澳大利亚专利AU2013213544A1 Steel for producing parts for railway, railway crossings and switches and method for producing said

专利PDF首页>>澳大利亚专利

专利附录

专利说明

权利要求

类似技术

同族专利

引用文献

法律状态

优先权

专利摘要:
This invention relates to a wrought steel for producing parts for railway, railway crossings or railway switches comprising (in weight percent): -0.01 - 0.15 % carbon; -at most 0.5 % silicon; -10 – 15 % manganese; -at least 0.6 to 3.95 % molybdenum; -optionally one or more of the following elements i.0.05 to 0.2 % nickel and/or ii.0.05 to 0.2 % cobalt and/or iii.0.02 to 0.30 % Cr and/or iv.0.05 to 0.2 % copper; v. at most 5 ppm H; vi. at most 0.20 % V; vii. at most 0.10 % Nb; viii. at most 0.20 % Ti and/or Zr; ix. at most 50 ppm B; x. at most 250 ppm N; xi. at most 0.2 % Al; xii. at most 0.08 % S; xiii. at most 0.08 % P; xiv. at most 1.5 % W; -and balance iron and inevitable impurities and to a method of producing the wrought steel and its use.
公开号:AU2013213544A1
申请号:U2013213544
申请日:2013-01-25
公开日:2014-08-28
发明作者:Lifen DENG；Shreekant Jaiswal；Vijay Jerath
申请人:Tata Steel UK Ltd；
IPC主号:C22C38-04

