封面
市场调查报告书
商品编码
1530262

美国热处理市场规模、份额、趋势分析报告:2024-2030年按材料、製程、设备、应用和细分市场预测

U.S. Heat Treating Market Size, Share & Trends Analysis Report By Material (Steel, Cast Iron), By Process (Case hardening, Annealing), By Equipment, By Application, And Segment Forecasts, 2024 - 2030

出版日期: | 出版商: Grand View Research | 英文 100 Pages | 商品交期: 2-10个工作天内

价格
简介目录

美国热处理市场的成长与趋势:

根据Grand View Research, Inc.最新报告,预计到2030年美国热处理市场规模将达到273.2亿美元,2024年至2030年复合年增长率为2.8%。

由于电动车行业的快速扩张以及特定应用对冶金改性的需求不断增加,预计该市场在未来几年将显着增长。热处理在提高电动车传动系统和电池系统中关键部件的性能、效率和使用寿命方面发挥关键作用,导致电动车热处理需求迅速增加。

热处理是製造和金属加工中必不可少的工艺,需求趋势随着各行业的需求而变化。例如,航太工业不断寻求提高关键零件的耐用性和性能,这是真空热处理和等离子氮化等先进热处理技术的主要驱动力。汽车趋势,特别是转向轻量材料以提高燃油效率,正在推动对提高铝强度的热处理的需求。

热处理控製材料的加热和冷却,以实现不同的机械性能,例如强度、柔韧性和硬度。加热过程中的温度控制非常耗能。实现热效率和优化整体负载需要使用先进的技术。热处理设备使用各种炉型来改善系统的热分布。数值建模系统用于模拟热处理过程。

此外,加工技术的进步有助于提高材料效率。新技术的出现有助于减少摩擦并提高热处理材料的强度。热处理行业的一个重要技术方面是获得能源效率。真空渗碳和渗氮加热製程正迅速获得世界各地工业界的认可。这导致了熔炉设计技术和气氛控製过程的改进。

美国热处理行业的製造商正在采取多种策略,包括收购、合併、新产品发布和地理扩张,以提高市场渗透率并应对不断变化的技术需求。市场上的主要企业,包括 Bodycoat、Bluewater Thermal 热感和 Advanced Heat Treat Corporation,都致力于扩大其服务范围并投资最先进的设备,以增强其能力并满足严格的行业标准。例如,2024年1月,Bodycoat完成了对热等静压(HIP)和热处理服务供应商Lake City HT的收购。此次收购预计将在未来几年显着增加 Bodycoat 在医疗市场的客户群。

美国热处理市场报告亮点:

  • 到2023年,钢铁材料业将以79.7%的销售份额引领市场。建设产业对热处理钢部件的需求增加预计将在预测期内推动钢热处理的需求。钢材经过热处理以获得特定的机械性能,如强度、耐磨性能和表面硬度。
  • 预计表面淬火製程领域在预测期内将呈现良好的成长。市场成长对錶面硬化製程的需求持续强劲,各行业都非常重视提高金属零件的表面硬度和耐磨性。在汽车製造、航太和工业机械等应用中,表面硬化在延长遭受严重磨损和摩擦的零件的使用寿命和提高性能方面发挥关键作用。例如,汽车产业依靠表面硬化来提高齿轮、凸轮轴和其他关键引擎部件的耐用性。
  • 间歇式炉设备领域在 2023 年占据最大的收益占有率。间歇式炉也称为箱式炉,由于其适应性和功能性,在各种热处理应用中发挥重要作用。箱式炉具有一个隔热室,可容纳正在加工的材料,从而确保严格控制的加热环境。箱式炉的主要目的是为各种製程提供一致、可控的热处理环境。
  • 预计连续炉设备领域在预测期内将呈现良好的成长。连续炉是专门的工业热处理设备,旨在管理连续的工件流。与处理有限数量工件的间歇式炉不同,连续式炉有利于不间断的热处理过程。因此,连续炉适合大规模生产和一致的热处理作业。
  • 间歇式炉是燃油加热炉和电加热炉,适用于多种工业加热工艺,每种工艺都有不同的特点和应用。间歇式炉设计用于分批加热材料。这种设置可以精确控制加热循环和气氛,以适应各种材料和工艺。这些熔炉是分批运作的,不是连续运作的。
  • 由于电动汽车行业的成长以及对实现节能热处理的环保技术的需求不断增加,预计汽车应用在预测期内将呈现良好的成长。此外,电动车所需的新型先进设备预计将推动产业成长。由于不断追求轻量材料、改进的机械性能和提高的耐用性,汽车行业对热处理的需求仍然强劲。
  • 2024 年 4 月,西科沃克公司在印度开设了一家新生产工厂,标誌着其向各大洲提供高品质金属热处理设备的全球扩大策略的又一个里程碑。新厂面积4000平方公尺,层高12米。它配备了两台架空起重机,每台可起重15吨。该工厂地理位置优越,位于印度马哈拉斯特拉邦普纳附近的一个经济特区,靠近许多工厂和公司的潜在客户。该工厂预计将专注于製造真空设备和 CAB 生产线,并提供全面的服务和支援。

