In continuous casting installations for casting metal strands, rolls are used to guide the metal strand along a predetermined path after leaving the mold and to cool it and possibly support it. The rolls comprise rotatably mounted cylindrical rolls that are free rolling on a fixed axle. The cylindrical rolls rotate as the metal strands move over them. As these rolls are exposed to high temperatures in operation by being in direct contact with the glowing hot metal strands, cooling of the rolls is a high priority. This is typically conducted in a closed circuit by a feed of a coolant (in particular water) under pressure into the interior of the roll to dissipate the heat. Prior art systems typically have included complicated pressure control systems and sealing units that are prone to failure and require significant efforts for maintenance and repair. What is presented is a roll for high temperature environments that has an improved coolant circuit system that addresses some of the drawbacks of prior art systems.
The roll for continuous casting comprising a cylindrical roll rotatably mounted on a fixed axle. The axle comprising a coolant inlet system and a coolant outlet system. A cooling chamber is defined by the space between the interior of the cylindrical roll and the axle. The cooling chamber receives a flow of coolant. At least one spiral is formed onto the axle that creates a helical flow path from the coolant inlet system to the coolant outlet system. In some embodiments, two overlapping spirals are formed onto the axle. The spiral could comprise ¼″ wide flutes.
The coolant inlet system comprises a first coolant inlet into the axle located along the centerline of the axle and a first coolant outlet from the axle into the cooling chamber. A first fluid path through the axle directs coolant from the first coolant inlet to the first coolant outlet for the non-turbulent flow of coolant into the cooling chamber. The first coolant outlet directs the flow of coolant towards the spirals on the axle.
The coolant outlet system comprises a second coolant inlet into the axle from the coolant chamber. A second coolant outlet from the axle is located along the centerline of the axle. A second fluid path through the axle directs coolant from the second coolant inlet to the second coolant outlet for the non-turbulent flow of coolant.
In various embodiments, the coolant is water. The coolant may be introduced into the coolant chamber at a pressure of 80 psi. The coolant may be introduced into the coolant chamber at a rate of 5 gpm.
Those skilled in the art will realize that this invention is capable of embodiments that are different from those shown and that details of the devices and methods can be changed in various manners without departing from the scope of this invention. Accordingly, the drawings and descriptions are to be regarded as including such equivalent embodiments as do not depart from the spirit and scope of this invention.
For a more complete understanding and appreciation of this invention, and its many advantages, reference will be made to the following detailed description taken in conjunction with the accompanying drawings.
Referring to the drawings, some of the reference numerals are used to designate the same or corresponding parts through several of the embodiments and figures shown and described. Corresponding parts are denoted in different embodiments with the addition of lowercase letters. Variations of corresponding parts in form or function that are depicted in the figures are described. It will be understood that variations in the embodiments can generally be interchanged without deviating from the invention.
Because each roll 10 comes in direct contact with the metal strands, heat transfer and cooling of each roll 10 is essential. It has been determined that the heat transfer system disclosed herein provides a better metal strand product that is less prone to cracking and warping as the metal stand cools along the path of rolls 10. The cylindrical rolls 14 are typically constructed of stainless steel, but any other appropriate material may be used that can bear the weight and heat of the metal strands that they are required to come in contact with.
As best understood by comparing
The cooling chamber is fed with a coolant liquid through a coolant inlet system that feeds coolant into the cooling chamber 23. Low temperature coolant flows into the cooling chamber through the coolant inlet system and heated coolant is drained from the coolant chamber through a coolant outlet system. In prior art axles 12a, as shown in
As best understood by comparing
The coolant inlet system of this roll 10 is different that what is presented in the prior art. The coolant inlet system comprises a first coolant inlet 24 into the axle 12 that is located along the centerline of the axle 12. A first coolant outlet 26 from the axle 12 leads into the cooling chamber 23. A first fluid path 34 through the axle 12 from the first coolant inlet 24 to the first coolant outlet 26 provides non-turbulent flow of coolant into the cooling chamber. As can be seen in
The coolant outlet system is like the coolant inlet system. A second coolant inlet 28 drains into the axle 12 from the coolant chamber 23. The second coolant outlet from the axle 12 is located along the centerline of the axle 12. A second fluid path 36 through the axle 12 from the second coolant inlet 28 to the second coolant outlet 30 provides non-turbulent flow of coolant out of the roll 10.
The coolant used in the system can be any coolant system that is typical for this type of system, but the preferred coolant is water. The system shown allows coolant introduction at various pressures, but it is the preferred that coolant is introduced into the coolant chamber at a pressure of 80 psi. Coolant introduction flow rate into the coolant chamber is 5 gpm.
Testing was conducted comparing the spiral configuration shown in
The prior art system, of course, did not have spirals on the axle. The spiral axle system experienced about 2.4 times greater fluid velocity through the roll. Higher coolant velocity means heat is pulled away from the cylindrical roll at faster rates which helps prevent the roll from overheating. An overheated roll can eventually cause defects on the metal slabs that roll over it.
The two spirals on the axle help direct the coolant flow around the axle, which eliminates hot spots. Having a predetermined coolant flow path reduces the chance for cavitation in the roll body. Cavitation leads to air bubbles and pockets which impede heat transfer. Air bubbles act as insulation preventing heat transfer to the coolant inside the roll body.
The tests show an increased water velocity in the spiral axle roll cavity over prior art systems given the same coolant supply properties. The spiral axle configuration reduces the opportunity for turbulence to occur. The fluid paths coolant inlet system and the coolant outlet system for in the spiral axle configuration further reduces the opportunity for cavitation to occur. The first coolant inlet and the second coolant outlet direct coolant to enter and exit the axle through the centerline of the axle. Prior art systems direct coolant to enter and leave the axle at 90° to the axle which can initiate turbulences in the coolant flow. The spiral axle configuration can be scaled up or down by increasing the length of the axle depending on specific application requirements, however the water flow properties will remain constant.
This invention has been described with reference to several preferred embodiments. Many modifications and alterations will occur to others upon reading and understanding the preceding specification. It is intended that the invention be construed as including all such alterations and modifications in so far as they come within the scope of the appended claims or the equivalents of these claims.
Number | Date | Country | |
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62646746 | Mar 2018 | US |