Global Low NOx Burner Market - Analysis by Geography, by Deployment Location Competitive Landscape, Key Company Information - Growth Trends and Forecasts 2017 - 2022

  • ID: 4386631
  • Report
  • Region: Global
  • 128 pages
  • Mordor Intelligence
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The market for global Low NOx Burner is expected to be USD XX billion at the end of the year 2015 and by the end of 2022 it is estimated to reach USDXX billion. The market is expected to grow at a rate of XX%. Low NOx burners operate on the principle of fuel re-burning technology. In this technique, a secondary fuel burner is placed in above the primary fuel burning complex. This secondary zone is divided in two parts i.e. reburn zone and burnout zone. In the primary zone during coal firing process the amount of coal used is 75-90% of the total heat requirement. The benefit of lower coal usage helps in lower production of NOx in the first stage. In the reburn the natural gas is inserted, which is about 1/4th of the total heat input. This addition of fuel creates an inducing condition for burning. In the burnout zone, the over fire air (OFA) is used to break down the NOx that is produced in the traditional wall fired cyclone burners to N2 compounds after incineration. During this entire process the fuel air mixture is carefully regulated at every step based on unique stoichiometric air ratio for each zone. This technique is also known as GR-LNB (Gas re-burning Low-NOx burner), since it is a mixture of two different activities.

The benefits of Low NOx burner is that it achieves better burning, lower peak flame temperature and longer flames. The major advantage of these type of burner is in the lower discharge of Nitrogen up to 30%. This is being driven by the need for reducing pollution from boilers. Boilers are extensively used in thermal power plants as well as chemical plants. These burners extensively use air recirculation but to achieve desired impact, higher fuel gas pressure and a larger burner throat are essential. For burners using older technology moving to this newer technology requires extensive, time consuming and costly modifications in the furnace floor. Also several factors affect the emission of NOx from the burner i.e. fuel gas, air preheat, particulates, liquid droplets and air leakage. Due to these factors the emissions of NOx can substantially increase if left uncontrolled. Another restraint is that even though the burner is able to reduce the NOx output the generation of CO2 and SO2 increases by following this technique. Furthermore due to the use of lesser fuel the output and efficiency of the boiler gets reduced.

Low NOx burners are consists of several major components like, air actuators, CCV nozzles, flow sensors, air distribution control, and coal control. This burner has actuators for primary secondary and tertiary flow control. At each of these stages, flow sensors and air distribution controller for accurately measuring the air flow. Coal burner is the basic component which is same as traditional burners. Low NOx burners can be divided into many types including oil, coal or gas based low NOX burner.

The market has also been geographically segmented. All the major regions including North America, Europe, Asia-Pacific, South America, and Middle East & Africa are analyzed in this report. Of these regions, the North America has in the past few years provided the largest demand. However Asia-Pacific region is expected to dominate the demand table during the study period. Due to enhanced focus on emissions this region is expected to follow the global trend of moving towards less polluting burners.

The major companies involved in the low Nox burner market are, Maxon Corporation, Alzeta Corporation, Babcock & Wilcox (B&W), Parker Boiler, R.F MacDonald Co., S. T. Johnson Company etc. The major producers are continuously striving to improve the existing design and achieve lower emissions at lesser cost.

Key Deliverables:

1. Market analysis for the global Low NOx Burner market, with region specific assessments and competition analysis on global and regional scales

2. Market definition along with the identification of key drivers and restraints

3. Identification of factors instrumental in changing the market scenarios, rising prospective opportunities, and identification of key companies that can influence this market on a global and regional scale

4. Extensively researched competitive landscape section with profiles of major companies along with their market shares

5. Identification and analysis of the macro and micro factors that affect the global Low NOx Burner market on both global and regional scales

6. A comprehensive list of key market players along with the analysis of their current strategic interests and key financial information

7. A wide-ranging knowledge and insights about the major players in this industry and the key strategies adopted by them to sustain and grow in the studied market