专利说明:
WO 2013/110798 PCT/EP2013/051517 Steel for producing parts for railway, railway crossings and switches and method for producing said parts This invention relates to a wrought steel for producing parts for railway crossings and switches and to a method for producing said parts. 5 Switches and crossings (S&C) are components of the rail system which are subjected to significant loads in use in a railway line. Several techniques are being used to produce these S&C. A significant proportion of S&C parts are currently manufactured from cast austenitic manganese steel (AMS). AMS has traditionally been used owing to its high 10 work hardening capacity on impact, excellent toughness following solution treatment and water quenching, and very good resistance to wear in the work hardened condition. The nominal chemical analysis of AMS is 1.2% C, 13% Mn and 0.5% Si, which produces a bulk hardness in the region of 200 to 250 HB. Following the passage of a certain amount of traffic, the 15 hardness of the S&C can reach levels of 500 to 550 HB. AMS also has a number of drawbacks, such as the low 0.2% proof stress. Railway points and crossings commonly experience severe impact loading conditions during service resulting in plastic deformation and work hardening which raise the material strength to levels more resistant to 20 further plastic flow. However, the associated dimensional changes that are unavoidable in the original unhardened condition are undesirable. In track, the differential loading leads to uneven hardening and localised plastic deformation, with the resulting poor ride quality eventually necessitating rebuilding of the deformed profile with weld deposits. As a 25 consequence, AMS in heavy axle load applications requires frequent grinding to remove lipping and weld repairs to restore deformation height loss. AMS is a difficult material to cast or machine into the complex shapes needed for S&C. Furthermore, any change to the footprint of the railway 30 crossing requires a new casting mould, making the production of uncommon crossing profiles very expensive. The narrow freezing range of AMS results in many cavity-type defects which may be the starting point of cracking seen in service. Commonly, porosity in AMS crossings occurs WO 2013/110798 - 2 - PCT/EP2013/051517 at depths of around 10 to 15mm from the new surface and once this depth is approached weld restoration to rebuild the crossing becomes impractical owing to the risk of cracks initiating from any residual porosity. For an AMS component, 10 years is commonly regarded as a 5 normal life span as beyond this period the extent of the defects has become so severe that it is uneconomical to continue remedial weld repair and the components have to be replaced. A further problem with AMS is the thermal instability of the austenitic microstructure, which renders the material difficult to weld. This difficulty in welding is a problem not only 10 when weld repairing the components in situ, but also during component manufacture, as rails have to be welded to the component prior to its installation in a railway line. As a result of these issues, several alternatives have been developed to the conventional AMS crossing type. Some S&C are made up of materials 15 in the form of a composite metal sandwich, where the part contacting the wheels of passing trains is made of a hard, wear resistant plate steel of different composition, microstructure and properties. The lower part of the item is manufactured from a basic steel composition. These solutions usually offer a cheaper alternative with better weld repairability, but the 20 properties of the crossing nose are then dependent on the level of sophistication of the steel composition making up the crossing nose. In many cases. such compositions do not match the wear, and in particular the rolling contact fatigue, resistance offered by AMS crossings. Moreover, these solutions are more difficult to produce as a result of the composite 25 sandwich of different steels. Another alternative to AMS is to provide the high manganese parts with a work-hardened layer prior to installation of the parts in the line. Surface pre-hardening techniques may include shot blasting, rolling or explosive hardening. Of these techniques, explosive hardening is generally the 30 preferred choice as it provides a hardened layer which is thick enough to meet the service requirements of the S&C. However, it is difficult to control the thickness of the hardened layer with these surface hardening techniques. Moreover, surface hardening does not WO 2013/110798 - 3 - PCT/EP2013/051517 address the weld repairability issues and casting defects associated with cast high manganese parts. The inventors therefore set out to devise a solution to these problems. It is an object of this invention to provide a new wrought steel for S&C as 5 an alternative to AMS and in particular to cast AMS. It is also an object to provide a new wrought steel for S&C as an alternative to AMS which is readily weldable for in-situ repairing by a top of-head weld repair procedure. It is also an object to provide a new wrought steel which will be more 10 resistant to nose batter. It is also an object to provide a new wrought steel for S&C which is weldable to conventional pearlitic rails. It is also an object to provide a new wrought steel for S&C which is flash butt weldable to conventional pearlitic rails. 