KR101042419B1 - Gas welding equipment equipped with automatic opening and closing feature - Google Patents

Abstract

PURPOSE: A gas welding apparatus having an automatic opening/closing function is provided to prevent the leakage of fuel and oxygen gas in spite of damage or cut of gas hoses. CONSTITUTION: A gas welding apparatus having an automatic opening/closing function comprises a fuel gas distributor(10), an oxygen gas distributor(20), a torch(30), a fuel gas hose(40), an oxygen gas hose(50), a first solenoid valve(60), and a solenoid valve(70). The fuel gas distributor delivers fuel gas from a fuel gas source(110) to a plurality of fuel gas vents(130). The oxygen gas distributor delivers oxygen gas from an oxygen gas source(210) to a plurality of oxygen gas vents(230). The torch comprises a fuel gas inlet port(310) and an oxygen gas inlet port(330) which is electrically connected to the fuel gas inlet port. The fuel gas hose comprises a connector of a conductive material on one end connected to the fuel gas inlet port and is connected to the fuel gas vent of the fuel gas distributor on the other end. The oxygen gas hose comprises a connector of a conductive material on one end connected to the oxygen gas inlet port and is connected to the oxygen gas vent of the oxygen gas distributor on the other end. The first solenoid valve opens and closes the fuel gas vent of the fuel gas distributor and the flow path of the fuel gas hose. The second solenoid valve opens and closes the oxygen gas vent of the oxygen gas distributor and the flow path of the oxygen gas hose.

Description

GAS WELDING EQUIPMENT EQUIPPED WITH AUTOMATIC OPENING AND CLOSING FEATURE}

According to the present invention, when a torch is coupled to and electrically connected to a gas welding device, the power supply of the power supply unit may be supplied to the first solenoid valve and the second solenoid valve, and the valve may be opened. The present invention relates to a gas welding device having an automatic opening / closing function so that the valve is closed because power is not supplied to the first and second solenoid valves.

In the conventional gas welding apparatus, as shown in FIG. 1, a fuel gas distributor receives gas fuel from a gas fuel supply source, is supplied to a torch through a fuel gas hose, and an oxygen gas distributor receives oxygen gas from an oxygen gas source to supply oxygen gas. The torch is fed through a hose.

However, since the actual extension length of the fuel gas hose and the oxygen gas hose of the gas welding device is so long as to reach 100m or more, the fuel gas hose and the oxygen gas hose are damaged as well as the fuel gas and the oxygen gas due to the external force. Leakage concerns are also very high.

In addition, a coupler is provided at the ends of the fuel gas hose and the oxygen gas hose for connecting to the torch, and for ease of use, a coupler is automatically closed when the torch is separated. When the worker finishes the welding operation, the torch is separated from the fuel gas hose and the oxygen gas hose and stored separately. In this case, the fuel gas hose and the oxygen gas hose are left in a state filled with fuel gas and oxygen. In this state, when a part of the fuel gas hose and the oxygen gas hose is damaged or cut, the fuel gas and the oxygen gas leak.

A part of the fuel gas hose and the oxygen gas hose is damaged or cut, and there is a problem that a human accident may occur, such as an explosion or suffocation due to a spark, a cigarette fire, etc. in a state where the fuel gas and the oxygen gas are leaked.

The present invention has been made to solve the above problems, when the torch is coupled to the gas welding device electrically connected to the first solenoid valve and the second solenoid valve can be supplied with the power supply of the power supply to open the valve, If the torch is disconnected and not electrically connected, the power is not supplied to the first and second solenoid valves so that the valve is closed, so that fuel gas and oxygen gas do not leak even if the fuel gas hose and the oxygen gas hose are damaged or cut. It is an object of the present invention to provide a gas welding device equipped with an automatic opening and closing function to prevent explosions, casualties, and the like.

The present invention for achieving the above object is a fuel gas distributor for receiving the fuel gas from the fuel gas supply source to discharge to a plurality of fuel gas outlets; An oxygen gas distributor configured to receive oxygen gas from an oxygen gas supply source and discharge the oxygen gas to a plurality of oxygen gas outlets; A torch having a fuel gas inlet and an oxygen gas inlet electrically connected to the fuel gas inlet; A fuel gas hose having the other end coupled to the fuel gas outlet of the fuel gas distributor, and having one end connected to a fuel gas inlet of the torch; An oxygen gas hose having a second end coupled to an oxygen gas outlet of the oxygen gas distributor, and having one end connected to a oxygen gas inlet of the torch; A first solenoid valve for opening and closing a fuel gas discharge port of the fuel gas distributor and a flow path of the fuel gas hose; A second solenoid valve for opening and closing an oxygen gas outlet of the oxygen gas distributor and a flow path of the oxygen gas hose; The first solenoid valve when the fuel gas inlet and the oxygen gas inlet of the torch are coupled to the connector of the fuel gas hose and the connector of the oxygen gas hose so that the connector of the fuel gas hose and the connector of the oxygen gas hose are electrically connected. And opening and supplying power to the second solenoid valve, and when the fuel gas inlet and the oxygen gas inlet of the torch are separated from the connection of the fuel gas hose and the connection of the oxygen gas hose, the first solenoid valve and the second solenoid valve. It provides a gas welding device comprising a; power supply for shutting off and closing the power.

