Analýza mechanických vlastností bimetalových materiálů s cladovanou vrstvou Inconelu / Analysis of Mechanical Properties of Bimetallic Materials with Clad Layer of Inconel

Sýkora, Milan

January 2020

This diploma thesis deals with the analysis of mechanical properties of bimetallic materials with clad layer of Inconel. In the theoretical part of the work there is an analysis of the investigated bimetallic material. The following is a description of mechanical tests and methods for evaluating the integrity of the surface, which were used to determine the properties of bimetallic material. The experimental part focuses on individual tests of mechanical properties of the material. For each test, the procedure for the production of test specimens, a description of the test equipment, the performance of the tests, the evaluation of the data obtained and finally, the evaluation of the results obtained are given.

Rozměrová, tvarová a materiálová analýza bimetalových dílců s definovaným poloměrem ohybu / Dimensional, Shape and Material Analysis of Bimetal Parts with Defined Bending Radius

Ivánek, Radim

January 2020

The thesis aim is an evaluation of achieved results coming from the analysis of pipe bend 180° for the critical bending / bend 1D and supercritical bending / bend 0,7D. The theoretical part is focused on material property of a bimetallic pipe and on methods applied to work out the analysis. The definition of critical points at a considered segment and possible defects arisen while bending is embodied in the thesis. The practical part of the thesis is based on presenting dimensional and proportional analysis based on using optical microscopes and 3D scanner GOM ATOS. The material analysis was aimed at macrostructure as well as microstructure of the bimetallic pipe material, at chemical composition and at the hardness when low-loaded. The analysis achieved results are assessed at the end of the thesis.

Comportement en corrosion de matériaux métalliques commerciaux et modèles dans des conditions types UVEOM / Corrosion behavior of commercial metallic materials and models under typical conditions UVEOM

Schaal, Emmanuel

23 October 2015

La corrosion des échangeurs de chaleur est un problème économique et technique majeur des Unités de Valorisation Energétique de Ordures Ménagères (UVEOM). Elle est causée par l’action combinée (i) des gaz de combustion contenant notamment HCl et SO2 et (ii) des cendres riches en chlorures et sulfates alcalins, et sels de métaux lourds. Les travaux présentés dans ce mémoire s’inscrivent dans le projet ANR SCAPAC (n°11-RMNP-0016) et portent sur l’influence des paramètres expérimentaux (température, teneur en chlorures dans les cendres, présence de gaz corrosifs et présence de chlorures de métaux lourds dans les cendres) sur la tenue à la corrosion de deux alliages utilisés en milieu UVEOM : l’acier 16Mo3 et l’alliage base nickel Inconel 625. Ces travaux ont permis de mettre en évidence que la présence de phases fondues, l’augmentation de la teneur en chlorures, la présence de 10% en masse de ZnCl2 dans les mélanges de cendres et la présence de gaz corrosifs (HCl, SO2) dans l’atmosphère sont trois facteurs qui ont induit une corrosion plus importante sur les matériaux, de manière plus prononcée sur l’alliage base fer. Une autre partie du travail s’est focalisée sur l’influence des éléments d’alliage Fe, Cr et Mo. Des alliages « modèles » dont les compositions oscillent autour de la composition de l’alliage Inconel 625 commercial ont été synthétisés par fusion haute fréquence et leur tenue à la corrosion a été évaluée sous air et sous atmosphère corrosive. La bonne optimisation de l’alliage commercial a ainsi été démontrée sous air. Sous atmosphère gaz corrosifs, une teneur en chrome supérieure à 22% massique s’est montrée indispensable à la bonne tenue de l’alliage / Corrosion of heat exchangers is an economic and technical issue in Waste-to-energy plants. It is caused by the combined action of (i) flue gas containing HCl and SO2 and (ii) chlorides and alkali sulfates rich ash. This work is part of the ANR project SCAPAC (supported by the ANR-11-RMNP 0016) and focused on the influence of experimental parameters on the corrosion behavior of two commercial alloys used in Waste-to-Energy plants: the 16Mo3 steel and the nickel-based alloy Inconel 625. This study allowed to highlight that the presence of molten phase, the increase in the chloride content, the presence of 10% by weight of ZnCl2 in the ash mixtures and the presence of corrosive gases (HCl, SO2) in the atmosphere are three factors that have induced an higher corrosion of materials, more pronounced on the iron alloy base. Another part of the work has been focused on the influence of alloying elements Fe, Cr and Mo. Thus, model alloys with compositions oscillating around the composition of Inconel 625 commercial alloy were synthesized by high frequency induction and their corrosion resistance was evaluated in air and in corrosive atmosphere. Good optimization of the commercial alloy has been demonstrated in air. In corrosive atmosphere, a minimum chromium content was required to obtain a good corrosion resistance