8. Insights on the major countries/regions in which this industry is blooming and to also identify the regions that are still untapped
Note: Product cover images may vary from those shown
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1. Introduction
1.1 Study Deliverables
1.2 Market Definition
1.3 Sizing Units
1.4 Base Currency
1.5 Review and Forecast Period Years
2. Research Methodology
2.1 Introduction
2.2 Analysis Methodology
2.3 Econometric Forecast Model
2.4 Research Assumptions
3. Executive Summery
4. Key Inferences
5. Market Overview and Technology Trends
5.1 Current Market Scenario
5.2 Applications of Low NOx Burner
5.3 Investment Analysis
5.4 Porters Five Forces Framework
5.5 Bargaining Power of Supplier
5.6 Bargaining Power of Consumer
5.7 Threat of New Entrants
5.8 Threat of Substitute of Products and Services
5.9 Competitive Rivalry Within The Industry
5.10 Drivers, Restraints, Opportunities, and Challenges Analysis (Endogenous Factors)
5.11 Market Drivers
5.11.1 Demand For Reducing Pollution From Burners
5.12 Market Restraints
5.12.1 Up gradation Cost for Existing Boilers
5.12.2 Boiler Efficiency Loss
5.13 Key Challenges
5.13.1 Emissions of Gases i.e. CO2, SO2
5.13.2 Impact of External factors on NOx
5.14 Current Opportunities in the Market
5.14.1 Attaining the Emission Norms
5.14.2 Reduction in NOX Discharge
5.15 Technology Trends
5.15.1 New Developments
5.15.2 Industry Value Chain Analysis
5.15.3 Product Life-Cycle Analysis
5.15.4 Product Benchmarking
6. Global Low NOx Burner Market, by Component
6.1 Air Actuator
6.2 CCV Coal Nozzle
6.3 Flow Sensor
6.4 Air Distribution Control
6.5 Coal Burner
7. Global Low NOx Burner Market, by Type
7.1 Coal Based Low NOx Burner
7.2 Gas Based Low NOx Burner
7.3 Oil Based Low NOx Burner
8. Global Low NOx Burner Market, by Industry
8.1 Commercial
8.2 Office
8.3 Factory
8.4 Power Plant
9. Global Low NOx Burner Market, by Geography – Regional Share and Forecasts
9.1 North America (NA)
9.1.1 Introduction
9.1.2 United States
9.1.3 Canada
9.1.4 Rest of North America
9.2 Europe
9.2.1 Introduction
9.2.2 Germany
9.2.3 United Kingdom
9.2.4 France
9.2.5 Italy
9.2.6 Spain
9.2.7 Russia
9.2.8 Rest of the Europe
9.3 Asia-Pacific (APAC)
9.3.1 Introduction
9.3.2 China
9.3.3 Japan
9.3.4 India
9.3.5 Australia
9.3.6 South Korea
9.3.7 Rest of Asia-Pacific
9.4 Middle-East and Africa (MEA)
9.4.1 Introduction
9.4.2 UAE
9.4.3 Saudi Arabia
9.4.4 Israel
9.4.5 Rest of the MEA
9.5 Latin America
9.5.1 Introduction
9.5.2 Brazil
9.5.3 Argentina
9.5.4 Mexico
9.5.5 Rest of Latin America
10. Competitive Landscape
10.1 Market Share Analysis
10.2 Organic and Inorganic Growth Strategies
10.3 Patent Analysis
10.4 The Challengers
10.5 Zero-Sum Quadrant
11. Key Vendor Analysis
11.1 Maxon Corporation
11.2 Alzeta Corporation
11.3 Faber Burner Company
11.4 RJM International
11.5 Power Flame
11.6 S.T. Johnson Company
11.7 Hurst Boiler and Welding Company, Inc.
11.8 Babcock & Wilcox (B&W)
11.9 Coen
11.10 Burnham Commercial Boiler Inc.
11.11 Parker Boiler
11.12 R.F MacDonald Co.
12. Analyst Outlook for Investment Opportunities
13. Future Outlook of the Market
14. Appendix
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