The first solenoid valve may be provided between the fuel gas outlet of the fuel gas distributor and the fuel gas hose, and the second solenoid valve may be provided between the oxygen gas outlet of the oxygen gas distributor and the oxygen gas hose. desirable.

In addition, the first solenoid valve and the second solenoid valve is preferably a normally closed solenoid valve.

Furthermore, a first branch pipe provided between the first solenoid valve and the fuel gas hose, a third solenoid valve provided in the first branch pipe to open and close the first branch pipe, and the second solenoid valve A second branch pipe provided between the oxygen gas hose and a fourth solenoid valve provided in the second branch pipe to open and close the second branch pipe, and the power supply unit has a fuel gas inlet port and oxygen of the torch; When the inlet is coupled to the connector of the fuel gas hose and the connector of the oxygen gas hose, the third solenoid valve and the fourth solenoid valve are closed, and the fuel gas inlet and the oxygen gas inlet of the torch are connected to the fuel gas hose. And opening the third solenoid valve and the fourth solenoid valve when the oxygen gas hose is disconnected from the connector. It is good.

In addition, the third solenoid valve and the fourth solenoid valve is preferably a normally open solenoid valve.

In addition, the first wire for electrically connecting any one pole of the power supply unit and the connection of the fuel gas hose, the first connection of the connection port of the oxygen gas hose and the input terminal of any one of the first and second solenoid valve Two wires are provided, and the other one pole of the power supply unit is preferably connected to the input terminal of the other one pole of the first and second solenoid valves.

The first electric wire and the second electric wire are preferably provided in the flow path of the fuel gas hose and the oxygen gas hose, respectively.

In addition, the fuel gas hose and the oxygen gas hose comprises an outer tube formed in the state wrapped around the inner peripheral surface and the inner tube, the first wire and the second wire is the fuel gas hose and the oxygen gas hose It is preferable that each is provided between the inner tube and the external appearance of the.

Further, a first wire for electrically connecting any one pole of the power supply unit and the connection port of the oxygen gas hose, and the first connection port connecting the connection port of the fuel gas hose and the input terminal of any one pole of the first and second solenoid valves. Two wires are provided, and the other one pole of the power supply unit is preferably connected to the input terminal of the other one pole of the first and second solenoid valves.

In addition, the first wire and the second wire is preferably provided in the flow path of the oxygen gas hose and the fuel gas hose, respectively.

Further, the oxygen gas hose and the fuel gas hose comprises an outer tube and the outer circumferential surface of the inner tube is formed to include a state, wherein the first wire and the second wire is the oxygen gas hose and the fuel gas hose It is preferable that each is provided between the inner tube and the external appearance of the.

In addition, the first solenoid valve and the second solenoid valve is provided with a relay to control the power supply of the power supply unit, the fuel gas inlet and oxygen gas inlet of the torch is connected to the fuel gas hose and the oxygen gas hose The transistor is coupled to the connector of the fuel gas hose and the connection of the oxygen gas hose is energized so that the transistor is turned on when the control voltage is sensed.

In particular, a control voltage is applied to the connection port of the fuel gas hose or the connection port of the oxygen gas hose, and the fuel gas inlet port and the oxygen gas inlet port of the torch are connected to the fuel gas hose port and the oxygen gas hose at the base of the transistor. It is coupled to the connector is supplied with a control voltage applied by energizing the connector of the fuel gas hose and the connector of the oxygen gas hose, the negative voltage of the power supply is applied to the emitter, the collector is connected to the relay coil of the relay It is preferable to be.

According to the present invention, when a torch is coupled to and electrically connected to a gas welding device, the power supply of the power supply unit may be supplied to the first solenoid valve and the second solenoid valve, and the valve may be opened. Since the valve is closed because no power is supplied to the first and second solenoid valves, the fuel gas and the oxygen gas do not leak even if the fuel gas hose and the oxygen gas hose are damaged or cut, thereby preventing fire, explosion, and personal injury. It works.

Since the first and second solenoid valves are provided between the fuel gas outlet and the oxygen gas outlet, and the fuel gas hose and the oxygen gas hose, from the fuel gas outlet and the oxygen gas outlet to the fuel gas hose and the oxygen gas hose. There is an effect that can more easily control the discharge of the fuel gas and oxygen gas discharged.

In addition, since the first and second solenoid valves are normally closed valves, when the torch is separated from the fuel gas hose and the oxygen gas hose, the first and second solenoid valves are closed to discharge the fuel gas outlet and the oxygen gas outlet. There is an effect that can prevent the fuel gas and oxygen gas is discharged.

