KR101492596B1 - Multifunctional welding machine - Google Patents

Abstract

The present invention relates to a hybrid multifunctional welder.
The present invention relates to a hybrid multifunctional welding machine, which comprises a power source unit including an input power source, a power source input terminal, an inverter unit, and a power supply unit for converting an AC voltage into a DC voltage using a normal commercial power source and supplying the converted DC voltage, A transformer for dropping the DC voltage inputted from the power supply unit; When supplied with a DC voltage drop from the transformer CO _2, A positive output terminal connected to the rectifier and the reactor for outputting a current for performing a manual metal arc (MMA), a tungsten inert gas (MIG), a metal inert gas (MIG) An output section including an output terminal composed of a CO ₂ output terminal and a TIG output terminal connected to a high frequency generator for high frequency control; 380V, and 440V according to the required power by switching the power source inputted to the power source unit; And an arc welding control panel switched to a TIG welding mode or an ARC welding mode by the on / off method of the switch unit and an arc welding control panel switched to a CO ₂ welding mode, a MIG welding mode, and a MAG welding mode, And a mode control unit for performing a welding operation.

Description

Technical Field [0001] The present invention relates to a hybrid multifunctional welding machine,

The present invention relates to a hybrid multifunctional welder. More specifically, the CO ₂ via the switching voltage control, high-frequency control, the feed motor control, gas valve control, welding control mode of the welder, In order to perform various welding with one welder by integrating MMA (Manual Metal Arc), TIG (tungsten inert gas), MIG (Metal Inert Gas) and MAG (metal active gas) welding machine, To a hybrid multifunctional welder.

Generally, welding is a technique for cutting and joining metals by using heat or pressure, and is widely used in the production of electric and electronic products and general industrial sites. The tendency of development of such welding is high quality, high precision, multi-function, unmanned and automated trend according to the development of power electronics and consumer demands, and a spatter reduction in the workplace is demanded.

Such a conventional welding machine is not a device for producing materials and materials in the manufacturing and manufacturing industry, but rather functions to increase the value of goods by processing the materials, and the materials used are steel, non-ferrous, and non-metal materials.

Here, the welding machine is classified according to the material, and the amount of the current supplied to the welding machine must be changed as the material is divided.

That is, general welding machines are divided into CO ₂ welding machine, MIG welding machine, MAG welding machine, TIG welding machine, ARC welding machine and the like. Also, the two types of welding machines are classified into mechanical bonding and metallurgical bonding.

Mechanical bonding is a localized plastic deformation of the joint surface, such as bolt joint, rivet joint, and heating joint. The metallurgical joint is used to locally melt the joint surface by applying heat energy to the joint surface, Most of the welds belong to this method.

In addition, the components necessary for the welding operation are different from each other in the kind of welding, but the same heat source as the base material to be welded, gas heat or electric energy is mainly used, and heat source such as chemical reaction heat, mechanical energy, , Welding consumables such as welding rod or lead necessary for fusion, welding cable, holder, toothed wire, and other tools.

However, in the case of the conventional welding machine, since the welding machine used for connecting the metal to the nonmetal and the electricity supplying the electric power to the welding machine in an environment difficult to receive electric power at the construction site are operated separately and operated inefficiently, Of course, there is a problem of polluting the atmospheric environment.

In addition, in order to weld a material made of only a metal material by general welding in which a metal is bonded by heating with an additive metal having almost the same melting point as the metal, electric welding or gas welding should be selected depending on the type of welding or the environment of the base material , There is also a problem that the efficiency of the welding is remarkably reduced unlike the welding machine used depending on the type of welding.

On the other hand, in recent years, the number of persons working in the welding field is decreasing and the proportion of women is increasing. Therefore, the development direction of the technology required for the welding machine is required to be suitable for automation and robotization.

The welding wire is fed to the head portion of the welding torch by the wire feeding device and is connected to the power source by the contactor tip at the head of the welding torch and an arc is generated between the welding material and the base material, So that the metal is bonded.

As shown in Fig. 1, the inverter control type welding machine converts the alternating current of the commercial frequency into the direct current and converts it into the high frequency of 10 to 50 kHz by the inverter using the high speed switching device.

The high-frequency output is rectified by the welding transformer to a voltage suitable for welding, and the DC current is smoothed through a DC reactor to supply an appropriate DC to the arc load. Inverter type MAG / CO2 welder can reduce the generation of spatter by directly controlling the voltage and current in the form suitable for welding by using switching device.

