DEVICE FOR COUPLING A COOLANT SUPPLY TO A ROLL

Abstract

Device (1) for coupling a coolant supply and/or coolant drainage to a roll (2), especially in a continuous casting installation, wherein the roll (2) comprises a journal (3), which is mounted rotatably in a bearing block (4), and a lateral recess, extending in the axial direction, and at least one roll cooling channel, through which a coolant can pass, wherein the device (1) comprises: at least one coolant channel (11, 12), which can be brought into fluidic connection with the roll cooling channel on the journal (3) side; and a sealing unit for sealing the fluidic connection between the coolant channel and the roll cooling channel, comprising an inner module and an outer module; wherein the inner module comprises a hollow cylindrical element (7), which can be inserted into the lateral recess of the journal (3), characterized in that the hollow cylindrical element (7) has no flange on the outer side of the journal, looking in the axial direction.

Claims

1. A device (1) for coupling a coolant supply and/or coolant drainage to a roll (2), especially in a continuous casting installation, wherein the roll (2) comprises a journal (3), which is mounted rotatably in a bearing block (4), and a lateral recess, extending in the axial direction, and at least one roll cooling channel, through which a coolant can pass, wherein the device (1) comprises: at least one coolant channel (11, 12), which can be brought into fluidic connection with the roll cooling channel on the journal (3) side; and a sealing unit for sealing the fluidic connection between the coolant channel and the roll cooling channel, comprising an inner module and an outer module; wherein the inner module comprises a hollow cylindrical element (7), which can be inserted into the lateral recess of the journal (3), characterized in that the hollow cylindrical element (7) has no flange on the outer side of the journal, looking in the axial direction.

2. The device according to claim 1, characterized in that the inner module comprises a securing cover (22), which in the mounted condition abuts against an end face of the hollow cylindrical element (7) and is fastened to the journal (3), preferably being screwed to the journal (3) by means of one or more screws (23).

3. The device according to claim 2, characterized in that the securing cover (22) secures the hollow cylindrical element (7) with form fit in the lateral recess of the journal (3).

4. The device according to claim 1, characterized in that the inner module moreover comprises a securing ring (98), which can abut against an end face of the hollow cylindrical element (7), the securing ring (98) being securable preferably in a groove formed in the lateral recess of the journal (3).

5. The device according to claim 1, characterized in that the hollow cylindrical element (7) in the installed condition comprises a bottom on its inside, looking in the axial direction, which at least partly closes the hollow cylindrical element (7).

6. The device according to claim 1, characterized in that the inner module comprises at least one pin (99), by which the hollow cylindrical element can be secured to the journal (3), the pin (99) being introduced into a pin opening of the hollow cylindrical element (7) and a corresponding pin opening of the journal (3) which is aligned with it.

7. The device according to claim 5, characterized in that the pin opening of the hollow cylindrical element (7) is formed in the bottom.

8. The device according to claim 1, characterized in that the outer module comprises an elastic sleeve (8), which can be installed in the hollow cylindrical element (7).

9. The device according to claim 1, characterized in that the inner module comprises a slide ring (20), preferably firmly connected to the hollow cylindrical element (7), and the outer module comprises a slide ring (19), preferably firmly connected to the elastic sleeve (8), which stand in frictional contact with each other to seal off the fluidic connection.

10. The device according to claim 9, characterized in that the two slide rings (19, 20) are arranged inside the hollow cylindrical element.

11. The device according to claim 3, characterized in that the slide rings (19, 20) are provided on the bottom side, wherein the slide ring (20) of the inner module is preferably installed at least partly in a recess of the bottom of the hollow cylindrical element (7) and is thus secured to the hollow cylindrical element (7).

12. The device according to claim 1, characterized in that the outer module moreover comprises an insert piece (14), which can be mounted releasably on the bearing block (4) and comprises at least a first channel (15), which in the mounted condition of the insert piece (14) brings the coolant channel (11) into fluidic connection with the roll cooling channel.

13. The device according to claim 1, characterized in that the roll has an axially extending roll bore (6), in which a tube (17) is installed, so that inside the tube a first roll cooling channel is formed, and in a gap between the tube (17) and the roll bore (6) or a second coaxially extending tube a second roll cooling channel is formed, wherein the device comprises at least two coolant channels (11, 12), which can be brought into fluidic connection respectively with the first roll cooling channel and the second roll cooling channel.

