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    • 专利摘要:
    The present invention presents a method for manufacturing rollers (1) of multimaterial, in which the method comprises manufacturing a part of the preform (1 ') consisting of base material (B), joining another part consisting of special material (A) with this part, hot working of the preform (1 ') of the roll consisting of the part of base material (B) and the part of special material (A), the hot working being done for at least a part of the length of the preform (1') so that at least a desired length (Lv ) and diameter (Hv) are obtained by hot working and final treatment of the hot preform (1 ') to produce a finished roll (1). With the method it is possible to manufacture large rollers (1), for example with a length (Lv) over 3 m, as a single piece without welding and mechanical joints so that on the working surfaces (2) of the rollers there are steels containing abundant alloying elements and carbides formed by alloying substances.
    公开号:FI20197024A1
    申请号:FI20197024
    申请日:2019-02-14
    公开日:2020-08-14
    发明作者:Mikko Talvitie
    申请人:Kerpua Solutions Oy;
    IPC主号:
    专利说明:

    METHOD - FOR THE MANUFACTURE OF A MULTI - MATERIAL ROLLER - AND MULTI-MATERIAL ROLLER
    FIELD OF THE INVENTION The invention relates to a method for producing a roll for hot and cold rolling metallic materials made of at least two different materials and to such a roll.
    BACKGROUND OF THE INVENTION Rollers, especially work rolls, are used for hot and cold rolling of metallic materials such as steel, copper, aluminum and titanium. Work rollers are subjected to considerable mechanical, thermal and chemical loads during use. The amount and type of load varies in different areas of the rollers. On rolling surfaces, the surface of the roll is subjected to thermal stresses during hot rolling, including stress fluctuations due to temperature fluctuations. In addition, the rolling forces cause mechanical loads on the surface of the roll. The oxides on the surface of the hot rolled material cause abrasive wear on the work surface of the roll, and adhesive wear even causes the material to rupture from the work surface of the roll as the material to be rolled is welded to the surface of the roll. In hot rolling, high temperatures also cause oxidation of the work surface and coolants used to cool the surface may increase corrosion. In cold rolls, the surface is subjected to significant loads that promote surface fatigue and adhesion, which gradually degrade the surface quality and thus the surface quality achieved by rolling = the surface quality achieved. Thus, the surface damage mechanisms vary N depending on the type of rolling application (hot or cold rolling) and the type and shape of materials to be rolled (e.g. sheets or bars).
    I E 30 The other areas of the roll are subjected to considerably different stresses compared to the working surface of the roll, N, which is in contact with the material to be rolled. The roll shafts on which the roll> can be rotated and through which the drive motors of the roll can rotate the roll are subjected to N particularly significant mechanical loads due to rolling forces. Adequate mechanical properties, material strength, surface quality and design of the roller shafts enable the mechanical reliability of these areas and prevent damage, for example due to fatigue. Due to the different damage mechanisms of the roller work surfaces, the preferred material choices also vary | by application. Typically, the rollers - work surfaces = materials - should be as homogeneous in behavior as possible to avoid uncontrolled fluctuations in life or expected damage. In addition, the material should have as few different material defects as possible, such as inclusions, cracks, or pores, which could cause even macroscopic damage to the rollers, for example, when fatigue damage begins from these initial defects.
    Various cast and forged iron-based materials are currently used as the materials of the work rolls, = - the properties of which have been - sought - to be - developed - inexpensive - for various uses. In the case of both forged and cast rolls, the restrictions caused by the choice of material and the development of material properties - made difficult - by the manufacturing methods - in order to increase the alloy content, e.g. to improve wear resistance, temperature resistance or mechanical properties. In particular, large cast and forged products, including rolls, have a large grain size, a coarse cast structure and a more inhomogeneous alloy distribution than smaller products, including rolls, for manufacturing reasons, which makes it difficult to improve the quality and service life of rolls.
    The properties of the materials can be improved by alternative manufacturing methods such as powder metallurgical and melt-based technologies as well as, for example, electroslag smelting. With all these methods, it is possible to improve the homogeneity of the roll materials. In addition, powder metallurgical and melt deposition-based methods in particular can increase the alloy content more than some other methods, for example according to casting or electro-slag smelting technology, in order to improve the service life of the rolls without N significant manufacturing problems. On the other hand, the manufacturing costs + of these methods are higher than with forged or cast materials. This is due not only to the manufacturing technology itself due to more expensive production equipment and complex manufacturing solutions E 30, but also to the higher alloying used to increase service life. <+ = o Efforts have been made to reduce the use and production costs of raw materials, especially special raw materials, by manufacturing larger rolls in particular, so that, for example, high-alloy powder raw materials are used only on rolling mills, with the rest of the rolls being forged or cast low-alloy material. Also by conventional methods such as centrifugal casting, multilayer rolls can be produced, for example by casting on a rotating die, for example, high-alloy tool steel and then low-alloy cast iron as the base material of the roll, for example. However, centrifugal casting methods do not achieve the same homogeneity and optimization of carbide size and degree of alloying as, for example, rolls coated with powder metallurgy or molten deposited tool steels. One limitation of powder metallurgical and, for example, melt-deposited methods relates to the size limitations of their manufacture. In the manufacture of powder metallurgical rollers, Hot Isostatic Pressing (HIP) is used in the manufacture of the products, which is carried out in a special pressure vessel capable of high simultaneous isostatic pressing and high temperature. As the size of the pieces to be manufactured increases, the required size of these pressure vessels and the energy and space requirements of the process increase correspondingly. The investment and operating costs of these pressure vessels also increase significantly as the size increases. In addition, there are currently not large enough pressure vessels to make the largest rolls, which limits the use of high alloy powder metallurgical rolls in large rolls. Large rollers typically refer to rolls longer than 3.5 meters or more than 4 meters. Roll length refers to the dimension of the finished roll that is largest. In general, this largest dimension is the longitudinal dimension along the axes of the roll. This applies to both monolithic or single material rollers and multi-material rollers, i.e. rolls made of more than one material. In thermostatic compression, impurities may remain on the interfaces of large bodies and hot working reduces their effect on the mechanical properties of the interface. In addition, heat treatment widens the diffusion area between the coating and the base material, which makes the interface less S steep and thus may reduce the interface stresses. OF
    S + The same size limitation as in the case of thermostatic pressing also applies to the use of substance-adding> manufacturing methods such as melt deposition or 3D printing - in the manufacture of E 30 rolls. For example, it is very difficult and expensive to produce large N rolls by melt deposition, and the production equipment currently in use is not capable of producing the largest> rolls. Increasing the size of the roll blank in the molten layer degrades the metallurgical quality of the product N, slowing down the cooling and solidification of the metal droplets, which makes the solidification structure rougher, increases the grain size and causes the formation of carbide networks. Melt deposition can also be used to make multi-material blanks, for example, by melt deposition of a more durable material on the portion of the solid base material that corresponds to the work surface of the roll to be fabricated. However, melt deposition generally does not achieve as reliable a connection between the material to be melt deposited and the base material as, for example, thermostatic compression. In addition, when melt-coated, the properties of the material, at least in thick layers of material and high-alloy materials, are not sufficient, at least for all rolling applications, due to the pores in the structure and partly continuous coarse carbide networks.