Furthermore, since the third and fourth solenoid valves are provided in the fuel gas hose and the oxygen gas hose, when the torch is separated from the fuel gas hose and the oxygen gas hose, the third and fourth solenoid valves are opened to open the fuel gas hose. And it is possible to discharge the fuel gas and oxygen gas remaining in the oxygen gas hose to the outside to prevent the fire, explosion, human life, etc., which may occur due to leakage of the fuel gas in the workplace indoors have.

In addition, since the power supply of the power supply is connected to the first wire, the second wire and the input terminals of the first and second solenoid valves, the power supply of the power supply can be more easily supplied to the first and second solenoid valves. It works.

In addition, since the first wire and the second wire are respectively provided in the flow paths of the fuel gas hose and the oxygen gas hose, not only can the wires which are complicatedly wired in the workplace be arranged neatly, but in particular, the first There is an advantage that the electric wire and the second electric wire do not have to be cut.

In addition, since the first electric wire and the second electric wire are respectively provided between the inner pipe and the external pipe of the fuel gas hose and the oxygen gas hose, not only can the wires which are complicatedly wired in the workplace be arranged more easily and in particular, The first and second electric wires are more likely to be cut by external force or the like.

Since the power supply of the power supply unit is connected to the relay and the transistor, the power supply of the power supply unit is supplied to the first and second solenoid valves even when a voltage drop or a voltage loss occurs in the first and second wires having a long extension. There is an effect that can be supplied and opened.

Furthermore, since the power supply of the power supply unit is supplied to the relay and the transistor and supplied to the first solenoid valve, the second solenoid valve, the third solenoid valve, and the fourth solenoid valve, the voltage drop is applied to the first and second wires having a long extension length. Even if a voltage loss occurs, power is supplied to the first, second, third, and fourth solenoid valves, thereby opening and closing the valve.

1 is a configuration diagram schematically showing a gas welding apparatus according to the prior art,
2 is a configuration diagram schematically showing a gas welding apparatus equipped with an automatic opening and closing function according to the first embodiment of the present invention,
3 is a configuration diagram schematically showing that the torch is separated from the gas welding apparatus according to the first embodiment of the present invention;
4 is a block diagram schematically showing a second embodiment of the present invention,
5 is a block diagram schematically showing a third embodiment of the present invention,
6 and 7 are cross-sectional views of A-A first and second embodiments of FIG. 5,
8 is a perspective view schematically illustrating a state in which wires are connected to first and second solenoid valves;
9 is a cross-sectional view taken along the line BB of FIG. 8,
10 is a configuration diagram schematically showing a fourth embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Of course, the scope of the present invention is not limited to the following examples, and various modifications can be made by those skilled in the art without departing from the technical gist of the present invention.

Figure 2 is a schematic view showing a gas welding device with an automatic opening and closing function of the first embodiment of the present invention, Figure 3 is a schematic view showing that the torch 30 is separated from the gas welding device of the first embodiment of the present invention. It is a block diagram shown.

According to the present invention, the gas welding apparatus with the automatic opening and closing function according to the first embodiment has a fuel gas distributor 10, an oxygen gas distributor 20, a torch 30, a fuel gas hose 40, Oxygen gas hose 50, the first solenoid valve 60, the second solenoid valve 70 and the power supply unit 80 is made.

First, the fuel gas distributor 10 receives fuel gas from a fuel gas supply source 110 such as a fuel gas tank and discharges the fuel gas to the plurality of fuel gas outlets 130.

The fuel gas may be made of acetylene, LPG, LNG, argon gas and the like.

The oxygen gas distributor 20 receives oxygen gas from an oxygen gas supply source 210 such as an oxygen tank and discharges the oxygen gas to the plurality of oxygen gas outlets 230.

The torch 30 includes a fuel gas inlet 310 and an oxygen gas inlet 330.

The fuel gas inlet 310 and the oxygen gas inlet 330 are formed of a conductor having a large conductivity of a metal material so as to be electrically connected.

The torch 30, the fuel gas inlet 310, and the oxygen inlet 330 are entirely or partially made of a conductive material.

The other end of the fuel gas hose 40 is coupled to the fuel gas outlet 130 of the fuel gas distributor 10. One end of the fuel gas hose 40 is provided with a connector 410 of a conductive material coupled to the fuel gas inlet 310 of the torch 30.

The other end of the oxygen gas hose 50 is coupled to the oxygen gas outlet 130 of the oxygen gas distributor 10. One end of the oxygen gas hose 50 is provided with a connector 510 of a conductive material coupled to the oxygen gas inlet of the torch 30.

The fuel gas hose 40 and the oxygen gas hose 50 may be made of a rubber tube or the like.

The connector 410, 510 of the fuel gas hose 40 and the oxygen gas hose 50 is made of a conductive material in whole or in part.

