KR100815741B1 - An apparatus for detecting roll bearing - Google Patents

Abstract

Provided is a bearing abnormality detection device for hot rolling rolls, which makes it easy to detect an abnormality of a roll bearing used in a rolling roll of a rolling line that performs high-speed rolling in a steel mill.

The roll bearing abnormality detection device 1 is inserted into a plurality of points inside the upper and lower roll chocks 14 on which the rolling roll bearings 12 are mounted, and a lamp 26 is connected to one of them 24a. And a dummyster (24) (24a) which is covered with a protective socket (22), and a power supply (28) which is built-in and connected to the side of the roll choke (14) to supply power to the dummy and lamps. Bearing temperature detector 20 for detecting the temperature of the bearing 12; and a connecting means 44 having a photodiode 42 for receiving the light of the detector lamp 26 mounted therein; A bearing detection signal receiver 40 in which the front side cowcket 46 of the 44 is attached to and detached from the roll chock socket 22; And a rotation shaft installed so that the first and second link means 62 and 64 to which the connecting means 44 of the receiver 40 are connected are rotated inside the base 65 disposed to one side of the roll choke 14. And a device unit 60 connected to the upper and lower sides of the 66 and configured to fit the socket 46 of the receiver 40 into the detector socket 22 when rotating.

Therefore, according to the present invention, by always knowing the bearing state of the rolling roll, the rolling equipment is prevented from being emergency stop due to the bearing abnormality of the rolling roll during operation of the rolling line, thereby improving the operation rate of the rolling line In other words, the effect is to improve product productivity and quality.

Hot Rolled, Rolled Roll, Roll Bearing, Bearing Detection Device, Dummyster

Description

Device for detecting bearing abnormality of hot rolling rolls {AN APPARATUS FOR DETECTING ROLL BEARING}             

1 is a schematic front view showing a finish rolling mill of a general hot rolling process

Figure 2 is a schematic diagram showing a roll bearing inspection operation of a conventional rolling roll

Figure 3 is a schematic diagram showing a conventional roll bearing inspection method of another rolling roll

Figure 4 is an overall configuration showing a bearing abnormality detection device of the hot rolling roll according to the present invention

5 is a cross-sectional view showing the device of the present invention.

6 is a cross-sectional view taken along the line 'A-A' of FIG.

7 is a perspective view of the device of the present inventors;

8 is an exploded perspective view showing the abnormality detection of the roll bearing in the present invention device

Fig. 9 is a circuit diagram showing a circuit for detecting abnormality of a roll bearing in the device of the present invention.

10 is an exploded perspective view of the device of the present invention;

11 is an exploded perspective view of the device of the present invention;                 

Explanation of symbols on the main parts of the drawings

1 .... Bearing abnormality detection device 10 .... Rolling roll

12 ... bearing 14. Roll chocks

20 .... Detector 22 .... Socket

24 .... Dummyst 26 .... Lamp

28 .... Power supply 40 .... Receiver

42 .... photodiode 44 .... connection means

46 .... Cowcket 60 ....

62,64 .... link means 66 .... rotary shaft

The present invention relates to an apparatus for detecting a bearing abnormality of a rolling roll for easily detecting the abnormality of a roll bearing used in a rolling roll of a hot rolling line that performs high-speed rolling in a steel mill. The presence of abnormality can be detected in real time even while the rolling roll is in operation online, so that the state of the bearing can be always checked, thereby preventing the rolling equipment from emergency stop due to the bearing abnormality of the rolling roll during the rolling line operation. The present invention relates to a device for detecting bearing abnormality of a hot rolling roll to improve product productivity and quality.

In general, among the various rolling processes, in particular, in the hot rolling process that performs high-speed rolling, as shown in FIG. 1, a back-up roll is placed on the top and bottom of each stand 102 in the finishing mill 100 composed of a plurality of stands 102. Mounting the work roll 120 between the set and the work roll 120, the rolling material is passed through the work roll 120, that is, the hot strip 130 to perform a rolling operation, and the roller table 140 Feeding the strip 130 through to secure the winding temperature through a predetermined cooling operation and then wound in the form of a coil to produce a coil product.

