NO139322B - DEVICE FOR COOLING BAR MATERIAL - Google Patents

Description

The present invention relates to a device for cooling rod material, in particular steel, where the material can be fed longitudinally through a number of cooling tubes arranged one behind the other and filled with water, which cooling tubes are each provided with an introduction funnel and a connection for water supply.

Such a device is known, for example, from German patent 2 121 712. In this known device, elements are placed at both ends of the cooling pipes which cause an increase in the static pressure in the cooling pipe. Due to wear and tear when changing to a different diameter, these elements are made interchangeable. Furthermore, each pipe has a valve that makes it possible to control the static pressure in the cooling pipe. With this known device, however, it is not excluded that air is sucked into the pipe, particularly if said elements are worn out, due to the very rapid movement of the through rod. This is detrimental to maintaining a constant rod quality. For cooling reinforcing bars fitted with cross ribs. this known device is not very suitable.

From BRD publicly available document no. 2 214 681

a device for cooling bar steel is also known, which device works according to a principle similar to the principle of the invention, but this device will lead to inhomogeneous cooling and the formation of water vapor when used, which will be harmful to the metallurgical properties of the steel, which - materially due to the fact that the known device has an extraordinarily long cooling pipe and the placement of nozzles and openings in the cooling pipe.

The invention aims to eliminate these disadvantages

and provide a device for cooling rod material which is suitable for rod material provided with cross ribs and at the same time

for use with different diameters without the necessity to close the cooling device to change certain parts when changing to another rolling program.

According to the invention, this task is solved in that the pipes are placed in a box that is designed to be filled with water, that the holes are located in a number of transverse planes and successive holes are staggered, and that correspondingly, holes in successive cooling pipes are advance.

As the pipes are placed in a box and submerged in the water, the suction of air into the pipes is prevented. Because the water is directed at a number of points on the circumference at right angles to the rod, the water is distributed homogeneously around the circumference of the rod and homogenous cooling is effected around the circumference of the rod. As the pipes are submerged, it is possible to use high water velocities without air intake. The advantages of this are that with profiled material, the absolute water speed on the bar is determined by the results of the bar's speed and the water's speed, so that the shadow effects behind the cross ribs are prevented. With higher water velocities, a lower surface temperature on the rod will be achieved more quickly, as the heat transfer factor rises significantly at a lower surface temperature.

In the aforementioned patent, no length dimensions for the pipes are specified either. It can be deduced from the drawings that these are quite long. When using the device according to the present invention, however, short pipes can be used. This has the advantage of rapid water drainage, whereby the water temperature in the pipe does not rise very much and the heat transfer factor remains high. If there is any difficulty in the factory and a bar has been left in the cooling plant, the bar can be cut through in the case between the separated pipes, which adds favorably to the time necessary to eliminate the difficulty. By arranging short pipes in the cooling box, the distribution of water over the length is also more controllable.

By arranging a separate feed funnel in front of the water-filled box and which can be pivoted upwards in the event of jamming of the bar in or after the cooling device, the risk of damage from the incoming rolled bar is reduced.

The invention will be explained in more detail below with reference to an embodiment shown in the drawings,

where fig. 1 schematically shows the discharge table on a rolling mill for rod and wire, fig. 2 shows . the device according to the invention 1 a side view, fig. 3 shows the device according to the invention seen from above and with more detail, fig. 4 is a section along the line IV-IV in fig. 3 of the device according to the invention on a larger scale, and fig. 5 shows a longitudinal section of a separate inner tube with two sets of staggered holes on its circumference.

In fig. 1, the reference number 20 denotes the last rolling stand in a rolling mill for rod and wire. Immediately after this rolling stand 20, a cooling device of the type corresponding to the present invention is arranged, and generally denoted by the reference number 40. The reference number 77 denotes a pair of scissors for cutting the rolled material to desired lengths. After the scissors there are a number, in the example shown 3, of cooling devices denoted by the reference numbers 1, 2 and 3 and an outlet table 4.

In the cooling device 40 in accordance with the invention and shown in fig. 2, 3 and 4, the rolled material passes continuously at a fairly high speed. In fig. 2 schematically shows a side view, partly in section, of a device in accordance with the invention. The rod material is indicated at 5 and moves from left to right. A long rectangular box 6 is for the most part filled with water which is brought into the box in a way that will be discussed later, and leaves the box through a drainage opening 7 at the bottom. A valve can be arranged in the drain opening 7 to enable control of the water level in the box 6.

In the case, a number is arranged, in fig.

2 seven, pipes, through which the material to be cooled is passed. These tubes, which are indicated in the direction of movement of the material by 11, 12, 13, 14, 15, 16 and 17, are each provided with an introduction funnel 18 and are equipped with double walls.

Outside the box 6, an additional feed funnel 19 is placed on a console 20. This funnel is hinged and pivotable at 21 to provide space for the rolled bar in case of difficulties and to reduce the risk of damage to the cooling device from the bar .