The connection ports 410 and 510 of the fuel gas hose 40 and the oxygen gas hose 50 may be made of a coupling of a conductive material.

When the connector 410, 510 of the fuel gas hose 40 and the oxygen gas hose 50 is coupled to the fuel gas inlet 310 and the oxygen gas inlet 330 of the torch 30, the connector 410, 510 is opened to discharge the fuel gas and oxygen gas flowed through the fuel gas hose 40 and the oxygen gas hose 50 to the fuel gas inlet 310 and the oxygen gas inlet 330 of the torch 30. It is preferable that it consists of a coupling comprised so that.

The first solenoid valve 60 opens and closes a flow path of the fuel gas outlet 130 of the fuel gas distributor 10 and the fuel gas hose 40.

As shown in FIG. 2, the first solenoid valve 60 may be provided between the fuel gas outlet 130 of the fuel gas distributor 10 and the other end of the fuel gas hose 40, but is not limited thereto. Of course, it can be provided in a variety of locations.

The second solenoid valve 70 opens and closes the flow path of the oxygen gas outlet 230 of the oxygen gas distributor 20 and the oxygen gas hose 50.

The second solenoid valve 70 may be provided between the oxygen gas outlet 230 of the oxygen gas distributor 20 and the other end of the oxygen gas hose 50, but is not necessarily limited thereto. Of course it can be provided in position.

The first solenoid valve 60 and the second solenoid valve 70 are provided between the fuel gas outlet 130 and the oxygen gas outlet 230 and the fuel gas hose 40 and the oxygen gas hose 50. Therefore, the fuel gas discharge port 130 and the oxygen gas discharge port 230 can be more easily controlled to discharge the fuel gas and oxygen gas discharged to the fuel gas hose 40 and the oxygen gas hose 50. This will be.

 The first solenoid valve 60 and the second solenoid valve 70 may be formed of a normally closed solenoid valve.

Since the first solenoid valve 60 and the second solenoid valve 70 are normally closed valves, the torch 30 is separated from the fuel gas hose 40 and the oxygen gas hose 50. The solenoid valve 60 and the second solenoid valve 70 are closed to prevent the fuel gas and the oxygen gas from being discharged from the fuel gas outlet 130 and the oxygen gas outlet 230.

As shown in FIG. 2, the power supply 80 has a fuel gas inlet 310 and an oxygen gas inlet 330 of the torch 30 connected to the connector 410 and the oxygen gas hose of the fuel gas hose 40. The first solenoid valve 60 is coupled to the connector 510 of the fuel cell hose 50 when the connector 410 of the fuel gas hose 40 and the connector 510 of the oxygen gas hose 50 are electrically connected to each other. Power is supplied to the second solenoid valve 70 to be opened.

On the contrary, as shown in FIG. 3, the power supply unit 80 has the fuel gas inlet 310 and the oxygen gas inlet 330 of the torch 30 connected to the connector 410 and the oxygen of the fuel gas hose 40. When disconnected to the connector 510 of the gas hose 50, the first solenoid valve 60 and the second solenoid valve 70 is shut off by closing the power.

Two electrodes of the power supply unit 80 may be connected to an input terminal of one pole of the first electric wire 810, the second electric wire 830, the first solenoid valve 60 and the second solenoid valve 70. .

The first wire 810 may electrically connect the one end of the power supply unit 80 and the connector 410 of the fuel gas hose 40.

The second wire 830 may connect the connection port 510 of the oxygen gas hose 50 and the input terminal of one pole of the first and second solenoid valves 60 and 70.

An electric wire 850 may be connected to the other one pole of the power supply unit 80 to an input terminal of the other one pole of the first solenoid valve 60 and the second solenoid valve 70.

On the contrary, the first wire 810 may electrically connect the one end of the power supply unit 80 and the connector 510 of the oxygen gas hose 50.

The second wire 830 may connect the connector 410 of the fuel gas hose 40 and the input terminal of one pole of the first and second solenoid valves 60 and 70.

An electric wire 850 may be connected to the other one pole of the power supply unit 80 to an input terminal of the other one pole of the first and second solenoid valves 60 and 70.

Since the electric wire of the power supply unit 80 is connected to the first electric wire 810, the second electric wire 830 and the input terminals of the first and second solenoid valves, the electric power of the electric power supply 80 There is an advantage that can be more easily supplied to the first solenoid valve 60 and the second solenoid valve 70.

As shown in FIG. 2, when the torch 30 is connected to the hoses 40 and 50, the anode (+) of the power supply unit 80 is energized to the first electric wire 810 so that the fuel gas hose 40 The connector 410 is energized.

In addition, the power supplied to the connector 410 is supplied to the second wire 830 connected to the connector 510 of the oxygen gas hose 50 through the torch 30.

In addition, the power supplied to the second electric wire is energized to the positive electrode (+) of the first and second solenoid valves 60 and 70, respectively.