The welding current is controlled by the direct control circuit to be suitable for welding during the short-circuit period or arc occurrence, and the maximum current at the time of short circuit is reduced so that the spatter does not scatter from the melting point during arc regeneration. The instantaneous short-circuit current is temporally controlled.

The MIG / CO2 welder is a welding method in which an arc is generated at the feeding end by continuously supplying consumable electrode wires while using a shielding gas, and the volume is transferred to the melting furnace. This welding method largely depends on the type of the shielding gas used, , CO2 welding using pure carbon dioxide gas, and MAG welding in which CO2 and AR gas are mixed.

Korean Patent Publication No. 2008-0001303 (2008.05.26.)

Korea Registered Utility Model 0403989 (Dec. 9, 2005)

In order to solve the above problems, the present invention provides a welding apparatus and a welding apparatus for welding CO ₂ , CO ₂ and CO ₂ through a welding voltage control, a welding motor control, a welding motor control, It can supply various current to welder in order to perform various welding with one welder by integrating MMA (Manual Metal Arc), TIG (tungsten inert gas), MIG (Metal Inert Gas) and MAG The present invention relates to a hybrid multifunctional welding machine.

In addition, the present invention CO _2, By providing an integrated control system that integrates MMA (Manual Metal Arc), TIG (tungsten inert gas), MIG (metal inert gas) and MAG (metal active gas) welders, It has its purpose.

In addition, since the present invention can perform various welding methods with a single welding machine, not only high quality welding and energy saving, but also welding cost, adjustment of parameters, improvement of productivity, It aims to save material, reduce weight, and increase production speed.

According to an aspect of the present invention, there is provided a hybrid multifunctional welding machine including an input power source, a power input terminal, an inverter unit, and an inverter unit for converting an AC voltage into a DC voltage using a normal commercial power source, A power supply unit including a power supply unit, a transformer for dropping a DC voltage input from the power supply unit, When supplied with a DC voltage drop from the transformer CO _2, A positive output terminal connected to the rectifier and the reactor for outputting a current for performing a manual metal arc (MMA), a tungsten inert gas (MIG), a metal inert gas (MIG) An output section including an output terminal composed of a CO ₂ output terminal and a TIG output terminal connected to a high frequency generator for high frequency control; 380V, and 440V according to the required power by switching the power source inputted to the power source unit; And an arc welding control panel switched to a TIG welding mode or an ARC welding mode by the on / off method of the switch unit and an arc welding control panel switched to a CO ₂ welding mode, a MIG welding mode, and a MAG welding mode, And a mode control unit for performing a welding operation.

In the present invention, the power supply unit converts the AC voltage from an input power source to a DC voltage, stores the converted AC voltage in a battery, inputs the converted DC voltage to an inverter unit using an IGBT (Insulated Gate Bipolar Transistor) through a power input terminal, The DC voltage converted by the converter is converted into an AC voltage through the high frequency control and input to the transformer to lower the voltage, and then the voltage is supplied to the output unit.

In the present invention, the power input terminal is a safety protection diode for preventing a reversed voltage that may occur when the switch unit is turned off, in contrast to the case where the polarity of the power source is changed. The hybrid multi- Lt; / RTI >

In the present invention, when the switch unit selects the TIG mode using the switch SW1, the CR1 is turned off to connect the switching signal to the resistance welding control board on the drive substrate, CR1 to connect the TIG torch switch to the resistance welding control board, And a CO ₂ mode torch switch is cut off through a common feed unit configured in an arc welding control panel.

Further, in the present invention, the resistance welding control panel is constituted by a high frequency control module such that TIG welding and ARC welding are performed.

According to the present invention, CO ₂ , MMA (Manual Metal Arc), TIG (tungsten inert gas), TIG (tungsten inert gas), MIG (Metal Inert gas, and MAG (metal active gas) welding machine, it is possible to stably supply various currents to the welding machine to perform various welding with one welding machine.

Further, according to the present invention, CO _2, By providing an integrated control system that integrates MMA (Manual Metal Arc), TIG (tungsten inert gas), MIG (Metal Inert Gas) and MAG (metal active gas) welders, There is an effect that can be.

In addition, according to the present invention, it is possible to perform various welding methods with a single welding machine, thereby not only improving the quality of welding, saving energy, but also improving the welding conditions, parameters, productivity, Reduction in weight, reduction in weight, reduction in weight, and production speed.