    It is also possible to manufacture multi-material rolls by casting a special material in the rolling area of the base material which is more durable than the coating. One significant limitation of such a casting method is that the microstructure of the material so cast is coarse and inhomogeneous, and in addition it may contain casting defects that impair mechanical properties. In addition, it is possible that the joint strength is not good enough for the loads during use of the roll.
    On the other hand, the casting method has been utilized in a centrifugal casting method, in which a more durable material forming the work surface is cast into a rotary casting die and then, for example, low-alloy cast steel or cast iron forming the roll body. The method allows a better connection between different materials. On the other hand, the surface layer thus obtained is still a casting material, which is limited by the limitations of normal casting steels, i.e., a rough inhomogeneous structure, casting defects, and limitations in alloying and thus in improving wear resistance.
    Welding coating by different methods is a method of additive manufacturing = like melt deposition and 3D printing. In the case of welding coating, the situation is of the same type as in the case of —casting coating, i.e. the metallurgical quality of the coating, = welding defects and limitations in alloying prevent their use in the production of higher,> alloyed rolls. On the other hand, welding coating can also be used for coating work surfaces of very long E 30 long rolls, because in method e there are no actual N size limitations. However, in welding the metallurgical quality e is not possible to improve. The use of a welding coating is further limited by the fact that the weldability of the base material N must be sufficiently good and that the welding coating material used must be available as a welding additive.
    For example, size limitations of thermostatically pressed multi-material rolls with respect to the length of the rolls have been solved e.g. by the method of patent AT 5129239 B1.
    The method initially produces a thermostatically pressed preform 5, after which joints are joined to the ends of the preform by welding to obtain the desired overall length of the roll.
    However, the problem with the method is that the method requires sufficient weldability of the base material and the material of the extensions to be welded.
    Because roll materials must often have a high carbon content to achieve sufficient strength and surface hardness, the weldability of these materials is typically poor.
    In addition, welding requires machining of the welding heads of the part and extensions, relatively large welding work, especially in the case of large rolls, and finally heat treatment of the welding points to reduce residual stresses.
    In addition, a non-destructive inspection is usually required to ensure the level of integrity of the end result.
    Furthermore, in this method, the bond strength of the coating to the base material and the metallurgical quality of the coating cannot be improved, nor can the coated area be modified longer.
    The use of welding to extend the rolls has not been significantly utilized due to the quality and quality assurance counters of the method.
    When using a roller, failure of the weld joint can cause significant risks of injury and damage to the rolling mill, which can result in a long downtime.
    Various mechanical joining technologies have also been used, such as shrink joints to join special materials to a low-alloy, low-cost base material.
    However, these methods are uncertain, especially in large rolls, and their use is generally limited to very small work rolls, for example the joining of carbide rings = mechanically to small steel frame rolls.
    For example, shrinkage of a sleeve-like wear-resistant special material N around the roll base material e1 is not possible very well = for long sleeves and large rollers, because reliable installation of long sleeves is difficult, causing movement of the sleeve during rolling and possible damage to the sleeve or shaft E30.
    In addition, the shrink-bonded ring has residual stresses N after the shrinkage joint, and in use it is subjected to large bending loads, which causes the relative movement of the shrink-bonded ring relative to the base material, which in turn N can cause damage in use.
    At present, there is no manufacturing method for utilizing multi-material technology in rolls that can cost-effectively use various high-alloy composite materials produced as a single integrated component in very large rolls, such as over 3 meters in length, while ensuring good material adhesion and defect retention. The problems are particularly related to rolls with a carbide content of more than 8% by volume, which makes it very easy for large and continuous carbides to reduce toughness to form in the structure, making it difficult to achieve fine carbide distributions where the average carbide size is less than 15.
    BRIEF SUMMARY OF THE INVENTION The manufacturing method according to the invention makes it possible to manufacture rollers, in particular large rolls, in a multi-material structure, so that the properties of the special material of the roller surface and the bond strength to the base material are very good. In particular, the method allows the use of production methods for materials which would not be useful without the production process according to the invention. Large rollers here mean rollers with a length of more than 3 meters, such as more than 3.5 meters or more than 4 meters. This length refers to the largest parallel dimension of the roll. Generally, this dimension is the length of the roll axially from end to end. The very good properties of the special material of the work surface mean that there is no unacceptable wear on the work surface during the use of the roll due to the interaction between the material to be rolled and the work surface of the roll. Such wear can be due to, for example, thermal, = mechanical and chemical effects. In general, the hardness of the work surface material should preferably be N, depending on the application, in hot forming applications above HRC50 and = in cold rolling applications above HRC60 so that the size of the work surface shells is less than 15 μm> determined according to the largest dimension of the carbides. E 30 N Very good bond strength of the work surface to the base material means that the bond strength of the work surface material to the base material is sufficient to prevent it from tearing or gradually coming loose | fatigue - due to dynamic loads, atypical loads or thermal stresses during operation. As these loads vary from application to application, the requirements for joint strength may also vary depending on the application. By special material is meant a variety of alloyed wear steels that generally use a sufficient combination of carbon content and carbide-forming alloys to achieve a favorable carbide distribution after heat treatments. Typically, these materials have a carbon content of more than 0.8% by weight and an amount of carbide-forming alloys of more than 8% by weight. In order to achieve particularly good wear resistance, for example, vanadium, tungsten or niobium can be used as carbide formers, the carbides of which are harder than the carbides of, for example, chromium. - Typical - wear-resistant special materials suitable for multi-material rollers include e.g. steels AISI D2, AISI M2, AISI M3, AISI M4, AISI A11 and AISI T15, in which different combinations of alloying elements have been used to obtain a suitable combination of properties.
    Base materials are those materials from which the part of the multi-material roll which is not normally in contact with the material to be rolled and which is not subjected to the same wear, heat and corrosion stresses as the work surface of the roll is produced. However, the base material must be able to withstand the mechanical loads on the roll and be subjected to the same manufacturing parameters for coating, heat treatment and heat treatment as the special material. Suitable base materials include e.g. rebar steels such as DIN 42CrMo4 or carbon steel EN S355.
