TW201800590A - Method for manufacturing austenitic alloy steel - Google Patents
Method for manufacturing austenitic alloy steel Download PDFInfo
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本發明是關於一種合金鋼材的製造方法,特別是關於一種沃斯田鐵系合金鋼材的製造方法。 The present invention relates to a method for producing an alloy steel material, and more particularly to a method for producing a Worthfield iron-based alloy steel material.
沃斯田鐵主要為面心立方(face center cubic;FCC)結構。常見的沃斯田鐵系合金包括鎳基合金(例如,Alloy 800H、825、A-286、625、718)、鎳銅合金(例如,Alloy 400、500K)及沃斯田鐵系不鏽鋼(例如,309、310不鏽鋼)。沃斯田鐵系合金可用於需要高溫機械性質的場合,例如,發動機之組件、渦輪引擎緊固件、高溫軸承、加熱爐外罩、石化廠之管線等。 The Worthfield iron is mainly a face center cubic (FCC) structure. Common Worthfield iron-based alloys include nickel-based alloys (eg, Alloy 800H, 825, A-286, 625, 718), nickel-copper alloys (eg, Alloy 400, 500K), and Worthfield iron-based stainless steels (eg, 309, 310 stainless steel). Worthfield iron alloys can be used in applications where high temperature mechanical properties are required, such as engine components, turbine engine fasteners, high temperature bearings, furnace envelopes, pipelines in petrochemical plants, and the like.
一般而言,沃斯田鐵系合金材料可先利用熔煉製程,例如以燃料加熱爐、非真空電爐(Electric Arc Furnace,EAF)或真空電弧熔煉爐(Vacuum arc melting,VAM)等進行熔煉,以形成合金胚料,其中合金胚料可例如模鑄鑄錠或連鑄胚料。在熔煉製程後,前述合金胚料可選擇性進行精煉製程,例如氬氣吹氧脫碳(Argon Oxygen Decarburization,AOD)、真空吹氧脫碳(Vacuum Oxygen Decarburization,VOD)、電渣重熔(electroslag remelting,ESR)及真空電弧重熔(Vacuum arc remelting,VAR)等。接著,上述所得之模鑄鑄錠或連鑄胚料進行熱加工,針對不同需求,可形成板狀、塊狀、棒狀、管狀、片狀等各種外型的產品。 In general, the Worthfield iron-based alloy material can be first smelted by a melting process, for example, by a fuel heating furnace, an Electric Arc Furnace (EAF) or a vacuum arc melting (VAM). An alloy blank is formed, wherein the alloy blank can be, for example, a molded ingot or a continuous casting billet. After the smelting process, the foregoing alloy blank can be selectively subjected to a refining process such as Argon Oxygen Decarburization (AOD), Vacuum Oxygen Decarburization (VOD), Electroslag Remelting (electroslag) Remelting, ESR) and vacuum arc remelting (Vacuum arc Remelting, VAR) and so on. Then, the die-cast ingot or the continuous-cast billet obtained as described above is subjected to hot working, and various shapes such as a plate shape, a block shape, a rod shape, a tube shape, and a sheet shape can be formed for different needs.
關於習知的熱加工製程,請參閱圖1,其係繪示根據習知沃斯田鐵系合金鋼材之製造方法100的部分流程圖。首先,對沃斯田鐵系合金材料進行熔煉製程步驟110後,形成合金胚料。然後,對此合金胚料進行加熱步驟120和熱軋延步驟130,其係以固定加熱溫度進行加熱和固定裁減率重複進行熱加工,以製得具有目標厚度的板材。 With regard to the conventional thermal processing process, please refer to FIG. 1, which is a partial flow chart showing a manufacturing method 100 of a conventional Worthfield iron-based alloy steel. First, after the smelting process step 110 is performed on the Vostian iron-based alloy material, an alloy billet is formed. Then, the alloy billet is subjected to a heating step 120 and a hot rolling step 130, which are repeatedly subjected to hot working at a fixed heating temperature for heating and a fixed reduction rate to obtain a sheet having a target thickness.
