The present invention relates generally to a carburetor and more particularly to a carburetor having a butterfly type throttle valve.
As shown in
In the above-described diaphragm type carburetor, fuel in the fuel metering chamber 13 is directly taken into the air intake passage 30 from the pilot fuel nozzle holes 28a. Fuel is not always sufficiently mixed with air in the air intake passage 30, and particularly during idle operation of the engine, fuel from the low speed fuel nozzle hole 28 may collect on the throttle valve 24 to the inner peripheral wall of the air intake passage 30, and the mixture of fuel and air is not always supplied to the engine in a stabilized manner. Particularly, when fuel that had collected on the inner wall of the air intake passage 30 suddenly enters the airflow through the air intake passage 30 due, for example, to the tilting of the carburetor body, a richer than desired fuel and air mixture is supplied to the engine momentarily, and may adversely affect idle operation of the engine. In extreme cases, the fuel and air mixture may be so rich that the engine stalls, and immediate re-starting of the engine may be difficult.
The carburetor as shown in
Further, in the conventional float type carburetor, as shown in
An idle fuel supply device for a carburetor has an idle air passage that communicates with an air intake passage and a fuel chamber. A passage extending from a fuel metering chamber is connected to the fuel chamber preferably via a fuel adjusting needle valve. A low speed fuel nozzle hole communicates the fuel chamber with the air intake passage in the vicinity of a throttle valve when in its idle position. A passage communicates with the fuel chamber and the idle air passage, so that fuel and air may mix in at least a portion of the idle air passage.
According to one presently preferred embodiment of a carburetor, a fuel jet is provided in the passage communicating the fuel metering chamber with the fuel chamber, and a fuel adjusting needle valve is provided in the passage communicating the fuel chamber and the idle air passage. The needle valve may have a valve chamber that communicates with the idle air passage. According to other embodiments, the invention may also be employed in float-type carburetors.
These and other objects, features and advantages of the present invention will be apparent from the following detailed description of the preferred embodiments, appended claims and accompanying drawings in which:
As shown in
In the fuel metering assembly B, a cover plate 8 and a fuel metering diaphragm 9 are connected to the carburetor body 32, and the fuel metering chamber 13 and an atmospheric chamber 33 are formed on the opposed sides of the diaphragm 9. One end of a lever 10 pivotally supported by a shaft 12 is yieldably biased into engagement with a center protrusion of the diaphragm 9 by a force of a spring 6 while the other end of the lever 10 is engaged with the lower end of the inlet valve 7. When the volume of fuel in the fuel metering chamber 13 reduces, the resultant force of intake pressure exerted on the fuel metering chamber side of the diaphragm 9 becomes greater than the force of the spring 6, the lever 10 is pivoted or rotated to open the inlet valve 7, and fuel is supplied from the fuel pump A to the fuel metering chamber 13. The fuel pump A and fuel metering assembly B and their components may be of conventional construction, and are also shown in
A fuel chamber 27 is provided in the carburetor body 32, preferably adjacent to a throttle valve 24 disposed in the air intake passage 30 on a valve shaft 25. A passage 2 communicates with the fuel metering chamber 13 and the fuel chamber 27 via a fuel adjusting needle valve 31. A plurality of low speed fuel nozzle holes 28 communicate with the fuel chamber 27 and the air intake passage 30 upstream of the throttle valve 24 when the throttle valve is in its idle position. Further, the fuel metering chamber 13 is connected to a high speed fuel nozzle hole 29 opened to a venturi portion 30a of the air intake passage 30 via a fuel jet 5, a passage 3 and a check valve 29a.
To supply atomized fuel during idle operation of the engine, an idle air passage 26 is provided in communication with the air intake passage and with the fuel chamber 27. Preferably, the idle air passage 26 is open to the air intake passage 30 upstream of the throttle valve at one end, and downstream of the throttle valve at its other end, at least when the throttle valve is in its idle position. A passage 2a extending from the fuel chamber 27 is connected to the idle air passage 26 preferably between the ends of the idle air passage 26.
