Three wire feeding modes: wire feeding, variable speed wire feeding and pulse wire feeding.

电压采样反馈电路可采用现有技术，例如中国发明《一种智能型弧焊机器人潜水送丝机》(公开号：103706927B)中详细公开的送丝速度检测电路。所述电压采样反馈电路的连接器P3与电机正负两端相连接，电机两端电压经过电阻分压，差分放大，线性光耦隔离，进一步分压后输入到控制芯片STM32F405RG，进过A/D转换后与电压给定值进行比较，从而调整PWM信号的占空比，达到调节电机运行速度的目的。其中，电阻R6、电阻R7与电阻R8、电阻R9分别组成两个输入电压的分压电路，将电压等比例降低至适合运算放大器LF353的输入电压。电感L5、电感L6、电容C10组成输入端的LC滤波电路。运算放大器U4构成差分放大电路，将经过降压后的电机两端的电压先放大至两倍，然后求两者差值后输出，从而将输入的差动信号转变为单边电压信号输出。二极管D6、二极管D7与二极管D8、二极管D9分别为运算放大器U4两输入端的保护二极管，当输入端电压绝对值高于15V时，其中一个二极管导通，有效保护了运算放大器。由于线性光耦U6为电流驱动型光耦元件，所隔离的为电流量，所以运算放大器U5与电阻R17组成电压-电流转换电路，将运算放大器输入端的电压转换成线性光耦HCNR201的LED驱动电流，而运算放大器U5与电阻R16、电容C11、二极管D10组成线性光耦U6的闭环反馈电路，以补偿U6的LED的非线性以及温度漂移，而电容C11也能起到滤除高频噪声信号的作用。运算放大器U7与电阻R22、电阻R18组成电流-电压转换电路，将线性光耦U6的输出电流转换成电压，调整电阻R22的阻值至合适值，即可得到与运算放大器U4单边输出电压相等的电压值，经过电阻R18的进一步降压，将运算放大器U7的输出电压降至控制芯片STM32F405RG合适的输入电压，其中二极管D11、二极管D12组成输入端保护电路，防止Feedback端的电压高于3.3V。The voltage sampling feedback circuit can use the existing technology, for example, the wire feeding speed detection circuit disclosed in detail in the Chinese invention "A Smart Arc Welding Robot Submersible Wire Feeder" (Publication No. 103706927B). The connector P3 of the voltage sampling feedback circuit is connected to the positive and negative ends of the motor. The voltage at both ends of the motor is divided by resistance, amplified by differential, and isolated by linear optocoupler. After further division, it is input to the control chip STM32F405RG and enters the A/ After D is converted, it is compared with the given voltage value to adjust the duty cycle of the PWM signal to achieve the purpose of regulating the running speed of the motor. Among them, the resistor R6, the resistor R7, the resistor R8, and the resistor R9 respectively form a voltage divider circuit of two input voltages, and the voltage is proportionally reduced to the input voltage suitable for the operational amplifier LF353. The inductor L5, the inductor L6, and the capacitor C10 form an LC filter circuit at the input. The operational amplifier U4 forms a differential amplifier circuit, which amplifies the voltage at both ends of the motor after the step-down to twice, and then calculates the difference between the two and outputs it, thereby converting the input differential signal into a unilateral voltage signal output. The diode D6, the diode D7, the diode D8, and the diode D9 are respectively the protection diodes of the two input terminals of the operational amplifier U4. When the absolute value of the input terminal voltage is higher than 15V, one of the diodes is turned on, effectively protecting the operational amplifier. Since the linear optocoupler U6 is a current-driven optocoupler element, the amount of current isolated is the amount of current, so the operational amplifier U5 and the resistor R17 form a voltage-current conversion circuit, which converts the voltage at the input of the operational amplifier into the LED drive current of the linear optocoupler HCNR201 , And the operational amplifier U5, resistor R16, capacitor C11, and diode D10 form a closed-loop feedback circuit of linear optocoupler U6 to compensate for the nonlinearity and temperature drift of the LED of U6. The capacitor C11 can also filter out high-frequency noise signals. effect. Operational amplifier U7, resistor R22 and resistor R18 form a current-voltage conversion circuit, which converts the output current of linear optocoupler U6 into a voltage, adjust the resistance of resistor R22 to a suitable value, and obtain the same unilateral output voltage as operational amplifier U4 After the further step-down of the resistor R18, the output voltage of the operational amplifier U7 is reduced to the appropriate input voltage of the control chip STM32F405RG. The diode D11 and the diode D12 form the input terminal protection circuit to prevent the voltage at the Feedback terminal from being higher than 3.3V.

