《化工过程强化传热系统》深入剖析了传热的基本原理，系统总结了强化传热的理论知识与实践经验。本书基于过程系统与换热设备技术的有机结合，创新性地开发出化工过程强化传热的新方法。
书中以石油炼制、芳烃、乙烯等石化行业的典型工艺为重点研究对象，从设备部件、工艺单元到全厂系统，进行了全方位、多层次的详细阐述，展示了强化传热在石化行业的系统优化和综合应用，为该行业的传热技术升级提供了切实可行的思路和方法。
本书不仅为石油化工领域的专业人士提供了宝贵的参考，其适用范围还广泛涵盖了多个相关行业。无论是从事炼油、精细化工、煤化工的学者和工程师，还是工业化学、生化制药、食品加工行业的技术人员，亦或是专注于废气和废水处理领域的从业者，都能从本书中获取丰富的专业知识和实践指导。

内容简介
Heat Transfer Enhancement in Chemical Processes systematically analyzes the basic principles of heat transfer , summarizes the theories and practices of heat transfer enhancement , and develops new methods for heat transfer enhancement in chemical processes on the basis of integrating process systems with heat exchange equipment technologies . The book focuses on the representative processes in the petrochemical industry , i.e., oil refining , aromatics , and ethylene production , and systematically details the system optimization and integrated application of heat transfer enhancement in the petrochemical industry from the equipment components , and the process units to the whole plant .
This book provides scholars , engineers , students , and technicians in oil refining , petrochemical , fine chemical , and coal chemical industries , chemical and biochemical pharmacy , food processing , and waste gas and waste water treatment , with a comprehensive reference .

孙丽丽，中国工程院院士、全国工程勘察设计大师、石化工程专家、中国石油化工集团公司首席科学家。
她带领团队攻克了高效环保芳烃关键工程技术，主持建成我国首套自主技术芳烃联合装置，整体达国际领先水平，推动了芳烃产业的高质量发展。在原油高效清洁转化技术集成创新上取得重大突破，主持建成我国首座单系列千万吨级炼厂，同步解决了劣质原油高效利用和污染源头治理等系列重大难题，成果已应用于惠州等十余座炼化基地，为端牢能源饭碗奠定了重要基础。开发超大型高酸天然气净化与安全高效硫回收关键技术，主持建成世界第 二大高酸天然气净化厂，填补了高酸天然气净化关键技术空白，为长江经济带70多个城市和上千家企业提供清洁能源，并将H2S变害为宝，年产硫黄占当年全国总产量的30%。主持建成我国海外合资炼油工程——中沙延布2000万吨/年炼厂，创造了多项当地工程建设史上的新纪录，生产运行达到领先水平，赢得两国政府高度赞誉。面对双碳目标和炼化绿色高质量发展的新挑战，她又带领团队，全力开展炼化流程再造、多能耦合利用和数字赋能桌面石化工厂模式研究。
获国家科技进步奖特等奖2项、二等奖2项；获全国优秀工程勘察设计金奖、菲迪克杰出项目奖；获何梁何利科学与技术创新奖、侯德榜化工科学技术成就奖；获全国优秀科技工作者称号，所带团队荣获中央企业先进集体和中央企业楷模。

1. Introduction 1
1.1 Significance of heat transfer enhancement 1
1.2 Progress in heat transfer enhancement technology 3
1.3 Engineering applications of heat transfer enhancement 8
1.4 Heat transfer enhancement of the whole plant 20
References 27

2. Basic principles and methods of heat transfer enhancement 29
2.1 Basic principles of heat transfer enhancement 29
2.2 Heat transfer enhancement technology 35
2.3 Commonly used enhanced heat transfer elements and equipment 49
2.4 Heat transfer network synthesis technology 72
References 85

3. Heat transfer enhancement in typical oil refining units 89
3.1 Crude oil distillation unit 90
3.2 Catalytic cracking unit 112
3.3 Hydrocracking unit 124
3.4 Hydrotreating unit 139
3.5 Heavy oil hydrotreating unit 152
3.6 Hydrogen production unit 165
3.7 Delayed coking unit 177
3.8 Adsorption desulfurization unit for catalytic cracking gasoline 196
3.9 Alkylation unit 204
References 216

4. Heat transfer enhancement in a typical aromatic complex 219
4.1 Naphtha hydrotreating and catalytic reforming unit 220
4.2 Aromatics extraction unit 238
4.3 Disproportionation unit
4.4 Xylene isomerization unit 262
4.5 Paraxylene separation and xylene fractionation unit 271
References 293

5. Heat transfer enhancement in typical ethylene plants and downstream units 295
5.1 Steam cracking 296
5.2 Ethylene separation 312
5.3 Ethylene oxide/ethylene glycol unit 331
5.4 Propylene oxide unit 346
5.5 Styrene unit 353
5.6 C5 separation unit 363
5.7 Butyl rubber unit 371
References 379

6. Heat transfer enhancement and overall plant energy saving 383
6.1 Innovative methodology for systematic energy saving 384
6.2 Global heat integration optimization design 393
6.3 Typical cases of heat transfer enhancement across the plant 399
References 432

Index 433