    The invention is particularly suitable for use in rollers in which the volume content of carbides of the special material is high, at least 8% by volume, and in which the size of the carbides is limited to less than 15 μm in order to improve the toughness and surface fatigue resistance. o
    With the manufacturing method according to the invention, the roll can be manufactured in such a way that = - First, the material components of the multi-material starting blank are prepared in a manner suitable for the materials used. Depending on the materials, suitable methods may include, for example, casting, welding, powder metallurgical process, molten metal injection and -N deposition and / or forging. > - - After the fabrication of the material components, the multi-material starting blank & material components are combined into one multi-material starting material, if the combination has not already been carried out in the previous step. Suitable methods for joining the material components may include, for example, thermostatic pressing, material-adding fabrication such as molten metal deposition, 3D printing, and welding coating or casting. - - As a multi-material starting blank of material components = after combining, the heat treatment of the obtained multi-material starting blank can be carried out at a suitable temperature by sufficient reduction to obtain the desired length and diameter. - After heat treatment, post-treatments can be performed on the hot-formed multi-material blank. Such post-treatments may include, for example, rough machining or machining, heat treatment (s), finishing machining or machining, and / or inspection or inspections. In addition, in the method according to the invention, after combining the material components and before the heat treatment, the preparation of the multi-material starting blank for the heat treatment can be carried out, if necessary. Such preparation may include, for example, encapsulation and / or gas evacuation. In addition, with the manufacturing method according to the invention, the roll can be manufactured in such a way that, for example, the production of material components, the combination of material components and preparation for hot working or part thereof are combined into one step, after which direct hot working can proceed. This can be done, for example, when using casting methods for the production of a multi-material starting blank. In addition, this manufacturing method is suitable for so-called additive manufacturing, such as 3D printing, molten metal spraying or deposition, or even traditional fill or coating welding. In doing so, the quality of the starting blank prepared by the method and its suitability for hot working must be taken into account. As an example = for the simultaneous production of a special material part and a base material part of a blank, N is cast simultaneously with two different molten metals so that the different molten metals are not mixed
    O + in a mold but is separated, for example, by metal plates. The advantage of simultaneous production is> e.g. the fact that if the material is produced simultaneously and the production takes place at an elevated temperature E 30, their cooling takes place more homogeneously than if only the production of another material N takes place at an elevated temperature, whereby lower stresses are associated with the connection between them. > This is well realized, for example, by casting both materials at the same time according to drawing 7a N. This method of preparation also promotes the joining of different materials due to diffusion and materials = interfaces - partial melting. On the other hand, in substance-adding production, the production can be carried out by starting the addition of the second material by melt metal spraying or deposition before cooling the first material, where the cooling rate of the materials is closer than if the first material was completely cold or only slightly preheated before depositing the second material. If the first material is solid prior to incorporating the second material therein, it is preferable to heat it to an elevated temperature prior to making and incorporating the second material into the material to reduce cooling stresses.
    The production method according to the invention can be used to produce multi-material rolls, which can now be produced from higher quality materials rich in fine carbides of less than 15 μm, for example by thermostatic pressing or electroslag smelting in the case of long rolls, such as more than 3 meters long. At present, it is not possible to manufacture the largest rolls in sheet and strip rolling mills - using - for example - thermostatic - compression for the production of rolls containing special powder metallurgical materials. This is due to the size limitations of the equipment and no suitable equipment is available. This limits the quality, service life and surface quality control of these rolling mills, which are key to productivity.
    The manufacturing method according to the invention can limit the use of special materials only to critical areas of the rollers = such as work surfaces, and thus also save on the total manufacturing costs, because the special materials are typically high in cost. This can limit the use of special materials in the case of large rolls and help control costs. Thus, the manufacturing method according to the invention promotes the industrial utilization of high-alloy work rolls manufactured by more expensive methods. OF
    S + The manufacturing method according to the invention makes it possible to produce multi-material and long rolls, such as, for example, more than 3 meters in length, from one integrated material blank E 30, so that the joints of different materials are based on metallurgical and diffusion grafts. In this way, the use of welds and mechanical joints, which are perceived as uncertain, can be avoided in the manufacture of large rolls with a length of, for example, more than 3 meters.
    i
    Although the method according to the invention offers significant advantages, especially in large and long rolls, it is also suitable for the production of smaller multi-material rolls in a material-, resource- and cost-efficient manner.
    The manufacturing method according to the invention can improve the properties of special materials produced by different methods, compact them or break the carbide or cast structure by heat treatment. Thus, for example, casting technology can be used to make a special material portion, because the large carbides and carbide strips in the structure can be chopped smaller in hot working. However, breaking the structure in hot working is not necessarily necessary, for example in the case of rapidly solidified materials, for example when using raw materials prepared by gas atomization, such as powders, which solidify into particles smaller than 1000 .mu.m. Particles of this type are used e.g. in the manufacture of a special material such as tool or high-speed steel by thermostatic pressing of powders, 3D printing or melt metal injection or deposition.
    With the manufacturing method according to the invention, the strength of the joints of special materials to the base material can be improved by hot working also the area coated with the special material from the multimetal blank. = This = also allows the use of - inexpensive - methods for making multi-material blanks and - special material - joining - methods, - because hot working can achieve - a higher quality - connection between special material and base material than most manufacturing methods such as casting and injection molding or melt deposition.
    With the manufacturing method according to the invention, in the case of very poorly heat-formable = materials =, the elongation - elongation - can be performed by applying only N multi-material blanks to an easily formable base material, such as carbon or + rejuvenation core, and thus avoiding
    According to the manufacturing method according to the invention, it is possible to encapsulate the entire blank 5 or only the area coated with a special material, whereby in the case of cracking of the special material or N interfaces, the resulting cracks can be closed without oxidation of the cracks. This also allows the use of technically simpler, cheaper - and less achievable = quality - manufacturing methods for the fabrication and joining of specialty materials, as encapsulation facilitates hot working, reducing the risk of rupture or the risk of rupture not being repaired as hot working progresses. In addition, encapsulation can prevent oxidation of the special material and reduce carbon loss and thus the need to remove the material from the surface of the athio by machining.
    In the manufacturing process according to the invention, interlayer materials can be used to prevent harmful interfacial reactions and residual stresses in multi-material structures can be reduced. This allows poorly matched materials to be joined and processed without the typical tear problems.
    The manufacturing method according to the invention can - improve - the mechanical reliability of the rollers, because the areas in the rollers which are subjected to high bending loads during rolling can be made of a less crack-sensitive base material and a special material can be used only on the roll work surface. This increases the reliability of the rollers and facilitates their use in demanding applications where critical areas of the rollers, such as work surfaces, are subjected to significant loads.
    With the manufacturing method according to the invention, it is possible to flexibly select an appropriate and cost-effective roller work surface material for different sizes, in particular large rolls, with regard to the application and the desired roller properties. At present, it is not possible to manufacture a roller work surface from the most alloyed materials as part of composite structures, especially in the case of large rolls. Thus, the manufacturing method according to the invention can advantageously implement customization and material selection for each rolling application.
    o S
    DESCRIPTION OF THE S + DRAWINGS
    I E 30 Drawings - 1a-1c - show - schematically - examples = different - alternatives for making N multi-material output blanks. Drawing 1a shows 5 heat isotate compression, Drawing 1b shows melt metal injection or -Q deposition, and Drawing 1c shows casting.
    Figures 24-2c schematically show the fabrication of a multi-material roll in stages by hot working only the uncoated areas so that Figure 2a shows the roll multiform material before forming, Figure 2b shows the hot forming of the blank by forging, and Figure 3c shows the multi-material roll after hot working.
    Figures 3a-3c schematically show the production of a multi-material roll in stages, so that the multi-material blank of the roll is produced by thermostatic pressing completely coated and encapsulated with a special material, and hot working takes place by forging along the entire length of the blank.
    Figures 4a-4c schematically show the manufacture of a multi-material roll in stages, so that the multi-material starting blank has a third material between the special material and the base material, and the hot working takes place by forging the entire length of the blank.
    Figures 5a-5c show schematically the production of a multi-material roll in stages, so that - in the multi-material starting blank = there is - a special material - connected to the multi-material die - a sheet metal capsule is made in the rolling work area and around the special material, and hot forming takes place along the entire length.
    Figures 6a-6 ¢ schematically show the fabrication of a multi-material roll in stages with a special material in the multi-material blank - connected to the multi-material blank = rolling work area and around the special material = a sheet metal capsule is made, and hot forming is done by forging only non-special material.