At this time, the work roll 120 and the backup roll 110, because the high-temperature strip 130 is rolled, it is cooled in a large amount of cooling water, although not shown in detail in the drawing, in particular the high-temperature strip 130 and The direct contact with the work roll 120 is a large amount of cold water splashing water is generated by the injection of high-pressure cooling water, the fatigue of the roll is much more frequently generated a number of times to be replaced with a new work roll.

However, the work roll 120 of such a hot rolling line often performs rolling work continuously in a state where abnormality or absence of bearings is not confirmed due to abnormal heat generation phenomenon of the roll bearing part due to wear or overload of the bearings. In this case, the work roll 120 causes a large-scale equipment accident such as being broken.

Therefore, during such hot rolling, the bearing state of the work roll 120 should be periodically checked, but FIG. 2 illustrates a conventional roll bearing inspection operation.                         

That is, as shown in Figure 2, the inspection worker 200 is in close contact with the choke 122 supporting the work roll 120 rotated by the listening rod 210, or hear the sound, non-contact radiation thermometer A method of monitoring the temperature by holding the choke 122 and illuminating the choke 122 to measure the temperature of the bearing 220 or by installing a non-contact radiation thermometer (not shown) around the choke 122 is used. .

However, in such a conventional bearing inspection work, the method in which the worker 200 measures the presence or absence of bearing abnormality by bringing the listening rod 210 into close contact with the roll choke 122 directly is a work roll in the actual online rolling process. Since a large amount of coolant is scattered on the 120, the check operation cannot be performed, and the check operation is limited only when the strip 130 does not pass and the coolant is not sprayed. The risk of safety accidents for workers working around the facility is increasing.

In addition, although not shown in the drawing, the method of using a non-contact radiation thermometer (not shown) changes the atmosphere around the rolling mill from time to time, so that the emissivity does not maintain a constant state. 220 is difficult to check accurately, and expensive equipment must be operated in terms of cost, thereby raising the cost.

On the other hand, another conventional conventional temperature measuring device for a roll bearing for solving such a conventional problem is disclosed in Korean Utility Model Publication No. 2000-13337, the configuration is schematically shown in FIG.

That is, as shown in FIG. 3, a hole is formed in the liner 300 attached to one side of the rolled roll choke 122, the temperature sensor 302 is attached, and the cable 312 is connected to the temperature sensor connector 310. ) Is connected to the signal amplifier 320 and then sends the signal to the analysis system 330 to sense the temperature.

However, even in such a conventional roll bearing inspection device, it takes more than 20 minutes to dismantle the liner 300 coupled to the roll choke 122 when the sensor is installed and replaced due to breakage. Since a considerable time is required for attaching the temperature sensor 302 to the 300 and disassembly and reattachment for moving the liner 300 to another rolling mill, the operation rate of the rolling roll moving itself is lowered, and in particular, the roll choke Since the temperature sensor 302 is attached to the liner 300 attached to the outer surface of the 122, it is difficult to accurately sense the temperature of the roll bearing.

That is, the inspection of the abnormality of the roll bearing through the temperature measurement is to increase the temperature due to the increase of the friction load when the abnormality of the roll bearing, and to check the abnormality of the roll bearing by measuring this, the other conventional inspection device In this case, since the temperature is detected in the liner 300 even when abnormal heat is generated in the bearing 220 of the roll choke 122, the temperature mounted on the liner 300 exposed to the heat of the strip 130 generated during rolling. The sensor 302 alone is incorrect in temperature measurement.

In addition, when the roll gap is changed according to the thickness difference of the raw material during hot rolling, frictional heat is generated as the liner 300 installed in the roll choke 122 and the rolling mill slide each other, and thus the liner 300 is independent of the roll bearing. The temperature of itself rises, which in turn is not able to accurately measure the temperature of the roll bearing.

