奥地利专利AT511429A4 METHOD AND DEVICE FOR PRE-TREATING A ROLLING BEFORE ROLLING

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专利摘要:
The invention relates to a method and a device for the pretreatment of a rolling stock (3). The object of the invention is to find a method and a device with which the rolling stock (3) can be both energy-efficiently heated and thoroughly descaled before hot-rolling. This object is achieved by the following method steps: preheating the rolling stock (3) in a preheating furnace (4) by a plurality of burners (11) descaling the preheated rolled stock (3) in a descaling device (5); heating the descaled rolled stock (3 ) in a heating furnace through a plurality of burners (11), wherein the burners substoichiometrically burn a carbon support so that the rolling stock (3) in the heating furnace (7) is kept in a reducing atmosphere by the exhaust gas (12, 13) produced during the combustion; Introducing a first portion of the exhaust gas (12) and oxygen (15) into the preheat furnace (4); Post-combustion of the first part of the exhaust gas (12) in the preheating furnace (4), wherein the amount of oxygen (15) is chosen such that the rolling stock (3) is maintained in the preheating furnace (4) in an oxidizing atmosphere.
公开号:AT511429A4
申请号:T8612011
申请日:2011-06-10
公开日:2012-12-15
发明作者:Gerald Dipl Ing Dr Hohenbichler；Bernd Dipl Ing Dr Linzer
申请人:Siemens Vai Metals Tech Gmbh；
IPC主号:

专利说明:

