JP2010038553A - TOUGHNESS EVALUATING METHOD OF HIGH Cr-BASED STEEL STRUCTURE - Google Patents
TOUGHNESS EVALUATING METHOD OF HIGH Cr-BASED STEEL STRUCTURE Download PDFInfo
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- 229910000831 Steel Inorganic materials 0.000 title claims abstract description 52
- 239000010959 steel Substances 0.000 title claims abstract description 52
- 238000000034 method Methods 0.000 title claims abstract description 16
- 230000010287 polarization Effects 0.000 claims abstract description 22
- 239000003792 electrolyte Substances 0.000 claims abstract description 8
- 229910001068 laves phase Inorganic materials 0.000 claims description 19
- 238000011156 evaluation Methods 0.000 claims description 17
- 238000010586 diagram Methods 0.000 claims description 14
- 239000008151 electrolyte solution Substances 0.000 claims description 13
- 239000003929 acidic solution Substances 0.000 claims description 5
- 239000000463 material Substances 0.000 description 65
- 230000032683 aging Effects 0.000 description 17
- 238000003878 thermal aging Methods 0.000 description 12
- 238000010521 absorption reaction Methods 0.000 description 11
- 238000002474 experimental method Methods 0.000 description 11
- 229910052751 metal Inorganic materials 0.000 description 11
- 239000002184 metal Substances 0.000 description 11
- 238000010438 heat treatment Methods 0.000 description 10
- 230000005611 electricity Effects 0.000 description 7
- 238000001514 detection method Methods 0.000 description 5
- 238000009863 impact test Methods 0.000 description 5
- 230000000694 effects Effects 0.000 description 4
- 230000007774 longterm Effects 0.000 description 4
- 238000005259 measurement Methods 0.000 description 4
- 238000001556 precipitation Methods 0.000 description 4
- 238000011084 recovery Methods 0.000 description 4
- 206010027146 Melanoderma Diseases 0.000 description 3
- 230000000875 corresponding effect Effects 0.000 description 3
- 238000012545 processing Methods 0.000 description 3
- 238000012360 testing method Methods 0.000 description 3
- 241001417527 Pempheridae Species 0.000 description 2
- QAOWNCQODCNURD-UHFFFAOYSA-N Sulfuric acid Chemical compound OS(O)(=O)=O QAOWNCQODCNURD-UHFFFAOYSA-N 0.000 description 2
- 229910052804 chromium Inorganic materials 0.000 description 2
- 238000002848 electrochemical method Methods 0.000 description 2
- 230000004927 fusion Effects 0.000 description 2
- 239000000155 melt Substances 0.000 description 2
- 238000001000 micrograph Methods 0.000 description 2
- BASFCYQUMIYNBI-UHFFFAOYSA-N platinum Chemical compound [Pt] BASFCYQUMIYNBI-UHFFFAOYSA-N 0.000 description 2
- 239000000243 solution Substances 0.000 description 2
- 239000000126 substance Substances 0.000 description 2
- 238000012795 verification Methods 0.000 description 2
- 238000003466 welding Methods 0.000 description 2
- 239000002253 acid Substances 0.000 description 1
- 239000012670 alkaline solution Substances 0.000 description 1
- 239000007864 aqueous solution Substances 0.000 description 1
- 239000010953 base metal Substances 0.000 description 1
- 230000033228 biological regulation Effects 0.000 description 1
- 230000005540 biological transmission Effects 0.000 description 1
- 229910052799 carbon Inorganic materials 0.000 description 1
- 239000005539 carbonized material Substances 0.000 description 1
- 229910052729 chemical element Inorganic materials 0.000 description 1
- 230000002596 correlated effect Effects 0.000 description 1
- 230000008034 disappearance Effects 0.000 description 1
- 239000002932 luster Substances 0.000 description 1
- 239000011159 matrix material Substances 0.000 description 1
- 238000002844 melting Methods 0.000 description 1
- 230000008018 melting Effects 0.000 description 1
- 150000001247 metal acetylides Chemical class 0.000 description 1
- 239000007769 metal material Substances 0.000 description 1
- 239000000203 mixture Substances 0.000 description 1
- 229910052750 molybdenum Inorganic materials 0.000 description 1