然而,由於沃斯田鐵系合金胚料的熱加工性質(例如熱延性)不佳,適用的熱加工溫度及/或熱加工裁減率的範圍較窄,導致熱加工製程進行的時間較長。若為了縮短熱加工製程時間,而將加工溫度或加工裁減率超出適用的範圍,則所製得的板材容易產生表面缺陷。 However, due to the poor thermal processing properties (e.g., hot ductility) of the Worthfield iron-based alloy billet, the range of applicable hot working temperatures and/or hot working reduction rates is narrow, resulting in a longer thermal processing process. If the processing temperature or the processing reduction rate is out of the applicable range in order to shorten the hot working process time, the resulting sheet is liable to cause surface defects.
有鑑於此,亟須提出一種沃斯田鐵系合金鋼材之製造方法,以改善沃斯田鐵系合金的熱加工性質(例如擴大熱加工溫度、熱加工裁減率的範圍),縮短熱加工製程時間,且所製得的板材實質上不具有表面缺陷。 In view of this, it is not necessary to propose a method for manufacturing a Worthfield iron-based alloy steel to improve the hot working properties of the Worthfield iron-based alloy (for example, expanding the range of hot working temperature and hot working reduction rate) and shortening the hot working process. Time, and the resulting sheet has substantially no surface defects.
因此,本發明之一態樣是提供一種沃斯田鐵系合金鋼材之製造方法,利用多階段熱加工製程,藉此改善沃斯田鐵系合金的熱加工性質,縮短熱加工製程時間,且所製得的板材實質上不具有表面缺陷。 Therefore, an aspect of the present invention provides a method for manufacturing a Worthfield iron-based alloy steel, which utilizes a multi-stage hot working process, thereby improving the hot working property of the Worthfield iron-based alloy and shortening the hot working process time, and The resulting sheet material has substantially no surface defects.
根據本發明之上述態樣,提出一種沃斯田鐵系 合金鋼材之製造方法。在一實施例中,首先,對沃斯田鐵系合金材料進行熔煉製程,以形成沃斯田鐵系合金胚料。 According to the above aspect of the invention, a Worthian iron system is proposed. Manufacturing method of alloy steel. In one embodiment, first, a Vostian iron-based alloy material is subjected to a smelting process to form a Worthfield iron-based alloy billet.
接著,對沃斯田鐵系合金胚料進行多階段熱加工製程,其中多階段熱加工製程包含第一階段熱加工步驟和第二階段熱加工步驟。在一例示中,以第一裁減率和第一加熱溫度對沃斯田鐵系合金胚料進行第一階段熱加工步驟,並獲得具有第一厚度之沃斯田鐵系合金胚料。在一例示中,基於沃斯田鐵系合金胚料的初始厚度為100%,第一厚度相對於初始厚度之第一裁減率可例如不高於25%。在另一例示中,前述之第一加熱溫度可例如為850℃至1100℃。 Next, a multi-stage thermal processing process is performed on the Worthfield iron-based alloy blank, wherein the multi-stage thermal processing process includes a first-stage thermal processing step and a second-stage thermal processing step. In one example, the first stage thermal processing step is performed on the Worthfield iron-based alloy billet at a first reduction rate and a first heating temperature, and a Worthfield iron-based alloy billet having a first thickness is obtained. In one example, the initial thickness of the first thickness relative to the initial thickness may be, for example, no greater than 25% based on the initial thickness of the Worthfield iron-based alloy billet being 100%. In another illustration, the aforementioned first heating temperature may be, for example, 850 ° C to 1100 ° C.
