KR101240048B1 - Welding helmet provided auto-glare means and controlling method thereof - Google Patents

Abstract

The present invention relates to a welding helmet equipped with an automatic shading means and a control method thereof, and more particularly, to close an operator's eyes from direct light generated during welding by blocking the viewing window before starting welding and opening the viewing window after welding. It relates to a welding helmet equipped with an automatic shading means that can automatically protect and a control method thereof.
Welding helmet provided with an automatic shading means according to the present invention, the helmet body in close contact with the face of the worker and a see-through window formed on the front surface, the shading glass coupled to be elevated to the sight window of the helmet body, and one side of the helmet body Driving means for operating the light-shielding glass by forward and reverse rotation to open or cut off the see-through window, a torch switch provided in the torch connected to the welding machine body by a cable, and the driving means when the torch switch is turned off while the power is applied. It is configured to include a microcomputer for outputting a control signal to be welded to the welder body in a state that the drive window is opened, and when the switch of the torch is turned on to drive the drive means to block the viewing window.

Description

Welding helmet equipped with automatic shading means and control method thereof {WELDING HELMET PROVIDED AUTO-GLARE MEANS AND CONTROLLING METHOD THEREOF}

The present invention relates to a welding helmet equipped with an automatic shading means and a control method thereof, and more particularly, to close an operator's eyes from direct light generated during welding by blocking the viewing window before starting welding and opening the viewing window after welding. It relates to a welding helmet equipped with an automatic shading means that can automatically protect and a control method thereof.

In general, welding is a method of joining a metal material of the same type or different types to be directly bonded by applying heat and pressure locally. During welding, not only the light is emitted but also the fragments are splashed. Exposure can cause eye damage, and debris can cause injury to the eye.

Therefore, when performing the above welding work to block the strong light for the safety of the welder's eyes and various harmful substances, and to protect the worker's face from the sparks generated during welding to wear the welding helmet to perform the work.

The welding helmet according to the prior art has a security surface for protecting the operator's face from spark fragments scattered during the welding operation, a sight glass positioned within the security surface so that the worker can work while directly checking the welding portion, and the security surface on the operator's face. It is composed of wearing means to be in close contact to perform the work.

The see-through window is composed of shading glass, and before the start of welding, the see-through window is opened to determine the welding position and the relative position of the welded object and the welding rod. To protect the eyes of workers.

Conventionally, before the start of welding the shading glass to secure the field of view by flipping up from the security side and during the welding is to repeat the operation of blocking the viewing window to lower the shading glass down, which is quite cumbersome and adds to the fatigue of the arm.

In addition, conventionally, since the welding helmet is supported while being worn on the operator's head, when the operator leans or flips his head during the welding operation, the load of the welding helmet is concentrated on the operator's neck and the worker's neck is applied. There was a problem of increasing fatigue.

The present invention has been made to solve the above-mentioned problems, in the operation of the light-shielding glass, it is not provided with a separate operation switch, the lifting operation of the light-shielding glass is automatically performed by the drive of the drive means by the torch switch, convenient And it is an object to provide a welding helmet equipped with an automatic shading means that can automatically protect the eyes of the operator from direct light during welding and reduce the fatigue of the arm and its control method.

In addition, an object of the present invention is to reduce the fatigue of the worker during the work by allowing the load of the welding helmet to be distributed to the body portion of the worker by making the security surface is in close contact with the face of the worker while the lower portion of the welding helmet is supported on the body portion. The present invention provides a welding helmet equipped with automatic light shielding means and a control method thereof.

Welding helmet provided with an automatic shading means according to the present invention for achieving the above object is a helmet body in close contact with the face of the worker and a viewing window formed on the front;

Shading glass coupled to the elevating window of the helmet body;

Drive means mounted to one side of the helmet body to operate the light shielding glass by forward and reverse rotation to open or block the viewing window;

A torch switch provided in the torch connected by a cable to the welder main body; And

When the torch switch is turned off while the power is applied, the driving means is driven to open the viewing window, and when the torch switch is turned on, the driving means is driven to control the welding device to be welded to the main body of the welding machine while the viewing window is blocked. It is configured to include a microcomputer to output a signal.

In addition, the control method of the welding helmet equipped with an automatic light shielding means according to the present invention comprises the steps of determining whether the torch switch is in the ON state or the OFF state in the power-on state;

When the torch switch is in an ON state, driving the driving means to rotate in the opposite direction to cut off the viewing window by lowering the shading glass coupled to the viewing window of the helmet body;

Outputting a control signal to the welder main body by relay driving to weld through the torch;

Stopping the output of a control signal to the welder main body when the torch switch is in an OFF state to prevent welding; And

And rotating the driving means to lift the light shielding glass to open the viewing window.

