SEVERSTAL L-BLAST FURNACE HEARTH REFRACTORIES FINDINGS AND REPAIR AT SPARROWS POINT

Similar documents
L Blast Furnace Hearth Refractories Findings and Repair at Severstal Sparrows Point

Practices and Design for Extending the Hearth life in the Mittal Steel Company Blast Furnaces

Current Refractory Technology and Practices in the Steel Industry

Blast Furnace Cooling Stave Design

ADVANCED BLAST FURNACE BOSH AND STACK SYSTEMS R.J. van Laar and R.G. van Oudenallen Danieli Corus BV Rooswijkweg 291, Netherlands

Stahl-Zentrum. Influence of coke quality on BF hearth lifetime and operation results. Walter Hartig, Rongshan Lin * ) AG der Dillinger Huettenwerke

HOW A BLAST FURNACE WORKS

COMPUTATIONAL MODELING OF BLAST FURNACE COOLING STAVE BASED ON HEAT TRANSFER ANALYSIS

The modern blast furnace is a different animal to that

THE USE AND OPTIMISATION OF FERROUS FEED AT THE WHYALLA BLAST FURNACE

Prima PRO process mass spectrometer

PRODUCT LIST (REFRACTORIES)

italian engineering, contracting and plant components suppliers

IRONMAKING and THEORY AND PRACTICE. Ahindra Ghosh Amit Chatterjee

BLAST FURNACE OPERATIONAL SERVICES SPECIALIZED ASSISTANCE PACKAGES

Production of Steel by the

REDUCING REFRACTORY COST USING NEW ASCC BRICKS FOR HOT IRON TRANSPORT

Ironmaking, Energy and the Environment

Refractory Alternatives to Combat Elephant's Foot Erosion and Top Cap Wear in Coreless Furnaces

APPLICATION OF HIGH INTENSITY REFRACTORY COOLING SYSTEMS IN PYROMETALLURGICAL VESSEL DESIGN

Stahl-Zentrum. Coke quality parameters versus blast furnace process and hearth performance. Gerard Tijhuis, Luc Bol, Bart van der Velden, Huub Schulte

Pusher Furnace Bottom Side Tearing. at ArcelorMittal Indiana Harbor 84 Hot Strip Mill. Phone (219) ,

Results of Ultra High Rates of Natural Gas Injection Into the Blast Furnace at Acme Steel Company

Manufacture of Iron & Steel. Prepared By: John Cawley

Economic Wear Protection For the Iron and Steel Industry Worldwide

TMT- New Developments for the Cast House and Probes

VALUE ENHANCEMENT THROUGH ENGINEERED ALUMINA PRODUCTS FOR MONOLITHIC AND BRICK APPLICATIONS

Vessel relining and maintenance strategies play a major

Effect of Using Oxygen-Enriched Gas during Induration Process of Iron Ore Pellets Containing Solid Fuel

192GasCatalog.

Pelletizing technologies for iron ore

Calculation and Analysis the Influence on the Cooling Water Velocity and Hot Metal Circulation to the Long Life Blast Furnace

A New Prediction Model for Liquid Level in Blast Furnaces Based on Time Series Analysis

Fundamentals of Design Aspects of Gas-fired Cupola

Downsizing a Claus Sulfur Recovery Unit

I. Materials Properties and Cathode Construction 1 INTRODUCTION 1 THE CARBON LINING 4

S t e e l Ladle. Steel cleanliness is safeguarded by high alumina-spinel products

Lecture 14 Modern trends in BOF steelmaking

Most castables and gun mixes. Better Refractories through NANOTECHNOLOGY

Team Work - Failure Case Studies

Wet granulation of blast furnace slag has been

Twinjection Technology Improves Hot Metal Desulphurisation at Corus Scunthorpe Works

SUGGESTED MANHOLE FRAME SEALING SPECIFICATION (Rehabilitation)

Rebuild of Great Lakes Steel's No. A Blast Furnace

LKAB'S EXPERIMENTAL BLAST FURNACE FOR EVALUATION OF IRON ORE PRODUCTS

Development of the Process for Producing Pre-reduced Agglomerates

Effects and Analysis of Thermal Stresses on Large Induction Furnace Refractory Linings for Molten Metal Applications

