BEARING BLOCK FOR HOLDING A BEARING FOR A ROLLER

Abstract

A bearing block for holding a bearing for a roller, in particular a strand-guiding roller in a strandguiding device. The bearing block is designed as a solid casting having an integrated internal coolant channel. The coolant channel has an inlet and an outlet for coolant. In order to enable an improvement in the product quality of the cast slabs, the bearing block has a rotational speed sensor for sensing the rotational speed of the roller.

Claims

1-9. (canceled)

10. A bearing block for holding a bearing for a roller, in particular a strand-guiding roller in a strand-guiding device, comprising: at least one integrated coolant channel with an inlet and an outlet for coolant, wherein the bearing block with the integrated interior coolant channel is configured as a solid casting; a rotational speed sensor for detecting rotational speed of the roller; and temperature sensors for detecting temperature of the coolant in the coolant channel, wherein the temperature sensors are configured as thermocouples, including a first thermocouple provided in the inlet to detect the coolant inlet temperature, and a second thermocouple provided in the outlet of the coolant channel to detect the coolant outlet temperature.

11. The bearing block according to claim 10, wherein the rotational speed sensor is a Hall sensor.

12. The bearing block according to claim 11, further comprising a plurality of magnets fastened to a neck of the roller to cooperate with the Hall sensor.

13. The bearing block according to claim 10, further comprising a blind hole introduced externally into the bearing block, the rotational speed sensor being mounted in the blind hole.

14. The bearing block according to claim 10, wherein the thermocouples are screw-in thermocouples that are screwed into bores, one in the inlet and one in the outlet, of the coolant channel.

15. The bearing block according to claim 10, further comprising at least one stabilizing rib in the coolant channel.

16. The bearing block according to claim 10, the bearing block is cast from a hardened stainless chromium-nickel-copper steel.

17. The bearing block according to claim 11, further comprising corrugated hoses for signal cables of the thermocouples and/or of the Hall sensor, wherein the corrugated hoses are attached to the bearing block by couplings.

18. The bearing block according to claim 10, wherein the bearing is a sealed roller bearing.

19. A strand-guiding device of a strand-casting machine, comprising: a plurality of strand-guiding rollers for guiding a cast strand after the cast strand has left a strand-casting mold; a bearing block according to claim 10, wherein at least one neck of one of the strand-guiding rollers is supported in the bearing block; and a process control system for automatically controlling a feed quantity of the coolant based on an actual cooling action of the bearing block, wherein the actual cooling action is determined based on temperature of the coolant at the inlet and in the outlet of the coolant channel as detected by the temperature sensors.

Description

[0022] Four figures are attached to the description, wherein:

[0023] FIG. 1 shows a first vertical section through the bearing block according to the invention along a longitudinal axis of a supported roller;

[0024] FIG. 2 shows a second vertical section through the bearing block according to the invention transversely to the longitudinal axis of the supported roller;

[0025] FIG. 3 shows a horizontal section through the bearing block according to the invention; and

[0026] FIG. 4 shows a broken-off vertical section through the bearing block.

[0027] The invention is described in detail below in the form of exemplary embodiments with reference to the cited figures. In all the figures, technical elements which are the same are designated by the same reference numbers.

[0028] FIG. 1 shows the bearing block 1 according to the invention as a longitudinal section along the longitudinal axis of the roller 2 to be supported. The bearing block 1 according to the invention comprises a dirt hump 1a and an integrated coolant channel 1b. The coolant channel 1b is divided here by way of example into three subchannels by two stabilizing ribs 21. The bearing block serves to hold a bearing, in particular a roller bearing 3. The roller bearing 3 serves in turn to hold and support the bearing neck 2a of the roller 2; see also FIG. 2. Reference number 5 designates a rotary union; 6 designates a cartridge seal; 7 and 8 designate spacer rings; and 9 and 10 designate locking rings.

[0029] To detect the rotational speed of the roller and thus to monitor the rotational functionality of the bearing, the bearing block 1 comprises a Hall sensor 13, as shown in FIG. 4. It can be seen in FIG. 4 that this Hall sensor 13 is mounted in a blind hole in the outside surface of the bearing block 1. As can be seen in FIG. 1, magnets 11 are assigned to this Hall sensor; by means of magnet mounts 12, these magnets are permanently installed on the neck of the roller 2 and rotate along with the neck. When the roller 2 rotates, the Hall sensor 13 detects the changing magnetic field generated by the magnets co-rotating with the roller neck. In particular, the Hall sensor detects whether a magnet is rotating past it or not. The Hall sensor generates a corresponding measurement signal. From this measurement signal, it is then possible, under consideration of the number of magnets 11 distributed around the circumference of the roller neck, to calculate the rotational speed of the roller 2.

[0030] FIG. 1 also shows a coupling 17 for a corrugated hose, through which the cables of the Hall sensor 13 and the cables of the thermocouples can be guided. Finally, the reference number 22 designates a seal between the magnet mount 12 and the bearing neck 2a of the roller 2.

[0031] FIG. 2 shows the previously mentioned vertical section through the bearing block according to the invention, wherein this vertical section lies in a plane perpendicular to the longitudinal axis of the roller to be supported. The bearing block 1 and the coolant channel 1b formed in the bearing block can be seen. The coolant channel has a coolant inlet 19 and a coolant outlet 20. It can be seen that the coolant channel extends around the supported bearing, in particular around the roller bearing 3, over a very large portion of its circumference. The bearing neck 2a of the roller 2 and the rotary union 5 can be seen in the interior of the roller bearinghoused within in and coaxial to it.

[0032] FIG. 3 shows a horizontal section through the bearing block 1, in particular through the inlet 19 and the outlet 20 of the coolant channel 1b shown in FIG. 2. It is easy to recognize a first and a second thermocouple 14, which project radially into the inlet 19 and the outlet 20 to measure the coolant inlet temperature and the coolant outlet temperature. They are configured as screw-in thermocouples and are screwed into appropriate bores in the circumference of the inlet 19 and outlet 20. Their measuring cables are conducted to the outside through the corrugated hose and the previously mentioned coupling 17. Also shown in FIG. 3 are two mounting bores 16 for the mounting of the bearing block 1.

LIST OF REFERENCE NUMBERS

[0033] 1 bearing block with [0034] 1a dirt hump [0035] 1b coolant channel [0036] 2 roller [0037] 2a bearing neck of the roller [0038] 3 roller bearing [0039] 5 rotary union [0040] 6 cartridge seal [0041] 7 spacer ring [0042] 8 spacer ring [0043] 9 locking ring [0044] 10 locking ring [0045] 11 magnet [0046] 12 magnet mount [0047] 13 Hall sensor [0048] 14 screw-in thermocouples [0049] 15 cover plate [0050] 16 mounting bore [0051] 17 coupling for corrugated hose [0052] 18 sealing ring [0053] 19 water inlet [0054] 20 water outlet [0055] 21 stabilizing rib [0056] 22 sealing ring