1 is a block diagram schematically illustrating a control system of a hybrid multifunctional welder according to a preferred embodiment of the present invention.
2 is a view showing a mode control unit of a control system of a hybrid multifunctional welder according to a preferred embodiment of the present invention,
3 is an integrated circuit diagram of a hybrid multi-function welder according to a preferred embodiment of the present invention,
4 is an enlarged view of a main part of an integrated circuit diagram of a hybrid multi-function welder according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 is a block diagram schematically showing a control system of a hybrid multi-function welder according to a preferred embodiment of the present invention, FIG. 2 is a view showing a mode control unit of a control system of a hybrid multi-function welder according to a preferred embodiment of the present invention, FIG. 4 is an enlarged view of a main part of an integrated circuit diagram of a hybrid multifunctional welder according to a preferred embodiment of the present invention. FIG. 4 is an enlarged view of a hybrid multifunctional welder according to a preferred embodiment of the present invention.

As shown, the hybrid multifunctional welder of the present invention provides a power source for driving and welding a multi-function welder using a conventional commercial power source, converts an AC voltage to a DC voltage, and outputs the converted DC voltage to an output unit 200 A power supply unit 100 including an input power supply 102, a power supply input terminal 120, an inverter unit 130 and a power supply unit 140 for inputting a DC voltage input from the power supply unit 100, a transformer 106), when supplied with a DC voltage drop from the transformer (106), CO _2, A rectifier 210, a reactor 220, and an output terminal (not shown) for outputting a current for performing MMA (Manual Metal Arc), TIG (tungsten inert gas), MIG (Metal Inert Gas) A switching unit 300 for switching the power input to the power supply unit 100 and supplying 220 V, 380 V, and 440 V according to the required power, a TIG welding mode 412, an ARC welding mode The desired welding mode is selected through the arc welding control panel 420 constituted by the resistance welding control panel 410 constituted by the welding control panel 410, the CO ₂ welding mode 411, the MIG welding mode 413 and the MAG welding mode 415, And a mode control unit 400 for performing welding according to the mode.

When the AC voltage is input from the generator, the power supply unit 140 converts the AC voltage from the input power supply 102 to a DC voltage and stores the converted DC voltage in the battery. The power supply unit 140 supplies the converted DC voltage to the inverter unit 130).

Here, the power input terminal 120 is a safety protection diode for blocking a reverse voltage that may occur when the switch unit 300 is turned off, in case the polarity of the power source is changed.

The inverter unit 130 controls the voltage corresponding to the load variation of the DC voltage inputted through the power input terminal 120 of the power supply unit 140 and relaxes the high frequency current caused by the load current, Phase voltage inverters using IGBTs (Insulated Gate Bipolar Transistors).

The inverter unit 130 prevents a charge drop caused by an inrush current or a short circuit of the load during welding and repeats ON and OFF of the IGBT so that the temperature generated at the welding part during welding is constant If the temperature is exceeded, turn off the input power.

In addition, the power supply unit 100 of the present invention converts the DC voltage converted by the AC / DC converter 110 into an AC voltage through high frequency control, inputs the converted DC voltage to the transformer 106 to lower the voltage, Supply.

The output unit 200 outputs the AC voltage whose voltage has dropped through the transformer 106 to the DC 15V 5A to 50V 500A through the output side rectifier 210 and the output side reactor 220 and the output terminal 230.

Here, the output terminal 230, a rectifier 210 and a reactor 220 and connected to + pole output terminal 232 and, CO ₂ welding under the control of the arc welding control panel 420 of the mode controller 400 will be described later, Pole output terminal 234 connected to the high frequency generator 240 for high frequency power control so that MMA welding, MIG welding, and MAG welding can be performed.

-Pole output terminal 234 is composed of CO ₂ an output terminal (234a), TIG output terminal (234b) to the TIG welding to occur outputs a predetermined electric power so that the CO ₂ welding done output a predetermined power doedoe plurality configure And high-frequency control is performed through the high-frequency generator 240.

The switch unit 300 is a component that converts the DC voltage converted by the input power supply 102 from the AC converter 110 to an AC voltage and supplies the converted AC voltage to the respective components of each circuit.

Here, the AC converter 110 converts DC 12V to AC 220V, 60Hz, and sinusoidal wave 700W using a DC-AC inverter.

The switch unit 300 selectively supplies the AC voltage converted from the AC converter 110 to the resistance welding control panel 410 and the arc welding control panel 420 of the mode control unit 400 by the on / off method, A first transistor 310 for supplying power to the control panel 410 and a second transistor 320 for supplying power to the arc welding control panel 420.

