DE10006630C1 - Rotary transmission leadthrough used for introducing and removing liquid coolant onto a transport roller in a roller hearth furnace has coolant lines fixed to a tensioning plate on which a two way guide is fixed - Google Patents

Abstract

Rotary transmission leadthrough has coolant lines (1, 2) fixed to a tensioning plate (3) on which a two way guide (6) is fixed. The two way guide is connected to the coolant lines and with inclusion of a compensator (9) via a plug-in connector (10) to the coolant channels (15, 18). Preferred Features: The two way guide is detachedly fixed to the tensioning plate via a quick catch lever (5). The tensioning plate has a guiding rail along which the two way guide can travel.

Description

The invention relates to a rotating union for the and draining liquid coolant through a One end bearing journal on this and one additional bearing pivoted roller, especially a transport roller of a roller hearth furnace, with coolant channels running axially in the roll, via a fixed two-way guide with fixed, connected to a coolant supply network Coolant lines are connected, between which a journal and the two-way guide an axial and Tilting movements of a bearing journal Compensator device is arranged.

A rotary union of this type is, for example, out DE 197 52 336 C1 known. At this level the Technology are the coolant lines through which the Coolant, especially cooling water, of the rotating union is fed in or discharged from it as stationary standpipes educated. These are in plug-in receptacles stationary cover plate, which is fixed with a bearing block is connected to the bearing journal with a roller bearing is stored. The cover plate serves to encapsulate the entire rotating union. Through them the end is Roll formed a sealing space in which the bearing journal protrudes, so that possibly from the end Coolant escaping from the bearing journal Sealing space can emerge. In addition, the Cover plate designed as a two-way guide, by means of  the coolant through and separate channels of the role is dissipated by her. There are two coaxial tubes for this provided that leading away from the cover plate in the Bearing journal axially running coolant channels are plugged in. It is in the bearing journal inserted part of the outer tube as Compensator device for axial and tilting movements of the Bearing pin and at the same time as a seal outer axially extending coolant channel to the Formed sealing chamber. This as a torsionally rigid, length-flexible and flexible hose Part of the outer tube takes relative axial and Tilting movements between the stationary cover plate and the movable bearing journal.

To replace one with one Equipped roller it is necessary that the cover plate is unscrewed from the bearing block and then pulling it out into the trunnion leading pipes from the journal is removed before the roller is pulled out of the pedestal. This Setting up a rotating union therefore requires several time consuming disassembly and assembly steps during of exchanging a role.

In the field of use of such rotary unions However, there are use cases in which the Replacement of a role must be done very quickly. This is z. B. the case when at a Thin slab caster such rolls in one Roller hearth furnace are arranged. To be a continuous To ensure operation of the system, the Role change in the between casting and again Start of casting time available, the so-called Pouring break. The time-limited change of the  Role can with the known and described in more detail Construction of the rotating union cannot be carried out.

The invention is therefore based on the object To create a rotating union of the type mentioned at the beginning, that can be disassembled and reassembled more quickly than the well-known rotary union.

The task is at the turn of the beginning described type solved in that the Coolant lines firmly to a clamping plate are connected, on the two-way guide such can be fastened that the two-way guide with the Coolant lines and including the Compensator device in the one journal plug-in connector with the coolant channels connected is.

The rotary union according to the invention sees as an axial and allow tilting movements of the trunnion Rotating union with a stationary on a clamping plate Coolant lines attachable two-way guide mechanically by the compensator device Bearing journal is decoupled, but with line technology its coolant channels is connected. That's why it is for dismantling the rotary union according to the invention now only necessary, the two-way guidance from the Loosen the clamping plate and the plug connection from the Pull out coolant channels. This implies Another reason is that the dismantling of the Rotary union, since in the invention Turning on the elaborate measures for Densities provided in the prior art Sealing chamber can be dispensed with. Sealing the  Coolant channels of the one bearing journal take place at the end via the plug connection.

The necessary for the sealing effect of the connector Axial alignment of the connector with the in the role of axially extending coolant channels achieved in that the two-way guide firmly attached to the Clamping plate is connected, which in turn is firmly attached to the stationary coolant lines is connected. Thus by attaching the connector Two-way guide on the clamping plate ensures that the two-way guide always has the same relative position takes to the journal, whereby it is achieved that the plug connection axially with the bearing journal is aligned.

Another simplification of disassembly and assembly a role is achieved in that the journal on Bearing rollers supported and on by a holding element this is held. This enables that on the Disassembly of one provided in the prior art rolling bearing attached to the end of the bearing journal can be dispensed with. It must be dismantled from the role only the holding element can be solved, whereupon the Pull the bearing pin down from the two bearing rollers can be.

