RU2193938C1 - Apparatus for cooling rolled pieces and rolling rolls - Google Patents

Abstract

FIELD: rolled stock production, namely cooling deformed metal and rolling rolls. SUBSTANCE: apparatus includes nozzle for supplying continuous stream of cooling agent and deflecting member inclined by acute angle relative to axis of nozzle. Deflecting member is in the form at least of three flexible plates assembled in pack and mounted with possibility of independent motion and rotation one relative to another and relative to outlet opening of nozzle. Preferably each flexible plate is second-order curve in plan view. EFFECT: enlarged manufacturing possibilities of cooling equipment. 2 cl, 8 dwg

Description

 The invention relates to the field of rolling production and can be used to cool a wrought metal and rolling rolls.

A device is known for cooling a hot-rolled strip containing a filling tank, in the bottom of which holes are made across the tank, overlapped by throttling plates installed with the possibility of lateral movement with holes forming pairs of holes with their corresponding holes in the bottom, one of which is made with a profile in the form of a rectangular trapezoid , the inclined side of which intersects the axis of the second hole, while the angle between the inclined side of the trapezoid and its base is annym along the throttling plate, at the edges and in the middle of the plate close to 90 ^o and varies monotonically with distance along the length of the holes of the plate from its middle towards the edges by about 180 ^o; opposite each opening, drain pipes with flattened ends are attached on the outside of the filling container, and a sheet is inclined beneath the pipes, the throttling plate adjacent to the bottom of the container on its outer side, and the drain pipes mounted on the throttling plate (AS USSR 910266, class . 21 V 45/02, publ. 03/07/82).

 The total amount of cooler coming from the filling tank for hire or rolling rolls per unit time is constant in all cases, which does not allow intensifying the cooling of individual rolled elements and the most overheated sections on the roll barrel. The cooler from the surface of the inclined sheet flows down in a continuous laminar flow with a different distribution of the flow rate along the length of the inclined sheet, almost linearly depending on the change in intensity relative to the longitudinal axis of movement of the rolled product, which does not allow for a laminar flow of the cooler, depending on the actual conditions of cooling of the rolled product, to obtain the specified cooling rate with redistribution of flow.

 The closest analogue of the present invention is a nozzle for spraying a liquid containing a hollow body with an outlet opening forming a nozzle for supplying a continuous stream of cooler with a deflector element in the form of a reflector located at an acute angle to the axis of the nozzle on it, the working surface of which is made in the form of longitudinal and transverse relative to the axis of the housing of intersecting cylindrical surfaces and is conjugated with the inner surface of the outlet, the ratio of the radius of the longitudinal surface STI transverse to the radius is selected to be from 0.5 to 3 (AS USSR 1636058, cl. B 05 B 1/04, publ. 03.23.91).

Signs of the closest analogue, coinciding with the essential features of the invention:
1) nozzle for supplying a continuous stream of cooler;
2) a deflector element located at an acute angle to the axis of the nozzle.

 The known device does not provide control over the distribution of density of the cooler over the area of the irrigation spot, which does not allow uniform cooling of the rolled products and rolls, since the flow of the cooler has a constant thickness along the entire length of the slice of the reflector and the same flow rate. Since the axial component of the flow velocity varies along the length of the edge of the reflector, decreasing to the edges, which leads to a decrease in the irrigation density of the cooled surface along the peripheral irrigation zones.

 The reflector in the known device has straight lateral edges facing the cooled surface, so there is no way to control the density distribution of the cooler over the area of the irrigation spot, which narrows the technological capabilities of the equipment in solving a wide range of production problems. When using this device for cooling the rolls, it is impossible to control the thermal profile of the roll due to the lack of funds for the redistribution of the density of the cooler within the cooled surface. Due to the small size around the rolling roll (bed, input and output rolling reinforcement), the simultaneous location of the cooling systems of the rolls and the regulation of their thermal profile will lead to uneven cooling of the rolls, i.e. individual sections of the barrel will be undercooled and the temperature difference between the middle and the edges of the roll barrel will not allow to achieve the changes necessary for thermal adjustment of their geometric dimensions.

 The basis of the invention is the task of improving the device for cooling rolled products and rolls, in which, by changing the design of the deflector element, the density distribution of the cooler is controlled over the area of the irrigation spot and, due to this, the technological capabilities of the cooling equipment are expanded.

 The problem is solved in that in a device for cooling rolled products and rolls containing a nozzle for supplying a continuous stream of cooler and a deflector element located at an acute angle to the axis of the nozzle, according to the invention, the deflector element is made in the form of at least three elastic plates assembled in a package, installed with the possibility of independent movement and rotation relative to each other and the nozzle outlet.

 It is advisable that each elastic plate was made in plan according to a second-order curve.

 The installation of elastic plates with the ability to independently move and rotate relative to each other and cut off the nozzle allows you to finely adjust the thermal profile of the roll barrel along the length due to the different configuration of the cooler flow and the formation of boundary layers of a given thickness, providing a given heat removal from the surface of the rolled products or rolls.

 The continuity of the flow of the cooler along the length of the roll or roll barrel, taking into account their configuration, is ensured by a wide range of regulation of both the angle of inclination of the deflector element to the nozzle axis (α) and the distribution of the cooler over the jet cross section, which leads to rolled products with a given thickness and minimal deviation in flatness .

 The distribution of the flow of the cooler allows you to unify the cooling equipment and apply it even in the presence of rolling reinforcement, which is not always possible when using flows formed on a continuous sheet.

