Mass-airflow measurement conversion apparatus for internal combustion engine carburetors
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02D-041/18
G01M-015/09
G01F-001/34
G01K-013/02
G01M-015/04
F02M-019/10
출원번호
US-0484031
(2017-04-10)
등록번호
US-10132261
(2018-11-20)
발명자
/ 주소
Bowling, Bruce A.
Grippo, Albert C.
출원인 / 주소
BG SOFLEX LLC
대리인 / 주소
Kilpatrick Townsend & Stockton LLP
인용정보
피인용 횟수 :
0인용 특허 :
12
초록▼
A mass air flow measurement apparatus for an internal combustion engine includes: a plurality of pressure sensors disposed at different locations along an air intake path of the internal combustion engine, each pressure sensor adapted to sense a pressure of air flowing into the internal combustion e
A mass air flow measurement apparatus for an internal combustion engine includes: a plurality of pressure sensors disposed at different locations along an air intake path of the internal combustion engine, each pressure sensor adapted to sense a pressure of air flowing into the internal combustion engine and output an electrical signal as a pressure signal corresponding to the sensed air pressure; a carburetor having a plurality of booster venturis, the carburetor rendered permanently inoperable to mix fuel with air flowing in the air intake path, a body of the carburetor configured to accept one or more of the plurality of pressure sensors for each of the plurality of booster venturis; and a calculation section that receives the pressure signals and generates a mass air flow signal as an output signal to an engine management system to control an electronic fuel injection system based on the received pressure signals.
대표청구항▼
1. A mass air flow measurement apparatus for an internal combustion engine, the apparatus comprising: a plurality of pressure sensors disposed at different locations along an air intake path of the internal combustion engine, each pressure sensor adapted to sense a pressure of air flowing into the i
1. A mass air flow measurement apparatus for an internal combustion engine, the apparatus comprising: a plurality of pressure sensors disposed at different locations along an air intake path of the internal combustion engine, each pressure sensor adapted to sense a pressure of air flowing into the internal combustion engine and output an electrical signal as a pressure signal corresponding to the sensed air pressure;a carburetor having a plurality of booster venturis, the carburetor rendered permanently inoperable to mix fuel with air flowing in the air intake path, a body of the carburetor configured to accept one or more of the plurality of pressure sensors for each of the plurality of booster venturis; anda calculation section that receives the pressure signals and generates a mass air flow signal as an output signal to an engine management system to control an electronic fuel injection system based on the received pressure signals. 2. The apparatus of claim 1, wherein the plurality of pressure sensors comprises a booster venturi pressure sensor disposed on the carburetor for each of the plurality of booster venturis, wherein each of the booster venturi pressure sensors is configured to output an analog signal corresponding to an air pressure in each of the plurality of booster venturis. 3. The apparatus of claim 1, wherein the pressure signals are analog signals, and wherein the calculation section further comprises one or more analog-to-digital converters that input the analog signals and convert the analog signals to digital pressure signals from each of the plurality of booster venturis. 4. The apparatus of claim 3, wherein the calculation section further comprises a processor that inputs the digital pressure signals and processes the digital pressure signals to output a digital signal representing a mass air flow rate; and a memory that stores a program for causing the processor to process the digital pressure signals. 5. The apparatus claim 4, wherein the calculation section further comprises a digital-to-analog converter that inputs the digital signal representing the mass air flow rate and outputs an analog voltage signal representing the mass air flow rate. 6. The apparatus claim 4, wherein the calculation section further comprises a timer that inputs the digital signal representing the mass air flow rate and outputs a signal having a frequency representing the mass air flow rate. 7. The apparatus of claim 4, further comprising one or more throttle position sensor that output one or more analog electrical signals corresponding to a position of one or more throttle plates corresponding to each of the plurality of booster venturis that control the air flowing into the internal combustion engine through the carburetor as one or more throttle position signals; and an inlet air temperature sensor disposed at an entrance to the air intake path and adapted to measure a temperature of air entering the air intake path and output an analog electrical signal as a temperature signal corresponding to sensed inlet air temperature,wherein the one or more analog-to-digital converters input the one or more analog electrical signals corresponding to the positions of the one or more throttle plates and the analog electrical signal corresponding to the sensed inlet air temperature and convert the analog electrical signals to a digital throttle position signal and a digital temperature signal, respectively, andwherein the processor inputs the digital throttle position signal, the digital temperature signal, and an engine crankshaft revolutions per minute (rpm) signal, and processes the digital pressure signals, the digital throttle position signal, the digital temperature signal, and the engine crankshaft revolutions per minute (rpm) signal and outputs a digital signal representing a mass air flow rate. 8. The apparatus claim 7, wherein the calculation section further comprises a digital-to-analog converter that inputs the digital signal representing the mass air flow rate and outputs an analog voltage signal representing the mass air flow rate to the engine management system. 