Summary

The Global Dynamic Mechanical Analyzers Market is valued approximately at USD 169.24 million in 2023 and is anticipated to grow with a healthy growth rate of more than 5.42% over the forecast period 2024-2032. Dynamic mechanical analyzers (DMAs) are sophisticated instruments designed to study and characterize the viscoelastic properties of a wide range of materials, including polymers, composites, adhesives, foams, and films. These instruments operate by applying a controlled oscillating force or strain to the sample material while measuring its response across various temperatures and frequencies. The growing demand for dynamic mechanical analyzers is driven by their critical role in measuring mechanical properties within polymer material manufacturing industries. As polymers become increasingly integral to numerous sectors such as packaging, automotive, and aerospace, the necessity for precise measurement to ensure product quality and performance becomes paramount. Additionally, the rising application of DMAs in the food processing and pharmaceutical sectors to assess the physical properties of ingredients underscores their expanding utility. Despite their high cost limiting adoption among small-scale industries, innovations such as portable and advanced DMAs for on-site analysis are expected to boost their global adoption.
The adoption of forced resonance analyzers is gaining momentum as they provide detailed information on material properties such as storage and loss moduli. Consumables, which include sample holders, calibration standards, and gas canisters, are essential for maintaining the accuracy and reliability of DMA tests. The core equipment used in DMAs applies stress or strain to a material sample, offering insights into properties like modulus, viscosity, and glass transition temperature. The complexity of these equipment varies, with some models offering high-throughput testing or specialized tests such as creep recovery. Forced resonance analyzers, specifically, apply a known frequency and amplitude of oscillation to study a material's viscoelastic response. In contrast, free resonance analyzers excite the material and allow it to oscillate freely, measuring natural resonant frequencies and damping characteristics, providing unique insights into material behavior. Services related to DMAs, such as equipment maintenance, calibration, training, and consulting, ensure optimal performance and help interpret complex data.
Dynamic mechanical analyzers are increasingly being used in tension analysis to evaluate fundamental material properties such as tensile strength, elasticity, and ductility. In bending mode, DMAs analyze materials subjected to force at their center while supported at two points, revealing behavior critical for products that experience bending in everyday use. The shear mode, which applies force parallel to the material’s surface, is crucial for understanding the internal sliding action of molecules within materials like adhesives, films, and composites. Tension mode stretches materials, providing insights into performance under elongation, vital for fibers, films, and textiles. Torsion mode analyzes resistance to twisting forces, significant for materials used in applications with prevalent rotational forces.
Polymers and plastics are frequently tested materials in DMAs due to their versatility and wide-ranging applications. Ceramics, known for their hardness and brittleness, are tested for mechanical integrity under thermal stress. Composites, which combine strength and lightness, are analyzed to ensure their performance in industries like automotive and aerospace. Metals, fundamental to various sectors, are tested for strength, ductility, and resilience, ensuring the safety and lifespan of metal components.
In the aerospace industry, DMAs test materials for extreme conditions. The automotive sector relies on DMAs for testing materials used in vehicle manufacturing. Construction industry uses DMAs to analyze building materials. The electronics industry tests components for thermal and mechanical stability. The food and packaging industry uses DMAs to test packaging materials for elasticity and sealing properties. The pharmaceutical field uses DMAs to analyze drug formulations and delivery systems.
The Americas lead the DMA market due to significant R&D activities and the well-established aerospace sector. The Asia-Pacific region's rapid industrialization and expanding manufacturing sectors drive the demand for efficient materials testing solutions. The EMEA region's significant presence of manufacturing industries and focus on lightweight materials expand the use of DMAs. Integration of high-resolution sensors, advanced temperature control systems, and multi-frequency testing capabilities is anticipated to encourage global adoption of DMAs.
Major market player included in this report are:
TA Instruments by Waters Corporation
Anton Paar GmbH
NETZSCH-Gerätebau GmbH
Mettler-Toledo International Inc.
Bruker Corporation
PerkinElmer Inc.
Hitachi High-Tech Corporation
Shimadzu Corporation
Thermo Fisher Scientific Inc.
Illinois Tool Works Inc.
Admet, Inc.
Intertek Group plc
Freeman Technology Ltd by Micromeritics Instrument Corporation
Malvern Panalytical Ltd by Spectris Plc
C-Therm Technologies Ltd.
The detailed segments and sub-segment of the market are explained below:
By Component:
• Consumables
• Equipment
o Forced Resonance Analyzers
o Free Resonance Analyzers
• Services
By Functionality:
• DMA in Bending
• DMA in Shear
• DMA in Tension
• DMA in Torsion
By Testing Material:
• Ceramics
• Composites
• Metals
• Polymers & Plastics
By End-User:
• Aerospace
• Automotive
• Construction
• Electronics
• Food & Packaging
• Pharmaceutical
By Region: North America
• U.S.
• Canada
Europe
• UK
• Germany
• France
• Spain
• Italy
• ROE
Asia Pacific
• China
• India
• Japan
• Australia
• South Korea
• RoAPAC
Latin America
• Brazil
• Mexico
Middle East & Africa
• Saudi Arabia
• South Africa
• RoMEA
Years considered for the study are as follows:
• Historical year – 2022
• Base year – 2023
• Forecast period – 2024 to 2032
Key Takeaways:
• Market Estimates & Forecast for 10 years from 2022 to 2032.
• Annualized revenues and regional level analysis for each market segment.
• Detailed analysis of geographical landscape with Country level analysis of major regions.
• Competitive landscape with information on major players in the market.
• Analysis of key business strategies and recommendations on future market approach.
• Analysis of competitive structure of the market.
• Demand side and supply side analysis of the market.