Corrosion par les sels fondus

Chlorures alcalins

Chlorure de zinc

Température de solidus

Inconel 625

16Mo3

Alliages modèles

Corrosion by molten salts

Alkali Chlorides

Zinc chloride

Solidus temperature

Inconel 625

16Mo3

Model alloys

620.112 23

Furnace Wall Corrosion in a Wood-fired Boiler

Alipour, Yousef

January 2015

The use of renewable wood-based fuel has been increasing in the last few decades because it is said to be carbon neutral. However, wood-based fuel, and especially used wood (also known as recycled wood or waste wood), is more corrosive than virgin wood (forest fuel), because of higher amounts of chlorine and heavy metals. These elements increase the corrosion problems at the furnace walls where the oxygen level is low. Corrosion mechanisms are usually investigated at the superheaters where the temperature of the material and the oxygen level is higher than at the furnace walls.  Much less work has been performed on furnace wall corrosion in wood or used wood fired boilers, which is the reason for this project.    Tests are also mostly performed under simplified conditions in laboratories, making the results easier to interpret.  In power plants the interpretation is more complicated. Difficulties in the study of corrosion processes are caused by several factors such as deposit composition, flue gas composition, boiler design, and combustion characteristics and so on. Therefore, the laboratory tests should be a complement to the field test ones. This doctoral project involved in-situ testing at the furnace wall of power boilers and may thus contribute to fill the gap. The base material for furnace walls is a low alloy steel, usually 16Mo3, and the tubes may be coated or uncoated. Therefore tests were performed both on 16Mo3 and more highly alloyed materials suitable for protective coatings. Different types of samples exposed in used-wood fired boilers were analysed by different techniques such as LOM (light optical microscopy), XRD (X-ray diffraction), SEM (scanning electron microscopy), EDS (energy dispersive spectroscopy), WDS (wavelength dispersive spectroscopy), FIB (focused ion beam) and GD-OES (glow discharge optical emission spectroscopy). The corrosion rate was measured. The environment was also thermodynamically modelled by TC (Thermo-Calc ®). The results showed that 16Mo3 in the furnace wall region is attacked by HCl, leading to the formation of iron chloride and a simultaneous oxidation of the iron chloride. The iron chloride layer appeared to reach a steady state thickness.   Long term exposures showed that A 625 (nickel chromium alloy) and Kanthal APMT (iron-chromium-aluminium alloy) had the lowest corrosion rate (about 25-30% of the rate for 16Mo3), closely followed by 310S (stainless steel), making these alloys suitable for coating materials. It was found that the different alloys were attacked by different species, although they were exposed in the boiler at the same time in the same place. The dominant corrosion process in the A 625 samples seemed to be by a potassium-lead combination, while lead did not attack the APMT samples. Potassium attacked the alumina layer in the APMT samples, leading to the formation of a low-protective aluminate and chlorine was found to attack the base material.  The results showed that stainless steels are attacked by both mechanisms (Cl- induced attack and K-Pb combination). Decreasing the temperature of the furnace walls of a waste wood fired boiler could decrease the corrosion rate of 16Mo3. However, this low corrosion rate corresponds to a low final steam pressure of the power plant, which in not beneficial for the electrical efficiency. The short term testing results showed that co-firing of sewage sludge with used wood can lead to a reduction in the deposition of K and Cl on the furnace wall during short term testing. This led to corrosion reduction of furnace wall materials and coatings. The alkali chlorides could react with the aluminosilicates in the sludge and be converted to alkali silicates. The