KR200380043Y1 - 360°rotation nozzle for oxygen cutting machine - Google Patents

Abstract

 The present invention relates to a 360-degree rotating nozzle of an oxygen cutter having a flashback prevention function and a rotation function, and more particularly, a rotary nozzle of an oxygen cutter having an oxygen inlet hose, an oxygen inlet tube and a gas inlet tube to which the gas inlet hose is connected. In the configuration, when the rotary nozzle is flowing along the cutting surface by the cutting operation of the oxygen cutting machine, the oxygen inlet hose and the gas inlet hose connected after the rotating nozzle are prevented from twisting, and the operator's wrist is smoothed to improve work efficiency. Rotating nozzle with a rotating body having an oxygen flow path connected to the oxygen inlet of the rotating nozzle, a gas flow path connected to the gas inlet, and a fixed body having an oxygen flow path, a gas flow path and a flashback arrestor. By separating the rotating body and the fixed body with a screw rod and a nut, a rotary furnace of one oxygen cutting machine By using a, it is possible to prevent the entanglement of the oxygen inlet hose and the gas inlet hose and blocks the flame from entering the rotating nozzle, which is to use the oxygen cutter safely.

Description

 360 degree rotation nozzle for oxygen cutting machine with backfire prevention function and rotation function

The present invention relates to a 360-degree rotating nozzle of the oxygen cutting machine having a flashback prevention function and a rotation function, in detail, a rotary body formed with an oxygen flow passage connected to the oxygen inlet, a gas flow passage connected to the gas inlet, and oxygen Each flashback arrestor is formed by combining an oxygen flow passage in which an exhaust pipe is formed and a gas flow passage in which a gas discharge pipe is formed, respectively, and the outer rotor rotates 360 ° around the fixture. It is related with the rotating nozzle of the oxygen cutting machine characterized by the above-mentioned.

In general, the use of an oxygen cutter for dividing one metal is an operation of dissolving and separating metal with a high temperature flame generated in a cutting torch.

In the case of the oxygen cutter which combines oxygen and gas in the above-described transfer operation and uses the cutting flame, two fuels supplied from the oxygen cylinder and the gas cylinder are supplied to the cutting torch through the nozzle, so that the flame generated by ignition of the cutting torch The cutting work is performed.

However, the above cutting operation can improve the convenience of cutting the metal, but it is a risky operation for the fuel used. Since the fuel used uses a gas that is sensitive to flame and explosion, it is always possible for the operator to use it. It requires considerable attention.

Therefore, in the case of the above cutting operation, it is preferable to prevent the flame generated from the cutting torch from being backfired through the welding nozzle. However, the nozzle of the conventional cutting machine is not equipped with a function for preventing backfire and gas shutoff. Do not, because safety accidents frequently occur due to the backfire of the flame, there was a problem that human physical damage is one after another.

In addition, since the configuration of the nozzle provided in the conventional oxygen cutter only serves as a connector for simply supplying oxygen and gas, when the user moves the cutting torch along the cutting surface for cutting, the oxygen inlet hose formed at the rear of the nozzle and The gas inlet hoses are twisted with each other to cause an accident that the hose bursts, because the wrist of the operator operating the nozzle due to the twisted hose can not be easily performed for a long time, there was a problem that the work efficiency is reduced.

The present invention, in view of the above problems, in the configuration of a nozzle having an oxygen inlet and a gas inlet connecting the oxygen inlet hose and the gas inlet hose, while the nozzle flows along the cutting surface by the cutting operation of the operator, Oxygen inlet hose and gas inlet hose are not twisted, and the rotating body formed with a backfire prevention device having bearings, a heat conduction mesh and a blocking plate in the oxygen flow passage connected to the oxygen inlet and the gas flow passage connected to the gas inlet, and oxygen Divided into the flow passage and the gas flow passage and the fixed body which formed the heat conduction mesh body, the separated rotor and the fixed body are combined with the screw rod and the nut and used as the rotating nozzle of one oxygen cutting machine. It is to prevent the hose from twisting and to block the flame flowing into the rotating nozzle. In detail, it is as follows.