ARM微处理器产生一组PWM信号，经过驱动电路的放大隔离后，用于驱动电机半桥驱动电路中的功率开关管，从而实现电机的运转；而电机的转速则采用 电枢电压控制法进行调节，通过电压采样反馈电路采样得到电枢电压并反馈给ARM微处理器，ARM微处理器的ADC模块将馈入的信号进行模数转换后，与给定的数值比较并进行PI调节，进而输出相应脉宽的驱动信号，从而实现电枢电压的闭环调节，实现送丝速度的精确无级调节；所述送丝机通过CAN与***其他设备相连，送丝机的运行参数可由快频脉冲TIG焊接电源进行设置。The ARM microprocessor generates a set of PWM signals. After being amplified and isolated by the drive circuit, they are used to drive the power switch in the motor half-bridge drive circuit to realize the operation of the motor; and the motor speed is controlled by the armature voltage control method. Adjustment, the armature voltage is sampled by the voltage sampling feedback circuit and fed back to the ARM microprocessor. After the ADC module of the ARM microprocessor performs analog-to-digital conversion of the fed signal, it compares with the given value and performs PI adjustment. Output the drive signal of corresponding pulse width, so as to realize the closed-loop adjustment of the armature voltage, and realize the precise stepless adjustment of the wire feeding speed; the wire feeder is connected to other equipment in the system through CAN, and the operating parameters of the wire feeder can be pulsed with fast frequency TIG welding power source is set.

工业机器人、焊枪、送气装置和夹具可采用现有技术。Industrial robots, welding torches, air supply devices and fixtures can adopt existing technologies.

本发明快频脉冲TIG焊接***的工作原理为：首先进行焊接路径规划，设定好工业机器人的运动路径后，运行到焊接起始点，等待快频脉冲TIG焊接电源的同步信号；通过人机交互***设定焊接参数输入到快频脉冲TIG焊接电源；快频脉冲TIG焊接电源控制启动送气装置后，快频脉冲TIG焊接电源的主电路首先工作，利用高频高压引弧电路击穿焊枪的钨极和喷嘴间的气隙，在焊接工件和钨极之间将形成电弧；转起弧成功之后，快频脉冲TIG焊接电源将输出行走信号给工业机器人，焊枪则按照既定的路径和速度行走。其中工业机器人、人机交互***、快频脉冲TIG焊接电源、送丝机均通过CAN网络进行高速数字协同，从而确保在整个焊接过程中，各组成能实现有机配合和高速协同，提高了快频脉冲TIG焊接过程的自动化和智能化水平。The working principle of the fast-frequency pulse TIG welding system of the present invention is: firstly, the welding path planning is carried out, and after the motion path of the industrial robot is set, it runs to the welding starting point and waits for the synchronization signal of the fast-frequency pulse TIG welding power supply; through human-computer interaction The system sets the welding parameters and inputs them to the fast-frequency pulse TIG welding power supply; after the fast-frequency pulse TIG welding power supply controls and starts the air supply device, the main circuit of the fast-frequency pulse TIG welding power supply works first, and the tungsten of the welding gun is broken down by the high-frequency high-voltage arc ignition circuit The air gap between the electrode and the nozzle will form an arc between the welding workpiece and the tungsten electrode; after the arc start is successful, the fast-frequency pulse TIG welding power source will output a walking signal to the industrial robot, and the welding gun will walk according to the established path and speed. Among them, industrial robots, human-computer interaction systems, fast-frequency pulse TIG welding power supplies, and wire feeders all perform high-speed digital collaboration through the CAN network, so as to ensure that the components can achieve organic coordination and high-speed collaboration during the entire welding process, which improves the fast frequency The automation and intelligence level of the pulse TIG welding process.