Improving Energy Efficiency in Existing Reheating Furnaces of Small and Medium Sector Re-rolling Mills

Casthouse Machinery. Casthouse Machinery

HIsarna, a Revolution in Steelmaking. June 21, 2013 CEPS Meeting, Brussels Tim Peeters

STEEL PROCESSING AND METALLURGY

INSURAL* ATL INSULATING REFRACTORY LADLE LININGS FOR ALUMINIUM AND ZINC

Hydrosol System Furnace Cooling Water Cleaning Case Study: North American Stainless

Energy consumption, waste heat utilisation and pollution control in ferro alloy industry

Study on the Induration Cycle During Pelletization of Goethitic Iron Ore

September 1, 2003 CONCRETE MANUAL SPECIAL TYPES OF CONCRETE

Introduction. 1. MIDREX R process

Hardfacing Electrodes. Special tubular construction requiring low operating currents. Hardness : 650/700 HB.

Laboratory Investigations of the Electrical Resistivity of Cokes and Smelting Charge for Optimizing Operation in Large Ferrochrome Furnaces

Sidewall design for improved lining life in a PGM smelting furnace

By THE STAFF OF NML fr VISL, Presented by SHRI D. D. AKERKAR" ABSTRACT

UPDATED CASE STUDY OF FIRESIDE CORROSION MANAGEMENT IN AN RDF FIRED ENERGY-FROM-WASTE BOILER

Fuel Savings for Slab Reheating Furnaces through Oxyfuel Combustion

Study of the Compressive Strength of Concrete with Various Proportions of Steel Mill Scale as Fine Aggregate

SEWER FORCE MAIN HDPE PIPE

Experimental Study on Strength and Durability of Concrete with Partial Replacement of Blast Furnace Slag

Outline CASTING PROCESS - 2. The Mold in Casting. Sand Casting Mold Terms. Assoc Prof Zainal Abidin Ahmad Universiti Teknologi Malaysia

Mettop GmbH ILTEC Ionic Liquid Cooling Technology

Results are presented in Table 1. The tube was fabricated from a Type 347 and no unusual conditions were noted.

Fatigue Life & Reliability Consideration During Field Repair of Coke Drum & Piping

Installation of Praxair s CoJet Gas Injection System at Sumikin Steel and other EAFs with Hot Metal Charges

STULZ-SICKLES STEEL COMPANY

CONCRETE STEPS, HANDRAILS, AND SAFETY RAIL

MuShield s High Permeability Magnetic Shielding per ASTM A753 Alloy Type 4

Atlantis, The Palm, Dubai, U.A.E December 10, 2014

CLEANER PRODUCTION IN FOUNDRY INDUSTRIES

Steel Industry Technology Roadmap. Barriers and Pathways for Yield Improvements. by Energetics, Inc. for the American Iron and Steel Institute

true grit minerals CUMI lative range of EMD PRODUCT CATALOG 100 years US $ 3 billion 29 companies +30,000 people MURUGAPPA GROUP

Coinjection of Natural Gas and Pulverized Coal in the Blast Furnace at High Levels: Field Test Results at USS/Gary

Indian Experience in Construction of Kalugin Top Combustion Stoves

From Research to Manufacturing

SINTERED ALLOY POWDER CARBIDE AND TUNGSTEN CARBIDE MATERIALS FOR SHREDDER HAMMER TIPS

ENHANCING OPERATIONAL SAFETY AND LOGISTICAL EFFICIENCY FOR TORPEDO LADLES

Coke Manufacturing. Environmental Guidelines for. Multilateral Investment Guarantee Agency. Industry Description and Practices. Waste Characteristics

With Dura-Bar you will be able to:

FLOW-BOW - THE STRONG DEFLECTOR ELBOW

Where WVDOH is at with Mass Concrete

Global Innovation for your High Temp World

Optimization of Firing Temperature for Hematite Pellets

MANHOLES, VAULTS AND CATCH BASINS SECTION A. Section Soil and Aggregate Materials. C. Section Storm Drainage Systems

Effect of Silicon Carbide on Reactions between Molten Steel and Fused Magnesia Silicon Carbide Composite Refractory

