EP1121221A1

EP1121221A1 - Method for aluminothermic joint welding of two rails separated by a gap and casting mold for implementing said method

Info

Publication number: EP1121221A1
Application number: EP99970043A
Authority: EP
Inventors: Rolf Plötz
Original assignee: Individual
Current assignee: Individual
Priority date: 1998-10-06
Filing date: 1999-10-06
Publication date: 2001-08-08
Also published as: DE19981958D2; WO2000020156A1; AU1151600A

Abstract

The invention relates to a method for aluminothermic joint welding of two rails separated by a gap, wherein the steel produced in a melting pot in an aluminothermic process is cast into a casting mold consisting of at least two parts and surrounding the ends of the rails. The cavity between the ends of the rails is filled through a free space located on the head of the rail and in the risers provided in the mold part. In order to better utilize melting energy and improve melting of the ends of the rails when a two-part casting mold is used, the steel is cast through a single flow riser that is provided in one of the mold parts and connected to the head area and the base area of the casting mold while in the other mold part, steel flows out through the riser that is connected to at least the base area and to at least the head area of the casting mold.

Description

Process for the aluminothermic connection welding of two rails laid on a gap and casting mold for carrying out the process

The invention first relates to a method for the aluminothermic connection welding of two rails laid in a gap, in which the steel produced aluminothermally in a crucible is poured into an at least two-part casting mold surrounding the rail ends and the space between the rail ends while filling up a free space provided above the rail head and in the molded parts provided fillers.

From DE 196 37 283 a generic method is known in which, using a three-part mold according to FIG. 3, the molten steel from a crucible held at a distance above the casting mold onto a shaped piece in the form of a covering the rail head in the upper region of the casting mold Riegel strikes and then flows in laterally in each of the two mold halves and enters at the lower ends of the risers into the footwell of the casting mold until the space between the running surface of the rail head and the underside of the latch and the risers are filled to the appropriate level with steel . The slag also flows out of the crucible and fills the remaining volume of the mold, as well as slag trays attached to the side of the mold.

With this procedure, the melt jet loses kinetic and thermal energy at the top of the bar, which acts as an impact surface. Furthermore, in the ascending direction of flow at the rail ends, no reliable melting of the rail end surfaces can be achieved.

It is the object of the present invention to provide a generic method in which the melting energy is better utilized and the melting of the rail ends is improved.

This object is achieved in that when a two-part mold is used, the steel is poured in via a single flux riser provided in the one molded part and connected to the head space of the mold and the footwell of the mold, and in the other molded part steel is connected via at least one connected to the footwell and flows out at least one riser connected to the head space of the casting mold. Since the melt jet is introduced directly into the river riser without first hitting a bar and from there is deflected into the mold cavity, the necessary preheating energy can be reduced by applying a burner to the mold and / or the weight of the portion to be melted. By guiding the melt flows in the mold according to the invention the steel at least in the foot area and in the head area horizontally or slightly rising from the sprue side past the rail joint. In this way, the areas in the center of the foot and head that tend to cold welding can be subjected to increased heat from hot melting steel. The flow velocities or flow quantities of the transverse flows of the melt according to the invention can be set by the sizes of the assigned inlet and outlet cross sections.

It is preferably provided that steel flows out of the head space via two risers.

In the process according to DE 196 37 283, a head alloy is provided in that the hardness-forming alloy additives are alloyed over the bar in the casting mold. From the description it can be seen that there is at least an inherently undesirable alloying of the web. If the welding in the head part is to be alloyed in the present procedure, the cross-flow in the head part largely prevents the web from alloying, since excess alloy material is discharged into the head climber (s). The hardness-forming alloy additives can be arranged in the inlet to the head, in the head space itself and / or in the free space above the head.

Under certain circumstances, it is advisable to add toughness-giving inoculants to the weld in the foot part and, if necessary, the web part, the inoculants being arranged in the inlet and / or in the footwell and / or web space of the mold.

Finally, it is expedient for the steel to flow into the pedestrian in a closed stream from a crucible placed positively on the casting mold, since higher flow rates and an additional energy gain can be expected by extending the closed casting column into the crucible.