15 One or more of the objects of the invention is reached by providing a wrought steel for producing parts for railway, railway crossings or railway switches comprising (in weight percent): * 0.01 - 0.15 % carbon; * at most 0.5 % silicon; 20 e 10 - 15 % manganese; * at least 0.6 to 3.95% molybdenum; * optionally one or more of the following elements i. 0.05 to 0.2 % nickel and/or ii. 0.05 to 0.2 % cobalt and/or 25 iii. 0.02 to 0.30 % Cr and/or iv. 0.05 to 0.2 % copper; v. at most 5 ppm H; vi. at most 0.20 % V; vii. at most 0.10 % Nb; 30 viii. at most 0.20 % Ti and/or Zr; ix. at most 50 ppm B; x. at most 250 ppm N; xi. at most 0.2% Al; WO 2013/110798 - 4 - PCT/EP2013/051517 xii. at most 0.08% S; xiii. at most 0.08% P; xiv. at most 1.5% W; and balance iron and inevitable impurities 5 The current invention allows to produce a single type of feedstock blank that can subsequently be machined to any crossing design required to satisfy the local conditions. Computer controlled machining results in closer tolerances at reduced costs. As railways have many different angled crossings to cater for the local needs, a variety of casting moulds would be 10 needed to produce these from AMS castings and this is reflected in their relatively high cost. The current invention therefore offers a significant cost reduction. The role of carbon in this steel is to obtain sufficient hardness of the steel mainly by solid solution strengthening. On the other hand, a high carbon 15 content leads to an increase in the amount of retained austenite, leading to a reduction in hardness. An increase in carbon content will significantly enhance the risk of grain boundary embrittlement in these steels due to the formation of carbide networks, both in the as-manufactured condition and also following welding. Therefore, to maintain the delicate balance 20 between hardness and the risk of embrittlement, the carbon content needs to be between 0.01 and 0.15% for these steels (all compositions are given in weight percent, unless otherwise indicated). More preferably the carbon content is between 0.01 - 0.12%. As a consequence of their lower carbon content, most of these alloys are readily weldable. To further 25 improve the weldability the carbon content preferably is at most 0.10, more preferably at most 0.08. To achieve the desired microstructure the carbon content is at least 0.01% and preferably at least 0.02%. A suitable minimum carbon content from a steelmaking point of view is 0.
0 4 %. 30 Manganese is an austenite promoting element. It stabilises austenite i.e. increases the temperature range in which austenite exists. Varying the manganese content in the steels according to the invention revealed that a maximum in hardness is obtained at a manganese content WO 2013/110798 - 5 - PCT/EP2013/051517 of at least 10%. At very high manganese levels of e.g. 15% the hardness decreases to an inadequate level. The hardness has a strong correlation with wear resistance and the resistance to wear is a determining factor for the life span of most railway parts, including S&C. A low wear rate means 5 that repair of the part is needed less frequently. The significant difference in wear resistance between steels having a manganese content below 10% and those above 10% is attributed to the differences in microstructure. Manganese levels below 10% resulted in fully martensitic microstructures whereas levels above 10% displayed mixed 10 microstructures of retained austenite, s-martensite (hexagonal close packed, or hcp martensite) and martensite. Preferably the manganese level is at least 11%. The wear resistance of steels having fully martensitic microstructures has been found to be poorer than those of mixed microstructures containing martensite and retained austenite. However, 15 increasing the manganese content also results in an increase in retained austenite. At manganese contents above 15% the levels of retained austenite become sufficiently high that the increasing hardness of the martensite phase is more than offset by the increasing proportion of the softer austenite, with the result that the overall hardness of the steel falls, 20 along with the wear resistance. Resistance to crack propagation is high and is associated with very sluggish progressive failures. Because of this, there is an increased opportunity for any fatigue cracks that develop to be detected, and the affected part or parts removed from service or repaired before complete failure occurs. Based on the above reasoning the 25 manganese content is preferably at least 11 and at most 15%. As manganese is also a costly alloying element, a suitable maximum manganese content was found to be 14% or even 13%. A suitable minimum content of manganese was found to be 11.5%. The maximum value of hardness and wear resistance was achieved when the manganese 30 content was between 12 and 13% Mn. At these levels the amount of retained austenite + s-martensite on the one hand and hard martensite on the other is about 50:50, thereby providing a satisfactory combination of impact toughness and hardness.
WO 2013/110798 - 6 - PCT/EP2013/051517 Molybdenum is effective in increasing the impact toughness. In addition, due to the scavenging effect of molybdenum for phosphorus, temper embrittlement phenomena are prevented. At a level of 0.6% Mo, the increase in impact toughness is already notable, but a further increase is 5 obtained at values above 0.6%. The increase in impact toughness levels off at values of 1.5%. Consequently, the molybdenum addition in this steel needs to be between 0.6% and 3.95%, and preferably the molybdenum content is at most 2.95% and/or least 1.25%. A molybdenum content of 1.5% was found to be a suitable minimum value 10 for stable impact toughness values. A molybdenum content of 1.90% was found to be a suitable maximum value from a combined cost and technical perspective as the additions of values above 1.90% result in only a modest further improvement. Silicon was found to have little effect on the