RU2344893C1 - Device for cooling of hot rolled sheet and strip - Google Patents

Abstract

FIELD: technological processes; metallurgy.

SUBSTANCE: device comprises roller bed and cooling headers with flat jet nozzles. High density of cooling, availability of both turbulent zone and zone of even cooling are provided due to the fact that adjacent headers are installed at the distance of (0.3÷0.9)×H, where H is distance from nozzle end to support plane of roller bed, nozzles are installed with pitch equal to (0.8÷1.7)×H×tgβ/2, where β is angle of nozzle torch opening along larger axis, at that every pair of adjacent headers has nozzles installed with shift in direction of header axis by half of pitch between them, angle of their incline towards each other relative to vertical line makes 10°÷20°, and larger axis of nozzle outlet opening ellipse creates angle 5°÷25° with header longitudinal axis.

EFFECT: higher efficiency of cooling and reduction of cooler flow required for cooling of hot rolled sheet and strip in rolling mills.

2 dwg, 2 tbl

Description

The invention relates to rolling production and can be used to cool a hot-rolled sheet and strip, for example, on plate mills during inter-stand and post-deformation cooling, as well as on broadband mills during cooling in the inter-stand gap and on the discharge roller table.

A device is known for cooling a strip with a mixture of liquid and gas (Japanese Patent No. 57-600232, IPC ³ C21D 9/573, publ. 1982), containing a closed chamber in which cooling sections are located on the lower and upper sides of the strip that has entered it . Each section consists of a sufficiently large number of cooling elements equipped with two nozzles: the upper one for gas and the lower one for liquid. In such a device, the nozzles are inclined to each other, therefore, at a certain distance from them, the two streams are mixed together, and a single mixture flow reaches the strip surface, which after collision with the strip surface is divided into two initial components. The fluid flows down inclined planes into its collection manifold, and the gas flows into the suction pipe for reuse.

The disadvantages of such a device include the low density of strip irrigation due to the addition of gas, which leads to an increase in the size of the cooler plume and leads to a deterioration in the quality of rolled products, as well as uneven cooling of the strip in width, which is caused by the absence of fixation of the size of the cooling zone, which generally degrades the quality of the rental . The need to use in such a device in large quantities two components for cooling (liquid and gas) makes it difficult to operate, and also leads to an increase in capital costs. In addition, such a device cannot be used on the discharge roller table of plate and broadband mills, since the greatest efficiency of liquid-gas cooling is achieved when the distance from the nozzles to the strip surface is not more than 0.5 ÷ 0.6 m.

A device for cooling the strip (Aut. St. USSR No. 944701, IPC ³ B21B 45/02, publ. 1982), containing filling tanks installed above the discharge roller table is made in the form of an outer casing with a slot nozzle and an internal distribution manifold. The ratio of the installation height of the filling tanks above the discharge roller table to the size of the transverse clearance in the slotted nozzle is 220 ÷ 260.

The disadvantages of this device include the low efficiency of use of the cooler, due to the fact that the cooler is fed to the metal in a narrow strip with a high irrigation density over a short section length. In turn, the outflow of water with virtually no pressure leads to a violation of the uniformity of water movement at the edge sections of the flow, as a result of which the uniformity of cooling is violated when rolling wide strips. In addition, the use of pressureless cooling significantly reduces the range of possible regulation of the cooling intensity.

The closest to the claimed invention in technical essence and the achieved result is a device for cooling a hot-rolled strip (Aut. St. USSR No. 933735, IPC ³ C21D 1/02, publ. 1982), containing a roller table and collectors arranged parallel to the rollers with installed along their axes are flat-blast nozzles, the outlet openings of which are ellipsoidal, with the major axis of the ellipse forming an angle with the longitudinal axis of the collector. In such a device, nozzles are installed in increments of 12–19 small ellipse diameters, and a larger ellipse diameter forms an angle of 70–87 ° with the longitudinal axis of the collector, while adjacent collectors are located at a distance equal to 1–2 distances from the nozzle end to the reference plane live rolls.

