KR20050027730A - Apparatus for cooling and absorbing impact of measuring wheel used in continuous casting - Google Patents

Abstract

To provide an apparatus in which a rotary joint is not adopted on a cooling water supply passage, and the cooling water supply passage is dualized to cooling a measuring wheel more effectively by controlling pressure of cooling water sprayed onto the measuring wheel according as a slab passes by an upper part of the measuring wheel. An apparatus for cooling and absorbing impact of measuring wheel used in continuous casting process comprises an arm device installed on a roller table(16) used in the continuous casting process with being parallel to a driving roller(11) and installed such that the arm device is rotatably around the roller table as a shaft; a measuring wheel(30) installed at one side of the arm device through which the slab passes such that the measuring wheel measures length of the slab; a pulse generator(32) installed at the other side of the arm device to detect the number of revolutions of the measuring wheel; a cooling means(40) installed on a fixed base(41) supported to the roller table to selectively control spray pressure of cooling water according as the slab passes through an upper part of the measuring wheel by dualizing passage of cooling water supplied to the measuring wheel; and an impact absorption means(60) for absorbing impact generated when the measuring wheel is collided with the slab by an elastic member(61) connected to the cooling means.

Description

Apparatus for cooling and absorbing impact of measuring wheel used in continuous casting}

The present invention relates to a cooling and shock absorbing device of the measuring wheel used to measure the length of the slab in a continuous casting process, and more specifically, the measuring wheel by dualizing the cooling water supply passage provided for cooling the measuring wheel Cooling and impact of the measuring wheel configured to not only selectively control the injection amount of the coolant according to whether the slab passes on the top of the slab, but also to more effectively absorb the impact generated when the slab collides with the measuring wheel. It relates to an absorber.

In general, a measuring wheel is a device used to measure the length of a slab produced in a continuous casting process and is an important part of the combustion casting process. In other words, the slab produced by continuous casting is cut into a predetermined length required in a later process by a torch cutting machine, which must be preceded by measuring the length of the slab by the measuring wheel.

Referring to Figure 1 will be described the configuration of a roller table equipped with a conventional measuring wheel. The slab 10 produced by continuous casting is conveyed along the roller table 16, which has a plurality of drive rollers 11 connected to the drive motor 12 via the reducer 13. Is installed. On the other hand, an arm device 17 is provided on the roller table 16 so as to be parallel to the drive roller 11 and rotatable about the roller table 16, and the slab 10 of the arm devices 17 is provided. One side passing by the measuring wheel 18 is installed. The other side of the arm device 17 is provided with a weight 21 at a predetermined position, and the other end thereof is provided with a pulse generator 22 connected to the measuring wheel 18 to measure the number of revolutions thereof. In addition, an arm stopper 20 is provided at the tip of the bracket 19 on the roller table 16 on which the arm device 17 is fixed. One side of the measuring wheel 18 is connected to the cooling water supply line 24 via the rotary joint 23.

The measuring wheel on the roller table configured as described above operates as follows. Before the slab 10 is transferred, the side on which the pulse generator 22 is mounted is inclined downward by the weight 21 so that the measuring wheel 18 is raised about 30 mm above the upper surface of the driving roller 11. In this state, when the slab 10 is transported to collide with the measuring wheel 18, the measuring device 18 rotates downward while the arm device 17 rotates. Rotation is prevented by the arm stopper 20 and therefore does not go down over a certain distance. Thereafter, the measuring wheel 18 in contact with the bottom surface of the slab 10 rotates according to the movement of the slab 10, and the pulse generator 22 calculates the rotation speed thereof to measure the length of the slab 10. . When the measured length of the slab 10 reaches a predetermined length required in a later process, the slab 10 is cut by a torch cutting machine (not shown), and the cut slab is a stopper at a high speed along the roller table 16. Up to 14. The slab 10 stopped by the stopper 14 is descaled at its cut surface and the unique serial number is marked by the slab marking machine 36. Thereafter, the centering operation is performed by the measuring wheel 18, picked up by a crane, and transferred to a later process.

