JPH0138183B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a float valve device provided in a carburetor for supplying an air-fuel mixture to an internal combustion engine.

The inventor of the present application previously disclosed in Japanese Patent Application No. 58-44287 that the vertical movement of a float that rises and falls in response to changes in the fuel liquid level in the float chamber is controlled by a toggle mechanism and a system connected in series to the toggle mechanism. It was proposed that the valve member for opening and closing the fuel inlet to the float chamber be communicated via a lever mechanism.
The torge mechanism greatly expands the buoyant force acting on the float in a relatively small space, and increases the rate of expansion in a curved manner. The force magnified by this toggle mechanism is further amplified by the lever mechanism and transmitted to the valve member.

Therefore, according to the float valve device in which the toggle mechanism and the lever mechanism are connected in series, reliable opening and closing operations can be given to the valve member,
Since accidental leakage of fuel from the fuel inlet into the float chamber can be reliably prevented, it is possible to reliably prevent the fuel level in the float chamber from exceeding a specified level. This enables stable fuel supply.

An object of the present invention is to provide a float valve device that can reliably open and close a fuel inlet to a float chamber with a simpler configuration.

The present invention includes a float disposed in a float chamber of a carburetor, a valve member for opening and closing a fuel inlet for introducing fuel into the float chamber, and a valve member disposed above the float, one end of which is pivoted to the float. an arm member mounted on the float and having its other end pivotally connected to the valve member, the arm member extending from an upper portion of the float integrally with the arm member to a side opposite to the valve member, and having a liquid in the float chamber. An arm portion is provided that is pivotally connected to a wall of the float to allow the float to move up and down in accordance with the rise and fall of a surface, and the one end of the arm member is connected to the float at a position closer to the arm portion than a buoyant force acting point of the float. By being pivotally connected to the valve member, the buoyancy force received by the float can be greatly expanded and applied to the valve member with an extremely simple structure.

The features of the present invention will become clearer from the following description of the illustrated embodiments.

The float valve device 10 according to the present invention has a first
As shown in the figure, there is a float chamber 16 defined by a housing 14 fixed to the carburetor body 12, a float 18 disposed within the float chamber, a valve member 20, and an arm member 22. including.

The housing 14 can be integrally formed with the carburetor body 12, and one side of the housing 14 includes:
A guide hole 24 extending laterally is formed to slidably receive the valve member 20 whose axis is laterally disposed. One end of the guide hole 24 opens into the float chamber 16 at the upper part thereof, and a valve seat opening 26 is formed at the other end of the guide hole 24 . The valve seat opening 26 is located in the housing 14
It communicates with a mouthpiece 28 provided at the base, which is connected, for example, to a conventionally well-known fuel pump (not shown). Therefore, when the tip of the valve member 20 is separated from the valve seat opening 26, the fuel pumped from the fuel pump flows from the valve seat opening 26 into the valve member 20 from the fuel inlet. It is introduced into the float chamber 16 through the side of the float chamber 16.

An air vent hole 30 similar to the conventional one is opened in the upper part of the float chamber 16. The fuel introduced into the float chamber 16 through the valve seat opening 26, which serves as a fuel inlet, flows through a well-known fuel guide path (not shown) extending from the bottom of the float chamber to the fuel nozzle of the carburetor. The fuel is then supplied to the internal combustion engine according to its operating conditions.

The float 18 is a hollow box-shaped member made of, for example, a synthetic resin material, and on the side opposite to the side adjacent to the valve member, there is a support plate extending obliquely upward from the upper surface portion 18a to the side opposite to the valve member. arm part 3
2 are integrally formed. An extension line 34 of the longitudinal axis of the arm portion 32 passes through the center portion C of the upper surface portion 18a of the float, along which a vertical line (line of buoyancy action) passes through the point of action (center of buoyancy) of the buoyant force F received by the float. Further, the tip of the arm portion 32 is
a first pivot 36 extending laterally at right angles to the axis of the valve member on the side opposite to the valve member 20, ie opposite to the guide hole 24 for slidably receiving the valve member; It is pivotally connected to the housing 14, which is the wall of the float chamber, through the float chamber. Therefore, the float 18 responds to changes in the fuel level H in the float chamber 16.
It is swingable in the vertical direction around the first pivot.

An arm member 22 is disposed between the float and the valve member so that the valve member 20 slides along the guide hole 24 by the vertical movement of the float 18. The center portion C of the float upper surface portion 18a and the arm portion 32
A bearing portion 4 for receiving a second pivot 38 provided at one end of the arm member 22 is provided between the
0 is provided apart from the arm portion,
As a result, the one end of the arm member 22 is pivotally connected to the float 18 on the side closer to the arm portion than the center portion C via a second pivot shaft parallel to the first pivot shaft 36. The other end of the arm member 22 is also pivotally attached to the base of the valve member 20 via a third pivot 42 parallel to the first and second pivots 36 and 38.