9. The apparatus claim 7, wherein the calculation section further comprises a timer that inputs the digital signal representing the mass air flow rate and outputs a signal having a frequency representing the mass air flow rate. 10. A method of retrofitting an existing internal combustion engine carburetor having a plurality of booster venturis for mass air flow rate measurement, the method comprising: rendering the carburetor permanently inoperable to mix fuel with air flowing in an air intake path;installing pressure sensors that measure air pressure at several different points along an airflow path through the plurality of booster venturis of the carburetor;installing an air temperature sensor, and a throttle angle position sensor; andinstalling a controller that receives and processes information received from the sensors and generates an output signal representing engine mass air flow rate. 11. The method of claim 10, wherein the installing pressure sensors that measure air pressure at several different points along an airflow path through the carburetor comprises installing a booster venturi pressure sensor on the carburetor for each of the plurality of booster venturis, wherein each booster venturi pressure sensor is configured to output an electrical signal corresponding to booster venturi pressure for a corresponding one of the plurality of booster venturis, andwherein the controller generates the output signal representing engine mass air flow rate based at least in part on the on the electrical signals corresponding to booster venturi pressure of each of the plurality of booster venturis. 12. The method of claim 11, wherein the installing a throttle angle position sensor comprises installing one or more throttle angle position sensors for one or more throttle plates, each of the one or more throttle plates corresponding to one of the plurality of booster venturis. 13. The method of claim 12, wherein the installing pressure sensors that measure air pressure at several different points along an airflow path through the carburetor comprises installing pressure sensors on the carburetor that measure a pressure of air below each of the one or more throttle plates corresponding to one of the plurality of booster venturis. 14. The method of claim 13, wherein the installing pressure sensors that measure air pressure at several different points along an airflow path through the carburetor comprises installing a pressure sensor that measures a pressure of incoming air to sense barometric pressure. 15. The method of claim 14, wherein the installing an air temperature sensor comprises installing an air temperature sensor at an entrance to the air intake path, wherein the air temperature sensor measures a temperature of air entering the air intake path and outputs an analog electrical signal as a temperature signal corresponding to sensed inlet air temperature. 16. The method of claim 15, wherein the controller generates an output signal corresponding to a mass air flow rate based on the temperature signal and signals from the pressure sensors corresponding to the pressure of air flowing through the plurality of booster venturis, the pressure of air below the one or more throttle plates, and the pressure of incoming air to an engine management system to control an electronic fuel injection system. 17. The method of claim 10, further comprising installing the controller remotely from the carburetor. 18. A mass airflow measurement conversion apparatus for internal combustion engine carburetors, the apparatus comprising: a carburetor having a plurality of booster venturis and one or more throttle plates, the carburetor rendered permanently inoperable to mix fuel with air flowing in the air intake path, and one or more throttle plates corresponding to each of the plurality of booster venturis;a plurality of pressure sensors mounted to the carburetor, each pressure sensor adapted to sense a pressure of air flowing into the internal combustion engine at a different position along an air intake path and output an electrical signal as a pressure signal corresponding to the sensed air pressure;an air temperature sensor disposed at an entrance to the air intake path and adapted to measure temperature of air entering the air intake path and output an electrical signal as a temperature signal corresponding to the sensed air temperature; anda controller that receives the pressure signals and the temperature signal and generates a mass air flow signal as an output signal to an electronic fuel injection system based on the received pressure signals and temperature signal. 19. The apparatus of claim 18, wherein the plurality of pressure sensors comprises: a booster venturi pressure sensor disposed on the carburetor for each of the plurality of booster venturis and configured to output an electrical signal corresponding to an air pressure in each of the plurality of booster venturis;a plurality of manifold pressure sensors disposed on the carburetor that measure a pressure of air below each of the one or more throttle plates corresponding to one of the plurality of booster venturis; andbarometric pressure sensor disposed on the carburetor that measures a pressure of incoming in air the air intake path. 20. The apparatus of claim 19, wherein the controller generates an output signal corresponding to a mass air flow rate based on the temperature signal and signals from the pressure sensors corresponding to the pressure of air flowing through the plurality of booster venturis, the pressure of air below the one or more throttle plates, and the pressure of incoming air to an engine management system to control an electronic fuel injection system.
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이 특허에 인용된 특허 (12)
Kataoka Ryuji (Mitaka JPX), Air-fuel ratio control system for an automotive engine.
Marsh Richard A. (Beverly Hills MI) Garrett David P. (Sylvan Lake MI) Bauerle Paul A. (Dewitt MI) Mathews David S. (Okemos MI) Vanek Michael J. (South Lyon MI) Cubr Anthony E. (Flint MI), Method for controlling ignition timing for an internal combustion engine.
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