Maxon Telecom 1500, 850 Low temperature burners Inditherm Flame supervision, Flame development

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Low temperature burners - INDITHERM®

Flame supervision

1 - 2.3 - 11 E - m - 7/08

Flame supervision can be accomplished by use of a UV-scanner for all INDITHERM® burners and sizes. The scanner connection is 1”. Due to the presence of gas at the scanner port, only tight scanners can be used.

The use of a flame rod is only possible in a limited range of applications where the standard discharge sleeve is used. A flame rod combined with a high temperature discharge sleeve would generate a flame signal too low for proper flame scanning.

Contact MAXON for more details when considering a flame rod.

Flame development

INDITHERM® burners shall be installed in combustion chambers that allow full development of the burner flame. Consult MAXON for proper combustion chamber lay-out.

Gas pipe train design

The INDITHERM® burner is very sensitive to variations in gas pressures at burner gas inlet. The burner gas inlet pressure should not vary more then 2.5 mbar between high and low capacity.

Process back pressures

The INDITHERM® burner can operate between 0 and 1.5 mbar back pressure. The burner should not be used on applications where back pressures would fall outside these limits. It is possible to mount the burner on a process with changing back pressures as long as the fluctuating pressures stay within the 0 to 1.5 mbar limit.

Measuring equipment for burner commissioning

The burner gas pressures and air pressures as mentioned in table on page 1-2.3-6should be used as a guideline for burner system design and to have an approximative value for burner set up.To adjust the burner properly during commissioning, the oxygen content in the flue gas should be measured. A properly adjusted burner in an indirect fired application should have approximately 3% O2 in the stack at maximum capacity.

w w w . m a x o n c o r p . c o m

combustion systems for industry

MAXON reserves the right to alter specifications and data without prior notice. © 2008 Copyright Maxon Corporation. All rights reserved.

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Contents Specifications of Inditherm burners Low temperature burners Inditherm3 6 E m 7/08 Materials of construction 3 7 E m 7/08Available Inditherm burner versions and options Selection criteriaApplication details 3 8 E m 7/08Fuels Burner discharge sleeve3 9 E m 7/08 Minimum capacities Process temperatureMaximum capacities Preheated airGas pipe train design Low temperature burners Inditherm Flame supervisionFlame development Process back pressuresDimensions Inditherm with standard discharge sleeve all sizes3 12 E m 7/08 Inditherm with high temperature discharge sleeve all sizes 3 13 E m 7/08Adjustable orifice for pilot burner ADJ-ORF 3 14 E m 7/08Spark ignitor SI-1/2 Filter Elements FLT- Indi3 15 E m 7/08 Gaskets GSK- Indi 3 16 E m 7/08Installation instructions Application requirements3 18 E m 7/08 Low temperature burners Inditherm Burner mounting flange 3 19 E m 7/083 20 E m 7/08 Start-up instructions for Inditherm burners 3 21 E m 7/08Visual inspections Maintenance and inspectionSafety requirements Recommended spare parts

1100, 100, 1500, 700, 550 specifications

Maxon Telecom 1800, 850, 700, 1500, 300 represents a series of advanced telecommunications infrastructure solutions that cater to diverse connectivity needs. With its robust features and modern technologies, Maxon Telecom is paving the way for enhanced communication in various sectors, including mobile networks, satellite services, and broadband applications.

One of the main features of the Maxon Telecom series is its multi-band capabilities. Supporting frequencies such as 1800 MHz, 850 MHz, and 700 MHz, these systems enable operators to provide seamless coverage and improved data speeds across urban and rural landscapes. The 1500 MHz band is particularly advantageous for applications requiring high-capacity data throughput, making it suitable for dense population areas. The inclusion of the 300 MHz band enhances the offering by facilitating broader network coverage, crucial for emerging IoT technologies.

In terms of technology, Maxon Telecom utilizes state-of-the-art amplification and filtering systems that enhance signal clarity and strength. This approach minimizes dropouts and provides a consistent user experience. The incorporation of advanced digital signal processing techniques allows for better handling of high-volume data traffic, ensuring that users can stay connected even during peak usage times.

The design characteristics of the Maxon Telecom systems focus on both reliability and efficiency. Built to withstand various environmental conditions, these units come with rugged enclosures that protect against heat, moisture, and dust. Moreover, energy-efficient components ensure that the systems consume less power while delivering high performance, aligning with global sustainability goals.

Scalability is another key trait of the Maxon Telecom series. Operators can easily integrate these systems into existing networks, allowing for seamless upgrades without significant infrastructure changes. This modular approach also enables customization based on specific regional requirements, ensuring that the solutions can adapt as technology evolves.

Overall, Maxon Telecom 1800, 850, 700, 1500, 300 stands out as a comprehensive communication solution suitable for today's digital landscape. Its blend of multi-band support, advanced technology, and robust design makes it an ideal choice for telecom operators aiming to enhance their service offerings and meet the ever-increasing demands for reliable connectivity. Through continuous innovation, Maxon Telecom is well-positioned to address the challenges of modern communication needs.
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