上述实施例为本发明较佳的实施方式，但本发明的实施方式并不受上述实施例的限制，其他的任何未背离本发明的精神实质与原理下所作的改变、修饰、替代、组合、简化，均应为等效的置换方式，都包含在本发明的保护范围之内。The above-mentioned embodiments are preferred embodiments of the present invention, but the embodiments of the present invention are not limited by the above-mentioned embodiments, and any other changes, modifications, substitutions, combinations, etc. made without departing from the spirit and principle of the present invention Simplified, all should be equivalent replacement methods, and they are all included in the protection scope of the present invention.

Claims (10)

1. 一种快频脉冲TIG焊接***，其特征在于：包括快频脉冲TIG焊接电源；所述快频脉冲TIG焊接电源包括主电路、控制电路和人机交互***；A fast-frequency pulse TIG welding system, characterized in that it comprises a fast-frequency pulse TIG welding power source; the fast-frequency pulse TIG welding power source comprises a main circuit, a control circuit and a human-computer interaction system;

   所述主电路包括工频整流滤波模块、脉冲电流主电路、基值电流主电路和高频电流切换电路；所述脉冲电流主电路包括依次连接的SiC全桥逆变换流模块一、高频变压模块一和SiC整流平滑模块一；所述基值电流主电路包括依次连接的SiC全桥逆变换流模块二、高频变压模块二和SiC整流平滑模块二；所述高频电流切换电路包括依次连接的高频切换模块和防反灌模块；所述SiC全桥逆变换流模块一包括SiC功率开关管；The main circuit includes a power frequency rectification filter module, a pulse current main circuit, a base current main circuit, and a high-frequency current switching circuit; the pulse current main circuit includes a SiC full-bridge inverse conversion current module connected in sequence. Voltage module one and SiC rectification and smoothing module one; the base value current main circuit includes a SiC full-bridge inverse conversion module two, a high-frequency transformer module two, and a SiC rectification and smoothing module two connected in sequence; the high-frequency current switching circuit It includes a high-frequency switching module and an anti-reverse irrigation module connected in sequence; the SiC full-bridge reverse conversion current module includes a SiC power switch tube;

   其中，三相交流输入电源与工频整流滤波模块连接；工频整流滤波模块分别与SiC全桥逆变换流模块一和SiC全桥逆变换流模块二连接；SiC整流平滑模块一与高频切换模块连接；防反灌模块与外部电弧负载连接；SiC整流平滑模块二与外部电弧负载连接；Among them, the three-phase AC input power supply is connected to the power frequency rectification filter module; the power frequency rectification filter module is connected to the SiC full-bridge inverse conversion flow module 1 and the SiC full-bridge inverse conversion flow module 2; the SiC rectification and smoothing module 1 is connected to high-frequency switching Module connection; anti-reverse irrigation module connected with external arc load; SiC rectifier smoothing module 2 connected with external arc load;

   所述控制电路包括ARM最小控制***，以及分别与ARM最小控制***连接的人机交互通信模块、SiC高频驱动电路、切换开关驱动电路和输出电压电流采样反馈电路；其中，SiC高频驱动电路分别与SiC全桥逆变换流模块一和SiC全桥逆变换流模块二连接；切换开关驱动电路与高频切换模块连接；输出电压电流采样反馈电路分别与外部电弧负载、SiC整流平滑模块一和SiC整流平滑模块二连接；人机交互通信模块与人机交互***连接。The control circuit includes an ARM minimum control system, and a human-computer interaction communication module connected to the ARM minimum control system, a SiC high-frequency drive circuit, a switch drive circuit, and an output voltage and current sampling feedback circuit; wherein, the SiC high-frequency drive circuit Connected to SiC full-bridge inverse conversion current module 1 and SiC full-bridge inverse conversion current module 2 respectively; the switch drive circuit is connected to the high-frequency switching module; the output voltage and current sampling feedback circuit is connected to the external arc load and the SiC rectifier smoothing module 1 and SiC rectifying and smoothing module two is connected; the man-machine interactive communication module is connected with the man-machine interactive system.
2. 根据权利要求1所述的快频脉冲TIG焊接***，其特征在于：所述SiC全桥逆变换流模块一包括SiC功率开关管，是指：SiC全桥逆变换流模块一包括SiC功率开关管M101、SiC功率开关管M102、SiC功率开关管M103和SiC功率开关管M104；所述高频变压模块一包括高频变压器一T101；所述SiC功率开关管M101、SiC功率开关管M102、SiC功率开关管M103和SiC功率开关管M104组成全桥逆变 电路，之后通过隔直电容C109与高频变压器一T101的初级连接；所述SiC功率开关管M101、SiC功率开关管M102、SiC功率开关管M103和SiC功率开关管M104分别并联有RC吸收电路一；The fast-frequency pulse TIG welding system according to claim 1, characterized in that: the SiC full-bridge inverse conversion current module includes a SiC power switch tube, which means: the SiC full-bridge inverse conversion current module includes a SiC power switch tube M101, SiC power switch tube M102, SiC power switch tube M103, and SiC power switch tube M104; the high-frequency transformer module one includes a high-frequency transformer one T101; the SiC power switch tube M101, SiC power switch tube M102, SiC The power switch tube M103 and the SiC power switch tube M104 form a full-bridge inverter circuit, which is then connected to the primary of a high-frequency transformer T101 through a DC blocking capacitor C109; the SiC power switch tube M101, SiC power switch tube M102, and SiC power switch Tube M103 and SiC power switch tube M104 are connected in parallel with RC absorption circuit one;