impact toughness and wear 15 resistance of these steels, although it does provide an increase in tensile strength and hardness via solid solution strengthening. It also serves as a killing agent during steel production. On this basis, a maximum value of 0.5% Si is recommended. A suitable minimum content was found to be 0.10 or even 0.15%, and/or a suitable maximum was found to be 0.40 or 20 even 0.35%. Nickel (Ni), cobalt (Co) and copper (Cu) have a similar effect as manganese by way of their being austenite promoting elements. To a certain extent these elements can be added instead of, or in addition to, manganese. Ni, Co and Cu may be added to a maximum of 1.0% per 25 element, totalling not more than 3%. Preferably the maximum of Ni, Co and/or Cu is 0.5%. The alloys according to the invention have proven to be readily machinable. One or more additions of sulphur, calcium, tellurium, or selenium or any other known machinability enhancing elements may be 30 made to further these alloys if necessary. The phosphorus content is generally maintained below 0.08%, preferably below 0.05% and preferably below 0.02% to minimize the tendency for hot cracking. Phosphorus is a residual element in these steels. If no WO 2013/110798 - 7 - PCT/EP2013/051517 sulphur is to be added to enhance machinability, then the sulphur content is generally maintained below the impurity level of 0.02%. If sulphur is to be added, then a suitable maximum amount is 0.08%, preferably 0.05%. If the following elements are added as alloying elements, then preferable 5 ranges are as follows: between 0.02 and 0.20 % V, between 0.02 and 0.10 % Nb, between 0.02 and 0.20 % Ti, between 0.02 and 0.20 % Zr, from 5 to 50 ppm B and from 10 to 250 ppm N. Suitable maximum contents are 0.10% V, 0.075% Nb, 0.10 % Zr and/or 0.10 % Ti. B, V, Nb, Zr and Ti contribute to a grain refinement of the steel. 10 The steel according to the invention is preferably silicon-killed. Provided the cleanness of the steel remains in accordance with the specifications in terms of maximum value of aluminium oxide inclusions, the steel may also be aluminium-killed or aluminium-silicon killed. When added as an alloying element, the maximum total aluminium content is 0.2%. 15 Preferably the total aluminium content (when added as an alloying element) is between 0.02 and 0.15%. The metallic aluminium content (i.e. not present as an oxide) will be lower, dependent on the oxide content of the steel melt when adding the aluminium. The steel according to the invention has a hydrogen content of is below 5 20 ppm, preferably of below 3.5 ppm and more preferably below 2.5 ppm. Although chromium is preferably kept below the impurity level of 0.15%, i.e. the chromium is not deliberately added, for some applications chromium may be added up to a level of 0.3%. A suitable maximum chromium content is 0.2%. 25 It should be noted that the steel composition according to the invention could also be used to produce castings, but as the low carbon composition is more expensive than the normal AMS Hadfield type steels with high carbon content whilst not producing better properties in its cast condition than AMS, it is economically unattractive to use the composition according 30 to the invention to produce cast materials. According to a second aspect the invention is also embodied in a method for producing a wrought steel part for use in a railway track such as in railway crossings or railway switches comprising the steps of: WO 2013/110798 - 8 - PCT/EP2013/051517 * providing a starting material, such as a bloom or ingot, having a composition according to any one of claim 1 to 10; * providing starting material at an appropriate temperature for hot rolling it into a plate or rail, wherein 5 i. the hot-rolled plate has a thickness sufficient for machining the part out of the hot-rolled plate, or ii. wherein the rail has the desired rail profile for a. machining into a part for railway crossings and switches such as a switchblade or 10 b. for use as a rail; * allowing the plate or rail to cool after the last hot deformation to achieve the desired mechanical properties; * machining the part for railway crossings and railway switches from the hot-rolled and cooled plate or rail; 15 The wrought steel can be used to produce a part like or for a crossing by machining it from a hot-rolled and cooled plate. The wrought steel can also be provided in the form of a rail having the desired geometrical profile, and these hot-rolled and cooled rails can be welded to the part or be used to be machined into a switch blade. The rails can also be used as 20 such. The method according to the invention allows the production of blanks of different lengths that can then be machined into crossings with a wide range of angles. Also hot-rolled plate can be slit into thinner lengths that are subsequently machined into switch blades. However, to form switch 25 blades it may be preferable for the cast bloom to be hot-rolled into a rail of the desired geometrical profile and thereafter machining the rail to manufacture a switch blade. According to a third aspect the invention is also embodied in the use of the wrought steel part produced according to the invention and/or having 30 a composition according to the invention in a railway, railway crossing or railway switch, preferably wherein the steel part has been, at least partly, weld restored by an in-situ weld repair procedure.