1 1 • · * · 201110574
description
Method and device for pretreatment of a rolling stock before hot rolling
Field of engineering
The invention relates to a method and a device for the pretreatment of a rolled steel material before hot rolling.
State of the art
From JP 63-262417 A a method of heating a slab in a multi-part furnace is known wherein the slab is preheated in a preheating zone of the furnace by a burner and then heated in a reducing atmosphere of a heating zone of the furnace. The exhaust gas of the heating zone is supplied to the burner in the preheating zone of the furnace, where the unburned CO of the exhaust gas is burned by a burner. A disadvantage of this method is that the slab must be descaled either before or after heating. A disadvantage of descaling prior to heating is that the scale is difficult to remove due to its slow growth; A disadvantage of the descaling after heating is that the rolling stock must be heated to a higher temperature than the rolling temperature, whereby the energy efficiency of the process suffers. From JP 63-262417 A no approaches are known how these disadvantages can be overcome.
Summary of the invention
The object of the invention is to find a method and a device with which the rolling stock can be both energy-efficiently heated and thoroughly descaled before hot-rolling. * * * * * * * * * * '* * * * 201110574
This object is achieved by a method according to claim 1, comprising the following method steps: - preheating of the rolling stock in a preheating furnace by a plurality of burners; - Descaling of the preheated rolling stock in an Ent zunderungseinrichtung; - Heating the descaled rolling stock in a heating furnace through a plurality of burners, wherein the burners
Stoking carbon carriers substoichiometrically so that the rolling stock is kept in a reducing atmosphere in the heating furnace by the exhaust gas produced during combustion; Introducing a first part of the exhaust gas and oxygen into the preheating furnace; Post-combustion of the first part of the exhaust gas in the preheating furnace, wherein the amount of oxygen is chosen so that the rolling stock is kept in the preheating furnace in an oxidizing atmosphere.
In this case, the rolling stock, for example a slab, a so-called intermediate strip or an intermediate strip, in a preheating oven by a plurality of burners to a temperature of typically more than 1000 ° C, preferably more than 1050 ° C preheated. At these temperatures, the rolling stock is particularly descaled. After descaling, the stock is heated to a rolling temperature by a plurality of burners in a heating furnace, the burners being heated to a carbon support {e.g. a heating gas, such as methane, ethane,
Propane or butane, or even a liquid fuel, such as fuel oil) under the addition of oxygen stoichiometrically burn. The substoichiometric combustion of the carbon carrier produces an exhaust gas which keeps the rolling stock in the heating furnace in a reducing atmosphere. This reducing atmosphere ensures that the descaled stock is faced with another substantial - i. the subsequent hot rolling disturbing - scaling is protected. Due to the stoichiometric combustion in the heating furnace, the exhaust gas of the heating furnace still flammable 201110574
Shares of CO and typically also H2. Subsequently, at least a portion of the exhaust gas is introduced with the addition of oxygen in the preheating furnace, where the introduced exhaust gas is post-combusted. In the afterburning, the amount of oxygen in the preheating furnace is now chosen so that sets an oxidizing atmosphere in the preheating furnace. The oxidizing atmosphere in the preheating furnace ensures rapid scale growth on the rolling stock, whereby the scale can be removed very easily (i.e., at low water pressure or a low water quantity) and thoroughly removed in subsequent descaling. It is basically possible to introduce the after-burnt exhaust gas either directly into the furnace chamber or to burn it by means of burners which heat the furnace chamber.
In an advantageous embodiment, the burners in the preheating furnace and the burners in the heating furnace are designed as gas-fired oxygen burners which burn a heating gas-typically a saturated hydrocarbon such as methane, ethane, propane or butane-with the addition of oxygen. By the oxygen burner, on the one hand, the heating power is increased, on the other hand is reduced by the combustion of technically pure oxygen and the nitrogen oxide load in the exhaust gases of the furnaces. Of course, it would also be possible to design only the burners of a furnace or even just individual burners of a furnace as oxygen burners.
In a high-performance embodiment, a heating gas is additionally introduced into the preheating furnace and burned. As a result, the energy supply is increased in the preheating furnace, but even with the addition of a heating gas, the amount of oxygen in the preheating furnace is chosen so that the rolling stock is maintained in an oxidizing atmosphere.
According to another high-performance embodiment, the descaled rolling stock is treated immediately after descaling in 201110574 4 • · ·
an induction furnace is heated, wherein the rolling stock is kept in the induction furnace by a second part of the exhaust gas of the heating furnace in a reducing atmosphere. The use of the induction furnace ensures a highly dynamic heating of the rolling stock, so that in particular temperature changes, which are caused by changes in the transport speed of the rolling stock, can be very well compensated.
According to one embodiment, the exhaust gas of the heating furnace is divided into a first part and a second part of the exhaust gas at the inlet end of the heating furnace in the transporting direction of the rolling stock.
It is advantageous to also introduce the second part of the exhaust gas after flowing through the induction furnace, preferably opposite to the transport direction of the rolling stock, in the preheating furnace. As a result, the energy content of the exhaust gas of the heating furnace is utilized as best as possible, in which the temperature of the second exhaust gas heats the rolling stock in the induction furnace and contributes to the heating of the preheating furnace by means of the afterburning. The passage of the second part of the exhaust gas opposite to the transport direction of the rolling stock ensures that the hot exhaust gas contributes to the heating of the hot rolling stock.
