RU2203756C2 - Cooling container with vertically moving platform for coil - Google Patents

Abstract

FIELD: rolled stock production, namely improved process for decelerating cooling of hot rolled products in heat insulation containers called "pot". SUBSTANCE: apparatus for receiving continuously fed turns of hot rolled product includes: a) movable container having vertical cylindrical lateral wall open at upper and lower ends; base on lower end of wall for removably mounting container in zone for forming coil; horizontal shelf extending inside from inner surface of wall and central core resting upon shelf in such a way that it is spaced from inner surface of wall and forms annular chamber; through grooves communicated with chamber and provided in flange; b) elevator platform placed in zone of forming coil and having carrying members arranged in such a way that to provide passing along through grooves of shelf; c) mechanism for controlling vertical position of elevator platform by moving carrying members in through grooves of shelf between slightly raised working positions between which carrying members inside chamber carry coil formed by receiving turns from open upper end of container and idle position under shelf after achieving which coil is arranged on shelf. EFFECT: minimum volume of coil having maximum stability. 9 cl, 6 dwg

Description

FIELD OF THE INVENTION
The present invention mainly relates to rolling mills producing rolled steel products, long products, wire rod and the like, and, in particular, to improving the method of slowing down the cooling of such products in heat-insulating containers, referred to as "pots".

State of the art
Widely known methods for the manufacture of hot-rolled steel products, such as long products, wire rod, etc., in the form of spiral turns, collected in a riot in a heat-insulating container. The disadvantage of such devices is that the height at which the turns are lowered into the container varies significantly from the beginning to the end of the riot formation cycle. Changing the descent height negatively affects the uniformity of distribution and the density of turns from the bottom to the top of the riot, is the cause of instability of the riot, as well as an increase in the volume of the riot.

 The closest analogue of the claimed invention is the technical solution described in patent US 5735477, cl. B 21 C 47/02, 04/07/1998. A known device for receiving a continuous sequence of turns of a hot-rolled product includes a container located below the feed end of the conveyor along the vertical to the base located below the carrier. The carrier is equipped with a vertical core, around which rings are collected, forming a cylindrical coil.

 The device is equipped with gripping elements designed to prevent stall rings. A disadvantage of the known device is the insufficient density and uniform distribution of the turns of the product from the bottom to the top of the riot.

SUMMARY OF THE INVENTION
The main objective of the present invention is the creation of an improved container and interacting support for the riot, working together so that the top of the riot during its formation in the container remained at an optimum substantially constant height. When this condition is fulfilled, the density and distribution of turns are essentially optimal and constant from the bottom to the top of the riot, which, in turn, means achieving a minimum volume of the riot and maximum stability of the riot.

 A device for receiving a continuous sequence of turns of a hot-rolled product according to the invention comprises a container made with the possibility of movement and having a vertical cylindrical side wall open at the upper and lower ends, a base at the lower end of the wall to allow installation of the container with the possibility of removal in the riot formation area, a horizontal shelf with grooves extending inwardly from the inner surface of the wall, on which the central core, spaced from the inner the wall surface with the formation of an annular chamber, while the passage grooves of the shelf are in communication with the annular chamber, an elevator platform with load-bearing elements designed to pass through the passage grooves in the shelf located on the riot formation section, and a device for adjusting the vertical position of the elevator platform by moving the bearing elements through the grooves in the shelf between the raised working positions, between which on the supporting elements introduced into the chamber, a riot is located, forming my reception by coils through the open upper end, and an inoperative position beneath the shelf, at which riot placed on the shelf.

 Preferably, the shelf is made in the form of spaced around the circumference of the sectors with grooves between them.

 The core of the device can be made in the form of spaced apart ribs mounted vertically on the supporting elements of the shelf.

 The upper ends of the ribs may be connected by a tip.

 It is advisable that the tip was placed below the upper end of the wall for the formation of the upper cavity, designed to be placed in it with the possibility of extracting a thermally insulating top cover.

 It is also advisable that the shelf was placed above the lower end of the side wall to form a lower cavity intended for placement in it with the possibility of extracting a thermally insulating lower cover.

 It is preferable that the base rests on a roller conveyor in the forming portion, wherein the conveyor rollers are placed to form a passage aligned with the passage grooves in the shelf.

 The device may have rail elements protruding from the side wall into the cavity and placed with the possibility of a gap between the outer surface of the riot and the inner surface of the side wall.

 The elevator platform during vertical movement can be guided by rail elements.

 These and other objects and advantages of the present invention are described in detail below with reference to the accompanying drawings.

 The list of figures drawings.

 Figure 1 - schematic image of the discharge end of the rolling mill.

 FIG. 2 is a vertical section through a riot forming section represented by 1 when the elevator platform is fully lowered below the level of the roller table.

 FIG. 3 - cross section along the line 3-3 by 2.

 FIG. 4 is a view of a portion shown in 2 when the elevator platform is in a raised position during a riot formation operation.

 FIG. 5 is another view similar to that shown in FIG. 2, showing a fully formed riot in a container closed by lower and upper heat-insulating lids.

 6 is a view in plan of the roller table forming the riots of the plot.

 Information confirming the possibility of carrying out the invention.