A screw rod through-hole 6 is formed in the rotating body 5 in which the oxygen flow passage 2 connected to the oxygen inlet 1 and the gas flow passage 4 connected to the gas inlet 3 are formed inward. A flashback arrestor 8 is formed in the oxygen discharge pipe 7 connected to the oxygen inlet 1 and the oxygen flow passage 2 ', and connected to the gas inlet 3 and the gas flow passage 4'. A flashback arrestor (8) (8 ') is formed in the gas discharge pipe (9) to be used, and a threaded rod (11) is formed on the upper side of the fixed body (10). (12) is formed in a stack, and the separated rotating body (5) and the fixing body (10) are combined with the flat washer (13) and the nut (14) in the order outside the screw rod (11) in order to rotate the rotating nozzle ( 15, wherein the rotating body 5 and the fixing body 10 are formed with threaded portions 17 and 17 'for coupling the flashback arrestor 8 to the flashback arrestor 8, respectively. Bearings for opening and closing oxygen and gas 18, a barrier plate 21 having a through hole 19 through which oxygen and gas move and a heat conduction mesh 20 formed therein is formed in a diaphragm so as to operate the bearing 18 above. It is made by forming an elastic spring 22 fixed to the blocking plate 21 to push the bearing 18.

delete

delete

Reference numeral '41' indicates an oxygen distributor.

Thus, the use of the rotating nozzle 15 coupled to the rotating body 5 and the fixed body 10 is as follows.

The above-described hose is connected to the oxygen inlet 1 formed in the rotating body 5 of the present invention and the hose nut 33 through the oxygen inlet hose 31 and the gas inlet hose 32 connected to the gas inlet 3. The nut 33 is formed with an inclined threaded portion 34 and a ball inlet 35.

In the present invention, the oxygen and gas introduced and connected to the oxygen inlet 1 and the gas inlet 3 move along the oxygen flow passage 2 and the gas flow passage 4 formed inside the rotor 5, It moves to the oxygen flow path 2 'and the gas flow path 4' formed in the fixed body 10. FIG.

The oxygen and gas moving as described above are connected to the fixture 10 by the screw portion 17 'via the oxygen flow passage 2' and the gas flow passage 4 'formed in the fixture 10. The oxygen and gas discharged through the oxygen discharge pipe 7 and the gas discharge pipe 9, and the oxygen and gas flowing between the fixed body 10 and the rotating body 5 are formed on the outer side of the fixed body 10. As a result, the oxygen flow passage 2 'and the gas flow passage 4' are blocked so that oxygen and gas are mixed or moved along a predetermined flow passage without being discharged elsewhere. In the process of moving, looking at the operation of the rotating body 5 and the fixed body 10, the rotating body fixed with the screw rod 11, the flat washer 13 and the nut 14 of the fixed body 10 ( 5, the rotating body 5 coupled to the outer side of the flat washer 13 in the state that the fixing body 10 fixed with the screw rod 11 and the nut 14 does not rotate, the fixing body 10 Spine Therefore, when the user flows the cutting torch along the cutting surface, the rotating body 5 outside the fixed body 10 is rotated to prevent twisting of the oxygen inlet hose 31 and the gas inlet hose 32. .

Referring to the operation of the flashback arrestor 8 according to the present invention is as follows.

The flashback arrestor 8 is engaged with the rotary nozzle 15 by the screw portion 17 and the inclined threaded portion 34, respectively, so that oxygen and gas are stored in the state in which the flashback arrestor 8 is coupled to the rotary nozzle 15. When entering the rotary nozzle 15, the ball inlet 35 of the hose nut 33 at the pressure of oxygen and gas flowing into the oxygen flow passage 2 'and the gas flow passage 4' of the fixed body 10. The bearing 18 in close contact with the flashback arrestor 8 and the bearing 18 in close contact with the expansion and contraction spring 22, thereby providing oxygen through the open oxygen flow passage 2 'and the gas flow passage 4'. And gas is supplied.

