초전도 자기에너지 저장 시장 - 세계 산업 규모, 점유율, 동향, 기회, 예측 : 유형별, 용도별, 지역별, 경쟁(2019-2029년)

Global Superconducting Magnetic Energy Storage Market was valued at USD 67 Million in 2023 and is anticipated to project robust growth in the forecast period with a CAGR of 15.22% through 2029.

The Superconducting Magnetic Energy Storage (SMES) market pertains to the sector involved in the development, production, and deployment of energy storage systems that utilize superconducting materials to store and release electrical energy. SMES systems leverage the unique properties of superconductors, which have zero electrical resistance at cryogenic temperatures, to achieve high-efficiency energy storage with rapid charge and discharge capabilities.

The market encompasses various applications including grid stabilization, load leveling, and backup power systems. SMES technology is particularly valued for its ability to deliver instantaneous power, making it ideal for stabilizing electrical grids and supporting renewable energy integration. Key players in this market include manufacturers of superconducting materials, cryogenic cooling systems, and energy management systems.

Growth in the SMES market is driven by increasing demand for reliable and efficient energy storage solutions, advancements in superconducting materials, and a rising focus on enhancing grid stability and energy resilience. The market dynamics are influenced by technological innovations, regulatory support for clean energy, and the need for robust energy infrastructure. As the technology matures, it is expected to play a crucial role in the future energy landscape.

Key Market Drivers

Increasing Demand for Grid Stability and Reliability

The global Superconducting Magnetic Energy Storage (SMES) market is significantly driven by the escalating demand for grid stability and reliability. As the world becomes increasingly dependent on electricity for everyday activities and industrial processes, the need for a stable and reliable power grid has never been more critical. Traditional power grids are often vulnerable to fluctuations in supply and demand, which can lead to disruptions and outages. SMES systems offer a solution to these challenges by providing rapid response capabilities to stabilize the grid.

SMES technology can store energy and release it instantaneously, making it exceptionally effective in addressing short-term fluctuations in electricity supply and demand. This capability is particularly valuable in modern grids, which are increasingly integrating intermittent renewable energy sources such as wind and solar power. These sources can be unpredictable and vary in output, creating challenges for grid operators to maintain consistent supply. By deploying SMES systems, grid operators can smooth out these fluctuations, ensuring a steady and reliable power supply.

The growth of smart grid technologies and the increasing complexity of electrical networks necessitate advanced solutions for grid management. SMES systems enhance grid stability by providing ancillary services such as frequency regulation and voltage support. This is essential for maintaining the operational integrity of modern grids, which are becoming more interconnected and sophisticated. As governments and utilities invest in grid modernization and resilience, the demand for SMES technology is expected to rise, driving market growth.

Advancements in Superconducting Materials

Advancements in superconducting materials are a major driver of the global SMES market. Superconductors are materials that, at very low temperatures, exhibit zero electrical resistance and the ability to expel magnetic fields. These properties make them ideal for use in SMES systems, where efficient energy storage and rapid discharge capabilities are essential. Over the years, significant progress has been made in developing new superconducting materials and improving the performance of existing ones.

High-temperature superconductors (HTS) are a notable advancement in this field. Unlike conventional superconductors, which require extremely low temperatures close to absolute zero, HTS materials operate at relatively higher temperatures. This reduces the cost and complexity of the cooling systems required to maintain superconductivity. The development of HTS materials has expanded the practical applications of SMES systems, making them more commercially viable.

Research into new superconducting compounds and fabrication techniques continues to enhance the efficiency and performance of SMES systems. These advancements are leading to increased energy storage densities, improved reliability, and reduced costs. As superconducting materials become more advanced and accessible, their adoption in SMES systems is expected to grow, further driving market expansion.

Key Market Challenges

High Costs and Economic Viability

One of the primary challenges facing the global Superconducting Magnetic Energy Storage (SMES) market is the high cost associated with the technology. SMES systems require sophisticated superconducting materials, cryogenic cooling systems, and advanced infrastructure, all of which contribute to their overall expense. The costs of superconducting materials, especially high-temperature superconductors (HTS), remain relatively high due to the complexity of their production and the need for rare and expensive elements.