The invention is also directed to a casting mold for carrying out the method.

According to the invention, this is characterized in that, in the case of a two-part casting mold, a single footstool formed in one molded part is connected via a channel to the head space of the casting mold and via a channel at least to the footwell and in the other molded part at least the footwell is connected to a riser and the Headspace are connected to at least one other riser.

Claim 7 is directed to a preferred embodiment of the casting mold according to the invention.

The different cross-sections of the rail head and rail foot play a particularly important role in the connection welding of rails, since the steel filling the casting cavity in the region of the rail foot cools faster than the steel in the region of the rail head. This can lead to different microstructures in the two areas of the joint weld; the risk of void formation is possible.

Claims 8-10 are directed to preferred molds in which these problems essentially do not occur.

Furthermore, it is provided in a preferred embodiment that the feeder chambers are assigned a feeder channel designed as a knife gate, which essentially covers the entire foot and the transition radius from foot to web. In this way it is avoided that, particularly in the case of larger gaps in the sweat, hot cracks due to the formation of voids can occur in the center of the welding bead formed on the foot. The tendency to such a crack formation occurs to a greater extent in the radius of the transition from the foot to the web due to the so-called sand edge effect. This design of the feeder and / or riser with feeder chamber and knife gate riser can not only be used with advantage in the casting mold according to claim 1 but also e.g. in the feeders according to DE 196 37 283 C2 and other feeders or risers.

The claim 12 is directed to a casting system in which the crucible is placed on the mold in such a way that the pouring column is extended. In addition to increasing the casting speed, it is possible for the steel to flow in with the exclusion of air, which means that the steel is expected to be of high purity and less energy losses. This casting system could also be used to advantage with other types of casting molds.

The claim 13 is directed to a method in which a rapid cooling of the steel entering the free space above the rail head is achieved. The claim 14 relates to a preferred method, in which not only cooling, but also a hardening alloy of the rail head takes place. The claim 15 is directed to a correspondingly designed mold.

The invention will now be explained in more detail with reference to the accompanying figures.

It shows:

Fig. 1. a vertical section transverse to the direction of the rail through a casting mold assembled above the rails with a long-term crucible arranged at a distance from the casting mold and a suspended alloy carrier,

Fig. 2. a section corresponding to Fig.2. to show the sectional planes of the following figures. 3 - 6.

Fig. 3-6 horizontal sections according to the lines III-III Λ / I-VI in Fig. 2, Fig. 7. a supervision of the casting mold according to Fig.1. and

Fig. 8. a cut cf. Fig. 1. with a disposable crucible placed on the mold. According to Fig.1. the mold 1 consists of a first mold part 2 and a second mold part 3, which surround the rail ends to be welded. The two mold parts 2 and 3 determine a head space K assigned to the rail head, a web space S assigned to the rail web and a foot space F assigned to the rail foot, and a free space FF which adjoins the head space K at the top and is open at the top.

A flux riser 4 with an inlet funnel 5 is provided in the first casting part 2. The river riser 4 is connected to the head space K via a channel 6, preferably to the lower area thereof. The lower Inde of the river riser 4 is designed as a feed chamber 7, which is connected to the footwell F via a feed neck 8 designed as a knife gate. (see in particular Fig. 1 and Fig. 6.)

In the second mold part 3 there is a riser 9 connected to the footwell, the lower Inde of which is designed as a feeder chamber 10. The feeder chamber 10 is also connected to the footwell F via a feeder neck 11 designed as a knife gate. The volume of the feeder chamber 8 is preferably smaller than the volume of the feeder chamber 11, since the feeder chamber 10 is filled with less hot melt.

Two further risers 12 and 13 are arranged opposite one another on different sides of the riser 9 and are connected to the head space K, again preferably to the lower area thereof. As from Fig. 3-4. it can be seen that the cross section of the risers 12 and 13 is in each case preferably larger than the cross section of the head climber 9.

The mold parts 2 and 3 are provided on their top with edges 14 and 15, respectively, which the slag in Fig.1. drain to the right and left in slag pans 16 and 17.

