The invention relates to a thermal controlled treatment of rails and to a flexible cooling system to carry out the method. The treatment is designed for obtaining fully high performance bainite microstructure characterised by high strength, high hardness and good toughness in the whole rail section and, also, for obtaining fully pearlite fine microstructure in a selected portion of the rail section or in the whole rail section.
Nowadays, the rapid rise in weight and speed of trains, has inevitably forced to enhance the rails wear rate, in terms of loss of material due to the rolling/sliding between wheel and rail, and therefore an increasing of hardness has been required in order to reduce wear.
Generally, the final characteristics of a steel rail in terms of geometrical profiles and mechanical properties are obtained through a sequence of a thermo-mechanical process: a hot rail rolling process followed by a thermal treatment and a straightening step.
The hot rolling process profiles the final product according to the designed geometrical shape and provides the pre-required metallurgical microstructure for the following treatment. In particular, this step allows the achievement of the fine microstructure which, through the following treatments, will guarantee the high level of requested mechanical properties.
At present, two main hot rolling processes, performed in two kinds of plant, reversible and continuous mills, are available. The final properties of a rail produced by both of these hot rolling processes can be assumed as quite similar and comparable. In fact, bainitic, pearlitic and hypereutectoidic rails are commonly obtained at industrial level through these both kinds of plant.
The situation for thermal treatments is different. At present, there are mainly two means used to cool the rails: air or water. The water is typically used as liquid in a tank or sprayed with nozzles. Air is typically compressed through nozzles. None of these arrangements allows producing all the rail microstructures with the same plant. In particular, a thermal treatment plant tuned for production of pearlitic rails cannot produce bainitic rails.
Further, present cooling solutions are not flexible enough and therefore, it is not possible to treat the whole rail section or portions of the rail section in differentiated ways (head, web, foot).
Furthermore, in all the present industrial apparatus for thermal treatment of rails, most of the transformation of austenite occurs outside the cooling apparatus itself, this means that the treatment is not controlled. In particular, the increase of rail temperature due to the microstructure transformation cannot be controlled. In these processes the temperature at which austenite transformation occurs is different than the optimal one, with final mechanical characteristics lower than those potentially obtainable by finer and more homogeneous microstructures. This could be particularly true in case of bainite rails, where bainite microstructure has to be obtained in the whole rail section (head, web and foot).
Moreover, due to the real thermal profile of the rail along the length, a non controlled thermal treatment, can conduct to microstructures inhomogeneity also along the length.
U.S. Pat. No. 7,854,883 discloses a system for cooling a rail wherein only fine pearlite microstructure can be obtained. According to this document, a fine pearlite microstructure is created into the rail to increase the rail hardness. However, fine pearlite microstructure means high level of hardness but with degradation of elongation and toughness of the product. Elongation and toughness are also important mechanical properties for rails applications; in fact, both are related to the ductility of the material, an essential property for rail materials for the resistance to crack growth phenomena and failures.
Recent studies pointed out also to another particular and dangerous phenomenon, prevalent in pearlitic materials due to the particular chemical composition that affects the integrity of the rail during service. The discover concerned the formation of a martensitic layer, called White Etching Layer (WEL), in the contact sliding area between wheel and rail, especially due to the generation of high temperatures during severe accelerations and decelerations or surface mechanical attrition treatment. Due to its hard and brittle property WEL is usually believed to be the location of crack formation, with a consequent negative effect on the rail lifetime. The WEL formed in the bainitic steel rails has low hardness; therefore, a smaller difference in hardness compared to the base material is present. The reason is that the hardness of the martensitic layer mainly depends on the C content (higher the carbon and higher the hardness of the layer) and the quantity of carbon in bainitic chemical composition is lower than those present in pearlitic microstructure. From some researcher, WEL is considered as one of the cause of rolling contact fatigue. From studies on these topics appear that the bainitic steel rail showed at least twice the time for crack nucleation than that of the pearlitic steel rail.
High performance bainite microstructure is an improvement in respect to fine pearlite microstructure in terms of both wear resistance and rolling contact fatigue resistance. Further, high performance bainite microstructure allows enhancing toughness and elongation, keeping hardness greater than fine pearlite microstructure.