SUMMARY OF THE INVENTION The present invention has been made to solve various problems of the related art as described above. The object of the present invention is to change the temperature of the rolling roll bearing part of a hot rolling line that performs high-speed rolling at all times, even when the roll gap is adjusted, as well as online. By detecting and preventing burnout of roll bearings due to abnormal heat generation, detection of bearing abnormalities in hot rolling rolls is performed to improve product productivity and quality of rolled products as well as the operation rate of rolling lines. It is to provide a device.

As a technical configuration for achieving the above object, the present invention is an apparatus for detecting the presence or absence of a bearing abnormality of a rolling roll of a rolling mill that performs high-speed rolling, the inside of the upper and lower roll chocks on which the rolling roll bearing is mounted It is inserted into a plurality of points, one of which is equipped with a dummyster which is connected to the lamp by a lamp and is connected to the protection socket, and a power supply which is built in and connected to the side of the roll choke to supply power to the dummyists and the lamp. A bearing temperature detector for detecting a temperature; and

A bearing detection signal receiving unit having a connecting means in which a photodiode receiving the light of the detecting unit lamp is mounted therein, and a front side socket of the connecting means detachable from the roll chock socket; And,

First and second link means connected to the connecting means of the receiving unit is connected to the upper and lower sides of the rotary shaft installed to rotate inside the base disposed to one side of the roll choke, when the socket of the receiver is inserted into the detection socket A device unit configured to be built;
By providing a bearing abnormality detection device of the rolling roll configured as.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 4 is an overall configuration showing a bearing abnormality detection device of the hot rolling roll according to the present invention, Figure 5 is a cross-sectional view showing the apparatus of the present invention, Figure 6 is a device of the present invention in Figure 5 'A- 7 is a perspective view showing the apparatus of the present invention, Figure 8 is an exploded perspective view showing the abnormality detection of the roll bearing in the apparatus of the present invention, Figure 9 is an abnormality of the roll bearing in the apparatus of the present invention It is a circuit diagram which shows a detection part circuit, FIG. 10 is an exploded perspective view which shows the apparatus of this invention, and FIG. 11 is an exploded perspective view which shows the apparatus of this invention.

6 and 8 show the overall configuration of the bearing abnormality detection device 1 of the present invention rolling roll, the device 1 of the present invention is such a detection unit 20 for largely detecting the temperature of the bearing ), A receiver unit for receiving a detector signal, and an apparatus unit 60 for carrying out detachment of the roll chocks 14 of the receiver 40 on-line, each of which constitutes a component 20 (40). (60) in more detail as follows.

4 shows a rolling roll 10 in which the apparatus of the present invention is installed. The rolling roll 10 of the present invention, that is, the work roll 10 for directly rolling the raw material, has upper and lower chokes 14a and 14b. Each of them is mounted via a bearing 12, so that the detection device 1 of the present invention performs abnormality of the roll bearing 12 as temperature detection.

6 and 8 show the detection unit 20 of the apparatus 1 of the present invention, the bearing temperature detection unit 20 of the present invention is the upper and lower roll chocks on which the rolling roll bearings are mounted. Dummysters 24 and 24a inserted into a plurality of internal points 14a and 14b, one of which is connected with a lamp 26 and covered with a protective socket 22, and the dummyst 24 24 and 24a and a power supply 28 that is built-in and connected to the side of the roll choke 14 to supply power to the lamp 26.

That is, as shown in Figure 8, the dummy 24 (24a) of the detection unit 20 is 4 in the circumferential direction with respect to the roll bearing 12 of the upper and lower roll chocks (14a) (14b). Is inserted into the seating groove 30 formed at the point, the protective socket 22 is bolted to the outside of one seating groove (30a) in which the dummy (24a) and the lamp 26 of the seating groove 30 is inserted It is fixed and a liner (L) for adjusting the roll gap is attached to both sides of the roll choke (14).

