汽车热交换器市场（按设计类型、车辆类型、电动车、非公路车辆类型、应用和地区划分）2024 年至 2031 年

汽车热交换器市场，2024-2031

技术、工业和商业应用对汽车零件的需求日益增加。因此，由于汽车零件需求不断扩大，市场规模将从2024年的277亿美元迅速成长至2031年的436.5亿美元。

可支配收入的增加、购买力的增强和消费者偏好的演变，推动了高端商用车 (CV) 和非公路用车 (OHV) 采用 HVAC 系统。因此，高端商用车(CV) 和非公路用车(OHV) 扩大采用HVAC 系统，在快速成长的国家中越来越受欢迎，预计市场从2024 年到2025 年的复合年增长率将达到6.45%。

汽车热交换器市场定义/概述

热交换器是一种用于在两种不同温度的介质之间传递热量的系统。这些系统由至少两种在近距离内流动的介质组成，并由高导热材料（例如金属）製成的屏障隔开。该系统的一个特点是存在热流体和冷流体。热交换器依流动方式分为平行流、交叉流和逆流型。在汽车应用中，热交换器主要用于去除机械系统中的热量。

现代热交换器主要由铝製成，铝重量轻且导热性优良。常见的汽车热交换器有散热器、油冷器、中冷器等。维持引擎和其他车辆部件的适当温度在很大程度上依赖汽车热交换器。此外，这些设备也用于空调系统等冷却应用。热交换器通常位于车辆的各个位置，包括引擎室、排气系统和加热、通风和空调 (HVAC) 装置。

对热效率管理系统日益增长的需求将如何推动汽车热交换器市场的成长？

商用车对高效能热管理系统的需求日益增加，影响了汽车热交换器的需求。随着商用车的扩张和现代化，人们越来越重视车辆零件（包括热交换器）的性能和寿命。电动和混合动力汽车需要先进的热管理系统，从而增加了对先进热交换器的需求。这些系统对于维持最佳电池温度和提高整体车辆效率至关重要。

世界各国政府正在实施严格的排放和燃油经济性标准。这种监管压力要求开发更有效率的引擎和动力系统，其中热交换器发挥关键作用。因此，对高性能热交换器的需求显着增加。微通道热交换器和轻质材料等技术创新正被扩大采用。这些进步旨在提高传热效率，同时减轻车辆的整体重量。

据称，推动市场扩张的主要因素是汽车电气化的进步以及商用车对 HVAC 系统的日益广泛采用。随着越来越多的车辆配备先进的气候控制系统，对高效能热交换器的需求正在激增。新兴国家城市化进程加快和可支配收入上升促使汽车拥有率上升。这一趋势正在推动对包括热交换器在内的汽车零件的需求。随着道路上车辆平均使用年限的增加，热交换器的售后市场也正在经历成长。

对永续和环保技术的关注正在影响热交换器市场。製造商正在努力开发不仅更有效率，而且所使用的材料和製造流程也更环保的热交换器。

汽车热交换器高昂的初始成本将如何阻碍汽车热交换器市场的成长？

引入更高效、更紧凑的热交换器所需的初始研究、开发和投资成本很高。这将阻碍这种先进系统的采用，特别是在对成本敏感的低价车领域。高性能热交换器製造流程的复杂性。需要专门的设备和熟练的劳动力，这会导致更高的生产成本。这种复杂性限制了能够生产先进热交换器的製造商的数量，并可能造成供应链瓶颈。

对于热交换器所用材料的环境问题日益严重。铜和铝等传统材料虽然有效，但也面临对环境影响的课题。采用更环保的材料的压力越来越大，但替代材料的性能并不总是能与传统材料相媲美。铝和铜等热交换器生产所需的金属成本不稳定。这些价格波动会影响利润率，并使长期定价策略难以维持。