目录

第一章调查方法和范围

第 2 章执行摘要

第三章美国热处理市场变数、趋势与范围

  • 市场体系展望
  • 集中度和成长前景图
  • 产业价值链分析
  • 法律规范
  • 市场动态
    • 市场驱动因素分析
    • 市场限制因素分析
    • 市场机会分析
    • 市场问题分析
  • 美国热处理市场分析工具
    • 波特的分析
    • PESTEL分析
  • 经济大趋势分析

第四章美国热处理市场:依材料分类的预估及趋势分析

  • 2023 年和 2030 年市场占有率
  • 美国热处理市场:2023 年与 2030 年波动分析
  • 铸铁
  • 其他的

第五章美国热处理市场:依製程估算与趋势分析

  • 2023 年和 2030 年按製程分類的变化分析和市场占有率
  • 美国热处理市场:2023 年与 2030 年波动分析
  • 表面硬化
  • 淬火和回火
  • 退火
  • 正常化
  • 其他的

第六章美国热处理市场:依设备分類的估算与趋势分析

  • 2023 年和 2030 年设备变化分析和市场占有率
  • 美国热处理市场:2023 年与 2030 年波动分析
  • 间歇炉
  • 连续炉

第七章美国热处理市场:按应用估算与趋势分析

  • 2023年和2030年应用变化分析和市场占有率
  • 美国热处理市场:2023 年与 2030 年波动分析
  • 机器
  • 建造
  • 航太
  • 金属加工
  • 其他的

第八章 竞争格局

  • 主要市场参与企业的最新趋势和影响分析
  • 公司分类
  • 公司市场定位
  • 2023 年企业市场占有率分析
  • 企业热力图分析
  • 策略规划
  • 公司简介
    • Bluewater Thermal
    • AMERICAN METAL TREATING, INC.
    • East~Lind Heat Treat, Inc.
    • General Metal Heat Treating
    • Pacific Metallurgical, Inc.
    • Nabertherm GmbH
    • SECO/WARWICK, INC.
    • Bodycote
    • American Heat Treating
    • Heat Treating Inc.
简介目录
Product Code: GVR-4-68040-356-0

U.S. Heat Treating Market Growth & Trends:

The U.S. heat treating market size is anticipated to reach USD 27.32 billion by 2030 and is anticipated to register a CAGR of 2.8% from 2024 to 2030, according to a new report by Grand View Research, Inc. The market is expected to grow significantly in the coming years, driven by the rapid expansion of the EV industry and the increasing demand for metallurgical alterations to suit specific applications. Heat treatment plays a crucial role in enhancing the performance, efficiency, and longevity of critical components within EV drivetrains and battery systems, leading to a surge in demand for heat treatment in EVs.

Heat treating, an essential process in the manufacturing and metalworking sectors, has seen evolving demand trends shaped by various industry needs. For instance, the aerospace industry, constantly seeking enhanced durability and performance in critical components, has been a substantial driver for advanced heat-treating techniques like vacuum heat treating and plasma nitriding. Automotive trends, particularly the shift towards lightweight materials for improved fuel efficiency, have spurred demand for heat treatments that enhance aluminum's strength.