- 229910052758 niobium Inorganic materials 0.000 description 1
- 238000012856 packing Methods 0.000 description 1
- 229910052697 platinum Inorganic materials 0.000 description 1
- 238000005498 polishing Methods 0.000 description 1
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- 238000007789 sealing Methods 0.000 description 1
- 229910052710 silicon Inorganic materials 0.000 description 1
- 229910052720 vanadium Inorganic materials 0.000 description 1
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Abstract
Description
本願発明は高Cr系鋼構造物のじん性評価方法に関する。更に詳細には、本願発明は、超々臨界圧プラントや高速炉において高いクリープ強度を要求される部位に広く用いられ、核融合炉での使用も検討されているCr含有量が8〜14wt%の高Cr系鋼に対して、長期間使用によるじん性低下、及びその後の熱処理によるじん性回復を、pHの値が0より大きく5より小さい酸性溶液を電解液に用いたアノード分極曲線における電流密度の極大値、または電気量により評価する方法に関する。 The present invention relates to a method for evaluating the toughness of a high Cr steel structure. More specifically, the present invention is widely used in parts that require high creep strength in ultra-supercritical plants and fast reactors, and has a Cr content of 8 to 14 wt%, which is also being considered for use in fusion reactors. Current density in an anodic polarization curve using an acidic solution with a pH value greater than 0 and less than 5 for high Cr steels with reduced toughness after long-term use and subsequent toughness recovery by heat treatment It is related with the method of evaluating by the local maximum value or the electric quantity.
Cr含有量が8〜14wt%の高Cr系鋼は超々臨界圧プラントや高速炉において高いクリープ強度を要求される部位に広く用いられ、核融合炉での使用も検討されている。高Cr系鋼として例えば、火STPA27(原子力安全・保安院 電力安全課作成の火力業務内規集より)、火STPA28(同)を挙げることができる。高Cr系鋼は長期間の稼動により材質の劣化が生じてじん性が低下するが、適正な条件で熱処理を行うとじん性は回復するという特徴を有する。このようなじん性の低下と向上は、ラーベス相と呼ばれる脆い相の析出と消失によることが知られている。そのため、ラーベス相の析出量を把握することが可能となれば、高Cr系鋼構造物のじん性を把握することができる。 High Cr steels with a Cr content of 8-14wt% are widely used in parts that require high creep strength in ultra-supercritical plants and fast reactors, and are also being considered for use in fusion reactors. Examples of high-Cr steels include Fire STPA27 (from the Thermal Power Business Regulations prepared by NISA Electric Power Safety Division) and Fire STPA28 (same). High Cr steel has a characteristic that the material deteriorates due to long-term operation and the toughness is lowered, but the toughness is restored by heat treatment under appropriate conditions. It is known that such a decrease and improvement in toughness is due to precipitation and disappearance of a brittle phase called a Laves phase. Therefore, if it becomes possible to grasp the amount of precipitation of the Laves phase, the toughness of the high Cr steel structure can be grasped.
現状では、高Cr系鋼構造物からレプリカ試料等を採取して、透過型電子顕微鏡等の大規模な装置を用いてラーベス相の生成状況を観察し、過去のデータや経験からじん性を評価している。しかし、この手法では、(1) 現場で直接評価することができないこと、(2) ラーベス相の観察に長時間を要することから、効率性に欠ける。そのため、現場で簡易的にじん性を評価できる手法が望まれている。 At present, we collect replica samples from high Cr steel structures, observe the generation of Laves phase using a large-scale device such as a transmission electron microscope, and evaluate toughness based on past data and experience. is doing. However, this method lacks efficiency because (1) it cannot be directly evaluated in the field and (2) it takes a long time to observe the Laves phase. Therefore, a method that can easily evaluate toughness at the site is desired.
このような状況下、現場で簡易的にじん性を評価する手法の1つとして、電気化学計測が提案されている。例えば、pH=14のアルカリ性溶液を電解液に用いたアノード分極曲線から電流密度の極大値を求めることにより熱時効ぜい化を評価する方法が提案されている(非特許文献1参照)。このような電流密度の増加(極大値)は、材料中の析出物等がイオン化して電解液中に溶解し、このときに電子を放出するために生じる。
しかしながら、上記文献には、じん性に大きな影響を及ぼすラーベス相の他に、じん性にほとんど影響を及ぼさない炭化物も電解液中に溶解する旨が記載されている。そうすると、上記文献に記載された評価方法では、材料の化学成分等の違いで炭化物の析出量が異なる場合、じん性を評価することは困難である。 However, the above-mentioned document describes that, in addition to the Laves phase that greatly affects toughness, carbides that hardly affect toughness are also dissolved in the electrolyte. If it does so, in the evaluation method described in the said literature, when the precipitation amount of a carbide | carbonized_material changes with the difference in the chemical component etc. of material, it is difficult to evaluate toughness.