然後,以第二裁減率和第二加熱溫度對具有第一厚度之沃斯田鐵系合金胚料進行至少一次第二階段熱加工步驟,以獲得具有第二厚度之沃斯田鐵系合金胚料。在一例示中,基於上述沃斯田鐵系合金胚料的第一厚度為100%,第二厚度相對於第一厚度之第二裁減率可例如不低於30%,且第二裁減率大於第一裁減率。在另一例示中,前述之第二加熱溫度可例如為1050℃至1300℃。 Then, the Worth Iron-based alloy billet having the first thickness is subjected to at least one second-stage thermal processing step at a second reduction rate and a second heating temperature to obtain a Worthfield iron-based alloy embryo having a second thickness. material. In an example, the first thickness of the Worstian iron-based alloy billet is 100%, and the second reduction ratio of the second thickness relative to the first thickness may be, for example, not less than 30%, and the second reduction rate is greater than The first reduction rate. In another illustration, the aforementioned second heating temperature may be, for example, 1050 ° C to 1300 ° C.
根據本發明之一實施例,上述之沃斯田鐵系合金材料包含5至75wt%的鐵、7至75wt%的鎳、15至35wt%的鉻以及其他不可避免的雜質。 According to an embodiment of the present invention, the above-mentioned Vostian iron-based alloy material contains 5 to 75 wt% of iron, 7 to 75 wt% of nickel, 15 to 35 wt% of chromium, and other unavoidable impurities.
根據本發明之一實施例,上述之第一裁減率為5%至20%。 According to an embodiment of the invention, the first reduction rate is 5% to 20%.
根據本發明之一實施例,上述之第二裁減率為35%至60%。 According to an embodiment of the invention, the second reduction rate is from 35% to 60%.
根據本發明之一實施例,上述第一階段熱加工步驟只進行一次。 According to an embodiment of the invention, the first stage thermal processing step is performed only once.
根據本發明之一實施例,上述多階段熱加工製程可例如軋延製程、鍛造製程、擠壓製程或沖壓製程。 According to an embodiment of the present invention, the multi-stage thermal processing process may be, for example, a rolling process, a forging process, an extrusion process, or a stamping process.
應用本發明的一種沃斯田鐵系合金鋼材之製造方法,其利用多階段熱加工製程,即,先藉由低加熱溫度和低裁減率的第一階段熱加工步驟,改善沃斯田鐵系合金胚料的熱加工性質,且擴大胚料之可熱加工製程窗口後,再進行高加熱溫度和高裁減率的第二階段熱加工步驟,以將胚料進一步加工至目標厚度。因此可有效改善沃斯田鐵系合金的熱加工性質,並縮短熱加工製程時間。 A method for manufacturing a Worthfield iron-based alloy steel according to the present invention, which utilizes a multi-stage thermal processing process, that is, a first stage thermal processing step with a low heating temperature and a low reduction rate to improve the Worth Iron system After the hot working property of the alloy billet, and expanding the hot work process window of the billet, a second stage thermal processing step of high heating temperature and high reduction rate is performed to further process the billet to the target thickness. Therefore, the hot working property of the Worthfield iron alloy can be effectively improved, and the hot working process time can be shortened.
100‧‧‧方法 100‧‧‧ method
110‧‧‧對沃斯田鐵系合金鋼材進行熔煉 110‧‧‧Smelting of Worthfield iron alloy steel
120‧‧‧進行加熱步驟 120‧‧‧heating steps
130‧‧‧進行熱軋延步驟 130‧‧‧Shot rolling step
200‧‧‧方法 200‧‧‧ method
210‧‧‧對沃斯田鐵系合金鋼材進行熔煉 210‧‧‧Smelting of Worthfield iron alloy steel
220‧‧‧以第一加熱溫度進行加熱步驟 220‧‧‧ Heating step at the first heating temperature
230‧‧‧以第一裁減率進行熱軋延步驟 230‧‧‧The hot rolling step at the first reduction rate
240‧‧‧以第二加熱溫度進行加熱步驟 240‧‧‧ Heating step at a second heating temperature
250‧‧‧以第二裁減率進行熱軋延步驟 250‧‧‧The hot rolling step with a second reduction rate
為讓本發明之上述和其他目的、特徵、優點與實施例能更明顯易懂,所附圖式之詳細說明如下:[圖1]係繪示根據習知沃斯田鐵系合金鋼材之製造方法的部分流程圖。 The above and other objects, features, advantages and embodiments of the present invention will become more <RTIgt; <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; Part of the flow chart of the method.