Heat treating involves controlled heating and cooling of materials to attain distinct mechanical properties such as strength, flexibility, and hardness. The temperature control in the heating process is highly energy intensive. Achieving thermal efficiency and optimizing the load throughout requires the use of advanced technology. Heat-treating units use various furnace models to improve the thermal profile of the system. Numerical modeling systems are used to stimulate the heat-treating process.

Moreover, advancement in processing technology has helped to increase the efficiency of materials. The emergence of new technologies helped reduce friction and increase the strength of heat-treated materials. The key technological aspect of the heat treating industry involves obtaining energy efficiency. Vacuum carburizing and nitriding heating processes have gained rapid industrial acceptance across the globe. This has led to improvements in furnace designing technologies and atmosphere control processes.

Manufacturers in the U.S. heat treating industry are adopting several strategies, such as acquisitions, mergers, new product launches, and geographical expansion, to enhance market penetration and cater to changing technological demands. Key players in the market, including Bodycote, Bluewater Thermal Solutions, and Advanced Heat Treat Corp., focus on expanding their service offerings and investing in state-of-the-art facilities to enhance their capabilities and meet stringent industry standards. For instance, in January 2024, Bodycote completed the acquisition of Lake City HT, a provider of hot isostatic pressing (HIP) and heat treatment services. With this acquisition, the customer reach of Bodycote is expected to significantly increase in the medical market in the coming years.

U.S. Heat Treating Market Report Highlights:

  • The steel material segment led the market with a revenue share of 79.7% in 2023. Growing demand for heat-treated steel parts in the construction industry, is expected to propel the demand for heat treating for steel over the forecast period. Steel is subjected to heat treating to obtain certain mechanical properties including strength, wear properties, and surface hardness.
  • The case hardening process segment is anticipated to show lucrative growth over the forecast period. The demand for case hardening processes within the market growth remains strong, driven by industries where enhanced surface hardness and wear resistance of metal components are paramount. In applications such as automotive manufacturing, aerospace, and industrial machinery, case hardening plays a critical role in extending the lifespan and improving the performance of components subjected to heavy wear and friction. The automotive sector, for instance, relies on case hardening to enhance the durability of gears, camshafts, and other critical engine components.
  • The batch furnace equipment segment held the largest revenue share in 2023. Batch furnaces, also known as box furnaces, play a crucial role in various heat treatment applications owing to their adaptability and functionality. They feature an insulated compartment, which is designed to hold the materials being processed, thereby ensuring a tightly controlled heating environment. The primary aim of box furnaces is to offer a consistent and controllable heat treatment setting for a variety of processes.
  • The continuous furnace equipment segment is expected to show lucrative growth over the forecast period. Continuous furnaces are specialized industrial heat treatment equipment that are designed to manage an ongoing stream of workpieces. In contrast to batch furnaces, which process workpieces in limited quantities, continuous furnaces facilitate an uninterrupted heat treatment process. This makes continuous furnaces suitable for high-volume production and consistent heat treatment operations.
  • Batch furnaces are fuel-fired and electrically heated furnaces that cater to a broad array of industrial heating processes, each with distinct characteristics and suited to different applications. Batch furnaces are designed to heat materials in discrete batches. This setup allows for precise control over the heating cycle and atmosphere, accommodating a wide variety of materials and processes. Since these furnaces operate on a batch-by-batch basis, they do not run continuously.
  • The automotive application is anticipated to show lucrative growth over the forecast period due to the growing EV industry and the increasing demand for greener technologies that can deliver energy-efficient heat treatment. Moreover, new and advanced equipment required for EVs is expected to propel industry growth. The demand for heat treating in the automotive industry remains robust, driven by the sector's relentless pursuit of lightweight materials, improved mechanical properties, and enhanced durability.
  • In April 2024, SECO/WARWICK, INC. inaugurated a new production facility in India, marking another milestone in its global expansion strategy to deliver high-quality metal heat treatment equipment across all continents. The new plant spans 4,000 m2 with a ceiling height of 12 meters. It is equipped with two overhead cranes capable of lifting 15 tons each. Strategically located in a special economic zone near Pune, Maharashtra, India, the facility is close to numerous industrial plants and potential customers for the company. The plant is expected to focus on manufacturing vacuum equipment and CAB lines and providing comprehensive service support.