Furthermore, the negative electrode (−) of the power supply unit 80 is energized to the negative electrodes of the first and second solenoid valves 60 and 70 through the wire 850, respectively.

As a result, since the power of the power supply unit 80 is supplied to the first and second solenoid valves 60 and 70, the valve is opened and fuel gas and oxygen gas flow into the hoses 40 and 50.

The fuel gas inlet 310 and the oxygen gas inlet 330 of the torch 30 are electrically coupled to the connector 410 of the fuel gas hose 40 and the connector 510 of the oxygen gas hose 50. When connected, since the power of the power supply unit 80 is supplied to the first solenoid valve 60 and the second solenoid valve 70, the first solenoid valve 60 and the second solenoid valve 70 are opened. Not only to supply fuel gas and oxygen gas to the fuel gas hose 40 and the oxygen gas hose 50, but also to the fuel gas inlet 310 and the oxygen gas inlet 330 of the torch 30. If it is not electrically connected to the connector 410 of the fuel gas hose 40 and the connector 510 of the oxygen gas hose 50 to the first solenoid valve 60 and the second solenoid valve 70 Since the power of the power supply unit 80 is not supplied, the first sole Since the fuel valve 60 and the second solenoid valve 70 are closed, the fuel gas hose 40 and the oxygen cannot be supplied to the fuel gas hose 40 and the oxygen gas hose 50. When the gas hose 50 is cut by an external force or the like, or when the torch 30 is separated, a large fire accident, an explosion accident, and a life accident that may occur due to leakage of fuel gas may be prevented in advance.

The fuel gas distributor 10, the fuel gas supply source 110, the oxygen gas distributor 20, the oxygen gas supply source 210, the first solenoid valve 60, the second solenoid valve 70, and the power supply unit 80. Is provided in the workplace outdoors and the torch 30, the fuel gas hose 40 and the oxygen gas hose 50 is preferably provided in the workplace indoors.

4 is a block diagram schematically showing a second embodiment of the present invention.

As shown in FIG. 4, the gas welding device having the automatic opening and closing function according to the second embodiment of the present invention has the same fuel gas distributor 10, oxygen gas distributor 20, torch 30, and fuel as in the first embodiment. It comprises a gas hose 40, oxygen gas hose 50, the first solenoid valve 60, the second solenoid valve 70 and the power supply unit 80.

As shown in FIG. 3, the first solenoid valve 60 and the second solenoid valve 70 of the second embodiment include the first branch pipe 610, the third solenoid valve 630, and the second branch pipe 710. The fourth solenoid valve 730 may be formed.

The first branch pipe 610 may be provided between the first solenoid valve 60 and the fuel gas hose 40.

The third solenoid valve 630 may be provided in the first branch pipe 610 to open and close the first branch pipe 610.

The second branch pipe 710 may be provided between the second solenoid valve 70 and the oxygen gas hose 50.

The fourth solenoid valve 730 may be provided in the second branch pipe 710 to open and close the second branch pipe 710.

The third solenoid valve 630 and the fourth solenoid valve 730 may be formed of a normally open solenoid valve.

As shown in FIG. 4, the power supply unit 80 has a fuel gas inlet 310 and an oxygen gas inlet 330 of the torch 30 connected to the connector 410 and the oxygen gas hose of the fuel gas hose 40. When coupled to the connector 510 of the 50, the third solenoid valve 630 and the fourth solenoid valve 730 may be closed.

On the contrary, the power supply unit 80 has a fuel gas inlet 310 and an oxygen gas inlet 330 of the torch 30 connected to the connector 410 and the oxygen gas hose 50 of the fuel gas hose 40. When separated to 510, the third solenoid valve 630 and the fourth solenoid valve 730 may be opened.

Since the third solenoid valve 630 and the fourth solenoid valve 730 are provided in the fuel gas hose 40 and the oxygen gas hose 50, the torch 30 is connected to the fuel gas hose 40 and When separated from the oxygen gas hose 50, the third solenoid valve 630 and the fourth solenoid valve 730 is opened to the fuel gas present in the fuel gas hose 40 and the oxygen gas hose 50 And since the oxygen gas can be discharged to the outdoors there is an advantage that can prevent in advance the fire, explosion, human life and the like that the fuel gas can be leaked to the interior of the workplace.

Fig. 5 is a schematic view showing a third embodiment of the present invention, Figs. 6 and 7 are cross-sectional views of A-A first and second embodiments of Fig. 5, and Fig. 8 is a first and second solenoid valves. It is a perspective view which shows schematically the state in which the wire was connected to 60 and 70, and FIG. 9 is sectional drawing of B-B of FIG.

As shown in FIG. 5, the gas welding apparatus with the automatic opening and closing function according to the third embodiment of the present invention has the same fuel gas distributor 10, oxygen gas distributor 20, torch 30, and fuel as in the first embodiment. It comprises a gas hose 40, oxygen gas hose 50, the first solenoid valve 60, the second solenoid valve 70 and the power supply unit 80.