[圖2]係繪示根據本發明之一實施例的沃斯田鐵系合金鋼材之製造方法的部分流程圖。 Fig. 2 is a partial flow chart showing a method of manufacturing a Worthfield iron-based alloy steel according to an embodiment of the present invention.
承前所述,本發明提出的一種沃斯田鐵系合金鋼材之製造方法,其利用多階段熱加工製程以改善沃斯田鐵系合金的熱加工性質,並縮短熱加工製程時間。請參閱圖 2,其繪示根據本發明之一實施例的沃斯田鐵系合金鋼材之製造方法的部分流程圖。首先,對沃斯田鐵系合金材料進行熔煉製程步驟210,以形成沃斯田鐵系合金胚料。 As described above, the present invention provides a method for manufacturing a Worthfield iron-based alloy steel which utilizes a multi-stage hot working process to improve the hot working properties of the Worthfield iron-based alloy and to shorten the hot working process time. Please refer to the picture 2, which is a partial flow chart showing a method of manufacturing a Worthfield iron-based alloy steel according to an embodiment of the present invention. First, a smelting process step 210 is performed on the Vostian iron-based alloy material to form a Worthfield iron-based alloy billet.
在熔煉製程後,前述合金胚料可選擇性進行習知的精煉製程,例如AOD、VOD、ESR、VAR等,此為本發明所屬技術領域中具有通常知識者所熟知,在此不另贅述。 After the smelting process, the foregoing alloy blanks may be selectively subjected to conventional refining processes, such as AOD, VOD, ESR, VAR, etc., which are well known to those of ordinary skill in the art to which the present invention pertains, and are not described herein.
接著,對沃斯田鐵系合金胚料進行多階段熱加工製程。其中多階段熱加工製程包含第一階段熱加工步驟和第二階段熱加工步驟。第一階段熱加工步驟是包含以第一加熱溫度進行加熱步驟220和以第一裁減率進行熱軋延步驟230,並獲得具有第一厚度之沃斯田鐵系合金胚料。裁減率定義為裁減厚度(△h=入料胚料厚度h0-出料胚料厚度h1)和入料胚料厚度(h0)的比值,即△h/h0。基於沃斯田鐵系合金胚料的初始厚度為100%,第一厚度相對於初始厚度之第一裁減率為不高於25%。第一加熱溫度為850℃至1100℃。在此說明的是,第一階段熱加工步驟的第一裁減率和第一加熱溫度須配合材料成分性質做調整,其中若第一裁減率高於25%,除了可能導致胚料產生表面缺陷,也將導致胚料的晶粒成長過大,則無法有效改善胚料的熱加工性質。因此,第一裁減率可例如為5%至20%。而第一加熱溫度若高於1100℃或低於850℃,則可能超過胚料的可熱加工區間,而造成胚料產生表面缺陷。此第一階段熱加工步驟係為了誘發合金材料發生再結晶,優化合金組織,進而提升材料的高 溫熱延性,並擴大其熱加工溫度及熱加工裁減率。因此,第一階段熱加工步驟通常僅須進行一次即可。若進行一次以上的第一階段熱加工步驟,則同樣會導致胚料的晶粒成長過大,且增加熱加工製程的時間。 Next, a multi-stage thermal processing process is performed on the Worthfield iron-based alloy billet. The multi-stage thermal processing process includes a first stage thermal processing step and a second stage thermal processing step. The first stage thermal processing step includes performing the heating step 220 at the first heating temperature and the hot rolling step 230 at the first reduction rate, and obtaining the Worthfield iron-based alloy billet having the first thickness. The reduction rate is defined as the ratio of the cut thickness (Δh = feed blank thickness h 0 - discharge blank thickness h 1 ) to the feed blank thickness (h 0 ), ie Δh/h 0 . The initial thickness of the first thickness relative to the initial thickness is not more than 25% based on the initial thickness of the Worthite iron-based alloy blank. The first heating temperature is 850 ° C to 1100 ° C. It is explained here that the first reduction rate and the first heating temperature of the first stage thermal processing step are adjusted in accordance with the material composition properties, wherein if the first reduction rate is higher than 25%, in addition to causing surface defects of the billet, It will also cause the grain growth of the billet to be too large, and the hot processing property of the billet cannot be effectively improved. Therefore, the first reduction rate can be, for example, 5% to 20%. If the first heating temperature is higher than 1100 ° C or lower than 850 ° C, it may exceed the hot workable interval of the billet, causing surface defects of the billet. The first stage of the thermal processing step is to induce recrystallization of the alloy material, optimize the alloy structure, thereby improving the high temperature hot ductility of the material, and expanding the hot working temperature and the hot working reduction rate. Therefore, the first stage thermal processing step usually only needs to be performed once. If more than one first-stage thermal processing step is performed, the grain growth of the billet is also excessively increased, and the time of the hot working process is increased.
