HU196922B - Gas deflecting nozzle for shielded-arc welding torch - Google Patents

Abstract

The nozzle discharges gas from its inner space through the opening. The nozzle material which surrounds the opening is metallic, pref. copper or iron, and is electrically insulated from the material of the rear opening. The nozzle material is internally knurled or ribbed along 5-70% of the length of the discharge opening. A rear opening is provided, coaxial with the discharge opening. The rear opening is provided with an adjuster device, such as a threaded piece.

Description

BACKGROUND OF THE INVENTION The present invention relates to a gas deflector nozzle for a shielded gas arc welding torch, which is particularly applicable to consumable electrode shielded gas arc welding equipment. The shielding gas and electrode outlet opening on the face of the gas deflector nozzle of the present invention are connected to the interior of the nozzle by a conductive bore. The nozzle interior has a gas distributor insert or gun tip end which opens at the rear of the nozzle and is centered in the center of the guide hole, which has a recessed gas distributor insert or a nozzle stopper in the position. The wall defining the leading bore of the gas deflector nozzle is made of metal, most preferably copper or iron, and this wall is electrically insulated from the side wall of the rear bore.

It is known that the primary function of the gas deflection nozzles is to provide a definite directional flow of gas from the shielding gas at the end of the arc welding gun stem or through the holes of the gas distributor mount mounted thereon, which is flushed around the electrode and Accordingly, the gas deflector nozzles are configured to have a rear bore which opens at their rear and extends into their interior and has a corresponding fixing wall design, and an electrode and shield gas outlet opening at their forehead with a central bore connecting to their interior space. During the installation of the gas deflector nozzle in the rear bore of the deflector nozzle, the end of the gun stem or the gas distributor mounted on the end thereof is introduced with or secured by a cooperative clamping joint on the outer surface of the gun tip end and the sidewall of the rear hole.

The gas deflector nozzles, when properly used, become very warm due to the heat emitted from the welding wire, the gas distributor but mainly from the electric arc, and reach a temperature equilibrium of hundreds of degrees Celsius. If the electric arc is closer to any part of the gas deflector nozzle, for example, while holding the welding torch where the electric arc occupies an acute angle with the center line of the gas deflector nozzle, the heat load of the nozzle portion of the gas deflector nozzle becomes uneven. As a result, the exposed portion of the gas deflector nozzle may be deformed, often heated to such a high temperature that the nasal portion melts and drips, thereby rendering the gas deflector nozzle unusable for its intended function. Because welding tasks require the welding torch to be held in a variety of situations, gas deflector nozzles have a relatively short lifetime.

The known solutions seek to increase the life span of the gas deflector nozzles by various cooling solutions, which are closely related to the design of arc welding guns. For example, 321686 is incorporated herein by reference. In the solution described in Patent No. T, cooling water passages are also provided in the bow portion of the arc welding gun, thereby reducing the rate of warming of the gas deflector nozzle by separately cooling the bow portion. No. 370,019. In the solution disclosed in T patent, the gas deflector nozzle is provided with a heat insulating liner.

Commonly used gas deflector nozzles are designed to have an internal threaded sleeve of copper or iron material which, by inserting a heat-resistant and electrically insulating insert on its sheath, is tightly coupled to a deflector nozzle of good thermal conductivity such as copper or iron. nickel plated tube. Such gas deflector nozzles are capable of delivering heat only by radiation to the environment and by convection to a shielding gas flowing through the conductor bore, typically in the range of 5 to 10 dmV / min. However, these two types of heat dissipation allow only a relatively small amount of heat to be transported overall, and are proven by the short life of the gas deflector nozzles.

In addition, a gas equilibrium nozzle at the lowest possible temperature is also desirable in the event of accidental contact: the damage caused is minimized.

so it became our job cg]? seeking a solution that results in the gas deflector nozzle having an equilibrium temperature set as low as possible during welding. It is a further task to find a solution that does not require the modification of the known and rotary arc welding torch to achieve the former purpose.

The invention is based on the idea that the amount of heat that can be removed from the gas deflector nozzles can only be increased by increasing the amount of heat transported by the shielding gas while maintaining the design of the arc welding guns.

The present invention is based on the discovery that while maintaining a shielding gas current of the usual gas deflector nozzle, the heat transfer rate can be increased by increasing the turbulence of the shielding gas current flowing through the guiding hole of the deflector nozzle, typically up to 5-10 l / pcrc. the desired shielding gas sheath. Increasing turbulence can be solved by properly designing the side of the outlet bore.

Thus, the shielding gas and electrode outlet of the gas deflector nozzle of the present invention for use with a gas deflector nozzle, in particular a consumable electrode arc welding torch, are connected via a centerline bore that fits into the center line of the guide bore, the rear bore being provided with a side wall clip, such as a thread, for securing the guiding hole in an inserted position to the inserted gas distributor insert or pistol end, wherein the guide bore sidewall material is metal, mainly copper or iron; isolated from the side wall. The point of the gas deflector nozzle is that the sidewall of the guide bore has a roughened surface, in particular rusted or ribbed surface, in the range of 5 to 70% of the length of the guide bore.

In a preferred embodiment of the gas deflector nozzle, at least one section of the guide bore tapers in the direction of the outlet opening.

In the gas deflector nozzle of the present invention, the characteristics and extent of the roughened, predominantly knurled or ribbed surface of the conductor bore depend on the diameter, length, and optionally taper of the conductor bore. Thus, in the case of shorter gas inlet nozzles having a larger diameter bore, the roughened surface has a greater wavelength at a distance shorter from the outlet on the front face, while for gas jets with a smaller diameter bore, the roughened surface at the outlet and it is designed with a lower wave height. If the guide bore of the gas deflector nozzle has a tapered design in the direction of the front face, the roughened surface is preferably in the tapered section of the guide bore.