The cryogenic cooling systems necessary to maintain superconductors at their operational temperatures also add to the cost. These cooling systems typically involve the use of liquid helium or other cryogens, which are not only expensive but also require ongoing maintenance and operational management. The combination of these factors results in a high initial capital investment for SMES systems, which can be a barrier to their widespread adoption, particularly in markets where cost constraints are a significant concern.

Economic viability is further challenged by the fact that SMES systems, while providing rapid response and high efficiency, may not always offer the same cost-effectiveness as other energy storage technologies such as lithium-ion batteries or pumped hydro storage. These alternative technologies have achieved significant cost reductions over time due to advancements in technology and economies of scale. In contrast, the SMES market is still in a phase where costs need to decrease further to compete effectively with these more established alternatives.

To address these challenges, ongoing research and development efforts are focused on reducing the cost of superconducting materials and improving the efficiency of cooling systems. Innovations in material science, such as the development of more cost-effective HTS materials, and advancements in cooling technologies could play a crucial role in making SMES systems more economically viable in the future. However, until these cost barriers are overcome, the widespread adoption of SMES technology may remain limited.

Technical and Operational Complexity

Another significant challenge for the global SMES market is the technical and operational complexity of the systems. SMES technology involves intricate components and processes that require precise engineering and sophisticated management. The core of an SMES system is the superconducting magnet, which needs to be maintained at extremely low temperatures to remain in a superconducting state. Achieving and maintaining these temperatures involves complex cryogenic cooling systems, which add to the operational complexity and require specialized knowledge and skills to manage effectively.

The technical challenges extend beyond cooling systems to the design and integration of the SMES components. The superconducting magnets need to be carefully engineered to handle high currents and magnetic fields without experiencing quenching, a phenomenon where the superconducting state is lost, leading to a sudden increase in resistance and heat generation. This requires advanced materials and precise engineering to ensure the reliability and safety of the system.

Integrating SMES systems into existing power grids can be challenging. The technology needs to be compatible with the grid's operational requirements, including voltage regulation, frequency control, and response to sudden changes in load. This requires sophisticated control systems and software to manage the SMES system effectively and to ensure it provides the intended benefits without disrupting grid operations.

The complexity of SMES systems also implies higher operational and maintenance requirements. Skilled personnel are needed to manage the systems, perform routine maintenance, and address any technical issues that may arise. This adds to the overall operational costs and complexity of deploying SMES technology.

Efforts to simplify the design and operation of SMES systems, as well as advancements in automation and control technologies, are crucial for addressing these challenges. Research and development aimed at reducing the technical complexity and improving the ease of integration and operation will be essential for the broader adoption of SMES technology in the future.

Key Market Trends

Growing Adoption of High-Temperature Superconductors (HTS)

A prominent trend in the global Superconducting Magnetic Energy Storage (SMES) market is the increasing adoption of high-temperature superconductors (HTS). Traditionally, superconducting materials required extremely low temperatures to maintain their superconducting state, necessitating the use of expensive and complex cryogenic cooling systems. However, HTS materials operate at relatively higher temperatures, which significantly reduces the cooling requirements and associated costs.

The development and commercialization of HTS have been driven by advancements in material science and manufacturing technologies. HTS materials such as yttrium barium copper oxide (YBCO) and bismuth strontium calcium copper oxide (BSCCO) have demonstrated superior performance characteristics, including higher critical current densities and magnetic field capabilities. This has made them increasingly attractive for SMES applications, where efficient energy storage and rapid response are critical.

The adoption of HTS is expected to continue growing as the technology matures and becomes more cost-effective. Enhanced performance characteristics of HTS materials allow for the design of smaller and more efficient SMES systems, which can be integrated into a wider range of applications, from grid stabilization to renewable energy support. Additionally, the reduced cooling requirements of HTS systems lead to lower operational costs, further boosting their attractiveness.