According to the above-mentioned means for solving the above problem, the operation of the shading glass is automatically performed by driving the drive means by the torch switch in the operation of the shading glass. It can automatically protect worker's eyes and reduce arm fatigue.

In addition, the security surface is in close contact with the face of the worker in the state that the lower portion of the welding helmet is supported on the body portion, the load of the welding helmet is distributed to the body portion of the worker can reduce the fatigue of the worker during the operation.

1 is a side view showing a welding helmet according to an embodiment of the present invention,
Fig. 2 is a front view of Fig. 1,
3 is a perspective view of a part of the light-shielding glass shown in FIG. 2 separated from the helmet body;
4 is a control block diagram of a welding helmet according to an embodiment of the present invention;
5 is a detailed block diagram of the interface substrate shown in FIG. 4;
6 is a control flowchart of a welding helmet according to an embodiment of the present invention.

Hereinafter, the configuration and operation of the present invention will be described with reference to the accompanying drawings.

1 is a side view showing a welding helmet according to an embodiment of the present invention, Figure 2 is a front view of FIG.

As shown, the welding helmet 100 according to the embodiment of the present invention includes a wearing means 200 and an automatic light shielding means 300.

The wearing means 200 provided at the lower portion of the helmet body 110 having the see-through window 120 on the front side is fixed to the body portion of the worker 210 and the elevating portion coupled to the elevating to the fixing portion 220, and the control unit 230 is provided between the lifting unit 220 and the helmet body 110 so that the helmet body 110 is in close contact with the face of the worker by a multi-joint structure.

The fixing part 210 is connected to the fixing plate 212 and the fixing plate 212 is located in the front portion of the operator's body, so that the fixing plate 212 by tightening over the shoulder portion and side of the operator and the back portion of the worker It comprises a fixing belt 214 to be fixed to the front portion of the body.

The lifting unit 220 is a guide plate 222 which is fixed to the upper portion of the fixing plate 212 and the guide rail is formed up and down, and the lifting table coupled to the lifting and lowering along the guide rail formed on the guide plate 222 ( 224 and the adjustment bolt 226 which lifts the platform 224 and fixes the platform 224 when the platform 222 is at a predetermined position.

The control seat 230 is the first joint 232 is axially coupled to the horizontal rotation of the upper platform 226, the second shaft axially coupled to one side of the first joint 232 to rotate. The joint 234 and the third joint 236 are axially coupled to rotate left and right on the upper portion of the second joint 234.

In addition, the third joint 236 has a structure in which the lower portion of the helmet body 110 is fitted to the upper portion of the third joint 236 so that the helmet body 110 can move forward and backward.

As a result, the helmet body 110 may not only rotate horizontally, front, rear, left, and right at the upper portion of the fixing part 210, but also move up and down and back and forth.

Automatic shading means 300 for automatically elevating the shading glass to the sight glass 120 of the helmet body 110, the shading glass 310, the driving means 320, the limit sensor 330, the microcomputer 340, ventilation It comprises a fan 350.

The light shielding glass 310 is coupled to the rear of the see-through window 120 formed on the front of the helmet body 110, the drive means 320 is mounted on one side of the helmet body 110 of the microcomputer 340 The light blocking glass 310 is elevated by rotating forward and reverse by the control.

In the figure a drive motor is shown as the drive means 320.

The limit sensor 330 is composed of an upper limit limit sensor 332 positioned at an upper portion of the see-through window 120 and a lower limit limit sensor 334 positioned at a lower portion thereof, and the light shielding glass 310 contacts with rising or falling. When the signal is input to the microcomputer 340, the microcomputer 340 stops the operation of the driving means 320 when the signal is input from the upper or lower limit sensors 332 and 334 so that the light shielding glass 310 rises further. Control not to descend.

The ventilation fan 350 rotates under the control of the microcomputer 340 to suck the air in front of the helmet main body 110 and to send it to the rear of the helmet main body 110 with the head to vent the helmet main body 110 together with the ventilation. Cool.

3 is a partial perspective view of the light-shielding glass shown in Figure 2 separated from the helmet body, the driving means 320 is mounted on one side of the helmet body 110 and the roller 312 at the left and right upper and lower ends at the rear of the viewing window 120 The shading glass 310 is mounted.

The light shielding glass 310 slides up and down while being driven by being inserted into the guide rail 314, and the light shielding glass 310 has a pinion 316 mounted vertically on one side thereof with a rack 322 of the driving means 320. It has a structure to engage.

