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市場調查報告書

商品編碼

1644965

歐洲空氣品質監測-市場佔有率分析、產業趨勢與統計、成長預測（2025-2030 年）

Europe Air Quality Monitoring - Market Share Analysis, Industry Trends & Statistics, Growth Forecasts (2025 - 2030)

出版日期: 2025年01月05日 | 出版商:

Mordor Intelligence | 英文 110 Pages | 商品交期: 2-3個工作天內

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簡介目錄

預計2025年歐洲空氣品質監測市場規模為107.5億美元，預計2030年將達到115.6億美元，預測期內（2025-2030年）的複合年成長率為1.45%。

關鍵亮點

從長遠來看，預計預測期內政府對工業和商業營運的嚴格排放法規將推動市場發展。
另一方面，可再生能源產業的不斷壯大導致煤炭和天然氣發電廠的關閉，預計這將導致全部區域的空氣污染水平下降，從而抑制預測期內對空氣品質監測設備的需求。
預計在預測期內，監測微量污染物水平的監測設備的技術進步將為市場帶來巨大的成長機會。

歐洲空氣品質監測市場趨勢

系列主導市場

自動或連續空氣品質監測站 (CAAQMS) 可以使用各種分析儀器監測污染物，減少人工錯誤的機會，以幾分鐘的時間間隔產生資料，並以最少的人工干預傳輸資料。這些系統由採樣、調節和分析組件以及軟體組成，旨在透過分析代表性空氣樣本提供直接、即時、連續的污染測量。
由於它們提供即時測量，這些系統通常安裝在空氣污染嚴重的地方，以進行動態空氣品質監測。因此，這些系統傳統上用於工業設施周圍的空氣品質監測，以測量工業空氣污染物（如 SOx、NOx、COx 和細顆粒物（主要是 PM2.5 和 PM10））的動態水平。大多數連續空氣監測計劃需要同時監測氣象狀況。
在歐洲等新興經濟體中，空氣品質已成為保障社會健康的一個越來越重要的參數。因此，這些國家在建築和工業建築中頒布了嚴格的健康、安全、安保和環境 (HSSE) 法規，從而增加了對室內空氣品質監測系統的需求以確保合規。
歐洲各地智慧建築的不斷建設，對結合物聯網 (IoT) 系統的連續室內空氣品質監測系統的需求激增。這些系統可以透過安裝在商業空間、辦公室、學校等的室內連續空氣品質監測系統，動態地提醒業主潛在的空氣品質問題。
空氣污染已成為歐洲日益嚴重的健康問題。根據歐洲環境署 (EEA) 的數據，超過 90% 的歐盟 (EU) 城市人口所接觸的細懸浮微粒水平超過了世界衛生組織 (WHO) 設定的指導水平。此外，接觸濃度超過2021年世衛組織指導值的細懸浮微粒導致歐盟27國有超過23萬人過早死亡。該地區空氣污染的主要來源是能源、交通、家庭、工業和農業活動中石化燃料的燃燒。
2022 年，能源產業是歐洲污染最嚴重的產業，排放量約 37.698 億噸二氧化碳當量。
與其他受到新冠疫情引發的全球經濟衰退負面影響的市場不同，空氣品質設備和監測市場實現了大幅成長。由於 SARS-2 冠狀病毒是一種透過空氣傳播的病毒，人們擔心該病毒會在密閉空間內透過室內病毒污染傳播，這導致了先進的抗病毒空氣監測和處理系統的開發和部署，以降低傳播的可能性。這導致對專門的連續室內空氣品質監測系統的需求激增。

英國佔很大市場佔有率

2023年4月，英國啟動新一輪地方政府空氣品質補助金計劃，以支持當地社區減少污染空氣對民眾健康的影響。英格蘭各地的地方當局現在可以申請政府 761 萬美元的部分資金來實施空氣品質改善計劃。
年度空氣品質津貼允許城市製定和實施措施，使企業、學校和社區受益，並減少空氣污染對人們健康的影響。自 2010 年以來，該計劃已向 500 多個計劃頒發了超過 6,719 萬美元的獎勵。
這筆資金將優先用於解決顆粒物問題的計劃，提高公眾對空氣污染影響的認知，並幫助地方政府將氮氧化物 (NO2) 和其他污染物的含量降低到法定基準值以下。因此，政府的此類措施可能會在預測期內增加對空氣品質監測系統的需求。
英國環境署營運的約 300 個監測站遍布全英國，負責監測空氣質量，這些監測站組成網路，使用特定方法收集特定類型的資訊。每個網路測量的污染物和所採用的方法取決於網路建立的原因和資料的使用方式。
2022 年，能源產業是英國污染最嚴重的產業之一，排放量約 3.446 億噸二氧化碳當量。最著名的監測污染物濃度的網路稱為自動化城鄉網路（AURN），它每小時幾乎即時報告資料。
英國擁有嚴格的指導方針和廣泛的監控網路，預計這些因素將在預測期內推動市場成長。