然後,對沃斯田鐵系合金胚料以第二加熱溫度進行加熱步驟240及以第二裁減率進行熱軋延步驟250的第二階段熱加工步驟,並獲得具有第二厚度之沃斯田鐵系合金胚料。基於沃斯田鐵系合金胚料的第一厚度為100%,第二厚度相對於第一厚度之第二裁減率為不低於30%。第二加熱溫度為1050℃至1300℃,其中第二裁減率大於第一裁減率。若第二加熱溫度超過1300℃,則可能導致胚料產生表面缺陷;若第二加熱溫度低於1050℃,則無法以高第二裁減率進行熱軋延。而若以30%以下的裁減率進行熱軋延,則無法達到本發明有效減少熱加工製程時間的優勢。在此說明的是,第二加熱溫度為經過第一階段熱加工步驟大幅改善材料熱加工性質後的可熱加工區間,同樣須配合使用的沃斯田鐵系合金材料而調整。經過第一階段熱加工步驟後的胚料可使用高於30%的裁減率進行熱加工,例如可為35%至60%。此第二階段熱加工步驟可選擇性地反覆實施,以製得目標厚度的材料。 Then, the Worsfield iron-based alloy billet is subjected to a heating step 240 at a second heating temperature and a second-stage hot working step of the hot rolling step 250 at a second reduction rate, and a Worstian having a second thickness is obtained. Iron-based alloy billet. The first thickness based on the Worthfield iron-based alloy blank is 100%, and the second reduction ratio of the second thickness relative to the first thickness is not less than 30%. The second heating temperature is from 1050 ° C to 1300 ° C, wherein the second reduction rate is greater than the first reduction rate. If the second heating temperature exceeds 1300 ° C, surface defects may occur in the billet; if the second heating temperature is lower than 1050 ° C, hot rolling may not be performed at a second second reduction rate. However, if the hot rolling is performed at a reduction rate of 30% or less, the advantage of the present invention for effectively reducing the hot working process time cannot be achieved. It is explained here that the second heating temperature is a heat-processable section after substantially improving the hot working property of the material through the first-stage thermal processing step, and is also adjusted in accordance with the use of the Worthfield iron-based alloy material. The billet after the first stage thermal processing step can be thermally processed using a reduction ratio of more than 30%, for example, from 35% to 60%. This second stage thermal processing step can be selectively repeated to produce a target thickness of material.