The detachable connection between the two-way guide and the clamping plate is preferably a Quick release lever mechanism reached. By the Two-way guidance via quick release lever on the Clamping plate is attached, it will be used during the Operating safely and firmly held on the clamping plate and, connected to the coolant lines in a sealing manner, while on the other they can be dismantled quickly by loosening  the quick release lever can be released from the clamping plate can.

To the axial alignment of the connector relative to adjust the coolant channels in a simple way can, the clamping plate can be a guide rail have, along which the two-way guide is movable. With this guide rail ensures that the connector is always accurate experienced axial alignment relative to the journal.

In a preferred embodiment of the invention, the Plug connection have two concentric tubes, by which the inner tube with one end in one Coupling of the central coolant channel of the axial extending coolant channels can be inserted and with its other end is connected to the two-way guide and of which the outer tube as a guide tube with its one end in a centering bushing of another Coolant channel is insertable and with its other End over a compensator of the compensator device is connected to the two-way guide. According to this preferred embodiment, the connector consists of two pipes, the inner pipe of which, for example Coolant discharge and its outer tube, for example the coolant supply can serve. The inner tube is then in the central axially running in the role Coolant channel inserted, which is the return of the Coolant is used within the roll. The outer tube in this case is axial with the one in the roll extending coolant channel connected to the supply and distribution of the coolant within the role.

The outer tube is in the preferred embodiment Invention designed as a guide tube that serve  should, the connector in the bearing end introduce and insert.

There is regular transport rollers in roller hearth furnaces the problem that the role due to the Expands heat and due to the Weight load caused by the roll Material is bent so that the end arranged bearing journal from its horizontal extending orientation is tilted. The axial and Tilting movement of the bearing journal is carried out by a Compensator device added so that they are not on the fixed two-way tour is passed on. Otherwise, stress or deformation of the stationary two-way guidance.

In the preferred embodiment of the The invention is the compensator device as a compensator formed with the outer tube of the connector the two-way guide connects. That in the bearing journal inserted outer tube comes with the bearing pin its thermal expansion shifted and tilted. This Relative movement of the outer tube is however caused by the Compensator added and not to the two-way guide passed on.

According to a first embodiment, the compensator is as corrugated circular disc formed, the outer edge with the two-way guide and its inner edge with the Guide tube is connected.

According to a second embodiment of the compensator this is tubular and corrugated and with two pipes connected, the first of which is external Guide tube is inserted in the bearing pin and that  second tube as a connection between the compensator and serves as a two-way guide.

The centering bush into which the guide tube of the Plug connection is inserted, preferably consists of a wrought copper alloy. Wrought copper alloys are inexpensive to manufacture and also have a low coefficient of friction, so that Guide tube into the centering bushing easily and without abrasion can be inserted.

To prevent the coolant from escaping from the journal prevent, the centering bush seals the axial Coolant channel both at the end and opposite Guide tube. The seal against that Guide tube is preferably achieved in that the inner circumference of the centering bush on the A sealing ring in the face facing the inside of the roller a groove intended for this is inserted. This Sealing ring can, for example, from one against the Front face of the centering bush facing the inside of the roller screwed retaining ring held and pressed into the groove is.

The present invention is based on a two embodiments illustrating the drawing explained. In detail show:

Fig. 1 a rotary duct in a partially sectioned side view,

Fig. 2 shows another rotary union in a partially sectioned side view

Fig. 3 shows the rotary union of FIG. 2 in an end view.

Fig. 1 shows two coolant lines 1, 2 to the coolant supply respectively -abfuhr a coolant supply system, not shown. The coolant lines 1 , 2 are each firmly connected to a clamping plate 3 . The clamping plate 3 is fixedly connected to a base plate 4 .

A two-way guide 6 is firmly clamped on the clamping plate 3 via a clamping lever 5 . As a result, channels 7 , 8 provided separately in the two-way guide 6 are each connected to one of the coolant lines 1 , 2 . The two-way guide 6 , including a compensator device 9, is connected at the end via a plug connection 10 to a bearing journal 11 , with which and a further bearing journal a transport roller of a roller hearth furnace, which is only partially shown, is rotatably supported at the end.

The plug connection 10 consists of an inner tube 12 and an outer tube, referred to as the guide tube 13 . The inner tube 12 is connected within the two-way guide 6 to the channel 8 provided therein. On the side of the bearing pin 11 , the inner tube 12 is inserted into a coupling piece 14 of a coolant channel 15 which is guided centrally and axially in the bearing pin 11 .

