氮氧化物控制系統市場：現況分析與預測（2023-2030）

Nitrogen Oxide Control System Market: Current Analysis and Forecast (2023-2030)

出版日期: 2024年04月01日 | 出版商:

UnivDatos Market Insights Pvt Ltd | 英文 125 Pages | 商品交期: 最快1-2個工作天內

價格

簡介目錄

由於人們對空氣污染的擔憂日益加劇以及政府對此問題的嚴格監管，氮氧化物控制系統市場預計將以約 5.8% 的複合年增長率強勁增長。氮氧化物 (NOx) 是一組高活性氣體，是空氣污染的主要來源，有助於形成煙霧、酸雨和地面臭氧。這些氣體主要是由發電廠、工業設施和汽車中化石燃料的燃燒所排放的。隨著人們對空氣品質及其對人類健康和環境影響的日益關注，世界各地對有效氮氧化物控制系統的需求正在迅速增加。此外，世界各國政府正在引入更嚴格的排放標準，以控制空氣污染並減少氮氧化物對環境的影響。例如，美國環保署 (EPA) 將在 2024 年 2 月加強氮氧化物國家空氣品質標準 (NAAQS)，旨在保護公眾免受心臟病和過早死亡等有害且代價高昂的健康影響。受到限制。

根據技術，市場分為選擇性催化還原 (SCR)、選擇性非催化還原 (SNCR)、低氮氧化物燃燒器和燃料再燃燒。選擇性催化還原 (SCR) 在市場佔有率和滲透率方面脫穎而出，成為主導細分市場。控制工業和公用事業鍋爐的氮氧化物 (NOx) 排放是一個主要的環境問題。人們已經開發了各種技術來減少氮氧化物，包括選擇性催化還原（SCR）、選擇性非催化還原（SNCR）、低氮氧化物燃燒器和燃料再燃燒。其中，SCR目前在NOx控制系統市場佔據主導佔有率。 SCR 可實現高達 90% 或更高的氮氧化物減排效率，使其成為滿足嚴格排放法規最有效的技術。此外，SCR 系統用途廣泛，可改造現有鍋爐和其他燃燒源，以及發電、水泥、化學和煉油等多個行業的新裝置。此外，SCR 系統可以在廣泛的溫度和負載條件下運行，從而可以靈活地控制不同運行情況下的氮氧化物排放。這種市場發展表明了 SCR 氮氧化物控制系統市場的重要性，並創造了有利的情景來支持其在整個預測期內的成長軌跡。

根據應用，市場分為發電/能源、化學、交通和工業。氮氧化物（NOx）是各種工業、交通、發電和化工廠燃燒過程中釋放的有害污染物。為了解決氮氧化物排放對環境的影響，全球市場各領域對氮氧化物控制系統的需求顯著增加。就市場收入和氮氧化物控制系統的廣泛採用而言，發電和能源領域脫穎而出。推動發電和能源領域採用氮氧化物控制系統的主要因素包括法規遵循。氮氧化物 (NOx) 是發電廠燃燒煤炭、天然氣和石油等化石燃料時產生的常見污染物。氮氧化物排放是煙霧、酸雨和空氣品質差的主要原因。為了解決這個問題，世界各國政府實施了嚴格的法規，限制發電設施的氮氧化物排放量。美國環保署的酸雨計畫、歐盟的工業排放指令和中國的超低排放標準只是推動電力產業氮氧化物監管的一些法規範例。超過限制的發電廠將面臨巨額罰款和處罰。此外，發電廠，尤其是燃煤發電廠，是最大的固定氮氧化物排放源之一。單一燃煤電廠每年排放數千噸氮氧化物。氮氧化物控制系統對於發電廠至關重要，因為控制如此大的點源比針對較小的分散式來源更有效。這些因素創造了一個促進氮氧化物控制系統在發電和能源領域廣泛採用的環境。