   所述SiC整流平滑模块一包括整流二极管VD101、整流二极管VD102和电感L101；高频变压器一T101的次级第一输出端通过依次连接的整流二极管VD101和整流二极管VD102与高频变压器一T101的次级第三输出端连接；整流二极管VD101和整流二极管VD102的连接处与电感L101的一端连接；电感L101的另一端与高频变压器一T101的次级第二输出端分别作为脉冲电流主电路的输出端来与高频切换模块连接。The first SiC rectifier and smoothing module includes a rectifier diode VD101, a rectifier diode VD102, and an inductor L101; the secondary first output end of the high-frequency transformer-T101 is connected to the rectifier diode VD101 and the rectifier diode VD102 and the high-frequency transformer-T101 in sequence. The third output terminal of the stage is connected; the connection of the rectifier diode VD101 and the rectifier diode VD102 is connected to one end of the inductor L101; the other end of the inductor L101 and the secondary output terminal of the high-frequency transformer T101 are respectively used as the output of the pulse current main circuit The terminal is connected with the high-frequency switching module.
3. 根据权利要求2所述的快频脉冲TIG焊接***，其特征在于：所述的SiC功率开关管M101、SiC功率开关管M102、SiC功率开关管M103和SiC功率开关管M104组成全桥逆变电路，之后通过隔直电容C109与高频变压模块一的初级连接；所述SiC功率开关管M101、SiC功率开关管M102、SiC功率开关管M103和SiC功率开关管M104分别并联有RC吸收电路一，是指：The fast frequency pulse TIG welding system according to claim 2, characterized in that: the SiC power switch tube M101, SiC power switch tube M102, SiC power switch tube M103, and SiC power switch tube M104 form a full-bridge inverter circuit After that, it is connected to the primary of the high-frequency transformer module 1 through the blocking capacitor C109; the SiC power switch tube M101, SiC power switch tube M102, SiC power switch tube M103, and SiC power switch tube M104 are respectively connected in parallel with RC absorption circuit 1 ,Refers to:

   还包括电容C101、电容C102、电容C103、电容C104、电容C109、电阻R101、电阻R102、电阻R103和电阻R104；It also includes a capacitor C101, a capacitor C102, a capacitor C103, a capacitor C104, a capacitor C109, a resistor R101, a resistor R102, a resistor R103, and a resistor R104;

