Diaphragm-type carburetor

Abstract
The present invention facilitates increased output, decreased size, and simplified design and manufacture for a carburetor system in which a metering pin, which moves on a throttle valve, controls the fuel flow rate for a single fuel system. A carburetor of the present invention includes a butterfly-like throttle valve on an air intake pathway with a nearly uniform diameter along its entire length, and a fuel nozzle positioned on the downstream side thereof. A metering pin retained by an actuating member that reciprocates linearly and remains in constant contact with a cam face of a cam member located on a valve stem. Fuel supplied to the air intake pathway from a constant fuel chamber via the fuel nozzle is controlled according to the opening and closing of a throttle. The metering pin by means of a cam controls the volume of the fuel flow rate at a desired stroke set irrespective of the opening and closing movement of the throttle valve.
Description




FIELD OF THE INVENTION




The invention primarily relates to a diaphragm-type carburetor for supplying fuel to general-purpose engines and, more particularly, relates to a diaphragm-type carburetor comprising a butterfly-type throttle valve and a single fuel nozzle that allows fuel measured in accordance with the opening or closing of the throttle valve to be sent from the fuel nozzle.




BACKGROUND OF THE INVENTION




Two- and four-cycle general-purpose engines are small in size, and small diaphragm-type carburetors are often used to supply fuel thereto. Examples of commonly known diaphragm-type carburetors are the fixed venturi model discussed in Japanese Kokai S55-69748, which comprises a butterfly-type throttle valve and two fuel systems, a low-speed system and a main system; the variable venturi model presented in Japanese examined utility model application No. S49-17682, which comprises a single fuel system capable of supplying a variable amount of fuel by means of a cylindrical sliding throttle valve and a metering pin attached to the sliding throttle; and the carburetor described in Japanese Kokai S58-101253, which comprises a single fuel system capable of supplying a variable amount of fuel by means of a cylindrical rotary throttle valve and a metering pin attached to the rotary throttle valve.




The control of the fuel supply by the metering pin in response to axial movement of the sliding or rotary throttle valve in the single fuel system models is beneficial in that it requires no special consideration for fuel-related connections and, unlike the models with two fuel systems, includes a simple pathway structure. In addition, the cross sectional area of the sliding or rotary throttle valve, when fully open, is identical to that of the air intake pathway, thus beneficially allowing such models to more easily supply the required volume of air at times of high output than the fixed venturi model.




The sliding valve linearly reciprocates along a length nearly identical to the diameter of the air intake pathway. As a result, a spacing of a size at least equivalent to the stroke of the sliding throttle valve must be provided between a constant fuel chamber, which contains a constant amount of fuel by means of a diaphragm, and the opening of the fuel nozzle to the air intake pathway in order to accommodate a metering pin that operates integrally with the sliding throttle valve. For this reason, the air intake pathway cannot be made sufficiently small. As far as the rotary throttle valve, it moves slightly in the central axial direction as it rotates so that a metering pin that moves integrally with the rotating throttle valve can control the amount of fuel supplied. Because minute movements of the metering pin control the required fuel amounts for all operating levels of the engine, the dimensional and positional relationships between the fuel nozzle and the metering pin have to be set with a high degree of accuracy, which poses design and manufacturing problems.




SUMMARY OF THE INVENTION




The present invention was created in order to solve the above problems of the fixed venturi, sliding throttle valve, and rotary throttle diaphragm-type carburetors—including those problems related to a transition to high output, fuel-related connections, miniaturization of the carburetor, and design and construction simplicity. A primary object of the present invention is to provide a diaphragm-type carburetor that enables high output and miniaturization of the carburetor as a whole, yet poses no particular design or manufacturing problems.




In order to solve the above problems, the present invention provides a diaphragm-type carburetor comprising an air intake pathway that penetrates a body and is formed with a nearly uniform diameter along its entire length, a constant fuel chamber that is provided along one face of the body and contains a constant amount of fuel by means of a diaphragm, a butterfly-type throttle valve that opens and closes the air intake pathway, a fuel nozzle that is disposed on the downstream side of the throttle valve and supplies fuel introduced from the constant fuel chamber to the air intake pathway, a metering pin having a tip thereof inserted into the fuel nozzle, a cam member centered on a valve stem of the throttle valve and having an arc-shaped cam face, and an actuating member that makes constant contact with the cam face and reciprocates linearly. The metering pin, which is held by the actuating member, reciprocates linearly following the opening and closing of the throttle valve, and controls the amount of fuel supplied from the fuel nozzle to the air intake pathway.