With this arrangement, an air flow moving from the upstream end toward the downstream end of the air intake passage 30 is generated in the idle air passage 26 due to a pressure difference between the upstream end and the downstream end during idle operation of the engine. Accordingly, fuel in the fuel chamber 27 is taken into the idle air passage 26, is mixed with air or atomized in the idle air passage 26 and is taken into the air intake passage 30. Thus, a mixture for which atomization is accelerated in the idle air passage 26 is taken into the air intake passage 30, and therefore fuel does not collect on the peripheral wall of the air intake passage 30, and the mixture is supplied to the engine in a stable and continuous flow, thereby improving steady idle engine operation.
While in the embodiment shown in
The embodiment shown in
A plurality of low speed fuel nozzle holes 28 communicate the fuel chamber 27 with the air intake passage 30 upstream of the throttle valve 24 when the throttle valve 24 is in its idle position. The passage 31a surrounding the needle end of the fuel adjusting needle valve 31 is connected to the idle air passage 26.
A fuel reservoir 56 is fastened by a bolt 60 to the lower end of a column 55 projecting downward form the bottom of the carburetor body 32. The upper end peripheral portion of the fuel reservoir 56 is closely mounted on the bottom of the carburetor body 32 through a seal member 53. A well known horseshoe-shaped float 54 is enclosed inside the fuel reservoir 56, that is, in a float chamber 57. An inlet valve, not shown, is opened and closed due to the vertical movement of the float 54, and fuel is suitably replenished to the float chamber 57. A cylindrical bore 51 as an extending portion of a tapped hole engaging with the bolt 60 is provided on the column 55, an inlet 59 in communication with the float chamber 57 is provided on part of the bore 51, and a fuel jet 58 and a high speed fuel supply pipe 50a are fitted. The fuel supply pipe has a vacant portion relative to the bore 51, and an air passage 52 opened to the inlet of the air intake passage 30 is connected to the bore 51.
Air in the bore 51 enters into the high speed fuel supply pipe 50a through a plurality of through-holes provided in the peripheral wall of the high speed fuel supply pipe 50a, is mixed with fuel flowing into the high speed fuel supply pipe 50a via the fuel jet 58, and is taken into a venturi portion 30a of the air intake passage 30 from a high speed fuel nozzle hole 50. On the other hand, fuel in the high speed fuel supply pipe 50a flows into the air passage 42 through the low speed fuel supply pipe 47 and the fuel jet 46, and is supplied to the air intake passage 30 upstream of the throttle valve 24 via the fuel chamber 27, while mixing with air in the air passage 42, and the low speed fuel nozzle holes 28. Further, the fuel and air mixture in the fuel chamber 27 is supplied to the air intake passage 30 downstream of the throttle valve 24 via the fuel adjusting needle valve 31, the passage 31a and the idle air passage 26. When forming the idle air passage 26 in the arrangement shown, the idle air passage 26 is extended to the end wall of the carburetor body 32, and the end of the idle air passage 26 is closed by a plug. A portion of the idle air passage 26 extending obliquely to the air intake passage 30 is formed from the peripheral wall of the air intake passage 30. Preferably, a choke valve 49 is supported by a valve shaft 48 at the inlet portion of the air intake passage 30.
In the embodiment shown in
The idle air passage provides an airflow, fuel in the fuel chamber is taken into the flow of air, and fuel is mixed with air in the idle air passage. Atomization of fuel is accelerated and fuel is taken into the air intake passage, because of which fuel does not collect on the inner peripheral wall of the air intake passage. Accordingly, atomized fuel is supplied to the engine via the air intake passage to provide stable idle operation of the engine.
Number | Date | Country | Kind |
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2002-062856 | Mar 2002 | JP | national |
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54-116523 | Sep 1979 | JP |
Number | Date | Country | |
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20030168753 A1 | Sep 2003 | US |