   SiC功率开关管M101和SiC功率开关管M103串联后，与SiC功率开关管M102和SiC功率开关管M104串联形成的电路一起并联到工频整流滤波电路上；电容C101和电阻R101串联后并联到SiC功率开关管M101上；电容C102和电阻R102串联后并联到SiC功率开关管M102上；电容C103和电阻R103串联后并联到SiC功率开关管M103上；电容C104和电阻R104串联后并联到SiC功率开关管M104上；所述SiC功率开关管M101与SiC功率开关管M103的连接处与电容C109串联后与高频变压模块一的初级第一输入端连接；所述SiC功率开关管M102与SiC功率开关管M104的连接处与高频变压模块一的初级第二输入端连接。After the SiC power switch tube M101 and the SiC power switch tube M103 are connected in series, the circuit formed by the series connection of the SiC power switch tube M102 and the SiC power switch tube M104 is connected in parallel to the power frequency rectifier filter circuit; the capacitor C101 and the resistor R101 are connected in parallel to the SiC On the power switch M101; the capacitor C102 and the resistor R102 are connected in series and then connected in parallel to the SiC power switch M102; the capacitor C103 and the resistor R103 are connected in series and then connected in parallel to the SiC power switch M103; the capacitor C104 and the resistor R104 are connected in series and connected in parallel to the SiC power switch On the tube M104; the connection between the SiC power switch tube M101 and the SiC power switch tube M103 is connected in series with the capacitor C109 and then connected to the primary first input terminal of the high frequency transformer module one; the SiC power switch tube M102 and the SiC power The connection of the switch tube M104 is connected with the primary second input terminal of the high-frequency transformer module one.
4. 根据权利要求2所述的快频脉冲TIG焊接***，其特征在于：所述SiC全桥逆变换流模块二的电路结构与SiC全桥逆变换流模块一相同；高频变压模块二的电路结构与高频变压模块一相同；SiC整流平滑模块二的电路结构与SiC整流平滑模块一相同。The fast-frequency pulse TIG welding system according to claim 2, wherein the circuit structure of the second SiC full-bridge inverse conversion flow module is the same as that of the first SiC full-bridge inverse conversion flow module; and the circuit of the second high-frequency transformer module The structure is the same as the high-frequency transformer module one; the circuit structure of the SiC rectifying and smoothing module two is the same as that of the SiC rectifying and smoothing module one.
5. 根据权利要求2所述的快频脉冲TIG焊接***，其特征在于：所述高频切换模块包括调制开关管IGBT Q202和调制开关管IGBT Q201；所述防反灌模块包括整流二极管VD201；所述调制开关管IGBT Q201并联在所述SiC整流平滑模块一上；SiC整流平滑模块一通过依次连接的调制开关管IGBT Q202和整流二极管VD201与外部电弧负载连接；所述调制开关管IGBT Q202并联有尖峰电压吸收模块一；调制开关管IGBT Q201并联有尖峰电压吸收模块二。The fast-frequency pulse TIG welding system according to claim 2, characterized in that: the high-frequency switching module includes a modulation switch tube IGBT Q202 and a modulation switch tube IGBT Q201; the anti-backflow module includes a rectifier diode VD201; The modulation switch IGBT Q201 is connected in parallel to the SiC rectification and smoothing module 1; the SiC rectification and smoothing module 1 is connected to the external arc load through the modulation switch IGBT Q202 and the rectifier diode VD201 connected in sequence; the modulation switch IGBT Q202 is connected in parallel with a spike Voltage absorption module one; Modulation switch tube IGBT Q201 is connected in parallel with peak voltage absorption module two.
6. 根据权利要求5所述的快频脉冲TIG焊接***，其特征在于：所述尖峰电压吸收模块一包括电容C202、电阻R202、二极管D204和二极管D203；电阻R202和电容C202并联后与二极管D204串联形成的电路并联到调制开关管IGBT Q202上；二极管D203并联在调制开关管IGBT Q202上；The fast-frequency pulse TIG welding system according to claim 5, characterized in that: the spike voltage absorption module one includes a capacitor C202, a resistor R202, a diode D204, and a diode D203; the resistor R202 and the capacitor C202 are connected in parallel and formed in series with the diode D204 The circuit of is connected in parallel to the modulation switch IGBT Q202; the diode D203 is connected in parallel to the modulation switch IGBT Q202;