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Table of Contents

Chapter 1. Global Dynamic Mechanical Analyzers Market Executive Summary
1.1. Global Dynamic Mechanical Analyzers Market Size & Forecast (2022-2032)
1.2. Regional Summary
1.3. Segmental Summary
1.3.1. By Component
1.3.2. By Functionality
1.3.3. By Testing Material
1.3.4. By End-User
1.4. Key Trends
1.5. Recession Impact
1.6. Analyst Recommendation & Conclusion

Chapter 2. Global Dynamic Mechanical Analyzers Market Definition and Research Assumptions
2.1. Research Objective
2.2. Market Definition
2.3. Research Assumptions
2.3.1. Inclusion & Exclusion
2.3.2. Limitations
2.3.3. Supply Side Analysis
2.3.3.1. Availability
2.3.3.2. Infrastructure
2.3.3.3. Regulatory Environment
2.3.3.4. Market Competition
2.3.3.5. Economic Viability (Consumer’s Perspective)
2.3.4. Demand Side Analysis
2.3.4.1. Regulatory frameworks
2.3.4.2. Technological Advancements
2.3.4.3. Environmental Considerations
2.3.4.4. Consumer Awareness & Acceptance
2.4. Estimation Methodology
2.5. Years Considered for the Study
2.6. Currency Conversion Rates

Chapter 3. Global Dynamic Mechanical Analyzers Market Dynamics
3.1. Market Drivers
3.1.1. Increasing demand for precise measurement in polymer material manufacturing
3.1.2. Rising application in food processing and pharmaceutical sectors
3.2. Market Challenges
3.2.1. High cost of dynamic mechanical analyzers
3.2.2. Limited adoption across small-scale industries
3.3. Market Opportunities
3.3.1. Introduction of portable and advanced DMAs
3.3.2. Collaborative initiatives for upgrading water infrastructure

Chapter 4. Global Dynamic Mechanical Analyzers Market Industry Analysis
4.1. Porter’s 5 Force Model
4.1.1. Bargaining Power of Suppliers
4.1.2. Bargaining Power of Buyers
4.1.3. Threat of New Entrants
4.1.4. Threat of Substitutes
4.1.5. Competitive Rivalry
4.1.6. Futuristic Approach to Porter’s 5 Force Model
4.1.7. Porter’s 5 Force Impact Analysis
4.2. PESTEL Analysis
4.2.1. Political
4.2.2. Economical
4.2.3. Social
4.2.4. Technological
4.2.5. Environmental
4.2.6. Legal
4.3. Top investment opportunity
4.4. Top winning strategies
4.5. Disruptive Trends
4.6. Industry Expert Perspective
4.7. Analyst Recommendation & Conclusion

Chapter 5. Global Dynamic Mechanical Analyzers Market Size & Forecasts by Component 2022-2032
5.1. Segment Dashboard
5.2. Global Dynamic Mechanical Analyzers Market: Component Revenue Trend Analysis, 2022 & 2032 (USD Million)
5.2.1. Consumables
5.2.2. Equipment
5.2.3. Forced Resonance Analyzers
5.2.4. Free Resonance Analyzers
5.2.5. Services

Chapter 6. Global Dynamic Mechanical Analyzers Market Size & Forecasts by Functionality 2022-2032
6.1. Segment Dashboard
6.2. Global Dynamic Mechanical Analyzers Market: Functionality Revenue Trend Analysis, 2022 & 2032 (USD Million)
6.2.1. DMA in Bending
6.2.2. DMA in Shear
6.2.3. DMA in Tension
6.2.4. DMA in Torsion