一般而言,熔煉製程後所得之沃斯田鐵系合金胚料的晶粒尺寸大,因晶界處之雜質元素濃度的增加和聚集,導致晶界弱化,而大幅降低胚料的熱加工性質,故若以高加熱溫度和高裁減率進行熱加工時,會因高溫熱延性不 佳,晶粒成長過大,來不及發生塑性變形,而造成表面缺陷。因此,通常僅會在材料的可熱加工溫度和較小的裁減率之條件下進行熱加工,否則即會有軋裂或鍛裂等表面缺陷產生。意即,未經過本發明之第一階段熱加工步驟的沃斯田鐵系合金胚料,並無法實施高加熱溫度和高裁減率的第二階段熱加工步驟。換句話說,利用第一階段熱加工步驟將胚料的可熱加工溫度及可熱加工裁減率提高,由於加熱胚料至熱加工溫度的時間係遠大於實際進行熱加工(例如:軋延)的時間,因此減少熱加工製程次數,即減少須回爐加熱的次數,則可減少熱加工製程時間。 In general, the grain size of the Wostian iron-based alloy billet obtained after the smelting process is large, and the grain boundary is weakened due to the increase and concentration of the impurity element at the grain boundary, thereby greatly reducing the hot working property of the billet. Therefore, if the hot processing is performed at a high heating temperature and a high reduction rate, the hot ductility due to high temperature is not Good, the grain growth is too large, and it is too late to plastically deform, resulting in surface defects. Therefore, hot working is usually performed only under the conditions of the hot process temperature and the small reduction rate of the material, otherwise surface defects such as rolling or forging may occur. That is, the Worth Iron-based alloy blank which has not undergone the first-stage thermal processing step of the present invention cannot be subjected to the second-stage thermal processing step of high heating temperature and high reduction rate. In other words, the first stage thermal processing step is used to increase the hot process temperature and the hot work reduction rate of the billet, since the time for heating the billet to the hot working temperature is much greater than the actual hot working (for example, rolling) The time, therefore reducing the number of thermal processing processes, that is, reducing the number of times the furnace needs to be heated, can reduce the hot processing time.
以下利用數個實施例以說明本發明之應用,然其並非用以限定本發明,本發明技術領域中具有通常知識者,在不脫離本發明之精神和範圍內,當可作各種之更動與潤飾。 The following examples are used to illustrate the application of the present invention, and are not intended to limit the present invention. Those skilled in the art can make various changes without departing from the spirit and scope of the present invention. Retouching.
實施例一使用的沃斯田鐵系合金材料為鎳基合金,包含55wt%的鐵、26wt%的Ni、15wt%的Cr、0.3wt%的V、2.2wt%的Ti、1.3wt%的Mo以及微量的B和Al。首先,對沃斯田鐵系合金材料進行熔煉製程。接著,對熔煉製程後所得之沃斯田鐵系合金胚料進行第一階段熱加工步驟,請參閱表1,其係根據本發明之一實施例進行多階段熱加工製程的製程參數。此實施例之沃斯田鐵系合金胚料的起始厚度(h0)為750mm。其中以第一加熱溫度為850℃至1050℃,且以h0為100%時,第一裁減率為5%至10%的條 件,可將沃斯田鐵系合金胚料軋延至第一厚度(h1),即675mm。 The Worthfield iron-based alloy material used in the first embodiment is a nickel-based alloy containing 55 wt% of iron, 26 wt% of Ni, 15 wt% of Cr, 0.3 wt% of V, 2.2 wt% of Ti, and 1.3 wt% of Mo. And trace amounts of B and Al. First, a smelting process is performed on the Worthfield iron-based alloy material. Next, the first stage thermal processing step is performed on the Vostian iron-based alloy billet obtained after the smelting process. Please refer to Table 1, which is a process parameter for performing the multi-stage hot working process according to an embodiment of the present invention. The starting thickness (h 0 ) of the Worthite iron-based alloy billet of this example was 750 mm. Wherein the first heating temperature is 850 ° C to 1050 ° C, and when the h 0 is 100%, the first reduction rate is 5% to 10%, the Worth iron alloy billet can be rolled to the first thickness (h 1 ), ie 675 mm.
