KR101772126B1 - torch assembly for welding - Google Patents

Abstract

According to the present invention, a torch assembly for welding comprises a body housing, a torch housing, a nozzle unit, and a connection member. More specifically, a mixing partition wall is more provided in the torch housing. Therefore, in a space made by the mixing partition wall, at least two different gases are mixed with each other. Moreover, the mixed gases are uniformly supplied to emit an additional mixing machine.

Description

Torch assembly for welding [0002]

The present invention relates to a welding torch assembly, and more particularly, to a welding torch assembly that does not have a separate mixer and allows gas to be smoothly mixed with the welding torch assembly itself, To a welding torch assembly according to a novel aspect.

Generally, a welding torch assembly is a tool used for various metal working such as melting of a work object with high heat or cutting, surface treatment, welding, etc., and it is a welding tool according to a welding method such as a teig welding or a plasma welding And is provided in various structures.

The welding torch assembly includes a nozzle through which an arc is blown, an electrode installed so as to penetrate through the center of the nozzle, and a mounting cap installed to surround an end of the nozzle. In this case, A passage through which the cooling water flows is formed so that the electrode and the nozzle are prevented from overheating by the heat of the arc.

Regarding such conventional welding torch assemblies, there have been proposed a welding torch assembly as disclosed in Japanese Patent No. 10-1473663, No. 10-0306264, No. 10-1413911, No. 10-1427852, No. 10-1686540 Lt; / RTI >

However, in the conventional welding torch assembly according to the related art described above, a mixer for providing the mixed gas to the corresponding welding torch assembly has to be provided separately, which makes it difficult to increase the cost and manage the addition of the maintenance of the mixer .

In addition, the conventional welding torch assembly according to the related art has a problem in that the mixing ratio of the mixed gas supplied to the welding torch assembly is not constant due to the provision of the mixer described above.

That is, the gases (e.g., argon and helium or hydrogen, etc.) stored in the respective storage vessels are supplied to the mixer through respective gas hoses to be mixed with each other to form a mixed gas, and then supplied to the welding torch assembly. In the course of this process, when a temporary interruption of the welding operation occurs, the gas tends to flow from a gas hose having a high gas pressure to a gas hose having a low gas pressure among the two gas hoses connected to the mixer, It is inevitable to provide the welding torch to the welding torch assembly.

Accordingly, the prior art has a problem in that welding failure is often caused in the initial stage of the welding operation or in the early stage of resuming the welding operation because the gas mixing is not accurate.

In addition, although the welding torch assembly according to the related art is applied with a water-cooled structure, such a water-cooled structure is very complicated, so that it is not easy to manufacture, and there is a problem that leakage of water is particularly serious.

Patent No. 10-0306264 Registration No. 10-1473663 Registration No. 10-1413911 Patent No. 10-1427852 Patent No. 10-1686540

It is an object of the present invention to provide a welding torch assembly capable of smoothly mixing gas in a welding torch assembly itself without a separate mixer, The present invention provides a welding torch assembly according to a new form in which cooling using a fluid can be easily performed.

According to an aspect of the present invention, there is provided a welding torch assembly, wherein the interior of the welding torch assembly is fixedly coupled to a body housing, and the rear end of the welding torch assembly is provided with a plurality of A torch housing having a connecting member having a plurality of cooling water pipes guiding the supply and discharge of the gas pipe and the cooling water, respectively, A torch housing coupled to the body housing and having an inner hollow body; A plurality of cooling water flow paths provided at the tip of the torch housing and through which electrodes are inserted, a cooling water flowing into the plurality of cooling water flow paths, and a nozzle unit through which a mixed gas flow path is guided so as to guide the flow of the mixed gas; A plurality of gas pipes provided to interrupt the rear end of the torch housing and provided with respective gases for welding, and a plurality of cooling water pipes guiding the supply and discharge of the cooling water, respectively, And one or more mixing baffles provided in the torch housing to divide an internal space of the torch housing into a gas mixing space and a mixed gas supply space, wherein the gas can pass through the partition wall.

Here, the mixing partition is formed of a mesh body or a porous plate.

According to another aspect of the present invention, the mixing partition wall is formed with through holes through which the plurality of cooling water pipes pass, and each of the cooling water pipes passes through the through holes of the mixing partition wall and is connected to the nozzle part.