Alternatively, the light shielding glass 310 may slide up and down while being inserted into the guide rail 314, and the light shielding glass 310 may have a structure connected by the driving means 320 and a belt (not shown).

4 is a control block diagram of a welding helmet according to an embodiment of the present invention, Figure 5 is a detailed block diagram of the interface substrate shown in FIG.

As shown in FIG. 4, the welding helmet 100 according to the exemplary embodiment of the present invention further includes a torch 130, a wire feeder 140, and a welder main body 150. It further includes 360.

The welder body 150 generates a voltage so that each electrode is generated, and the torch 130 is connected to the wire feeder 140 connected to the welder body 150 by a cable 160, and at the microcomputer 340. A torch switch 132 is provided to control the lifting and lowering of the light blocking glass 310, and an electrode is installed at the discharge port.

The interface unit 360 connects the interface board 362 connected to the microcomputer 340, the torch switch 132, the wire feeder 140 (the welder main body 150) through the connectors 372, 374, and 376, respectively, and a commercial AC power source. And an SMPS 364 for converting to DC.

That is, the SMPS 364 receives the AC power, converts the voltage to a voltage having a desired size, and converts the DC power into a DC power.

The gas connection pipe 380 is connected to the connection port 378 connected to the wire feeder 140, the torch 130, and the interface substrate 362.

As shown in FIG. 5, the interface substrate 362 includes a second relay R2 and a first relay R1, and a power supply stabilization circuit 366.

The power stabilization circuit 366 receives the DC power of the SMPS 364, determines the magnitude of the DC voltage by a predetermined voltage control signal, stably outputs the DC voltage, and is connected to the power switch SW.

The second relay R2 receives stable power through the power stabilization circuit 366 and is connected to the torch 130, the microcomputer 340, and the rear end first relay R1.

The first relay R1 receives stable power through the power stabilization circuit 366 and is connected to the second relay R2, the microcomputer 340, and the welder main body 150 of the front end.

6 is a control flowchart of a welding helmet according to an embodiment of the present invention.

First, each connector 376, 374, 372 is connected to the interface board 362 to electrically connect the welder main body 150, the torch 130, and the microcomputer 340 to the interface board 362 of the interface unit 360.

Next, the fixing plate 212 of the wearing means 200 is fastened to the body of the worker by fastening the fixing belt 214 in a state of being attached to the front of the body, and elevating the lifting platform 224 of the lifting unit 220 by raising the worker's height. After fixing to tightening by adjusting bolt 226, the adjustment seat 230 is rotated and moved back and forth to wear the helmet body 110 to be in close contact with the operator's face.

In this state, when the power switch SW of the power stabilization circuit 366 is turned on (S602), when the power is normally applied, the second relay R2 operates to signal the torch switch 132 to the microcomputer 340. Is passed.

Since the second relay R2 does not operate when the power is not normally applied, the torch switch 132 is directly connected to the welder main body 150 through the cable 160 and the wire feeder 140 to weld the main body 150. There is no abnormality in use.

At this time, the driving means 320 of the automatic light shielding means 300 does not operate, and the light shielding glass 310 descends to a lower limit position and thus the viewing window 120 is blocked so that the user does not interfere with welding.

When power is normally applied and power is supplied to the microcomputer 340, the microcomputer 340 outputs a control signal to the ventilation fan 350 to operate the ventilation fan 350 (S604) and the welding helmet 110. Ventilate the air between worker faces.

Thereafter, the microcomputer 340 determines whether a signal of the torch switch 132 is input (S606).

When the signal of the torch switch 132 is input, the microcomputer 340 blocks the control signal output to the welder main body 150 (S612) to prevent welding.

Next, the light shielding glass 10 is raised by outputting a control signal to the driving means 320 to rotate the driving means 320 (S614).

In detail, the driving means 320 is operated to drive the rack 322 arranged on the shaft, thus raising the pinion 316 engaged with the rack 322.

That is, the rack 322 and the pinion 316 meshed with each other are a structure for converting rotational motion into linear motion, and the pinion 316 is vertically lifted by the rotational motion of the rack 322.

Therefore, the light shielding glass 310 integrally mounted with the pinion 316 moves upward by the synergistic action of the pinion 316 to open the see-through window 120, and the light shielding glass 310 is disposed on the upper limit switch 332. When the signal of the upper limit limit switch 332 is input in contact with each other, the driving of the driving means 320 is stopped.

As such, the sight window 120 is opened by the rising of the light shielding glass 310 to secure the worker's view.