The guide tube 13 is connected to the side of the two-way guide 6 via a compensator 16 designed as a corrugated annular disc of the compensator device 9 with the two-way guide 6 and connected tightly to the channel 7 by its inner edge against a collar 13 a of the guide tube 13 and with its outer periphery is externally connected close to an outgoing from the channel 7 a radial flange 6 of the two-way guide. 6 The radial flange 6 a carries on the side of the bearing pin 11 a cover 6 b, which engages behind the collar 13 a, so that it acts on the one hand as a driver when pulling out the guide tube 13 and on the other hand, together with the radial flange 13 a, a protective housing for the compensator 16 forms.

On the side of the bearing pin 11 , the guide tube 13 is inserted into a centering bushing 17 screwed to the end of the bearing pin 11 . The centering bushing 17 closes at the end of the bearing pin 11 a coolant channel 18 that runs axially in the bearing pin 11 and is arranged coaxially to the coolant channel 15 . For this purpose, a groove 19 is provided on the inner circumference of the centering bushing 17 , in which sits a sealing ring 20 which is held in the groove 19 by a retaining ring 21 screwed to the centering bushing 17 .

The bearing pin 11 is rotatably supported on two parallel bearing rollers 22 and is held on the bearing rollers 22 by a releasable bracket (not shown) which overlaps it from above.

Fig. 2 shows a further embodiment of the rotary union. This differs from the first embodiment shown in FIG. 1 only in the shape and arrangement of the compensator device, so that only the special construction of this compensator device is to be dealt with while maintaining the same reference numbers for the same components to avoid repetition.

The connector 10 shown in Fig. 2 consists of an inner tube 12 and an outer guide tube 13 , which consists of a front tube 24 and a rear tube 25 . Both tubes 24 , 25 are connected to one another via a corrugated, tubular compensator 26 , the two ends of which are tightly connected to collars 24 a, 25 a of tubes 24 , 25 . The compensator 26 is surrounded by a sleeve 26 a serving as a protective housing and driver, which engages behind the collars 24 a, 25 a. At one end, the sleeve 26 a is attached to the front tube 24 . It can be composed of half shells. The front tube 24 is inserted into the centering bushing 17 of the bearing pin 11 . The rear tube 25 is connected to the two-way guide 6 .

In Fig. 3 it can be seen that and how the coolant line 2 is firmly and tightly connected to the clamping plate 3 . It is also shown that the two-way guide 6 is axially displaceably guided in a guide rail 27 to the bearing journal. It can be seen more precisely that seals 28 are provided between the two-way guide 6 and the clamping plate 3 , which enable a tight connection between the coolant line 2 and the channel 8 . Likewise, the coolant line 1 (not shown in FIG. 3 ) is connected to the channel 7 in this way.

The two-way guide 6 has hooks 29 on each side, into which the eyelets of the clamping levers 5 each engage in order to firmly clamp the two-way guide 6 on the clamping plate 3 .

To cool the roller, not shown, heated together with the bearing journal 11 by the hot material rolling on it, coolant is introduced from the coolant supply network, not shown, via the rotary leadthrough into the coolant channel 18 running axially in the bearing journal 11 , from which the coolant flows into several in the not intended role, not shown channels is distributed. The heated coolant is collected via the coolant channel 15 running axially in the center of the bearing journal 11 and discharged via the rotary feedthrough and the coolant line 2 .

Within the rotating union, the coolant is introduced from the coolant line 1 into the channel 7 and from there via the guide tube 13 into the coolant channel 18 . The coolant to be discharged is introduced via the inner tube 12 into the channel 8 of the two-way guide 6 and from this channel 8 into the coolant line 2 .

If the bearing journal 11 expands axially due to thermal expansion, this expansion of the bearing journal 11 is partially compensated for by a relative displacement of the centering bushing 17 relative to the guide tube 13 . Above all, however, the compensator 16 or 26 of the compensator device 9 can absorb part of the axial displacement. The inner tube 12 can move axially in the coupling piece 14 .

If the bearing pin 11 is tilted about its central axis by bending the roller, this tilting movement is transmitted to the guide tube 13 guided in the centering bushing 17 . However, the tilting movement is absorbed by the compensator 16 or 26 of the compensator device 9 , so that it is not transmitted to the two-way guide 6 . The limited flexible inner tube 12 also takes up the tilting movement. This ensures that no voltages are transmitted to the two-way guide 6 , which could influence the secure and firm hold of the two-way guide 6 on the clamping plate 3 caused by the tensioning lever 5 .