The increasing focus on reducing the costs and improving the efficiency of HTS materials is likely to drive further innovation and expansion in the SMES market. As HTS technology continues to evolve, it is anticipated that its adoption will become more widespread, contributing to the growth and development of the global SMES market.

Integration with Renewable Energy Sources

Another key trend in the global SMES market is the growing integration of SMES systems with renewable energy sources. The rise in renewable energy generation, such as wind and solar power, presents challenges related to the variability and intermittency of these sources. SMES systems offer a solution by providing rapid energy storage and discharge capabilities that can help balance supply and demand fluctuations associated with renewable energy.

SMES technology is particularly well-suited for applications that require high power density and quick response times. By integrating SMES systems with renewable energy installations, operators can smooth out the fluctuations in power output, enhance grid stability, and improve the overall efficiency of renewable energy systems. This integration helps address the challenge of intermittency, making renewable energy sources more reliable and viable.

The focus on transitioning to clean energy and reducing carbon emissions has led to increased investments in technologies that support renewable energy integration. SMES systems are increasingly being deployed in conjunction with renewable energy projects to provide ancillary services such as frequency regulation and voltage support. This trend is driven by both regulatory policies and market incentives that promote the use of advanced energy storage solutions to support renewable energy goals.

The trend towards integrating SMES with renewable energy sources is expected to continue as countries and regions strive to meet their renewable energy targets and enhance the resilience of their energy systems. The synergy between SMES technology and renewable energy generation is likely to drive further growth and innovation in the SMES market.

Advancements in System Design and Efficiency

Advancements in system design and efficiency represent a significant trend in the global SMES market. Ongoing research and development efforts are focused on improving the performance, reliability, and cost-effectiveness of SMES systems. Innovations in system design, including enhancements in superconducting magnets, cryogenic cooling systems, and control technologies, are driving these advancements.

New design approaches are being explored to optimize the energy storage density and efficiency of SMES systems. For instance, improvements in magnet design and material processing techniques are leading to more compact and powerful superconducting magnets. These advancements contribute to higher energy storage capacities and more efficient operation of SMES systems.

The development of advanced control systems and software is enhancing the functionality and performance of SMES technology. These systems enable more precise management of energy storage and discharge processes, leading to better integration with grid operations and improved overall efficiency.

The focus on increasing efficiency and reducing operational costs is driving the development of innovative cooling technologies and more effective thermal management solutions. These advancements help to lower the cost of maintaining superconducting temperatures and improve the economic viability of SMES systems.

As technology continues to advance, the trend towards more efficient and cost-effective SMES systems is expected to drive market growth and adoption. Innovations in system design and efficiency will play a crucial role in shaping the future of the SMES market and expanding its applications.

Segmental Insights

Type Insights

The High-Temperature segment held the largest Market share in 2023. High Temperature materials operate at relatively higher temperatures, compared to Low Temperature materials which require temperatures close to absolute zero. The higher operating temperatures of high temperature semiconductor (HTS) materials reduce the need for complex and costly cryogenic cooling systems. This lowers the operational and maintenance costs associated with SMES systems, making HTS-based solutions more economically viable.

Recent advancements in HTS technology have significantly enhanced its performance characteristics. Materials such as yttrium barium copper oxide (YBCO) and bismuth strontium calcium copper oxide (BSCCO) exhibit high critical current densities and strong magnetic field capabilities. These improvements have led to more efficient and powerful SMES systems, capable of handling larger energy storage and faster discharge rates. As a result, HTS systems are increasingly favored for applications requiring high performance and rapid response.

The reduction in cooling requirements not only lowers costs but also simplifies system design and integration. HTS systems are more versatile and easier to deploy in various settings, including urban environments and industrial applications, compared to Low Temperature Semiconductor (LTS) systems which require extensive and expensive cooling infrastructure.

As HTS technology continues to mature, its advantages over LTS systems become more pronounced. The decreasing costs and improved performance of HTS materials are driving wider adoption and acceptance in the market. Supportive regulatory policies and increased investment in research and development further bolster the growth of HTS-based SMES systems.