汽车电气化趋势为热交换器市场带来了机会和课题。电动车所需的热管理系统与传统内燃机汽车的热管理系统性质不同。这种变化将需要对热交换器设计进行重大调整，并可能使一些现有技术过时。监管压力和变化的排放标准不断发展。热交换器製造商必须不断调整其产品以满足这些不断变化的需求，这是昂贵且耗时的。为了满足新标准而需要频繁重新设计可能会减缓市场成长。

汽车产业正在努力减轻汽车重量以提高燃油效率，这对热交换器製造商来说是一个课题。热交换器对于车辆性能至关重要，但其重量必须保持在最低限度，且不能影响功能。效率和减轻重量之间的平衡通常很难实现。近期全球供应链的中断凸显了汽车零件产业的脆弱性。热交换器的生产可能会受到原材料和关键零件短缺的影响，导致生产延迟和成本增加。

人们对热电冷却等替代冷却技术的日益关注可能会对传统热交换器构成长期威胁。儘管这些技术尚未在汽车领域广泛应用，但其未来应用的潜力不容忽视。

目录

第 1 章全球汽车热交换器市场：简介

• 市场概况
• 调查范围
• 先决条件

第 2 章执行摘要

第3章 VERIFIED MARKET RESEARCH研究方法

• 数据挖掘
• 验证
• 一次资料
• 数据源列表

第4章 汽车热交换器全球市场展望

• 概述
• 市场动态
  • 促进因素
  • 阻碍因素
  • 机会
• 波特的五力模型
• 价值链分析

第 5 章 全球汽车热交换器市场（依设计类型）

• 概述
• 板棒材
• 管翅片

第6章 全球汽车热交换器市场（依车型）

• 概述
• 乘用车
• 轻型商用车

第 7 章 全球电动汽车汽车热交换器市场

• 概述
• 纯电动汽车 (BEV)
• 混合动力汽车 (HEV)

第8章全球汽车热交换器市场（依非公路车辆类型）

• 概述
• 农业机械
• 工程机械

第9章全球汽车热交换器市场（按应用）

• 概述
• 散热器
• 油冷却器

第 10 章 全球汽车热交换器市场（按区域）

• 概述
• 北美
  • 美国
  • 加拿大
  • 墨西哥
• 欧洲
  • 德国
  • 英国
  • 法国
  • 欧洲其他地区
• 亚太地区
  • 中国
  • 日本
  • 印度
  • 亚太其他地区
• 世界其他地区
  • 拉丁美洲
  • 中东/非洲

第11章全球汽车热交换器市场竞争格局

• 概述
• 各公司市场排名
• 主要发展策略

第12章 公司简介

• AKG Thermal Systems, Inc.
• American Industrial Heat Transfer, Inc.
• Banco Products（India）Ltd
• Climetal S.L.-Heat Exchanger
• Clizen Inc.
• Constellium SE
• DENSO Corporation
• G&M Radiator Mfg Ltd
• Hanon Systems
• MAHLE GmbH.

第13章 附录

• 相关报导

Automotive Heat Exchanger Market- 2024-2031

The increase in demand for automotive components in technical, industrial, and commercial applications. Thus, the growing demand for automotive components leads to a surge in the growth of market size comprising USD 27.7 Billion in 2024 to reach athe valuation at USD 43.65 Billion by 2031.

The growing adoption of HVAC systems in high-end commercial vehicles (CV) and off-highway vehicles (OHV) on account of the rise in disposable income, enhanced purchasing power, and evolving consumer preferences. Thus, the growing adoption of HVAC systems in high-end commercial vehicles (CV) and off-highway vehicles (OHV) is gaining popularity in rapidly growing countries enabling the market to grow at a CAGR of 6.45% from 2024 to 2031.