Advanced Master Course Process Technology of Metals

Brimacombe Lecture. Research on Sustainable Steelmaking

COATED GRAPHITE ELECTRODES

INSTALLATION OF REFRACTORY FIBER KILN AND FURNACE LININGS

High-Carbon DRI: the feeding material to improve performances and decrease

Solutions for Wear Protection in Power Plants

Discussion on change of threshold value of Iron Ore

Challenges and limiting factors for the Recycling of steel scrap in Europe

Effect of Volatile Matter Content of Coal on Carbothermic Reduction of Ore / Coal Composite Pellets Packed in a Tall Bed

Transcription:

SEVERSTAL L-BLAST FURNACE HEARTH REFRACTORIES FINDINGS AND REPAIR AT SPARROWS POINT Richard E. Fash - Senior Manager Primary Severstal Sparrows Point James O. Barrett - Primary Refractory Process Manager Severstal Sparrows Point Ronald Timmer - President X & R Consultants. Robert Hansen - Project Manager Refractories CIMTECH Floris van Laar - Manager Marketing and Technical Services Allied Mineral Products Guy Ritterman - Project Engineer Severstal Sparrows Point Bruce Stackhouse - Ironmaking Process and Technology Manager Severstal Sparrow Point Abstract This paper will discuss the findings and repair of Severstal NA Sparrows Point L Furnace hearth refractories during the late 2008 to early 2009 planned outage. The significance of improving the refractory configuration, upgrading of the hearth monitoring systems & practices to match the campaign strategy goals will be discussed. Introduction Sparrows Point L Furnace was commissioned in 1978 and a complete reline was completed in 1990. In 1999, new hearth walls and bosh were installed. The furnace was blown down in the fall of 2008 for a 30 day scheduled internal taphole repair. The hearth wall and bottom had 24.6 and 50.3 million tons of hot metal production, respectively, before this outage (see figures 1 and 2). External taphole repairs were made from 2003 to 2005. More time was available to do the repair than originally scheduled as a result of the poor market conditions in late 2008. The two original planned taphole repairs were then changed from an external repair to an internal repair and included all four tapholes. To facilitate the internal repair, the furnace was blown down and the salamander was successfully tapped and the furnace was quenched. Additional hearth wear was identified after core drilling the rest of the hearth bottom. Thus, the furnace outage was extended to facilitate a bottom repair. In a compressed time frame the bottom was engineered, manufactured and installed to meet the scheduled blow-in date. In addition to the upgraded bottom and taphole refractories, the hearth instrumentation was upgraded with over 250 thermocouples installed HM improvement to allow for improved monitoring during the campaign following this repair. At the same time, the bottom cooling system has been restored to full function. The furnace stack required only local brick repairs which were followed by shotcrete to reprofile the lining. The high conductivity graphite bosh with dense plate cooling was in good condition, as anticipated and did not require repair. 453

Severstal Steel Sparrows Point L Blast Furnace on the Hearth Bottom 60,000,000 50,000,000 50,311,605 40,000,000 Tonnes 30,000,000 29,247,717 25,680,029 20,000,000 15,069,366 10,000,000 7,100,769 0 1978 to 1984 1984 to 1990 1990 to 1993 1993 to 1999 1993 to 2008 Figure 1 Severstal Steel Sparrows Point Tonnes on Hearth Bottom Severstal Steel Sparrows Point L Blast Furnace Tonnes on Hearth Walls Tonnes 35,000,000 30,000,000 25,000,000 20,000,000 15,000,000 10,000,000 5,000,000 0 29,247,717 25,680,029 24,631,576 15,069,366 7,100,769 1978 to 1984 1984 to 1990 1990 to 1993 1993 to 1999 1999 to 2008 Campaign Figure 2 Severstal Steel Sparrows Point Tonnes on Hearth Walls Table 1: Characteristics of Severstal L Blast Furnace in Sparrows Point USA Hearth Diameter ID Refractory M 14 Working Volume m 3 3908 Charging System Bell-less top No. of Tuyeres 38 No. of Tapholes 4 Bottom Cooling Air pipes Hearth Wall Cooling Channels Daily Maximum Production tonnes 9000 Hearth Productivity tonnes/m 2 /day 58.5 Hearth Sump Depth (Taphole to bottom) M Blast Furnace Productivity thm/24hr/m 3 WV 2.53 Before 1.67 m ( after the repair 2.28m) 454

