1 Scope of the Report
1.1 Market Introduction
1.2 Years Considered
1.3 Research Objectives
1.4 Market Research Methodology
1.5 Research Process and Data Source
1.6 Economic Indicators
1.7 Currency Considered
1.8 Market Estimation Caveats
2 Executive Summary
2.1 World Market Overview
2.1.1 Global Ionizing Radiation Monitoring Equipment Annual Sales 2018-2029
2.1.2 World Current & Future Analysis for Ionizing Radiation Monitoring Equipment by Geographic Region, 2018, 2022 & 2029
2.1.3 World Current & Future Analysis for Ionizing Radiation Monitoring Equipment by Country/Region, 2018, 2022 & 2029
2.2 Ionizing Radiation Monitoring Equipment Segment by Type
2.2.1 Personal Dose Alarm
2.2.2 αβγ Surface Contamination Measuring Instrument
2.2.3 χ/γ Dosimeter
2.2.4 Others
2.3 Ionizing Radiation Monitoring Equipment Sales by Type
2.3.1 Global Ionizing Radiation Monitoring Equipment Sales Market Share by Type (2018-2023)
2.3.2 Global Ionizing Radiation Monitoring Equipment Revenue and Market Share by Type (2018-2023)
2.3.3 Global Ionizing Radiation Monitoring Equipment Sale Price by Type (2018-2023)
2.4 Ionizing Radiation Monitoring Equipment Segment by Application
2.4.1 Environmental Monitoring
2.4.2 Health and Epidemic Prevention
2.4.3 Radiology
2.4.4 Address Census
2.4.5 Others
2.5 Ionizing Radiation Monitoring Equipment Sales by Application
2.5.1 Global Ionizing Radiation Monitoring Equipment Sale Market Share by Application (2018-2023)
2.5.2 Global Ionizing Radiation Monitoring Equipment Revenue and Market Share by Application (2018-2023)
2.5.3 Global Ionizing Radiation Monitoring Equipment Sale Price by Application (2018-2023)
3 Global Ionizing Radiation Monitoring Equipment by Company
3.1 Global Ionizing Radiation Monitoring Equipment Breakdown Data by Company
3.1.1 Global Ionizing Radiation Monitoring Equipment Annual Sales by Company (2018-2023)
3.1.2 Global Ionizing Radiation Monitoring Equipment Sales Market Share by Company (2018-2023)
3.2 Global Ionizing Radiation Monitoring Equipment Annual Revenue by Company (2018-2023)
3.2.1 Global Ionizing Radiation Monitoring Equipment Revenue by Company (2018-2023)
3.2.2 Global Ionizing Radiation Monitoring Equipment Revenue Market Share by Company (2018-2023)
3.3 Global Ionizing Radiation Monitoring Equipment Sale Price by Company
3.4 Key Manufacturers Ionizing Radiation Monitoring Equipment Producing Area Distribution, Sales Area, Product Type
3.4.1 Key Manufacturers Ionizing Radiation Monitoring Equipment Product Location Distribution
3.4.2 Players Ionizing Radiation Monitoring Equipment Products Offered
3.5 Market Concentration Rate Analysis
3.5.1 Competition Landscape Analysis
3.5.2 Concentration Ratio (CR3, CR5 and CR10) & (2018-2023)
3.6 New Products and Potential Entrants
3.7 Mergers & Acquisitions, Expansion
4 World Historic Review for Ionizing Radiation Monitoring Equipment by Geographic Region
4.1 World Historic Ionizing Radiation Monitoring Equipment Market Size by Geographic Region (2018-2023)
4.1.1 Global Ionizing Radiation Monitoring Equipment Annual Sales by Geographic Region (2018-2023)
4.1.2 Global Ionizing Radiation Monitoring Equipment Annual Revenue by Geographic Region (2018-2023)
4.2 World Historic Ionizing Radiation Monitoring Equipment Market Size by Country/Region (2018-2023)
4.2.1 Global Ionizing Radiation Monitoring Equipment Annual Sales by Country/Region (2018-2023)
4.2.2 Global Ionizing Radiation Monitoring Equipment Annual Revenue by Country/Region (2018-2023)
4.3 Americas Ionizing Radiation Monitoring Equipment Sales Growth
4.4 APAC Ionizing Radiation Monitoring Equipment Sales Growth
4.5 Europe Ionizing Radiation Monitoring Equipment Sales Growth
4.6 Middle East & Africa Ionizing Radiation Monitoring Equipment Sales Growth
5 Americas
5.1 Americas Ionizing Radiation Monitoring Equipment Sales by Country
5.1.1 Americas Ionizing Radiation Monitoring Equipment Sales by Country (2018-2023)
5.1.2 Americas Ionizing Radiation Monitoring Equipment Revenue by Country (2018-2023)
5.2 Americas Ionizing Radiation Monitoring Equipment Sales by Type
5.3 Americas Ionizing Radiation Monitoring Equipment Sales by Application
5.4 United States
5.5 Canada
5.6 Mexico
5.7 Brazil
6 APAC
6.1 APAC Ionizing Radiation Monitoring Equipment Sales by Region
6.1.1 APAC Ionizing Radiation Monitoring Equipment Sales by Region (2018-2023)
6.1.2 APAC Ionizing Radiation Monitoring Equipment Revenue by Region (2018-2023)