Oxygen and gas supplied as described above is passed through the oxygen discharge pipe 7 and the gas discharge pipe 9 of the fixed body 10 via the blocking plate 21 and the through hole 19 of the oxygen cutter (not shown). It is discharged to the outside of the rotating nozzle 15, and oxygen cutting operation is performed.

As described above, when the operation of the rotary nozzle 15 proceeds, if the flame of the cutting torch is reversed and introduced into the rotary nozzle 15 due to an external obstacle, the oxygen discharge pipe 7 or the gas discharge pipe 9 of the flashback arrestor 8 is prevented. Flame flows into the first blocking plate 21 and the heat conduction mesh 20, the rate of progress of the flame is primarily reduced, the flame is reduced speed heat the heat conduction mesh 20 to the heat shield of the block 21 By raising the temperature, it is to conduct the temperature to the expansion spring 22 coupled to one side of the blocking plate (21).

When heat is applied to the expansion spring 22 as described above, the expansion spring 22 is extended by the deformation by the heat, so the ball 18 of the hose nut 33 by pushing the bearing 18 located on one side of the expansion spring 22 In close contact with the part 35, the oxygen flow path 2 ′ and the gas flow path 4 ′ of the stationary body 10 are blocked to block the oxygen, gas, and flame, and the flame is moved outside the stationary body 10. It is to prevent backfire, and the thermally conductive mesh 20 formed in the threaded portion 17 'eliminates the residual heat applied to the fixing agent 10.

As described in detail above, the use of an oxygen cutter in which the rotating body 5 and the fixed body 10 are coupled to the rotating nozzle 15 that rotates 360 ° is used when the operator flows the cutting torch along the cutting surface. Since the rotating body 5 rotates to the outside of the fixed body 10 so that the oxygen inlet hose 31 and the gas inlet hose 32 are not twisted, the operator's hand does not hurt, and the inlet hose (when the user performs the cutting operation) 31) Since 32 is not concerned with twisting, it is possible to concentrate on cutting work and to increase the efficiency of the work, and to solve the problems caused by twisting the oxygen inlet hose 31 and the gas inlet hose 32 at the same time. It works.

In addition, the present invention, when the flame generated during the oxygen cutting operation is backfired, when entering the rotary nozzle 15, the flashback arrestor 8 coupled to the rotary nozzle 15 blocks the oxygen and gas inlet and flame, the rotary nozzle (15) It prevents the flame from being transmitted to the outside and blocks the gas flowing through the rotating nozzle 15, thereby preventing the backfire of the flame and the expansion of the generated flame, thereby preventing human and physical safety accidents caused by the flame. It is effective to prevent economic losses by preventing.

1 is an exploded perspective view of the present invention

2 is a perspective view of the present invention

Figure 3 is a cross-sectional view illustrating the use state of the present invention

Figure 4 is a perspective view of the gas discharge pipe portion separated in the present invention

Figure 5 is a perspective view illustrating the configuration of the (A) partial flashback arrester in the present invention Figure 6 is a cross-sectional view illustrating the operation of the flashback arrestor in the present invention

a is gas open

b is gas blocked

Explanation of symbols for main parts of the drawings

One; Oxygen inlet 2,2 '; Oxygen flow path 3; Gas inlet

4,4 '; Gas channel 5; Rotating body 6; Threaded hole

7; Oxygen discharge line 8; Flashback arrestor 9; Gas discharge pipe

10; Fixture 11; Screw rod 12; Rubber ring 13; Flat Washer

14; Nut 15; Rotating nozzle

17,17 '; Threaded portion 18; bearing

19; Through 20; Thermal mesh 21; Blocking plate 22; Telescopic spring

31; Oxygen inlet hose 32; Gas inlet hose 33; Hose nut 34; Inclined threaded portion 35; Ball inlet