On the other hand, as shown in FIG. 8, the power supply device 28 is seated inside the opening 28a formed at the side of the roll choke 14 and covered with a protective plate 28b. Although not shown in the figure, a certain amount of batteries are built-in, and although not shown in the figure, the power supply device 28 is covered with a heat insulating material and seated in the opening 28a side of the roll choke 14, and then the protective plate 28b is removed. It would be desirable to be bolted.

And, the power supply device 28, dummy 24 (24a) and the lamp 26 is connected by a cable will be described as a circuit diagram in the following Figure 9, each of the dummy is 4 of the roll choke (14) It is configured to detect the temperature of the bearing 12 at the point and adjust the light brightness of one lamp 26 connected to the work dummy 24a.

6, 7 and 11 show the detection signal receiver 40 of the apparatus 1 according to the present invention. The receiver 40 of the present invention provides the light of the detector lamp 26. The receiving photodiode 42 has a connecting means 44 mounted therein, and the front side socket 46 of the connecting means 44 is configured to be attached to and detached from the roll choke socket 22.

That is, as shown in Figures 6 and 11, the connecting means 44 of the bearing detection signal receiving unit 40, the first fixing plate 48 is fixed to the socket 46 is detachable to the socket 22 And a second fixing plate 56 which is elastically connected as a connecting bolt 54 which is fixed to the nut through a spring 52 through the bellows pipe 50 to the rear of the first fixing plate 48.

At this time, as shown in Figure 6, in front and rear of the bellows pipe 50, connecting plates 56a and 56b connected to the first and second fixing plates 48 and 56 as connecting bolts 54, respectively. It is integrally fixed, the bellows pipe 50 serves to cushion the shock when the cowcket 46 is moved to fit the socket 22 of the roll choke 14, for this purpose the connecting bolt 54 It is elastically supported via the spring 52.

6 and 11, the photodiode 42 is fixed to the front of the second fixing plate 56, and the cable C is installed to be drawn out through the link means. As shown in FIG. 9, the port diode 42 is connected to a circuit to raise the buzzer Bu if the set value is equal to or greater than the set value in the circuit configuration according to the detection signal.

Next, FIGS. 4 and 5 show the device part 60 of the device of the present invention. The device part 60 of the present invention has the first and second connections to which the connection means 44 of the receiver part 40 is connected. Link means 62 and 64 are respectively connected to the upper and lower sides of the rotary shaft 66 installed to rotate inside the base 65 disposed to one side of the roll chocks 14, and the rotary shaft and the link means are rotated. The socket 46 of the receiver 40 is fitted to the detector socket 22.

That is, as shown in FIGS. 10 and 11, the rotation shaft 66 of the device unit 60 is connected to a drive motor 66a vertically fixed to the upper side of the base 65 and the base 65. It is supported by the bearing (B) on the upper and lower sides of the motor (66a) is installed to rotate integrally when driving.

At this time, the driving motor 66a is vertically mounted on the base 65 through the bracket 66b and connected to the upper end of the rotary shaft 66, and the rotary shaft 66 is upward and downward in the center portion. Although not indicated by a separate sign, a screw groove is formed in which a nut (N) for assembling the connection ring of the first and second link means (62, 64) is formed, and the upper side of the rotary shaft (66). The key groove 66c into which the inner gear groove 70a of the first connection ring 70 is fitted is integrally formed in the longitudinal direction.

On the other hand, as shown in Fig. 10, when the portion of the second link arm 88 of the second link means 64, which will be described later, comes into contact with the horizontal extension portion of the base 65, i.e., the rotary shaft 66 The limit switch 65a is electrically connected to the driving motor 66a to stop the driving of the rotating motor.                     