    Figures 7a-7d show schematically the production of a multi-material roll in steps E 30, so that both materials of the multi-material die are produced and joined N simultaneously by casting - on a steel plate - separated from each other, the blank 5 is encapsulated if necessary and hot formed over the entire length. OF
    Figures 8a-8d schematically show the stepwise fabrication of a multi-material roll so that the base material is shaped to facilitate encapsulation and hot working, and the hot working takes place along the entire length of the blank.
    Figures 94-9d schematically illustrate the stepwise fabrication of a multi-material roll with a multi-material die coated by any selected method and a sheet metal capsule formed around the preform, and hot forming by forging the entire length of the preform.
    The drawings are intended to illustrate the inventive idea. Thus, the drawings are not drawn to a particular scale and are not intended to define the specific interrelationships of parts or components.
    DETAILED DESCRIPTION OF THE INVENTION The text refers to the drawings with the following reference numerals: 1 Roller P Roller blank 2 Work surface 3 Shaft 4 Frame 5 Shell 6 Intermediate layer 2 7 Separating plate & forging tool = 11 Casting mold> 12 Evacuation tube E 30 14 Welding head E 30 13 Welding head
    O> 15 Heating element N A Friction material B Base material
    C Intermediate layer material D Capsule material Hy ’Roller billet diameter Hy Roller diameter H3 Roller shaft diameter L Length | Length of special material portion in roll preform La Length of special material portion in roll Lc Length of encapsulated area Ly Length of roll athion before hot working Ly Roll length In the method according to the invention, multi-material rolls 1 are produced in such a way that it is possible to utilize with. The method according to the invention can be used to produce large rolls, such as rolls with a length Lv of more than 3 meters. With the method according to the invention, such large rollers 1 can be produced in one piece without welding and mechanical joints, so that the working surface 2 of the rollers 1 is rich in alloys and carbides containing carbides formed by alloying elements. With the method according to the invention, rollers 1 with a length Ly of up to more than 7 meters can be produced, so that their work surfaces 2 are made of the materials containing the most high-alloy wear-resistant steels. The length Ly of the roll 1 means the total length of the roll 1. In general, this total length is the length along the axes 3 of the roller 1, as shown, for example, in Drawing 2c. Then = length Ly contains both the portion representing the work surface 2 and the axes 3. OF
    S + The work surface 2 of the roll 1 means the part of the roll 1 on which the rolling is performed and which is in contact with the material to be rolled during the use of the roll 1> E 30 N The multi-material nature of the roll 1 means that the roll 1 contains several different materials connected by metallurgical or by diffusion joints without the use of mechanical joints such as N shrink joints, bolt fastenings or anchor joints.
    Hereinafter, a multi-material blank means a roll blank made of at least two materials 1 after hot working, whereby the roll blank P is ready for finishing, for example by machining and / or heat treatment. Hot working means modifying the dimensions of the roll athion 1 at high temperature so that - - the length Ly of the roll 1 is desired and greater than the length Lv of the roll blank P before hot working, and / or - - the diameter Hy of the roll 1 is desired and smaller than the diameter Hv of the roll blank P before hot working, and / or - the diameter Hs of the shaft 3 of the roll 1 is desired and smaller than the diameter of the corresponding section in the roll blank I before hot working. However, it is to be understood that if several rolls 1 are made from the hot-rolled roll blank P, for example by cutting the hot-rolled roll blank P into several rolls 1, the length Ly of each such roll-formed roll 1 is not necessarily greater than the length of the roll blank P. This special case will not be repeated below for the sake of clarity of presentation. However, even in this special case, the lengths Ly of the rollers 1 prepared by separating from the heat-treated athio 1 are, in total, greater than the length Ly 'of the roll athion P before the hot-working. The high temperature of the heat treatment may be, for example, above 1000 ° C, such as 1060-1200 ° C or 1000-1175 ° C or 1000-1200 ° C or 1100-1250 ° C. Hereinafter, a multi-material starting blank means a multi-material blank as defined above = before hot working. OF
    S + In the method according to the invention, the> roll 1 used in the hot and cold forming of metals is manufactured in a multi-material structure by a suitable method, using a more durable special material A on the working surfaces 2 of the roll 1 E 30 and a lower material but mechanically durable base material 5 in the roll body 4 and other parts.
    The section of the special material A of the roll 1 may comprise, for example, not more than 60% by volume or not more than 50% by volume or not more than 40% by volume or not more than 30% by volume or not more than 20% by volume or not more than 10% by volume or not more than 5 volume-%.
    For example, the section of the roll comprising special material A may form a coating on the outer surface of the finished roll. In such a case, the coating can be, for example, 500 mm or 750 mm or 1000 mm or 1250 mm or 1500 mm from the total length Lv of the finished roll 1. The special material A can be, for example, one of the steels AISI D2, AISI T15, AISI A11, AISI M3 and AISI M4. Special material A is characterized in that in order to increase its wear resistance and hardness better than normal steels, its total carbides have been increased by a sufficient carbon content and the use of carbide-forming alloys. The carbon content of the special material A can be, for example, more than 0.8% by weight or, for example, more than 1.1% by weight.
    Special material A may contain carbide and / or nitride-forming alloys such as chromium, molybdenum, vanadium, tungsten, niobium or titanium. The alloying elements formed by carbides and / or nitrides can be, for example, more than 8% by weight or more than 12% by weight of Y or more than 15% by weight.
    The special material A can have a hardness, for example, greater than HRC 35 or greater than HRC 45 when heat-treated.
    For example, the average size of the carbides of the special material A may be less than an average of 50 μm = tar less than an average of 20 μm. The size of the carbide is determined by the maximum N of the carbide. .
    According to dimension A.
    O x - Base material B can be, for example, steel DIN 42CrMo4 or carbon steel EN S355.
    E 30 The basic material B is characterized in that it has a relatively low mixture content and a carbon content of N generally less than 0.5% by weight.
    O N A section comprising a special material A of a multi-material roll blank P, such as a work surface 2, is connected to a section comprising a base material B, such as a frame 4, by any suitable method suitable for manufacturing and / or joining the materials used. The joining can take place simultaneously in the production of the section comprising the special material A, such as in the case of welding coating or by using thermostatic pressing for the production and coating of the powder metallurgical material on the surface of the base material B. In the method according to the invention, it is also possible to manufacture the section comprising the special material A of the roller athion I and the section comprising the base material B simultaneously so that they are joined together simultaneously during the manufacture of at least one of these sections. Figure 7a shows an example in which both the section comprising special material A and the section comprising base material B are produced by casting simultaneously and, when they cool, these sections are connected to each other at the same time. Various methods can be used to make the multi-material outlet 1 of the roll 1, such as the thermostatic pressing shown in Fig. 14, the molten metal injection or deposition shown in Fig. 19, or the casting shown in Fig. 1c. As shown in Figure 14, in thermostatic pressing, the special material A and the base material B are placed together with the joint surfaces opposite each other, the material is encapsulated around with a sheet metal capsule, and the body is subjected to elevated temperature and pressure in a special high temperature pressure vessel. Special material A can be either in powder form or solid. The multi-material output blank is then ready for hot working. As shown in Figure 1/4, in molten metal spraying or deposition after coating, the multi-material starting blank is ready for hot working. o
    S a As shown in Figure 1c, in the casting, a special material A and a base material B = are cast in the same process step in a mold using an intermediate layer plate to separate the molten metals. > After solidification, the multi-material output blank is ready for hot working. & 30 <+ = o The production method of the section comprising the special material A of the roll is selected according to the composition of the base material B, such as N, for example steel. For example, the use of a powder metallurgical or other special material A prepared by rapid cooling methods is suitable for the most high-alloyed materials, and its compaction and bonding to the base material B takes place by thermostatic pressing. On the other hand, when welding welding, the weldability and availability of special material A as different welding consumables must be taken into account. In addition, due to the productivity limitations of the welding deposition method, it is mainly suitable for thin coatings. When using a casting method for the production of a section comprising special material A and joining it to a section comprising base material B, the castability of special material A and - sufficient - material - hot workability = roll TP in the hot working step must be taken into account.