In the operating condition of the bearing pin 11, the coupling piece 14, the inner coolant channel 15 and the centering sleeve 17 with the roller rotate, while the inner tube 12 and the guide tube in a rotationally fixed 13 of the plug connection are connected to the fixed two-way guide. 6

To replace the roller and the necessary disassembly of the rotary union, the clamping levers 5 are released so that the fixed connection between the two-way guide 6 and the clamping plate 3 is released. The two-way guide 6 is then pulled away from the bearing journal in the axial direction, the plug connection 10 being pulled out of the bearing journal 11 . Then the bracket, not shown, which holds the bearing pin 11 on the bearing rollers 22 , is released so that the bearing pin 11 can be pulled axially down from the bearing rollers 22 and - in a roller hearth furnace - the roller can be pulled out axially with a manipulator acting on the other bearing pin can.

To assemble a new roller, the roller is pushed with its bearing pin 11 onto the bearing rollers 22 and held there with the bracket, not shown. The two-way guide 6 with its plug connection 10 is then inserted into the bearing journal 11 at the end and clamped firmly on the clamping plate 3 by means of the clamping lever 5 .

With the rotary union shown, one is also with quick disassembly to be carried out in a few assembly steps and assembly of the rotating union and one with it associated rapid change of role possible.

Claims (11)

1. Rotary feedthrough for the introduction and discharge of liquid coolant via a bearing journal ( 11 ) on a roller rotatably mounted at the end of this and a further journal, in particular a transport roller of a roller hearth furnace, with coolant channels ( 15 , 18 ) running axially in the roller, which are connected via a fixed two-way guide ( 6 ) to fixed coolant lines ( 1 , 2 ) connected to a coolant supply network, axial and tilting movements of the one bearing pin ( 11 ) permitting between the one bearing journal ( 11 ) and the two-way guide ( 6 ) Compensator device ( 9 ) is arranged, characterized in that the coolant lines ( 1 , 2 ) are firmly connected to a clamping plate ( 3 ) on which the two-way guide ( 6 ) can be fastened such that the two-way guide ( 6 ) with the coolant lines ( 1 , 2 ) and including the compensator device ( 9 ) in one position rzapfen ( 11 ) plug-in connector ( 10 ) is connected to the coolant channels ( 15 , 18 ). 2. Rotary feedthrough according to claim 1, characterized in that the bearing journal ( 11 ) is supported on bearing rollers ( 22 ) and is held thereon by a holding element. 3. Rotary union according to claim 1 or 2, characterized in that the two-way guide ( 6 ) via quick release lever ( 5 ) is releasably attachable to the clamping plate ( 3 ). 4. Rotary feedthrough according to one of claims 1 to 3, characterized in that the clamping plate ( 3 ) has a guide rail ( 27 ) along which the two-way guide ( 6 ) is slidably guided. 5. Rotary union according to one of claims 1 to 4, characterized in that the plug connection ( 10 ) has two concentric tubes ( 12 , 13 ), of which the inner tube ( 12 ) with one end in a coupling piece ( 14 ) of the central Coolant channel ( 15 ) of the axially extending coolant channels ( 15 , 18 ) can be inserted and is connected at its other end to the two-way guide ( 6 ) and of which the outer tube as a guide tube ( 13 ) has one end in a centering bushing ( 17 ) A further coolant channel ( 18 ) can be inserted and its other end is connected to the two-way guide ( 6 ) via a compensator ( 16 , 26 ) of the compensator device ( 9 ). 6. Rotary union according to claim 5, characterized in that the compensator ( 16 ) is a corrugated annular disc, the outer edge of which is connected to the two-way guide ( 6 ) and the inner edge of which is connected to the guide tube ( 13 ). 7. Rotary feedthrough according to claim 5, characterized in that the guide tube ( 13 ) consists of two tubes ( 24 , 25 ) which are connected to one another via a tubular, corrugated compensator ( 26 ), the first tube ( 24 ) at its the End facing away from the compensator ( 26 ) can be inserted into the centering bushing ( 17 ) and the second tube ( 25 ) is connected at its end facing away from the compensator ( 26 ) to the two-way guide ( 6 ). 8. Rotary union according to one of claims 5 to 7, characterized in that the centering bush ( 17 ) consists of a wrought copper alloy. 9. Rotary feedthrough according to one of claims 5 to 8, characterized in that the centering bush ( 17 ) seals the axial coolant channel ( 18 ) both at the end and with respect to the guide tube ( 13 ). 10. Rotary union according to claim 9, characterized in that on the inner circumference of the centering bushing ( 17 ) on its end facing the inside of the roller, a sealing ring ( 20 ) is inserted into a groove ( 19 ) provided therefor. 11. Rotary feedthrough according to claim 10, characterized in that the sealing ring ( 20 ) is held by a retaining ring ( 21 ) screwed against the end face of the centering bushing ( 17 ) facing the inside of the roller and is pressed into the groove ( 19 ).