As shown in FIGS. 7 and 11, the first link means 62 includes a first connection ring having a key assembled on an upper side of the rotary shaft 65 and an elastically supported spring 68 upward. A spring connected to the first connecting plate 72 horizontally extended to the outside of the 70, the second connecting plate 76 connected to the first connecting plate 72 and the hinge 74, and the second connecting plate 76; It is composed of a first link arm (80), which is elastically connected as a guide bar (79) and is connected to the receiver second fixing plate (56).

At this time, the hinge portion 74 is actually connected to the connecting portion formed in the first and second connection plates 72 and 76 are connected to the pin to be capable of rotating based on this, in particular in the second connection plate 76 As shown in FIG. 11, a guide rod 75 inserted into the first link arm 80 is provided.

Thus, when the roll chocks 14a are raised upward for adjustment of the roll gap, the first link means 62 is pulled by the springs 78 between the connecting plates while rotating the hinge 74 about the shaft to roll the chokes. In this case, the temperature of the roll bearing 12 is detected in the state where the socket 46 is always fitted to the roll choke socket 22 without detachment of the link means 62.

That is, the first link means 62 moves toward the upper roll chocks 14a, and the cowcket 46 is detached from the roll chock socket 22, and the roll chocks 14a close the roll gap of the rolling roll. Since it moves up and down in case of adjustment, it has a connection structure to absorb the movement amount although the movement amount is not large, and the first connection ring 70 of the first link means 620 is vertically moved to the rotation shaft 66. It is for the same reason that it is installed to be flexible.

In addition, the second link means 64 of the device unit 60 is integrally formed at one side of the second connection ring 82 and the second connection ring 82 which are key-assembled under the rotary shaft 65. Extends to a second link arm 84 connected to and fixed to the second fixing plate 56 of the receiver 40.

That is, since the second link means 64 rotates to the lower roll choke 14b side, the roll gap adjustment does not move corresponding to the lower roll choke without vertical movement, and the rotary shaft ( The driving of 66 is performed only when the roll chocks themselves are interlocked to rotate the first and second link means 40 and 60 to which the receivers 40 are connected, and in the on-line state of the rolling line, the roll chocks are moved to the roll choke side. It is made up of configurations to maintain.

Referring to the operation of the present invention made of the above configuration as follows.

As shown in Fig. 4 to Fig. 11, the light of the lamp 26 is brightened when the temperature of the bearing is detected by detecting the temperature of the bearing in the presence or absence of a roll bearing abnormality of the rolling roll, in particular, the work roll 10 for directly reducing the material. The apparatus of the present invention to detect the abnormality of the bearing 12 to detect the abnormality of the bearing 12, in particular to detect the bearing abnormality without interference with the equipment even during the online operation of the rolling roll 10 is as follows.

First, in the initialization mode of the apparatus 1 of the present invention, when the driving motor 66a of the bearing abnormality detecting apparatus device unit 60 is operated, the rotation shaft 66 rotates clockwise, and the first link means connected thereto. The 62 and the second link means 64 are integrally rotated so that the socket 42 disposed in front of the connecting means 44 of the receiver 40 in front of the socket 22 is provided in the roll choke 14. )

At this time, the home position of the first and second link means 62, 64 is controlled as a limit switch 65a installed in the market portion of the base 65, and the link rotates when the rotary shaft 66 rotates. Since the receiver 40 is connected to the means 62 and 64, even when the choke of the work roll 10 is replaced, the bearing presence or absence can be detected without any interference.

Next, when the socket 42 of the receiver 40 is in close contact with the protective socket 12 of the roll choke 14 as described above, it is elastically tight by the receiver bellows pipe 50, and eventually the receiver socket 46 ) Is stably in close contact with the outside of the detector socket 22.

In addition, when the first and second link means 62 and 64 are rotated by the motor as described above, and the socket 46 is in close contact with the socket 22, the driving of the driving motor 66a is stopped. The bellows pipe 50 of the receiver connection means 44 and the guide bar 54 and the spring 52 are provided for the adhesion of the cowcket 46.