Since the measuring wheel 18 is in constant contact with the hot slab 10 during operation, it is necessary to cool it quickly. The cooling of the measuring wheel 18 is carried out via a rotary joint 23 on one side thereof. It is made by the cooling water sprayed through the connected cooling water supply line 24. However, in this cooling method, rotational deficiency of the rotary joint 23 occurs due to radiant heat generated from the slab 10, causing the cooling water supply line of the rotary joint to be twisted, and thus, water flow is not smoothly performed. The problem that the gerring wheel 18 overheats was often caused. Moreover, the coolant sprayed through the rotary joint 23 was also sprayed on the slab 10 passing over the measuring wheel 18 to cool the slab 10 unevenly, thereby degrading the organizational properties of the final product.

In addition, since the slab 18 moves at a high speed of 60 m / sec on the roller table 16, the pulse generator 22 is dropped due to the strong impact when the slab 18 collides with the measuring wheel 18. Or the arm stopper 20 is broken, and in severe cases, the shaft of the wheel is broken, which causes various problems such as a safety accident.

The present invention has been proposed to solve this problem, and does not adopt a rotary joint on the cooling water supply passage while dualizing the cooling water supply passage is sprayed on the measuring wheel depending on whether the slab passes over the measuring wheel. It is an object of the present invention to provide an apparatus capable of cooling the measuring wheel more effectively by adjusting the pressure of the cooling water.

In addition, another object of the present invention is to provide a means for effectively absorbing the impact caused by the collision with the slab.

The cooling and impact absorbing device of the measuring wheel used in the continuous casting process according to the present invention for achieving the above object is installed in parallel with the drive roller on the roller table used in the continuous casting process and the roller table as the axis An arm device rotatably provided; A measuring wheel installed at one side of the arm device through which the slab passes and measuring the length of the slab; A pulse generator installed at the other side of the arm device to sense the rotational speed of the measuring wheel; Cooling means provided on a fixed base supported by the roller table and selectively adjusting the injection amount of the coolant according to whether the slab passes on the measuring wheel by dualizing a passage of the coolant supplied to the measuring wheel; And shock absorbing means for absorbing the impact generated by the measuring wheel colliding with the slab by an elastic member connected to the cooling means.

The cooling means may include: a guide tube installed on the fixed base and communicating with a cooling water supply line and having a small diameter low pressure water supply hole and a large diameter high pressure water supply hole, respectively; The low-pressure water supply pipe and the high-pressure water supply pipe on the guide tube are provided with the low pressure water supply pipe and the high pressure water supply pipe which are placed on the guide tube and connected to the other side of the arm device and slide along the guide tube when the arm device rotates. A sliding tube selectively communicating with the supply hole; And a low pressure water nozzle and a high pressure water nozzle formed in the arm device and connected to one side of the low pressure water pipe and the high pressure water pipe connected to the low pressure water supply pipe and the high pressure water supply pipe provided on the sliding tube, respectively. Include.

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

2 and 3 are an overall perspective view and an exploded perspective view of the cooling and shock absorbing device of the measuring wheel according to the present invention.

A hollow arm device 35 is installed on the roller table 16 in parallel with the drive roller 11 so as to be rotatable, and the measuring wheel 30 is bolted to one side through which the slab of the arm device 35 passes. do. The pulse generator 32 is fixedly installed on the fixed block 34 provided on the other side of the arm device 35, and the connecting shaft 31 provided inside the measuring wheel 30 has a hollow arm device 35. It is connected to the pulse generator 32 via the long shaft 33 penetrating therein to allow rotation of the measuring wheel 30 to be transmitted to the pulse generator 32. The arm device 35 is installed through a trinion shaft 37 rotatably fixed between the trinion blocks 38 provided on the roller table 16 so as to rotate about the trinion shaft 37. It is composed.

The cooling and shock absorbing device of the measuring wheel 35 according to the present invention is largely composed of the cooling means 40 of the measuring wheel and the shock absorbing means 60 of the measuring wheel. Let's look at the configuration first. An arc-shaped guide tube 43 extending upward is provided on the fixed base 41 supported by the roller table 16, and the guide tube 43 communicates with the cooling water supply line 42. Two cooling water supply holes are formed in the guide tube 43 at predetermined intervals, one of the low pressure water supply holes 44 having a small diameter and the other of the high pressure water supply holes 45 having the large diameter. The two cooling water supply holes 44 and 45 are fitted with a sealing member 46 for preventing leakage of the cooling water. In general, an O-ring is mainly used. Since the supply holes are different in size, the amount of cooling water flowing out also varies. That is, a greater amount of cooling water flows out through the high pressure water supply hole 45.