14. The device according to claim 12 characterized in that the insert piece (14) moreover comprises a second channel (16), wherein, in the mounted condition of the insert piece (14), the first channel (15) and the second channel (16) stand in fluidic connection respectively with the first roll cooling channel and the second roll cooling channel.

15. The device according to claim 1, characterized in that the hollow cylindrical element (7), in the installed condition, does not protrude beyond the journal (3), looking in the axial direction.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0024] FIG. 1 shows a longitudinal section through a device for coupling a coolant supply and coolant drainage to a roll according to one exemplary embodiment.

[0025] FIG. 2 shows a longitudinal section through a device for coupling a coolant supply and coolant drainage to a roll according to another exemplary embodiment.

DETAILED DESCRIPTION OF PREFERRED EXEMPLARY EMBODIMENTS

[0026] In the following, preferred exemplary embodiments shall be described with the aid of the figures. The same, similar, or equivalent elements shall be given the same reference numbers. Moreover, a repeat description of these elements will sometimes be foregone in order to avoid redundancy.

[0027] FIG. 1 shows a device 1 according to a first exemplary embodiment, for coupling a coolant supply to a roll 2, which can be a transport roller, working roll, back-up roll, and so forth, in a continuous casting installation. The roll 2 comprises a journal 3, which is rotatably mounted in one or more roller bearings 5. The roller bearing 5 is secured to a bearing block 4, such as a stationary frame or rack.

[0028] The roll 2 comprises an axially extending roll bore 6, which functions as a cooling channel, through which the roll 2 is supplied with a coolant, preferably water. The cooling channel in the present exemplary embodiment extends centrally along the axis of the roll 2, but the roll 2 can also receive a flow of coolant in another manner (such as through one or more cooling channels passing through the body of the roll 2 in another location), as long as a reliable supply of coolant from a coolant supply is assured.

[0029] In a lateral recess or bore of the journal 3 there is installed a hollow cylindrical element 7, serving to hold an elastic sleeve 8. The hollow cylindrical element 7 has roughly the shape of a pot, apart from the fact that the bottom of the pot is pierced by a tube 17, running in the roll bore 6. The hollow cylindrical element 7 is installed such that the bottom lies further inside the roll 2, looking in the axial direction, than the fully open end of the hollow cylindrical element 7. The hollow cylindrical element 7 has no flange lying against the end face of the journal 3 on the outside. The hollow cylindrical element 7 in the present exemplary embodiment furthermore does not extend beyond the end of the journal 3, looking in the axial direction.

[0030] The elastic sleeve 8 is made of stainless steel, for example, but it may also be made of another material or a combination of different materials and/or parts (such as a plastic or rubber), as long as it is assured that its shape and elasticity assure a reliable sealing. The elastic sleeve 8 in the exemplary embodiment shown is installed releasably in the flange 7, in particular replaceably.

[0031] The axial end face of the journal 3 is covered according to the exemplary embodiment by a bearing block cover 9. The bearing block cover 9 comprises a first coolant channel 11 and possibly a second coolant channel 12 (for a supply and drainage of the coolant on the same side of the roll 2). The coolant channels 11, 12 may be seen as part of the coolant supply or as being connected to such. The coolant channel 11 stands in fluidic connection with a coolant channel inside the roll 2, so that it can be supplied with coolant through the coolant channel 11.

[0032] In the present exemplary embodiment, for this purpose an insert piece 14 is installed in an opening of the bearing block cover 9 having a first channel 15 extending therein, which stands in fluidic connection with the coolant channel 11 in the mounted state of the insert piece 14. The first channel 15 pointing into the interior of the roll protrudes into an annular gap or passes into such, which is formed by two coaxially extending tubes, the inner tube being the aforementioned tube 17. The coolant is transported through the annular gap into the interior of the roll 2. The annular gap is dimensioned such that, on the one hand, a relative rotatability of the tube tubes is assured, and at the same time an adequate flow of the coolant is made possible. The back transport of the coolant occurs through the interior of the tube 17.

