Eclipse Combustion 6500 AIR Proven, AIR not Proven Lkout, Purge AT High Firexx, LOW Fire Fail

Page 37

Table 10.1 Bi-Flame Operating Sequence (continued)

NORMAL MESSAGE

AIR PROVEN

NORMAL MESSAGE

WAIT FOR HI. FIRE SWITCH XX:XX

Modulator sent to high fire.

BURNER START-UP

Is voltage present at air flow switch

within ten seconds?

 

YES

 

 

NO

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

ERROR MESSAGE

AIR NOT PROVEN

LKOUT XXXX:XX:XX

Is voltage present at high fire input?

NORMAL MESSAGE

PURGE AT HIGH

FIREXX

Countdown of “XX” seconds as set by DIP switch.

NORMAL MESSAGE

WAIT FOR LO.FIRE

SWITCH XX:XX

YES

NO

ERROR MESSAGE

HIGH FIRE FAIL LKOUT XXXX:XX:XX

 

 

Modulator sent to low fire.

 

 

 

Is voltage present

 

 

 

 

 

 

 

 

 

 

 

 

 

at low fire input?

 

 

 

 

 

 

 

 

 

 

 

 

 

 

NORMAL MESSAGE

 

 

 

 

 

 

 

YES

 

NO

 

PILOT TRIAL FOR

 

 

 

 

 

 

 

 

 

IGNITION

XX

 

 

 

 

 

 

 

 

 

Spark energized until pilot flame

 

 

 

 

 

 

 

 

 

 

 

proven; pilot valve energized for

 

 

ERROR MESSAGE

countdown of “XX” seconds

 

 

LOW FIRE FAIL

(“XX” equals selected trial for

 

 

LKOUT XXXX:XX:XX

 

 

 

 

 

 

 

 

 

 

 

 

 

ignition).

NORMAL MESSAGE

PILOT ON

XX

After “XX” equals zero (0)...

NORMAL MESSAGE

PILOT ON

IGNITION OFF

Delay 5 seconds.

NORMAL MESSAGE

MAIN FLAME ON

Is pilot flame signal present?

YES NO

Is flame signal present?

YES NO

ERROR MESSAGE

PILOT # (0X) FAILED LKOUT XXXX:XX:XX

X = burner number.

ERROR MESSAGE

MAIN # (0X) FAILED LKOUT XXXX:XX:XX

X = burner number.

Is flame signal present?

(see next page)

Eclipse Bi-Flame v1.8, Instruction Manual 826, 05/03

37

 

Image 37
Contents Bi-Flame Copyright Disclaimer Notice Liability Warranty Audience Important Notices Document Conventions About this manualTable of Contents Page Page Product Description IntroductionIntroduction SpecificationsAffectedTerminals Main Chassis DimensionsModules Description Power ModuleIntroduction Module Description Identification Relay ModuleRemote Display Sensor ModuleIntroduction DIP Switch Location DIP Switch Access DIP Switch SelectionS2 DIP Switches DIP Switch SettingsS4 DIP Switches S6 DIP SwitchesCombustion Air Flow Check Terminal Function SummaryMain Fuel Valve Proof-of-Closure Terminal Low Fire Start TerminalPilot Test Mode Recycle ModeInterrupted or Intermittent Pilot Spark, Pilot Flame and Main Flame SeparationHistory Log Auxiliary InputsLast Recycle by AIR=XXXXXX or Last Recycle by FLAME=XXXXXXModulation Contacts Valve Leakage Valve Leak Sensing Device Vlsd InterfaceValve Leak Fail Lkout Hhhhmmss RS232 Communication Interfaces RS485 optional Remote Display UnitLimits Alarm FaultReset AirSystem Lockout Conditions System FaultsSystem Installation Page Power must be off when inserting or removing the cable Remote Reset Remote DisplayJ6 J3 Wiring Diagram & Connections-Main Chassis Introduction Sensor Wiring Sensor InstallationDo not ground the shield to terminal GND Scanners Flame RodsScanner Sighting Conditions Introduction Flame Signal Strength Minimum Pilot Test Test ProceduresSpark Sighting Test Limits and Interlock Tests Pilot Flame Failure Test Main Flame FaiulreMonthly Checklist Introduction MaintenanceYearly Checklist Contact Check air filter Check blower rotation Troubleshooting Problem Possible Cause SolutionRemote Display Messages Bi-Flame Operating Sequence AIR Proven Wait for LO.FIRE SwitchAIR not Proven Lkout Purge AT High FirexxAutomatic Modulation Main Flame on Pilot OFFFlame #OX Time = Main # OX FailedMain Valve Fail Lkout Post PurgeMessage Type Explanation Remote Display Diagnostic Messages ListedAlphabeticallyRemote Display Diagnostic Messages Valve Leakage UNSAFE-FLM-PURGEValve Leak Fail Watchdog FailConversion Factors AppendixMetric to English Metric to MetricPos Eclipse Qty Description Part Number Illustrated Parts List

6500 specifications

The Eclipse Combustion 6500 is a cutting-edge industrial burner designed to optimize combustion efficiency and reduce emissions in various applications. Known for its innovative approach to fuel burning, the 6500 model combines advanced technology with robust engineering, making it a preferred choice for industries such as power generation, manufacturing, and petrochemicals.

One of the hallmark features of the Eclipse Combustion 6500 is its versatility to operate on multiple fuels, including natural gas, propane, and biogas. This flexibility allows companies to adapt to changing fuel availability and cost, ensuring operational efficiency and economic viability. The burner is designed with a range of firing rates, catering to both small and large-scale applications, which enhances its utility across diverse operational scenarios.

Another significant characteristic of the 6500 is its sophisticated control system. The burner employs advanced digital controls that enable precision in fuel-to-air ratios and overall combustion management. This technology not only optimizes thermal performance but also facilitates compliance with stringent emissions regulations. By continuously monitoring combustion conditions, the 6500 ensures maximum efficiency while minimizing harmful emissions of nitrogen oxides (NOx) and carbon monoxide (CO).

Moreover, the Eclipse Combustion 6500 features a unique combustion geometry. This design promotes a stable flame while maintaining excellent mixing of fuel and air. The result is improved combustion efficiency and a reduction in pollutant formation. The structural integrity of the burner is engineered to handle high temperatures and corrosive environments, ensuring long-term reliability and reduced maintenance needs.

Safety is a paramount consideration in the design of the 6500. Integrated safety systems monitor operational parameters and provide alerts to prevent unsafe conditions. This focus on safety, combined with high performance, ensures that the burner not only meets but exceeds industry standards.

In summary, the Eclipse Combustion 6500 stands out due to its versatility, advanced control technologies, and efficient combustion capabilities. Its design prioritizes safety, reliability, and compliance with environmental regulations, making it an ideal choice for various industrial applications. As industries strive for greener and more efficient operations, the 6500 is poised to play a pivotal role in the evolution of combustion technology.