Regional Insights

North America region held the largest market share in 2023. North America, particularly the United States, is a hub for advanced research and development in superconducting technologies. Major research institutions, such as those funded by the Department of Energy (DOE) and other federal agencies, drive innovation in SMES technology. This emphasis on R&D fosters technological advancements and commercializes new superconducting materials and systems, giving North America a competitive edge in the SMES market.

The region benefits from substantial investment and funding opportunities dedicated to energy storage technologies. Government grants, subsidies, and private sector investments support the development and deployment of SMES systems. The U.S. DOE and various state-level initiatives provide financial incentives and support for projects aimed at enhancing grid stability and integrating renewable energy sources, further boosting market growth.

North America has been at the forefront of modernizing its electrical grid infrastructure. As part of these modernization efforts, there is a significant focus on adopting advanced energy storage solutions like SMES to enhance grid reliability and resilience. The region's emphasis on upgrading grid infrastructure to support renewable energy integration creates a favorable environment for SMES technology adoption.

Major players in the SMES market, including technology providers and energy companies, are based in North America. These companies actively engage in deploying and commercializing SMES systems, leveraging their extensive industry expertise and established networks to drive market growth.

North America's energy market requires high-performance storage solutions to address issues such as grid stability, frequency regulation, and load leveling. SMES systems, with their rapid response capabilities and high efficiency, are well-suited to meet these demands.

Key Market Players

• Schneider Electric SE
• Siemens AG
• American Superconductor Corporation
• Bruker Corporation
• Fujikura Ltd.
• General Electric Company
• Hitachi, Ltd.
• Asahi Kasei Corporation
• Konecranes Plc
• Linde plc
• Magnetics (Division of Spang & Company)
• Mitsubishi Electric Corporation

Report Scope:

In this report, the Global Superconducting Magnetic Energy Storage Market has been segmented into the following categories, in addition to the industry trends which have also been detailed below:

Superconducting Magnetic Energy Storage Market, By Type:

• Low-Temperature
• High-Temperature

Superconducting Magnetic Energy Storage Market, By Application:

• Power System
• Industrial Use
• Research Institution
• Others

Superconducting Magnetic Energy Storage Market, By Region:

• North America
  • United States
  • Canada
  • Mexico
• Europe
  • France
  • United Kingdom
  • Italy
  • Germany
  • Spain
• Asia-Pacific
  • China
  • India
  • Japan
  • Australia
  • South Korea
• South America
  • Brazil
  • Argentina
  • Colombia
• Middle East & Africa
  • South Africa
  • Saudi Arabia
  • UAE
  • Kuwait
  • Turkey

Competitive Landscape

Company Profiles: Detailed analysis of the major companies present in the Global Superconducting Magnetic Energy Storage Market.

Available Customizations:

Global Superconducting Magnetic Energy Storage Market report with the given Market data, TechSci Research offers customizations according to a company's specific needs. The following customization options are available for the report:

Company Information

• Detailed analysis and profiling of additional Market players (up to five).

Table of Contents

1. Product Overview

• 1.1. Market Definition
• 1.2. Scope of the Market
  • 1.2.1. Markets Covered
  • 1.2.2. Years Considered for Study
• 1.3. Key Market Segmentations

2. Research Methodology

• 2.1. Objective of the Study
• 2.2. Baseline Methodology
• 2.3. Formulation of the Scope
• 2.4. Assumptions and Limitations
• 2.5. Sources of Research
  • 2.5.1. Secondary Research
  • 2.5.2. Primary Research
• 2.6. Approach for the Market Study
  • 2.6.1. The Bottom-Up Approach
  • 2.6.2. The Top-Down Approach
• 2.7. Methodology Followed for Calculation of Market Size & Market Shares
• 2.8. Forecasting Methodology
  • 2.8.1. Data Triangulation & Validation

3. Executive Summary

4. Voice of Customer

5. Global Superconducting Magnetic Energy Storage Market Outlook

• 5.1. Market Size & Forecast
  • 5.1.1. By Value
• 5.2. Market Share & Forecast
  • 5.2.1. By Type (Low-Temperature, High-Temperature)
  • 5.2.2. By Application (Power System, Industrial Use, Research Institution, Others)
  • 5.2.3. By Region (Asia Pacific, North America, South America, Middle East &Africa, Europe)
  • 5.2.4. By Company (2023)
• 5.3. Market Map