6.2 APAC Ionizing Radiation Monitoring Equipment Sales by Type
6.3 APAC Ionizing Radiation Monitoring Equipment Sales by Application
6.4 China
6.5 Japan
6.6 South Korea
6.7 Southeast Asia
6.8 India
6.9 Australia
6.10 China Taiwan
7 Europe
7.1 Europe Ionizing Radiation Monitoring Equipment by Country
7.1.1 Europe Ionizing Radiation Monitoring Equipment Sales by Country (2018-2023)
7.1.2 Europe Ionizing Radiation Monitoring Equipment Revenue by Country (2018-2023)
7.2 Europe Ionizing Radiation Monitoring Equipment Sales by Type
7.3 Europe Ionizing Radiation Monitoring Equipment Sales by Application
7.4 Germany
7.5 France
7.6 UK
7.7 Italy
7.8 Russia
8 Middle East & Africa
8.1 Middle East & Africa Ionizing Radiation Monitoring Equipment by Country
8.1.1 Middle East & Africa Ionizing Radiation Monitoring Equipment Sales by Country (2018-2023)
8.1.2 Middle East & Africa Ionizing Radiation Monitoring Equipment Revenue by Country (2018-2023)
8.2 Middle East & Africa Ionizing Radiation Monitoring Equipment Sales by Type
8.3 Middle East & Africa Ionizing Radiation Monitoring Equipment Sales by Application
8.4 Egypt
8.5 South Africa
8.6 Israel
8.7 Turkey
8.8 GCC Countries
9 Market Drivers, Challenges and Trends
9.1 Market Drivers & Growth Opportunities
9.2 Market Challenges & Risks
9.3 Industry Trends
10 Manufacturing Cost Structure Analysis
10.1 Raw Material and Suppliers
10.2 Manufacturing Cost Structure Analysis of Ionizing Radiation Monitoring Equipment
10.3 Manufacturing Process Analysis of Ionizing Radiation Monitoring Equipment
10.4 Industry Chain Structure of Ionizing Radiation Monitoring Equipment
11 Marketing, Distributors and Customer
11.1 Sales Channel
11.1.1 Direct Channels
11.1.2 Indirect Channels
11.2 Ionizing Radiation Monitoring Equipment Distributors
11.3 Ionizing Radiation Monitoring Equipment Customer
12 World Forecast Review for Ionizing Radiation Monitoring Equipment by Geographic Region
12.1 Global Ionizing Radiation Monitoring Equipment Market Size Forecast by Region
12.1.1 Global Ionizing Radiation Monitoring Equipment Forecast by Region (2024-2029)
12.1.2 Global Ionizing Radiation Monitoring Equipment Annual Revenue Forecast by Region (2024-2029)
12.2 Americas Forecast by Country
12.3 APAC Forecast by Region
12.4 Europe Forecast by Country
12.5 Middle East & Africa Forecast by Country
12.6 Global Ionizing Radiation Monitoring Equipment Forecast by Type
12.7 Global Ionizing Radiation Monitoring Equipment Forecast by Application
13 Key Players Analysis
13.1 Narda
13.1.1 Narda Company Information
13.1.2 Narda Ionizing Radiation Monitoring Equipment Product Portfolios and Specifications
13.1.3 Narda Ionizing Radiation Monitoring Equipment Sales, Revenue, Price and Gross Margin (2018-2023)
13.1.4 Narda Main Business Overview
13.1.5 Narda Latest Developments
13.2 Thermo Fisher Scientific
13.2.1 Thermo Fisher Scientific Company Information
13.2.2 Thermo Fisher Scientific Ionizing Radiation Monitoring Equipment Product Portfolios and Specifications
13.2.3 Thermo Fisher Scientific Ionizing Radiation Monitoring Equipment Sales, Revenue, Price and Gross Margin (2018-2023)
13.2.4 Thermo Fisher Scientific Main Business Overview
13.2.5 Thermo Fisher Scientific Latest Developments
13.3 Mirion Technologies
13.3.1 Mirion Technologies Company Information
13.3.2 Mirion Technologies Ionizing Radiation Monitoring Equipment Product Portfolios and Specifications
13.3.3 Mirion Technologies Ionizing Radiation Monitoring Equipment Sales, Revenue, Price and Gross Margin (2018-2023)
13.3.4 Mirion Technologies Main Business Overview
13.3.5 Mirion Technologies Latest Developments
13.4 Ludlum Measurements
13.4.1 Ludlum Measurements Company Information
13.4.2 Ludlum Measurements Ionizing Radiation Monitoring Equipment Product Portfolios and Specifications
13.4.3 Ludlum Measurements Ionizing Radiation Monitoring Equipment Sales, Revenue, Price and Gross Margin (2018-2023)
13.4.4 Ludlum Measurements Main Business Overview
13.4.5 Ludlum Measurements Latest Developments
13.5 Beijing Zhongke Nuclear Safety Technology Co., Ltd.
13.5.1 Beijing Zhongke Nuclear Safety Technology Co., Ltd. Company Information
13.5.2 Beijing Zhongke Nuclear Safety Technology Co., Ltd. Ionizing Radiation Monitoring Equipment Product Portfolios and Specifications
13.5.3 Beijing Zhongke Nuclear Safety Technology Co., Ltd. Ionizing Radiation Monitoring Equipment Sales, Revenue, Price and Gross Margin (2018-2023)