為了更瞭解氮氧化物控制系統的市場實施情況，市場為北美（美國、加拿大和其他北美地區）、歐洲（德國、英國、法國和其他歐洲地區）和亞太地區（中國、日本）、印度、韓國和亞太地區其他地區）以及世界其他地區。亞太地區各行業氮氧化物 (NOx) 控制系統的採用量正在迅速增加。推動這種採用的因素有很多，包括城市化進程的加速、電力需求的增加以及對排放對環境影響的日益擔憂。亞太地區各國政府日益認識到應對氣候變遷和減少溫室氣體排放的重要性。一些國家已經實施了政策和措施來促進清潔技術的採用，包括氮氧化物控制系統。例如，日本經濟產業省（METI）針對引進排放控制技術的產業推出了各種補貼和稅收優惠。同樣，韓國的排放控制技術開發計畫旨在支持先進排放控制系統的開發和商業化。此外，由於快速工業化和人口成長，亞太地區的電力需求正在快速成長。例如，根據國際能源總署 (IEA) 的數據，到 2040 年，該地區的電力需求預計將增加近 60%。電力需求的成長主要由燃煤電廠和天然氣電廠滿足，它們是氮氧化物排放的重要來源。為了減少這些發電廠對環境的影響，該地區國家要求安裝氮氧化物控制系統。例如，印度環境、森林和氣候變遷部對火力發電廠製定了嚴格的氮氧化物排放法規，並正在推廣採用選擇性催化還原（SCR）和選擇性非催化還原（SNCR）系統。這些因素提供了推動力，並支持亞太地區氮氧化物控制系統在預測期內的成長軌跡。

市場上的主要公司包括Honeywell International Inc.;CECO ENVIRONMENTAL; John Wood Group PLC; MITSUBISHI HEAVY INDUSTRIES, LTD.; DUCON Environmental; Babcock & Wilcox Enterprises, Inc; Siemens Energy; Phinia Inc.; Yara; and Spraying Systems Co.

A nitrogen oxide (NOx) control system is a set of technologies and measures implemented in various industrial processes and combustion systems to reduce the formation and emission of nitrogen oxides. Nitrogen oxides, primarily nitric oxide (NO) and nitrogen dioxide (NO2) are air pollutants that contribute to acid rain, ground-level ozone formation, and respiratory health issues. The primary objective of a NOx control system is to minimize the formation of nitrogen oxides during combustion processes or to remove them from the exhaust gases before they are released into the atmosphere. These systems are commonly employed in power plants, industrial furnaces, boilers, and vehicles.

The Nitrogen Oxide Control System Market is expected to grow at a strong CAGR of around 5.8% owing to the growing concerns about air pollution and governments' stringent regulations regarding this issue. Nitrogen oxides (NOx) are a group of highly reactive gases that are a major source of air pollution, contributing to the formation of smog, acid rain, and ground-level ozone. These gases are primarily emitted from the combustion of fossil fuels in power plants, industrial facilities, and vehicles. As concerns over air quality and its impact on human health and the environment continue to rise, the demand for effective nitrogen oxide control systems has been growing rapidly worldwide. Furthermore, Governments around the world have implemented stringent emission standards to curb air pollution and reduce the environmental impact of nitrogen oxides. For instance, in February 2024, the U.S. Environmental Protection Agency (EPA) strengthened National Ambient Air Quality Standards (NAAQS) for NOx, limiting it, aiming to protect its population from harmful and expensive health impacts, such as heart attack and premature deaths.

Based on the technology, the market is categorized into selective catalytic reduction (SCR), selective non-catalytic reduction (SNCR), low NOx burner, and fuel reburning. Selective catalytic reduction (SCR) stands out as a dominant segment in terms of market share and widespread adoption. The control of nitrogen oxide (NOx) emissions from industrial and utility boilers is a major environmental concern. Various technologies have been developed to reduce NOx, including selective catalytic reduction (SCR), selective non-catalytic reduction (SNCR), low NOx burners, and fuel reburning. Among these technologies, SCR currently holds the dominant share of the NOx control systems market. SCR can achieve NOx reduction efficiencies of up to 90% or higher, making it the most effective technology for meeting stringent emission regulations. Furthermore, SCR systems exhibit broad applicability and can be retrofitted to existing boilers and other combustion sources, as well as integrated into new installations across various industries, such as power generation, cement, chemical, and refining. Additionally, SCR systems can operate over a wide range of temperatures and load conditions, providing flexibility in controlling NOx emissions during varying operational scenarios. These developments along with others demonstrate the significance of SCR NOx control systems in the markets, creating a favorable scenario supporting its growth trajectory throughout the forecast period.