6. North America Superconducting Magnetic Energy Storage Market Outlook

• 6.1. Market Size & Forecast
  • 6.1.1. By Value
• 6.2. Market Share & Forecast
  • 6.2.1. By Type
  • 6.2.2. By Application
  • 6.2.3. By Country
• 6.3. North America: Country Analysis
  • 6.3.1. United States Superconducting Magnetic Energy Storage Market Outlook
    • 6.3.1.1. Market Size & Forecast
      • 6.3.1.1.1. By Value
    • 6.3.1.2. Market Share & Forecast
      • 6.3.1.2.1. By Type
      • 6.3.1.2.2. By Application
  • 6.3.2. Canada Superconducting Magnetic Energy Storage Market Outlook
    • 6.3.2.1. Market Size & Forecast
      • 6.3.2.1.1. By Value
    • 6.3.2.2. Market Share & Forecast
      • 6.3.2.2.1. By Type
      • 6.3.2.2.2. By Application
  • 6.3.3. Mexico Superconducting Magnetic Energy Storage Market Outlook
    • 6.3.3.1. Market Size & Forecast
      • 6.3.3.1.1. By Value
    • 6.3.3.2. Market Share & Forecast
      • 6.3.3.2.1. By Type
      • 6.3.3.2.2. By Application

7. Europe Superconducting Magnetic Energy Storage Market Outlook

• 7.1. Market Size & Forecast
  • 7.1.1. By Value
• 7.2. Market Share & Forecast
  • 7.2.1. By Type
  • 7.2.2. By Application
  • 7.2.3. By Country
• 7.3. Europe: Country Analysis
  • 7.3.1. Germany Superconducting Magnetic Energy Storage Market Outlook
    • 7.3.1.1. Market Size & Forecast
      • 7.3.1.1.1. By Value
    • 7.3.1.2. Market Share & Forecast
      • 7.3.1.2.1. By Type
      • 7.3.1.2.2. By Application
  • 7.3.2. United Kingdom Superconducting Magnetic Energy Storage Market Outlook
    • 7.3.2.1. Market Size & Forecast
      • 7.3.2.1.1. By Value
    • 7.3.2.2. Market Share & Forecast
      • 7.3.2.2.1. By Type
      • 7.3.2.2.2. By Application
  • 7.3.3. Italy Superconducting Magnetic Energy Storage Market Outlook
    • 7.3.3.1. Market Size & Forecast
      • 7.3.3.1.1. By Value
    • 7.3.3.2. Market Share & Forecast
      • 7.3.3.2.1. By Type
      • 7.3.3.2.2. By Application
  • 7.3.4. France Superconducting Magnetic Energy Storage Market Outlook
    • 7.3.4.1. Market Size & Forecast
      • 7.3.4.1.1. By Value
    • 7.3.4.2. Market Share & Forecast
      • 7.3.4.2.1. By Type
      • 7.3.4.2.2. By Application
  • 7.3.5. Spain Superconducting Magnetic Energy Storage Market Outlook
    • 7.3.5.1. Market Size & Forecast
      • 7.3.5.1.1. By Value
    • 7.3.5.2. Market Share & Forecast
      • 7.3.5.2.1. By Type
      • 7.3.5.2.2. By Application

