KR20180094234A - Torch device for scarfing - Google Patents

Abstract

Disclosed is a scarfing torch device. The scarfing torch device of the present invention comprises: a nozzle unit forming a flame; a first pipe unit supplying fuel gas to the nozzle unit; a second pipe unit connected to the nozzle unit with the first pipe unit and supplying low-pressure oxygen to the nozzle unit; a third pipe unit connected to the nozzle unit with the second pipe unit and supplying high-pressure oxygen to the nozzle unit; a connecting pipe unit connecting the second pipe unit to the third pipe unit; and a check valve unit installed in the connecting pipe unit and allowing one-way flow in which the low-pressure oxygen moving along the second pipe unit moves to the third pipe unit.

Description

Scorching torch device {TORCH DEVICE FOR SCARFING}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a scarifying torch device, and more particularly, to a scarifying torch device capable of stabilizing a preheating flame and shortening a working time.

Generally, the sparging operation to remove defects on the slab surface ignites the oxygen and gas discharged through the scarifying torch device to form sparks, and then instantaneously melts the slab surface to remove defects on the slab surface.

BACKGROUND ART [0002] The background art of the present invention is disclosed in Korean Patent Laid-Open Publication No. 2017-0003826 (published on 2017.01.10, entitled Scarcings).

According to an embodiment of the present invention, there is provided a scarping torch device capable of stabilizing a preheating flame and shortening a working time.

The scatting torch device according to the present invention comprises: a nozzle portion for forming a flame; a first conduit portion for supplying a fuel gas toward the nozzle portion; a second conduit portion connected to the nozzle portion together with the first conduit portion, A third conduit portion connected to the nozzle portion together with the second conduit portion and supplying high-pressure oxygen toward the nozzle portion, a third conduit portion connecting the second conduit portion and the third conduit portion, and a connection conduit portion connecting the second conduit portion and the third conduit portion, And a check valve unit installed in the second conduit and allowing the low-pressure oxygen to be moved to the third conduit part only in one direction.

The nozzle portion includes a first discharge passage portion through which the low-pressure oxygen moved through the first passage portion and the low-pressure oxygen moved through the second passage portion are discharged, and a second discharge portion that forms a passage through which the fluid moved through the third passage portion is discharged. And a passage portion.

The first discharge passage portion is located on the outer side of the second discharge passage portion and the second discharge passage portion forms a circular second discharge hole. The first discharge passage portion has a plurality of Thereby forming a first discharge hole.

Further, when the preheating flame is formed in the nozzle portion, it is preferable that the supply of the high-pressure oxygen through the third conduit portion is blocked.

In addition, when the preheating flame is formed in the nozzle portion, the low-pressure gas moved along the second duct portion is mixed with the fuel gas supplied through the first duct portion and then discharged through the first discharge passage portion, Is partially passed through the connection pipe portion and the check valve portion, is moved to the third pipe portion, and then discharged through the second discharge passage portion.

The check valve unit includes a housing part connected to the connection pipe part and having an inner space, a ball member movably installed inside the housing part and opening / closing the first passage communicating with the second pipe part, And an elastic member for elastically pressing the ball member toward the first passage.

In the scatting torch device according to the present invention, most of the low-pressure oxygen is discharged through the second channel portion, and the remainder of the low-pressure oxygen is discharged to the third channel portion through the check valve portion to stabilize the preheating flame, .

1 is a front view schematically showing a structure of a scarifying torch device according to an embodiment of the present invention.
FIG. 2 is a perspective view showing the installation state of a check valve unit and a connection pipe according to an embodiment of the present invention. FIG.
3 is a view illustrating a nozzle unit according to an embodiment of the present invention.
4 is a perspective view schematically showing a nozzle unit according to an embodiment of the present invention.
5 is a cross-sectional view schematically showing an internal structure of a check valve unit according to an embodiment of the present invention.

Hereinafter, a scarping torch device according to an embodiment of the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation.

Further, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

FIG. 1 is a front view schematically showing a structure of a scarifying torch according to an embodiment of the present invention. FIG. 2 is a perspective view showing a state in which a check valve unit and a connection pipe unit are installed according to an embodiment of the present invention And FIG. 3 is a view illustrating a nozzle unit according to an embodiment of the present invention. FIG. 4 is a perspective view schematically illustrating a nozzle unit according to an embodiment of the present invention. Sectional view schematically showing the internal structure of the check valve unit.