The nozzle unit includes a nozzle body having a plurality of cooling water flow paths and a mixed gas flow path formed therethrough, a cooling water communication hole communicating with each cooling water flow path and a gas communication hole communicating with the mixed gas flow path, And a nozzle tip coupled to the front end of the nozzle body. The nozzle is installed around the tip of the nozzle to surround the portion where the gas communication hole is formed, and guides the flow direction of the mixed gas discharged through the gas communication hole And a mesh type partition wall is further provided between the inner circumferential surface of the guide ring and the outer circumferential surface of the nozzle portion so that the mixed gas passing through the gas communication hole is uniformly sprayed.

In addition, a torch cap may be further provided on a front end side of the nozzle unit, which is a front side portion of the body housing, and a guide portion for guiding a welding rod may be further provided on at least one of an outer circumferential surface of the body housing and an outer circumferential surface of the torch cap .

In accordance with another aspect of the present invention, there is provided a welding torch assembly including a torch housing coupled to a body housing, the torch housing having an inner tubular body; A plurality of cooling water flow paths through which cooling water flows and a mixed gas flow path for guiding the flow of the mixed gas are respectively formed in the inner center of the torch housing and at the tip of the torch housing, A plurality of cooling water communication holes communicating with the cooling water flow path in a radial direction and having a plurality of gas communication holes communicating with the mixed gas flow path and radially penetrating therethrough; A guide ring provided so as to surround a periphery of the nozzle unit and having a plurality of guide holes communicating with the respective cooling water communication holes; A guide ring positioned at the tip of the guide ring and guiding the flow of the mixed gas flowing through each gas communication hole of the nozzle portion; A torch ring which surrounds the guide ring and has a plurality of guide grooves communicating with the guide holes and a first horizontal guide hole communicating with the guide grooves and horizontally penetrating the guide grooves; A guide ring disposed at a front end of the torch ring so as to surround the periphery of the guide ring and guiding the discharge direction of the mixed gas flowing through the gas communication hole and guided by the guide ring, A torch cap through which a plurality of second horizontal guide holes communicate with the guide holes, respectively; The torch cap and the torch ring are coupled to each other, and an inner circumferential surface of the torch cap is provided with a coupling nut in which a communication groove communicating between the second horizontal guide holes of the torch cap is formed.

A mesh type partition wall is further provided between the outer circumferential surface of the tip of the nozzle unit and the inner circumferential surface of the guide ring so that the mixed gas flowing through the respective gas communication holes and flowing along the guide ring is uniformly sprayed.

Further, it is preferable that one or two or more mixing partition walls, which are provided in the torch housing and partition the internal space of the torch housing into a gas mixing space and a mixed gas supply space, .

As described above, since the welding torch assembly according to the present invention can uniformly mix two different gases in the welding torch assembly without using a separate mixer, The cost or difficulty of maintenance can be solved.

In addition, the welding torch assembly according to the present invention is configured such that the gas mixing space in which the two gases for mixing gas are mixed is partitioned from the mixed gas supplying space by the mesh partition or the mixing partition made of the porous plate The gas mixing in the gas mixing space can be sufficiently performed and the mixed gas can be uniformly flowed from the gas mixing space to the mixed gas supply space.

In addition, the welding torch assembly according to the present invention is capable of uniformly discharging the mixed gas in a state where the vortex is prevented from being generated by the mesh-shaped partition wall during the passage of the mixed gas through the torch cap, .

In addition, the welding torch assembly according to the present invention can improve the cooling performance because the cooling water can cool not only the nozzle portion but also the guide ring, the guide ring and the torch cap integrated therewith, Thus minimizing the risk of leakage.

1 is a perspective view of a welding torch assembly according to a preferred embodiment of the present invention.
FIG. 2 is a front view illustrating a welding torch assembly according to a preferred embodiment of the present invention.
3 is a side view illustrating a rear side structure of a welding torch assembly according to a preferred embodiment of the present invention
4 is a sectional view taken along the line I-I in Fig. 2
Fig. 5 is an enlarged view of " A &
6 is an enlarged view of " B &
7 is a sectional view taken along the line II-II in Fig. 3
8 is an enlarged view of " C " in Fig. 7
9 is an enlarged view of " D "
10 is a perspective view illustrating a torch housing of a welding torch assembly according to a preferred embodiment of the present invention and a coupling structure of a nozzle body and a coupling member coupled thereto,
FIG. 11 is a cross-sectional view illustrating a structure of a torch housing of a welding torch assembly according to a preferred embodiment of the present invention and a coupling structure of a nozzle body and a coupling member coupled thereto;
12 is a cross-sectional view illustrating an internal structure of a welding torch assembly according to another embodiment of the present invention.