    Other methods of manufacturing the multi-material output blank P of the roll 1 can also be utilized depending on the amount of doping used, the microstructure and the suitability for the different steps of the manufacturing process.
    The multi-material starting blank P of the roll can also be manufactured in such a way that both the section comprising the special material A and the section comprising the base material B are manufactured at the same time and joined together at the same time. The advantage of this procedure is that the number of work steps is reduced and that the surface of the section comprising the base material B does not have to be machined and prepared for coating. In addition, when these two sections of the multi-material output blank P of the roll comprising different materials cool at the same time, lower residual stresses are generated in the structure of the blank.
    Figures 74-74 show the principle of a method based on simultaneous joining with such a manufacture in the case of a casting method. When using the casting method, for example, both the special material A and the base material B are cast in the mold at the same time according to drawing 74. In the case of the example, a section comprising special material A and a section comprising base material B are separated, for example, by a metal separating plate 7, which S withstands the casting temperature and is able to separate the sections comprising materials A and B. After this N, the multi-material output blank 1 heat treated according to drawing 74 either = as is - according to drawing 74 or encapsulated according to drawing 7. > The result of the hot working is a multi-material blank 1 'hot-formed to the desired roll thickness Hy and length Lv E 30. This production method is also suitable for production methods other than casting-based blanks, such as powder metallurgically prepared blanks, in which, for example, special material A and / or base material B are / are in N powder form and are compacted in one operation, for example by thermostatic compression.
    Another example of the simultaneous production of materials is the method of variation of drawing 1b in which the base material is first produced by melt metal injection or - deposition - of base material B followed by melt metal injection - continued with special material A around base material B to produce a multi-material starting blank. According to this method, as well as the method previously described for the casting technology described in Figure 7a, there is the advantage of a lower risk of cracks because the special material A cools almost simultaneously with the base material B. In addition, the production of the base material A and possible machining before the production of the multi-material starting blank are avoided.
    In the method according to the invention, the entire roller athio 1 is heated to a high temperature in whole or in part after a section comprising special material A such as a work surface 2 is connected to a section comprising base material B such as frame 4. High temperature means e.g. 800-1300 ° C, or above 1000 PC, such as 1060-1200 ° C or 1000-1175 ° C or 1000-1200 ° C or 1100-1250 ° C. For example, when hot forming only the base material B at the ends of the roll blank 1 to increase the length, it is possible to heat only these areas to the hot working temperature. By hot working, the athio 1 of the roll can be extended at a high temperature to a length Lv long enough for the production of the final roll 1 so that the length Lv of the final roll 1 is greater than the length LY of the roll blank 1 before hot working. In addition, the heat treatment can achieve the desired structure and quality of the special material A, as well as the desired bond strength of the section comprising the special material A to the section comprising the base material B. Hot working can be performed on the entire roll blank 1 °, as shown in Figures 3-5 and 8-9, or only a portion thereof, as shown in Figures 2 and 6. If hot working = is performed only on a part of the roll blank 12, it can be carried out, for example, only on that part of the blank N 1 which does not comprise special material A, as shown in Figures 2 and 6.
    O s - The extent of heat treatment can be selected, for example, on the basis of whether or not E 30 requires special heat treatment to ensure the quality and strength of the joint coated with special material A.
    S Q According to one example, the heat treatment of the roller athion 1 ° can be performed as shown in Figs. 34 to 3c so that the heat treatment is subjected to a thermostatic multiform material blank 1 ° having a shell 5 formed of capsule material D as the outer layer, as shown in Fig. 34. In this example, hot working is performed according to Drawing 32 for the entire ingot by 1 ° to extend it to obtain the desired length Ly of the finished roll 1.
    According to another example, roller athion 1 the hot working can be performed as shown in Figs. 4a to 4c so that the hot working is subjected to a multimaterial starting blank 1 ”having an intermediate layer 6 comprising a special material A and a base material B portion between the special material A section. In this example, hot working is performed on the entire multilaterial material according to Drawing 46.
    Roll material blank 1 can be made, for example, as described in Figures 34-3c and 44-4c, with the special material A attached to the outer surface of the entire base material section B, the hot blank elongating the entire blank so that the cross section of the blank material surrounds the purchase of the special material A in the cross section. = In this case, the roll blank P, which has been lengthened by length Lv by hot working, also contains special material A in areas other than the work surface 2 of the finished roll. Thus, the finished roll 1 can be made, for example, by finishing machining in which the special material A can be removed, for example from surfaces other than the finished roll 1 or surfaces 2. This method is suitable for applications where the special material A is desired to cover a significant part of the base material B and / or improves the structure and bond strength of special material A to base material B.
    Rolling material material 1 can also be manufactured, for example, as described in Figures 54-5c and 64-6c =, so that the special material A is connected to the N part comprising the base material B only to a part of its outer surface. By doing so, it is possible to save on the cost of a higher quality and higher material cost - special material A and to use> special material A only on critical surfaces of roll 1, such as work surface 2. In this case, & 30 can be hot-formed for the entire roll ingot 1 for example N according to Drawings 54-5 ¢ including a section comprising special material A, i.e. for example> the area surrounded by special material A from the roller atio P. Alternatively, the multi-material blank of roll 1 N can only be partially modified according to Figures 64-6c, for example from areas not comprising special material A that is to say, from areas such as
    having no special material A surrounding the section comprising the base material B. This latter option is particularly advantageous in situations where the hot workability of the special material A is poor and / or where the section comprising the special material A does not require hot working to improve the joint strength or material properties.
    Such a situation in which the bond strength between the special material A and the base material B is sufficient even without heat treatment is, for example, when making the special material A 0810 and joining it to the section comprising the base material B using thermosetical compression. In thermostatic pressing, according to Figure 14, the special material A, either in powder form or in solid form, is encapsulated together with a section comprising the base material B, after which the interior of the capsule is evacuated from the air. The encapsulated preform P is then transferred to a high temperature resistant pressure vessel 14 for use in thermostatic compression, where a combination of high temperature and isostatic pressure is applied to the preform P, resulting in a joint between special material A and base material B, i.e. a section comprising special material A and base material. If the special material A is in powder form, it compacts in the same manufacturing step. The high temperature used in the pressure vessel can be, for example, 1000-1200 ° C. The isostatic pressure used in the pressure vessel can be, for example, 80-150 MPa.