したがって、高Cr系鋼において、材料の化学成分等の違いに影響されることなく、ラーベス相のみが溶解して生じるパラメータを用いてじん性を簡便に評価する方法が求められている。 Therefore, there is a need for a method for simply evaluating toughness using parameters generated by melting only the Laves phase in high Cr steels without being affected by differences in the chemical composition of the material.
本願発明は、このようなじん性を簡便に評価する方法を提供することを目的とする。
[課題を解決するための手段及びその効果]
1.上記課題を解決するための、本願発明に係る高Cr系鋼からなる構造物のじん性を評価する方法は、所定の高Cr系鋼について、所定の電解液を用いて得られたアノード分極曲線から所定のパラメータとじん性との間の特性線図を予め求める工程と、前記高Cr系鋼からなる構造物に対して前記電解液を用いてアノード分極曲線から前記パラメータの値を計測する工程と、前記構造物から計測された前記パラメータの値を前記特性線図に当てはめることにより、前記高Cr系鋼からなる構造物のじん性を評価する工程とを有することを特徴とする。
The object of the present invention is to provide a method for simply evaluating such toughness.
[Means for solving problems and their effects]
1. In order to solve the above problems, a method for evaluating the toughness of a structure made of a high Cr steel according to the present invention is an anodic polarization curve obtained using a predetermined electrolyte for a predetermined high Cr steel. Pre-determining a characteristic diagram between a predetermined parameter and toughness from the step, and measuring a value of the parameter from an anodic polarization curve using the electrolytic solution for the structure made of the high Cr steel And evaluating the toughness of the structure made of the high Cr steel by applying the value of the parameter measured from the structure to the characteristic diagram.
本願発明に係るじん性評価方法によれば、高Cr系鋼構造物に関して、長期間使用後のじん性低下及びその後の熱処理によるじん性回復について簡便に評価することができるという有利な効果を奏することができる。 According to the toughness evaluation method according to the present invention, there is an advantageous effect that it is possible to easily evaluate toughness reduction after long-term use and toughness recovery by heat treatment for high Cr steel structures. be able to.
2.好ましくは、前記高Cr系鋼は、Cr含有量(wt%)が8以上14以下であってラーベス相が析出する鋼である。
また好ましくは、前記電解液は、pHの値が0より大きく5より小さい酸性溶液である。
また好ましくは、前記パラメータがアノード電流密度の極大値である。
また好ましくは、前記パラメータがアノード電流密度の電気量であり、前記電気量は、アノード電流密度が極小値となる電流密度に対応する電位間における電流密度の積分値である。
また好ましくは、前記アノード分極曲線を求める際の電位掃引速度が100mV/s以下である。
2. Preferably, the high Cr steel is a steel having a Cr content (wt%) of 8 or more and 14 or less and in which a Laves phase is precipitated.
Preferably, the electrolytic solution is an acidic solution having a pH value larger than 0 and smaller than 5.
Preferably, the parameter is a maximum value of the anode current density.
Preferably, the parameter is an electric quantity of an anode current density, and the electric quantity is an integral value of the current density between potentials corresponding to a current density at which the anode current density is a minimum value.
Preferably, the potential sweep rate when determining the anodic polarization curve is 100 mV / s or less.