In a further preferred embodiment of the gas deflector nozzle, the groove or rib direction of the knurled or ribbed surface is at an acute angle. The roughened surface shall have a wave height of at least 0.1 mm.

A very preferred embodiment of the gas deflector nozzle according to the invention has a tapered tapering at its front end and a tubular body with an insulating insert at its rear end and an internal threaded sleeve fixed in position in this insulating insert.

The main advantage of the gas deflector nozzle according to the invention is that, due to its design, it can be cooled or cooled. Cooling is increased compared to conventional gas deflector nozzles. As a result, the gas balance nozzle of the present invention can be brought to a temperature substantially lower than the conventional nozzle temperature at which the nozzle has a long life, even when welding continuously with a conventional amount of shielding gas. This is explained by the fact that in the shielding gas entering the interior of the gas deflector nozzle perpendicular to the centerline of the nozzle and in a directional current in the guiding bore, the roughened surface of the guiding bore increases the turbulent boundary layer in which the it is capable of delivering heat, as in the case of gas deflector nozzles with conventional smooth bore walls. In addition to increasing turbulence, the roughened surface also provides an increased surface, which also increases the amount of heat that can be transported.

BRIEF DESCRIPTION OF THE PREFERRED EMBODIMENT The present invention will now be described in more detail with reference to a preferred embodiment, with reference to the accompanying drawings, in which the figure illustrates a half sectional side view of a gas deflector nozzle according to the present invention for use with a consumable electrode arc welding gun.

As shown in the figure, the nose portion of the consumable electrode arc welding gun fitting to this embodiment of the gas deflector nozzle is such that a gas distributor 30 having a longitudinal hole and a locking nut 30 with a longitudinally bore a contact nozzle 34 having a through hole 39 in the electrode conductor is fixed to the front portion by a threaded connection. The welding wire guide spiral (not shown in the drawing) extends from the torch end 37 to a shoulder formed inside the insert 30, the welding wire also extending through the insert piece 34 and extending through the insert piece and the shielding gas exiting through the bore of the gun stem dispenser 37 into the interior of the gas distributor insert 30, which exits through openings 31, 32 in its sidewall, as illustrated by arrows.

The gas deflector nozzle 10 has an interior space 23 which extends spaced apart between the gas distributor portion 30 and the apertures 31, 32. The inner space 23 is connected by a shielding gas and electrode outlet opening at the nozzle front face 10 to the front of the gas distributor insert 30 and a guide bore 18 which includes an annular space with the contact nozzle 34. The inner bore 23 has a center bore 28, which is centered with the leading bore 18 and opens at the rear of the nozzle 10, through which the gas distributor insert 30 is introduced into the interior space 23 of the nozzle 10.

The gas distributor is provided with a thread at the rear of its casing 30 which engages a thread 29 in the sidewall 28 of the bore 28 of the nozzle 10, which threaded connection secures the nozzle 10 to the nozzle tip 37.

The guide bore 18 is tapered in a direction in the direction of the outlet through a funnel. The side wall 19 of this narrowing bore section has a surface 20 having a length of 20% of the length of the bore, which is grooved. At the cut surface 20, the groove has a corrugation height of 0.4 mm and the groove direction of the groove forms an acute angle with the centerline of the bore 18.

The side wall 19 defining the guide lumen 18 of the nozzle 10 is the wall of the body 12 of the nozzle 10 made of copper. The rear bore 28 is a sleeve bore 14 which is secured to the rear end of the tubular body 12 by inserting a sleeve insulating sleeve 13 in vinyl 14.

The isolation of the gas deflector nozzle body 12 from the galvanically connected welding potential 37, the gas distributor insert 30 and the contact nozzle 34 at the contact area and the sealing member 36 over the sealing member 36 provided by an annular space.

The increased coolability of the gas deflector nozzle 10 is provided by the ratchet surface 20. The turbulence of the shielding gas exiting the insert 30 and exiting the interior 23 through the conductive bore 18 is increased by the knurled surface 20. Thus, the shielding gas, on the one hand, has a 3

The increase in 196,922, on the other hand, due to the increased heat transfer surface, is capable of cooling the gas deflector nozzles of the present invention to a greater extent than a conventional gas deflector nozzle.

Claims (5)

Claims A gas deflector nozzle (10) for a shielded gas arc welding torch having a shield gas and electrode outlet at its front end connected via a guide bore (18) to the interior space (23) of the nozzle (10) and a gas distributor insert or insert a central bore (28) which opens at the rear of the nozzle (10) and is centered on the center line of the guide bore (18) and which is provided with a side wall design for securing an inserted gas distributor insert or gun end in an inserted position; wherein the side wall (19) delimiting the guide bore (18) is made of metal, most preferably copper or iron, and this delimiter side wall (19) is electrically insulated from the side wall of the rear bore (28), 19) roughened in the range of 5 to 70% of the length of the guide bore (18), mainly rusted or ribbed has a surface (20). g Gas deflector nozzle (10) according to claim 1, characterized in that at least one section of the guide bore (18) is tapered in the direction of the outlet opening. Gas deflector nozzle (10) according to claim 1 or 2, characterized in that the groove or rib direction of the knurled or ribbed surface (20) closes at an acute angle with the center line of the guide bore (18). 4. A gas diverting nozzle (10) according to any one of claims 1 to 4, characterized in that said rough surface _1E has a ripple height of at least 0.1 mm. 5. A gas discharge nozzle according to any one of claims 1 to 6, characterized in that it has a tubular body (12) with a tapered tapering at its front end and an insulating insert (13) at its rear end and an internal threaded sleeve (14) fixed in position within this insulating insert (13).