然後,對具有較佳熱加工性能的沃斯田鐵系合金胚料進行第二階熱加工步驟,其中包含對胚料以第二加熱溫度進行加熱和以第二裁減率進行熱軋延。如表1的實施例中,第二加熱溫度為1050℃至1290℃,且以上述第一階段熱加工步驟所得之沃斯田鐵系合金胚料的第一厚度(h1)為100%,第二裁減率為35%至50%。並重覆進行3次第二階段熱加工步驟(即回爐再加熱2次),以得到目標厚度150mm的鋼材。 Then, a second-stage thermal processing step is performed on the Worthfield iron-based alloy billet having better hot workability, which comprises heating the billet at a second heating temperature and hot rolling at a second reduction rate. In the embodiment of Table 1, the second heating temperature is 1050 ° C to 1290 ° C, and the first thickness (h 1 ) of the Worth Iron-based alloy billet obtained by the first-stage hot working step is 100%. The second reduction rate is 35% to 50%. The second stage hot working step (ie, reheating and reheating twice) was repeated three times to obtain a steel material having a target thickness of 150 mm.
實施例二至三以與實施例一相同的製造方法進行,差別在於所使用的沃斯田鐵系合金材料、加熱溫度及裁減率不同,其具體製程條件如表2及表3所示。實施例二使用的沃斯田鐵系合金材料是34wt%的Ni、21wt%的Cr、43.5%的Fe、0.08%的C、1wt%的Al+Ti以及微量的Cu、Si、Mn,而實施例三使用的沃斯田鐵系合金材料是42wt%的Ni、21.5wt%的Cr、30%的Fe、3.2wt%的Mo、2.2%的Cu、1.0wt%的Ti以及微量的Al、C。 The second to third embodiments were carried out in the same manner as in the first embodiment except that the Worstian iron-based alloy materials used, the heating temperature and the reduction rate were different, and the specific process conditions are shown in Tables 2 and 3. The Worthite iron-based alloy material used in the second embodiment is 34 wt% of Ni, 21 wt% of Cr, 43.5% of Fe, 0.08% of C, 1 wt% of Al+Ti, and a trace amount of Cu, Si, and Mn. The Worthite iron-based alloy material used in Example 3 was 42 wt% of Ni, 21.5 wt% of Cr, 30% of Fe, 3.2 wt% of Mo, 2.2% of Cu, 1.0 wt% of Ti, and trace amounts of Al and C. .
比較例一使用與實施例一相同成分的沃斯田鐵系合金材料,且同樣將厚度750mm的沃斯田鐵系合金胚料軋延至150mm,但是以習知製造方法進行。請參閱表4,其係根據本發明之比較例進行習知熱加工製程的製程參數。如表2所示,其加熱溫度為950℃至1125℃,且裁減率為10%至15%,則所須熱加工製程次數為8次(即回爐再加熱7次)。 In Comparative Example 1, a Worth Iron-based alloy material having the same composition as in Example 1 was used, and a Worstian iron-based alloy blank having a thickness of 750 mm was similarly rolled to 150 mm, but was carried out by a known production method. Please refer to Table 4, which is a process parameter for a conventional thermal processing process in accordance with a comparative example of the present invention. As shown in Table 2, the heating temperature is 950 ° C to 1125 ° C, and the reduction rate is 10% to 15%, the number of hot processing processes required is 8 (ie, reheating 7 times).