本願発明に係るじん性評価方法は、以下のような有利な効果を奏することができる。すなわち、じん性に大きな影響を与えるラーベス相のみがアノード分極時に溶解して、アノード電流密度の極大値や電気量として検出される。したがって、本願発明に係るじん性評価方法は、アノード電流密度の極大値や電気量を用いることで、Cr含有量が8〜14wt%の高Cr系鋼構造物に関して、長期間使用後のじん性低下及びその後の熱処理によるじん性回復について簡便に評価することができるという有利な効果を奏することができる。 The toughness evaluation method according to the present invention can provide the following advantageous effects. That is, only the Laves phase, which has a great influence on the toughness, dissolves during anodic polarization and is detected as the maximum value of the anode current density or the amount of electricity. Therefore, the toughness evaluation method according to the present invention uses the maximum value of the anode current density and the amount of electricity, and the toughness after long-term use of the high Cr-based steel structure having a Cr content of 8 to 14 wt%. The advantageous effect that it is possible to easily evaluate the reduction and toughness recovery by the subsequent heat treatment can be obtained.
(1)高Cr系鋼のじん性評価に使用する検出装置について
本願発明の実施例を説明する前に、既に知られている計測に用いる装置の例について説明する。
(1) About the detection apparatus used for toughness evaluation of high Cr system steel Before explaining the Example of this invention, the example of the apparatus used for the already known measurement is demonstrated.
図1中、10は検出装置を示す。検出装置10は、容器3の上面を経由して白金製の対極5及び照合電極6が内部に挿入された容器3と、リード線により対極4及び照合電極5に接続されたポテンショスタット7と、ポテンショスタットに接続されたポテンシャルスイーパ8及びデータ収録装置9とを備える。容器3は、下面が開口しており、開口端には内部の電解液4の漏出を防止するためのパッキンのようなシール部材2が設けられている。
Cr含有量(wt%)が8以上14以下の高Cr系鋼構造物に対してじん性を評価する場合、図1に示すように、電解液4を高Cr系鋼構造物1に直接接触させ、その際、生成される電荷の変化を電気的に検出して、高Cr系鋼構造物1のアノード分極曲線を記録する。高Cr系鋼構造物1はリード線を経てポテンショスタット7に接続されている。
In FIG. 1, reference numeral 10 denotes a detection device. The detection apparatus 10 includes a container 3 in which a platinum counter electrode 5 and a verification electrode 6 are inserted through the upper surface of the container 3, a potentiostat 7 connected to the counter electrode 4 and the verification electrode 5 by lead wires, A potential sweeper 8 and a data recording device 9 connected to the potentiostat are provided. The container 3 has an open bottom surface, and a sealing member 2 such as a packing for preventing leakage of the electrolyte 4 inside is provided at the open end.
When evaluating toughness for high Cr steel structures with a Cr content (wt%) of 8 or more and 14 or less, as shown in FIG. At that time, the change in the generated charge is electrically detected, and the anodic polarization curve of the high Cr steel structure 1 is recorded. The high Cr steel structure 1 is connected to a potentiostat 7 through lead wires.
(2)実験1
次に、高Cr系鋼としての9Cr-1Mo-Nb-V系耐熱鋼(Cr含有量は8.8wt%)の溶接金属についてじん性評価実験を行った結果について説明する。この耐熱鋼は、Cr、Mo、Nb、V、Si、C、残部Feなどの化学元素で構成されている。勿論、9Cr-1Mo-Nb-V系耐熱鋼は例示であり、その他の高Cr系鋼(Cr含有量が8〜14重量パーセント)についても同様の実験を行うことができる。
(2) Experiment 1
Next, the results of a toughness evaluation experiment on a weld metal of 9Cr-1Mo-Nb-V heat resistant steel (Cr content: 8.8 wt%) as a high Cr steel will be described. This heat-resistant steel is composed of chemical elements such as Cr, Mo, Nb, V, Si, C, and the balance Fe. Of course, the 9Cr-1Mo-Nb-V heat resistant steel is an example, and the same experiment can be performed for other high Cr steels (Cr content: 8 to 14 weight percent).
実験1で用いたサンプルは、9Cr-1Mo-Nb-V系耐熱鋼のMIG溶接金属を600℃の温度にて半年間保持した熱時効材Aと、上記金属を600℃の温度にて1年間保持した熱時効材Bと、上記金属を600℃の温度にて1年間保持した熱時効材を750℃の温度にて1.5時間保持した熱処理材Cとの3種類である。なお、本明細書において、「溶接金属」とは、溶接を施した際に溶接中に溶融して凝固した金属のことをいう。 The sample used in Experiment 1 is a heat aging material A in which a 9Cr-1Mo-Nb-V heat resistant steel MIG weld metal is held at a temperature of 600 ° C for half a year, and the above metal at a temperature of 600 ° C for one year. There are three types: a heat aging material B held and a heat treatment material C in which the metal is held at a temperature of 600 ° C. for 1 year and held at a temperature of 750 ° C. for 1.5 hours. In this specification, “welded metal” refers to a metal that melts and solidifies during welding when welding is performed.