The switch unit 300 selectively switches the modes of the resistance welding control panel 410 and the arc welding control panel 420 according to the ON / OFF method, and the first or second transistor 310 or 320 And supplies the power required for the resistance welding control panel 410 or the arc welding control panel 420 through the transistors connected and connected to the arc welding control panel 420. [

The switch unit 300 commonly uses the switching unit of the main power control and mode control unit 400 of the multi-function welding machine.

When the switch unit 300 selects the TIG mode using the switch SW1, the CR1 is turned OFF to connect the switching signal to the TIG control board, that is, a resistance welding control board 410, which will be described later.

The CR1 also connects the TIG torch switch 412 to the resistance welding control panel 410 and cuts off the CO ₂ mode torch switch F through the common feed portion 422 configured in the arc welding control panel 420.

Here, a noise filter 414 for removing noise is attached to the TIG torch switch 412, and a start signal is transmitted through the noise filter 414.

The mode control unit 400 is composed of an MLS-11X corresponding to a PCB for a constant current and includes an arc welding control panel 420 for controlling TIG (Tungsten Inert-Gas) and ARC welding, and MLS-9PS And a resistance welding control plate 410 for controlling CO ₂ , MMA (Manual Metal Arc), MIG (Metal Inert Gas), and MAG (Metal Active Gas) welding.

The resistance welding control board 410 uses a converter capable of sinusoidal output because the control method of the wire feed motor is controlled by the SCR control method and the power input of the motor must be made of an AC having a sinusoidal wave.

In this resistance welding control panel 410, the first transistor 310 is operated by turning off the SW1 of the switch unit 300 to supply power to the resistance welding control board 410 so that TIG welding and ARC welding are performed. A module 416 is constructed, and a TIG welding mode 412, an ARC welding mode 414 are configured and controlled by them.

In the CN1 terminal configured in the resistance welding control panel 410, a gas check terminal for checking the gas to be injected is operated to start only the CO ₂ gas valve in the gas valve and start welding.

The CN8 terminal of the resistance welding control panel 410 indicates the rotary switch 418, recognizing only the crater part, recognizing only the spot mode without recognizing the arc repetition, switching to the constant current mode, So that the volume can be varied. Here, the high-frequency induction device is induced not to occur because it cuts off the high frequency.

The second transistor 320 is operated by turning on the switch SW1 of the switch unit 300 to supply power to the arc welding control panel 420 so that CO ₂ , ₂ A welding module 421, an MIG welding module 423, and a MAG welding module 425 are constituted and are components for controlling them.

The CN6 terminal in the arc welding control panel 420 indicates the common feed part 422 and operates the welder's copper signal of the wire feeder line. The feeder gas valve terminal E, the CO ₂ welder copper torch terminal F, Wire inching starting terminal G, wire feed motor terminal I, CO ₂ , MIG, MAG common terminal H.

In addition, the arc welding control panel 420 controls the gas and the welding material according to the welding mode by the feed motor control module 427 and the gas valve control module 429 configured in the common feed section 422.

The main welding voltage, the main welding current, and the second transistor 320, which are parts for performing the automatic switching, represent the remote controller 430 so that the CN8 to CN10 terminals configured in the arc welding control panel 420 can be remotely controlled by the remote controller. And controls the on / off state of the switch unit 300 using a variable resistor.

The CN12 terminal configured in the arc welding control panel 420 functions as a variable resistor to adjust the crater current and voltage.

In addition, the arc welding control panel 420 is provided separately from the TIG mode for the remote control for CO ₂ mode and the wire feeder connection terminal, the torch switch, the remote control, and the wire feeder.

The mode control unit 400 constitutes switches and volumes for the respective adjustment functions on the front operation panel.

The MIG welding machine using inert gas can be selected through the remote controller 430 of the arc welding control panel 420. The CN1 terminal of the resistance welding control plate 410 is connected to the CO ₂ The Ar gas valve is operated based on the welding control mode 421 so that mode switching is performed.

In particular, the voltage and current can be automatically switched by the mode control unit 400 of the present invention, and the pulse current and the pulse frequency can be arbitrarily adjusted.

In the MAG welding machine in which the CO ₂ and the AR gas are mixed, the portion receiving the welding signal of the wire feed line of the common feed portion 422 of the CN 6 terminal of the arc welding control panel 420 is the same as CO ₂ , 420 is also configured in such a way that the driving time is changed so that the CO ₂ and Ar gas valves operate together.