Because the air intake pathway lacks a venturi and has a nearly uniform diameter along its entire length, it can easily provide the airflow rate required during high output. Additionally, because the throttle valve is a butterfly-type throttle valve, the valve stem length is shorter than the sliding and rotary models. This allows for miniaturization of the carburetor as a whole. Moreover, the fuel nozzle is positioned on the downstream side of the throttle valve and the fuel supply amount is controlled by the metering pin, which follows the throttle via a cam mechanism. Therefore, the required fuel rate can be controlled over an entire operating range of the engine with a single fuel system. In this case, the stroke of the metering pin may be set as desired with the cam irrespective of the throttle valve. As a result, the function of appropriately controlling the amount of fuel supplied over the entire operation range of the engine can be easily provided.




In the above embodiment of the invention, the actuating member has a contact portion that makes contact with the cam face and a retaining member for retaining the metering pin, and is supported on the body by a rotation locking means. The force of a spring acts to place the contact portion in contact with the cam face. The retaining member, which has the shape of an open-ended tube, is positioned in a region outside of the cam member. The retaining member retains the metering pin so that the insertion depth thereof into the fuel nozzle can be adjusted by an adjustment screw screwed into the interior thereof. The retaining member configuration is preferred for smooth and accurate conversion of the opening and closing motion of the throttle valve into linear reciprocating motion of the metering pin and that also for appropriate adjustment of the insertion depth of the metering pin into the fuel nozzle after assembly.




In the above embodiment of the present invention, the throttle lever—which is attached to the valve stem so that movement associated with acceleration control is transmitted to and opens or closes the throttle valve—preferably acts as a cam member as well in order to reduce the number of parts.




Further, objects and advantages of the invention will become apparent from the following detailed description and accompanying drawings.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a longitudinal sectional view of the first embodiment of a carburetor of the present invention.





FIG. 2

is a top view of the carburetor of FIG.


1


.





FIG. 3

is a longitudinal sectional view of the second embodiment of a carburetor of the present invention.





FIG. 4

is a top view of the carburetor shown in FIG.


3


.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT




A preferred embodiment of the carburetor of the present invention will be discussed in reference to the drawings. In

FIGS. 1 and 2

, which show a first preferred embodiment of the present invention, an air intake pathway


2


with a uniform diameter is formed through a body


1


, and a conventional butterfly-type throttle valve


3


comprising a valve plate


5


composed of a disk attached to a valve stem


4


is rotatably supported on the body


1


. The valve stem


4


horizontally crosses the air intake pathway


2


and protrudes at both ends from the body


1


. Air coming from an air cleaner (not shown) passes through the throttle valve


3


flowing in the direction of Arrow A, to supply a combustion chamber of an engine (not shown).




In this embodiment, a throttle lever


6


affixed to one end of the valve stem


4


is pulled and rotated by acceleration controls to open and close the throttle valve


3


. Optimally, the throttle valve


3


can be closed under the force of a return spring


7


comprising a screw coil spring attached to the same end of the valve stem


4


, which is a commonly known configuration.




An indentation formed on one face of the body


1


is covered with a diaphragm


8


to form a constant fuel chamber


9


. Fuel from a fuel tank (not shown) is introduced into the constant fuel chamber


9


by a fuel pump (not shown) attached along an appropriate face of the body


1


. The pump is typically a conventional pulsating diaphragm fuel pump driven under pressure pulsations generated in the crank chamber of the engine. The amount of fuel introduced is regulated by a fuel valve (not shown) that opens or closes according to changes in position of the diaphragm


8


. Accordingly, the constant fuel chamber


9


always contains a constant amount of fuel.




A main jet


10


that regulates the maximum flow rate of the fuel and a fuel nozzle


11


that supplies fuel to the air intake pathway


2


are disposed adjacently between the air intake pathway


2


and the constant fuel chamber


9


of the body


1


. The fuel nozzle


111


comprises a pipe


13


and a clamping flange


14


on its base end superimposed on the main jet


10


. The pipe


13


comprises a hole


12


connected to the jet hole of the main jet


10


. The fuel nozzle


11


also comprises a supply flange


15


at an end of the pipe


13


, adjacent the air intake pathway


2


, one or a plurality of nozzle ports


17


located on the supply flange


15


, and a metering hole


16


that extends in the axial direction along the pipe wall of the pipe


13


. A toric mixing chamber


18


is present in the outside area between the two flanges


14


and


15


of the pipe


13


, and an air bleeding pathway


20


with a jet


19


that regulates air flow is connected to the mixing chamber


18


.