じん性低下及びじん性回復を把握するために、シャルピー衝撃試験の結果をグラフ化したものを図2に示す。なお、図2中のグラフのデータは、各サンプルについて3回繰り返し試験を行いその平均をとった値である。同図に示すように、600℃に1年間保持した熱時効材Bは、半年間保持した熱時効材Aと比較して衝撃吸収エネルギーが低く、熱時効が長時間の方がじん性が低下することがわかる。一方、600℃に1年間保持した熱時効材を750℃に1.5時間保持した熱処理材Cの場合、衝撃吸収エネルギーが高くなっており、じん性が向上(回復)することがわかる。シャルピー衝撃試験後の熱時効材B及び熱処理材Cの破面の顕微鏡写真を夫々、図3及び図4に示す。図3及び図4中、aはラーベス相を、bは母相を示す。熱時効材Bの顕微鏡写真を観察すると、熱時効材Aと比較してラーベス相aが多数観察された。一方、熱処理材Cを同様に観察すると、ほとんどのラーベス相aが母相b中に固溶して消失していた。このことから、ラーベス相の量とじん性とは相関があると考えられる。 FIG. 2 shows a graph of the results of the Charpy impact test in order to grasp toughness reduction and toughness recovery. In addition, the data of the graph in FIG. 2 are the values which averaged the result which repeated the test 3 times about each sample. As shown in the figure, thermal aging material B held at 600 ° C for 1 year has lower impact absorption energy than thermal aging material A held for half a year, and the toughness is lower when the thermal aging is longer. I understand that On the other hand, in the case of the heat-treated material C which was kept at 600 ° C. for 1 year and was kept at 750 ° C. for 1.5 hours, the impact absorption energy was high and the toughness was improved (recovered). 3 and 4 show micrographs of fracture surfaces of the heat-aging material B and the heat-treated material C after the Charpy impact test, respectively. 3 and 4, a represents the Laves phase, and b represents the parent phase. When a micrograph of the heat aging material B was observed, many Laves phases a were observed as compared with the heat aging material A. On the other hand, when the heat treatment material C was observed in the same manner, most of the Laves phase a was dissolved in the matrix phase b and disappeared. From this, the amount of Laves phase and toughness are considered to be correlated.
続いて、各サンプルについて、上記検出装置10を用いてアノード分極曲線を計測した。なお、計測時の表面は金属光沢面を呈している必要があり、酸化皮膜や汚れ等の異物が表面に付着している場合は、研磨等により取り除かなければならない。 Subsequently, an anodic polarization curve was measured for each sample using the detection device 10. In addition, the surface at the time of measurement needs to exhibit a metallic luster surface, and when foreign matters, such as an oxide film and dirt, have adhered to the surface, it must remove by grinding | polishing etc.
一例として、電解液4としてpH=0.2の硫酸水溶液を用いて、電位掃引速度1.67mV/sでアノード分極曲線を求めた結果を図5に示す。なお、図5中のグラフのデータは、各サンプルについて3回繰り返し試験を行いその平均をとった値に基づく。 As an example, FIG. 5 shows the results of obtaining an anodic polarization curve at a potential sweep rate of 1.67 mV / s using a sulfuric acid aqueous solution with pH = 0.2 as the electrolyte solution 4. In addition, the data of the graph in FIG. 5 are based on the value which repeated the test 3 times about each sample and took the average.
図5中、600℃に半年間保持した熱時効材A及び1年間保持した熱時効材Bでは、アノード電流密度に極大値が生じた。一方、熱処理材Cでは極大値が生じず、熱時効材A及び熱時効材Bと熱処理材Cとの間に相違が見られた。 In FIG. 5, in the heat aging material A held at 600 ° C. for half a year and the heat aging material B held for 1 year, a maximum value occurred in the anode current density. On the other hand, the heat treatment material C did not have a maximum value, and a difference was observed between the heat aging material A and the heat aging material B and the heat treatment material C.