13.5.4 Beijing Zhongke Nuclear Safety Technology Co., Ltd. Main Business Overview
13.5.5 Beijing Zhongke Nuclear Safety Technology Co., Ltd. Latest Developments
13.6 Fuji Electric
13.6.1 Fuji Electric Company Information
13.6.2 Fuji Electric Ionizing Radiation Monitoring Equipment Product Portfolios and Specifications
13.6.3 Fuji Electric Ionizing Radiation Monitoring Equipment Sales, Revenue, Price and Gross Margin (2018-2023)
13.6.4 Fuji Electric Main Business Overview
13.6.5 Fuji Electric Latest Developments
13.7 Canberra Industries
13.7.1 Canberra Industries Company Information
13.7.2 Canberra Industries Ionizing Radiation Monitoring Equipment Product Portfolios and Specifications
13.7.3 Canberra Industries Ionizing Radiation Monitoring Equipment Sales, Revenue, Price and Gross Margin (2018-2023)
13.7.4 Canberra Industries Main Business Overview
13.7.5 Canberra Industries Latest Developments
13.8 Berkeley Nucleonics
13.8.1 Berkeley Nucleonics Company Information
13.8.2 Berkeley Nucleonics Ionizing Radiation Monitoring Equipment Product Portfolios and Specifications
13.8.3 Berkeley Nucleonics Ionizing Radiation Monitoring Equipment Sales, Revenue, Price and Gross Margin (2018-2023)
13.8.4 Berkeley Nucleonics Main Business Overview
13.8.5 Berkeley Nucleonics Latest Developments
13.9 Atomtex
13.9.1 Atomtex Company Information
13.9.2 Atomtex Ionizing Radiation Monitoring Equipment Product Portfolios and Specifications
13.9.3 Atomtex Ionizing Radiation Monitoring Equipment Sales, Revenue, Price and Gross Margin (2018-2023)
13.9.4 Atomtex Main Business Overview
13.9.5 Atomtex Latest Developments
13.10 ShangHai Ergonomics Detecting Instrument Co., Ltd.
13.10.1 ShangHai Ergonomics Detecting Instrument Co., Ltd. Company Information
13.10.2 ShangHai Ergonomics Detecting Instrument Co., Ltd. Ionizing Radiation Monitoring Equipment Product Portfolios and Specifications
13.10.3 ShangHai Ergonomics Detecting Instrument Co., Ltd. Ionizing Radiation Monitoring Equipment Sales, Revenue, Price and Gross Margin (2018-2023)