1 to 3, the scatting torch apparatus 1 according to the embodiment of the present invention includes a nozzle unit 10 for forming a flame, a fuel supply unit for supplying fuel gas toward the nozzle unit 10, A second conduit section 30 connected to the nozzle section 10 together with the first conduit section 20 and supplying low pressure oxygen toward the nozzle section 10, A third conduit section 40 connected to the nozzle section 10 together with the conduit section 30 and supplying high pressure oxygen to the nozzle section 10 and a third conduit section 40 connected to the second conduit section 30 and the third conduit section 40 A check valve which is provided in the connection pipe portion 50 and the connection pipe portion 50 for connecting the first pipe portion 40 and the second pipe portion 30 and permits only one- And a valve portion (60).

In the nozzle unit 10, low-pressure oxygen and fuel gas are discharged in a mixed state to form a flame, and high-pressure oxygen is discharged as needed to perform a scarping operation. The nozzle unit 10 according to one embodiment includes the nozzle body 12, the nozzle head 14, the first discharge passage portion 15, and the second discharge passage portion 18.

1, 3 and 4, the nozzle body 12 forming the body of the nozzle unit 10 is provided with a first channel unit 20, a second channel unit 30, (The reference right side in Fig. 1) of the motor 40 is connected. A first discharge passage portion (15) and a second discharge passage portion (18) are provided in the nozzle head (14) extending from the nozzle body (12).

The first discharge passage portion 15 discharges the fuel gas transferred through the first conduit portion 20 and the low-pressure oxygen transferred through the second conduit portion 30. The second discharge passage portion 18 forms a passage through which the fluid moved through the third passage portion 40 is discharged. The first discharge passage portion 15 according to one embodiment is located outside the second discharge passage portion 18. The second discharge passage portion 18 forms a circular second discharge hole 19. The first discharge passage portion 15 is formed in a circular arc along the outer circumference of the second discharge passage portion 18, 1 discharge hole 16 is formed.

That is, the second discharge passage portion 18 is connected to the third passage portion 40, and the gas moved through the third passage portion 40 is discharged through the second discharge hole 19. The first discharge passage portion 15 is connected to the first conduit portion 20 and the second conduit portion 30 and is connected to the second conduit portion 30 through the first conduit portion 20, Pressure gas is mixed and then discharged through the first discharge hole 16 of the first discharge passage portion 15.

The first exhaust hole 16 is smaller than the diameter of the second exhaust hole 19 and is provided in plural around the outer periphery of the second exhaust hole 19. Therefore, the flame for heating the slab is formed by the gas discharged through the first discharge passage portion 15, and the flame on the slab surface heated by the high-pressure oxygen discharged through the second discharge passage portion 18 or the foreign matter Is removed.

The first conduit portion 20 is formed in a tubular shape and supplies the fuel gas toward the nozzle portion 10. One side of the first duct portion 20 is connected to the nozzle body 12 and the other side is connected to the operation body 72 of the operation portion 70.

The second conduit portion 30 is connected to the nozzle portion 10 together with the first conduit portion 20 and supplies low pressure oxygen toward the nozzle portion 10. One side of the second conduit part 30 is connected to the nozzle body 12 together with the first conduit part 20 and the other side is connected to the operation body 72 of the operation part 70.

The third conduit portion 40 is connected to the nozzle portion 10 together with the second conduit portion 30 and supplies high-pressure oxygen toward the nozzle portion 10. One side of the third conduit part 40 is connected to the nozzle body 12 together with the second conduit part 30 and the other side is connected to the operation body 72 of the operation part 70.

The connection conduit section 50 is a conduit connecting the second conduit section 30 and the third conduit section 40. The check conduit section 60 is provided in the conduit conduit section 50, 30 to flow through the third channel portion 40 only.

The check valve unit 60 is provided in the connection conduit unit 50 and includes various kinds of various types within the technical idea of allowing the one-way flow in which the low-pressure oxygen moved along the second conduit unit 30 is moved to the third conduit unit 40 Can be used. The check valve portion 60 according to one embodiment includes a housing portion 62, a ball member 68, and an elastic member 69.