Hereinafter, a preferred embodiment of the welding torch assembly of the present invention will be described with reference to FIGS. 1 to 12 attached hereto.

FIG. 1 is a perspective view of a welding torch assembly according to a preferred embodiment of the present invention, FIG. 2 is a front view illustrating a welding torch assembly according to a preferred embodiment of the present invention, 3 is a side view for explaining a rear side structure of a welding torch assembly according to a preferred embodiment of the present invention, and FIGS. 4 to 9 are sectional views for explaining a welding torch assembly according to a preferred embodiment of the present invention to be.

As shown in these drawings, the welding torch assembly according to the embodiment of the present invention mainly includes a body housing 100, a torch housing 200, a nozzle unit 300, and a connecting member 400, Particularly, since the mixing partition wall 500 is further provided in the torch housing 200, two or more different gases can be mixed with each other in the space formed by the mixing partition wall 500, So that the supply of a separate mixer can be omitted.

This will be described in more detail below for each configuration.

First, the body housing 100 is a part of the outer body of the welding torch assembly according to the embodiment of the present invention.

The body housing 100 has a hollow interior opened to the front and rear, and protects the torch housing 200, which will be described later, from the external environment.

Next, the torch housing 200 is a portion where the nozzle unit 300 and a connecting member 400 are connected to each other.

The torch housing 200 is fixedly coupled to the body housing 100 and has a hollow interior opened to the front and rear. The interior of the torch housing 200 is divided into a gas mixing space 210 and a mixed gas supplying space 220 do.

Next, the nozzle unit 300 is a portion where the electrode 301 is installed and guides the discharge flow of the mixed gas.

The nozzle unit 300 is provided at the tip of the torch housing 200 and includes a nozzle body 310 and a nozzle tip 320.

The nozzle body 310 has a plurality of cooling water flow paths 311 and 312 and a mixed gas flow path 313 extending from its rear surface in the axial direction and a cooling water passage 311 and 312 communicating with the cooling water flow paths 311 and 312, The gas communication holes 315 and 316 and the gas communication holes 317 communicating with the gas mixture passage 313 are formed through the through holes.

The cooling water flow paths 311 and 312 include an inlet side cooling water passage 311 through which cooling water flows and an outlet side cooling water passage 312 through which cooling water flows out. And the cooling water flow paths 312 are formed at symmetrical positions of the nozzle body 310, respectively.

In addition, the mixed gas flow path 313 is formed to guide the flow of the mixed gas. In the embodiment of the present invention, the mixed gas flow path 313 is provided as one unit, and is formed to pass through the center of the nozzle body . Although not shown, the mixed gas flow path 313 may be provided in a plurality of two or more.

In addition, the nozzle tip 320 is coupled to the front end of the nozzle body 310, and the electrode 301 is inserted into the center of the nozzle.

The nozzle body 310 and the nozzle tip 320 are coupled to each other by a screw fastening structure and a protrusion stopper 319 for preventing excessive insertion into the torch housing 200 is formed on an outer circumferential surface of the nozzle body 310. [ Is formed.

Meanwhile, a torch cap 600 is further provided around the tip of the nozzle unit 300.

The torch cap 600 is installed so as to collectively surround the nozzle tip 320 and the portion where the gas communication hole 317 of the nozzle body 310 is formed while passing through the gas communication hole 317, The flow direction of the mixed gas is guided.

In particular, a torch ring 110 is further provided at the front end of the body housing 100, and a guide ring 120 for guiding the flow of cooling water is provided inside the torch ring 110. At the tip of the torch ring, The rear end of the torch cap 600 is fixed to the torch ring 110 by the tightening nut 130 while being positioned at the tip of the torch ring 110, A guide ring 140 positioned at the tip of the guide ring 120 and guiding the flow of the mixed gas flowing through each gas communication hole 317 of the nozzle unit 300 is formed on the inner circumferential surface of the cap 600 .