Blow-Down and Quench L Blast Furnace was successfully blown down and quenched between November 2 nd the 6 th to prepare the furnace for taphole repairs and shotcreting of the furnace stack and belly (see figures 3 and 4). Prior to these events the salamander was tapped and ~ 438 tonnes of hot metal and slag were removed from the furnace. The last time this was accomplished was in 1999. For the new team, this was the first time they executed the task. Unfortunately business conditions extended the scheduled duration of the outage longer than required for the original scope of work. This allowed additional time to address critical repairs and concentrate on the quality of the repair. BLOW DOWN FURNACE PRESSURE VS WIND RATE 40 180 35 End of Blowdown 160 30 140 25 120 PRESSURE (PSI) 20 Draining Salamander 100 80 WIND (KSCFM) 15 Bottom/Side Tap under #2 Tap Hole 60 10 40 5 20 0 0 21:30 22:30 23:30 0:30 1:30 2:30 3:30 4:30 5:30 6:30 7:30 8:30 9:30 10:30 11:30 12:30 13:30 14:30 15:30 16:30 17:30 18:30 19:30 20:30 21:30 11/2/2008 TIME 11/3/2008 BLAST TOP WIND RATE Figure 3 Blow down Pressure vs. Wind rate 455

100 90 BLOW DOWN TOP GAS ANALYSIS Stage 1 Stage 2 Stage 3 Stage 4 20 80 70 15 PERCENT 60 50 40 10 O2 PERCENT 30 20 5 10 0 0 0 1 23 24 2 3 4 5 6 7 8 9 10 11 12 TIME 11/2/2008 HYDROGEN CO CO2 NITROGEN OXYGEN 11/3/2008 13 14 15 16 17 18 19 20 21 22 Figure 4 Blow down Top Gas Analysis The Salamander Tap Normally after blow down with the practice of this plant, the wind would be taken off and the furnace prepared for the quench. Instead, the pressure was maintained on the furnace to help cast the salamander (see figure 3). The wind was reduced to 64000 Nm 3 /hr due to the noise at the bleeders until iron was tapped at 18:00 hours. Then the wind was raised to 128000 Nm 3 /hr. About 398 tonnes of iron and slag were cast into the pig bed (see figure 5). The tap was deemed a success since enough liquid slag and iron were removed to insure a safe taphole repair. The tap was declared over at 21:47 hours on November 2 and the wind was taken off. Figure 5 Bottom Tap 456

The Quench The quench was started at 00:05 hours on November 5 th with a water flow of 389 L/min. Very little activity was seen at both the bleeders and the top gas analysis and it was decided to further increase the water flow to 778 L/min at 00:20 hours, 1167 L/min at 00:46 hours, and to 1525 L/min at 01:30 hours. At that point, it was found that the gas samples taken at the demister were being diluted by the nitrogen blanket. When the nitrogen was turned off we discovered the actual hydrogen level in the furnace was around 40%. This level is high, but still within reason. The plan called for us to increase the water flow 389 L/min per hour until we reached 2723 L/min, but 1517 L/min was as much as we could get. The same restriction that occurred during the blow down was in place for the quench. This probably didn t increase the length of the quench, but it just took longer to submerge and less water leaked out the blowpipes. Essentially the quench was completed in 14 hours when the top gas hydrogen dropped below 0.5%. Since no one was scheduled to work until the following morning, and the contractor had concerns about the re-ignition of the coke and the temperature inside the furnace, it was decided to continue putting water in the furnace until the next morning. The water was secured at 05:54 hours on November 6 th and the quench procedure was completed. A total of 1,801.9484 Liters of water was used during the quench. 457

Hearth Excavation As the remaining burden was removed from the hearth, test cores were taken to validate condition of the remaining bottom refractory and compare with those test cores taken in 1992. These cores were also taken to further validate the bottom to determine if the refractories left in the bottom would be compatible with the expected campaign life. At this time, it was discovered that the bottom had worn (the test core results shown, see figure 6). The location of the deepest core also correlated with the earlier bottom thermal data. The hearth bottom was completely mapped by additional core-drilling. Samples were taken and analyzed to determine the integrity of the remaining material. Core drill locations Figure 6 Profile of the Remaining Bottom To facilitate a bottom replacement without removing the complete hearth wall, an underpinning system was designed to support the remaining hearth wall while the bottom work took place. The remaining lower hearth walls and top two (2) bottom carbon beam layers were completely removed. The damaged section (approximately 25%) of course B between tapholes 1 and 4 was also replaced. To monitor the hearth for the next campaign from the remaining section of course B, several samples were taken to obtain actual thermal data the material left in place. This layer has been in place since 1990. Table 2 is a summary of the current thermal conductivity of the remaining Level B carbon. 458