    If it is advantageous to modify the section comprising special material A in connection with the entire blank, for example to improve the properties of special material A = and / or to increase the strength of the joint between the section comprising special material A and the section comprising base material B, a section comprising special material A can also be coated with special material A 1 edit blank 1 in addition to other areas. Figures 54-5c illustrate such a procedure according to one example.
    o
    S a If the section comprising the special material A of the roller athion 1 'and = the section comprising the base material B are modified simultaneously, it is important to select hot working parameters such as> working temperature so that the hot working parameters are suitable for both E 30 materials and so that the selected hot working parameters do not / or cracks in base material B. For example, the combination of the special material A AISI 5 D2 and the base material B DIN 42CrMo4 can advantageously be modified at a temperature N of 1000-1200 ° C. After this hot working, in the above case, the hot worked blank can be transferred to an oven, the temperature of which can advantageously be set in the range
    650-750 ° C for 6 hours, after which time the oven temperature can be slowly lowered to room temperature. Between some materials, such as AISI T15 steel used as special material A and carbon steel EN S355 used as base material B, it may be advantageous to use an intermediate layer material C between special material A and base material B to facilitate the formation of a joint between special material A and base material B. formation of brittle - microstructures. When the intermediate layer material C is thus used, the roller portion P may have an intermediate layer 6 comprising the intermediate layer material C between the section comprising the special material A and the section comprising the base material B. When the intermediate layer material C is thus used, the finished roll 1 may have an intermediate layer 6 comprising the intermediate layer material C between the section comprising the special material A and the section comprising the base material B. The use of the intermediate layer material C as described above is shown in Figures 44-4c according to an example. The intermediate layer material C can be, for example, reed steel or nickel. Prior to hot working, especially if the section of the roller athion P comprising material A is also hot worked, it may be necessary to protect the section comprising material A by encapsulating it in a shell 5, for example according to Figures 84-84 and 94-9c. Shell 5 may be thin metal.
    The thin metal shell 5 can be, for example, a highly malleable very low carbon steel with a carbon content of less than 0.1% by weight. The shell 5 can be used, for example, so that the shell 5 covers the entire roll blank 1 ', as described in Figures 94-9c. The thickness of the shell 5 can be, for example, at least 0.5 mm or at least 1.5 mm.
    The shell 5 can be used to protect a special material A, which can be prone to cracks due to high alloying. Such protection, i.e. encapsulation, makes it possible to prevent the oxidation of the cracked surfaces of the special material A and N, in particular the surface of the section comprising the special material A of the roller athion P. It is advantageous to prevent the oxidation of the crack surfaces, since the oxidation reduces or even prevents the closure of any cracks E 30 which may occur in the heat treatment as the heat treatment progresses. Also, the protection of the ruptures of the interface 5 between the section comprising the special material A N of the roll blank 1 and the section comprising the base material B from oxidation and thus from preventing repair during machining is facilitated by protecting the encapsulated surfaces 5 of the shell 5. The shell 5 also protects the section comprising the special material A from oxidation and carbon loss, reducing the need to remove the carbon loss layer in the finishing machining of the roller athion 1. In addition, encapsulation may reduce the need for special furnaces such as vacuum or shielding gas furnaces for heat treatment, which are also more expensive to use than conventional furnaces. It is advantageous to evacuate the void space between the shell 5 of the roll blank P and the layer below it, even a small one, i.e. to remove air from this void space or alternatively to fill this void space with a suitable inert or e1-harmful gas such as nitrogen or gas mixture. Air evacuation enhances the effects of encapsulation by preventing oxidation of the interfaces and improving the quality of the joints between the shell and the layer below it. After evacuation, said void space can be sealed to prevent oxidation and / or carbon loss.
    If the connection of the section of the roll blank P comprising the special material A to the purchase of the base material B is made by thermostatic pressing using either a metal encapsulating shell 5 made around the entire roll blank P or at least around the section of the special material A to be joined, this encapsulating shell no longer needs 5 for. Instead, if, for example, some other connection method is used, such as electric slag melting, casting, spraying, melt deposition or over-welding, the manufacture of the encapsulating shell 5 must be carried out separately. In particular, in a situation where in the roll multi-material output blank P, the entire base material B section is not coated with the special material A, it is also possible to encapsulate the special material A section by welding the encapsulating shell 5 around the special material A section to the base material B. This can be done, for example, in the cases described in Figures 54-50, 64-6c and 84-84. Figs. According to drawing 84, the part comprising the base material B is immersed, for example, by machining, casting or forging> in the area to which the special material A is attached, i.e. in which area the part comprising the special material A E 30 is formed. According to drawing 82, the special material A is coated in the N embedding, i.e. the section comprising the special material A is formed in the embedding. Encapsulation N is performed around the portion comprising the special material A formed according to Fig. 8c> with the shell 5. According to Fig. 87, for the entire multi-material output blank 1 formed as described above hot working is performed. In this case shown in Figures 84-84, the encapsulating shell 5 can be produced, for example, by rolling a sheet or using a tubular shell of a suitable size 5. The production method according to the invention can be made of two different materials by cold or hot forming a multi-material roll 1. The method according to the invention can be made of more than two or by hot forming a multi-material roll 1. By the manufacturing method according to the invention, a multi-material roll 1 can be produced in one piece without welding and / or mechanical joints.
    In particular, the method according to the invention is suitable for the production of large multi-material rollers 1 with a length Lv of more than 3 meters long or more than 3.5 meters long or more than 4 meters long.
    The method according to the invention comprises at least the following steps: - - a section comprising the base material B of the roller athion P is produced, for example by forging, welding or casting,
    - - the necessary machining of the part of the roll blank 1 comprising the base material B, the surface cleaning and optionally the installation of the intermediate layer 6 comprising the intermediate layer material C is carried out,
    - - preheating of the section comprising the base material B of the roll athion 1 and the intermediate layer 6 optionally connected to it, if preheating is necessary due to the requirements of the method of joining special material A to be used later and / or possibly for the whole roll 1 manufacturing process, eg casting coating, additive manufacturing and - deposition or welding,
    - - a section comprising a special material A of the roll blank 1 is formed, for example, by coating the surface of a section comprising the base material B or a part thereof
    S with a special material A which is suitable in terms of wear resistance and other properties A for the multi-material roll 1 to be manufactured,
    = - - is performed on the roll blank P thus formed to achieve the desired blank length 1v Lv I, and / or to optimize the microstructure> 30 of the section comprising special material A and / or to improve the joint strength between the section N comprising special material A and the section comprising base material B,
    > - - a final treatment of the hot-rolled roll blank 1, such as N heat treatment and / or machining, is carried out to obtain the finished roll 1.
    It is essential to note that both materials of the multi-material output blank are almost dense or compact even before hot working and have good enough properties for many less demanding applications than for roller applications.
    In addition, in the method according to the invention, the surface or part of the surface of the roller athion P can be encapsulated by the shell 5 before hot working. Encapsulation - is performed - whenever thermostatic compression is used, with special material A being a powder material. However, encapsulation can also be performed as previously described to ensure successful hot working and to minimize carbon loss when using other specialty material A manufacturing and joining methods. In addition, in the method according to the invention, an intermediate layer 6 comprising an intermediate layer material € can be used between the section comprising the special material A of the roll blank P and the section comprising the base material B to reduce adverse interface reactions. The intermediate layer 6 can be mounted, for example, on the surface of the section of the roll blank 1 comprising the base material B, for example by welding coating, spraying or as a thin plate or strip. Example 1 A section comprising the base material B of the roller athion P is prepared as a steel security, so that the base material B is made of steel with 0.15% by weight of carbon. A special material A of tool steel with a carbon content of 1.6% by weight and a sum of carbide-forming alloys (vanadium, molybdenum, chromium) = 15% by weight is applied around this preform P by thermostatic pressing at a temperature of 1100 ° C and a pressure of 100 MPa. % (vanadium 9.5% by weight, chromium 5.0% by weight and molybdenum 0.5% by weight). N In this way, a section comprising the special material A of the blank P is formed around the = section comprising the base material B. For hot isostatic pressing, a 5 mm thick encapsulating shell 5 is made of low carbon structural steel E 30 (carbon content 0.1% by weight) around the section comprising the base material B and the special material A, which is evacuated from the air before the N hot isostatic pressing. o N The multi-material roll blank P thus obtained is hot-formed by forging after thermostatic pressing at a temperature of 1060-1200 ° C over the entire length of the blank P so that the encapsulating metal shell 5 used in thermostatic pressing remains in the piece during hot-working. The encapsulating shell 5 is removed during machining after hot working.