The same arc-shaped sliding tube 43 is covered on the guide tube 43, and two cooling water supply pipes are provided outside the sliding tube 43, one having the same size as the low pressure water supply hole 44. The low pressure water supply pipe 48 and the other is the high pressure water supply pipe 49 having the same size as the high pressure water supply hole 44. The connection block 50 to which the two supply pipes 48 and 49 are connected is bolted to the fixed block 34 to which the pulse generator 32 is fixed. The supply pipes 48 and 49 extend into the fixed block 34 to form a low pressure water pipe hole 51 and a high pressure water pipe hole 52 formed on a flange 36 provided at the other end of the arm device 35. Each communicates.

The low pressure water pipe hole 51 and the high pressure water pipe hole 52 communicate with the low pressure water pipe 53 and the high pressure water pipe 54 formed on the arm device, respectively. The low pressure water nozzle 55 is fitted to one side facing the low ring hole 30, and the high pressure water nozzle 56 is fitted to one side facing the measuring hole 30 of the high pressure water pipe 54. Since the low pressure nozzle 55 has the same diameter as the low pressure water supply hole 44 of the guide tube 43, the amount of cooling water injected therethrough is small, and the end of the nozzle has a measuring wheel 30. It is installed to face the inside of the. On the contrary, since the high pressure water nozzle 56 has the same diameter as the high pressure water supply hole 45 of the guide tube 43, the amount of cooling water injected therethrough is relatively lower than that of the low pressure water nozzle 55. In addition to the many, the end of the nozzle is also installed to face the entire measuring wheel 30.

On the other hand, the shock absorbing means 60 is configured to absorb the shock generated by the collision with the slab by the elastic member 61 is connected to the cooling means 40. The elastic member 61 may be a coil spring or a hydraulic cylinder and may be any elastically generating restoring force. In this embodiment, the coil spring is configured as shown, which will be described based on this. First, the coil spring is mounted on the upper side of the guide tube 43, and one side of the coil spring is elastically supported by the fixing plate 63 fixedly installed by the fixing bolt 64 on the upper end of the guide tube 43. . A fixing ring 62 is installed between the fixing plate 63 and the coil spring to fix the coil spring. The other side of the coil spring is elastically supported by the sliding tube 47 is configured to expand and contract as the sliding tube 47 slides on the guide tube 43.

The operation of the cooling and impact absorbing device of the measuring wheel according to the present invention configured as described above will be described with reference to FIGS. 4A and 4B.

First, in the state where the slab does not pass on the measuring wheel 30 as shown in FIG. 4A, the arm device 35 is inclined by the elastic force of the coil spring, whereby the measuring wheel 30 drives the driving roller ( It is located about 30mm higher than the upper surface of 11). At this time, since the cooling water sprayed to cool the measuring wheel 30 is sprayed onto the slab and there is no fear of uneven cooling of the slab, it is preferable to spray the cooling water evenly over the measuring wheel 30 to cool it quickly. Therefore, in this case, the high pressure water supply pipe 49 provided on the sliding tube 47 communicates with the high pressure water supply hole 47 formed on the guide tube 43, and as a result, a greater amount of cooling water is supplied. . The supplied cooling water is evenly sprayed on the entire inside and outside of the measuring wheel 30 through the high pressure water nozzle 56.

On the other hand, as shown in Figure 4b, when the slab 10 passes on the measuring wheel 30, the slab 10 and the measuring wheel 30 is located at least 30mm higher than the upper surface of the drive roller 11 and The collision and the measuring wheel 30 descends. As a result, the other side of the arm device 35 rises up, at which time the coil spring absorbs the shock. In addition, since the slab 10 is located on the upper part of the measuring wheel 30, cooling water sprayed to cool the measuring wheel 30 may be sprayed to the slab 10 to cause non-uniform cooling of the slab 10. have. Therefore, in this case, the low pressure water supply pipe 48 provided on the sliding tube 47 communicates with the low pressure water supply hole 44 formed on the guide tube 43, so that only a relatively small amount of cooling water is supplied. In addition, since the supplied cooling water is injected only into the measuring wheel 30 through the low pressure water nozzle 56, the cooling water is prevented from being sprayed on the slab 10 located outside the measuring wheel 30.