In the casting mold part 3, an inclined guide and holding notch 18 is preferably provided, into which a tube 19 is inserted at its front section 19a with alloy additives. The front section 19a of the tube extends across the rail head in the free space FF. The middle section 19b of the tube is pressed flat and in the from the Fig.1. clearly angled. The rear pipe section 9c is not pressed flat and serves as a handling handle. The free space FF has a cross-sectional reduction at its upper inde, as shown in Fig.1. and 2. can be seen. The container for receiving the alloy carriers can also have a shape other than a tube; Cans or cans are also suitable.

Above and at a distance from the casting mold 1, a cone-like long-term crucible 20 is held, from which, after the aluminothermic mass has ignited, the melted steel and melting of the stopper 21 held in a stopper carrier, the bottom of the crucible flows into the funnel 5 in a free jet. The steel flow from the feeder chamber 7 via the footwell F to the feeder chamber 10 builds up a flow with a substantial horizontal component and / or a slightly increasing component and steel flows into the web space F. Melt rises from riser 9 in riser 9.

The steel flow from the connecting channel 6 via the head space K to the inlet openings in the ends of the risers 12 and 13 angled toward the head space builds up a cross flow with an essentially horizontal component. The free space FF is filled and melts the pipe section 19a. The cross flow impedes the diffusion of alloy material into the rail web. The risers 12 and 13 are filled up. The slag flowing in from the crucible flows into the slag dishes 16 and 17.

The flow velocities or the amounts of the transverse flows are determined by the ratio of the cross sections of the flux riser 4, the connecting channel 6, the head risers 12 and 13 on the one hand and the flux riser 4, the riser necks 8 and 10 and the riser 9 on the other hand.

In the case of Fig. 8. shown embodiment, the right mold part 2 'has a different design. The refractory material is drawn beyond the edge height and at the upper end of the flux feeder 4 'an annular or angular recess 22 is formed, into which an extension 23 of a cylindrical disposable crucible 20' placed on the casting mold 1 'engages. The pouring plug 21 'is arranged in the tubular extension. In this casting system, the casting column extends into the crucible and the steel can flow into the flux riser 4 'in the absence of air. With this arrangement, with a suitable geometry of the casting mold and crucible, the slag can remain in the crucible, since the columns forming in risers 9, 12 and 13 can hydrostatically support the lighter slag column in the crucible. The same positive engagement can also be provided in a long-term crucible. A suitable adapter piece can also be used for the coherent, tight connection between the long-term crucible or disposable crucible.

When welding hardened steel, a drop in hardness occurs in the heat-affected zone (HAZ) due to the tempering effect associated with the heat input. Therefore, if head-hardened rails are to be welded together using an aluminothermic welded joint, it is desirable to keep the heat-affected zone and thus the inevitable hardening valley as small as possible.

In the case of aluminothermic connection welding, after the cavity between the two rail ends to be connected has been filled, the molten steel causes the heat introduced to spread through heat conduction in the longitudinal direction of the rail. Since the refractory mold surrounding the rail joint can only be removed after the protruding weld bead has been sheared off, an unsatisfactory heat-affected zone and thus a large hardness valley can form in the two opposite rail ends. The welding bead can only be sheared off when the molten phase has solidified in the free space above the rail head. To freeze the molten phase in FF To withdraw arms, at least one cooling iron or heat sink 24 is inserted into the space FF above the head before filling the free space FF or even before the rails are preheated, as shown in dotted lines in the figure. The heat sink 24 extracts heat from the incoming steel, preferably melting itself. The heat sink 24, which is made of normal structural steel, for example, significantly shortens the duration of the molten phase, and it is thus possible to remove the unnecessary weld bead considerably earlier and then remove the refractory form from the weld seam. The consequence of this is a significantly reduced heat-affected zone and thus a significantly shortened hardness valley.

In the in Fig.1. In the embodiment shown, the cooling iron 24 consists of the actual heat sink 24a, a handle 24b and a support 24c. The heat sink 24a can be cylindrical or cuboid, for example. Such a cooling iron can also be used in the embodiment according to FIG. be used. A corresponding recess would then have to be provided for the support 24c in the casting mold part 2 '.

