A Study of fume particle deposition

Goerg, Kristin A.

01 January 1989

No description available.

Recovery furnaces

Recovery boilers

Papermaking

Particles

Fumes

The Effectiveness of Magnesium Oxide-based Additives in Mitigating Fouling Problems in Kraft Recovery Boilers

Zhao, Liming

05 January 2012

Magnesium oxide-based additives have been used in kraft recovery boilers to minimize deposit accumulation on superheater and generating bank tubes. Due to inconclusive results observed in boilers and claims made for additive effectiveness backed by little scientific evidence, only a few mills still use the additives for fouling control. A systematic study was performed to examine the effect of MgO-based additives on deposit accumulation and removal under controlled laboratory conditions, and to evaluate the additive effect in a kraft recovery boiler. The results show that while the additive coating has no effect on deposition, it could ease deposit removal if a coating greater than 5 µm can be applied on the tube surface effectively. Separate injection of additive and black liquor had insignificant effect on deposition and removal. Results of the field study show that the amount of additive collected on the tube is too small to have an impact.

additives

kraft recovery boilers

fouling problems

pulp and paper

0542

The Effectiveness of Magnesium Oxide-based Additives in Mitigating Fouling Problems in Kraft Recovery Boilers

Zhao, Liming

05 January 2012

Magnesium oxide-based additives have been used in kraft recovery boilers to minimize deposit accumulation on superheater and generating bank tubes. Due to inconclusive results observed in boilers and claims made for additive effectiveness backed by little scientific evidence, only a few mills still use the additives for fouling control. A systematic study was performed to examine the effect of MgO-based additives on deposit accumulation and removal under controlled laboratory conditions, and to evaluate the additive effect in a kraft recovery boiler. The results show that while the additive coating has no effect on deposition, it could ease deposit removal if a coating greater than 5 µm can be applied on the tube surface effectively. Separate injection of additive and black liquor had insignificant effect on deposition and removal. Results of the field study show that the amount of additive collected on the tube is too small to have an impact.

additives

kraft recovery boilers

fouling problems

pulp and paper

0542

An Examination of Heavy Metal Vaporization from the Combustion of Black Liquor

Malbrue, Courtney Michelle

25 August 2006

The research focuses on the fate of heavy metals and their emissions from pulp mill recovery boilers. Heavy metals are extremely toxic and cause adverse effects on human health. There is limited information about factors affecting heavy metal vaporization from recovery boilers, in which spent pulping liquors, (also called black liquor) is burnt. The heavy metals are present in trace quantities in black liquor. They are emitted in the air as submicron particles, and their amount of emission depends on the input of metals into the recovery boiler, volatilization of metals in the boiler and the efficiency of the electrostatic precipitator (ESP) to remove the metals. The heavy metals vaporization from different recovery boilers vary widely and the reason is not known. My thesis will focus on determining what conditions affect the volatility of the heavy metals, and whether differences in heavy metal vaporization are due to differences in boiler operating conditions or the composition of the liquor. I will examine black liquor pyrolysis, combustion and gasification in well-controlled laboratory conditions. I will analyze three different black liquors. The liquors will be spray-dried and burnt or gasified in a laminar entrained-flow reactor at high temperatures of 1000-1100C and residence times ranging from 0.5 to 1.5 s. Equilibrium calculations will be performed to determine the distribution of heavy metals and species under set conditions from previous devolatilization experiments. The equilibrium calculations will serve as a useful tool for prior estimation of the distribution of heavy metals. The impact of different liquors on volatilization of heavy metals in the experiments will be determined. The char residue and condensation aerosol (fume) particles from each experiment will be analyzed using ICP-AES. The amount of heavy metals volatilization during combustion and gasification will be determined based on the amount of the metals in the char residues and fume particles. Based on the results of the experimental study combined with data from the equilibrium analysis program the main cause of variability in heavy metal vaporization can be found. Also the boiler operating conditions can be studied to determine its affects on the volatility of the heavy metals.

Black liquors

Heavy metals

Recovery boilers

Heavy metal vaporization

Alkaline pulping : deadload reduction studies in chemical recovery system

Chandra, Yusup

02 December 2004

The kraft pulping process has been known for decades. The focus in kraft pulping has always been on better operation of the chemical recovery system. One of the targets is on deadload (sodium sulfate (Na2SO4) and sodium carbonate (Na2CO3)) reduction in white liquor. A model based on several literature references was developed to study the effect of deadload reduction. A base model was developed based on current mill operation. This base model was compared to the deadload reduction model. Overall improvement, such as operating cost saving and revenue generation was achieved from deadload reduction. Operating cost saving involves less deadload chemical in chemical recovery system, and less water that was associated with the deadload itself. Revenue generation involves generating more steam and heat from the recovery boiler that can be used for mill purposes or energy revenue. Two important variables to achieve deadload reduction are causticizing efficiency and reduction efficiency.