It is advantageous to measure the gas concentration, in particular the concentration of CO and / or H2, in the heating oven and to supply it to a controller, wherein the controller determines a manipulated variable with the aid of a desired concentration and at least one actuator (eg a valve, which controls the oxygen supply changed to the burners), so that the concentration of the target concentration corresponds as possible. As a result, the degree of reduction of the reducing atmosphere in the preheating oven can be set very precisely. 201110574 «* * ♦ *« t · »· · 1 * · 5 • * * f · ·« t * * * · ♦ ♦
It is furthermore advantageous to measure the oxygen concentration in the preheating furnace and to feed it to a controller, wherein the controller determines a manipulated variable with the aid of a desired oxygen concentration and at least one actuator {e.g. a valve that alters the supply of oxygen to the burners) so that the oxygen concentration is as close as possible to the desired oxygen concentration. As a result, the growth of scale in the preheating furnace can be controlled in a controlled manner, so that the descaling can be carried out as thoroughly as possible and, moreover, the rolling stock is cooled as little as possible.
The object of the invention is also achieved by a device according to claim 9, comprising: - a preheating oven for preheating the rolling stock, the preheating oven having a plurality of burners for burning a carbon carrier; a descaling device for descaling the preheated rolling stock, the descaling device being downstream of the preheating furnace; a heating furnace for heating the descaled rolling stock to rolling temperature, the heating furnace having a plurality of burners for burning a carbon carrier and the heating furnace downstream of the descaling means; an exhaust gas recirculation line for returning an exhaust gas of the heating furnace into the preheating furnace, the exhaust gas recirculation line leading from the heating furnace to the preheating furnace; and an oxygen line for introducing oxygen into the preheat furnace, wherein the oxygen line opens into the preheat furnace.
In a compact embodiment, the burners are designed as oxygen burners for burning a hot gas with the addition of oxygen. As a result, the system according to the invention can be realized with a particularly short overall length. 6 6 * * 201110574
In an advantageous embodiment, a heating gas line opens for introducing a heating gas into the preheating furnace.
In a high-performance embodiment, an induction furnace is arranged immediately after the descaling device, wherein the heating furnace is connected to the induction furnace via an exhaust gas duct.
It is advantageous that the input end of the induction furnace in the transport direction is connected to the preheating furnace by means of an exhaust gas recirculation line.
It is advantageous if a controller is connected on the one hand to a gas concentration measuring device for determining the gas concentration in an oven and on the other hand to an actuator for influencing the gas concentration in the oven. As a result, the concentration of CO in the heating oven or the oxygen concentration in the preheating oven can be set very accurately.
Brief description of the drawings
Further advantages and features of the present invention will become apparent from the following description of non-limiting embodiments, reference being made to the following schematic figures, which show the following:
1 shows a representation of a device according to the invention with an induction furnace
FIG. 2: a control diagram for the preheating furnace FIG. 3: a control diagram for the heating furnace
DESCRIPTION OF EMBODIMENTS 201110574 ι ··· * e · '«> · * Μ 7 • ♦ · «· · ·
1 shows a plant for the preparation of a rolling stock is shown. The rolling stock designed as intermediate strip 3 is fed to a preheating furnace 4 after rough rolling in a two-stand rolling mill 1 in the transporting direction 10, where it is preheated by a plurality of oxygen burners 11 to a temperature of 1050 DC. The oxygen burners 11 burn the heating gas methane with the addition of technically pure oxygen. Moreover, in the preheating furnace 4, a first part 12 and a second part 13 of an exhaust gas of a downstream heating furnace 7 are post-combusted. After preheating, the rolling stock 3 is descaled in a descaling device 5, which is designed as a rotary descaling device, wherein the rolling stock is cooled to 980 .mu.m. Immediately thereafter, the rolling stock is fed to an induction furnace 6 and heated there by 5 Induktormodule. Subsequently, the rolling stock 4 is heated in a heating furnace 7 to a rolling temperature of 1150 ° C, so that the rolling stock in the last rolling pass in the frame 9b still has an austenitic structure. In the heating furnace 7, the rolling stock is heated by 9 rows of oxygen burners in the lower part of the furnace and 9 rows of oxygen burners in the upper part of the furnace, again burning methane with the addition of technically pure oxygen. The amount of oxygen supplied to the oxygen burners 11 is adjusted so that the methane in the heating furnace 7 is burned substoichiometrically. The resulting at the assumed bandwidth amount of exhaust gas 12 of a total of 10,000 m3 iN / h is collected in each case in the upper part of the furnace and in the lower part of the furnace, has about 10% vol CO and 2% vol H2 and a temperature about 1000th ° C, and is introduced by means of an exhaust gas recirculation line 14 in the preheating furnace 4. Since the input side end of the heating furnace 7 is connected to the output side end of the induction furnace 6 via an exhaust passage 17, a second part of the exhaust gas 13, which constitutes about 5000 m 3 in / h, flows through the induction furnace 