If alloy additives such as are introduced with the tube 19, the heat sink 24 must of course be arranged above the tube 19 in the free space FF.

However, it is also possible not to introduce the hardness-forming alloy additives by means of a separate alloy additive carrier such as the tube 19, but this can also be done by means of the heat sink itself, which then has the required alloy additives such as V, Cr, Ni, Ti, Nb, C, Nb, Contains Mn or mixtures thereof and releases them into the melt when it melts.

Claims

Expectations

1. Process for the aluminothermal connection welding of two rails laid in a gap, in which the steel produced aluminothermically in a crucible is poured into an at least two-part mold surrounding the rail ends and the space between the rail ends is filled by filling a free space provided above the rail head and in the molded parts Increase is filled, characterized in that when using a two-part mold, the steel is poured via a single flow riser provided in one mold part and connected to the head space of the mold and the foot space of the mold and steel is poured into the other mold part via a flow riser at least with the foot space connected and at least one riser connected to the head space of the mold flows out.

2. The method according to claim 1, characterized in that steel flows out of the head space via two risers.

3. The method according to claim 1 or 2, characterized in that the weld in the head part is alloyed by hardness-forming alloy additives.

4. The method according to at least one of claims 1 - 3, characterized in that toughness-forming vaccination additives are supplied to the weld in the foot part and, if necessary, in the web part.

5. The method according to at least one of claims 1 - 4, characterized in that the steel flows into the flow riser in a closed stream from a crucible placed positively on the casting mold.

6. Casting mold for the aluminothermal connection welding of two rails laid in a gap to carry out the method according to at least one of claims 1 - 5, characterized in that in a two-part casting mold (1; 2, 3) there is a single flow riser formed in one mold part (2). (4) is connected via a channel (6) to the head space (K) of the mold and via a channel (8) at least to the foot space (F) and in the other mold part (3) the foot space (F) is connected to a riser ( 9) and the head space (K) are connected to at least one further riser (12; 13).

7. Casting mold according to claim 6, characterized in that in the other molded part (3) two headroom risers (12.13) are each provided on different sides of the footwell riser (9).

8. Casting mold according to claim 6 or 7, characterized in that a feeder chamber (7) is provided in one mold part (2) at the lower end of the flow riser (4).

Casting mold according to at least one of claims 6 - 8, characterized in that in the one mold part (3) at the lower end of the foot climber

(9) one

Feeder chamber (10) is provided.

10. Casting mold according to at least one of claims 6 - 9, characterized in that the volume of the feeder chamber (7) of the flow riser (4) in one mold part (2) is smaller than the volume of the feeder chamber (10) in the other mold.

11. Casting mold according to at least one of claims 6 - 10, characterized in that the feed chambers (7, 10) are assigned a feeder channel (8; 11) designed as a knife cut which essentially covers the entire foot and the transition radius from foot to web

12. Welding system consisting of the casting mold according to at least one of claims 6 - 11 and a crucible, characterized in that the crucible (20; 20 ^* ) can be placed positively on the casting mold in such a way that the casting column is extended.

13. Process for the aluminothermal connection welding of two rails laid in a gap, in which the steel produced aluminothermically in a crucible is poured into an at least two-part mold surrounding the rail ends and the space between the rail ends is filled by filling a free space provided above the rail head and in the molded parts Increase is filled, in particular method according to one of claims 1 - 5, characterized in that the steel rising into the free space above the rail head is supplied with heat via at least one metallic heat sink, in particular iron or steel body, introduced into the free space, preferably by melting the metal body , is withdrawn.

14. The method according to claim 13, characterized in that hardness is formed by means of the melting heat sink

CORRECTED SHEET (RULE 91) ISA/EP Alloy additives are introduced into the rail head.

15. Casting mold according to at least one of claims 6 - 10, characterized in that at least one metallic cooling body (24), preferably a cooling iron containing hardness-forming alloy additives, is arranged in the free space (FF) above the rail head.