A method for operating a furnace system includes initiating a start sequence comprising starting an inducer fan operative to induce an air flow through a burner assembly, a heat exchanger portion and a collector portion, determining whether an air pressure in the collector portion is above a first t
A method for operating a furnace system includes initiating a start sequence comprising starting an inducer fan operative to induce an air flow through a burner assembly, a heat exchanger portion and a collector portion, determining whether an air pressure in the collector portion is above a first threshold value, starting a furnace ignition sequence including providing fuel to the burner assembly, igniting a fuel and air mixture and starting an ignition timer responsive to determining that the air pressure in the collector portion is above the first threshold value, determining whether the ignition timer has expired, determining whether the air pressure in the collector portion is above a second threshold value responsive to determining that the ignition timer has expired, and stopping the provision of fuel to the burner assembly responsive to determining that the air pressure in the collector portion is not above the second threshold value.
대표청구항▼
1. A method for operating a furnace system, the method comprising: receiving a start instruction at a controller;initiating a start sequence comprising: starting an inducer fan operative to induce an air flow through a burner assembly, a heat exchanger portion and a collector portion;comparing an ai
1. A method for operating a furnace system, the method comprising: receiving a start instruction at a controller;initiating a start sequence comprising: starting an inducer fan operative to induce an air flow through a burner assembly, a heat exchanger portion and a collector portion;comparing an air pressure to a first threshold value;starting a furnace ignition sequence including providing fuel to the burner assembly, mixing the fuel with induced air, igniting the fuel and air mixture and starting an ignition timer responsive to determining that the air pressure is above the first threshold value;determining whether the ignition timer has expired;determining whether the air pressure is above a second threshold value responsive to determining that the ignition timer has expired; andstopping the provision of fuel to the burner assembly responsive to determining that the air pressure is not above the second threshold value;wherein the first threshold value is less than the second threshold value. 2. The method of claim 1, wherein the method further comprises outputting a fault indicator responsive to determining that the air pressure is not above the first threshold value. 3. The method of claim 1, wherein the method further comprises stopping the provision of fuel to the burner assembly responsive to determining that the air pressure is not above the first threshold value. 4. The method of claim 1, wherein the method further comprises sending a fault indication responsive to determining that the air pressure is not above the second threshold value. 5. The method of claim 1, wherein the method further comprises: incrementing a fault counter responsive to determining that the air pressure is not above the second threshold value;determining whether the fault counter has reached a fault counter threshold value; andinitiating the start sequence responsive to determining that the fault counter has not reached the fault counter threshold value. 6. The method of claim 1, wherein the air pressure comprises air pressure in the collector portion. 7. The method of claim 1, wherein determining that the air pressure is above the first threshold value is based on air pressure in the collector portion and determining whether the air pressure is above the second threshold value is based on air pressure in an inducer portion. 8. The method of claim 1, wherein the air pressure comprises air pressure in at least one of the collector portion and an inducer portion. 9. A method for operating a furnace system, the method comprising: receiving a start instruction at a controller;initiating a start sequence comprising: starting an inducer fan operative to induce an air flow through a burner assembly, a heat exchanger portion and a collector portion;comparing an air pressure to a first threshold value;starting a furnace ignition sequence including providing fuel to the burner assembly, mixing the fuel with induced air, igniting the fuel and air mixture and starting an ignition timer responsive to determining that the air pressure is above the first threshold value;determining whether the ignition timer has expired;determining whether the air pressure is above a second threshold value responsive to determining that the ignition timer has expired;stopping the provision of fuel to the burner assembly responsive to determining that the air pressure is not above the second threshold value;incrementing a fault counter responsive to determining that the air pressure is not above the second threshold value;determining whether the fault counter has reached a fault counter threshold value; andinitiating the start sequence responsive to determining that the fault counter has not reached the fault counter threshold value;starting a fault timer responsive to determining that the fault counter has reached the fault counter threshold value;determining whether the fault timer has expired; andinitiating the start sequence responsive to determining that the fault timer has expired. 