WO 2013/110798 - 9 - PCT/EP2013/051517 Flash butt welding of the steel according to the invention is preferably performed by using a stainless steel insert to be welded to the crossing first before it is welded to a pearlitic rail with the stainless insert acting as a sandwich filler to improve compatibility for high integrity welds. 5 The steel according to the invention can be used to produce parts for railway crossings and switches such as a frog in a common crossing as shown in figure 1. This shows a one-piece cast frog in a common crossing. This self-guarding frog without guard rails has raised flanges on the frog, bearing on the face of the wheel as it passes through the frog. Although 10 the wrought steel according to the invention is primarily intended to be applied in parts for railway, railway crossings or railway switches such as frogs and switchblades, it was found that the steel is also suitable for other track components such as expansion joints, insulated rail joints or rails. 15 A frog also forms part of a railroad switch, and is also used in a level junction (flat crossing). The frog is designed to ensure the wheel crosses the gap in the rail without "dropping" into the gap; the wheel and rail profile ensures that the wheel is always supported by at least one rail. To ensure that the wheels follow the appropriate flangeway, a check-rail or 20 guard rail is installed inside the rail opposite the frog. Figure 2 shows a frog on the right hand side and a check-rail on the left hand side. The frog or a double-frog would typically be made from the steel according to the invention. The invention is now described in more detail by means of the following, 25 non-limiting examples. A series of casts were produced and the chemical compositions are given in Table 1.
WO 2013/110798 PCT/EP2013/051517 0C~ 0~ 0CC)00 0 Z C! 0! 0! 0! 0! 0 0 0 0 0 06 o ~ ~ ~ L o ~ - - j 0! 0C! 0 0 0 ~~~~-~~ C- ~ - . N L j Cj - C'lj co~ 0 C~- N.) Cl LO LO 0 0 Cj C~j 0 0 '~) CC) L V V0 0 0 0 0 CC) CC) LO) Cj V V 4-J ~ L mLO C)OO L 0 0 N O O 0 VL co N Ou0 CJ Cj Cj Cj L ~ ~ O L 4- 00 o) LO LO LCO LO c) 0 0~ C ~ Co cr 01 0NCN o 0 -u CC) C o cv '~ O CO C) 0o C'LO OLO L CC) L o 0I,-LO LO L UL Li-j U'jcL j ~ - -~ o 6 Cj ~ j C~) C~ Cj ~ j Cj Cj t 0 0 0 0 0 0 E _ _M o LIx o~~~~- co N O u~ 'o ~- LO LO E WO 2013/110798 PCT/EP2013/051517 The mechanical properties of the steels are excellent as shown in Table 2. Table 2 - Mechanical properties A(50) 0.2%PS UTS Impact Hardness RCF Wear (%) (MPa) (MPa) (J) (HB) (Cycles to (mg/m initiation) of slip) 10FJ41 18 239 1227 52 350 300000 4.9 Cr 10JF15 > 12* 230 996 74 348 n.a. 3.7 10JF16 > 12* 225 1186 78 343 n.a. 4.59 10JF17 > 12* 229 995 80 361 n.a. 3.26 10JF18 > 12* 218 1309 92 384 n.a. 4.22 12JF26 > 12* 255 1213 94 353 n.a. 3 - 5** 12JF27 > 12* 224 1223 96 348 n.a. 3 - 5** *A(50) could not be reliably determined but is at least 12%. **Wear tests were not completed, but preliminary results show a value of between 3 and 5 mg/m of slip. An assessment of the rolling contact fatigue, RCF, resistance of the steels according to the invention is performed by means of twin disc wear tests at room temperature with a rolling contact stress of 900 MPa, a level of slip of 5% and a small amount of lubricant applied throughout the duration of the test. This test and the rig used in these tests is described in Fletcher & Beynon, "Development of a machine for closely controlled rolling contact fatigue and wear testing", J. Test. Eval. 28 (2000), 267 275. The RCF resistance is defined as the number of cycles to crack initiation. The test data indicate the new material outperforms alternative rail steels currently in the market by a factor of two. In the case of premium grade heat treated rail, for example, the number of cycles prior to crack initiation is typically 110000 cycles. Furthermore, the new material displays RCF resistance comparable to that of AMS and Maraging Steels (AMS and MS respectively in figure 3), with RCF cracks initiating only after 300000 cycles. In terms of low cycle fatigue it was found that the steel according to the invention outperformed AMS in this respect. Comparison with other rail materials revealed that the steels according to the invention show good impact toughness values which are more than WO 2013/110798 - 12 - PCT/EP2013/051517 adequate for the purpose of producing parts for railway crossings and switches. Figure 4 shows the value of the Charpy toughness (in J at 20 0 C) as a function of the Mo-content, justifying the minimum value for Mo of 0.6%. The open circles correspond to the microalloyed samples 12JF26 and 27. The material has a very high work hardening rate resulting in an increase in stress during low cycle fatigue testing of about 400 MPa after three cycles from + 1 to - 1% in the standard NF12 test specimen (see figure 5a and 5b). In figure 5b an enlarged portion of figure 5a is shown in which the stress increase during the first (1x), second (2x) and third (3x) cycle is clearly visible. An assessment of the rolling contact wear resistance for the steels according to the invention is also performed by means of twin disc wear tests at room temperature, but with a rolling contact stress of 750 MPa with the wear rate being measured after 2130 cycles (see Figure 6 where the rolling contact wear resistance is plotted as a function of Brinell hardness, HB. The insert shows a magnified portion of the graph). The wear rates (in mg/m of slip) of the material according to the invention (black circles in Figure 6) were found to be extremely low in the range of 0 to 5 mg/m of slip, and of the same magnitude as AMS and of the newly developed HPRail* (indicated by the diamonds in Figure 6). The weldability of the steel according to the invention is excellent due to its low carbon content and is much better that than of AMS, making the new steels a preferred option for applications where weldability is an issue, such as in the production and use of parts for railway crossings and switches.