Table 2 Course B Current Thermal Conductivity of Material Left In Place Actual test data from the remaining course B Carbon manufacturer published data Tested Dec 2008 Tested Dec 2008 Tested Dec 2008 Conductivity @ 20C Conductivity @ 20C Conductivity @ 175C Conductivity @ 300C W/m.K (With Grain direction) W/m.K (random direction) W/m.K (random direction) W/m.K (random direction) 10 7.5 9.1 10 10 7.3 8.8 9.6 10 8.8 10.4 11.3 10 10.5 13.6 15.6 10 9.1 11 12 Average 8.64 10.58 11.7 The remaining exposed hearth wall in general had a very thick skull. Lower in the furnace there was about 900 mm of wall away from the tapholes. It was remarkable to see the well-known brittle layer phenomenon in the sidewall. In front of the wall there was a powdery skull type zone followed by a zone which contained good bricks (see figure 7 @ Tuyere #21 and figure 8 @ Tuyere #22) Skull Brick Powder 900 mm good brick Figure 7 Hearth Sidewall Brittle Zone and Skull 459

Skull Brick Skull + Powder Figure 8 Good bricks in the skull separated from the wall 460

To be able to repair the bottom, the hearth skull had to be removed from around the furnace. The remaining hearth wall was checked and measured (i.e. outside the taphole areas) as shown in the figure 9. Figure 9 Typical Section through the Hearth Wall outside the Taphole Area The Repair The Project was Executed by Severstal Project Engineering Group. The hearth repair, detailed engineering and construction was carried out by 2 local contractors (Forest City Erectors and BISCO Refractories), engineering and quality control was accomplished by the partnership between (Cim-Tech of Valparaiso Indiana and Allied Mineral Products of Columbus Ohio) in close cooperation with the Severstal Sparrows Point Engineering and Blast Furnace Groups. The original project scope included the repair of 2 tapholes, which would be completed from the outside. In October 2008, the business climate changed and the scope was modified to repair all 4 tapholes from the inside. Eventually, as the calculated position of the wear line for the bottom was validated by means of core drillings (figure 6) the decision was made to use this opportunity to repair the bottom as well, which extended the outage further. The planned repair included refractories for a 3 meter by 3 meter section on all four tapholes for including upgraded cooling at the taphole panels. The stack would be lined with a shotcrete lining. When the scope changed, the bottom was replaced with 2 layers of low iron graphite blocks, 1 layer of super micropore carbon blocks and 1 layer of pre-cast shapes having a low 461

permeability for the ceramic arrestor course. Figure 10 shows the bottom repair in progress and the hearth wall solely supported by underpinning. In addition to the Taphole areas, several sections above the Taphole were also deteriorated and needed repair (see Figure 11). Remaining hearth wall Steel shell Under pinning Bottom Figure 10 A View of the New Bottom Repair In Progress and the Underpinned Hearth Wall Caps. Tuyeres Repaired hearth wall section Taphole section Figure 11 The Taphole Section Removed and the Repaired Zone above the Taphole. 462

The planned outage did not originally include a repair to the hearth bottom. Upon discovering of the core sample analysis, a bottom repair became necessary. Several options were considered. The area selected was quickly determined based on various requirements and based on the materials that would be required and could be made available to the Sparrows Point team within the given time constraints. The materials for the bottom were selected for their chemical composition and thermal properties. However, a feature of this hearth is that the top layer or so called arrestor course, was made of a material composed of a combination of a high grade brown fused alumina combined with silicon carbide. This will provide the hearth bottom with excellent resistance to iron and slag corrosion and erosion; also this material has good resistance against thermal shock compared to a mullite layer. For comparison of the permeability of the different materials, the ASTM testing procedure C-577 was used (see results Table 3). Table 3 Permeability of Materials Permeability in centidarcies Material type Location in the furnace Average Maximum individual sample Hot pressed carbon bricks Hot face of the wall 0.11 0.30 Ceramic Pre-cast shape The top layer of the bottom 0.11 0.13 Super Micropore Carbon The 1st layer below the ceramic 0.11 0.13 Ceramic Pre-cast shape The hot face of the taphole 0.11 0.13 463