   所述尖峰电压吸收模块二包括电容C201、电阻R201、二极管D202和二极管D201；电阻R201和二极管D202并联后与电容C201串联形成的电路并联到调制开关管IGBT Q201上；二极管D201并联在调制开关管IGBT Q201上。The second peak voltage absorption module includes a capacitor C201, a resistor R201, a diode D202, and a diode D201; the resistor R201 and the diode D202 are connected in parallel with the capacitor C201 to form a circuit connected in parallel to the modulation switch IGBT Q201; the diode D201 is connected in parallel to the modulation switch IGBT Q201 on.
7. 根据权利要求1所述的快频脉冲TIG焊接***，其特征在于：所述ARM最小控制***通过隔离一与SiC高频驱动电路连接；所述ARM最小控制***通过隔离二与切换开关驱动电路连接。The fast-frequency pulse TIG welding system according to claim 1, characterized in that: the ARM minimum control system is connected to the SiC high frequency drive circuit through isolation one; the ARM minimum control system is connected to the switch drive circuit through isolation two .
8. 根据权利要求7所述的快频脉冲TIG焊接***，其特征在于：所述ARM最小控制***通过隔离一与SiC高频驱动电路连接，是指：ARM最小控制***通过型号为ISO5451的隔离驱动芯片与SiC高频驱动电路连接，隔离驱动芯片还连接有驱动供电电路一；The fast-frequency pulse TIG welding system according to claim 7, characterized in that: the ARM minimum control system is connected to the SiC high-frequency drive circuit through isolation 1, which means that the ARM minimum control system is connected to the ISO5451 isolation drive chip Connected to the SiC high-frequency drive circuit, and the isolation drive chip is also connected to drive power supply circuit one;

   所述SiC高频驱动电路包括电容C304、电容C305、稳压管ZD301、 二极管D302、二极管D303、电阻R310、电阻R311、电阻R312和电阻R313；隔离驱动芯片的引脚CLAMP与SiC功率开关管栅极连接；SiC功率开关管栅极通过并联的电阻R313和电容C305接地；隔离驱动芯片的引脚OUT通过电阻R312与SiC功率开关管栅极连接；二极管D303和电阻R311串联后并联在电阻R312上；隔离驱动芯片的引脚OUT通过串联的电阻R310和二极管D302与SiC功率开关管漏极连接；隔离驱动芯片的引脚OUT还通过并联的电容C304和稳压二极管ZD301接地；隔离驱动芯片的引脚DESAT与隔离驱动芯片的引脚OUT连接。The SiC high-frequency drive circuit includes capacitor C304, capacitor C305, Zener tube ZD301, diode D302, diode D303, resistor R310, resistor R311, resistor R312, and resistor R313; the pin CLAMP of the isolation drive chip and the SiC power switch grid Pole connection; the gate of the SiC power switch is connected to the ground through the parallel resistor R313 and the capacitor C305; the pin OUT of the isolation drive chip is connected to the gate of the SiC power switch through the resistor R312; the diode D303 and the resistor R311 are connected in parallel to the resistor R312 in series The pin OUT of the isolation drive chip is connected to the drain of the SiC power switch through the series resistor R310 and diode D302; the pin OUT of the isolation drive chip is also grounded through the parallel capacitor C304 and the Zener diode ZD301; the lead of the isolation drive chip The pin DESAT is connected to the pin OUT of the isolation driver chip.
9. 根据权利要求7所述的快频脉冲TIG焊接***，其特征在于：所述ARM最小控制***通过隔离二与切换开关驱动电路连接，是指：ARM最小控制***通过光耦隔离芯片与切换开关驱动电路连接；所述切换开关驱动电路包括NPN三极管Q401、NPN三极管Q402、NPN三极管Q404、PNP三极管Q403和驱动供电电路二；The fast-frequency pulse TIG welding system according to claim 7, characterized in that: the ARM minimum control system is connected to the switch drive circuit through isolation two, which means that the ARM minimum control system is driven by the optocoupler isolation chip and the switch drive circuit Circuit connection; the switch drive circuit includes NPN transistor Q401, NPN transistor Q402, NPN transistor Q404, PNP transistor Q403 and driving power supply circuit two;

   光耦隔离芯片的输出端通过依次连接的电阻R402、电阻R403和二极管D402与NPN三极管Q401基极连接；电阻R403并联有电容C401；二极管D402反向并联有二极管D403；电阻R403和二极管D402连接处通过二极管D401与NPN三极管Q401集电极连接；NPN三极管Q401集电极还通过电阻R404与驱动供电电路二正极连接；The output terminal of the optocoupler isolation chip is connected to the base of the NPN transistor Q401 through the resistor R402, the resistor R403 and the diode D402 connected in sequence; the resistor R403 is connected in parallel with the capacitor C401; the diode D402 is connected in reverse parallel with the diode D403; the resistor R403 and the diode D402 are connected The collector of the NPN transistor Q401 is connected through a diode D401; the collector of the NPN transistor Q401 is also connected to the two anodes of the driving power supply circuit through a resistor R404;

