Optimization and management of flare gases through modification of knock-out drum HP flares by 4R approach based on 3E structures

International Journal of Renewable Energy Development Pub Date : 2023-12-02 DOI:10.14710/ijred.2024.56524

Ali Ahmadzadeh, Alireza Noorpoor, Gholamreza Nabi Bidhendi

{"title":"Optimization and management of flare gases through modification of knock-out drum HP flares by 4R approach based on 3E structures","authors":"Ali Ahmadzadeh, Alireza Noorpoor, Gholamreza Nabi Bidhendi","doi":"10.14710/ijred.2024.56524","DOIUrl":null,"url":null,"abstract":"The goal of this study is the Optimization and Management of Flare Gases through the Modification of Knock-out Drum HP Flares. The optimization of the K.O.D. is to create a shell around it and inject water steam into the shell, so that a uniform temperature distribution has done inside the drum, so freezing does not occur, and liquid that drops inside the burner, does not burn. The result of the simulations showed that in the drainage part of the drum, humidity associated with inlet gas freezes upon entering it after pressure and temperature drop suddenly. In the drainage part of the drum and the entrance of water steam with a temperature of 438 K and relative pressure of 550,000 Pa, the freezing of the coating part of it is eliminated. Finally, the water steam with liquid water caused by the heat transfer between the steam, and the bottoms of the drum is out from its drainage part. In the following, two issues were examined; First, simulating the drum to prove the insufficient power of the electric heater at the entrance of the drum. Second, simulating the drum with its surrounding cover in order to eliminate possible freezing. As the result, this work simulated and optimized the K.O.D. flare system to reduce valuable and toxic gas which burned in the flare system and caused environmental, economic, and social effects. This modelling optimized 8 points to add optimum heat flux and used a water steam jacket to prevent the formation of a freezing zone. The optimum zone around the bottom of K.O.D. steam injected this zone and observed no ice formation occurred in this zone. The steam jacket creates uniform heating by using this design and steam injection to the outer wall of the drum. For many reasons, the implementation of this project will reduce smoke and flare pollution: Inhibition of freezing in the liquid outlet of the K.O.D., the liquid level inside the drum remains constant and prevents the transfer of liquid droplets associated with the exhaust gas to the flare.","PeriodicalId":14200,"journal":{"name":"International Journal of Renewable Energy Development","volume":"345 ","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2023-12-02","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"International Journal of Renewable Energy Development","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.14710/ijred.2024.56524","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 0

Abstract

The goal of this study is the Optimization and Management of Flare Gases through the Modification of Knock-out Drum HP Flares. The optimization of the K.O.D. is to create a shell around it and inject water steam into the shell, so that a uniform temperature distribution has done inside the drum, so freezing does not occur, and liquid that drops inside the burner, does not burn. The result of the simulations showed that in the drainage part of the drum, humidity associated with inlet gas freezes upon entering it after pressure and temperature drop suddenly. In the drainage part of the drum and the entrance of water steam with a temperature of 438 K and relative pressure of 550,000 Pa, the freezing of the coating part of it is eliminated. Finally, the water steam with liquid water caused by the heat transfer between the steam, and the bottoms of the drum is out from its drainage part. In the following, two issues were examined; First, simulating the drum to prove the insufficient power of the electric heater at the entrance of the drum. Second, simulating the drum with its surrounding cover in order to eliminate possible freezing. As the result, this work simulated and optimized the K.O.D. flare system to reduce valuable and toxic gas which burned in the flare system and caused environmental, economic, and social effects. This modelling optimized 8 points to add optimum heat flux and used a water steam jacket to prevent the formation of a freezing zone. The optimum zone around the bottom of K.O.D. steam injected this zone and observed no ice formation occurred in this zone. The steam jacket creates uniform heating by using this design and steam injection to the outer wall of the drum. For many reasons, the implementation of this project will reduce smoke and flare pollution: Inhibition of freezing in the liquid outlet of the K.O.D., the liquid level inside the drum remains constant and prevents the transfer of liquid droplets associated with the exhaust gas to the flare.

查看原文本刊更多论文

通过基于 3E 结构的 4R 方法对淘汰滚筒式 HP 火炬进行改造，优化和管理火炬气体

这项研究的目标是通过改装熄火鼓式 HP 火炬来优化和管理火炬气体。K.O.D.的优化是在其周围创建一个壳体，并向壳体内注入水蒸气，从而使桶内的温度分布均匀，这样就不会发生冻结，滴入燃烧器内的液体也不会燃烧。模拟结果表明，在转鼓的排水部分，与入口气体相关的湿气在进入转鼓后压力和温度骤降，从而冻结。在转鼓的排水部分，当温度为 438 K、相对压力为 550,000 Pa 的水蒸汽进入时，其涂层部分就不会冻结。最后，由蒸汽和转鼓底部之间的热传导引起的带有液态水的水蒸汽从其排水部分排出。接下来将研究两个问题：第一，模拟转鼓以证明转鼓入口处的电加热器功率不足。第二，模拟滚筒及其周围的盖子，以消除可能出现的冻结。结果，这项工作模拟并优化了 K.O.D. 火炬系统，以减少在火炬系统中燃烧并造成环境、经济和社会影响的有毒有害气体。该模型优化了 8 个点，以增加最佳热通量，并使用水蒸汽夹套防止形成冻结区。在 K.O.D.底部周围的最佳区域注入蒸汽，观察到该区域没有结冰现象。蒸汽夹套通过这种设计和向转鼓外壁注入蒸汽来实现均匀加热。由于多种原因，该项目的实施将减少烟雾和火炬污染：抑制 K.O.D. 液体出口处的结冰，使桶内液面保持恒定，防止与废气有关的液滴转移到火炬。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

International Journal of Renewable Energy Development

自引率

0.00%

发文量