A line connecting the centers of each of the first, second, and third pivots 36, 38, and 42 forms a triangle, and the second axis 38 is greater than the line h connecting the centers of each of the first and third pivots. It is located on the side of the float 18. Therefore, when the fuel level H in the float chamber 16 falls below the specified value shown in FIG. 1, the valve member 20 moves away from the valve seat opening 26 due to the downward movement of the float 18. is actuated via the arm member 22, thereby introducing fuel into the float chamber from the fuel inlet 26. Further, when the float moves upward as the fuel level H rises, the valve member 20 moves the arm to close the valve seat opening 26, which is the fuel inlet. The valve member 20 is operated toward the opening of the valve seat, and the opening/closing operation of the valve member 20 maintains the fuel level H at approximately a specified value.

Regarding the vertical movement of the float 18 described above, the buoyant force F acting on the float is the lever ratio of the arm portion 32, that is, the first fulcrum which is the fulcrum of the float 18.
The distance L ₁ from the pivot 36 to the central portion C is increased by the ratio of the distance L ₂ from the first pivot 36 to the second pivot 38 which is the pivot point of the arm member 22, and It acts on the pivot shaft 38 of No. 2 upward in the figure. The one end of the arm member is connected to the center portion C.
If the arm member is pivoted to the float on the side opposite to the arm member, the lever ratio becomes a value of 1.0 or less, and the buoyancy force F is reduced, but as described above, the one end of the arm member Since it is pivotally attached to the float closer to the arm than the center C, the buoyant force F is increased by the lever ratio.

Furthermore, the buoyancy force (F×L ₁ /L ₂ ) expanded by a constant lever ratio (L ₁ /L ₂ ) is
2 and the arm member 22, the force is magnified by the toggle ratio (T).
As a result, the valve member 20 opens the fuel inlet 2
6, it is pressed against the fuel inlet with a strong acting force (F×L ₁ /L ₂ ×T). The force magnification rate (T) due to this toggle mechanism does not exhibit a linear characteristic like the lever ratio, but is
As the angle θ between the line h connecting the centers of the two centers and the axis of the arm portion 32 decreases, it increases quadratically.

Therefore, according to the float valve device 10, the valve member can be reliably operated to maintain the fuel level H in the float chamber constant, and the fuel level H can be maintained as shown in FIG. When at a specified value as shown, said valve member 20
can be pressed against the fuel inlet 26 with strong force to reliably close the fuel inlet.
The fuel level H in the float chamber can be reliably prevented from exceeding a specified value, and the fuel level can be maintained at an appropriate level.

Instead of forming the bearing part 40 for receiving the second pivot 38 provided at the one end of the arm member 22 independently of the arm part 32, as shown in FIG. It can be formed at the base of the arm portion 32.

According to the present invention, as described above, the arm portion is provided integrally with the float and is pivotally connected to the wall surface of the float chamber, and one end is pivotally connected to the float and the other end is pivotally connected to the valve member. The buoyant force acting on the float is reduced to a constant lever ratio (L ₁ /L ₂ ) by an extremely simple structure consisting of a
The toggle ratio (T), which increases quadratically as the valve member approaches its closed position, can greatly expand the effect on the valve member. Therefore, the fuel inlet can be reliably opened and closed with a relatively simple configuration without independently providing a toggle mechanism and a lever mechanism, thereby preventing accidental inflow of fuel from the fuel inlet into the float chamber. By reliably preventing leakage of the fuel and reliably preventing the fuel level in the float chamber from exceeding a specified level, stable fuel supply to the internal combustion engine becomes possible.

[Brief explanation of drawings]

FIG. 1 is a longitudinal sectional view of a float valve device according to the present invention, and FIG. 2 is a drawing similar to FIG. 1 showing another embodiment of the present invention. 14: Housing (wall surface), 16: Float chamber,
18: Float, 18a: Upper surface of float, 2
0: Valve member, 22: Arm member, 26: Fuel inlet (valve seat opening), 32: Arm portion, 34: Extension line of arm portion, 36, 38, 42: Pivot, 40: Bearing portion.

Claims (1)

[Scope of Claims] 1. A float disposed in a float chamber of a carburetor, a valve member for opening and closing a fuel inlet for introducing fuel into the float chamber, and a valve member disposed above the float, one end of which is connected to the float chamber. an arm member pivotally connected to the float and having its other end pivotally connected to the valve member; An arm is pivotally connected to the wall of the float chamber to allow the float to move up and down in accordance with the rise and fall of the liquid level in the chamber, and the one end of the arm member is located closer to the arm than the buoyant force acting point of the float. A float valve device for a carburetor, characterized in that it is pivotally connected to the float on its side. 2. The arm portion is pivotally connected to the wall surface of the float chamber via a first pivot, and the arm member is coupled to the wall of the float chamber via second and third pivots, respectively, having axes parallel to the first pivot. the float and the valve member, a line connecting the centers of the first, second and third pivots forming a triangle, and the second pivot extending from the centers of the first and third pivots; The float valve device according to claim 1, wherein the float valve device is located closer to the float than a line connecting the float valves. 3. An extension of the longitudinal axis of the arm section passes through the center of the upper surface of the float, through which a vertical line passing through the point of buoyancy application of the float passes, and the second pivot axis is disposed on the extension line. A float valve device according to claim 2. 4. Claim 3, wherein a bearing part is provided on the upper surface of the float at a position apart from the arm part, and the second pivot shaft is supported by the bearing part.
Float valve device as described in Section. 5. A bearing portion is provided at the base of the arm portion,
4. The float valve device according to claim 3, wherein the second pivot is supported by the bearing portion.