Table of Contents

Chapter 1. Methodology and Scope

  • 1.1. Research Methodology
  • 1.2. Research Scope & Assumptions
  • 1.3. Information Procurement
    • 1.3.1. Purchased Database
    • 1.3.2. GVR's Internal Database
    • 1.3.3. Secondary Sources & Third-Party Perspectives
    • 1.3.4. Primary Research
  • 1.4. Information Analysis
    • 1.4.1. Data Analysis Models
  • 1.5. Market Formulation & Data Visualization
  • 1.6. Data Validation & Publishing

Chapter 2. Executive Summary

  • 2.1. Market Outlook
  • 2.2. Segment Outlook
  • 2.3. Competitive Insights

Chapter 3. U.S. Heat Treating Market Variables, Trends, & Scope

  • 3.1. Market Lineage Outlook
  • 3.2. Concentration & Growth Prospect Mapping
  • 3.3. Industry Value Chain Analysis
  • 3.4. Regulatory Framework
  • 3.5. Market Dynamics
    • 3.5.1. Market Drivers Analysis
    • 3.5.2. Market Restraints Analysis
    • 3.5.3. Market Opportunity Analysis
    • 3.5.4. Market Challenge Analysis
  • 3.6. U.S. Heat Treating Market Analysis Tools
    • 3.6.1. Porter's Analysis
      • 3.6.1.1. Bargaining Power of The Suppliers
      • 3.6.1.2. Bargaining Power of The Buyers
      • 3.6.1.3. Threats Of Substitution
      • 3.6.1.4. Threats From New Entrants
      • 3.6.1.5. Competitive Rivalry
    • 3.6.2. PESTEL Analysis
      • 3.6.2.1. Political Landscape
      • 3.6.2.2. Economic And Social Landscape
      • 3.6.2.3. Technological Landscape
      • 3.6.2.4. Environmental Landscape
      • 3.6.2.5. Legal Landscape
  • 3.7. Economic Mega Trend Analysis

Chapter 4. U.S. Heat Treating Market: Material Estimates & Trend Analysis

  • 4.1. Material Movement Analysis & Market Share, 2023 & 2030
  • 4.2. U.S. Heat Treating Market: Service Movement Analysis, 2023 & 2030
  • 4.3. Steel
    • 4.3.1. Market Estimates And Forecasts, 2018 - 2030 (USD Billion)
  • 4.4. Cast iron
    • 4.4.1. Market Estimates And Forecasts, 2018 - 2030 (USD Billion)
  • 4.5. Others
    • 4.5.1. Market Estimates And Forecasts, 2018 - 2030 (USD Billion)

Chapter 5. U.S. Heat Treating Market: Process Estimates & Trend Analysis

  • 5.1. Process Movement Analysis & Market Share, 2023 & 2030
  • 5.2. U.S. Heat Treating Market: Source Movement Analysis, 2023 & 2030
  • 5.3. Case hardening
    • 5.3.1. Market Estimates And Forecasts, 2018 - 2030 (USD Billion)
  • 5.4. Hardening & tempering
    • 5.4.1. Market Estimates And Forecasts, 2018 - 2030 (USD Billion)
  • 5.5. Annealing
    • 5.5.1. Market Estimates And Forecasts, 2018 - 2030 (USD Billion)
  • 5.6. Normalizing
    • 5.6.1. Market Estimates And Forecasts, 2018 - 2030 (USD Billion)
  • 5.7. Others
    • 5.7.1. Market Estimates And Forecasts, 2018 - 2030 (USD Billion)

Chapter 6. U.S. Heat Treating Market: Equipment Estimates & Trend Analysis

  • 6.1. Equipment Movement Analysis & Market Share, 2023 & 2030
  • 6.2. U.S. Heat Treating Market: Polymer Movement Analysis, 2023 & 2030
  • 6.3. Batch Furnace
    • 6.3.1. Market Estimates And Forecasts, 2018 - 2030 (USD Billion)
    • 6.3.2. Market Estimates And Forecasts, by heating method, 2018 - 2030 (USD Billion)
  • 6.4. Continuous Furnace
    • 6.4.1. Market Estimates And Forecasts, 2018 - 2030 (USD Billion)
    • 6.4.2. Market Estimates And Forecasts, by heating method, 2018 - 2030 (USD Billion)