なお、電位掃引速度が100mV/s以上の場合、図5に示すような明瞭な電流密度の極大値が生じないため、電位掃引速度が100mV/s以下であることが好ましい。また、溶液のpHが0以下では、材料を電解液中に浸漬しただけで材料の溶解が始まるため、使用する電解液の条件として不適切である。また、pHが5以上では、図5に示すような熱時効材での電流密度の明瞭な極大値が生じないため、電解液の条件として不適切である。したがって、pHの値が0より大きく5より小さい酸性溶液が本評価に適した電解液としての条件となる。 Note that when the potential sweep rate is 100 mV / s or higher, a clear current density maximum value as shown in FIG. 5 does not occur, and therefore the potential sweep rate is preferably 100 mV / s or lower. In addition, when the pH of the solution is 0 or less, the material starts to be dissolved just by immersing the material in the electrolytic solution, which is inappropriate as the condition of the electrolytic solution to be used. Further, when the pH is 5 or more, a clear maximum value of the current density in the thermal aging material as shown in FIG. 5 does not occur, so that it is inappropriate as the condition of the electrolytic solution. Therefore, an acidic solution having a pH value larger than 0 and smaller than 5 is a condition as an electrolytic solution suitable for this evaluation.
上記アノード分極曲線の計測後に熱時効材Bの表面を撮影した顕微鏡写真を図6に示す。同図中、bは母相を、cは黒点を示す。ここで見られる黒点cの穴はラーベス相aが溶解した痕跡であることから、本実験に使用した電解液4はラーベス相aのみを溶解することがわかる。このことは、pHの値が0より大きく5より小さい他の酸性溶液を電解液として使用した際も同様である。 FIG. 6 shows a photomicrograph of the surface of the heat aging material B after measurement of the anodic polarization curve. In the figure, b indicates a parent phase and c indicates a black spot. Since the hole of the black spot c seen here is the trace which the Laves phase a melt | dissolved, it turns out that the electrolyte solution 4 used for this experiment melt | dissolves only the Laves phase a. This is the same when another acidic solution having a pH value larger than 0 and smaller than 5 is used as the electrolytic solution.
以下の説明を簡便にするために、ある熱時効材(例えば、熱時効材B)のアノード分極曲線を図7に例示する。同図中、Ip及びI0は夫々、アノード電流密度の極大値及び極小値を示す。また、Qは、極小値(I0)となる電流密度に対応する電位(V1、V2)間における電流密度の積分値である電気量を示す。 In order to simplify the following description, an anodic polarization curve of a certain heat aging material (for example, heat aging material B) is illustrated in FIG. In the figure, Ip and I 0 represents respectively, the maximum and minimum values of the anode current density. Further, Q represents an electric quantity that is an integrated value of the current density between the potentials (V 1 , V 2 ) corresponding to the current density at which the minimum value (I 0 ) is obtained.
上述したように、電解液(pH=0〜5の酸性溶液)はラーベス相のみを溶解するから、図7に示すアノード電流密度の極大値(Ip) がラーベス相の析出量を表す一のパラメータとして挙げられる。また、極小値(I0)となる電流密度に対応する電位(V1、V2)間における電流密度の積分値である電気量(Q)がラーベス相の析出量を表す他のパラメータとして挙げられる。 As described above, since the electrolytic solution (acid solution having a pH of 0 to 5) dissolves only the Laves phase, the maximum value (Ip) of the anode current density shown in FIG. 7 is one parameter representing the amount of deposited Laves phase. As mentioned. In addition, the quantity of electricity (Q), which is the integrated value of the current density between the potentials (V 1 , V 2 ) corresponding to the current density at which the minimum value (I 0 ) is obtained, is cited as another parameter representing the amount of precipitation of Laves phase It is done.
上記3種類のサンプル(熱時効材A、熱時効材B、熱処理材C)を用いて、アノード分極曲線から求めた一のパラメータとしてのアノード電流密度の極大値(Ip)とじん性(30℃での衝撃吸収エネルギー)との間の特性線図(例えば、特性曲線)を定めた結果を図8に示す。 Using the above three types of samples (thermal aging material A, thermal aging material B, heat treatment material C), the maximum value (Ip) and toughness (30 ° C) of the anode current density as one parameter obtained from the anode polarization curve FIG. 8 shows the result of defining a characteristic diagram (for example, a characteristic curve) with respect to (impact absorption energy).