In addition, between the outer circumferential surface of the tip end of the nozzle unit 300 and the inner circumferential surface of the guide ring 140, a mixed gas flowing through the gas communication holes 317 and flowing along the guide ring 140 is uniformly ejected Shaped barrier ribs 610 are formed.

At this time, the guide ring 140 is formed integrally with the tip of the guide ring 120. However, the guide ring 140 may be provided separately from the guide ring 120.

The cooling water flowing through the cooling water communication hole 315 communicated with the inlet side cooling water flow path 311 of the two cooling water communication holes 315 and 316 of the nozzle body 310 is supplied to the guide ring 120 through the torch ring 110 Side guide hole 121 for guiding the cooling water to flow to the inner circumferential surface and an outflow side guide hole 121 for guiding the cooling water flowing out through the torch ring 110 to flow into the cooling water communication hole 316 communicated with the outflow- And guide holes 122 are formed respectively.

The inner circumferential surface of the torch ring 110 is provided with an inlet side guide groove 111 for temporarily storing the cooling water flowing through the inlet side guide hole 121 and a cooling water flow to the outlet side guide hole 122 Side guiding grooves 112 are formed in the inner side of the torch ring 110 and guide the cooling water stored in the inlet side guide grooves 111 to the side where the torch cap 600 is located, Side first guide hole 114 for guiding the outflow flow of the cooling water into the first horizontal guide hole 113 and the outflow guide groove 112. The torch cap 600 is provided with a flow- Side second guide hole 621 for guiding the cooling water introduced through the first side horizontal guide hole 113 to the inner circumferential surface of the clamping nut 130 and the outflow side first horizontal guide hole 114, Side second guide holes 622 for guiding the outflow, Side second guide hole 622 and the outflow-side second horizontal guide hole 622 on the inner circumferential surface of the inflow-side second horizontal guide hole 621, And a communication groove 131 for guiding to the second horizontal guide hole 622 is formed.

At this time, a portion where the cooling water communication holes 315 and 316 meet with the guide holes 121 and 122 and a portion where the guide holes 121 and 122 meet the guide grooves 111 and 112 and the horizontal guide holes 113, 114, The seal members 810, 820, and 830 are provided at portions where they meet, thereby preventing leakage of water between the gaps.

Next, the connecting member 400 is a portion provided for connection of the gas pipes 411 and 412 and the cooling water pipes 421 and 422.

The connecting member 400 is installed so as to block the open rear end of the torch housing 200, and includes a plurality of gas pipes 411 and 412 provided with respective gases for welding, A plurality of cooling water pipes (a supply-side cooling water pipe and an outlet-side cooling water pipe) 421 and 422 are connected to each other. Each of the gas pipes 411 and 412 and each of the cooling water pipes 421 and 422 is installed at a position orthogonal to the circumferential direction from the rear surface of the connecting member 400. In addition, The cooling water pipes 421 and 422 pass through the connecting member 400 and pass through the through hole 510 of the mixing partition wall 500 to be described later, Side cooling water flow path 311 and the outflow-side cooling water flow path 312 of the nozzle body 310 positioned at the front end of the cooling water channel 100 in the nozzle body 310, respectively.

Next, the mixing barrier 500 separates the gas mixing space 210 and the mixed gas supply space 220 inside the torch housing 200 from each other.

That is, by providing the mixing barrier ribs 500, the gas mixing space 210 is generated in the torch housing 200, so that the provision of the separate mixer for gas mixing is omitted and the torch housing 200 And the function of the mixer can be performed at the same time.

Particularly, the mixing partition wall 500 is formed of a mesh body (or a porous plate) provided in the rear side space of the torch housing 200 so as to partition the front and rear side spaces thereof, 421, and 422 are formed, respectively, as shown in FIGS. 10 and 11.

That is, the respective gases supplied through the two gas pipes 411 and 412 passing through the connecting member 400 are mixed with each other in the gas mixing space 210 in the torch housing 200 formed by the mixing partition wall 500 The mixed gas is supplied to the mixed gas supply space 220 through the mixing barrier wall 500. Particularly when considering that the mixing barrier rib 500 is formed of a mesh body (or a porous plate) During the passage through the barrier ribs 500, the mixed gas can be uniformly discharged at a constant flow rate.