Automotive Heat Exchanger Market: Definition/ Overview

Heat exchangers are systems designed for the transfer of heat between two mediums at different temperatures. These systems are comprised of at least two mediums that are made to flow nearby, separated by a barrier typically made of materials with high heat conductivity, such as metal. The system is characterized by the presence of hot and cold fluids. Heat exchangers are classified into parallel flow, cross flow, and counterflow types based on their flow patterns. In automotive applications, heat exchangers are primarily utilized to dissipate heat from mechanical systems.

Modern heat exchangers are predominantly constructed from aluminum, chosen for their lightweight properties and exceptional thermal conductivity. Common automotive heat exchangers include radiators, oil coolers, and intercoolers. The maintenance of appropriate temperatures for the engine and other vehicle components is largely dependent on automotive heat exchangers. Additionally, these devices are employed in cooling applications, such as air conditioning systems. Heat exchangers are typically installed in various areas of a vehicle, including the engine bay, exhaust system, and heating, ventilation, and air conditioning (HVAC) units.

How Does the Increasing Need for Thermal Efficient Management Systems Surge the Growth of the Automotive Heat Exchanger Market?

The increase in need for efficient thermal management systems in commercial vehicles affects the demand for automotive heat exchanger. As commercial fleets expand and modernize, a greater emphasis is being placed on the performance and longevity of vehicle components, including heat exchangers. Electric and hybrid vehicles require sophisticated thermal management systems, which has led to an increased demand for advanced heat exchangers. These systems are crucial for maintaining optimal battery temperatures and enhancing overall vehicle efficiency.

Stringent emission norms and fuel efficiency standards have been implemented by governments worldwide. This regulatory pressure has necessitated the development of more efficient engines and powertrains, wherein heat exchangers play a vital role. As a result, the demand for high-performance heat exchangers has been boosted significantly. Innovations such as micro-channel heat exchangers and the use of lightweight materials are being increasingly adopted. These advancements are aimed at improving heat transfer efficiency while reducing the overall weight of vehicles.

The growth in vehicle electrification and the rise in the adoption of HVAC systems in commercial vehicles have been noted as key factors contributing to market expansion. As more vehicles are equipped with advanced climate control systems, the demand for efficient heat exchangers has surged. Increase in urbanization and rise in disposable incomes in emerging economies have led to a growth in vehicle ownership. This trend has subsequently driven the demand for automotive components, including heat exchangers. The aftermarket segment for heat exchangers has also been experiencing growth due to the increasing average age of vehicles on the road.

The focus on sustainable and environmentally friendly technologies has influenced the heat exchanger market. Manufacturers are being pushed to develop heat exchangers that are not only more efficient but also more environmentally friendly in terms of materials used and manufacturing processes.

How Does the High Initial Costs Associated with the Automotive Heat Exchanger Impede the Growth of the Automotive Heat Exchanger Market?

High initial costs for the investment required for research, development, and implementation of more efficient and compact heat exchangers are substantial. The adoption of these advanced systems hindered, particularly in lower-end vehicle segments where cost sensitivity is high. The complexity of manufacturing processes for high-performance heat exchangers. Specialized equipment and skilled labor are required, which can lead to increased production costs. This complexity may limit the number of manufacturers capable of producing advanced heat exchangers, potentially creating supply chain bottlenecks.

Environmental concerns related to the materials used in heat exchangers are being increasingly scrutinized. Traditional materials like copper and aluminum, while effective, may face challenges due to their environmental impact. The pressure to adopt more eco-friendly materials is growing, but alternatives may not always match the performance of conventional materials. The fluctuations in the costs of metals like aluminum and copper, which are essential for heat exchanger production, can be volatile. These price fluctuations may impact profit margins and make long-term pricing strategies difficult to maintain.

The trend towards vehicle electrification is creating both opportunities and challenges for the heat exchanger market. While electric vehicles require thermal management systems, the nature of these systems differs from those in traditional internal combustion engine vehicles. This shift necessitates significant adaptations in heat exchanger design and may render some existing technologies obsolete. Regulatory pressures and the change in emission standards are constantly evolving. Heat exchanger manufacturers must continually adapt their products to meet these changing requirements, which are costly and time-consuming. The need for frequent redesigns to comply with new standards may slow down market growth.