10. A furnace system comprising: an inlet duct communicatively connected to an air source and a burner assembly;a heat exchanger portion communicatively connected to an output of the burner assembly;a collector portion communicatively connected to an output of the heat exchanger assembly;an inducer portion communicatively connected to an output of the collector portion and an exhaust duct;a gas valve communicatively connected to a fuel source and the burner assembly;a first pressure sensor operative to sense a pressure in the collector portion;a second pressure sensor operative to sense a second pressure in the collector portion; anda controller operative to control the gas valve, and the inducer portion, the controller operative to receive a start instruction, initiating a start sequence comprising starting the inducer portion, receive a signal from the first pressure sensor and determine whether the sensed pressure is above a first threshold value, starting a furnace ignition sequence including controlling the gas valve to provide fuel to the burner assembly and starting an ignition timer responsive to determining that an air pressure in the collector portion is above the first threshold value, determining whether the air pressure in the collector portion is above a second threshold value, and stopping the provision of fuel to the burner assembly by controlling the gas valve responsive to determining that the air pressure in the collector portion is not above the second threshold value; wherein the first threshold value is less than the second threshold value. 11. The system of claim 10, wherein the start sequence further comprises outputting a fault indicator responsive to determining that the air pressure in the collector portion is not above the first threshold value. 12. The system of claim 10, wherein the start sequence further comprises stopping the provision of fuel to the burner assembly responsive to determining that the air pressure in the collector portion is not above the first threshold value. 13. The system of claim 10, wherein the start sequence further comprises outputting a fault indication responsive to determining that the air pressure in the collector portion is not above the second threshold value. 14. A furnace system comprising: an inlet duct communicatively connected to an air source and a burner assembly;a heat exchanger portion communicatively connected to an output of the burner assembly;a collector portion communicatively connected to an output of the heat exchanger assembly;an inducer portion communicatively connected to an output of the collector portion and an exhaust duct;a gas valve communicatively connected to a fuel source and the burner assembly;a first pressure sensor operative to sense a pressure in the collector portion;a second pressure sensor operative to sense a pressure in the inducer portion; anda controller operative to control the gas valve, and the inducer portion, the controller operative to receive a start instruction, initiating a start sequence comprising starting the inducer portion, receive a signal from the first pressure sensor and determine whether the sensed pressure is above a first threshold value, starting a furnace ignition sequence including controlling the gas valve to provide fuel to the burner assembly and starting an ignition timer responsive to determining that an air pressure in the collector portion is above the first threshold value, determining whether the air pressure in the inducer portion is above a second threshold value, and stopping the provision of fuel to the burner assembly by controlling the gas valve responsive to determining that the air pressure in the inducer portion is not above the second threshold value;wherein the first threshold value is less than the second threshold value. 15. The system of claim 14, wherein the start sequence further comprises outputting a fault indicator responsive to determining that the air pressure in the collector portion is not above the first threshold value. 16. The system of claim 14, wherein the start sequence further comprises stopping the provision of fuel to the burner assembly responsive to determining that the air pressure in the collector portion is not above the first threshold value. 17. The system of claim 14, wherein the start sequence further comprises outputting a fault indication responsive to determining that the air pressure in the collector portion is not above the second threshold value.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (26)
Thompson Kevin D. (Indianapolis IN), Adaptive microprocessor control system and method for providing high and low heating modes in a furnace.
Katchka Jay R. (Cypress CA) Haddad Nabil M. (Santa Ana CA), Heat exchanger control system, control valve device therefor and methods of making the same.
Weber ; III Richard H. (Lafayette IN) Richardson Paul T. (Indianapolis IN) Langenkamp David E. (Lafayette IN) Gable Gerald K. (Carmel IN), Heat-exchanger especially for forced air furnaces.
Rowlette Mitchell R. (Berea KY) Ting Youn H. (Lexington KY) Bailey Walter H. (Versailles KY) Garnett Ronald E. (Lexington KY), Induced draft fan control for use with gas furnaces.
Ripka Chester D. (E. Syracuse NY) Clark Daniel R. (Fayetteville NY), Method and apparatus for controlling fuel-to-air ratio of the combustible gas supply of a radiant burner.
Landis William R. (Bloomington MN) Schimbke Paul A. (Shorewood WI) Seidel Michael J. (Wauwatosa WI), Method and apparatus for monitoring pressure sensors.
Kyeong Soo Kim KR; Yeong Soo Kim KR; In Kyu Kim KR; Yang Ho Kim KR, Pressure sensing device in gas furnace and method for controlling operation thereof.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.