High performance bainite microstructure shows a better behaviour at following phenomena in comparison with fine pearlite microstructure: short and long pitch corrugation, shelling, lateral plastic flow and head checks. These typical rail defects are amplified by train acceleration and deceleration (e.g. Underground lines) or in low radius curves.
Furthermore, bainitic steel shows also higher values of ratio between yield strength and ultimate tensile strength, tensile strength and fracture toughness compared to the best heat-treated pearlitic steel rails.
Therefore there is a need to have a new thermal treatment method and system allowing obtaining rail with good hardness but without any degradation of the other important mechanical properties as for example elongation and toughness. In this way, the resistance of the rail to the wear and to rolling contact fatigue would be improved and crack propagation would be decreased.
The main objective of the invention is therefore to provide this kind of process and apparatus.
A companion objective of the present invention is to provide a thermal treatment process which allows the formation high performance bainite microstructure in the rail.
Another objective of the present invention is to provide a process and system allowing in the same plant production of rail having fine pearlite microstructure.
According to other features of the invention taken alone or in combination:
According to a second aspect, the invention concerns a system for thermal treatment of a hot rail to obtain a desired microstructure having enhanced mechanical properties, the system comprising:
According to other features of the invention taken alone or in combination:
Other objects and advantages of the present invention will be apparent upon consideration of the following specification, with reference to the accompanying drawings wherein:
Alternatively, in a off-line embodiment (not shown on the drawings), instead of coming directly from the last rolling stand, the product, in an rolled condition, entering the reheating unit can be a cold rail coming from a rail yard (or from a storage area).
Each cooling module 12.n comprises a plurality of aligned cooling section. Each cooling section comprises nozzles located in the same plan define by a transversal cross section of the rail.
Each nozzle N1-N6 can spray different cooling medium (typically water, air and a mixture of water and air). The nozzles N1-N6 are operated by the control means 15 individually or in group, depending on the targeted final mechanical characteristics of rail.
The exit pressure of each nozzle N1-N6 can be chosen and controlled independently by the means 15.
Due to its geometry the corner of the rail head is a part naturally subjected to a higher cooling relative to the other head areas; acting directly with a cooling mean on the corners of the head could be dangerous and could overcool the head corners which in turn brings to the formation of bad microstructure like martensite or low quality bainite. This why nozzles N2 and N3 are located on the sides of the head, and are arrange to spray the cooling medium on the sides of the head of the rail, and to avoid spraying on the top corners of the rail. In one embodiment nozzles N2 and N3 are located transversal (perpendicular) to the travelling direction of the rail.
The control of the parameters of each nozzle by the control means 15 enables:
All information concerning the temperature are provided to the control means 15 as data to control the rail cooling process.
The control means 15 control the rail thermal treatment by controlling the parameters (flow rates, temperature of the cooling medium, and pressure of the cooling medium) of each nozzle of each cooling module and also the entry rail velocity. In other words, the flow, pressure, number of active nozzles, position of the nozzles and cooling efficiency of every nozzle group (N1, N2-N3, N4-N5 and N6) can be individually set. Any module 12.n can therefore be controlled and managed alone or coupled with one or more modules. The cooling strategy (e.g. heating rate, cooling rate, temperature profile) is pre-defined as a function of the final product properties.
The flexible thermal treatment system, comprising the above mentioned control means 15, the cooling modules 12.n and the measuring means T and S, is able to treat rails with an entry temperature in the range of 750-1000° C. measured on the running surface of the rail 6. The entry rail speed is in range of 0.5-1.5 m/s. The cooling rate reachable is in the range of 0.5-70° C./s as function of desired microstructure and final mechanical characteristics. The cooling rate can be set at different values along the flexible thermal treatment apparatus. The rail temperature at the thermal treatment system exit is in the range of 300-650° C. The rail hardness in the case of high performance bainite microstructure is in the range of 400550 HB, in the case of fine pearlite microstructure is in the range of 320-440 HB.