Therefore, the second transistor 320 connected to the CN4 and CN5 terminals of the arc welding control panel 420 recognizes and adjusts only the crater current voltage among the variable resistors, makes the other arc arc not recognized, recognizes only the spot mode, And the arc generation time is changed to the voltage volume.

In addition, the TIG welding machine switches the rotary switch of the CN 8 terminal of the resistance welding control plate 410. At this time, the welding machine signal of the wire feeder line connected to the CN6 terminal of the arc welding control panel 420 is cut off, and the welding machine output such as the CN7 of the resistance welding control plate 410 is activated

Here, only the Ar gas valve connected to the CN1 terminal of the resistance welding control plate 410 is operated during welding start and welding after gas checking.

Therefore, the CN10 terminal of the resistance welding control plate 410 becomes a variable front end for adjusting the main welding current crater current.

The variable resistor connected to the CN 8 terminal and the CN 10 terminal of the resistance welding control plate 410 is recognized as a pulse current, a crater current, a main current, and an initial current and adjusted.

The rotary switch connected to the CN8 terminal of the resistance welding control plate 410 recognizes the welding mode, the repeat mode, the spot mode, and the arc mode. In the spot mode, the arc generation time can be changed to the voltage value of the CN 8 terminal .

This invention is a switching power control of the welding machine, a high-frequency control, the feed motor control, via a gas valve control, welding control mode CO _2, It can supply various current to welder in order to perform various welding with one welder by integrating MMA (Manual Metal Arc), TIG (tungsten inert gas), MIG (Metal Inert Gas) and MAG By providing an integrated control system that integrates CO ₂ , MMA, TIG, MIG and MAG welders, it is possible to efficiently reduce the welding work and energy, and it is possible to perform various welding methods with a single welder In addition to high quality welding and energy saving, it is an invention that can increase labor cost, material saving, weight reduction and production speed as well as increase sales by adjusting welding condition, parameter adjustment, productivity, process improvement etc. .

The foregoing description is merely illustrative of the technical idea of the present invention and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas falling within the scope of the same shall be construed as falling within the scope of the present invention.

100: power supply unit 102: input power supply
106: Transformer 110: AC converter
120: Power input terminal 130: Inverter section
140: Power supply unit 200: Output unit
210: Rectifier 220: Reactor
230: Output terminal 232: + polarity output terminal
234: - pole output terminal 240: high frequency generating device
300: switch unit 400: mode control unit
410: Resistance welding control panel 412: TIG welding mode
414: ARC welding mode 420: arc welding control panel
421: CO ₂ welding mode 423: MIG welding mode
425: MAG welding mode

Claims (5)

In a hybrid multifunctional welder,
A power supply unit including an input power source, a power input terminal, an inverter unit, and a power supply unit for converting the AC voltage into a DC voltage using a normal commercial power supply and supplying the converted DC voltage,
A transformer for dropping a DC voltage input from the power supply unit;
When supplied with a DC voltage drop from the transformer CO _2, A positive output terminal connected to the rectifier and the reactor for outputting a current for performing a manual metal arc (MMA), a tungsten inert gas (MIG), a metal inert gas (MIG) An output section including an output terminal composed of a CO ₂ output terminal and a TIG output terminal connected to a high frequency generator for high frequency control;
380V, and 440V according to the required power by switching the power source inputted to the power source unit; And
A desired welding mode is selected through a resistance welding control panel which is switched to the TIG welding mode or the ARC welding mode by the on / off method of the switch unit and an arc welding control panel which is switched to the CO ₂ welding mode, the MIG welding mode, And a mode control unit for controlling the operation of the control unit,
The power unit converts an AC voltage from an input power source to a DC voltage and stores the DC voltage in a battery. The converted DC voltage is input to an inverter unit using an insulated gate bipolar transistor (IGBT) through a power input terminal, Is converted into an AC voltage through a high frequency control and input to a transformer to lower the voltage, and then supplied to an output unit.
delete The method according to claim 1,
Wherein the power input terminal is a safety protection diode for preventing a reversed voltage that may occur when the switch unit is turned off, in case the polarity of the power source is changed.
The method according to claim 1,
When the switch unit selects the TIG mode using the switch SW1, the CR1 is turned off to connect the switching signal to the resistance welding control board on the drive board, CR1 to the resistance welding control board to the TIG torch switch, Wherein the CO ₂ mode torch switch is cut off through the welding portion.
The method according to claim 1,
Characterized in that the resistance welding control panel comprises a high frequency control module for TIG welding and ARC welding.

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