8. Asia-Pacific Superconducting Magnetic Energy Storage Market Outlook

• 8.1. Market Size & Forecast
  • 8.1.1. By Value
• 8.2. Market Share & Forecast
  • 8.2.1. By Type
  • 8.2.2. By Application
  • 8.2.3. By Country
• 8.3. Asia-Pacific: Country Analysis
  • 8.3.1. China Superconducting Magnetic Energy Storage Market Outlook
    • 8.3.1.1. Market Size & Forecast
      • 8.3.1.1.1. By Value
    • 8.3.1.2. Market Share & Forecast
      • 8.3.1.2.1. By Type
      • 8.3.1.2.2. By Application
  • 8.3.2. India Superconducting Magnetic Energy Storage Market Outlook
    • 8.3.2.1. Market Size & Forecast
      • 8.3.2.1.1. By Value
    • 8.3.2.2. Market Share & Forecast
      • 8.3.2.2.1. By Type
      • 8.3.2.2.2. By Application
  • 8.3.3. Japan Superconducting Magnetic Energy Storage Market Outlook
    • 8.3.3.1. Market Size & Forecast
      • 8.3.3.1.1. By Value
    • 8.3.3.2. Market Share & Forecast
      • 8.3.3.2.1. By Type
      • 8.3.3.2.2. By Application
  • 8.3.4. South Korea Superconducting Magnetic Energy Storage Market Outlook
    • 8.3.4.1. Market Size & Forecast
      • 8.3.4.1.1. By Value
    • 8.3.4.2. Market Share & Forecast
      • 8.3.4.2.1. By Type
      • 8.3.4.2.2. By Application
  • 8.3.5. Australia Superconducting Magnetic Energy Storage Market Outlook
    • 8.3.5.1. Market Size & Forecast
      • 8.3.5.1.1. By Value
    • 8.3.5.2. Market Share & Forecast
      • 8.3.5.2.1. By Type
      • 8.3.5.2.2. By Application

9. South America Superconducting Magnetic Energy Storage Market Outlook

• 9.1. Market Size & Forecast
  • 9.1.1. By Value
• 9.2. Market Share & Forecast
  • 9.2.1. By Type
  • 9.2.2. By Application
  • 9.2.3. By Country
• 9.3. South America: Country Analysis
  • 9.3.1. Brazil Superconducting Magnetic Energy Storage Market Outlook
    • 9.3.1.1. Market Size & Forecast
      • 9.3.1.1.1. By Value
    • 9.3.1.2. Market Share & Forecast
      • 9.3.1.2.1. By Type
      • 9.3.1.2.2. By Application
  • 9.3.2. Argentina Superconducting Magnetic Energy Storage Market Outlook
    • 9.3.2.1. Market Size & Forecast
      • 9.3.2.1.1. By Value
    • 9.3.2.2. Market Share & Forecast
      • 9.3.2.2.1. By Type
      • 9.3.2.2.2. By Application
  • 9.3.3. Colombia Superconducting Magnetic Energy Storage Market Outlook
    • 9.3.3.1. Market Size & Forecast
      • 9.3.3.1.1. By Value
    • 9.3.3.2. Market Share & Forecast
      • 9.3.3.2.1. By Type
      • 9.3.3.2.2. By Application

10. Middle East and Africa Superconducting Magnetic Energy Storage Market Outlook

• 10.1. Market Size & Forecast
  • 10.1.1. By Value
• 10.2. Market Share & Forecast
  • 10.2.1. By Type
  • 10.2.2. By Application
  • 10.2.3. By Country
• 10.3. Middle East and Africa: Country Analysis
  • 10.3.1. South Africa Superconducting Magnetic Energy Storage Market Outlook
    • 10.3.1.1. Market Size & Forecast
      • 10.3.1.1.1. By Value
    • 10.3.1.2. Market Share & Forecast
      • 10.3.1.2.1. By Type
      • 10.3.1.2.2. By Application
  • 10.3.2. Saudi Arabia Superconducting Magnetic Energy Storage Market Outlook
    • 10.3.2.1. Market Size & Forecast
      • 10.3.2.1.1. By Value
    • 10.3.2.2. Market Share & Forecast
      • 10.3.2.2.1. By Type
      • 10.3.2.2.2. By Application
  • 10.3.3. UAE Superconducting Magnetic Energy Storage Market Outlook
    • 10.3.3.1. Market Size & Forecast
      • 10.3.3.1.1. By Value
    • 10.3.3.2. Market Share & Forecast
      • 10.3.3.2.1. By Type
      • 10.3.3.2.2. By Application
  • 10.3.4. Kuwait Superconducting Magnetic Energy Storage Market Outlook
    • 10.3.4.1. Market Size & Forecast
      • 10.3.4.1.1. By Value
    • 10.3.4.2. Market Share & Forecast
      • 10.3.4.2.1. By Type
      • 10.3.4.2.2. By Application
  • 10.3.5. Turkey Superconducting Magnetic Energy Storage Market Outlook
    • 10.3.5.1. Market Size & Forecast
      • 10.3.5.1.1. By Value
    • 10.3.5.2. Market Share & Forecast
      • 10.3.5.2.1. By Type
      • 10.3.5.2.2. By Application