6 counter to the transport direction 10 of the rolling stock. After flowing through the induction furnace, the second part of the exhaust gas 13 is still at a temperature of close to 1000.degree. C. 201110574 8 M »ft. · «· ♦ * · * ψ 4« II 4 «f φ a. ». t ·. * * * · • 4 and is also introduced via a further exhaust gas recirculation line 14 in the preheating furnace 4. In the preheating furnace 4, the first part 12 and the second part 13 of the exhaust gas, total after 15000 m3 iN / h afterburning, wherein the preheating furnace additionally methane as heating gas, concretely about 1000 m3 iN / h, and oxygen, specifically about 2000 m3 iN / h. The actually supplied amount of oxygen is regulated so adjusted that the rolling stock 3 is exposed in the preheating furnace 4 an oxidizing atmosphere. By preheating the rolling stock 3 in the preheating furnace 4 to a temperature of 1050 ° C in an oxidizing atmosphere, the scale growth on the intermediate belt 3 is accelerated. In practical experiments, it has been found that a rapidly growing scale in a descaling device 5 can be removed thoroughly and with a small temperature drop of the rolling stock. In total, the oxygen burners 11 in the preheating furnace 4 and in the heating furnace 7 each produce approximately 10 MW of thermal energy. In addition, the by-burning of the exhaust gas 13, 14 in the preheating furnace 4 heats the rolling stock with a thermal power of an additional nearly 2 MW. Finally, the rolling stock in the induction furnace 6 is heated very dynamically with an adjustable heating power of about 5 to 10 MW. Of course, the gas quantities given are specific to the embodiment of Figure 1 and therefore can vary widely.
2 shows a control scheme for carrying out the method according to the invention for a preheating furnace 4. As shown in FIG. 1, the rolling stock 3 is preheated by a plurality of burners 11 in a preheating furnace 4, then descaled in a descaling device 5, and by means of a heating furnace (not shown) brought to rolling temperature in a reducing atmosphere. The exhaust gas produced in the stoichiometric combustion in the heating furnace 7 is introduced into the preheating furnace 4 by means of an exhaust gas recirculation line 14 and post-combusted therein with the supply of oxygen and a heating gas which according to FIG. 2 is methane. The actual temperature 23 of the rolling stock after the * * «« «* * * * * • • • Λ * *« 9 9 9 9 9 9 9 9 9 9 9 9 9 9. * «9 · * - 201110574
Preheating and before the descaling is constantly measured by means of a temperature measuring device 23 and fed to a controller 19. In addition, the actual oxygen concentration 22 in the heating oven 4 is continuously measured by an oxygen concentration meter 20 and also supplied to the controller 19. Taking into account a desired oxygen concentration 21 and a desired temperature 24, the controller now determines two manipulated variables 26a, 26b, which are each supplied to a control valve 18a, 18b. The control valve 18 a changes the amount of oxygen supplied to the preheating furnace 4 via an oxygen pipe 15. Similarly, the control valve 18b changes the amount of heating gas supplied to the preheating furnace 4 via a heating gas line 16. This control ensures that the rolling stock 3 is at a suitable temperature, typically > 1000 ° C or preferably around 1050 ° C, descaled and that the scale growth of the rolling stock 3 can be selectively controlled in the oxidizing atmosphere of the preheating furnace 4, so that a rapidly grown scale formed in the descaling 5 thoroughly and at low temperature drop can be removed. Of course, it would also be possible to apply the control to several regulators, e.g. a temperature controller and a controller for controlling the oxygen concentration in the preheating furnace, split.
FIG. 3 shows a control diagram for carrying out the method according to the invention for a heating furnace 7. The descaled rolling stock 3 is introduced into the heating furnace 7 immediately after the descaling device 5. In the heating furnace 7, the rolling stock 3 is heated by a plurality of oxygen burner 11, wherein each burner technically pure oxygen via an oxygen line 15 and the heating gas methane is fed via a heating gas line 16. For reasons of clarity, only the first burner 11 has been shown somewhat more accurately. On the one hand to bring the rolling stock 3 to the rolling temperature and on the other hand to keep the rolling stock 3 in the heating furnace 7 in a defined reducing atmosphere, on the one hand the actual 201110574
Temperature 25 of the rolling stock 3 directly from the hot rolling in the finishing train 8 by means of a
Temperature measuring device 23 is determined and fed to a controller 19. On the other hand, the actual carbon monoxide concentration 29 in the heating furnace 7 is determined by means of a carbon monoxide concentration measuring device 27 and also fed to the regulator 19. Regulating the setpoint temperature 24 and the desired carbon monoxide concentration 28, the controller 19 determines two manipulated variables 26a and 26b, which respectively change the supply of oxygen or of heating gas to the burners 11 in the heating oven 7 via control valves 18a, 18b.
Of course, it would also be possible to connect the separate control circuits of FIGS. 2 and 3 with each other and to realize them by a single digital controller, for example. 201110574 • ΓΓ
DESCRIPTION OF PREFERRED EMBODIMENTS 1 Pre-rolling line 2a, 2b Pre-rolling mill 3 Pre-heating furnace 5 Ignition furnacing 6 Induction furnace 7 Heating furnace 8 Finish rolling line 9a, 9b Scaffolding of finishing train 10 Transporting direction 11 Oxygen burner 12 First part of exhaust 13 Second part of exhaust 14 Exhaust gas recirculation line 15 Oxygen line 16 Heating gas line 17 Exhaust duct 18a , 18b Control valve 19 Controller 20 Oxygen concentration meter 21 Target oxygen concentration 22 Actual oxygen concentration 23 Temperature measuring device 24 Target temperature 25 Actual temperature 26a, 26b Control value 27 Carbon monoxide concentration meter 28 Target carbon monoxide concentration 29 Actual carbon monoxide concentration