The housing portion 62 is connected to the connecting conduit portion 50 and has an inner space for moving the ball member 68. Both sides of the housing part 62 are connected to the connecting tube part 50 and the connecting tube part 50 connected to the second tube part 30 is connected to the first passage 64 of the housing part 62. And the third duct portion 40 is connected to the second passage 66 of the housing portion 62.

The ball member 68 is provided movably inside the housing portion 62 and opens and closes the first passage 64 communicated with the second conduit portion 30.

An elastic member 69 using a spring is provided inside the housing portion 62 and elastically presses the ball member 68 toward the first passage 64. Therefore, the ball member 68 is separated from the first passage 64 only when the fluid that is transferred to the ball member 68 through the first passage 64 is equal to or higher than the set pressure.

When the preheating flame is formed in the nozzle part 10, the supply of the high-pressure oxygen through the third conduit part 40 is blocked, the fuel gas is supplied to the first conduit part 20, Low-pressure oxygen is supplied.

When the low pressure gas moving along the second duct portion 30 is mixed with the fuel gas supplied through the first duct portion 20 and then the first discharge passage portion 15 is mixed with the fuel gas supplied through the first duct portion 20 when the preheating flame is formed in the nozzle portion 10, . A part of the low pressure gas moving along the second conduit portion 30 passes through the connection conduit portion 50 and the check valve portion 60 and is moved to the third conduit portion 40 and then flows into the second conduit portion 18 to stabilize the preheating flame.

The scarification torch device 1 according to an embodiment of the present invention includes an operation portion 70 for controlling the supply amount of fuel gas, low-pressure oxygen, and high-pressure oxygen. The operating portion 70 includes a first conduit portion 20 and an operation body 72 connected to the ends of the second conduit portion 30 and the third conduit portion 40. A first adjusting member (74) rotatably mounted on the operating body (72) regulates the amount of fuel gas supplied to the first conduit section (20). The second adjusting member 76 is also rotatably mounted on the operating body 72 and adjusts the amount of low-pressure oxygen supplied to the second channel portion 30. [ A third adjusting member (78) rotatably installed on the operating body (72) regulates the amount of high pressure oxygen supplied to the third conduit section (40).

Low pressure oxygen is oxygen gas with lower pressure than high pressure oxygen. The low-pressure oxygen is used for the spark formation of the nozzle unit 10, and the high-pressure oxygen is used for the sparring work to cut the surface of the slab through the nozzle unit 10. [

Hereinafter, an operating state of the scarifying torch device 1 according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The maximum value of the fuel gas flowing through the first conduit portion 20 is set to 100%, and the time when the fuel gas is not supplied is set to 0%. The maximum value of the low-pressure oxygen to be moved through the second channel portion 30 is set to 100%, and the time when the low-pressure oxygen is not supplied is set to 0%. The maximum value of the high-pressure oxygen to be moved through the third conduit portion 40 is set to 100%, and the time when the high-pressure oxygen is not supplied is set to 0%.

Before the scarping operation, the scatting torch device 1 forms a preheating flame first. 100% of the fuel gas is supplied to the first conduit part 20 through the operation part 70 and 100% of the low pressure oxygen is supplied to the second conduit part 30 and the high pressure oxygen is supplied to the third conduit part 40 It does not.

10% of the low pressure gas moving through the second conduit section 30 is moved to the third conduit section 40 through the connection conduit section 50 and the check valve section 60. [ Therefore, gas mixed with 100% of the fuel gas and 90% of the low-pressure oxygen is discharged through the first discharge passage portion 15 of the nozzle unit 10, and a flame is formed. Further, 10% of low-pressure oxygen is discharged through the second discharge passage portion 18 and helps to form a flame, so that the preheating flame is stabilized.

After the slab, which is the base material, is preheated, high pressure oxygen is supplied to the third conduit portion 40 by the operation of the third control member 78. The high-pressure oxygen moved through the third conduit portion (40) discharges through the second discharge passage portion (18) to perform a scarping operation.