[0033] The insert piece 14 can moreover comprise a second channel 16, which—if present—stands in fluidic connection with the coolant channel 12. In the exemplary embodiment shown in FIG. 1, the transport of coolant away from the tube 17 occurs through the second channel 16, thereby realizing a coolant circulation with an inlet and an outlet on one side of the roll 2. The channels inside the roll 2 and the journal 3 through which the coolant can flow are also known as roll cooling channels. The inflow and outflow of the coolant inside the roll 2 is preferably organized such that the fresh coolant flows into the roll 2 through the above described annular gap and flows out through the interior of the tube 17. For this purpose, the coolant channel empties inside the tube 17 through the second channel 16 into the coolant channel 12. However, there is no restraint in this regard, as long as the roll cooling channels and the connections to the coolant channels 11, 12 are realized such that a reliable coolant circulation is assured. It should be pointed out in this regard that only one coolant channel 11 is shown in the cross section of FIG. 1, while the other coolant channel 12 runs outside the sectional view. The two coolant channels 11 and 12 preferably form a V shape in the cross section, perpendicular to the axis of rotation of the roll 2, converging with each other toward the tube 17 and standing there in fluidic connection with the corresponding roll cooling channels via the two channels 15 and 16.

[0034] For the secure fluidic connection between the fluid supply and the roll 2, a sealing unit is provided. The sealing unit comprises an outer and an inner module.

[0035] The inner module comprises the hollow cylindrical element 7 and, in the present first exemplary embodiment, a slide ring 20. The hollow cylindrical element 7 and the slide ring 20 may be firmly joined together, which also includes an integral and/or one-piece connection. Preferably, the slide ring 20 is at least partly inserted into a recess in the bottom of the hollow cylindrical element 7, thereby assuring a simple and secure fixation of the slide ring 20 on the hollow cylindrical element 7. In this way, a form-fitting and/or force-locking connection is produced between the slide ring 20 and the hollow cylindrical element 7.

[0036] The outer module comprises the elastic sleeve 8 as well as the insert piece 14. Moreover, the outer module of the sealing unit comprises a slide ring 19, which stands in frictional contact with the slide ring 20, in order to enable a turning of the roll 2 relative to the outer module and at the same time assure a tight seal, thereby preventing a leakage of the cooling fluid. According to the present exemplary embodiment, the sealing surfaces of the two slide rings 19 and 20 are situated perpendicular to the axis of rotation of the roll 2. This geometrical arrangement of the sealing surfaces is preferable for a technically simple and secure cushioning of the forces acting on the slide rings 19 and 20; however, the sealing unit may also have a different construction in this regard, as long as a leakage of the cooling fluid at the parts moving relative to each other is prevented. In the present exemplary embodiment, the outer module of the sealing unit moreover comprises an extension 21, serving for stabilization and fastening of the slide ring 19 on the sleeve 8. The extension 21 may also be omitted. One, several, or all of the components of the outer module may be firmly joined together, also including an integral and/or one-piece design.

[0037] In the present exemplary embodiment, the slide rings 19, 20 are located at the bottom end of the hollow cylindrical element 7 (looking in the axial direction), which can save design space on the part of the insert piece 14, contributing overall to a more compact structural design of the device. However, the slide rings 19, 20 may also be positioned in another location.

[0038] According to the present exemplary embodiment, the hollow cylindrical element 7 is secured on the part of the insert piece 14 by means of a securing ring 98, which abuts against the end face of the hollow cylindrical element 7 and is secured in a groove formed in the lateral recess of the journal 3. The securing ring 98 and the hollow cylindrical element may alternatively be formed integrally or as a single piece. Moreover, the securing ring may also be fashioned as a single-piece or integral part of the journal 3. The opposite bottom end of the hollow cylindrical element is secured on the journal 3, for example by means of one or more pins 99. For this purpose, the 99 (or several pins) is introduced into an opening at the bottom of the hollow cylindrical element 7 and a corresponding opening of the journal 3, aligned with it. The securing ring 98 and the pin 99 are associated with the inner module.

[0039] The exemplary embodiment depicted and its described modifications enable a structurally simple and reliable fixation of the hollow cylindrical element in the lateral recess of the journal 3. However, the fastening or fixation may also be done otherwise, as long as a flange can be eliminated on the part of the insert piece 14.