During step 100 a plurality of setting values are introduced in the cooling control means 15. In particular:
At step 101, the setting values are provided in different embedded models (hosted by the computerised control means 15) that work together in order to provide the best cooling strategy. Several embedded numerical, mechanical and metallurgical models are used:
The embedded process models define the cooling strategies in terms of heat to be removed from the profile and along the length of the rail taking into account entry rail velocity. A specific cooling strategy in function of time is proposed such that the amount of austenite transformed is not lower than 50% on rail surface and not lower than 20% at rail head core at the exit of the flexible thermal treatment system. This means that the above mentioned transformation occurs while the rail is still inside the thermal treatment system and not outside, after or downstream this system. In other words, for a transversal cross section of a rail advancing within the thermal treatment system 12, the above mentioned transformation occurs between the first and the last cooling sector of the system. This means that this transformation is fully controlled by the thermal treatment system 12. An example of cooling strategy computed by the embedded process models is given by the curves of
At step 102 the control system 15 communicates with the data libraries 16 in order to choose the correct thermal treatment strategy, after the evaluation of the input parameters.
The pre-set thermal treatment strategy is then fine-tuned taking into account the actual temperature, measured or predicted during the rail process route. This guarantees the obtainment of expected level of mechanical characteristics all along the rail length and through transverse rail section. Very strict characteristic variation can be obtained avoiding formation of zone with too high or too low hardness and avoiding any undesired microstructure (e.g. martensite).
At step 103, the control means 15 show the computed thermal treatment strategy and the expected mechanical properties to the user, for example on a screen of the control means 15. If the user validates the computed values and accept the cooling strategy (step 103), settings data are submitted to the cooling system at step 104.
If the user does not validate the cooling strategy new setting data are provided by the user (step 105 and 106) and step 101 is executed.
Further at step 107 a first cooling modules set up is carried out. The suitable parameters (e.g. pressure, flow rate) are provided to each module according to the optimized cooling strategy suggested by the process models at step 101. At this step, the cooling flux (or rate) is imposed to the different nozzles of the different modules of the cooling system 12 in order to guarantee the obtainment of the target temperature distribution in due time.
At step 108 measures of surface temperatures of the rail 6 coming from the hot rolling mill 10 or from a rail yard (or storage area) are taken before the rail enter each cooling module 12.n, for example upstream of cooling module 12.1. The temperature measuring devices T take temperature measures continuously. This set of data is used by the thermal treatment system 12 to impose the fine regulation to the automation system in terms of cooling flux in order to take into account the actual thermal inhomogeneity along the rail length and across the rail section.
At step 109 the measured temperatures are compared with the ones calculated by the process models at step 101 (temperature that the rail should have at the location of the current temperature measuring device). If the differences between the temperatures are not bigger than predefined values, the cooling pre-set parameters are applied to drive the cooling modules.
In case of differences, between the calculated temperature and the measured temperatures, at step 111 the pre-set value of heat flux removal for the current module of the cooling module 12.n is consequently modified with values taken from the data libraries 16, and at step 112 the new values of heat flux removal (or cooling rate) are applied to control the cooling modules.
At step 113, if there is other modules step 108 is repeated and a new set of temperature profile of the rail surface is measured in step 108.
At step 114, at the exit of the last cooling module 12.n of the flexible cooling system 12 a final temperature profile is taken. The cooling control means 15 calculate the remaining time for cooling down the rail till ambient temperature on the cooling bed. This is important to estimate the progression of the cooling process across the rail section.
At step 115, the real cooling strategy previously applied by the cooling system is provided to the embedded process models in order to obtain the mechanical properties expected for the final product, and at step 116 the expected mechanical properties of the rail are delivered to the user.
In
As can be seen, on
From the austenite decomposition curve of a controlled thermal treatment, shown in
Two examples of targeted temperature evolutions in three different points, in the section of a rail, cooled according to the invention are shown in
The system parameters (water and/or air flow rate) are controlled in order that the temperatures of different points of the rail match the temperatures provided by these curves. In other words these curves give the target evolution of temperature values of predefined set points across the rail section.
Following the temperature provided from the models, the rail is controlled to enter the first module with a temperature of about 800° C. Subsequently, in a phase Ia the rail skin (curve 1) is fast cooled by the first two cooling modules down to a temperature of 350° C. with a cooling rate in this example of approximately 45° C./s. Here, fast cooling means a cooling with a cooling rate comprised between 25 and 70° C./s.