The disadvantages of such a device include uneven cooling of the roll along its width, which is due to the step of installing nozzles without taking into account the distance from them to the supporting plane of the roller table. The installation of nozzles in such a way that the larger diameter of the ellipse of the nozzle opening forms an angle of 70 ÷ 87 ° with the longitudinal axis of the collector, causes various cooling of the strip edges and its quality deterioration. In addition, the size of the cooling zone that is not uniform across the width of the strip causes a deterioration in the quality of the strip. The location of adjacent collectors at a distance equal to 1 ÷ 2 distances from the end of the nozzle to the supporting plane of the roller table, and the direction of the axis of the jets perpendicular to the strip surface determine the inefficient use of a cooler. Outside the plume, the irrigation density decreases sharply and the cooler is used inefficiently.

The basis of the claimed invention is the task of creating such a device for cooling a hot-rolled sheet and strip, which due to the new mutual arrangement of structural elements allows you to create a cooling zone with a fixed length and high density of irrigation on the surface of the rolled sheet and strip, provides both the formation between the zones of direct leakage of the cooler coming from adjacent collectors, a turbulent zone with high cooling intensity, and uniform cooling of the proc yvaemyh sheet and strip with a high speed, and hence improves the quality of the rolled products, reduces production costs and reduces cooling costs.

The problem is solved due to the fact that in the device for cooling a hot-rolled sheet and strip containing a roller table and collectors arranged parallel to the rollers with plane-jet nozzles installed along their axes, the outlet openings of which are ellipsoidal in shape, and the large axis of the ellipse forms an angle with the longitudinal axis of the collector, according to the invention, adjacent collectors are installed at a distance of (0.3 ÷ 0.9) × H, where N is the distance from the end of the nozzle to the supporting plane of the roller table, and the nozzles are placed in increments of (0.8 ÷ 1.7) × H × tgβ / 2, where β is the nozzle plume opening angle along the major axis, while on each pair of adjacent collectors the nozzles are offset halfway between the collector axis and the angle between them the inclination towards each other relative to the vertical is 10 ÷ 20 °, and the large axis of the ellipse of the nozzle outlet forms an angle of 5 ÷ 25 ° with the longitudinal axis of the collector.

Installing adjacent collectors at a distance of (0.3 ÷ 0.9) × H, where N is the distance from the nozzle end to the supporting plane of the roller table, allows you to create an inextricable turbulent cooling zone between the rows of cooler jets reaching the surface of the sheet and strip and ensures efficient mixing cooler in the turbulent zone, and therefore, allows for a relatively short length of the cooling zone to carry out stable and high-intensity cooling of the rolled sheet and strip.

The installation of adjacent collectors at a distance of less than 0.3 × N does not allow creating a turbulent cooling zone on the surface of the sheet and strip.

If the distance between adjacent collectors is 0.15 × N (for example, at H = 1 m, the distance will be 0.15 m), as a result of the intersection of the cooler flares before the rolled surface, they are mutually extinguished. This leads to a significant decrease in heat removal from the rolled sheet and strip, leads to a deterioration in the quality of rolled products, a decrease in the cooling rate, to an increase in the flow rate of the cooler and, due to an increase in the length of the transport roller table, to an increase in the cost of production.

Installation of adjacent collectors at a distance of more than 0.9xN leads to the appearance of uncontrolled cooling in the turbulent zone, which introduces instability in the cooling process and affects the quality of the rental.

Table 1 shows the results of studies regarding the installation of adjacent collectors at various distances.

Table 1. The distance between adjacent collectors, m The ratio of the distance between adjacent collectors to the distance to the reference plane of the roller table The size of the turbulent zone, m The average decrease in temperature, ° C Instability of heat removal, ° С 0.15 0.15 0.00 3 +3 0.30 0.30 0.10 7 0 0.45 0.45 0.25 8 0 0.60 0.60 0.40 8 0 0.75 0.75 0.55 9 0 0.90 0.90 0.70 9 0 1,2 1.20 1.00 9 ± 2 1,5 1,50 1.30 10 ± 5

Placing the nozzles on the collectors with a step equal to (0.8 ÷ 1.7) × H × tgβ / 2, where β is the angle of the nozzle plume opening along the major axis, allows for the distribution of the cooler with high uniformity across the width of the rolled sheet and strip, which helps to increase the uniformity of cooling under adjacent collectors.