Meanwhile, although only one mixing barrier 500 is provided as an example, it may be provided as two or more as necessary.

In addition, the mixing barrier rib 500 is configured to be held in the torch housing 200 by the stop ring 520 supporting the front and rear of the mixing barrier rib 500.

Hereinafter, the operation of the welding torch assembly according to the embodiment of the present invention described above will be described in more detail.

First, each of the gas hoses 11, 12 connected to each gas reservoir (not shown) is connected to each of the gas pipes 411, 412 of the welding torch assembly, and the hose 13 for supplying the cooling water is connected to the supply side cooling water pipe 421 and the hose 14 for discharging the cooling water is connected to the outflow cooling water pipe 422. [

At this time, no separate mixer is provided between the gas hoses 11 and 12 and the gas pipes 411 and 412, and they are directly connected to each other.

The gas supplied through the respective gas hoses 11 and 12 is supplied to the respective gas pipes 411 and 412 of the welding torch assembly (for example, To the gas mixing space 210 of the torch housing 200. The gas mixing space 210 of the torch housing 200 is provided with a plurality of gas-

The gas introduced into the gas mixing space 210 of the torch housing 200 as described above is mixed with each other in the gas mixing space 210 and then passes through the mixing partition wall 500 to the torch housing 200 200 into the mixed gas supply space 220.

At this time, as the mixed gas mixed in the gas mixing space 210 passes through the mixing partition wall 500 at a constant flow rate, the gas mixing in the gas mixing space 210 is more smoothly performed The gas supply into the mixed gas supply space 220 can be performed stably.

The mixed gas supplied into the mixed gas supply space 220 flows along the mixed gas flow path 313 formed in the nozzle body 310 and then passes through the gas communication hole 317 to be connected to the torch cap 600 And is supplied to the space between the nozzle tips 320. Then, the gas is discharged to the front of the torch cap 600 while flowing along the space and supplied to the arc generated in front of the torch cap 600.

Particularly, the mixed gas passing through the gas communication hole 317 and flowing along the space between the torch cap 600 and the nozzle tip 320 passes through the mesh type partition wall 610 provided in the corresponding space, A uniform discharge can be achieved as the vortex of the mixed gas is eliminated.

In addition, while the above-described supply of each gas, mixing of the supplied gas, and discharge of the mixed gas are continuously performed, cooling water flows into the supply-side cooling water pipe 421 and flows along the supply- Side cooling water flow path 311 of the inlet-side cooling water passage 311.

At the same time, the cooling water flows along the inlet-side cooling water passage 311 and then flows into the cooling water communication hole 315, the inlet-side guide hole 121, the inlet-side guide groove 111, Through the hole 113 and the inlet side first horizontal guide hole 621 and flows into one side of the communication groove 131 formed in the inner circumferential surface of the lock nut 130, Through the outlet side second horizontal guide hole 622, the outlet side first horizontal guide hole 114, the outlet side guide groove 112, the outlet side guide hole 122 and the cooling water communication hole 316 And then flows out to the outflow side cooling water pipe 422 through the rear outflow side cooling water flow path 312. As a result, the torch cap 600, the nozzle body 310, and the electrode 301 installed to penetrate the inside of the nozzle body 310 can be cooled according to the flow of the cooling water.

As a result, the welding torch assembly according to the present invention can achieve uniformity of mixing of two different gases in the welding torch assembly without using a separate mixer, Cost or difficulty can be solved.

In addition, in the welding torch assembly according to the present invention, the gas mixing space 210 in which the two gases for mixing gas are mixed is formed by the mixing barrier 500 formed of the mesh body or the porous plate, The gas mixture can be sufficiently mixed in the gas mixing space 210 and the mixed gas can be uniformly supplied from the gas mixing space 210 to the mixed gas supply space 220 So that it can flow.

In addition, the welding torch assembly according to the present invention can uniformly discharge the mixed gas in a state where the vortex is prevented from being generated by the mesh-type partition 610 during the passage of the mixed gas through the torch cap 600, .

Meanwhile, the welding torch assembly of the present invention is not limited to the structure of the above-described embodiment.