    In this example, the length LY of the roll multiform material before hot working is 2 meters and the diameter Hv is 0.5 meters, and after the hot working, the length Ly ’is 5.5 meters and the diameter Hv is about 0.15 meters.
    Example 2 A part of the roll blank P comprising the base material B as a steel guarantee is made so that the base material B is made of AISI H13 steel. A special material A, made of powder metallurgical tool steel AISI M4, is bonded around this blank P by thermostatic pressing at a temperature of 1150 ° C and a pressure of 120 MPa. The special material A is attached only to the part of the base material B of the roll athion P which, after the subsequent heat treatment of the blank 1, forms the working surface 2 of the roll 1. Thus a section comprising the special material A of the blank P is formed in connection with the section B of the base material B.
    The multi-material roll blank 1 thus obtained is heat-treated after thermostatic pressing at a temperature of 1000 to 1175 ° C so that the athion 1 the uncoated areas of both ends with special material A are forged longer and the area coated with special material A is not hot worked. Thus, the heat treatment is not applied to the section of the roll athion 1 ° made of special material A, but is applied to the roll blank 1 other parts. o
    S a In this example, the length Ly of the multi-material thion P before the hot working is 2 meters and = the diameter Hv 0.5 m, and after heat treatment the length Ly is 5.5 m and the diameter Hv ’> is about 0.15 m. & 30 a Example 3
    O 5 N As a steel guarantee, a section comprising the base material B of the roll blank 1 is made so that the base material B is made of rejuvenated steel.
    Around this preform P, the entire length Ly 'of this athion 1 is joined by casting a special material A made of tool steel AISI D2. In this way, a section of athio 1 ° comprising special material A is formed around the section comprising base material B.
    The multi-material roll P of the roll thus obtained is encapsulated in a shell 5 of 10 mm thick structural steel containing 0.1% by weight of carbon. The area encapsulated in the shell 5 is evacuated by sucking air out of the capsule. The blank is then heat treated at 1 ° by forging at a temperature of 1050-1200 ° C over its entire length, including the area coated with special material A. After hot working, the blank 1 is slowly cooled in an oven to room temperature, after which it is machined to the desired final dimension Ly of the roll 1 and heat-treated by tempering and passing to a hardness of HRC52. In this example, the length LY of the multi-material blank P before the hot working is 2 meters and the diameter Hy ’is 0.5 meters, and after the hot working, the length Lv is 8 meters and the diameter Hy is 0.125 meters.
    Example 4 A section comprising 1 ° of base material B of a roll athion is prepared by casting a structural steel containing 0.15% by weight of carbon as the base material B.
    = For that part of Roller 1 a section comprising the base material of the blank, which corresponds to the working surface 2 of the roll 1 after N subsequent hot working, is formed by an intermediate layer 6 = by coating a 1 mm thick layer of nickel as the intermediate layer material C. x a 30 After this coating, a special part> A of tool steel AISI T15 is applied to the coated part of the outer surface of the athion PP by N thermostatic pressing at a temperature of 1120 ° C and a pressure of 105 MPa. This forms an athion P comprising special material A section on the intermediate layer 6.
    After thermostatic pressing, the multiform material blank 1 hot worked by forging at a temperature of 1000-1200 ° C along its entire length, including the area coated with special material A.
    In this example, the length Ly of the multiform material blank P before hot working is 1.5 m and the diameter Hy ’is 0.5 m, and after hot working the length Lv is 6 m and the diameter HV is 0.125 m.
    Example 5
    As a steel guarantee, a section comprising the base material B of the roll blank 1 'is made so that the base material B is carbon steel.
    In addition, a section comprising special material A is produced in a separate piece by thermostatic pressing, so that special material A is made of tool steel AISI D2. This section comprising the special material A is machined in a separate piece to such an extent that it can be placed around the section comprising the base material B of the roll blank P.
    The multi-material roll 1 ”of the roll thus formed is encapsulated in a shell 5 so that the shell is made of 10 mm thick structural steel containing 0.1% by weight of carbon.
    The encapsulating shell is then evacuated, removing air.
    Thereafter, the multi-material blank P is subjected to thermostatic pressing at a temperature of 1140 ° C and a pressure of 100 MPa to join a separately prepared section comprising special material A around the section comprising base material B. o 3 a After this roll multi-material thio 1 hot forging at a temperature of 1000-1175 ° C areas not coated with the blank = special material A to achieve the desired total length Ly> of the roll 1.
    The hot forging is thus applied to the sections of the roll blank P other than those comprising the special material E 30 A. <+ © o In this example, the length Ly of the multiform material blank before hot working is 1.5 meters and the diameter N is Hv is 0.5 m, and after heat treatment the length Lv is 6 m and the diameter Hy ’is 0.125 m.
    Example 6 As a steel guarantee, a section comprising a base material B of a roll blank 1 is prepared so that the base material B is made of rejuvenated steel. A section comprising special material A is formed around the section of base material B of the roll blank P so that the section comprising base material B is welded by powder arc welding of a special material A of a tool batch having a carbon content of 1.5% by weight and a chromium content of 15% by weight. After welding, the welded area is encapsulated in a shell 5 and the encapsulated area is evacuated by sucking air out of the capsule. After this blank 1 hot working by forging at a temperature of 1100-1250 ° C so that the hot working is applied to the welded area. After hot working - the roll - the multi-material blank 1 is finalized - and heat-treated by hardening and allowing a hardness of 45 HRC.
    In this example, the length of the multiform material Ly before hot working is 2 meters and the diameter Hv ’is 0.3 meters, and after hot working the length Lv is 4.5 meters and the diameter Hy is 0.2 meters. Example 7 o i a The roll blank P is cast in a vertical or vertical position so that the section comprising the special material A of the roll athion P and the section W comprising the base material B are formed simultaneously so that the special material A and the base material B
    Ia 30 is cast simultaneously, in the N - casting mold the special material A and the base material B are separated by a separating plate 7, which is I. O 10 mm thick steel sleeve, N - —tool steel AISI D2 is used as special material A, and - - carbon steel is used as base material B.
    After casting multi-material blank 1 is completely encapsulated in a shell 5 so that the shell 5 is 15 mm thick and has a material of 0.1% by weight of carbon-containing structural steel. The roll blank 1 thus encapsulated is hot-formed by forging at a temperature of 1000-1200 ° C.
    In this example, the length Ly of the multi-material blank P before heat treatment is 1.5 meters and the diameter Hv is 0.4 m, and after hot working, the length Ly ’is 3 m and the diameter Hy’ is 0.28 m.