13.10.4 ShangHai Ergonomics Detecting Instrument Co., Ltd. Main Business Overview
13.10.5 ShangHai Ergonomics Detecting Instrument Co., Ltd. Latest Developments
14 Research Findings and Conclusion
| ※参考情報 電離放射線監視装置とは、電離放射線を測定、監視、または記録するための装置を指します。この装置は、放射線にさらされる環境や物質に対して、安全性を確保するために重要な役割を果たします。電離放射線は、α線、β線、γ線、中性子線など、放射性物質や放射線源から放出される粒子や波です。電離放射線監視装置は、これらの放射線を検出し、その強度や種類を分析することで、放射線による健康被害や環境への影響を評価する手段となります。 この監視装置の特徴には、まず第一に、放射線の種類と強度を異なる方法で測定できることがあります。一般的には、ガイガーカウンター、シンチレーションカウンター、半導体検出器などが使用されます。ガイガーカウンターは、放射線を受けることで発生する電気信号をカウントし、その数から放射線の強度を測定します。一方、シンチレーションカウンターは、放射線が特定の材料に当たることで光を発生させ、その光を検出する方法です。半導体検出器は、半導体材料に放射線が当たることで生じる電気信号を計測します。 次に、これらの装置は、非常に高い感度を持っていることが特徴です。微量の放射線であっても検出可能であり、例えば、環境放射線や職場での放射線量の測定にも適しています。さらに、一部の装置はリアルタイムでデータを表示することができ、放射線量の変化を即座に監視することが可能です。これにより、短時間で危険な状況を察知し、適切な対応をとることができます。 電離放射線監視装置には、いくつかの種類があります。先に挙げたガイガーカウンター、シンチレーションカウンター、半導体検出器のほかにも、フィルムバッジやラジオアイソトープモニターなどがあります。フィルムバッジは、放射線にさらされることでフィルムが感光し、その変化から被ばく量を評価します。この方式は特に長期間にわたる被ばく量を測定するためのもので、主に従業員の被ばく管理に利用されます。ラジオアイソトープモニターは、特定の放射性物質を検出するために特化した装置で、医療用放射線治療や研究施設で使用されます。 用途としては、電力会社や研究機関、病院、放射線治療施設、さらには環境モニタリングなど多岐にわたります。原子力発電所では、作業者や周辺地域の放射線量を常時監視することが求められます。これにより、放射線の漏洩が万が一にも発生した場合、迅速に対策を講じることができます。また、放射線治療を行う病院では、患者に対して正しい放射線量が照射されているかどうかを確認するために、この装置が使われます。さらに、環境においても、自然放射線や人為的な放射線の影響を監視するための重要なツールとして活用されています。 最近の技術進歩により、電離放射線監視装置はより高性能かつコンパクトになっています。例えば、デジタル技術の進化によって、装置の操作が簡単になり、データの蓄積や分析が容易にできるようになりました。また、インターネットに接続することができる装置も登場しており、データをオンラインでリアルタイムに共有したり、遠隔から監視したりすることが可能になっています。これにより、全国レベルや国際的なスケールでの放射線監視が促進され、より効果的なリスク管理が行えるようになっています。 加えて、AI技術の導入も進んでいます。放射線検出データを分析し、異常があった場合に警告を発するシステムや、データのトレンドを予測するプログラムが開発されています。これにより、事前に放射線の影響を予測し、適切な対策を講じることが期待されています。 最後に、今後の展望についてですが、電離放射線監視装置の技術はさらに進化し、より小型化・高性能化が進むでしょう。それにより、個人でも持ち運べる小型の放射線測定器が普及し、一般市民の放射線に対する意識も高まることが予想されます。また、国際的な放射線監視の必要性が増す中、各国間のデータ共有や共同研究が行われ、世界的な安全基準の策定にも寄与することが期待されます。 電離放射線監視装置は、放射線の健康への影響を評価し、環境保護や人類の安全を守るために欠かせない重要な技術であり、今後の科学技術の発展とともに、ますますその重要性が増していくことでしょう。 |
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