Based on the application, the market is segmented into power generation & energy, chemical, transportation, and industrial. Nitrogen Oxides (NOx) are harmful pollutants released during combustion processes in various industries, transportation, power generation, and chemical plants. To combat the environmental impact of NOx emissions, the global market has seen a significant rise in the demand for NOx control systems across different sectors. Among the sectors mentioned, power generation & energy stands out as a dominant segment in terms of market revenue and widespread adoption of NOx control systems. The primary factor driving the adoption of NOx control systems in power generation & energy includes regulatory compliance. Nitrogen oxides (NOx) are a prevalent pollutant produced from the combustion of fossil fuels like coal, natural gas, and oil in power plants. NOx emissions are a major contributor to smog, acid rain, and poor air quality. To combat this, governments globally have implemented stringent regulations capping the allowable NOx emissions from power generation facilities. The U.S. Environmental Protection Agency's Acid Rain Program, the European Union's Industrial Emissions Directive, and China's Ultra-Low Emissions Standards are just some examples of the regulations driving NOx control in the power sector. Plants exceeding limits face hefty fines and penalties. Furthermore, Power plants, especially those fired by coal, are among the largest stationary sources of NOx emissions. A single coal-fired plant can emit thousands of tons of NOx per year. Controlling these large point sources is more effective than targeting smaller distributed sources, making NOx control systems crucial for power plants. Factors such as these are creating a conducive environment, driving widespread adoption of NOx control systems in power generation & energy.

For a better understanding of the market adoption of the Nitrogen Oxide Control Systems system, the market is analyzed based on its worldwide presence in countries such as North America (The U.S., Canada, and the Rest of North America), Europe (Germany, The U.K., France, Rest of Europe), Asia-Pacific (China, Japan, India, South Korea, Rest of Asia-Pacific), Rest of World. The Asia Pacific region is witnessing rapid growth in the adoption of nitrogen oxide (NOx) control systems across various industries. Several factors are driving this widespread adoption, fueled by increasing urbanization, rising power demand, and growing concerns about the environmental impact of emissions. Governments in the Asia Pacific region are increasingly recognizing the importance of addressing climate change and reducing greenhouse gas emissions. Several countries have implemented policies and initiatives to promote the adoption of clean technologies, including NOx control systems. For instance, Japan's Ministry of Economy, Trade, and Industry (METI) has introduced various subsidies and tax incentives for industries implementing emission control technologies. Similarly, South Korea's Emission Control Technology Development Program aims to support the development and commercialization of advanced emission control systems. Furthermore, the Asia Pacific region is experiencing a surge in power demand due to rapid industrialization and population growth. For instance, according to the International Energy Agency (IEA), the region's electricity demand is expected to grow by nearly 60% by 2040. This increasing demand for power is primarily being met by coal-fired and natural gas-fired power plants, which are significant sources of NOx emissions. To mitigate the environmental impact of these power plants, countries in the region are mandating the installation of NOx control systems. For example, India's Ministry of Environment, Forest, and Climate Change has set stringent NOx emission limits for thermal power plants, driving the adoption of selective catalytic reduction (SCR) and selective non-catalytic reduction (SNCR) systems. Factors such as these are creating favorable tailwinds, supporting the growth trajectory of the Asia Pacific NOx control system throughout the forecast period.

Some of the major players operating in the market include Honeywell International Inc.; CECO ENVIRONMENTAL; John Wood Group PLC; MITSUBISHI HEAVY INDUSTRIES, LTD.; DUCON Environmental; Babcock & Wilcox Enterprises, Inc; Siemens Energy; Phinia Inc.; Yara; and Spraying Systems Co.

1MARKET INTRODUCTION

1.1.Market Definitions
1.2.Main Objective
1.3.Stakeholders
1.4.Limitation

2RESEARCH METHODOLOGY OR ASSUMPTION

2.1.Research Process of the Nitrogen Oxide Control System Market
2.2.Research Methodology of the Nitrogen Oxide Control System Market
2.3.Respondent Profile

3MARKET SYNOPSIS

4EXECUTIVE SUMMARY

5IMPACT OF COVID-19 ON THE NITROGEN OXIDE CONTROL SYSTEM MARKET

6NITROGEN OXIDE CONTROL SYSTEM MARKET REVENUE (USD BN), 2020-2030F.

7MARKET INSIGHTS BY TECHNOLOGY

7.1.Selective Catalytic Reduction (SCR)
7.2.Selective Non-Catalytic Reduction (SNCR)
7.3.Low NOx Burner
7.4.Fuel Reburning

8MARKET INSIGHTS BY APPLICATION

8.1.Power Generation and Energy
8.2.Chemical
8.3.Transportation
8.4.Industrial

9MARKET INSIGHTS BY REGION

9.1.North America
- 9.1.1.The U.S.
- 9.1.2.Canada
- 9.1.3.Rest of North America
9.2.Europe
- 9.2.1.Germany
- 9.2.2.The U.K.
- 9.2.3.France
- 9.2.4.Italy
- 9.2.5.Rest of Europe
9.3.Asia-Pacific
- 9.3.1.China
- 9.3.2.India
- 9.3.3.Japan
- 9.3.4.South Korea
- 9.3.5.Rest of Asia-Pacific
9.4.Rest of the World