高Cr系鋼構造物のじん性を評価する場合、その構造物についてアノード分極曲線からアノード電流密度の極大値(Ip1)を求める。次に、この極大値(Ip1)の値を予め求めておいた特性曲線(図8)に当てはめることにより、高Cr系鋼構造物のじん性(30℃での衝撃吸収エネルギー)を求めることができる。図8に示す例では、実験によりアノード電流密度の極大値としてIp1=1.5A/m2が得られた場合、高Cr系鋼構造物のじん性は、このIp1の値に対応する30℃での衝撃吸収エネルギー(E)=75ジュールであると評価することができる。 When evaluating the toughness of a high Cr steel structure, the maximum value (Ip 1 ) of the anode current density is obtained from the anode polarization curve for the structure. Next, to determine the toughness (impact absorption energy at 30 ° C) of the high Cr steel structure by applying this maximum value (Ip 1 ) to the characteristic curve (Fig. 8). Can do. In the example shown in FIG. 8, when Ip 1 = 1.5 A / m 2 is obtained as a maximum value of the anode current density by experiment, the toughness of the high Cr steel structure corresponds to this Ip 1 value. It can be evaluated that the impact absorption energy (E) at 75 ° C. = 75 Joules.
同様に、他のパラメータとしてのアノード電流密度の電気量(Q) とじん性との間の特性線図を求めた結果を図9に示す。上述したアノード電流密度の極大値(Ip1)の場合と同様に、じん性評価の対象物としての高Cr系鋼構造物のアノード分極曲線で得られた電気量(Q)の値を予め求めておいたじん性と電気量Qとの間の特性線図に当てはめることにより、高Cr系鋼構造物のじん性を求めることができる。 Similarly, FIG. 9 shows the result of obtaining a characteristic diagram between the electric quantity (Q) of the anode current density as another parameter and the toughness. As in the case of the maximum value (Ip 1 ) of the anode current density described above, the value of the quantity of electricity (Q) obtained from the anode polarization curve of the high Cr steel structure as an object of toughness evaluation is obtained in advance. The toughness of the high Cr steel structure can be obtained by applying the characteristic diagram between the toughness and the quantity of electricity Q.
勿論、上記9Cr-1Mo-Nb-V系耐熱鋼(Cr含有量は8.8wt%)の溶接金属は例示であり、その他の高Cr系鋼(Cr含有量が8〜14重量パーセント)の溶接金属についても同様の結果を得ることができる。 Of course, the weld metal of the above 9Cr-1Mo-Nb-V heat resistant steel (Cr content is 8.8wt%) is an example, and other high Cr steel (Cr content is 8-14wt%) weld metal Similar results can be obtained for.
なお、参考までに、上述した3回繰り返し試験の結果(熱時効材A、熱時効材B、及び熱処理材Cに関する、アノード電流密度の極大値(Ip)と、アノード電流密度の電気量(Q)と、30℃での衝撃吸収エネルギーとの関係)をまとめたものを表1に示す。 For reference, the results of the three-time repeated test described above (maximum value (Ip) of anode current density and thermal quantity of anode current density for thermal aging material A, thermal aging material B, and heat treatment material C (Q ) And the relationship between the impact absorption energy at 30 ° C.) are summarized in Table 1.
(3)実験2
続いて、高Cr系鋼としての9Cr-1Mo-Nb-V系耐熱鋼(Cr含有量は8.8wt%)の母材についてじん性評価実験を行った結果について説明する。なお、本明細書において、「母材」とは、被溶接金属材料のことをいう。
(3) Experiment 2
Next, the results of a toughness evaluation experiment on the base material of 9Cr-1Mo-Nb-V heat resistant steel (Cr content is 8.8 wt%) as high Cr steel will be described. In the present specification, the “base material” refers to a metal material to be welded.