Chapter 7. U.S. Heat Treating Market: Application Estimates & Trend Analysis

  • 7.1. Application Movement Analysis & Market Share, 2023 & 2030
  • 7.2. U.S. Heat Treating Market: Polymer Movement Analysis, 2023 & 2030
  • 7.3. Automotive
    • 7.3.1. Market Estimates And Forecasts, 2018 - 2030 (USD Billion)
  • 7.4. Machine
    • 7.4.1. Market Estimates And Forecasts, 2018 - 2030 (USD Billion)
  • 7.5. Construction
    • 7.5.1. Market Estimates And Forecasts, 2018 - 2030 (USD Billion)
  • 7.6. Aerospace
    • 7.6.1. Market Estimates And Forecasts, 2018 - 2030 (USD Billion)
  • 7.7. Metalworking
    • 7.7.1. Market Estimates And Forecasts, 2018 - 2030 (USD Billion)
  • 7.8. Others
    • 7.8.1. Market Estimates And Forecasts, 2018 - 2030 (USD Billion)

Chapter 8. Competitive Landscape

  • 8.1. Recent Developments & Impact Analysis By Key Market Participants
  • 8.2. Company Categorization
  • 8.3. Company Market Positioning
  • 8.4. Company Market Share Analysis, 2023
  • 8.5. Company Heat Map Analysis
  • 8.6. Strategy Mapping
  • 8.7. Company Profiles
    • 8.7.1. Bluewater Thermal
      • 8.7.1.1. Participant's Overview
      • 8.7.1.2. Financial Performance
      • 8.7.1.3. Technique Benchmarking
      • 8.7.1.4. Recent Developments
    • 8.7.2. AMERICAN METAL TREATING, INC.
      • 8.7.2.1. Participant's Overview
      • 8.7.2.2. Financial Performance
      • 8.7.2.3. Technique Benchmarking
      • 8.7.2.4. Recent Developments
    • 8.7.3. East~Lind Heat Treat, Inc.
      • 8.7.3.1. Participant's Overview
      • 8.7.3.2. Financial Performance
      • 8.7.3.3. Technique Benchmarking
      • 8.7.3.4. Recent Developments
    • 8.7.4. General Metal Heat Treating
      • 8.7.4.1. Participant's Overview
      • 8.7.4.2. Financial Performance
      • 8.7.4.3. Technique Benchmarking
      • 8.7.4.4. Recent Developments
    • 8.7.5. Pacific Metallurgical, Inc.
      • 8.7.5.1. Participant's Overview
      • 8.7.5.2. Financial Performance
      • 8.7.5.3. Technique Benchmarking
      • 8.7.5.4. Recent Developments
    • 8.7.6. Nabertherm GmbH
      • 8.7.6.1. Participant's Overview
      • 8.7.6.2. Financial Performance
      • 8.7.6.3. Technique Benchmarking
      • 8.7.6.4. Recent Developments
    • 8.7.7. SECO/WARWICK, INC.
      • 8.7.7.1. Participant's Overview
      • 8.7.7.2. Financial Performance
      • 8.7.7.3. Technique Benchmarking
      • 8.7.7.4. Recent Developments
    • 8.7.8. Bodycote
      • 8.7.8.1. Participant's Overview
      • 8.7.8.2. Financial Performance
      • 8.7.8.3. Technique Benchmarking
      • 8.7.8.4. Recent Developments
    • 8.7.9. American Heat Treating
      • 8.7.9.1. Participant's Overview
      • 8.7.9.2. Financial Performance
      • 8.7.9.3. Technique Benchmarking
      • 8.7.9.4. Recent Developments
    • 8.7.10. Heat Treating Inc.
      • 8.7.10.1. Participant's Overview
      • 8.7.10.2. Financial Performance
      • 8.7.10.3. Technique Benchmarking
      • 8.7.10.4. Recent Developments