The power supply unit 80 of the third embodiment may include a transistor TR and a relay RY.

The relay RY may interrupt the power supply of the power supply unit 80 to the first solenoid valve 60 and the second solenoid valve 70.

The transistor TR has a fuel gas inlet 310 and an oxygen gas inlet 330 of the torch 30 connected to a connector 410 of the fuel gas hose 40 and a connector 510 of the oxygen gas hose 50. When the connector 410 of the fuel gas hose 40 and the connector 510 of the oxygen gas hose 50 are energized to detect the control voltage, the contact point of the relay RY may be turned on.

The transistor TR may include a base B, an emitter E, and a collector C.

In the base B, the fuel gas inlet 310 and the oxygen gas inlet 330 of the torch 30 are connected to the connector 410 of the fuel gas hose 40 and the connector 510 of the oxygen gas hose 50. A control voltage applied to the connector 410 of the fuel gas hose 40 and the connector 510 of the oxygen gas hose 50 is energized.

The cathode voltage of the power supply unit 80 may be applied to the emitter E.

The collector C may be connected to a relay RY coil of the relay RY.

As shown in FIG. 5, when the torch 30 is connected to the connectors 410 and 510 of the hoses 40 and 50, the positive electrode 12V of the power supply 80 is the first wire (see FIG. 6). 810 is supplied to the connector 410 of the fuel gas hose (40).

In addition, the power supplied to the connector 410 is supplied to the second electric wire 830 of FIG. 6 connected to the connector 510 of the oxygen gas hose 50 through the torch 30.

In addition, the power supplied to the second wire 830 of FIG. 6 is energized to the base B of the transistor TR so that the base B is operated.

The negative (−) power of the power supply unit 80 is energized to the negative (−) of the first and second solenoid valves 60 and 70.

However, due to the operation of the base B, a part of the cathode (−) power of the power supply unit (−) is supplied toward the collector C from the emitter E of the transistor TR and the relay RY The coil is energized to turn on the contact of the relay RY.

As a result, the positive electrode 24V of the power supply unit 80 passes through the contact of the relay RY and is energized to the positive electrode of the first and second solenoid valves 60 and 70, respectively.

The first and second solenoid valves 60 and 70 are energized to the first and second solenoid valves 60 and 70, respectively, so that the first and second solenoid valves 60 and 70 are opened to supply the fuel gas and the oxygen gas. Drain it.

Since the power of the power supply unit 80 is connected to the relay RY and the transistor TR, the voltage drop in the first wire (810 of FIG. 6) and the second wire (830 of FIG. 6) having a long extension length Even when a voltage loss occurs, power of the power supply unit 80 is supplied to the first solenoid valve 60 and the second solenoid valve 70 to be opened.

As shown in FIG. 5, when the positive (+) 12V of the power supply unit 80 is energized by the first wire 810 and the second wire 810, the first wire 810 and the second wire 830. 6 and 7 may be provided in the fuel gas hose 40 and the oxygen gas hose 50.

As shown in FIG. 6, the first wire 810 and the second wire 830 may be provided in the flow path of the fuel gas hose 40 and the oxygen gas hose 50, respectively.

In addition, the first wire 810 and the second wire 830 may be provided in the flow path of the oxygen gas hose 50 and the fuel gas hose 40, respectively.

The first electric wire 810 and the second electric wire 830 are provided in the flow path of the fuel gas hose 40 and the oxygen gas hose 50 or the oxygen gas hose 50 and the fuel gas hose 40, respectively. Therefore, not only the wires that are complicatedly wired in the workplace can be arranged neatly, but also, there is an advantage in that the first wire 810 and the second wire 830 may not be cut by the external force.

As shown in FIG. 7, the fuel gas hose 40 and the oxygen gas hose 50 may include an inner tube 450 and 550, an exterior 470 and 570, and wires 810 and 830.

The inner pipes 450 and 550 of the fuel gas hose 40 and the oxygen gas hose 50 are located at the inner circumferential centers of the fuel gas hose 40 and the oxygen gas hose 50. And it may be provided to extend a predetermined length in the longitudinal direction, that is, the left and right direction of the oxygen gas hose (50).

Preferably, the fuel gas and the oxygen gas flow through the inner pipes 450 and 550 of the fuel gas hose 40 and the oxygen gas hose 50.

Appearances 470 and 570 of the fuel gas hose 40 and the oxygen gas hose 50 may be formed to surround the inner pipes 450 and 550 of the fuel gas hose and the oxygen gas hose 50. .

The first electric wire 810 and the second electric wire 830 may be provided between the inner pipes 450 and 550 of the fuel gas hose 40 and the oxygen gas hose 50 and the exteriors 470 and 570. .