歐洲空氣品質監測產業概況

歐洲空氣品質監測市場正在變得半固體。市場的主要企業（不分先後順序）包括霍尼韋爾國際公司、堀場製作所有限公司、3M、賽默飛世爾科技和西門子股份公司。

2022 年 9 月，霍尼韋爾推出了整合預警煙霧偵測和先進室內空氣品質 (IAQ) 監測的解決方案，以推動安全健康的建築發展。 Vesda Air 解決方案基於旗艦產品 Vesda-E 系列吸氣式煙霧偵測器開發，在一個盒子中整合了五個 IAQ 感測器。在生命安全、財產保護或室內空氣品質問題變得嚴重之前發現它們，您可以使您的建築物更加安全。

其他福利

Excel 格式的市場預測 (ME) 表
3 個月的分析師支持

介紹
至2028年市場規模及需求預測（單位：美元）
最新趨勢和發展
政府法規和政策
市場動態
- 驅動程式
  - 政府對工業和商業運作的排放法規非常嚴格
- 限制因素
  - 可再生能源產業需求不斷成長
供應鏈分析
波特五力分析
- 供應商的議價能力
- 消費者議價能力
- 新進入者的威脅
- 替代品的威脅
- 競爭對手之間的競爭

第5章市場區隔

產品類型
- 室內監控
- 戶外監視器
取樣方法
- 連續的
- 手動的
- 間歇性
按最終用戶
- 住宅和商業
- 發電
- 石油化工
- 其他
按地區
- 英國
- 德國
- 法國
- 義大利
- 西班牙
- 歐洲其他地區

第6章競爭格局

併購、合資、合作與協議
主要企業策略
Companies Profiles
- Siemens AG
- Thermo Fisher Scientific Inc.
- Horiba Ltd
- Emerson Electric Co.
- 3M Co.
- Honeywell International Inc.
- Teledyne Technologies Inc.
- TSI Inc.
- Merck KGaA
- Agilent Technologies Inc.
- Aeroqual Limited

第7章市場機會與未來趨勢

監測微量污染物水準的監測設備技術進步

簡介目錄

Product Code: 5000122

The Europe Air Quality Monitoring Market size is estimated at USD 10.75 billion in 2025, and is expected to reach USD 11.56 billion by 2030, at a CAGR of 1.45% during the forecast period (2025-2030).

Europe Air Quality Monitoring - Market - IMG1

Key Highlights

Over the long term, strict government-mandated emission norms in industrial and commercial operations are expected to drive the market during the forecast period.
On the flip side, the growing impetus to the renewable energy industry leading to a closure of coal and natural gas-fired power plants is expected to result in a decrease in air pollution levels across the region, restraining the demand for air quality monitoring devices during the forecast period.
Nevertheless, technological advancements in monitoring equipment to monitor levels of trace contaminants are expected to be a significant growth opportunity for the market during the forecast period.

Europe Air Quality Monitoring Market Trends

Continuous Type to dominate the market

Automatic or continuous ambient air quality monitoring stations (CAAQMS) can monitor pollutants using different analyzers, reducing the chances of manual error, generating data at time intervals of minutes, and transmitting the data while minimizing manual intervention. These systems comprise sampling, conditioning, and analytical components and software designed to provide direct, real-time, continuous pollution measurements by analyzing representative sample(s) of air.
Due to their real-time measurement capabilities, these systems are typically installed at places with a high level of air pollution for dynamic air quality monitoring. Therefore, these systems have been traditionally used for air quality monitoring around industrial facilities to measure the dynamic levels of industrial air pollutants such as SOx, NOx, COx, and particulates (mostly PM2.5 and PM10). Most continuous air monitoring programs require simultaneous monitoring of meteorological conditions because these parameters influence local and regional air quality.
In developed economies like those in Europe, air quality has become an increasingly significant parameter for safeguarding social health. Hence, these countries have enacted strict Health, Safety, Security, and Environment (HSSE) regulations in building and industrial construction, which, in turn, has led to the growth in demand for indoor air quality monitoring systems to ensure compliance.
The rise in the construction of smart buildings across Europe has led to a surge in demand for continuous indoor air quality monitoring systems coupled with Internet of Things (IoT) systems. These systems can dynamically alert the owners about prospective air quality issues, with indoor continuous air quality monitoring systems installed in commercial spaces, offices, and schools.
Air pollution is a growing health concern in Europe. According to the European Environmental Agency (EEA), more than 90% of the urban population in the European Union (EU) were exposed to fine particulate matter levels above the guideline level set by the World Health Organization (WHO). Further, exposure to concentrations of fine particulate matter above the 2021 WHO guideline resulted in more than 230,000 premature deaths in the EU-27 region. The region's primary sources of air pollution come from burning fossil fuels in energy, transport, households, and industrial and agricultural activities.
In 2022, the energy sector was the most polluting in Europe, emitting roughly 3769.8 million tonnes of carbon dioxide equivalents of carbon dioxide.
Unlike other markets that were negatively impacted due to the global recession triggered by the COVID-19 pandemic, the air quality equipment and monitoring markets have grown considerably. As the SARS-2 coronavirus is an airborne virus, concerns about infections caused by indoor viral pollution in constrained spaces have led to the developing and deploying advanced anti-viral air monitoring and treatment systems to reduce the chances of contagion. This has led to explosive growth in demand for specialized continuous indoor air quality monitoring systems.