In a single nozzle, the cooler is distributed along the major axis with variable density (the maximum is reached in the middle), there is unevenness in irrigation, and when nozzles are located with the claimed step, the unevenness in cooling along the width of the rolled sheet and strip does not exceed 10%.

When nozzles are placed in increments of less than 0.8 × H × tgβ / 2, the maximum irrigation density is provided in the middle between the cooler flares. With this step, the interaction of torches occurs even before contact with the rental, which leads to the mutual extinguishment of torches.

Placing nozzles in increments of more than 1.7 × H × tgβ / 2 results in a minimum irrigation density between the nozzles.

Table 2 shows the results of studies regarding the location of plane-spray nozzles with different pitch between them.

Table 2. Step between flat spray nozzles, m The ratio of the step between the nozzles to half the length of the torch Heat transfer coefficient, kW / m ² K Uneven cooling,% 0.20 0.6 2.2 twenty 0.30 0.8 3.4 7 0.36 1,0 3,5 5 0.44 1,2 3.3 6 0.51 1.4 3.0 8 0.62 1.7 2.7 10 0.73 2.0 2,4 25

When placing flat-blast nozzles with a step of 0.6 × H × tgβ / 2 (for example, at H = 1.0 m and β = 40 °, the step will be 0.25 m), the irregularity of the irrigation density reaches 20%, and the heat transfer coefficient decreases by 30 %, which indicates a significant decrease in cooling efficiency. Due to the uneven cooling of the rolling stock, its quality is deteriorating, and due to the increase in the length of the conveyor, the cost of production increases and the consumption of cooler increases.

When placing flat-blast nozzles with a step equal to 2.0 × H × tgβ / 2 (at H = 1.0 m and β = 40 °, the step will be 0.73 m), the cooling unevenness reaches 25%, and the heat transfer coefficient does not provide an effective cooling, which leads to a deterioration in the quality of rolled products, an increase in the cost of production, although at the same time there is a reduction in the consumption of cooler.

The location of the nozzles on each pair of adjacent collectors with a shift in the direction (along) the axis of the collector by half a step between them allows you to create a uniform distribution of the density of irrigation on the surface of the car. Due to this, in the area where the maxima of the irrigation density take place in the first row, the minima are located in the second row, and vice versa. In addition, due to this arrangement of nozzles, the cooler jets interact in the turbulent zone, which, in turn, further increases the uniformity of cooling. This provides an increase in the cooling efficiency of rolled steel and, accordingly, an improvement in its quality.

The inclination of the nozzles on adjacent collectors towards each other relative to the vertical by an angle of 10 ÷ 20 ° allows you to direct the cooler into the cooling zone (in the turbulent zone) and provide effective heat removal there. With this arrangement of nozzles, the cooler moves from the external borders and is actively mixed, which eliminates uncontrolled cooling of the rolled products outside the zone. Such a constructive solution provides an improvement in the quality of rolled products, reducing the cost of production and reducing the consumption of cooler.

If the angle of the nozzles is less than 10 °, part of the cooler spreads outside the main cooling zone, which leads to unorganized cooling uneven in rolling width.

If the angle of the nozzles exceeds 20 °, the effect of mutual quenching of the torch coolers is observed, which leads to an increase in unevenness and a decrease in the intensity of heat removal from the rental.

The location of the nozzles so that the large axis of the ellipse of the nozzle outlet forms an angle of 5 ° ÷ 25 ° with the longitudinal axis of the collector allows you to create a rectilinear boundary of the cooling zone on the rolled surface, while the irregularity of irrigation at the beginning of the zone does not exceed 5%, which ensures uniform cooling over rolled width, especially at the edges.