    Example 8 Base material B is first prepared by melt metal deposition, followed immediately by cooling the base material portion by melt deposition of special material A in a region of base material B, - - a section comprising roll blank I base material B and special material A 300 formed in successive working steps starting the coating, - —the AISI M3 tool steel is used as the special material A, and - - the AISI H13 steel is used as the base material B. After the two-stage melt deposition, the multi-material blank P is completely encapsulated in a shell 5 so that the shell 5 is 10 mm thick and has a material of 0.1% by weight of carbon-containing structural steel.
    o 5 Rolled blank 1 thus encapsulated hot worked by forging at a temperature of 1000-1200 ° C. OF
    S + In this example, the length Ly of the multi-material thion Ly before heat treatment is 1.5 meters and> diameter Hv is 0.4 m, and after hot working, the length Lv is 3 m and the diameter Hy ’E 30 is 0.28 m. N (Examples end) o N The inventive idea further comprises a multi-material hot or cold roll 1 comprising a section made of the base material B of the roll, a section made of a more wear-resistant coating material A and optionally an encapsulating shell 5 and / or a special material A . The process according to the invention makes it possible to produce - for example - rollers in which the hardness of the section comprising special material A is at least HRC 35 after heat treatment and the amount of carbide is at least 5% by volume. The examples described above are intended to illustrate the inventive idea. Thus, the examples described above should not be construed as an exhaustive representation of concrete embodiments of the inventive idea.
    o O OF
    N +
    I Ac a + OF O I O O OF
    权利要求:
    Claims (15)
    [1]
    A method for manufacturing multi-material rolls (1), the method comprising the steps of: is not more than 15% by weight, - a section comprising a special material (A) is prepared in a section comprising the base material (B) of the roll blank (1 °) by a suitable method so that the density of the special material (A) is at least 90% of theoretical. - 40% by volume of the total volume of the base material (B) and the special material (A), that the desired length (Lv) of the roll blank (1) after hot working is greater than the length of the roll blank (1 °) (L (v) before hot working, - - the diameter (Hv) of the roll blank (1) which is less than the diameter (Hv) of the athion (P) of the roll and / or the shaft diameter (Hs) of the roll blank (1) which is smaller than ) diameter before hot working - - the thickness of the special material layer (A) of the multiform material blank is at least 5 mm - before hot working the part of the roll blank (P) comprising at least the special material part (A) is encapsulated in a shell made of at least 0,55 mm o 25 sheet metal and other metal components 5) to protect the encapsulated portion of the roller> athion (1) during hot working
    [2]
    S x 2. The method according to claim 1, wherein the special material (A) is an iron-based material I having a carbon content of more than 0.8% by weight, S - the amount of carbide and nitride-forming alloys is more than 12% by weight. - the total amount of carbides and nitrides is 5 to 30% by volume, and - - the hardness after heat treatment is greater than HRC 35.
    [3]
    A method according to any one of claims 1-2, wherein the average size of the carbides in the special material (A) is less than 50 μm.
    [4]
    A method according to any one of claims 1-2, wherein the average size of the carbides in the special material (A) is 1-10 μm
    [5]
    A method according to any one of claims 1 to 4, wherein after encapsulation and before heat treatment of the roll blank (1 ) ... the void space between the encapsulating shell (5) and the layer below it is evacuated from air or filled with a gas mixture, and gas-tight to prevent oxidation and / or carbon loss.
    [6]
    Method according to one of Claims 1 to 5, in which a section comprising a special material (A) is connected to a section comprising the base material (B) of the roll blank (1), so that an intermediate layer (6) comprising an intermediate layer material (C) is arranged between these sections.
    [7]
    A method according to any one of claims 1 to 6, wherein a section or intermediate layer (6) comprising a special material (A) of a roll blank (1 °) is joined to a section comprising a base material (B) of the roll athion (1) by thermostatic pressing, casting, molten metal spraying or deposition , By 3D printing, welding or any other method of adding material.
    [8]
    A method according to any one of claims 1 to 7, wherein the special material (A) is a D powder metallurgical material. & S
    [9]
    A method according to any one of claims 1 to 8, wherein the section comprising the special material = (A) of the roller athion (1) and the section comprising the base material (B) are joined together simultaneously during the production of the special material (A).
    S 5
    [10]
    A method according to any one of claims 1 to 9, wherein both the base material B and the> special material A - are produced by - substance - adding - production - such as by melt spraying or deposition or by 3D printing.
    [11]
    A method according to any one of claims 1 to 10, wherein the heat treatment is applied only to those areas of the roll blank (P) which do not comprise a section comprising a special material (A).
    [12]
    A method according to any one of claims 1 to 10, wherein the heat treatment is also applied to those areas of the roll blank (1) which comprise a section comprising a special material (A).
    [13]
    A method according to any one of claims 1 to 12, wherein the hot working is carried out by hot forging, hot pressing or hot rolling at a temperature of 800 to 1300 ° C.
    [14]
    A method according to any one of claims 1 to 13, wherein - - the length (Lv) of the finished roll (1) is more than 3 meters, and - - the section comprising special material (A) forms a coating on the outer surface of the finished roll (1) such that at least 500 mm from the total length (Lv) of the finished roller (1). - - the special material (A) forms a layer at least 10 mm thick of at least 80% of the total surface area of the coating.
    [15]
    A roller (1) for hot or cold forming a metal produced by a method according to any one of claims 1-15. o
    O
    OF
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    OF
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    O
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    同族专利:
    公开号 | 公开日
    WO2020165489A1|2020-08-20|
    EP3833496A4|2021-06-23|
    FI128579B|2020-08-14|
    US20220032351A1|2022-02-03|
    EP3833496A1|2021-06-16|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    JPH0459901B2|1987-07-31|1992-09-24|Toray Industries|
    JPH0717930B2|1990-06-28|1995-03-01|新日本製鐵株式会社|Composite roll manufacturing method|
    IN2014DN08146A|2012-07-09|2015-05-01|Nippon Steel & Sumitomo Metal Corp|
    DE102014108823B9|2014-06-24|2016-10-06|Steinhoff Gmbh & Cie. Ohg|Roller and method for producing a roll for hot or cold rolling of flat metal products|
    SI3141335T1|2015-09-08|2021-08-31|Deutsche Edelstahlwerke Specialty Steel Gmbh & Co. Kg|Method for producing a component having a core section made of steel|
    CN108277443B|2018-01-29|2019-12-24|二重(德阳)重型装备有限公司|Support roll of wide and thick plate mill with width of more than 4200mm and manufacturing process thereof|
    法律状态:
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    FI20197024A|FI128579B|2019-02-14|2019-02-14|Method for producing multimaterial rolls, and multimaterial roll|FI20197024A| FI128579B|2019-02-14|2019-02-14|Method for producing multimaterial rolls, and multimaterial roll|
    EP20756087.1A| EP3833496A4|2019-02-14|2020-01-29|Method for the manufacture multimaterial roll and the multimaterial roll|
    US17/278,819| US20220032351A1|2019-02-14|2020-01-29|Method for the manufacture of multimaterial roll and the multimaterial roll|
    PCT/FI2020/000003| WO2020165489A1|2019-02-14|2020-01-29|Method for the manufacture multimaterial roll and the multimaterial roll|
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