The automotive industry's push for lighter vehicles to improve fuel efficiency poses a challenge for heat exchanger manufacturers. While heat exchangers are crucial for vehicle performance, their weight must be minimized without compromising functionality. This balance between efficiency and weight reduction is often difficult to achieve. The global supply chain disruptions, as seen in recent years, have highlighted the vulnerability of the automotive component industry. Heat exchanger production may be impacted by shortages of raw materials or critical components, leading to production delays and increased costs.

The increase in focus on alternative cooling technologies, such as thermoelectric cooling, may pose a long-term threat to traditional heat exchangers. While these technologies are not yet widely adopted in the automotive sector, their potential for future implementation cannot be ignored.

Category-Wise Acumens

How the Rise in Awareness of Environmental Issues has Accelerate the Growth of the Hybrid Electric Vehicle (HEV) Segment?

The hybrid electric vehicle (HEV) segment dominates the automotive heat exchanger market. The rise in global awareness of environmental issues has been driving the adoption of hybrid electric vehicles. As a result, the demand for specialized heat exchangers designed for these vehicles has been increasing. HEVs require more complex thermal management systems compared to traditional internal combustion engine vehicles, which has been fueling the growth of this market segment.

Increased environmental consciousness has been noted among consumers worldwide. As a result, a shift in preference towards more fuel-efficient and environmentally friendly vehicles, such as HEVs, has been witnessed. Stringent emissions regulations have been implemented by governments across the globe. These regulations have pushed automakers to invest more heavily in hybrid and electric vehicle technologies. Consequently, the demand for specialized heat exchangers designed for HEVs has been boosted.

The performance and efficiency of HEVs are highly dependent on effective thermal management systems. As awareness of this dependency has grown, greater emphasis has been placed on developing advanced heat exchangers tailored to the unique needs of hybrid powertrains. Public initiatives and incentives promoting the adoption of eco-friendly vehicles have been introduced in many countries. These measures have accelerated the uptake of HEVs, indirectly driving the growth of the associated heat exchanger market. Advancements in heat exchanger technology have been made to meet the specific requirements of HEVs. These innovations include more compact designs, improved efficiency, and better integration with hybrid powertrain systems. The availability of these specialized solutions has further propelled the growth of the HEV segment.

The increasing focus on reducing the overall carbon footprint of the transportation sector has led to greater investment in HEV technology. This investment has extended to the development of more sophisticated thermal management systems, including advanced heat exchangers. Rising fuel prices and the long-term cost benefits of HEVs have been recognized by consumers. This recognition has contributed to the growing popularity of hybrid vehicles, subsequently driving demand for HEV-specific heat exchangers.

How the Increase in Infrastructure Development Activities have aided in the Growth of the Construction Equipment Segment?

The construction equipment segment significantly dominates the automotive heat exchanger market. The increase in infrastructure development activities has surged the demand for construction equipment in the automotive heat exchanger. Large-scale infrastructure projects, including the construction of roads, bridges, airports, and urban development initiatives, have been undertaken worldwide. These projects require a wide range of construction equipment, such as excavators, bulldozers, cranes, and loaders, all of which rely heavily on efficient heat management systems to maintain optimal performance.

The harsh operating conditions typically encountered in construction sites have necessitated the use of more robust and efficient heat exchangers. These components are crucial for maintaining the temperature of hydraulic fluids, engine coolants, and transmission oils within safe operating ranges. As construction equipment is often subjected to extended periods of operation under heavy loads, the demand for high-performance heat exchangers has been intensified. Furthermore, stringent emission regulations imposed on off-highway vehicles, including construction equipment, have been driving the need for more advanced engine cooling systems. Heat exchangers play a vital role in ensuring that these machines comply with emission standards while maintaining optimal engine performance. This regulatory pressure has been compelling manufacturers to invest in more sophisticated thermal management solutions.

