A high efficiency laminar flow burner system for proving a stream of heat energy including a supply input module for providing fuel and laminar streams of air to a combustion manifold. The laminar air delivery system includes a damper, a blower, and an air delivery controller. The air delivery contr
A high efficiency laminar flow burner system for proving a stream of heat energy including a supply input module for providing fuel and laminar streams of air to a combustion manifold. The laminar air delivery system includes a damper, a blower, and an air delivery controller. The air delivery controller receives an efficiency signal to control the flow of a laminar air intake stream by adjusting the damper. The combustion manifold includes an air-fuel mixing system, a stoichiometric unit, and a refractory unit each coupled to one another. The laminar air intake stream traveling from the supply input module passes through a stoichiometric unit body to meet with a first combustion stream from an air-fuel mixing chamber within the stoichiometric unit body to define a second combustion stream. The second combustion stream then travels across the refractory passageway to define a third combustion stream.
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1. A combustion efficiency control system comprising: a laminar air delivery system, the laminar air delivery system including a blower;an air flow sensor arrangement, the air flow sensor arrangement including an air delivery controller, the air delivery controller electrically coupled to the blower
1. A combustion efficiency control system comprising: a laminar air delivery system, the laminar air delivery system including a blower;an air flow sensor arrangement, the air flow sensor arrangement including an air delivery controller, the air delivery controller electrically coupled to the blower,the air flow sensor arrangement measures laminar air flow and emits an efficiency signal, the air delivery controller receives the efficiency signal to control the flow of the laminar air intake stream by adjusting the blower;a combustion manifold, the combustion manifold in fluid communication with the laminar air delivery system; the laminar air delivery system, via the airflow sensor arrangement, provides a laminar air intake stream with a controlled flow to the combustion manifold, the combustion manifold includesan air-fuel mixing chamber system, the air-fuel mixing chamber system in fluid communication with the laminar air delivery system, and includes a mixing chamber and an injector device extending within the mixing chamber and along an alignment axis that extends through the combustion manifold, whereby fuel exits the injector device perpendicular to the laminar air intake stream traveling along the air-fuel mixing chamber system to combine to define a first combustion stream that flows along the alignment axis, anda stoichiometric combustion unit, the stoichiometric combustion unit in fluid communication with the air-fuel mixing chamber system, and includes a staging passageway and a stoichiometric unit body, the stoichiometric body includes a central axis that is defined by the alignment axis, a tube portion extending along the central axis as well as a mixing plate and a stoichiometric plate, each transversely fixed to opposing sides of the tube portion, the tube portion defines a plurality of air intakes, the plurality of air intakes pass through the tube portion, whereby the laminar air intake stream traveling along the staging passageway passes through the plurality of air intakes so as to enter a hollow of the tube portion to transversely intersect and combine with the first combustion stream that flows parallel to the alignment axis within the hollow of the tube portion of the stoichiometric unit body to define a second combustion stream that flows along the alignment axis;an air receiving port, the air receiving port configured to diffuse air received from the laminar air delivery system, the air receiving port, responsive to the blower regulated by the air delivery controller, diffuses air received from the laminar air delivery system to direct a plurality of laminar air intake streams to the combustion manifold; anda plurality of interchangeable reaction efficiency modules coupled to the stoichiometric combustion unit, at least one interchangeable reaction efficiency module of the plurality of interchangeable reaction efficiency modules receiving the second combustion stream. 2. The combustion efficiency control system according to claim 1 wherein the plurality of interchangeable reaction efficiency modules define a third combustion stream. 3. The combustion efficiency control system according to claim 2 wherein the plurality of interchangeable reaction efficiency modules receive the plurality of air intake streams. 4. The combustion efficiency control system according to claim 3 wherein at least one intake streams of the plurality of laminar air intake streams meet with the third combustion stream to define a fourth combustion stream. 5. The combustion efficiency control system according to claim 1 wherein the laminar air delivery system includes a damper, the damper in fluid communication with the blower. 6. The combustion efficiency control system according to claim 5 wherein the damper is electrically coupled to the blower and the air delivery controller, the air delivery controller receives the efficiency signal to control the flow of the laminar air intake stream by adjusting the damper. 7. The combustion efficiency control system according to claim 5 further comprising a sensor/controller, the sensor controller coupled to the damper. 8. The combustion efficiency control system according to claim 7 wherein the sensor/controller receives a predetermined wavelength of light to modify air supply by controlling the movement of the damper. 9. A combustion efficiency control system comprising: a laminar air delivery system, the laminar air delivery system including a damper;an air flow sensor arrangement, the air flow sensor arrangement including an air delivery controller, the air delivery controller electrically coupled to the damper, the air flow sensor arrangement measures laminar air flow and emits an efficiency signal, the air delivery controller receives the efficiency signal to control the flow of the laminar air intake streamby adjusting the damper;a combustion manifold, the combustion manifold in fluid communication with the laminar air delivery system; the laminar air delivery system, via the airflow sensor arrangement, provides a laminar air intake stream with a controlled flow to the combustion manifold, the combustion manifold includesan air-fuel mixing chamber system, the air-fuel mixing chamber system in fluid communication with the laminar air delivery system, and includes a mixing chamber and an injector device extending within the mixing chamber and along an alignment axis that extends through the combustion manifold, whereby fuel exits the injector device perpendicular to the laminar air intake stream traveling along the air-fuel mixing chamber system to combine to define a first combustion stream that flows along the alignment axis, anda stoichiometric combustion unit, the stoichiometric combustion unit in fluid communication with the air-fuel mixing chamber system, and includes a staging passageway and a stoichiometric unit body, the stoichiometric body includes a central axis that is defined by the alignment axis, a tube portion extending along the central axis as well as a mixing plate and a stoichiometric plate, each transversely fixed to opposing sides of the tube portion, the tube defines a plurality of air intakes whereby the laminar air intake stream traveling along the staging passageway passes through the plurality of air intakes so as to enter a hollow of the tube portion to transversely intersect and combine with the first combustion stream that flows parallel to the alignment axis within the hollow of the tube portion of the stoichiometric unit body to define a second combustion stream that flows along the alignment axis; anda plurality of interchangeable reaction efficiency modules coupled to the stoichiometric combustion unit and positioned along the alignment axis, at least one interchangeable reaction efficiency module of the plurality of reaction efficiency modules receiving the second combustion stream. 10. The combustion efficiency control system according to claim 9 further comprising an air receiving port, the air receiving port diffuses air received from the laminar air delivery system to direct a plurality of laminar air intake streams to the combustion manifold. 11. The combustion efficiency control system according to claim 10 wherein the plurality of interchangeable reaction efficiency modules receive the plurality of laminar air intake streams. 12. The combustion efficiency control system according to claim 10 wherein at least one intake streams of the plurality of air intake streams meets with the third combustion stream to define a fourth combustion stream. 13. The combustion efficiency control system according to claim 9 wherein the laminar air delivery system includes a blower, the blower in fluid communication with the damper. 14. The combustion efficiency control system according to claim 13 wherein the blower is electrically coupled to the damper and the air delivery controller, the air delivery controller receives the efficiency signal to control the flow of the laminar air intake stream by adjusting the blower. 15. The combustion efficiency control system according to claim 13 further comprising a sensor/controller, the sensor/controller coupled to the blower. 16. The combustion efficiency control system according to claim 15 wherein the sensor/controller receives a predetermined wavelength of light to modify air supply by controlling the fluid movement produced by the blower.
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