If the angle between the larger axis of the ellipse of the nozzle outlet and the longitudinal axis of the collector is less than 5 °, the effect of mutual quenching of the cooler flares is observed, which leads to an increase in unevenness and a decrease in the intensity of heat removal from the rental. As a result, the quality of the rental is deteriorating, its cost is increasing, and the consumption of the cooler is increasing. So, at an angle of 2 °, the non-uniformity of cooling can reach 25%, and the heat transfer coefficient decreases by 35%.

If the angle between the larger axis of the ellipse of the nozzle outlet and the longitudinal axis of the collector exceeds 25 °, the proportion of cooler increases, which leaves the cooling zone and carries out unorganized heat removal from the rental, resulting in poor quality of the rental.

Given the above and taking into account the disclosed causal relationship between the totality of the features of the claimed invention and the achieved technical result, it can be argued that the problem posed is the basis for creating a device for cooling a hot rolled sheet and strip, since the use of the invention allows you to create on the surface of the rolled sheet and strip cooling zone with a fixed length and high density of irrigation, to ensure the formation between the zones of direct leakage of the cooler, stumbles of the adjacent collectors turbulent zone with a high cooling intensity, to ensure uniform cooling of the rolled sheet and strip at a high speed, improve rolling quality, reduce production costs and reduce the coolant flow.

The essence of the invention is illustrated by drawings, which depict:

 figure 1 - device for cooling a hot-rolled sheet and strip (side view);

 figure 2 - installation diagram of the collectors and nozzles (top view).

The composition of the device for cooling a hot-rolled sheet and strip includes rollers of the rolling table 1 and adjacent collectors 3 and 3 'arranged transversely to the movement of the cooled strip 2. Adjacent collectors 3 and 3 'are installed at a distance C from one another, which is 0.6 × N (at a distance H from the end of the nozzle 4 to the supporting plane of the roller table 1, equal to 1 m (C = 0.6 × N)). The collectors 3 and 3 'are equipped with flat-jet nozzles 4, the outlet openings of which are ellipsoidal. Moreover, at a distance H from the end of the nozzle 4 to the supporting plane of the roller table 1, equal to 1 m, and the angle β of the flare of the nozzle 4 along the major axis, equal to 40 °, the nozzles 4 on the manifolds 3 and 3 'are placed with a step α equal to 1, 3 × H × tgβ / 2. Moreover, on each pair of adjacent collectors 3 and 3 ', the nozzles 4 are displaced on one manifold 3' relative to the nozzles 4 on the other manifold 3 in the direction (along) the axis of the collector 3 (3 ') by a distance b equal to half the step between them (b = a / 2). The nozzles 4 are inclined towards each other relative to the vertical by an angle Θ equal to 15 °. The large axis of the ellipse of the outlet of the nozzle 4 forms an angle ω equal to 15 ° with the longitudinal axis of the manifold 3 (3 ').

The inventive device operates as follows.

The cooler from the piping system (not shown in the drawings) enters adjacent collectors 3, 3 'and, through spray nozzles 4, is sprayed to the cooled strip 2, which is transported by the rollers of the roller table 1.

Claims (1)

A device for cooling a hot-rolled sheet or strip, comprising a roller table and collectors arranged parallel to the roller table rollers with plane-jet nozzles installed along their axes, the outlet openings of which are ellipsoidal in shape, the larger axis of the ellipse forming an angle with the longitudinal axis of the collector, characterized in that adjacent collectors are mounted on the distance (0.3 ÷ 0.9) · N, where N is the distance from the end of the nozzle to the supporting plane of the roller table, and the nozzles are placed with a step equal to (0.8 ÷ 1.7) · H · tgβ / 2, where β - opening angle f of the nozzle nozzle along the major axis, while on each pair of adjacent collectors the nozzles are offset with a half step in the direction of the collector axis between them, the angle of their inclination towards each other relative to the vertical is 10 ÷ 20 °, and the angle between the larger axis of the ellipse of the nozzle outlets and the longitudinal axis of the collector is 5 ÷ 25 °.

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