由表1至表4的結果可知,實施例一至三由於所用的沃斯田鐵系合金胚料的組成成分不同,因此其熱加工溫度和裁減率均有所差異。然而,實施例一至三利用本發明的多階段熱加工製程方法,先將沃斯田鐵系合金胚料進行一次第一階段熱加工,使胚料的表面和心部均勻發生塑性變形,在塑性變形過程中,伴隨動態再結晶效應(dynamic recrystallization)和動態回復(dynamic recover),以形成尺寸小的晶粒組織,進而改善其熱加工性質,擴大其可熱加工窗口(擴大熱加工溫度、熱加工裁減率的範圍)。接著,再實施高加熱溫度和高裁減率的第二階段熱加工製程,因此可縮短熱加工製程時間,包括減少習知熱加工製程的重覆次數,即減少胚料回爐再加熱的次數,故可減少習知熱加工製程所需的時間。再者,由本發明方法所製得的板材實質上不具有表面缺陷,確實達到本發明的目的。相較之下,比較例所需熱加工步驟次數較多,即回爐再加熱次數較多,則其熱加工製程的進行時間較長。 From the results of Tables 1 to 4, it is understood that Examples 1 to 3 differ in the hot working temperature and the reduction ratio due to the difference in the composition of the Worstian iron-based alloy billet used. However, in the first to third embodiments, the multi-stage thermal processing method of the present invention is used to first perform a first-stage thermal processing of the Worth iron-based alloy billet to uniformly plastically deform the surface and the core of the billet. Dynamic recrystallization effect (dynamic Recrystallization) and dynamic recovery to form a small-sized grain structure, thereby improving its hot working properties and expanding its hot-processable window (expanding the range of hot working temperature and hot working reduction rate). Then, the second-stage thermal processing process with high heating temperature and high reduction rate is implemented, so that the hot processing time can be shortened, including reducing the number of repetitions of the conventional thermal processing process, that is, reducing the number of times the billet is reheated and reheated. It reduces the time required for conventional thermal processing. Furthermore, the sheet produced by the method of the present invention does not substantially have surface defects and does achieve the object of the present invention. In comparison, the number of hot working steps required in the comparative example is large, that is, the number of times of reheating in the furnace is more, and the hot working process takes a longer time.
由上述實施例可知,本發明之沃斯田鐵系合金鋼材之製造方法利用多階段熱加工製程,即,先藉由一次低加熱溫度和低裁減率的第一階段熱加工步驟,確實可有效改善沃斯田鐵系合金胚料的熱加工性質,提升材料高溫熱延性,並擴大熱加工溫度、熱加工裁減率的範圍。後續進行高加熱溫度和高裁減率的第二階段熱加工步驟,重覆第二階段熱加工步驟一次以上,可將胚料加工至目標厚度,又可大幅減少熱加工步驟的次數,有效縮短熱加工製程所需時間,且所製得的板材實質上不具有表面缺陷。 It can be seen from the above embodiments that the manufacturing method of the Vostian iron-based alloy steel of the present invention utilizes a multi-stage hot working process, that is, the first stage thermal processing step by a low heating temperature and a low reduction rate is indeed effective. Improve the hot processing properties of the Worthfield iron-based alloy billet, improve the high-temperature hot ductility of the material, and expand the range of hot processing temperature and hot processing reduction rate. Subsequent high-heating temperature and high-reduction rate of the second-stage thermal processing step, repeating the second-stage thermal processing step more than once, the billet can be processed to the target thickness, and the number of thermal processing steps can be greatly reduced, effectively reducing the heat The time required for the processing process, and the resulting sheet material has substantially no surface defects.
雖然本發明已以數個實施例揭露如上,然其並非用以限定本發明,在本發明所屬技術領域中任何具有通常知識者,在不脫離本發明之精神和範圍內,當可作各種之更動與潤飾,因此本發明之保護範圍當視後附之申請專利範圍所界定者為準。 While the invention has been described above in terms of several embodiments, it is not intended to limit the scope of the invention, and the invention may be practiced in various embodiments without departing from the spirit and scope of the invention. The scope of protection of the present invention is defined by the scope of the appended claims.
200‧‧‧方法 200‧‧‧ method
210‧‧‧對沃斯田鐵系合金鋼材進行熔煉 210‧‧‧Smelting of Worthfield iron alloy steel
220‧‧‧以第一加熱溫度進行加熱步驟 220‧‧‧ Heating step at the first heating temperature
230‧‧‧以第一裁減率進行熱軋延步驟 230‧‧‧The hot rolling step at the first reduction rate
240‧‧‧以第二加熱溫度進行加熱步驟 240‧‧‧ Heating step at a second heating temperature
250‧‧‧以第二裁減率進行熱軋延步驟 250‧‧‧The hot rolling step with a second reduction rate
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