At this time, when the upper roll choke 14a moves to adjust the roll gap, the first link arm 80 of the first link means 62 is rotated at the hinge 74, and the second connection is performed. In the state where the guide rod 75 of the plate 76 is inserted into the first link arm 80, the guide rod 75 is elastically moved by the elastic force of the spring 78 to be stably maintained while compensating for the movement width of the upper roll chocks.

Therefore, when the temperature of the work roll 10 rises, the temperature of the roll choke 14 on which the bearing 12 is mounted rises, and as shown in FIG. The MRs 24 and 24a are detectors for converting a temperature into a resistance value, the resistance value of which decreases to smooth the flow of current, thereby increasing the intensity of light emitted from the connected lamp 26.

As a result, as shown in FIG. 6, the light of the lamp 26 having different light intensity according to the operation of the dummy is mounted inside the photodiode through the bellows pipe 50 at the rear of the socket 46. 42, that is, detected by the port diode 42, which is a detector for converting light intensity into a current.

Therefore, as shown in FIGS. 6 and 9, when the intensity of light emitted from the lamp 26 increases or decreases in accordance with the temperature increase or decrease of the bearing, the port diode 42 increases or decreases the current to increase the bearing abnormality detection meter 41. And send it to the bearing temperature analysis system 43 to analyze it, and when the bearing 12 temperature is abnormally heated, it is determined by the system 43 and the display means such as a buzzer BU, etc. It will tell you when to replace.

That is, referring to FIG. 9, the operation of the dummy, the lamp 26, and the port diode 42 is described in detail. The dummysters 24 and 24a introduced into the roll choke 14 have a temperature as a resistance value. As the detector converts, the VBE rises, the rising IB increases, and the IC increases, causing the lamp 26 to operate.

That is, when the bearing temperature rises due to the bearing 12 or more, the temperature of the choke 14 rises and the resistance values of the thermistors 24 and 24a decrease, which causes a large current to flow to operate the lamp 26 and the temperature decreases. In this case, the resistance value increases and no current flows, so the VBE value becomes 0.6V or less in the low temperature state, so that no current flows in IB and the lamp 26 does not light, but the resistance R value is set so that IB does not flow. .

Next, as shown in FIG. 9, the photodiode 42 connected to the device unit 60 as a connecting means 44 inside the bellows tube 50 of the receiver 40 is a detector for converting light intensity into a current. If the light intensity is higher than the set light intensity, VBE rises, IB increases, IC increases, and if the current strength is large as the strength of the current in the bearing anomaly detection meter, the direction of the current meter moves much to the right, and if the current intensity decreases, the left side By using the principle of decreasing gradually, the strength of the current can be visually checked with the scale and guide according to the strength of the current, and when a certain range has elapsed, a signal to the buzzer (BU) or a warning lamp is sent to the operator to check whether the bearing 12 is abnormal. It is to inform.

Therefore, according to the apparatus 1 of the present invention, the bearing of the work roll can be replaced at an appropriate time, and the operator does not have to check the abnormality of the bearing periodically in the past, thereby improving the operation rate of the rolling line.

Thus, according to the present invention, the bearing abnormality detection device of the hot rolling roll, if abnormal heat generation of the rolling work roll bearing of the hot rolling mill that performs high-speed rolling occurs, even in the online state in which the rolling work roll is in operation without interfering with the equipment by the contact method. By detecting the temperature change of the beary early, it is possible to maintain and replace the rolling roll bearing at an appropriate time, thereby providing an effect of preventing large-scale equipment accidents such as roll breakage due to bearing abnormalities.                     

Therefore, the operation rate of the rolling roll is improved and the rolling of more precise material is performed to provide an excellent effect of improving the quality and productivity of the rolled product.

While the invention has been shown and described with respect to specific embodiments thereof, it will be apparent to those skilled in the art that various changes and modifications can be made without departing from the spirit or scope of the invention as set forth in the claims below. I would like to know that those who have knowledge of this can easily know.