[0040] The insert piece 14 assures an access from the outside to the sealing unit, for example in order to perform maintenance work or to replace components, without requiring a removal of the entire bearing block cover 9. This allows one to supply a flushing agent, such as compressed air, in order to blow out the cooling fluid or contaminants from the interior of the roll and thus facilitate the maintenance work. Moreover, the sealing unit and thus the overall device can have a particularly compact design on account of the flangeless hollow cylindrical element 7. In particular, the sealing unit can be used for journals 3 of especially small diameter.

[0041] The fastening of the bearing block cover 9 to the bearing block 4 is preferably releasable, such as by using fastening screws. Likewise, the insert piece 14 is preferably releasably fastened to the bearing block cover 9 by fastening screws. Hence, an access from the outside is easily possible. When the insert piece 14 is mounted in the bearing block cover 9, both the components of the coolant supply and coolant drainage and the sealing unit are protected against external factors, especially in the harsh environment of a continuous casting installation, thereby preventing excessive wear and tear.

[0042] FIG. 2 shows a device 1 for the coupling of a coolant supply and coolant drainage to a roll 2 according to a second exemplary embodiment.

[0043] The exemplary embodiment of FIG. 2 shows an alternative design for the securing and fixation of the hollow cylindrical element 7. According to this design, the securing ring 98 and/or the pins 99 of the first exemplary embodiment can be omitted. Those components not involving the fastening and fixation of the hollow cylindrical element 7 correspond to those of the first exemplary embodiment.

[0044] The hollow cylindrical Element 7 is also preferably flangeless according to the second exemplary embodiment. This is now secured with form fitting by means of a securing cover 22. The securing cover 22 is a disk-shaped element, which abuts against the end face of the hollow cylindrical element 7 and is somewhat compressed, so that the hollow cylindrical element 7 is held with form fitting in the lateral recess of the journal 3. For this purpose, the securing cover can be fastened by means of screws 23 to the journal 3. In order to prevent a twisting of the hollow cylindrical element 7 in the lateral recess of the journal 3 even more reliably, means can be provided in the lateral recess of the journal 3 and/or on the outside of the hollow cylindrical element 7 and/or on the securing cover 22 to assist in a form fitted support. The form fit may thus be present between the hollow cylindrical element 7 and the lateral recess of the journal 3 and/or between the hollow cylindrical element 7 and the securing cover 22. Thus, for example, grooves may be provided in the lateral recess of the journal 3, engaging with tongues on the outer circumference of the hollow cylindrical element 7, or the lateral recess of the journal 3 and the hollow cylindrical element 7 are not circular cylindrical, but instead have mutually matching shapes (such as polygonal cross sections) preventing a twisting. Alternatively or additionally, a form fit exists between the hollow cylindrical element 7 and the securing cover 22, such as by a kind of tongue and groove design.

[0045] The use of the securing cover 22 can simplify the mounting of the device 1. Furthermore, one special technical effect of the second exemplary embodiment is that a prevention of twisting of the hollow cylindrical element 7 can also be achieved if, for example, the pin 99 (or several pins 99) is forgotten when mounting the device 1. A protection against twisting of the hollow cylindrical element 7 is therefore important, since a turning of the hollow cylindrical element 7 relative to the journal 3 may result in great strain on the sealing means, such as O-rings in the hollow cylindrical element 7. This increases the risk of leakage of the rotary union.

[0046] All individual features presented in the exemplary embodiments can be combined with each other and/or exchanged for each other, as long as this is feasible, without leaving the scope of the invention.

LIST OF REFERENCE NUMBERS

[0047] 1 Device for coupling a coolant supply [0048] 2 Roll [0049] 3 Journal [0050] 4 Bearing block [0051] 5 Roller bearing [0052] 6 Roll bore [0053] 7 Hollow cylindrical element [0054] 8 Elastic sleeve [0055] 9 Bearing block cover [0056] 11 Coolant channel [0057] 12 Coolant channel [0058] 14 Insert piece [0059] 15 First channel [0060] 16 Second channel [0061] 17 Tube [0062] 19 Slide ring [0063] 20 Slide ring [0064] 21 Extension [0065] 22 Securing cover [0066] 23 Screw [0067] 98 Securing ring [0068] 99 Pin