After this fast cooling phase, the rail is soft cooled by the remaining cooling nozzles of the first cooling modules, and by the remaining cooling modules. For example in a phase Ib, the rail is cooled with a cooling rate of approximately 13° C./s. Between the end of the phase Ib (exit of the first cooling module) and the entry in the second cooling module materialised by the vertical dotted line B, the rail skin is naturally heated by the core of the rail and the rail skin temperature increases. Thereafter, the rail enters the second cooling module (phase II) and the rail is cooled with a cooling rate of approximately 8.7° C./s. Subsequently the rail enters the third and fourth cooling modules (in phases III and IV) and is cooled with approximate cooling rates of respectively 2.7 and 1.3° C./s. Of course between the exit of each cooling module 12.n and the entry of the next cooling module, natural increase of the skin temperature of the rail occurs due to the rail core temperature. Here, soft cooled means a cooling rate comprises between 0.5 and 25° C./s.
In case of entering temperature higher of 800° C. the modules acting in area Ib will be controlled such that to also produce fast cooling.
The final microstructure is fully bainite with hardness on the rail head in the range of 384-430 HB as shown in
Following the temperature provided from the models, the rail is controlled to enter the first module with a temperature in a range of about 850° C. Subsequently, in a phase Ia the rail skin is fast cooled by the first cooling module down to a temperature of about 560° C. with a cooling rate in this example of approximately 27° C./s. Here, fast cooling means a cooling with a cooling comprised between 25° C./s to 45° C./s.
After this fast cooling phase, the rail is soft cooled by the remaining cooling nozzles of the first cooling modules, and by the remaining cooling modules. For example in a phase Ib, the rail is cooled with a cooling rate of approximately 8° C./s. Between the end of the phase Ib (exit of the first cooling module) and the entry in the second cooling module materialised by the vertical dotted line B, the rail skin is naturally heated by the core of the rail and the rail skin temperature increases. Thereafter, the rail enters the second cooling module (phase II) and the rail is cooled with a cooling rate of approximately 4° C./s. Subsequently the rail enters the third and fourth cooling module (in phases III and IV) and is cooled with approximate cooling rates of respectively 1.8 and 0.9° C./s. Of course between the exit of each cooling module 12.n and the entry of the next cooling module natural increase of the skin temperature of the rail occurs due to the rail core temperature.
Here, soft cooled means a cooling rate comprised between 0.5 and 25° C./s.
In case of entering temperature of higher than 850° C. the modules acting in area Ib will be controlled such that to also produce fast cooling.
After the above mentioned process, the final microstructure is fine pearlite with hardness on the rail head in the range of 342-388 HB as shown in
The above mentioned curves are the cooling strategy adopted according to the invention. In other words, each nozzle is controlled such that the temperature distribution across the rail section follows the curves of
The present invention overcomes the problems of the prior art by means of fully controlling the thermal treatment of the hot rail until a significant amount of austenite is transformed. This means that the austenite transformation temperature is the lowest possible to avoid any kind of secondary structures: martensite for high quality bainitic rails and martensite or upper bainite for pearlitic rails.
As above shown, the process according to the invention is designed for obtaining fully high performance bainite microstructure characterised by high strength, high hardness and good toughness in the whole rail section and, also, for obtaining fully pearlite fine microstructure in a selected portion of the rail section or in the whole rail section.
The process is characterised by a significant amount of austenite transformed to the chosen bainite or pearlite microstructures when the rail is still subjected to the cooling process. This guarantees the obtainment of a high performance bainite or fine pearlite microstructures. In order to correctly impose the requested controlled cooling pattern to the rail along all the thermal treatment, the flexible cooling system includes several adjustable multi means nozzles typically, but not limited to, water, air and a mixture of water and air. The nozzles are adjustable in terms of on/off condition, pressure, flow rate and type of cooling medium according to the chemical composition of the rail and the final mechanical properties requested by the rail users.
Process models, temperature monitoring, automation systems are active parts of this controlled thermal treatment process and allow a strict and process control in order to guarantee high quality rails, a higher level of reliability and a very low rail rejection.
The rails so obtained are particularly indicated for heavy axle loads, mixed commercial-passenger railways, both on straight and curved stretches, on traditional or innovative ballasts, railway bridges, in tunnels or seaside employment.
The invention also allows obtaining a core temperature of the rail close to the skin temperature and this homogenises the microstructure and the mechanical features of the rails.
Number | Date | Country | Kind |
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12425110 | Jun 2012 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2013/061793 | 6/7/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2013/186137 | 12/19/2013 | WO | A |
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