DE1203893B - Electro-slag welding process and application of this process - Google Patents

Description

Electro-slag welding process and application of this process There is a difficulty in electro-slag welding, even in the variant of the channel welding that the workpiece parts not only during welding, but also shrink strongly when cooling down after welding. Because the degree of shrinkage depends on many factors and is therefore not exactly predictable, is a dimensionally accurate welding by this method has hardly been possible up to now.

Attempts have been made to cut the workpiece parts through during welding strong welded brackets in the desired position to each other, but has It turned out that the strong tensions that occur cannot be controlled are. In addition, this measure is associated with considerable costs.

In the case of the channel welding variant, it must also be ensured that that the melting wire guide in the desired position in the welding gap during the entire welding process remains. When changing the gap width due to shrinkage this also runs into difficulties with the isolated ones previously proposed Wire supports.

In the method of electro-slag welding according to the invention with a melting wire guide, all of these disadvantages are completely avoided. It consists in the fact that a consumable wire guide is used to feed the welding wire of such a shape is used that it covers the major part of the joint cross-section fills in that the workpiece flanks are in contact with the melting wire guide and that the melting wire guide at least in those areas in which there is contact with the workpiece or the jaws forming the seam or could take place, is provided with an electrically insulating layer.

It is advisable to use a ceramic coating as the insulating layer to use from such a material that when the wire guide melts in the liquid slag is absorbed and thereby the welding properties of the slag not significantly deteriorated.

It is advantageous, for example, to use one as the insulating layer Spray applied coating of aluminum oxide (A1203), titanium dioxide (Ti02) or Manganese oxide (MnO) or a z. B. prepared by immersion coating of solidified To use slag.

Experiments have shown it to be beneficial that the applied Aluminum oxide coating between 0.1 and 3 mm, preferably between 0.3 and 0.5 mm, is thick.

The method according to the invention allows the workpiece parts to be fixed to put on the melting wire guide without the risk of a short circuit exists between the melting wire guide and the workpiece. The initiated Electro-slag welding process runs absolutely smoothly and. perfect. the rising slag melts the wire guide as the welding process progresses and remove the layer of aluminum oxide. Since the melting point of the steel from which the melting wire guide exists, is considerably lower than the melting point of the aluminum oxide, the melting wire guide is always slightly shorter than the insulating layer of aluminum oxide. The surprising effect therefore occurs one that the thick, forming on the melting wire guide drops despite The very thin aluminum oxide layer prevents short circuits with the workpiece parts which would interfere with the welding process and even make it impossible, because the short-circuit bridges evaporate explosively due to the high short-circuit currents and would throw the slag out of the joint.

Another advantage of the method according to the invention is to be seen that the welding speed compared to the previously known procedure quite increases significantly. When welding a T-joint on 50 mm thick sheets, for example with the previously known channel welding a welding speed of 0.67 m / h achieved when a tube with a diameter of 15 mm and as the melting wire guide 600 A current were used. With the method according to the invention can not only reduce the air gap between the sheets considerably, so that less weld metal is required, but the cross-section of the melting wire guide and: thus the weight of the weld metal melted off per unit of time is significantly greater, so that the welding speed to 1.5 in / h, i.e. to well over double, was enlarged.

However, the main advantage of the method of the invention is therein to see that at any point in time the not yet melted off piece of the melted off Wire guide between .den workpiece parts and in this way the shrinkage completely prevented. While according to the previously known method, for example T-joint shrinkages of up to 17 mm across the seam were measured, the shrinkage remained when welding according to the method according to the invention with otherwise identical conditions less than 1 mm.

The method according to the invention can also be used to advantage in order to produce the alloy of the material to be welded in the weld seam, that the melting wire guide and the supplied welding wire from different Alloys exist in such a way that the mixture ratio of both in the Seam gives the composition of the material to be welded. This application opens, for example, a completely new, surprising and very economical one Possibility of machine welding of gray cast iron.

The machine hot welding of gray cast iron has so far failed because that gray cast iron rods had to be used as additional material, which were not on reels could be wound up and welded by an automatic machine. The inventive However, the method can be used for welding gray cast iron in such a way that as a melting wire guide a gray cast iron with increased carbon content and as Welding wire a normal carbon steel can be used, so that the weld metal receives a carbon content which corresponds to the composition of the to be welded Gray cast iron. The usual heating of the workpiece can be used in many cases can be omitted because the slag often has enough heat in it Workpiece supplies.

The invention is to be explained in more detail by means of examples.

In A b b. 1 is a cross-section through a seam drawn according to the method according to the invention is welded. 1 and 2 are the two to be connected Workpiece parts, 3 and 4 the two copper jaws forming the seam, which are located in in this case extend over the entire length of the seam. The two workpiece parts 1 and 2 rest on the melting wire guide 5 and are from this through the Separate insulating layers 6 and 7 made of sprayed-on aluminum oxide. The welding wire 8 is fed through the hole 9 in the melting wire guide 5 to the welding point. A b b. 2 shows a section through the weld. 1 and 2 are the two again Workpiece parts with the melting wire guide 5 clamped in between, in which the welding wire 8 enters at the top and exits at the bottom. The slag bath 10 extends to to the melting wire guide 5 and melts this as it progresses Upward movement continues to decrease. The insulating layers 6 and 7 between the consumable Wire guide 5 and the workpiece parts 1 and 2 are slightly above the lower edge the melting wire guide 5 and thereby prevent short circuits of drops, which are about to be released from the melting wire guide with the workpiece parts 1 and 2. 11 is an already finished piece of seam and 12 is the metallic weld pool.

In A b b. 3 is the application of the method according to the invention at a T-joint. The digits have the same meaning as in A b b. 1.

Finally, A b shows b. 4 the application of the method according to the invention with a cross strike. 13 to 16 are the four sheets to be connected, 17 to 20 are the pieces of copper forming the seam. The sheets 13 to 16 are on the melting point Wire guide 5, which in this case all around from the aluminum oxide existing Insulating layer 21 is surrounded. The welding wire 8 is through the hole 9 in the consumable Wire guide 5 advanced.

Claims (5)

Claims: 1. Method for electro-slag welding with consumable Wire guidance, especially in the variant of duct welding, which is marked by that for feeding the welding wire to the welding point a melting wire guide of such a shape is used that it covers the major part of the joint cross-section fills in that the workpiece flanks are in contact with the melting wire guide and that the melting wire guide at least in those areas in which there is contact with the workpiece or the jaws forming the seam or could take place, is provided with an electrically insulating layer. 2. The method according to claim 1, characterized in that as an insulating layer a ceramic coating made of such a material is used when the Wire guide is absorbed into the liquid slag and thereby the welding properties the slag does not deteriorate significantly. 3. The method according to claim 1 and 2, characterized in that an insulating layer, for example, by Spray applied coating of aluminum oxide (A120,), titanium dioxide (TiO2) or Manganese oxide (MnO) or a z. B. produced by immersion coating of solidified Slag is used. 4. The method according to claim 1 to 3, characterized in that the applied coating of aluminum oxide 0.1 to 3 mm, preferably 0.3 to 0.5 mm thick. 5. Application of the method according to claim 1 to 4, characterized in that that when welding gray cast iron the melting point Wire guide off a gray cast iron with increased. Carbon content and used as a welding wire Wire made from a normal carbon steel is used, making the weld metal contains a carbon content which corresponds to the composition of the material to be welded Gray cast iron. Documents considered: Fusion Welding, 1930, Pages 183 to 187.