Claims (5)

In the device (1) for detecting the presence or absence of the bearing 12 abnormality of the rolling mill rolling roll 10 to perform a high speed rolling, Dummyster is inserted into a plurality of points inside the upper and lower roll chocks 14a and 14b on which the rolling roll bearings are mounted, and one of them 24a is connected to a lamp 26 and covered with a protective socket 22. (24) and (24a), the dummy device (24) and (24a) and the power supply unit (28) built-in and connected to the side of the roll choke (14) to supply power to the lamp (26) and roll bearing ( Bearing temperature detection unit 20 for detecting a temperature of 12; and, A photodiode 42 for receiving the light of the detector lamp 26 has a connecting means 44 mounted therein, and the front side socket 46 of the connecting means 44 is connected to the roll choke socket ( A bearing detection signal receiver 40 detachably attached to the 22; And, First and second link means 62 and 64 to which the connecting means 44 of the receiver 40 are connected are rotated on the inner side of the base 65 disposed on one side of the roll choke 14. A device unit 60 connected to the upper and lower sides of the upper and lower sides, and configured to fit the socket 46 of the receiver 40 into the detector socket 22 when rotating; Bearing abnormality detection device of the rolling roll, characterized in that configured as According to claim 1, wherein the dummy 24 (24a) of the detection unit 20 is seated formed at four points in the circumferential direction with respect to the roll bearing 12 of the upper and lower roll chocks (14a, 14b) Inserted into the groove 30 and fixed, The socket 22 is bolted to the outside of the seating groove 30a in which the dummy 24a and the lamp 26 are inserted among the seating grooves 30, The power supply 28 is seated inside the opening 28a formed in the side of the roll choke 14 and covered with a protective plate 28b, and the power supply 28, dummy 24 and 24a, and lamps. (26) is a cable (C) connected to the bearing abnormality detection device of the hot rolling roll, characterized in that the light brightness of the lamp 26 is configured to vary according to the temperature of the roll bearing 12 The method according to claim 1, wherein the connection means (44) of the bearing detection signal receiver (40) comprises: a first fixing plate (48) to which a socket (46) detachable from the socket (22) is fixed; And a second fixing plate 56 elastically connected as a connecting bolt 54 which is fixed to the nut through the spring 52 through the bellows pipe 50 to the rear of the first fixing plate 48. The second fixing plate 56 is connected to the first and second link means 62 and 64 so that the socket 46 at the front side is detached from the detector socket 22 when the link means is rotated. The photodiode 42 is fixed to the front of the second fixing plate 56, the cable (C) is installed to the outside withdrawal through the link means bearing abnormality detection device of the rolling roll The rotating shaft 66 of the apparatus unit 60 is connected to a driving motor 66a vertically fixed to the upper side of the base 65 and has a bearing (upper and lower side) of the base 65. B) is installed to rotate as a motor, The first link means 62 is a first connecting plate extending horizontally to the outside of the first connection ring 70, which is key-assembled on the upper side of the rotary shaft 65 and the spring 68 is elastically supported on the upper side ( 72); A second connecting plate 76 connected to the first connecting plate 72 and the hinge 74; A first link arm 80 elastically connected to the second connecting plate 76 as a spring 78 and a guide bar 79 and connected to the receiving second fixing plate 56; Bearing abnormality detection device of the rolling roll, characterized in that configured to correspond to the movement during the roll gap adjustment The method of claim 1, wherein the second link means 64 of the device unit 60, the second connection ring 82 is keyed to the lower side of the rotary shaft 65; A second link arm 84 which is integrally extended at one side of the connection ring 82 and connected to and fixed to the second fixing plate 56 of the receiver 40; and wherein the second link means 64 is a roll gap. A device for detecting bearing abnormality of a rolling roll, characterized by being configured to move toward a lower roll choke 14b without movement during adjustment.

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