High-efficient energy-saving combustion aid
Technical field
This utility model relates to combustion furnace, and specifically a kind of high-efficient energy-saving combustion aid falls。
Background technology
Current most of combustion furnace all uses diesel oil, coal or wood flour as the energy, and its heat energy service efficiency is low, only 20%-30%, but also can produce volume of smoke, causes serious environmental pollution, and manufacturing cost is also of a relatively high。
Summary of the invention
The purpose of this utility model is for overcoming the deficiencies in the prior art, and provides a kind of high-efficient energy-saving combustion aid, and this combustion furnace heat energy service efficiency is high, and use cost is low, energy-saving and emission-reduction。
The technical scheme realizing this utility model purpose is:
A kind of high-efficient energy-saving combustion aid, including burning frame, the blower fan being arranged in burning frame, controller, temperature controller, oil pump, airduct, ignition electrode, nozzle, burner, nebulizer and with the burning body of heater that is connected of frame, it is provided with pot in the burner hearth of body of heater, nozzle one end is connected with oil pump by ignition electrode, the other end is connected with nebulizer, nebulizer is connected with body of heater, and oil pump, temperature controller are connected with controller respectively。
It is additionally provided with power on button, power-off button and alarm lamp in burning frame, is connected with controller respectively。
It is additionally provided with blast switch, is connected with blower fan, controller respectively。
Being additionally provided with temperature detector, be arranged on temperature sensor bracket, temperature sensor bracket is arranged on the bell of body of heater, and temperature detector is connected with temperature controller。
Described burner outer wall is provided with boiler clothing, and ignition electrode, nozzle are separately positioned in boiler clothing。
Described burning frame is connected with body of heater by combustor support。
Being provided with heat-insulation layer between boiler clothing and furnace wall, bell is provided with heat insulation foam, and furnace body outer wall is provided with loose collar, and furnace wall upper surface is uniformly laid with air vent。
Described pot is provided with fixing suspension ring。
Described nebulizer is inclined hole column type nebulizer, is connected with burner。
The invention have the advantage that use cost is low, energy-saving and emission-reduction, with existing technical equipment, heat energy service efficiency is high, and under the same conditions, heat energy efficiency improves more than 50%。
Accompanying drawing explanation
Fig. 1 is the structural representation of combustor;
Fig. 2 is the side view of combustor。
Fig. 3 is the structural representation of this utility model high-efficient energy-saving combustion aid;
Fig. 4 is the side view of combustion furnace;
In figure: 1. burning 18. pot 19., furnace wall of frame 2. blower fan 3. controller 4. oil pump 5. airduct 6. ignition electrode 7. nozzle 8. burner 9. boiler clothing 10 inclined hole column type nebulizer 11. power on button 12. power-off button 13. alarm lamp 14. temperature controller 15. combustor support 16. body of heater 17 burner hearth 20. heat insulation foam 21. heat-insulation layer 22. loose collar 23. fixes suspension ring 24. air vent 25. bell 26. temperature sensor bracket .27. temperature detector 28. blast switch
Detailed description of the invention
With reference to Fig. 1-4, a kind of high-efficient energy-saving combustion aid, is made up of burning frame 1, blower fan 2, controller 3, oil pump 4, airduct 5, ignition electrode 6, nozzle 7, burner 8, boiler clothing 9, nebulizer 10, power on button 11, power-off button 12, alarm lamp 13, temperature controller 14, combustor support 15, body of heater 16, furnace wall 17, pot 18, burner hearth 19, heat insulation foam 20, heat-insulation layer 21, loose collar 22, fixing suspension ring 23, air vent 24, bell 25, temperature sensor bracket 26, temperature detector 27 and blast switch 28。Blower fan 2, oil pump 4, controller 3, temperature controller 14, power on button 11, power-off button 12 and alarm lamp 13 are separately positioned in burning frame 1, airduct 5 is connected with boiler clothing 9, ignition electrode 6, nozzle 7 and burner 8 are arranged in boiler clothing 9, inclined hole column type nebulizer 10 connects with burner 8, nozzle 7 connects with burner 8, nozzle 7 connects with ignition electrode 6, ignition electrode 6 is connected with oil pump 4, oil pump 4, power on button 11, power-off button 12, alarm lamp 13, temperature controller 14 is connected with controller 3 respectively with blast switch 28, blast switch 28 is connected with blower fan 2, combustor support 15 is arranged on body of heater 16, burning frame 1 is arranged on combustor support 15, temperature detector 27 is connected with temperature controller 3, temperature detector 27 is arranged on temperature sensor bracket 27, temperature sensor bracket 27 is arranged on bell 25, bell 25 is arranged on body of heater 16, boiler clothing 9 is arranged on body of heater 16, furnace wall 17 is arranged on body of heater 16, heat-insulation layer 21 is arranged between boiler clothing 9 and furnace wall 17, burner hearth 19 is arranged on the upper surface interval 10-40mm of furnace wall 17, heat insulation foam 20 is arranged on bell, 18 pots are arranged in burner hearth 19, fixing suspension ring 23 are arranged on pot 18, loose collar 22 is arranged on body of heater 16 outer wall, air vent 24 is arranged along furnace wall 17 upper surface。
This utility model the results showed, under producing same heat energy situation:
Bio-fuel, produces sulfur dioxide 1.4mg/m3, oxynitride 1.58mg/m3, carbon monoxide 3.02mg/m3;
Diesel oil: produce sulfur dioxide 26.90mg/m3, oxynitride 11.00mg/m3, carbon monoxide 721.24mg/m3;
Liquefied gas: produce sulfur dioxide 4.02mg/m3, oxynitride 7.48mg/m3, carbon monoxide 178.74mg/m3。