The trend towards electrification has also been observed in the construction equipment sector, albeit at a slower pace compared to on-road vehicles. Hybrid and electric construction machines are gradually being introduced to the market, creating new opportunities for specialized heat exchangers designed to manage the thermal loads of electric drivetrains and battery systems. Additionally, the focus on improving fuel efficiency and reducing operating costs in the construction industry has been driving the adoption of more efficient heat exchange systems. Advanced heat exchangers are being utilized to optimize engine performance, potentially leading to reduced fuel consumption and lower operational expenses for construction companies. The increasing complexity of modern construction equipment, with the integration of advanced electronics and hydraulic systems, has further necessitated the use of more sophisticated cooling solutions. Multi-functional heat exchangers capable of managing heat from various systems simultaneously are being increasingly in demand.

Country/Region-wise Acumens

How the Rapid Adoption of Electric Vehicles (EVs) have Impacted the Growth of the Automotive Heat Exchangers Market in Asia-Pacific?

Asia Pacific substantially dominates the automotive heat exchanger market owing to the accelerating adoption of electric vehicles (EVs). This shift towards electrification is being propelled by a combination of government initiatives, environmental concerns, and technological advancements. As the transition to EVs gains momentum, the demand for specialized cooling systems is being significantly increased. In countries such as China, Japan, and South Korea, ambitious targets for EV adoption have been set by governments. These targets are being supported by a range of policies, including subsidies, tax incentives, and infrastructure development. As a result, the production and sales of EVs are being ramped up at an unprecedented rate. This surge in EV manufacturing is directly translating into a heightened demand for advanced heat exchangers.

The cooling requirements of EVs are fundamentally different from those of traditional internal combustion engine vehicles. In EVs, heat exchangers are being utilized not only for cabin climate control but also for critical functions such as battery thermal management and power electronics cooling. The performance and longevity of EV batteries are heavily influenced by temperature control, making efficient heat exchangers an indispensable component. To meet these specialized needs, heat exchanger designs are being continuously refined and optimized. New materials and manufacturing techniques are being explored to enhance heat transfer efficiency while reducing weight and size. This innovation is being driven by the competitive landscape of the Asia Pacific automotive industry, where manufacturers are striving to differentiate their products through improved performance and range.

The growing emphasis on fast charging capabilities is further intensifying the need for advanced thermal management solutions. As charging times are reduced, the amount of heat generated during the process is being increased. In addition, more sophisticated heat exchangers are being developed to manage this thermal load effectively. Moreover, the trend towards autonomous vehicles, which is gaining traction in technologically advanced Asian markets, is adding another layer of complexity to cooling requirements. The array of sensors and computing systems in these vehicles generates significant heat, which must be efficiently dissipated to ensure optimal performance and reliability.

How do the Stringent Emissions Regulations Foster the Growth of Automotive Heat Exchangers in Europe?

Europe is anticipated to witness the fastest growth in the automotive heat exchanger market during the forecast period owing to the region's stringent emissions regulations. These regulations, which are among the most rigorous in the world, are driving a fundamental shift in automotive design and technology. As automakers strive to meet increasingly demanding standards, the role of heat exchangers in vehicle efficiency and emissions reduction is being elevated to new levels of importance. The European Union has set ambitious targets for reducing carbon dioxide emissions from new cars. These targets are being progressively tightened, with substantial fines being imposed on manufacturers who fail to comply. Every aspect of vehicle design is being scrutinized for potential efficiency gains, and thermal management has been identified as a critical area for improvement. In response to these regulatory pressures, advanced heat exchanger technologies are being developed and implemented across a wide range of vehicle types. Traditional radiators are being redesigned for enhanced efficiency, while new types of heat exchangers are being introduced to address specific challenges. For instance, exhaust gas recirculation (EGR) coolers are being widely adopted to reduce nitrogen oxide emissions in diesel engines.