Chapter 7. Global Dynamic Mechanical Analyzers Market Size & Forecasts by Testing Material 2022-2032
7.1. Segment Dashboard
7.2. Global Dynamic Mechanical Analyzers Market: Testing Material Revenue Trend Analysis, 2022 & 2032 (USD Million)
7.2.1. Ceramics
7.2.2. Composites
7.2.3. Metals
7.2.4. Polymers & Plastics

Chapter 8. Global Dynamic Mechanical Analyzers Market Size & Forecasts by End-User 2022-2032
8.1. Segment Dashboard
8.2. Global Dynamic Mechanical Analyzers Market: End-User Revenue Trend Analysis, 2022 & 2032 (USD Million)
8.2.1. Aerospace
8.2.2. Automotive
8.2.3. Construction
8.2.4. Electronics
8.2.5. Food & Packaging
8.2.6. Pharmaceutical

Chapter 9. Global Dynamic Mechanical Analyzers Market Size & Forecasts by Region 2022-2032
9.1. North America Dynamic Mechanical Analyzers Market
9.1.1. U.S. Dynamic Mechanical Analyzers Market
9.1.1.1. Component breakdown size & forecasts, 2022-2032
9.1.1.2. Functionality breakdown size & forecasts, 2022-2032
9.1.1.3. Testing Material breakdown size & forecasts, 2022-2032
9.1.1.4. End-User breakdown size & forecasts, 2022-2032
9.1.2. Canada Dynamic Mechanical Analyzers Market
9.2. Europe Dynamic Mechanical Analyzers Market
9.2.1. U.K. Dynamic Mechanical Analyzers Market
9.2.2. Germany Dynamic Mechanical Analyzers Market
9.2.3. France Dynamic Mechanical Analyzers Market
9.2.4. Spain Dynamic Mechanical Analyzers Market
9.2.5. Italy Dynamic Mechanical Analyzers Market
9.2.6. Rest of Europe Dynamic Mechanical Analyzers Market
9.3. Asia-Pacific Dynamic Mechanical Analyzers Market
9.3.1. China Dynamic Mechanical Analyzers Market
9.3.2. India Dynamic Mechanical Analyzers Market
9.3.3. Japan Dynamic Mechanical Analyzers Market
9.3.4. Australia Dynamic Mechanical Analyzers Market
9.3.5. South Korea Dynamic Mechanical Analyzers Market
9.3.6. Rest of Asia Pacific Dynamic Mechanical Analyzers Market
9.4. Latin America Dynamic Mechanical Analyzers Market
9.4.1. Brazil Dynamic Mechanical Analyzers Market
9.4.2. Mexico Dynamic Mechanical Analyzers Market
9.4.3. Rest of Latin America Dynamic Mechanical Analyzers Market
9.5. Middle East & Africa Dynamic Mechanical Analyzers Market
9.5.1. Saudi Arabia Dynamic Mechanical Analyzers Market
9.5.2. South Africa Dynamic Mechanical Analyzers Market
9.5.3. Rest of Middle East & Africa Dynamic Mechanical Analyzers Market

Chapter 10. Competitive Intelligence
10.1. Key Company SWOT Analysis
10.1.1. TA Instruments by Waters Corporation
10.1.2. Anton Paar GmbH
10.1.3. NETZSCH-Gerätebau GmbH
10.2. Top Market Strategies
10.3. Company Profiles
10.3.1. TA Instruments by Waters Corporation
10.3.1.1. Key Information
10.3.1.2. Overview
10.3.1.3. Financial (Subject to Data Availability)
10.3.1.4. Product Summary
10.3.1.5. Market Strategies
10.3.2. Anton Paar GmbH
10.3.3. NETZSCH-Gerätebau GmbH
10.3.4. Mettler-Toledo International Inc.
10.3.5. Bruker Corporation
10.3.6. PerkinElmer Inc.
10.3.7. Hitachi High-Tech Corporation
10.3.8. Shimadzu Corporation
10.3.9. Thermo Fisher Scientific Inc.
10.3.10. Illinois Tool Works Inc.
10.3.11. Admet, Inc.
10.3.12. Intertek Group plc
10.3.13. Freeman Technology Ltd by Micromeritics Instrument Corporation
10.3.14. Malvern Panalytical Ltd by Spectris Plc
10.3.15. C-Therm Technologies Ltd.

Chapter 11. Research Process
11.1. Research Process
11.1.1. Data Mining
11.1.2. Analysis
11.1.3. Market Estimation
11.1.4. Validation
11.1.5. Publishing
11.2. Research Attributes