The first electric wire 810 and the second electric wire 830 may be provided to surround the outer circumferential surfaces of the inner pipes 450 and 550 of the fuel gas hose 40 and the oxygen gas hose 50.

In addition, the first electric wire 810 and the second electric wire 830 may be provided to surround the outer circumferential surfaces of the inner tubes 450 and 550 of the oxygen gas hose 50 and the fuel gas hose 40.

The first wire 810 and the second wire 830 is provided between the inner pipe (450, 550) and the exterior (470, 570) of the fuel gas hose 40 and oxygen gas hose 50, respectively, the workplace Not only can the wires that are complicatedly wired within the wires be more easily arranged, but in particular, the first wire 810 and the second wire 830 may be cut off by an external force.

As shown in FIG. 8, the wire connected to the positive electrode 12V of the power supply unit 80 and the base B of the transistor TR is connected to the first and second solenoid valves 60 and 70 made of a conductive material. 9 may be connected to the connectors 430 and 530 and may be energized through the wires 810 and 830 provided in the hoses 40 and 50 as shown in FIG. 9.

10 is a configuration diagram schematically showing a fourth embodiment of the present invention.

As shown in FIG. 10, the gas welding apparatus having the automatic opening and closing function according to the fourth embodiment of the present invention has the same fuel gas distributor 10, oxygen gas distributor 20, torch 30, and fuel as in the third embodiment. It comprises a gas hose 40, oxygen gas hose 50, the first solenoid valve 60, the second solenoid valve 70 and the power supply unit 80.

The first solenoid valve 60 and the second solenoid valve 70 of the fourth embodiment may include a third solenoid valve 630 and a fourth solenoid valve 730.

As shown in FIG. 10, the negative electrode (−) power of the power supply unit 80 is supplied to the negative electrode (−) of the first, second, third, and fourth solenoid valves 60, 70, 730, and 730, and the power A positive supply (24) of the supply portion is supplied to the positive (+) of the first, second, third, fourth solenoid valves (60, 70, 730, 730) so that the torch (30) to the hose (40, 50) When connected, the valves 60, 70, 630, and 730 may be opened and closed.

The power of the power supply unit 80 is energized to the relay RY and the transistor TR so that the first solenoid valve 60, the second solenoid valve 70, the third solenoid valve 630 and the fourth solenoid The first, second, third, and fourth solenoid valves 60, 630, and 70 are supplied to the valve 730 even when voltage drops or voltage losses occur in the first and second wires 810 and 830 having a long extension. , 730, the power of the power supply unit 80 is supplied, so that the valves 60, 630, 70, 730 can be opened and closed.

According to the present invention configured as described above, when the torch 30 is coupled to and electrically connected to a gas welding device, the power supply of the power supply unit 80 is supplied to the first solenoid valve 60 and the second solenoid valve 70. The valves 60 and 70 may be opened to open, and when the torch 30 is not separated and electrically connected, the first and second solenoid valves 60 and 70 are not supplied with power, thereby providing the valves 60 and 70. By closing the fuel gas hose (40) and oxygen gas hose (50) is damaged or cut the fuel gas and oxygen gas does not leak, there is an advantage that can prevent a fire, explosion, human life and the like.

10; Fuel gas distributor, 110; Fuel gas source,
130; A plurality of fuel gas outlets 20; Oxygen gas distributor,
210; Oxygen gas source, 230; A plurality of oxygen gas outlets,
30; Torch, 310; Fuel Gas Inlet,
330; Oxygen gas inlet, 40; Fuel Gas Hose,
410, 430; Connector, 450; shell,
470; Appearance, 50; Oxygen Gas Hose,
510, 530; Connector, 550; shell,
570; Exterior; 60; First solenoid valve,
610; First branch 630; Third solenoid valve,
70; A second solenoid valve 710; 2nd branch pipe,
730; A fourth solenoid valve, 80; Power Supply,
810; First wire, 830; Second electric wire,
850; Wire, RY; relay,
TR; Transistor B; Base,
C; Collector, E; Emitter.

Claims (13)