The push for greater fuel efficiency is also driving innovations in heat exchanger materials and designs. Lightweight materials such as aluminum and advanced plastics are being increasingly utilized to reduce overall vehicle weight without compromising thermal performance. Additionally, compact and highly efficient heat exchangers are being developed to optimize under-hood space utilization, which is becoming increasingly constrained as more components are added to meet emissions standards. Turbocharging, which is being widely employed to improve engine efficiency, is creating new demands for heat exchangers. Charge air coolers are being refined to manage the higher temperatures associated with turbocharged engines, contributing to both performance improvements and emissions reductions.

Furthermore, the gradual shift towards electrification in Europe is introducing new thermal management challenges. While full electric vehicles are still in the minority, hybrid powertrains are being rapidly adopted as an interim solution to meet emissions targets. These hybrid systems require sophisticated cooling solutions to manage the interplay between electric motors and internal combustion engines, further driving demand for advanced heat exchangers. The focus on emissions reduction is also spurring interest in waste heat recovery systems. Technologies such as thermoelectric generators and Rankine cycle systems are being explored to convert waste heat into useful energy, with heat exchangers playing a crucial role in these systems.

Competitive Landscape

The Automotive Heat Exchanger Market continues to change and evolve with innovations and also new technologies. There is a continuous promotion of new materials and the improvement of sensors. Cloud-based delivery by companies needs to meet new requirements and demands of industries. The market share for automotive heat exchangers is an intense and consistently evolving field where new and old players are still fighting for occupation.

Some of the key players operating in the automotive heat exchanger market include:

AKG Thermal Systems, Inc.

American Industrial Heat Transfer, Inc.

Banco Products (India) Ltd.

Climetal S.L. Heat Exchanger, Clizen Inc.

Constellium SE, DENSO Corporation

G&M Radiator Mfg LtdHanon Systems

MAHLE GmbH

Latest Developments

In February 2021, MAHLE successfully announced the acquisition of Keihin to expand its product offering.

In May 2021, global automotive supplier Hanon Systems announced the completion of its acquisition of Keihin Corporation's condenser division.

Automotive Heat Exchanger Market, By Category

• Design Type:
• Plate Bar
• Tube Fin
• Vehicle Type:
• Passenger Car
• Light Commercial Vehicle
• Electric Vehicle:
• Battery Electric Vehicle (BEV)
• Hybrid Electric Vehicle (HEV)
• Off-Highway Vehicle Type:
• Agricultural Equipment
• Construction Equipment
• Application:
• Radiator
• Oil Cooler
• Region:
• North America
• Europe
• Asia Pacific
• Rest of the world

TABLE OF CONTENTS

1. INTRODUCTION OF GLOBAL AUTOMOTIVE HEAT EXCHANGER MARKET

• 1.1. Overview of the Market
• 1.2. Scope of Report
• 1.3. Assumptions

2. EXECUTIVE SUMMARY

3. RESEARCH METHODOLOGY OF VERIFIED MARKET RESEARCH

• 3.1. Data Mining
• 3.2. Validation
• 3.3. Primary Interviews
• 3.4. List of Data Sources

4. GLOBAL AUTOMOTIVE HEAT EXCHANGER MARKET OUTLOOK

• 4.1. Overview
• 4.2. Market Dynamics
  • 4.2.1. Drivers
  • 4.2.2. Restraints
  • 4.2.3. Opportunities
• 4.3. Porters Five Force Model
• 4.4. Value Chain Analysis