Meanwhile, since the high-pressure oxygen is moved through the third conduit part 40, a part of the low-pressure oxygen moving through the second conduit part 30 is moved to the third conduit part 40 through the check valve part 60 . The high-pressure oxygen flowing through the third conduit portion 40 can not be moved to the second conduit portion 30 by the check valve portion 60 allowing only one-way flow. Therefore, by the operation of the third adjusting member 78, which is a valve for supplying high-pressure oxygen, 100% of the fuel gas is moved through the first channel portion 20, 100% of the low-pressure oxygen is moved through the second pipe portion, 100% of high-pressure oxygen moves through the third piping section.

A part of the low-pressure oxygen which is moved through the second conduit part 30 during the preheating operation of the scarifying torch device 1 is moved to the third conduit part 40 through the check valve part 60. [ At this time, the ratio of the low-pressure oxygen discharged through the third conduit portion 40 to the low-pressure oxygen discharged through the second conduit portion 30 is 1: 9, and may be 2: 8 or 3: 7 if necessary.

In the scatting torch device 1 according to the embodiment of the present invention, when the preheating flame is formed, a part of the low-pressure oxygen is also exhausted through the second exhaust hole 19, Oxygen and fuel gas. Therefore, the preheating time of the slab can be shortened, and the preheating flame off phenomenon can be improved when the high-pressure oxygen is exhausted through the second discharge passage portion 18.

As described above, according to the present invention, most of the low-pressure oxygen is discharged through the second conduit portion 30, and the remainder of the low-pressure oxygen is discharged to the third conduit portion 40 through the check valve portion 60, Since the flame is stabilized, the working time can be shortened.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the invention as defined by the appended claims. will be. Accordingly, the true scope of the present invention should be determined by the following claims.

1: scarping torch device 10: nozzle part
12: nozzle body 14: nozzle head
15: first exhaust passage portion 16: first exhaust passage
18: second discharge passage part 19: second discharge hole
20: first conduit section 30: second conduit section
40: third conduit part 50: connection conduit part
60: Check valve part 62: Housing part
64: first passage 66: second passage
68: ball member 69: elastic member
70: operating part 72: operating body
74: first adjustment member 76: second adjustment member
78: third adjusting member

Claims (6)

A nozzle portion for forming a flame;
A first conduit portion for supplying a fuel gas toward the nozzle portion;
A second conduit part connected to the nozzle part together with the first conduit part and supplying low pressure oxygen toward the nozzle part;
A third conduit connected to the nozzle portion together with the second conduit portion and supplying high-pressure oxygen toward the nozzle portion;
A connection conduit portion connecting the second conduit portion and the third conduit portion; And
And a check valve unit installed in the connection pipe portion and allowing only one-way flow in which the low-pressure oxygen moved along the second channel portion is moved to the third channel portion.
The method according to claim 1,
Wherein the nozzle unit comprises: a first discharge passage part through which the fuel gas moved through the first conduit part and the low-pressure oxygen moved through the second conduit part are discharged; And
And a second discharge passage part for forming a passage through which the fluid moved through the third conduit part is discharged.
3. The method of claim 2,
Wherein the first discharge passage portion is located on the outer side of the second discharge passage portion and the second discharge passage portion forms a circular second discharge hole and the first discharge passage portion has a circular arc along the outer circumference of the second discharge passage portion, To form a plurality of first discharge holes.
The method of claim 3,
Wherein when the preheating flame is formed in the nozzle portion, the supply of the high-pressure oxygen through the third channel portion is cut off.
5. The method of claim 4,
A low pressure gas moving along the second conduit portion is mixed with the fuel gas supplied through the first conduit portion and is discharged through the first discharge passage portion when the preheating flame is formed in the nozzle portion,
Wherein a part of the low-pressure gas moving along the second duct portion passes through the connection duct portion and the check valve portion, is moved to the third duct portion, and then is discharged through the second discharge passage portion.
The method according to claim 1,
Wherein the check valve unit comprises: a housing part connected to the connection pipe part and having an inner space;
A ball member movably installed inside the housing portion and opening / closing a first passage communicated with the second conduit portion; And
And an elastic member provided inside the housing part and elastically pressing the ball member toward the first passage.

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