実験2で用いたサンプルは、9Cr-1Mo-Nb-V系耐熱鋼の母材の初期材(製造したままの材料)Dと、この母材を600℃の温度にて半年間保持した熱時効材Eと、上記母材を600℃の温度にて1年間保持した熱時効材Fと、上記母材を600℃の温度にて1年間保持した熱時効材を660℃の温度にて1.5時間保持した熱処理材Gと、上記母材を600℃の温度にて1年間保持した熱時効材を690℃の温度にて1.5時間保持した熱処理材Hと、上記母材を600℃の温度にて1年間保持した熱時効材を720℃の温度にて1.5時間保持した熱処理材Iと、上記母材を600℃の温度にて1年間保持した熱時効材を750℃の温度にて1.5時間保持した熱処理材Jとの7種類である。 The sample used in Experiment 2 is the initial material (as-manufactured material) D of 9Cr-1Mo-Nb-V heat-resistant steel, and thermal aging with this base material held at a temperature of 600 ° C for half a year. Material E, thermal aging material F holding the base material at 600 ° C. for 1 year, and thermal aging material holding the base material at 600 ° C. for 1 year at 660 ° C. for 1.5 hours Heat-treated material G held, heat-treated material H held at a temperature of 690 ° C. for 1.5 hours, and heat-treated material H held at a temperature of 600 ° C. for 1 year, and the base material at a temperature of 600 ° C. Heat-treated material I held for 1 year at 720 ° C for 1.5 hours and heat aging material held for 1 year at 600 ° C for 1.5 hours at 750 ° C for 1.5 hours 7 types of heat treated material J.
表2は、上記サンプルについて実験1と同様に3回繰り返し試験を行い、アノード電流密度の極大値(Ip)と、アノード電流密度の電気量(Q)と、30℃での衝撃吸収エネルギーとの関係をまとめたものである。 Table 2 shows that the above sample was repeatedly tested three times in the same manner as in Experiment 1. The maximum value (Ip) of the anode current density, the quantity of electricity (Q) of the anode current density, and the impact absorption energy at 30 ° C. It summarizes the relationship.
この実験結果から、母材についても実験1の溶接金属と同様に、アノード電流密度の極大値(Ip)とじん性(30℃での衝撃吸収エネルギー)との間の特性線図(図10)、及びアノード電流密度の電気量(Q) とじん性との間の特性線図(図11)を求めることができる。すなわち、これらの特性線図を利用して、高Cr系鋼構造物の母材のじん性を評価することができる。 From this experimental result, the characteristic diagram between the maximum value (Ip) of the anode current density and the toughness (impact absorbed energy at 30 ° C) of the base metal as well as the weld metal of Experiment 1 (Fig. 10) , And a characteristic diagram (FIG. 11) between the electric quantity (Q) of the anode current density and the toughness. In other words, the toughness of the base material of the high Cr steel structure can be evaluated using these characteristic diagrams.
勿論、上記母材は例示であり、その他の高Cr系鋼(Cr含有量が8〜14重量パーセント)の母材についても同様の結果を得ることができる。 Of course, the above-mentioned base material is an example, and the same result can be obtained for the base material of other high Cr steel (Cr content: 8 to 14 weight percent).
1 高Cr系鋼構造物
4 電解液
5 対極
6 照合電極
7 ポテンシャルスイーパ
10 検出装置
a ラーベス相
b 母相
c 黒点
DESCRIPTION OF SYMBOLS 1 High Cr type steel structure 4 Electrolyte 5 Counter electrode 6 Reference electrode 7 Potential sweeper 10 Detector a Laves phase b Mother phase c Black spot
Claims (6)
所定の高Cr系鋼について、所定の電解液を用いて得られたアノード分極曲線から所定のパラメータとじん性との間の特性線図を予め求める工程と、
前記高Cr系鋼からなる構造物に対して前記電解液を用いてアノード分極曲線から前記パラメータの値を計測する工程と、
前記構造物から計測された前記パラメータの値を前記特性線図に当てはめることにより、前記高Cr系鋼からなる構造物のじん性を評価する工程とを有することを特徴とする、じん性評価方法。 In a method for evaluating the toughness of a structure made of high Cr steel,
For a predetermined high Cr steel, a step of obtaining a characteristic diagram between a predetermined parameter and toughness in advance from an anodic polarization curve obtained using a predetermined electrolyte,
Measuring the value of the parameter from an anodic polarization curve using the electrolyte solution for the structure made of the high Cr steel; and
A toughness evaluation method comprising: evaluating the toughness of the structure made of the high Cr steel by applying the value of the parameter measured from the structure to the characteristic diagram. .
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