Claims (6)

 A screw rod through-hole 6 is formed in the rotating body 5 in which the oxygen flow passage 2 connected to the oxygen inlet 1 and the gas flow passage 4 connected to the gas inlet 3 are formed inward. In the oxygen inlet (1) and the gas inlet (3), the bearing 18 is embedded, the backing plate 21 and the expansion spring 22 combined with the blocking plate 21, the through-hole 19 and the thermal conductive mesh 20 is formed To form the protector 8, The thermal conduction mesh is formed in the oxygen discharge pipe 7 of the oxygen flow passage 2 'connected to the oxygen oxygen inlet 1 and the gas discharge pipe 9 of the gas flow passage 4' connected to the gas inlet 3 '. Form 20, The screw rod 11 is formed on the upper side of the fixing body 10, and the rubber ring 12 is formed in a stack on the other periphery, so that the separated rotating body 5 and the fixing body 10 are formed. Combining the flat washer 13 and the nut 14 to the outside of the screw rod 11 in order to form a rotating nozzle (15), The rotating body 5 is formed with a screw portion 17 for coupling the flashback arrestor 8, the fixed body 10 is formed by forming a screw portion 17 'for coupling the thermal conductive mesh 20 360 degree rotating nozzle of oxygen cutter with flashback prevention function and rotation function. In the rotary nozzle 15 of the oxygen cutter, A fixed body 10 having an oxygen flow passage 2 and a gas flow passage 4 embedded in a wall surface, and having a screw rod 11 protruding from the top surface thereof; An oxygen flow passage 2 'connected to the oxygen flow passage 2 of the stationary body 10 and a gas flow passage 4' connected to the gas flow passage 4 are installed on the wall surface. A rotating body 5 having a threaded rod through hole 6 for inserting the four rods 11 on an upper surface thereof; A rubber ring 12 fitted to an outer surface of the fixed body 10 so as to maintain an airtight state with the rotating body 5; And a nut 14 coupled to the screw rod 11 exposed to the outside of the screw through hole 6 so that the rotating body 5 and the fixing body 10 can be freely fastened. 360 degree rotation nozzle of oxygen cutting machine with function and rotation function The method of claim 2, A flat washer 13 is additionally inserted between the screw rod through hole 6 and the screw rod 11 so that the rotating body 5 and the fixing body 10 rotate smoothly in a state of being kept airtight. The 360 degree rotation nozzle of the oxygen cutter which has a flashback prevention function and the rotation function characterized by the above-mentioned. The method according to claim 1 or 2, The thermally conductive mesh 20 in the threaded portion 17 'of the oxygen discharge pipe 7 fastened to one side of the oxygen flow passage 2' and the gas discharge pipe 9 fastened to one of the gas flow passage 4 '. 360 degree rotation nozzle of the oxygen cutting machine which has a flashback prevention function and a rotation function characterized by the additional installation. The method of claim 1, The flashback arrestor 8, A bearing 18 associated with opening and closing the oxygen flow passage 2, 2 'and the gas flow passage 4, 4'; An extension spring 22 that pushes the bearing 18 toward the inlet of the oxygen flow passage 2 and the gas flow passage 4; One end of the expansion spring (22) is supported, the blocking plate 21 is a plurality of through-holes 19 at the same interval to supply oxygen and gas to the oxygen discharge pipe (7) and the gas discharge pipe (9); 360 degree rotating nozzle of the oxygen cutter having a flashback prevention function and a rotation function comprising a. The method of claim 5 Thermal conductive mesh body 20 is further formed on one surface of the blocking plate 21, 360 degree rotation nozzle of the oxygen cutter having a backfire prevention function and a rotating function.