When the operator presses the torch switch 132 to perform welding in step S606, when the signal of the torch switch 132 is input to the microcomputer 340, the microcomputer 340 first outputs a control signal to the driving means 320. As the driving means 320 rotates in the opposite direction, the light shielding glass 310 descends to block the viewing window 120 to protect the eyes of the worker (S608), and the light shielding glass 310 contacts the lower limit switch 334. When the signal of the lower limit switch 334 is input, the driving of the driving means 320 is stopped.

Next, the microcomputer 340 drives the first relay R1 of the interface board 364 to output a control signal to the welder main body 150 (S610), whereby the worker can start welding by holding the torch 130 by hand. Make sure

That is, in the present invention, when the torch switch 132 is turned off, first, the control signal output to the welder main body 150 is blocked, and then the driving means 320 is driven to raise the light shielding glass 310 to the outside. By opening the see-through window 120 to be secured to ensure the view of the worker.

When the operator presses the torch switch 132 to turn on the welding, first, the driving means 320 is driven to lower the light shielding glass 310 to block the viewing window 120 to prevent the operator from direct light generated during welding. In a state to protect the eyes, the welding signal is output to the welder main body 150 to start welding.

100: welding helmet 110: helmet body
120: viewing window 132: torch switch
150: welder body 200: wearing means
210: fixed part 220: lifting part
230: control seat 300: automatic shading means
310: shading glass 320: driving means
330: limit sensor 340: microcomputer
R1, R2: relay

Claims (9)

A helmet body in close contact with a worker's face and a viewing window formed on the front surface;
Shading glass coupled to the elevating window of the helmet body;
Drive means mounted to one side of the helmet body to operate the light shielding glass by forward and reverse rotation to open or block the viewing window; And
When the torch switch provided in the torch connected to the welder main body by the power is turned off, the driving means is driven to open the viewing window, and when the torch switch is turned on, the driving means is driven to block the viewing window. Welding helmet provided with automatic light shielding means, characterized in that it comprises a microcomputer for outputting a control signal to the welder body to weld in a state. The method of claim 1,
The driving means is mounted on one side of the helmet body formed with a see-through window and the rear of the see-through window is configured with a light-shielding glass mounted on the left and right upper and lower ends,
The light shielding glass is welded helmet equipped with automatic light shielding means characterized in that the structure is fitted to the guide rail sliding vertically, the pinion mounted vertically on one side thereof is engaged with the rack built in the drive means. The method of claim 1,
A fixing part fixed to the body part of the worker, a lifting part coupled to the lifting part so as to be liftable, and provided between the lifting part and the helmet main body so that the helmet body is in close contact with the face of the worker by a multi-joint structure. Welding helmet provided with automatic shading means, characterized in that the wearing means further comprises an adjustment seat. The method of claim 3, wherein
The control seat has a first joint axially coupled to the upper portion of the elevating portion, the second joint axially coupled to rotate back and forth on one side of the first joint, and the left and right rotation to the top of the second joint Including a third joint that is axially coupled so that
The third joint has a welding helmet equipped with automatic shading means, characterized in that the lower part of the helmet body is fitted to the upper portion of the third joint so that the helmet body can move forward and backward. The method of claim 1,
The micom, torch switch, and welder body are electrically connected to an interface substrate;
The interface board receives a DC power supply and determines the magnitude of the DC voltage by the voltage control signal and outputs it stably, and a power stabilization circuit connected to the power switch;
A second relay receiving stable power through the power stabilization circuit and electrically connected to the first relay of the torch switch, the microcomputer, and the rear stage;
The welding helmet provided with the automatic shading means receiving a stable power supply through the power stabilization circuit, the first relay is connected to the front end of the second relay, the microcomputer and the welder body. The method of claim 1,
The helmet main body is provided with a welding shield, characterized in that the ventilation fan is further provided with a ventilation fan for introducing the air in front of the helmet body to the rear is connected to the microcomputer. The method of claim 1,
Upper and lower upper and lower limit sensors are further provided on the upper and lower parts of the see-through window so as to control the rising and falling of the shading glass. Determining whether the torch switch is in an ON state or an OFF state in a state where power is applied;
When the torch switch is in an ON state, driving the driving means to rotate in the opposite direction to cut off the viewing window by lowering the shading glass coupled to the viewing window of the helmet body;
Outputting a control signal to the welder main body by relay driving to weld through the torch;
Stopping the output of a control signal to the welder main body when the torch switch is in an OFF state to prevent welding; And
The control method of the welding helmet comprising the step of opening the see-through window by raising the light shielding glass by rotating the drive means reversely. The method of claim 8,
And operating the ventilation fan mounted to the helmet body in the state where the power is applied to ventilate the air between the welding helmet and the face.

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