The main jet


10


and the fuel nozzle


11


are positioned on the downstream side of the throttle valve


3


. A tip of a metering pin


21


, which horizontally crosses the air intake pathway


2


and is positioned parallel to the valve stem


4


, is inserted in the hole


12


. The metering pin


21


reciprocates linearly so as to set the metering hole


16


to the minimum aperture when the engine is idling and to the maximum aperture when the engine is at full output.




Fuel entering the hole


12


from the constant fuel chamber


9


via the main jet


10


is metered by the metering hole


16


and the metering pin


21


, enters the mixing chamber


18


, mixes with bled air, and is supplied to the air intake pathway


2


via the nozzle port


17


. In this embodiment, the supply flange


15


provided with the nozzle port


17


is positioned on the same surface as the wall surface of the air intake pathway


2


. Introduction of bled air, therefore, helps reduce the size of the fuel droplets and is effective in eliminating fuel flow along the walls.




A small-diameter component


4


A is formed on the other end of the valve stem


4


, opposite the throttle lever. A disc-shaped cam member


24


is joined to the small-diameter component stem


4


A and secured by a nut


23


and forced to press a step-like portion. The cam member


24


comprises an arc-shaped cam


25


that is centered on the valve stem


4


. A cam surface


26


thereof faces the body


1


.




A planar following member


28


is positioned along the surface of the body


1


on the side where the cam member


24


is disposed. Pin-shaped legs


29


A and


29


B that protrude from both ends thereof are inserted into receiving holes


30


A and


30


B established in the body


1


. Between the legs


29


A and


29


B, a ball is rotatably installed in an end of a platform


31


that protrudes in a direction opposite that in which the legs


29


A and


29


B protrude. The ball forms a contact portion


32


that makes contact with the cam face


26


.




In the portion between the platform


31


of the following member


28


and the leg


29


B, an open ended, tube-shaped retaining member


34


provided with a step portion having a control hole


35


is joined at its small-diameter base end to the following member


28


and is secured against the step portion by applying pressure with a nut


36


. The retaining member


34


is slidably and hermetically received in a retaining hole


33


provided in the body


1


. A base end of the metering pin


21


, which horizontally crosses the air intake pathway


2


, is inserted into the control hole


35


from the tip of the retaining member


34


, and a spring


37


biases it deeply therein. A tip of an adjustment screw


38


inserted and screwed into the control hole


35


from the base end side makes contact with an end of the metering pin


21


.




The following member


28


with the contact portion


32


and the retaining member


34


, which retains the metering pin


21


, constitute a actuating member


27


that causes the metering pin


21


to reciprocate linearly following the angular reciprocating movement of the cam member


24


. The legs


29


A and


29


B and the receiving holes


30


A and


30


B constitute a rotation locking means


39


that causes the retaining member


34


to reciprocate linearly centered on the same axis as the fuel nozzle


11


and the metering pin


21


, without the following member


28


being displaced under the angular reciprocating motion of the cam member


24


. Pressing springs


40


A and


40


B sandwich the leg


29


A and the retaining member


34


, which sandwich the contact portion


32


. The pressing springs


40


A and


40


B comprise pressurized coil springs that are sandwiched between the body


1


and the following member


28


. The pressing springs


40


A and


40


B constantly press the contact portion


32


into contact with the cam face


26


, cause the actuating member


27


to move parallel without tilting, and provide for accurate metering of fuel by the metering pin


21


.




Once this embodiment is assembled, the depth of insertion of the metering pin


21


into the hole


12


during idling in particular (i.e., the area of the effective aperture of the metering hole


16


) is adjusted as necessary by rotating the adjustment screw


38


to bring about stable idling. As

FIGS. 1 and 2

clearly show, the retaining member


34


of this embodiment is arranged in a region on the outside of the cam member


24


, so such adjustments can be easily made. Once adjustment is complete, a plug


41


is inserted to close the base end of the control hole


35


to prevent the engine user from moving the metering pin


21


and knocking the engine out of kilter.