11. Market Dynamics

• 11.1. Drivers
• 11.2. Challenges

12. Market Trends & Developments

13. Company Profiles

• 13.1. Schneider Electric SE
  • 13.1.1. Business Overview
  • 13.1.2. Key Revenue and Financials
  • 13.1.3. Recent Developments
  • 13.1.4. Key Personnel/Key Contact Person
  • 13.1.5. Key Product/Services Offered
• 13.2. Siemens AG
  • 13.2.1. Business Overview
  • 13.2.2. Key Revenue and Financials
  • 13.2.3. Recent Developments
  • 13.2.4. Key Personnel/Key Contact Person
  • 13.2.5. Key Product/Services Offered
• 13.3. American Superconductor Corporation
  • 13.3.1. Business Overview
  • 13.3.2. Key Revenue and Financials
  • 13.3.3. Recent Developments
  • 13.3.4. Key Personnel/Key Contact Person
  • 13.3.5. Key Product/Services Offered
• 13.4. Bruker Corporation
  • 13.4.1. Business Overview
  • 13.4.2. Key Revenue and Financials
  • 13.4.3. Recent Developments
  • 13.4.4. Key Personnel/Key Contact Person
  • 13.4.5. Key Product/Services Offered
• 13.5. Fujikura Ltd.
  • 13.5.1. Business Overview
  • 13.5.2. Key Revenue and Financials
  • 13.5.3. Recent Developments
  • 13.5.4. Key Personnel/Key Contact Person
  • 13.5.5. Key Product/Services Offered
• 13.6. General Electric Company
  • 13.6.1. Business Overview
  • 13.6.2. Key Revenue and Financials
  • 13.6.3. Recent Developments
  • 13.6.4. Key Personnel/Key Contact Person
  • 13.6.5. Key Product/Services Offered
• 13.7. Hitachi, Ltd.
  • 13.7.1. Business Overview
  • 13.7.2. Key Revenue and Financials
  • 13.7.3. Recent Developments
  • 13.7.4. Key Personnel/Key Contact Person
  • 13.7.5. Key Product/Services Offered
• 13.8. Asahi Kasei Corporation
  • 13.8.1. Business Overview
  • 13.8.2. Key Revenue and Financials
  • 13.8.3. Recent Developments
  • 13.8.4. Key Personnel/Key Contact Person
  • 13.8.5. Key Product/Services Offered
• 13.9. Konecranes Plc
  • 13.9.1. Business Overview
  • 13.9.2. Key Revenue and Financials
  • 13.9.3. Recent Developments
  • 13.9.4. Key Personnel/Key Contact Person
  • 13.9.5. Key Product/Services Offered
• 13.10. Linde plc
  • 13.10.1. Business Overview
  • 13.10.2. Key Revenue and Financials
  • 13.10.3. Recent Developments
  • 13.10.4. Key Personnel/Key Contact Person
  • 13.10.5. Key Product/Services Offered
• 13.11. Magnetics (Division of Spang & Company)
  • 13.11.1. Business Overview
  • 13.11.2. Key Revenue and Financials
  • 13.11.3. Recent Developments
  • 13.11.4. Key Personnel/Key Contact Person
  • 13.11.5. Key Product/Services Offered
• 13.12. Mitsubishi Electric Corporation
  • 13.12.1. Business Overview
  • 13.12.2. Key Revenue and Financials
  • 13.12.3. Recent Developments
  • 13.12.4. Key Personnel/Key Contact Person
  • 13.12.5. Key Product/Services Offered

14. Strategic Recommendations

15. About Us & Disclaimer