权利要求:
Claims (15)
[1] 1. Wrought steel for producing parts for railway, railway crossings or railway switches comprising (in weight percent): * 0.01 - 0.15 % carbon; * at most 0.5 % silicon; * 10 - 15 % manganese; * at least 0.6 to 3.95 % molybdenum; * optionally one or more of the following elements i. 0.05 to 0.2 % nickel and/or ii. 0.05 to 0.2 % cobalt and/or iii. 0.02 to 0.30 % Cr and/or iv. 0.05 to 0.2 % copper; v. at most 5 ppm H; vi. at most 0.20 % V; vii. at most 0.10 % Nb; viii. at most 0.20 % Ti and/or Zr; ix. at most 50 ppm B; x. at most 250 ppm N; xi. at most 0.2 % Al; xii. at most 0.08 % S; xiii. at most 0.08 % P; xiv. at most 1.5 % W; * and balance iron and inevitable impurities.
[2] 2. Steel according to claim 1 comprising at most 0.12% C and/or at least 11% of Mn, and/or at most 2.95% Mo.
[3] 3. Steel according to claim 1 comprising at most 0.02% S and at most 0.02 % P.
[4] 4. Steel according to any one of claim 1 to 3 comprising at most 0.10% C.
[5] 5. Steel according to any one of claim 1 to 4 comprising at most 14% Mn. WO 2013/110798 - 14 - PCT/EP2013/051517
[6] 6. Steel according to any one of claim 1 to 5 comprising at least 0.10% Si.
[7] 7. Steel according to any one of claim 1 to 6 comprising at least 15% in volume of retained austenite in its as-hot rolled state and/or comprising at least 15% in volume of retained austenite during its use as part of a railway, railway crossing or railway switch.
[8] 8. Steel according to any one of claim 1 to 7 comprising * at least 1% Mo, preferably at least 1.25% and/or * at most 2.45% Mo, preferably at most 1.90%.
[9] 9. Steel according to any one of claim 1 to 8 comprising at least 0.02 % C.
[10] 10. Steel according to any one of claims 1 to 9 wherein the steel comprises between 0.05 and 0.1% vanadium and/or between 0.025 and 0.075% Nb.
[11] 11. Method for producing a wrought steel part for railway, railway crossings or railway switches comprising the steps of: * providing a starting material, such as a bloom or ingot, having a composition according to any one of claim 1 to 10; * providing starting material at an--apprepr-ie temperature for hot rolling it into a plate or rail, wherein i. the hot-rolled plate has a thickness suffieient for machining the part out of the hot-rolled plate, or ii. wherein the rail has the desired rail profile for a. machining into a part for railway crossings and switches such as a switchblade or b. for use as a rail; iii. allowing the plate or rail to cool after the last hot deformation to achieve the desired mechanical properties; WO 2013/110798 - 15 - PCT/EP2013/051517 machining the part for railway crossings or railway switches from the hot-rolled and cooled plate or rail;
[12] 12. Method for producing a steel for producing a wrought steel part for railway, railway crossings or railway switches according to claim 11 comprising the additional step of welding one or more rails to the part.
[13] 13. Method according to claim 11 or 12 wherein the wrought steel part for railway, railway crossings or railway switches is a frog or a double frog or a switchblade.
[14] 14. Use of the wrought steel part produced according to any one of the claims 11 to 13 and/or having a composition according to any one of the claims 1 to 10 in a railway, railway crossing or railway switch.
[15] 15. Use of the wrought steel part according to claim 15 wherein the steel part has been, at least partly, weld restored by an in-situ weld repair procedure.