A fuel gas distributor configured to receive fuel gas from a fuel gas supply source and discharge the fuel gas to a plurality of fuel gas discharge ports;
An oxygen gas distributor configured to receive oxygen gas from an oxygen gas supply source and discharge the oxygen gas to a plurality of oxygen gas outlets;
A torch having a fuel gas inlet and an oxygen gas inlet electrically connected to the fuel gas inlet;
A fuel gas hose having the other end coupled to the fuel gas outlet of the fuel gas distributor, and having one end connected to a fuel gas inlet of the torch;
An oxygen gas hose having a second end coupled to an oxygen gas outlet of the oxygen gas distributor, and having one end connected to a oxygen gas inlet of the torch;
A first solenoid valve for opening and closing a fuel gas discharge port of the fuel gas distributor and a flow path of the fuel gas hose;
A second solenoid valve for opening and closing an oxygen gas outlet of the oxygen gas distributor and a flow path of the oxygen gas hose;
The first solenoid valve when the fuel gas inlet and the oxygen gas inlet of the torch are coupled to the connector of the fuel gas hose and the connector of the oxygen gas hose so that the connector of the fuel gas hose and the connector of the oxygen gas hose are electrically connected. And opening and supplying power to the second solenoid valve, and when the fuel gas inlet and the oxygen gas inlet of the torch are separated from the connection of the fuel gas hose and the connection of the oxygen gas hose, the first solenoid valve and the second solenoid valve. Gas supply apparatus with an automatic opening and closing function comprising a; power supply unit for shutting off and closing the power.
The method of claim 1,
The first solenoid valve is provided between the fuel gas outlet of the fuel gas distributor and the fuel gas hose,
The second solenoid valve is a gas welding device having an automatic opening and closing function, characterized in that provided between the oxygen gas outlet of the oxygen gas distributor and the oxygen gas hose.
The method of claim 2,
And the first solenoid valve and the second solenoid valve are normally closed solenoid valves.
The method of claim 2,
A first branch pipe provided between the first solenoid valve and the fuel gas hose, a third solenoid valve provided in the first branch pipe to open and close the first branch pipe, the second solenoid valve and the oxygen A second branch pipe provided between the gas hose, and a fourth solenoid valve provided in the second branch pipe to open and close the second branch pipe,
The power supply unit closes the third solenoid valve and the fourth solenoid valve when the fuel gas inlet and the oxygen gas inlet of the torch are coupled to the connector of the fuel gas hose and the connector of the oxygen gas hose, and closes the fuel of the torch. Gas welding device having an automatic opening and closing function, characterized in that for opening the third solenoid valve and the fourth solenoid valve when the gas inlet and oxygen gas inlet are separated from the connection of the fuel gas hose and the connection of the oxygen gas hose. .
The method of claim 4, wherein
The third solenoid valve and the fourth solenoid valve is a gas welding device with an automatic opening and closing function, characterized in that the normally open solenoid valve.
The method according to any one of claims 1 to 5,
A first wire electrically connecting one of the poles of the power supply unit to the connection port of the fuel gas hose; and a second wire connecting the connection port of the oxygen gas hose and the input terminal of one pole of the first and second solenoid valves. Is provided,
And the other one pole of the power supply unit is connected to an input terminal of the other one pole of the first and second solenoid valves.
The method of claim 6,
The first wire and the second wire is a gas welding device having an automatic opening and closing function, characterized in that each provided in the flow path of the fuel gas hose and the oxygen gas hose.
The method of claim 6,
The fuel gas hose and the oxygen gas hose comprises an inner tube and an inner tube formed to surround the outer peripheral surface of the inner tube,
The first electric wire and the second electric wire is a gas welding device having an automatic opening and closing function, characterized in that provided between the inner tube and the inner tube of the fuel gas hose and the oxygen gas hose, respectively.
The method according to any one of claims 1 to 5,
A first wire electrically connecting one of the poles of the power supply unit to the connection port of the oxygen gas hose; and a second wire connecting the connection port of the fuel gas hose and the input terminal of one pole of the first and second solenoid valves. Is provided,
And the other one pole of the power supply unit is connected to an input terminal of the other one pole of the first and second solenoid valves.
10. The method of claim 9,
The first electric wire and the second electric wire is a gas welding device with an automatic opening and closing function, characterized in that each provided in the flow path of the oxygen gas hose and the fuel gas hose.
10. The method of claim 9,
The oxygen gas hose and the fuel gas hose comprises an inner tube and an inner tube formed to surround the outer peripheral surface of the inner tube,
The first electric wire and the second electric wire is a gas welding device having an automatic opening and closing function, characterized in that provided between the inner tube and the inner tube of the oxygen gas hose and the fuel gas hose, respectively.
The method according to any one of claims 1 to 5,
The first solenoid valve and the second solenoid valve is provided with a relay to control the power supply of the power supply,
When the fuel gas inlet and the oxygen gas inlet of the torch are coupled to the connector of the fuel gas hose and the connector of the oxygen gas hose, the connector of the fuel gas hose and the connector of the oxygen gas hose are energized so that the control voltage is sensed. Gas welding device with an automatic switching function, characterized in that the transistor is provided to turn on the contacts.
The method of claim 12,
A control voltage is applied to the connection port of the fuel gas hose or the connection port of the oxygen gas hose,
The fuel gas inlet and the oxygen gas inlet of the torch are coupled to the connection of the fuel gas hose and the connection of the oxygen gas hose to the base of the transistor so that the connection of the fuel gas hose and the connection of the oxygen gas hose are energized and applied. A control voltage is supplied, the emitter is applied with a negative voltage of the power supply, the collector is a gas welding device having an automatic switching function, characterized in that connected to the relay coil of the relay.

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