chromia layer in A 625 and alumina in APMT were maintained with the addition of sludge. / Förnybara träbaserade bränslen har ökat i användning under de senaste decennierna, eftersom det är koldioxidneutrala. Emellertid är träbaserade bränslen, och i synnerhet använt trä (även känt som återvunnet trä, returträ eller träavfall), mer korrosivt än skogsbränsle, på grund av högre halter klor och tungmetaller. Dessa ökar korrosionsproblemen på eldstadsväggarna, särskilt på platser där syrehalten är låg. Korrosionsmekanismer undersöks vanligtvis på överhettare dvs. på områden där materialets temperatur och syrenivån är högre än vid eldstadsväggarna. Färre arbeten har utförts på eldstadskorrosion i returträ pannor, vilket är motiveringen till detta projekt. Normalt sätt så görs endast i laboratorietester där resultaten är lättare att tolka. I kraftverk är tolkningen mer komplicerad. Undersökningar av korrosionsprocesser försvåras av flera faktorer såsom panndesign, förbränningsegenskaper, rökgassammansättning, beläggningskemi och så vidare. Därför bör laboratorietester kompletteras med fältförsök. Detta doktorandprojekt kan således bidra till att fylla denna brist. Eldstadsväggarna är uppbyggda av flera rör som svetsas samman och de består vanligtvis av 16Mo3 stål. Rören kan vara belagda eller obelagda. Tester har därför genomförts på 16Mo3 samt på höglegerade material vilka är lämpliga som skyddande beläggningar. Olika typer av prov som exponerats i förbränningspannor av returträ analyserades med olika tekniker såsom SEM (svepelektronmikroskopi), EDS (energidispersiv spektroskopi), WDS (våglängd dispersiv spektroskopi), FIB (fokuserad jonstråle) LOM (ljusoptisk mikroskopi), XRD (röntgendiffraktion), och GD-OES (glimurladdning med optisk emissionsspektroskopi). Miljön samt korrosionsprocesser har modellerats termodynamiskt med mjukvaran TC (Termo-Calc®). Resultaten visade att 16Mo3 i eldstadsväggen angrips av väteklorid, vilket leder till bildning av järnklorid och en samtidig oxidation av järnkloriden. Järnkloridskiktet verkade nå ett stationärt tillstånd vad avser tjocklek. Sex veckors prov visade att A 625 (nickelkromlegering) och Kanthal APMT (järnkromaluminiumlegering) hade den lägsta korrosionshastigheten (ca 25-30% av korrosionshastigheten för 16Mo3), följt av 310S (rostfritt stål). Vi har funnit att de olika legeringarna angrips genom olika mekanismer, även om de var exponerade i pannan samtidigt på samma plats. Den dominerande korrosionsmekanismen för legeringen A 625 verkar i huvudsak bero på kalium och bly, medan bly inte attackerar Kanthal APMT. Kalium angriper aluminiumoxidskiktet på Kanthal APMT, vilket leder till bildning av icke-skyddande aluminat medan klor i sin tur attackerar basmaterialet. Resultaten visar att rostfritt stål attackeras genom klor-inducerad korrosion samt kalium och bly i kombination. Reducering av temperaturen kan minska korrosionshastigheten hos 16Mo3. Men denna lägre korrosionshastighet motsvarar ett lågt slutligt ångtryck hos kraftverket, vilket inte är fördelaktigt för elverkningsgraden. De kortare exponeringarna visade att samtidig förbränning av avloppsslam med returträ kan leda till minskad avsättning av kalium och klor i form av alkaliklorider på eldstadsväggarna. Detta ledde till korrosionsminskning av alla studerade material. Dessa alkaliklorider skulle kunna reagera med aluminiumsilikaterna från slammet och omvandlas till alkalisilikater. Detta verkar minska den alkali-inducerade korrosionen på A 625, APMT och 310S. Den aluminiumoxid som bildades på APMT och det kromoxidskikt som bildades på A 625 upprätthölls med tillsats av slam. / <p>QC 20151015</p>

High Temperature Corrosion

Used-wood Fired Boilers

Furnace Wall Corrosion

Cl-induced Corrosion

16Mo3

Nickel-based Alloys

FeCrAl Alloys

Fuel Additive

Sewage Sludge

>Thermodynamics Modelling

Högtemperaturkorrosion

Returträ Förbränningspannor

Eldstad Korrosion

klor-inducerad korrosion

16Mo3

Nickelbaslegeringar

FeCrAl-legeringar

Bränsletillsatser

Avloppsslam

Termodynamik Modellering