United Kingdom to have a Significant share in the market

The United Kingdom is widely recognized for having one of the most comprehensive air quality monitoring programs in the European Union. in April 2023, A new round of Air Quality Grants for local administrations was opened to aid communities and lessen the impact of polluted air on people's health in the United Kingdom. Local administrations across England can now apply for a share of USD 7.61 million of the government budget to provide projects to enhance air quality.
The annual Air Quality Grant permits councils to develop and execute measures to benefit businesses, schools, and communities and lessen the impact of air pollution on people's health. Since 2010, more than USD 67.19 million has been awarded across more than five hundred projects through the scheme.
The budget will be prioritized towards projects that tackle particulate matter, enhance public understanding of the effects of air pollution, and help local authorities bring down levels of nitrogen oxide (NO2) and other pollutants below legal limits. Thus, such initiatives by the government are likely to increase demand for air quality monitoring systems during the forecast period.
Around 300 environment agency-managed monitoring sites across the United Kingdom monitor air quality, and these are organized into networks that gather a particular kind of information using a particular method. The pollutants measured and the method used by each network depends upon the reason for setting up the network and what the data are to be used for.
In 2022, the energy sector was one of the most polluting in the United Kingdom, emitting roughly 344.6 million tonnes of carbon dioxide equivalents of carbon dioxide. The network that monitors concentrations of the most well-known pollutants is called the Automatic Urban and Rural Network (AURN), which reports data hourly in near real-time.
The United Kingdom has strict guidelines and a widespread monitoring network, and these factors are expected to drive the market's growth during the forecast period.

Europe Air Quality Monitoring Industry Overview

The Europe air quality monitoring market is semi-consolidated. Some of the key players in the market (in no particular order) include Honeywell International Inc., Horiba Ltd., 3M Company, Thermo Fisher Scientific Inc., and Siemens AG, among others.

In September 2022, Honeywell launched a solution that integrates early warning smoke detection with progressive indoor air quality (IAQ) monitoring, advancing its efforts to develop secure and healthful buildings. Created on the flagship Vesda-E line of aspirating smoke detectors, the Vesda Air solution has an individual five-in-one IAQ sensor within a single box. It can help enhance building safety by determinating life safety, asset protection, or IAQ issues before they escalate into problems.

Additional Benefits:

The market estimate (ME) sheet in Excel format
3 months of analyst support

1 INTRODUCTION

1.1 Scope of the Study
1.2 Market Definition
1.3 Study Assumptions

2 RESEARCH METHODOLOGY

3 EXECUTIVE SUMMARY

4 MARKET OVERVIEW

4.1 Introduction
4.2 Market Size and Demand Forecast in USD, till 2028
4.3 Recent Trends and Developments
4.4 Government Policies and Regulations
4.5 Market Dynamics
- 4.5.1 Drivers
  - 4.5.1.1 Strict Government-Mandated Emission Norms in Industrial and Commercial Operations
- 4.5.2 Restraints
  - 4.5.2.1 Growing Impetus to the Renewable Energy industry
4.6 Supply Chain Analysis
4.7 Porter's Five Forces Analysis
- 4.7.1 Bargaining Power of Suppliers
- 4.7.2 Bargaining Power of Consumers
- 4.7.3 Threat of New Entrants
- 4.7.4 Threat of Substitutes Products and Services
- 4.7.5 Intensity of Competitive Rivalry

5 MARKET SEGEMENTATION

5.1 Product Type
- 5.1.1 Indoor monitor
- 5.1.2 Outdoor Monitor
5.2 Sampling Method
- 5.2.1 Continuous
- 5.2.2 Manual
- 5.2.3 Intermittent
5.3 By End-user
- 5.3.1 Residential and Commercial
- 5.3.2 Power Generation
- 5.3.3 Petrochemicals
- 5.3.4 Other End Users
5.4 By Geography
- 5.4.1 United Kingdom
- 5.4.2 Germany
- 5.4.3 France
- 5.4.4 Italy
- 5.4.5 Spain
- 5.4.6 Rest of Europe

6 COMPETITIVE LANDSCAPE

6.1 Mergers and Acquisitions, Joint Ventures, Collaborations, and Agreements
6.2 Strategies Adopted by Leading Players
6.3 Companies Profiles
- 6.3.1 Siemens AG
- 6.3.2 Thermo Fisher Scientific Inc.
- 6.3.3 Horiba Ltd
- 6.3.4 Emerson Electric Co.
- 6.3.5 3M Co.
- 6.3.6 Honeywell International Inc.
- 6.3.7 Teledyne Technologies Inc.
- 6.3.8 TSI Inc.
- 6.3.9 Merck KGaA
- 6.3.10 Agilent Technologies Inc.
- 6.3.11 Aeroqual Limited