The sump depth of L Furnace in the previous campaign was 5-6 (1.67 meters); this repair allowed re-engineering by means of changing bottom qualities to 7-8 (2.33 meters) within the given constraints (see figure 12). Figure 12 L Furnace Sump Depth Comparison 464

Hearth Management Severstal NA Sparrows Point Project Group was to maximize the total return from this project achieving the maximum possible tonnage, campaign length and operating with-in safe limits. The implementation of a Hearth Management Program through the hearth thermocouples via the monitoring system, operational knowledge, preventative maintenance and thermal models are an integral part of the know-how needed to safely guide the Blast Furnace to its last tap, safely. The initial goals of the hearth management program include the following: 1. A daily production of 9,000 metric tons. 2. A campaign extension target of 6 (six) years minimum. 3. A total tonnage during the 6 ( six) years of operation is 19,000,000 metric tons The hearth management program at Severstal NA Sparrows Point L Blast Furnace was improved from a reactionary to preventative program. This includes the monitoring of the lining heat flux, temperature measurements at a number of lining & shell points, measurements of the as built and remaining lining thickness, core drilling(s) as the hearth ages, grouting records and operational data such as productivity, water leakage and tapping events. Blow-in and Preliminary results The Severstal Steel Sparrows Point L Blast Furnace blow-in took place in February, 2009 and hot metal was successful cast from the furnace to ladles in 36 hours (see figure 13). L FURNACE START UP RATE PLAN 2009 Actual 2009 Actual 1999 METRIC TON/ DAY 9000 8000 7000 6000 5000 4000 3000 2000 1000 0 2/7/09 2/8/09 2/9/09 2/10/09 2/11/09 2/12/09 2/13/09 2/14/09 2/15/09 2/16/09 DATE Figure 13 L Furnace Start Up February 2009 465

The initial taphole temperatures in the graphite are below 300 C, thus the lining if fully intact. Both the repaired and unrepaired areas of the hearth sidewall and bottom have temperatures that are within safe operating limits. Although this is expected with lower throughput, the initial temperature distribution in the hearth has improved from the previous designs. First Year of Operation Business conditions remained unfavorable the remainder of 2009 and prevented the purchase of the desired Hearth Management computer model. Instead all the data was input to the existing Level 2 system. Alarms points were set for all thermocouples and in-house personnel developed graphic displays to aid in the monitoring of critical data. (see figures 14 and 15) Figure 14 Seven thermocouple arrays in the #2 tap hole panel and six thermocouples embedded in the core of the taphole can easily be viewed from the Level 2 Plant Visualization screen. 466

Figure 15 The under hearth thermocouples in-line with #1 tap hole are trended in the Level 2 system. L furnace was designed to operate with 40-60% of its burden being sinter. With the relative cost of sintering fines approaching that of pellets, it became evident that shutting down the sinter plant and operating with a predominately pellet burden was likely to happen. While operating at a reduced capacity in the spring and summer, tests were conducted with high pellet burdens and new injected fuel materials. These tests were successful, but unfortunately did not translate well in the fall when the sinter plant was shut down and improved business required higher production than anticipated through the transition period. The furnace operation was often unstable and highlighted by periods of heavy tuyere burning. Despite these severe conditions, the increased monitoring has provided the operators with a sense of security since it has not detected any trouble spots. 467

Conclusions A cross functional team approach between the Severstal NA Sparrows Point personnel and contractors proved to be an excellent team effort. When a Blast Furnace is down for a local repair it has proven to be a very effective technique to core drill the hearth and measure the remaining lining in the expected worst location outside the planned repair. When an aged hearth is down for a repair use all possible opportunities to upgrade the instrumentation to get more extensive thermal data of the hearth. Installation of additional grout nipples and grouting the hearth while cold is essential to maintain contact with the cooling. The new instrumentation has assisted operations in determining if the lining is in a safe mode during times of operational problems. 468