 As can be seen in FIG. 1, the discharge end of the rolling mill has an installation 10 of pulling rollers guiding the hot-rolled bar 12 or other similar product into an inclined stacking mechanism 14, which deforms the product into a continuous sequence of turns 16. The turns are superimposed on each other with the centers shifted, arrive on the conveyor 18, which moves them to the forming section 20. Insulating casings 22 can be installed above the conveyor to slow down the cooling rate of the turns. In the riot-forming portion, the turns fall from the conveyor into a movable heat-insulating container 24, usually referred to as a “pot”, in which they form a vertically standing cylindrical riot. After filling, the container is moved to the next section 26, where the riot is cooled at a slower speed before being removed from the container.

 2 and 3, the container 24 according to the present invention is shown standing on a roller table 28 of the forming portion 20. The container has a vertical heat-insulating side wall 30 and is open from the upper and lower ends. The frame base 32, having a Central hole, is used to install the container on a roller table. Truncated sectors 34, resembling pieces of cake, a horizontal shelf protrude from the inner surface of the side wall. The inner ends of the shelf sectors 34 are vertically placed racks 36 of the Central core 38. The upper ends of the racks 36 of the core are connected by a tip 40. The core 38 is located along the Central axis of the side wall 30 and is separated from it to form an annular chamber 42. Sectors 34 of the shelves are spaced from each other circles for the formation of grooves communicating with vertical openings between the uprights 36 of the core.

 The vertical guide rails, indicated by 44, are attached to the inner surface of the side wall 30. The rails protrude inside the annular chamber 42 and, as will be explained below, serve to prevent the coils accumulating in the container from contacting the side wall 30, thereby providing uniform delayed motion. cooling.

 As shown in Fig.6, the rollers 46 of the roller table are spaced from each other and are located so that between them there is a cross-shaped passage 48, the shoulders of which are aligned with the passage grooves between the sectors 34 of the shelf.

 The elevator platform 50 is located under the roller table 28 so that it can move vertically through the cross path 48. The elevator platform is essentially cross-shaped and its shoulders 52 are provided with guide rollers 54. Crossed shoulders 52 are aligned with a cross path 48 between table rollers 46, as well as through grooves between sectors 34 of the shelf and vertical openings between the uprights 36 of the core. Vertical movement of the elevator platform is accomplished by a suitable mechanism, an example of which is drive 56, which defines axial movement using a rigid chain drive manufactured by Serapid USA, Inc., Troy, Michigan.

 4, the elevator platform 50 is pulled into the container 24 during operation, while the rollers 54 and the corresponding rails 44 define the direction of its movement. The turns 16 enter through the open top of the container. The turns are piled onto a raised platform 50, gathering in a riot around the central core 38. The platform 50 is gradually lowered to keep the top of the growing riot at the optimum level "L", so that the height of the fall of the turns remains essentially constant. After the operation of forming a riot, the platform is lowered below the roller table, so that the riot is on sectors 34 of the shelf.

 It should be noted that the upper end of the central core 38 is located below the upper end of the wall 30 to form the upper cavity 58. Similarly, the sectors 34 of the shelf are located above the lower end of the wall 30 to form the lower cavity 60. After the formation of the riot, as shown in FIG. 5, the upper and lower heat-insulating covers 62, 64 are inserted into the upper and lower cavities 58, 60, respectively, to completely insulate the riot in the container.

 All changes and modifications of the above device, without going beyond the essence and scope of the present invention, are defined by the attached formula.

Claims (9)

 1. Device for receiving a continuous sequence of turns of a hot-rolled product, containing a container made with the possibility of movement and having a vertical cylindrical side wall open at the upper and lower ends, a base at the lower end of the wall to enable installation of the container with the possibility of removal on the plot of formation of the riot, horizontal a shelf with grooves extending inwardly from the inner surface of the wall, on which the central core, spaced from the inner surface of the ki with the formation of an annular chamber, while the passage grooves of the shelf are in communication with the annular chamber, an elevator platform with load-bearing elements designed to pass through the passage grooves in the shelf, located on the plot of the riot, and a device for regulating the vertical position of the elevator platform by moving the bearing elements through grooves in the shelf between elevated working positions, between which on the supporting elements introduced into the chamber there is a riot formed by ma turns through an open upper end, and an inoperative position beneath the shelf, at which riot placed on the shelf.  2. The device according to claim 1, characterized in that the shelf is made in the form of sectors spaced around the circumference with through grooves between them.  3. The device according to p. 1, characterized in that the core is made in the form of spaced apart ribs mounted vertically on the supporting elements of the shelf.  4. The device according to p. 3, characterized in that the upper ends of the ribs are connected by a tip.  5. The device according to p. 4, characterized in that the tip is located below the upper end of the wall to form an upper cavity designed to be placed in it with the possibility of extracting a thermally insulating top cover.  6. The device according to p. 1, characterized in that the shelf is placed above the lower end of the side wall to form a lower cavity, designed to be placed in it with the possibility of removing the lower thermally insulating cover.  7. The device according to claim 1, characterized in that the base rests on a roller conveyor in the forming section, while the conveyor rollers are placed with the formation of the passage combined with the grooves in the shelf.  8. The device according to p. 1, characterized in that it has rail elements protruding from the side wall into the cavity and placed with the possibility of a gap between the outer surface of the riot and the inner surface of the side wall.  9. The device according to p. 8, characterized in that the rail elements are designed to guide the elevator platform during its vertical movement.

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