As described above, according to the cooling and shock absorbing device of the measuring wheel used in the continuous casting process according to the present invention, the measuring wheel is more effectively controlled by controlling the injection amount of the cooling water according to whether the slab passes on the measuring wheel. In addition to cooling, the structural wheel can also be absorbed by the impact of the mesuring wheel colliding with the slab to improve structural stability.

1 is a perspective view showing a measuring wheel according to the prior art.

Figure 2 is an overall perspective view of the cooling and shock absorbing device of the measuring wheel according to the present invention.

Figure 3 is an exploded perspective view of the cooling and shock absorbing device of the measuring wheel according to the present invention.

Figure 4a, 4b is a state of use of the cooling and shock absorbing device of the measuring wheel according to the present invention.

※ Explanation of symbols about main part of drawing ※

30: measuring wheel 31: connecting shaft

32: pulse generator 33: long shaft

34: fixed block 35: arm device

36: flange 37: trunnion axis

38: triion block 40: cooling means

41: fixed base 42: coolant supply line

43: guide tube 44: low pressure water supply hole

45: high pressure water supply hole 46: sealing member

47: sliding tube 48: low pressure water supply pipe

49: high pressure water supply pipe 50: connection block

51: low pressure water pipe hole 52: high pressure water pipe hole

53: low pressure water pipe 54: high pressure water pipe

55: low pressure water nozzle 56: high pressure water nozzle

60: shock absorbing means 61: elastic member

62: fixing ring 63: fixing plate

64: fixing bolt

Claims (4)

An arm device (35) mounted on the roller table (16) used in the continuous casting process in parallel with the driving roller (11) and provided to be rotatable about the roller table (16); A measuring wheel 30 installed at one side through which the slab 10 of the arm device 35 passes and measuring the length of the slab 10; A pulse generator (32) installed at the other side of the arm device (35) for sensing the rotational speed of the measuring wheel (30); Whether the slab 10 passes on the measuring wheel 30 by dualizing the passage of the cooling water provided on the fixed base 41 supported by the roller table 16 and supplied to the measuring wheel 30. Cooling means 40 for selectively adjusting the injection pressure of the cooling water according to; And shock absorbing means 60 for absorbing shock generated by the measuring wheel 30 colliding with the slab 10 by the elastic member 61 connected to the cooling means 40. Cooling and shock absorbing device for measuring wheel used in continuous casting process. The method of claim 1, wherein the cooling means 40 is installed on the fixed base 41 and in communication with the cooling water supply line 42, the small diameter low pressure water supply hole 44 and the large diameter high pressure water supply hole Guide tubes 43 each having 45 formed thereon; The low pressure water supply pipe 48 provided on the guide tube 43 and connected to the other side of the arm device 35 so as to slide along the guide tube 43 when the arm device 35 rotates, A high pressure water supply pipe 49 in which the low pressure water supply hole 44 on the guide tube 43 and the high pressure water supply hole 45 selectively communicate with the sliding tube 47; And a low pressure water pipe 53 and a high pressure water pipe 54 formed in the arm device 35 to communicate with the low pressure water supply pipe 48 and the high pressure water supply pipe 49 provided on the sliding tube 43, respectively. Cooling and shock absorbing device of the measuring wheel used in the continuous casting process, characterized in that it comprises a low pressure water nozzle 55 and a high pressure water nozzle 56 connected to one side facing the measuring wheel (30). The low pressure water supply pipe 48 of the sliding tube 47 and the low pressure water supply hole 44 of the guide tube 43 when the slab 10 passes on the measuring wheel 30. Is in communication with the slab 10 when the slab 10 does not pass on the measuring wheel 30, the high pressure water supply hole 45 of the guide tube 43 and the high pressure water supply tube 49 of the sliding tube 47. The low pressure water nozzle 55 is configured to communicate with the cooling water only to the inside of the measuring wheel 30 and the high pressure water nozzle 55 is configured to spray the cooling water to the whole of the measuring wheel 30. Cooling and shock absorbing device for measuring wheel used in continuous casting process. According to claim 2 or 3, wherein the elastic member 61 is a coil spring, the coil spring is mounted on one side of the guide tube 43, one end of which is fixed to one side of the guide tube 43 Cooling and shock absorbing device of the measuring wheel used in the continuous casting process, characterized in that the elastically supported by the plate 63 is configured to expand and contract as the sliding tube 43 slides on the guide tube (43).