5. GLOBAL AUTOMOTIVE HEAT EXCHANGER MARKET, BY DESIGN TYPE

• 5.1. Overview
• 5.2. Plate Bar
• 5.3. Tube Fin

6. GLOBAL AUTOMOTIVE HEAT EXCHANGER MARKET, BY VEHICLE TYPE

• 6.1. Overview
• 6.2. Passenger Car
• 6.3. Light Commercial Vehicle

7. GLOBAL AUTOMOTIVE HEAT EXCHANGER MARKET, BY ELECTRIC VEHICLE

• 7.1. Overview
• 7.2. Battery Electric Vehicle (BEV)
• 7.3. Hybrid Electric Vehicle (HEV)

8. GLOBAL AUTOMOTIVE HEAT EXCHANGER MARKET, BY OFF-HIGHWAY VEHICLE TYPE

• 8.1. Overview
• 8.1. Agricultural Equipment
• 8.1. Construction Equipment

9. GLOBAL AUTOMOTIVE HEAT EXCHANGER MARKET, BY APPLICATION

• 9.1. Overview
• 9.2. Radiator
• 9.3. Oil Cooler

10. GLOBAL AUTOMOTIVE HEAT EXCHANGER MARKET, BY GEOGRAPHY

• 10.1. Overview
• 10.2. North America
  • 10.2.1. U.S.
  • 10.2.2. Canada
  • 10.2.3. Mexico
• 10.3. Europe
  • 10.3.1. Germany
  • 10.3.2. U.K.
  • 10.3.3. France
  • 10.3.4. Rest of Europe
• 10.4. Asia Pacific
  • 10.4.1. China
  • 10.4.2. Japan
  • 10.4.3. India
  • 10.4.4. Rest of Asia Pacific
• 10.5. Rest of the World
  • 10.5.1. Latin America
  • 10.5.2. Middle East & Africa

11. GLOBAL AUTOMOTIVE HEAT EXCHANGER MARKET COMPETITIVE LANDSCAPE

• 11.1. Overview
• 11.2. Company Market Ranking
• 11.3. Key Development Strategies

12. COMPANY PROFILES

• 12.1. AKG Thermal Systems, Inc.
  • 12.1.1. Overview
  • 12.1.2. Financial Performance
  • 12.1.3. Product Outlook
  • 12.1.4. Key Developments
• 12.2. American Industrial Heat Transfer, Inc.
  • 12.2.1. Overview
  • 12.2.2. Financial Performance
  • 12.2.3. Product Outlook
  • 12.2.4. Key Developments
• 12.3. Banco Products (India) Ltd
  • 12.3.1. Overview
  • 12.3.2. Financial Performance
  • 12.3.3. Product Outlook
  • 12.3.4. Key Developments
• 12.4. Climetal S.L. - Heat Exchanger
  • 12.4.1. Overview
  • 12.4.2. Financial Performance
  • 12.4.3. Product Outlook
  • 12.4.4. Key Developments
• 12.5. Clizen Inc.
  • 12.5.1. Overview
  • 12.5.2. Financial Performance
  • 12.5.3. Product Outlook
  • 12.5.4. Key Developments
• 12.6. Constellium SE
  • 12.6.1. Overview
  • 12.6.2. Financial Performance
  • 12.6.3. Product Outlook
  • 12.6.4. Key Developments
• 12.7. DENSO Corporation
  • 12.7.1. Overview
  • 12.7.2. Financial Performance
  • 12.7.3. Product Outlook
  • 12.7.4. Key Developments
• 12.8. G&M Radiator Mfg Ltd
  • 12.8.1. Overview
  • 12.8.2. Financial Performance
  • 12.8.3. Product Outlook
  • 12.8.4. Key Developments
• 12.9. Hanon Systems
  • 12.9.1. Overview
  • 12.9.2. Financial Performance
  • 12.9.3. Product Outlook
  • 12.9.4. Key Developments
• 12.10. MAHLE GmbH.
  • 12.10.1. Overview
  • 12.10.2. Financial Performance
  • 12.10.3. Product Outlook
  • 12.10.4. Key Developments

13. Appendix

• 13.1. Related Reports