类似技术:

公开号 | 公开日 | 专利标题

CA2801703C|2016-05-24|Abrasion resistant steel plate which exhibits excellent weld toughness and excellent delayed fracture resistance

US20150191806A1|2015-07-09|Ultrahigh-strength, high-toughness, wear-resistant steel plate and manufacturing method thereof

KR20130025947A|2013-03-12|Wear-resistant steel sheet having excellent welded part toughness and lagging destruction resistance properties

US9945014B2|2018-04-17|High-manganese wear resistant steel having excellent weldability and method for manufacturing same

US8430976B2|2013-04-30|Rail steel with an excellent combination of wear properties and rolling contact fatigue resistance

CA3083362A1|2019-05-31|Method for manufacturing a rail and corresponding rail

US20150028165A1|2015-01-29|Steel for producing parts for railway, railway crossings and switches and method for producing said parts

EP2785890B1|2015-07-15|Rail steel with an excellent combination of wear properties, rolling contact fatigue resistance and weldability

Marich et al.1978|Development of high-strength alloyed rail steels suitable for heavy duty applications

JP5847330B2|2016-01-20|Wear-resistant steel with excellent toughness and weldability

JP2021509144A|2021-03-18|Structural high-strength steel with excellent fatigue crack propagation suppression characteristics and its manufacturing method

WO2020012297A1|2020-01-16|Track part made of a hypereutectoid steel

KR20150077549A|2015-07-08|Steel for cargo oil tank and method of manufacturing the same

JP7016345B2|2022-02-04|Microalloy steel and its steel production method

KR101505278B1|2015-03-24|Steel for cargo oil tank and method of manufacturing the same

KR101435318B1|2014-08-29|Method of manufacturing wear resisting steel

OA20006A|2021-08-31|Track Part Made of a Hypereutectoid Steel.

KR20140042105A|2014-04-07|Steel for cargo oil tank and method of manufacturing the same

同族专利:

公开号 | 公开日

MX2014008972A|2015-03-19|

KR20140119153A|2014-10-08|

WO2013110798A1|2013-08-01|

RU2014134530A|2016-03-20|

CN104160058A|2014-11-19|

HK1203572A1|2015-10-30|

JP2015510548A|2015-04-09|

EP2807283A1|2014-12-03|

BR112014018242A2|2017-07-04|

US20150028165A1|2015-01-29|

引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

DE1178880B|1961-10-21|1964-10-01|Huettenwerk Oberhausen Ag|Process for the production of steel, wear-resistant, naturally hard single-material rails|

FR2407987B1|1977-11-03|1980-04-25|Creusot Loire||

JP2533935B2|1989-06-10|1996-09-11|株式会社神戸製鋼所|Method for producing high Mn non-magnetic steel having excellent SR embrittlement resistance, high strength and high toughness|

DE19735285C2|1997-08-14|2001-08-23|Butzbacher Weichenbau Gmbh|Process for the production of a track part|

CN1061385C|1998-06-19|2001-01-31|四川工业学院|High-performance abrasion-resistant steel for switch tongue of high-speed or quasi high-speed railway|

GB0204558D0|2002-02-27|2002-04-10|Allen Edgar Eng|Railway crossings, etc|

CN100484701C|2005-10-17|2009-05-06|大连交通大学|Forging manufacture method of high-manganese steel frog centering rail|

CN100463992C|2007-06-12|2009-02-25|燕山大学|Forged abrasive austenic permanganic steel and its manufacture|KR101543898B1|2013-12-24|2015-08-11|주식회사 포스코|Steel having excellent impact toughness of welding zone and welding property|

JP6801747B2|2018-06-28|2020-12-16|Ｊｆｅスチール株式会社|Manufacturing method for austenitic rails|

法律状态:
2016-05-05| MK1| Application lapsed section 142(2)(a) - no request for examination in relevant period|

优先权:

申请号 | 申请日 | 专利标题

EP12152514||2012-01-25||

EP12152514.1||2012-01-25||

US201261595014P| true| 2012-02-03|2012-02-03||

EP12153948.0||2012-02-03||

EP12153948||2012-02-03||

US61/595,014||2012-02-03||

PCT/EP2013/051517|WO2013110798A1|2012-01-25|2013-01-25|Steel for producing parts for railway, railway crossings and switches and method for producing said parts|

[返回顶部]