   电阻R402和电阻R403连接处通过依次连接的电阻R408和二极管D408与NPN三极管Q402基极连接；电阻R408并联有电容C403；二极管D408反向并联有二极管D409；电阻R408和二极管D408连接处通过二极管D407与NPN三极管Q402集电极连接；NPN三极管Q402集电极还通过电阻R409与驱动供电电路二正极连接；NPN三极管Q401发射极和NPN三极管Q402发射极分别与驱动供电电路二负极连接；The connection of the resistor R402 and the resistor R403 is connected to the base of the NPN transistor Q402 through the resistor R408 and the diode D408 connected in turn; the resistor R408 is connected in parallel with the capacitor C403; the diode D408 is connected in reverse parallel with the diode D409; the resistor R408 and the diode D408 are connected through the diode D407 Connect with the collector of the NPN transistor Q402; the collector of the NPN transistor Q402 is also connected to the two positive poles of the driving power supply circuit through a resistor R409; the emitter of the NPN transistor Q401 and the emitter of the NPN transistor Q402 are respectively connected to the second negative pole of the driving power supply circuit;

   NPN三极管Q401集电极通过依次连接的电阻R405和二极管D405与PNP三极管Q403基极连接；电阻R405并联有电容C402；二极管C4 05反向并联有二极管D404；电阻R405和二极管D405连接处通过二极管D406与PNP三极管Q403集电极连接；PNP三极管Q403基极通过电阻R406与驱动供电电路二正极连接；PNP三极管Q403发射极通过电阻R407与驱动供电电路二正极连接；The collector of the NPN transistor Q401 is connected to the base of the PNP transistor Q403 through the resistor R405 and the diode D405 connected in sequence; the resistor R405 is connected in parallel with the capacitor C402; the diode C4 05 is connected in reverse parallel with the diode D404; the connection between the resistor R405 and the diode D405 is connected with the diode D406 through the diode D406 The collector of the PNP transistor Q403 is connected; the base of the PNP transistor Q403 is connected to the two positive poles of the drive power supply circuit through a resistor R406; the emitter of the PNP transistor Q403 is connected to the two positive poles of the drive power supply circuit through a resistor R407;

   NPN三极管Q402集电极通过依次连接的电阻R410和二极管D411与NPN三极管Q404基极连接；电阻R410并联有电容C404；二极管D411反向并联有二极管D412；电阻R410和二极管D411连接处通过二极管D410与NPN三极管Q404集电极连接；NPN三极管Q404集电极与PNP三极管Q403集电极连接；NPN三极管Q404发射极通过电阻R411与驱动供电电路二负极连接；NPN三极管Q404集电极通过电阻R412与驱动供电电路二负极连接；NPN三极管Q404集电极与高频切换模块连接。The collector of the NPN transistor Q402 is connected to the base of the NPN transistor Q404 through the resistor R410 and the diode D411 connected in sequence; the resistor R410 is connected in parallel with the capacitor C404; the diode D411 is connected in reverse parallel with the diode D412; the resistor R410 and the diode D411 are connected through the diode D410 and NPN The collector of the transistor Q404 is connected; the collector of the NPN transistor Q404 is connected to the collector of the PNP transistor Q403; the emitter of the NPN transistor Q404 is connected to the second negative electrode of the driving power supply circuit through the resistor R411; the collector of the NPN transistor Q404 is connected to the second negative electrode of the driving power supply circuit through the resistor R412 ; The collector of the NPN transistor Q404 is connected to the high-frequency switching module.
10. 根据权利要求1至9中任一项所述的快频脉冲TIG焊接***，其特征在于：还包括工业机器人、送丝机、焊枪、送气装置和夹具；所述工业机器人和送丝机分别与ARM最小控制***连接；所述夹具分别与工业机器人和焊枪连接；所述快频脉冲TIG焊接电源还与送气装置连接；所述焊枪还分别与送气装置和送丝机连接。The fast-frequency pulse TIG welding system according to any one of claims 1 to 9, characterized in that it further comprises an industrial robot, a wire feeder, a welding torch, an air supply device and a fixture; the industrial robot and the wire feeder are respectively connected with The ARM minimum control system is connected; the clamps are respectively connected with the industrial robot and the welding gun; the fast-frequency pulse TIG welding power source is also connected with an air supply device; the welding gun is also connected with an air supply device and a wire feeder respectively.

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