 Elastic plates, depending on the configuration of the assembled package, allow you to redistribute the laminar flow of the cooler depending on the requirements of the temperature conditions for the cooled rolls or rolled products. A wide range of changes in the configuration of the package of elastic plates, changes in their location not only in one plane, but also their location relative to each other, allows to achieve the desired configuration of the cooler flow by performing them in a plan along a second-order curve, and changing the angle (α) allows a wide range to change the length of the departure of a flat jet, which is especially important when installing devices in limited volumes.

 The execution in the plan of each plate according to the second-order curve ensures the continuity of the formed laminar flow when it is transferred to the adjacent plate or when the plane jet exits to cooling due to the action of the surface tension forces of the cooler, because in this case, there are no stress concentrators for breaking the laminar flow.

 Different mutual arrangement of the plates allows you to distribute the flow of the cooler without the mutual running of the redistributed flows and smoothly control their distribution along the discharge plane, thereby adjusting the configuration of the front edge of the flow of the cooler.

 In FIG. 1 presents the proposed device for cooling rolled products and rolls, a longitudinal section; figure 2 is the same, a top view; figure 3, 4 and 5 - various options for the location of the three elastic plates; in Fig.6, 7 and 8 - diagrams of the distribution of the cooler over the area of the irrigation spot for the location options of the elastic plates shown in Fig.3, 4 and 5, respectively.

 A device for cooling rolled products and rolls consists of a nozzle 1 with an outlet 2 of circular cross section for supplying a continuous stream of cooler. Directly at the outlet 2 of the nozzle 1 is fixed a deflector element 3 located at an acute angle α to the axis of the nozzle 1. The deflector element 3 has fixing means in the form of a fixing bolt 4 and means for adjusting the angle of inclination of its surface to the axis of the nozzle 1 in the form of a fixing bolt 5. The deflector element 3 is made in the form of three elastic plates 6, each of which has a longitudinal groove 8 in place of attachment to the nozzle 1 7. The grooves 8 in each plate 6, when the fixing bolt 4 is “loosened,” allow the plates to be independently moved and rotated 6 relative to the outlet 2 of the nozzle 1. After the plates 6 are installed in the position required by the cooling technology, their mutual orientation is again fixed by the bolt 4. The elastic plates 6 are made by a contour in the form of a second-order curve, for example, an ellipse.

 The device operates as follows.

The cooler, for example water supplied through the nozzle 1, moves under pressure to the outlet 2 of the nozzle 1 and is formed into a continuous stream of cylindrical shape, flowing out at a certain speed on the guide surface of the deflector element 3. As a result of the onset of a stream of cooler of a cylindrical shape with high kinetic energy on the guiding surface of the deflector element 3, it "spreads" along this surface at a certain angle - the angle of the jet (β).
The magnitude of the angle of the jet depends on the angle of inclination α of the deflector element 3 to the axis of the nozzle 1 and the velocity of the jet (i.e., the pressure of the cooler in front of the nozzle). With a wide range of operating pressures, for example, from 0.2 to 1.0 MPa with a constant α, the angle β can vary by 15-25%. If necessary, to keep the geometric dimensions of the irrigation spot constant, the angle of inclination of the deflector element 3 to the axis of the nozzle from α to α _{i is} adjusted by means of an adjusting bolt 5. This allows you to change the cooling intensity without the formation of surface sections not overlapping by the jets.

 If necessary, expand or change the cooling rate required by the technology, which occurs, for example, when switching to another branded or profile assortment of cooled products, the relative position of the elastic plates 6 and nozzle 1 is adjusted. Within the angle of the jet opening, the guiding surface of the deflector element 3 acquires different lengths in different directions of motion of the individual flows of the cooler forming a stream. In this case, when the unit stream “runs off” from the guide surface, the cooler redistributes in the direction of reducing the hydrodynamic interaction of adjacent unit flows, that is, the flow parts begin to flow in the transverse direction. Each variant of arrangement of elastic plates 6 (Figs. 3, 4, 5) provides the possibility of redistributing the cooler within a constant opening angle β of the jet, as evidenced by the diagrams of the distribution of the cooler over the area of the irrigation spot (Fig. 6, 7, 8). The elastic plates 6 are made in plan according to a second-order curve, for example, an ellipse, which makes it possible to achieve smooth contours of the edge of the guide surface of the deflector element 3 for all possible arrangements of the elastic plates 6. The smooth contours of the edges of the guide surface facilitate uniform run-off of the cooler stream and improve the quality of rolling rolls due to the absence of sharp peaks in the diagrams of the distribution of the cooler over the area of the irrigation spot. This extends the technological capabilities of the cooling equipment, which allows for the cooling of the rolls to simultaneously implement the process of regulating the thermal profile of the roll, or in the same design of the cooling device to realize differentiated heat removal over the cross-section of the profiles with different metal consumption of the elements.

 The rational distribution of the cooler along the width of the irrigation spot allows to unify the design of cooling devices, thereby reducing the weight of the equipment by 2-5 times and the fleet of spare and replaceable parts by 8-10 times.

Claims (2)

 1. A device for cooling rolled products and rolls containing a nozzle for supplying a continuous stream of cooler and a deflector element located at an acute angle to the axis of the nozzle, characterized in that the deflector element is made in the form of at least three elastic plates assembled in a bag, installed with the possibility of independent movement and rotation relative to each other, and the nozzle outlet.  2. The device according to claim 1, characterized in that each elastic plate is made in plan according to a second-order curve.

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