权利要求:
Claims (14)
[1]
201110574 • * * * * * ί2 < 1. A method for the pretreatment of a rolled stock (3) of steel before hot rolling, comprising the following steps: - preheating the rolled stock (3) in a preheating furnace (4) by a plurality of burners (11); Descaling the preheated rolling stock (3) in a descaling device (5); - Heating the descaled rolled stock (3) in a heating furnace (7) by a plurality of burners (11), wherein the burners (11) substoichiometrically burn a carbon support, so that the rolling stock (3) in the heating furnace (7) by the exhaust gas produced during combustion (12,13) is kept in a reducing atmosphere; - Introducing a first part of the exhaust gas (12) and oxygen (15) in the preheating furnace (4); Post-combustion of the first part of the exhaust gas (12) in the preheating furnace (4), wherein the amount of oxygen (15) is chosen such that the rolling stock (3) is maintained in the preheating furnace (4) in an oxidizing atmosphere.
[2]
2. Method according to claim 1, characterized in that the burners (11) in the preheating furnace (4) and the burners (11) in the heating furnace (7) are designed as gas-fired oxygen burners which burn a heating gas (16) with the addition of oxygen.
[3]
3. The method according to claim 1, characterized in that in addition a heating gas (16) is introduced into the preheating furnace (4) and burned.
[4]
4. The method according to claim 1, characterized in that the descaled rolling stock (3) is heated immediately after the descaling in an induction furnace (6), wherein the rolling stock (3) in the induction furnace (6) by a second part of the exhaust gas (13). of the heating furnace (7) is kept in a reducing atmosphere. 201110574 • · · * · ί3 <
[5]
5. The method according to claim 4, characterized in that the second part of the exhaust gas (13) after the flow, preferably opposite to the transport direction (10) of the rolling stock (3), the induction furnace (6) is introduced into the preheating furnace (4) ,
[6]
6. The method according to claim 1, characterized in that the actual gas concentration, in particular the actual concentration of CO and / or H2, measured in the heating oven (7) and a controller (19) is supplied, wherein the controller (19) below With the aid of a desired concentration determines a manipulated variable and at least one actuator, so that the actual concentration of the target concentration as possible.
[7]
7. The method according to claim 1, characterized in that the actual oxygen concentration (22) in the preheating furnace (4) is measured and fed to a controller (19), wherein the controller (19) with the aid of a target oxygen fkonzentration (21) a Determined manipulated variable (26a) and at least one actuator (18a) provides, so that the actual oxygen concentration (22) of the desired oxygen concentration (21) corresponds as possible.
[8]
8. The method according to claim 1, characterized in that the actual temperature (25) of the rolling stock (3) measured immediately before the descaling and a controller (19) is supplied, wherein the controller (19) with the aid of a target temperature ( 24) determines a control variable (26b) and at least one actuator (18b) provides, so that the actual temperature (25) of the target temperature (24) corresponds as possible.
[9]
9. An apparatus for pretreating a rolled material (3) of steel before hot rolling, comprising: - a preheating furnace (4) for preheating the rolling stock (3), the preheating furnace (4) having a plurality of burners (11) for burning a carbon carrier; A descaling device (5) for descaling the preheated rolling stock (3), the descaling device (5) being downstream of the preheating furnace (4); - a heating furnace (7) for heating the descaled rolling stock (3) to rolling temperature, the heating furnace (7) having a plurality of burners (11) for burning a carbon carrier and the heating furnace (7) downstream of the descaling device (5); an exhaust gas recirculation line (14) for introducing an exhaust gas (12) of the heating furnace (7) into the preheating furnace (4), the exhaust gas recirculation line (14) leading from the heating furnace (7) to the preheating furnace (4); and - an oxygen conduit (15) for introducing oxygen into the preheating furnace (4), the oxygen conduit (15) discharging into the preheating furnace (4).
[10]
10. The device according to claim 9, characterized in that the burners (11) are designed as oxygen burners for burning a hot gas with the addition of oxygen.
[11]
11. The device according to claim 9, characterized in that a heating gas line (16) for introducing a heating gas in the preheating furnace (4) opens.
[12]
12. The device according to claim 9, characterized in that an induction furnace (6) is arranged immediately after the descaling device (5), wherein the heating furnace (7) via an exhaust gas guide (17) to the induction furnace (6) is connected.
[13]
13. The apparatus according to claim 12, characterized in that in the transport direction (10) input end of the induction furnace (6) via an exhaust gas recirculation line (14) to the preheating furnace (4) is connected.
[14]
14. The device according to claim 9, characterized in that a controller (19) on the one hand with a 201110574 * * * * * * gas concentration meter (20) for determining the gas concentration (22) in a furnace (4) and on the other hand with an actuator (18a , 18b) for influencing the gas concentration.