The cooling tubes 11, 12, 13, 14, 15, 16 and 17 are, as mentioned, double-walled and the inner tube is provided with a number of holes 22 regularly distributed along the length and width of the tube. The holes 22 are located in fig. 2 in. two planes at right angles to the longitudinal axis of the inner tube. In this embodiment, there are two sets of four holes each with a mutual distance of 90° around the circumference. The successive holes are in the same position. In order to obtain a more uniform flow of the water and to produce cooling from all sides of the movable rod, it is advisable to stagger the holes in successive cross-sectional planes of a pipe. In fig. 5 it is indicated that the first set of four holes: denoted by 22a are arranged in accordance with a + and the second set of four holes denoted 22b in accordance with x viewed in the respective cross-sections and thus offset by 45° in relation to each other. In the successive tubes 11 - 17, the holes 22 can also be offset by an angle of 22.5°.

(This means that the two sets of four holes each for pipes 11, 13, 15 and 17 have a corresponding position and also those for pipes 12, 14 and 16. If there are more than four holes on the circumference, other values can of course be used ).

Fig. 3 shows the cooling device according to the invention seen from above and also simultaneously shows the water connection to the various cooling pipes. A drain pipe 23 is arranged outside the box.

In fig. 4 which is a vertical section along the line IV-IV in fig. 3, it is shown that the middle path of the rod material does not coincide with the center of the box 6. The water supply takes place at 24. The supplied water is distributed through the pipes 25 and 26. The water enters the annular space 27 between the inner pipe 14 and the outer tube 20. In fig. 4 shows the four holes 22 distributed on the circumference. Through these holes the water splashes into the inner pipe and in this way hits the material from all sides. The water can leave the pipe 14 at both ends. Due to the fact that a certain liquid level is maintained in the box 6, there is no possibility of air particles being carried into the inner tube, which would disturb the cooling.

Rapid cooling is important for achieving a specific microstructure in the material. At the same time, rapid cooling is important because below a certain temperature, oxide formation takes place much more slowly. With rapid cooling, the outlet table can be made shorter, which leads to a significant saving in investment. As the rod material is cooled with a high water velocity and from all sides, no shadow effect can be expected if the rod is equipped with transverse ribs. Cooling takes place around the bar's circumference and produces a homogeneous structure. Rod--., the core retains a large part of its heat during the temperature equalization which, after leaving the drain pipe 23, causes a heat flow from the core towards . the outer surface and creates a ■■■ certain tarnish.

The box 6 is open at the top and around the edge is provided with a splash screen 29.

As the water supply takes place through a concentric outer pipe and wide supply pipe, the resistance is . a particularly small and a large amount of water can be supplied at a relatively low supply pressure. The four-sided cooling gives the already mentioned advantage that the cooling takes place evenly across the bar's cross-section. Despite the high bar speed, the cooling is so intense that a temperature drop of a few hundred degrees is possible. The supply of water at right angles to the rod has a strong effect on the depth of cooling because the boundary layers are better broken up in this way and by increasing the heat transfer factor, the heat flow rises. This heat flow is naturally limited by the rod's thermal conductivity.

As is known, the bar's surface temperature during cooling can have an effect on the volume of the heat flow. Thus the water velocity will have no further effect if,

the maximum heat flow is achieved. As it is beneficial from a cooling point of view to maintain a low temperature for so long. as possible, in practice the first part of the box must have the most water. It is possible to supply the remaining pipes with a comparatively smaller amount of water in order to maintain the rod's surface temperature. In the pipelines 24 for the cooling pipes or groups of the same, separate valves are inserted to control the water distribution over the entire length of the box 6.

It is known that both the heat transfer factor and the heat flow decrease at higher water temperatures. It is in

in this connection it is advisable to bring the coldest water into contact with the hottest material and use water of a higher temperature for other cooling purposes. The first cooling pipes are therefore connected to a water supply with a relatively low temperature.

Claims (1)

1. Device for cooling bar material, particularly of steel, where the material can be fed in the longitudinal direction through a number of short cooling tubes (11 -17) which are arranged one behind the other and are arranged to be filled with water, which cooling tubes are each provided with an introduction funnel (18) and have double walls, and where the inner tube, through which the rod material can be fed, is provided with a number of radial holes (22) regularly distributed on the circumference and where a connection for cooling water is arranged on the outer pipe which is closed at both ends, characterized in that the pipes (11 - 17) are placed in a box (6) which is designed to be filled with water, that the holes (22) are located in a number of transverse planes and successive holes (22a, 22b) are staggered, and that also corresponding holes in successive cooling pipes (11 - 17) are staggered. 2. Device according to claim 1, characterized in that a separate intake pipe (19) is arranged outside the box (6) which can be pivoted upwards by hinges. 3. Device according to claims 1 and 2, characterized in that. successive cooling pipes are connected two by two to the water supply. ^."^•Vv Device according to claim 1, characterized that the holes (22) are distributed over 90° of the pipe circumference. 5. (Device according to claim 1, characterized ^ in that two sets of four holes each are arranged. 6. Device according to one or the preceding claims, characterized in that the supply pipe (24) for cooling pipes or groups of cooling pipes is provided with inserted separate nozzles for controlling the distribution over the length of the box (6). 7. Device according to one of the preceding claims, characterized in that the pipes (11 - 17) are arranged eccentrically in the box. 8. Device according to one of the preceding claims, characterized in that the first cooling pipe is connected to a water supply with a relatively low temperature.