That is, the welding torch assembly of the present invention may further include one or more guide portions 700 as shown in FIG.

The guide unit 700 may be provided on at least one of the outer circumferential surface of the body housing 100 and the outer circumferential surface of the torch cap 600 to guide the welding rod 20 to a predetermined position The guide part 700 may be fixedly coupled to the torch cap 600 while the through hole 710 through which the welding rod 20 passes may be additionally formed in the embodiment of the present invention.

In addition, the welding torch assembly of the present invention has a structure in which the nozzle unit 300, the guide ring 120, and the guide ring 140 and the torch cap 600 integrated therewith are cooled at the same time, 500) is most preferable because it can maximally improve the welding performance. However, the cooling structure or the structure in which the mixing barrier 500 is provided may be provided alone And can be designed in various ways depending on the needs of the user or the usage purpose.

As described above, the welding torch assembly of the present invention is a useful invention that can be modified into various structures.

11,12. Gas hose 13,14. Coolant hose
20. Welding rod 100. Body housing
110. Torch ring 111. Inlet guide groove
112. Outflow side guide groove 113. Inflow side first horizontal guide hole
114. Outflow side first horizontal guide hole 120. Guide ring
121. Inlet guide hole 122. Outlet guide hole
130. Operation nut 131. Communication groove
140. Guide ring 200. Torch housing
210. Gas mixing space 220. Mixed gas supplying space
300. Nozzle 301. Electrode
310. Nozzle body 311, 312. Cooling water flow path
313. Mixed gas flow path 315,316. Cooling water communication hole
317. Gas communication hole 320. Nozzle tip
400. Connecting members 411, 412. Gas pipe
421, 422. Cooling water pipe 500. Mixing partition
510. Through hole 520. Stop ring
600. Torch cap 610. Mesh type bulkhead
621. Inlet side second horizontal guide hole 622. Outlet side second horizontal guide hole
700. Guide section 710. Through hole

Claims (8)

delete delete delete delete delete A torch housing (200) coupled to the body housing (100) and having an inner hollow body (200);
A plurality of cooling water flow paths 311 and 312 through which the cooling water flows and a mixed gas flow path for guiding the flow of the mixed gas are provided in the interior of the torch housing 200, A plurality of cooling water communication holes 315 and 316 communicating with the respective cooling water flow paths 311 and 312 radially and communicating with the mixed gas flow paths 313 and 313 are formed at the tip end thereof, A nozzle unit 300 having a plurality of gas communication holes 317 formed therein;
A guide ring 120 installed to surround the tip of the nozzle unit 300 and having a plurality of guide holes 121 and 122 communicating with the respective cooling water communication holes 315 and 316;
A guide ring 140 positioned at the tip of the guide ring 120 and guiding the flow of the mixed gas flowing through each gas communication hole 317 of the nozzle unit 300;
A plurality of guide grooves 111 and 112 which are provided to surround the guide ring 120 and communicate with the respective guide holes and first horizontal guide holes 113 and 114 communicated with the guide grooves 111 and 112 and horizontally communicated with the guide grooves 111 and 112 A torch ring 110 formed therethrough;
And a guide ring 140 installed at the tip of the torch ring 110 so as to surround the circumference of the guide ring 140 and to guide the discharge direction of the mixed gas flowing through the gas communication hole 317 and guided by the guide ring 140 A torch cap 600 through which a plurality of second horizontal guide holes 621 and 622 communicating with the respective first horizontal guide holes 113 and 114 of the torch ring 110 are inserted;
The torch cap 600 and the torch ring 110 are coupled to each other and a communication groove 131 communicating between the second horizontal guide holes 621 and 622 of the torch cap 600 is formed And a fastening nut (130). The method according to claim 6,
A mesh type gasket (not shown) is provided between the outer circumferential surface of the tip end of the nozzle unit 300 and the inner circumferential surface of the guide ring 140 so that the mixed gas flowing through the gas communicating holes 317 and flowing along the guide ring 140 is uniformly ejected. Further comprising a partition wall (610). The method according to claim 6,
The inner space of the torch housing 200 is divided into the gas mixing space 210 and the mixed gas supplying space 220 while being provided in the torch housing 200, Further comprising a mixing barrier (500). ≪ RTI ID = 0.0 > 31. < / RTI >

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