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同族专利:

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CN103582708A|2014-02-12|

RU2605733C2|2016-12-27|

RU2013158326A|2015-07-20|

CN103582708B|2016-06-15|

AT511429B1|2012-12-15|

EP2718470A1|2014-04-16|

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WO2012168141A1|2012-12-13|

引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

DE4402402A1|1994-01-27|1995-08-03|Schloemann Siemag Ag|Process and plant for the production of hot-rolled steel strip from continuously cast starting material|

WO1997001403A1|1995-06-29|1997-01-16|Hoogovens Staal B.V.|Method and plant for the manufacture of a thin hot-rolled steel strip|

EP0771596A1|1995-11-03|1997-05-07|Sms Schloemann-Siemag Aktiengesellschaft|Installation for rolling hot strip by continuous or discontinuous rolling|

JPH052725B2|1987-04-21|1993-01-13|Sumitomo Metal Ind|

DE4236307A1|1992-10-28|1994-05-05|Schloemann Siemag Ag|Method and plant for the production of hot-rolled steel strip, in particular from strip-shaped continuous material|

SE519193C2|1998-12-18|2003-01-28|Avesta Polarit Ab Publ|Manufacture of stainless steel strip comprises cold rolling in a rolling mill line|

DE10203711A1|2002-01-31|2003-08-14|Sms Demag Ag|Process and plant for the production of hot strip from austenitic stainless steels|

DE102004040927A1|2004-08-24|2006-03-02|Sms Demag Ag|Method and device for producing metal strips|

AT504782B1|2005-11-09|2008-08-15|Siemens Vai Metals Tech Gmbh|METHOD FOR PRODUCING A HOT-ROLLED STEEL STRIP AND COMBINED CASTING AND ROLLING MACHINE TO PERFORM THE METHOD|

DE102007005015A1|2006-06-26|2008-01-03|Sms Demag Ag|Process and plant for the production of hot rolled strip of silicon steel based on thin slabs|

CN101484593B|2006-06-26|2011-06-08|西马克·西马格公司|A method and a system for producing hot-rolled strip silicon steel based on thin slabs|

DE102008029581A1|2007-07-21|2009-01-22|Sms Demag Ag|Method and apparatus for making strips of silicon or multi-phase steel|

CN101181718B|2007-12-11|2010-06-02|武汉钢铁公司|Method for producing wide strip steel by bar strip continuous casting and rolling as well as system therefor|

DE102009018683A1|2009-04-23|2010-10-28|Sms Siemag Ag|Method and device for continuous casting of a slab|

CN201525852U|2009-10-23|2010-07-14|秦皇岛秦冶重工有限公司|Baking equipment of hot blast stove|DE202013102749U1|2013-05-29|2013-10-17|Otto Junker Gmbh|Apparatus for heat treatment of metallic useful material under protective gas / reaction atmosphere in continuous operation|

WO2021038108A1|2019-08-30|2021-03-04|Sms Group Gmbh|Method for the heat treatment of a primary steel product|

法律状态:
2016-06-15| PC| Change of the owner|Owner name: PRIMETALS TECHNOLOGIES AUSTRIA GMBH, AT Effective date: 20160415 |

2018-02-15| MM01| Lapse because of not paying annual fees|Effective date: 20170610 |

优先权:

申请号 | 申请日 | 专利标题

AT8612011A|AT511429B1|2011-06-10|2011-06-10|METHOD AND DEVICE FOR PRE-TREATING A ROLLING BEFORE ROLLING|AT8612011A| AT511429B1|2011-06-10|2011-06-10|METHOD AND DEVICE FOR PRE-TREATING A ROLLING BEFORE ROLLING|

RU2013158326/02A| RU2605733C2|2011-06-10|2012-06-01|Method and apparatus for pretreatment of rolled article before hot rolling|

CN201280028378.1A| CN103582708B|2011-06-10|2012-06-01|For rolled piece being carried out pretreated method and device before hot rolling|

EP12726403.4A| EP2718470B1|2011-06-10|2012-06-01|Method and device for pretreating a rolled good before hot rolling|

PCT/EP2012/060327| WO2012168141A1|2011-06-10|2012-06-01|Method and device for pretreating a rolled good before hot rolling|

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