Chemical recovery

Recovery boilers

Modeling

Sodium carbonate

Sodium sulfate

Alkaline

Kraft pulping

Deadload reduction

White liquors

A study of the calcium complex of the potassium salt of catechol-4-sulfonate in aqueous, alkaline media.

Westervelt, Harvey H., III

01 January 1981

No description available.

Recovery boilers

Recovery furnaces

Calcium carbonate

Black liquors

Scale (Deposits)

Potassium salts

Sulphate waste liquor

A Model of the kraft recovery furnace

Jones, Andrew K.

01 January 1989

No description available.

Recovery boilers

Recovery furnaces

Sulphate pulping process

Mathematical models

Kraft pulping

Interaction between a Supersonic Jet and Tubes in Kraft Recovery Boilers

Pophali, Ameya

11 January 2012

Sootblowing is a process in which supersonic steam jets are used to periodically blast deposits off heat transfer tubes in kraft recovery boilers. However, sootblowing significantly consumes the valuable high pressure steam generated by the boiler, hence it should be optimized. A recovery boiler consists of three convective sections - superheater, generating bank and economizer. The tube arrangement in these sections, particularly the tube spacing is different from each other. Moreover, tubes in an economizer are finned. A sootblower jet will interact differently with these tube arrangements, potentially affecting its strength, and hence deposit removal capability. The objective of this work was to characterize jet/tube interaction in the three sections of a recovery boiler. Lab-scale experiments were conducted in which these interactions were visualized using the schlieren technique coupled with high-speed video, and were quantified by pitot pressure measurements. This work is the first to visualize the interactions. The offset between the jet and tube centrelines, the nozzle exit diameter relative to the tube diameter, and the distance between the nozzle and tube were varied to examine their effects on jet/tube interaction. Results showed that due to the very low spreading rate of a supersonic jet, a jet (primary jet) stops interacting with a superheater platen when the jet is only a small distance away from it. When the jet impinges on a tube, the jet deflects at an angle, giving rise to a weaker ‘secondary’ jet. Due to the large inter-platen spacing, a secondary jet has an insignificant impact in a superheater. In a generating bank, the primary jet weakens between the closely spaced tubes due to increased mixing. However, a secondary jet impinges on the adjacent tubes exerting a high impact pressure on those tubes. The primary jet also weakens between finned economizer tubes, but remains stronger for a greater distance than in a generating bank. As in the case inside a generating bank, a secondary jet also impinges on adjacent rows of tubes in an economizer. The results imply that in a superheater, a sootblower jet must be directed close to the platens to yield useful jet/deposit interactions, and to avoid wasting steam by blowing between the platens. In a generating bank, deposits beyond the first few tubes of a row experience a weaker sootblower jet, and thus may not be removed effectively. However, secondary jets may contribute to removing deposits from the first few adjacent tubes. They may also induce erosion-corrosion of those tubes. Secondary jets may also help remove deposits from adjacent rows in a finned tube economizer. In an economizer, the strength and hence, the deposit removal capability of a sootblower jet diminish only slightly beyond the supersonic portion of the jet. A mathematical model was also developed to determine the feasibility of using inclined sootblower nozzles in recovery boiler superheaters, and suggests that it may be possible to clean superheater platens more effectively with slightly inclined nozzles.

kraft recovery boilers

sootblowing

supersonic jet

jet impingement on cylinder

schlieren

high-speed imaging

fouling

deposit removal

0542

0548

Interaction between a Supersonic Jet and Tubes in Kraft Recovery Boilers

Pophali, Ameya

11 January 2012

Sootblowing is a process in which supersonic steam jets are used to periodically blast deposits off heat transfer tubes in kraft recovery boilers. However, sootblowing significantly consumes the valuable high pressure steam generated by the boiler, hence it should be optimized. A recovery boiler consists of three convective sections - superheater, generating bank and economizer. The tube arrangement in these sections, particularly the tube spacing is different from each other. Moreover, tubes in an economizer are finned. A sootblower jet will interact differently with these tube arrangements, potentially affecting its strength, and hence deposit removal capability. The objective of this work was to characterize jet/tube interaction in the three sections of a recovery boiler. Lab-scale experiments were conducted in which these interactions were visualized using the schlieren technique coupled with high-speed video, and were quantified by pitot pressure measurements. This work is the first to visualize the interactions. The offset between the jet and tube centrelines, the nozzle exit diameter relative to the tube diameter, and the distance between the nozzle and tube were varied to examine their effects on jet/tube interaction. Results showed that due to the very low spreading rate of a supersonic jet, a jet (primary jet) stops interacting with a superheater platen when the jet is only a small distance away from it. When the jet impinges on a tube, the jet deflects at an angle, giving rise to a weaker ‘secondary’ jet. Due to the large inter-platen spacing, a secondary jet has an insignificant impact in a superheater. In a generating bank, the primary jet weakens between the closely spaced tubes due to increased mixing. However, a secondary jet impinges on the adjacent tubes exerting a high impact pressure on those tubes. The primary jet also weakens between finned economizer tubes, but remains stronger for a greater distance than in a generating bank. As in the case inside a generating bank, a secondary jet also impinges on adjacent rows of tubes in an economizer. The results imply that in a superheater, a sootblower jet must be directed close to the platens to yield useful jet/deposit interactions, and to avoid wasting steam by blowing between the platens. In a generating bank, deposits beyond the first few tubes of a row experience a weaker sootblower jet, and thus may not be removed effectively. However, secondary jets may contribute to removing deposits from the first few adjacent tubes. They may also induce erosion-corrosion of those tubes. Secondary jets may also help remove deposits from adjacent rows in a finned tube economizer. In an economizer, the strength and hence, the deposit removal capability of a sootblower jet diminish only slightly beyond the supersonic portion of the jet. A mathematical model was also developed to determine the feasibility of using inclined sootblower nozzles in recovery boiler superheaters, and suggests that it may be possible to clean superheater platens more effectively with slightly inclined nozzles.

kraft recovery boilers

sootblowing

supersonic jet

jet impingement on cylinder

schlieren

high-speed imaging

fouling

deposit removal

0542

0548

Sistemas multiagentes para controle inteligente da caldeira de recuperação. / Multi-agent systems for the intelligent control of a recovery boiler.

Herrera Sosa, Ivan Raul

11 September 2007

Engenheiros têm introduzido um melhor suporte para procedimentos de monitoramento de condições complexas através da aplicação de sistemas descentralizados inteligentes usando uma variedade de técnicas de inteligência artificial. Agora é largamente reconhecido que estes problemas decorrentes da complexidade funcional do monitoramento de condições podem ser resolvidos com arquiteturas que contenham muitos módulos distribuídos e inteligentes, que interajam dinamicamente, os quais são chamados de agentes inteligentes. A tecnologia baseada em agentes tem gerado muita agitação nos últimos anos por causa da promessa de ser um novo paradigma na hora de definir os conceitos para modelar e implementar sistemas de controle. O objetivo do presente estudo é implantar esta tecnologia no controle de uma caldeira de recuperação com a finalidade de gerenciar e integrar produção, qualidade e segurança no processo. A caldeira de recuperação tem dois objetivos bem definidos, cada um com suas restrições operacionais: (1) geração de vapor vivo a ser utilizado no processo, e, (2) redução de reagentes inorgânicos para recuperar sulfeto e carbonato de sódio, necessários no ciclo do processo de fabricação de celulose. Cada um destes objetivos é um sistema com funções independentes dentro da caldeira, mas que, no entanto tem seus desempenhos interligados entre si através das variáveis comuns existentes no processo. Esta é exatamente a definição de um sistema agente, ou melhor, de um Sistema Multi-Agente (SMA), no qual não existe uma otimização e sim a busca de uma solução possível. O modelo dinâmico da Caldeira foi simulado em Matlab(TM) Simulink(TM) baseado no modelo matemático da caldeira de recuperação de licor negro B&W (Babcock&Wilcox). O SMA foi desenvolvido utilizando a linguagem de programação JAVA e a plataforma de agentes JADE. / Engineers have been introducing better support for procedures of monitoring complex conditions through the application of intelligent decentralized systems, implementing a variety of artificial intelligent techniques. Nowadays it is vastly known that these problems that are consequence of the functional complexity of monitoring conditioning can be solved trough architectures, built by many intelligent distributed modules, which interact dynamically, known as intelligent agents. Technology based on agents have been creating excitement over the last years because of its promise of being a new paradigm that can be used to define modeling and implementing concepts for control systems. The goal of this thesis is to implement this new technology on controlling a recovery boiler, aiming to manage and integrate production, quality and security to the process. The operation of the recovery boiler has two well defined objectives, each one with its operational constraints: (1) steam production, an important asset in the pulp and paper process, and, (2) reduction of inorganic reagents to recover sulfate and sodium carbonates, the necessary chemicals in the Kraft pulp production. Each one of these functions, is an independent system inside the recovery boiler, however they have their performances connected to each other by common variables present in the process. This is exactly the definition of an agent system, in other words, a definition of a Multi-Agent System (MAS), for which there is not an optimization, but the search for the best possible outcome. The recovery boiler dynamic model was simulated using Matlab(TM) Simulink(TM) based on the mathematic model of B&W (Babcock&Wilcox) recovery boiler of black liquor. The MAS was implemented using JAVA(TM) programming language and JADE(TM) agent platform.

Agentes inteligentes

Controle (teoria de sistema e controle)

Intelligent agents

JADE

Kraft recovery boilers

Multi-agent systems

Process control

Processo Kraft

Simulink

Sistemas multiagentes