The contact portion


32


comes into contact with the highest part of the cam face


26


when the engine idles, and the metering pin


21


minimizes the effective aperture area of the metering hole


16


. As the throttle valve


3


begins to open, the contact portion


32


makes contact with gradually lower parts of the cam face


26


, increasing the effective aperture area of the metering hole


16


. When the throttle


3


is fully open, the aperture of the metering hole


16


is at maximum.




In this embodiment, the flow rate characteristic of the fuel can be set arbitrarily by the shape of the cam


25


, the size and shape of the metering hole


10


, and, in particular, the shape of the tip of the metering pin


21


. The stroke of the metering pin


21


may be set as desired with the cam


25


irrespective of the opening and closing of the throttle valve


3


, and the position of the metering pin


21


relative to the fuel nozzle


11


can be adjusted with the adjustment screw


38


, thereby eliminating design and manufacturing problems and paving the way for miniaturization of the carburetor as a whole.




Next,

FIGS. 3 and 4

show a second preferred embodiment of the present invention. Aspects of this embodiment identical to those of the first embodiment are as follows: the butterfly-type throttle valve


3


, which opens and closes the air intake pathway


2


that is formed in the body


1


and has a uniform diameter along its entire length; the constant fuel chamber


9


that holds a constant amount of fuel by means of the diaphragm


8


; the cam member


24


, which comprises an arc-shaped cam


25


with d cam face


26


that is centered on the valve stem


4


, and faces the body


1


, is secured to an end of the valve stem


4


of the throttle valve


3


; the actuating member


7


, which comprises the planar following member


28


that has the contact member


32


and the cylindrical retaining member


34


; and the metering pin


21


, which extends across the air intake pathway


2


.




Similarly, an end of the metering pin


21


is inserted into the control hole


35


from a tip of the retaining member


34


, which is inserted into the retaining hole


33


, and a biasing force in the direction of insertion is provided by the spring


37


. In addition, the tip of the adjustment screw


38


, inserted and screwed from the base end side into the control hole


35


, makes contact with the tip of the metering pin


21


, just as it does in the first embodiment.




The fuel nozzle


11


of this embodiment, which is positioned adjacent to the main jet


10


, comprises a pipe


43


with a hole


42


passing through the entire fuel nozzle


11


. The pipe


43


has a pressing flange


14


on the base end thereof that is superimposed on the main jet


10


, a nozzle port


47


elongated in the axial direction on the peripheral side surface of the tip portion thereof, and one or a plurality of air bleeding holes


48


on the peripheral side surface of the base end thereof. The pipe protrudes in to the air intake pathway


2


downstream of the throttle valve


3


, and the tip of the metering pin


21


is inserted into the hole


42


. A toric air chamber


49


is provided in the outer area of the air bleeding hole


48


. A bled air pathway


20


with a jet


19


for controlling air flow is connected to an air chamber


49


.




Fuel entering the hole


42


from the constant fuel chamber


9


via the main jet


10


mixes with bled air entering from the air bleeding hole


48


and is sent to the air intake pathway


2


from the nozzle port


47


. The amount of fuel sent is controlled according to changes in the effective aperture area of the nozzle port


47


by the metering pin


21


.




The following member


28


of the actuating member


27


is arranged along the surface of the side of the body


1


to which the cam member


24


is disposed, as is the case in the first embodiment. A forked member


51


formed on one end thereof is fit with a minimal gap to a boss


52


of the valve stem


4


. The retaining member


34


is joined and secured to the opposite end and sandwiches the platform


31


, with the middle contact portion


32


, between it and the forked member


51


.




The boss


52


makes contact with three sides of the forked member


51


. The boss


52


and the forked member


51


constitute a rotation baffling means


39


, which causes the retaining member


34


to reciprocate linearly along the same axis on which the fuel nozzle


11


and the metering pin


21


move while preventing displacement of the following member


28


. Pressing springs


53


A and


53


B comprising pressure coil springs respectively sandwich the boss


52


and the retaining member


34


and are inserted between the body


1


and the following member


28


. The pressing springs


53


A and


53


B continually press the contact portion


32


into contact with the cam face


26


, cause the actuating member


27


to move parallel without tilting, and provide the accurate metering of fuel by the metering pin


21


.




In this embodiment as well, the retaining member


34


is arranged on the outside area of the cam member


24


, so the depth of insertion of the metering pin


21


into the hole


12


during idling in particular (i.e., the area of the effective aperture of the nozzle port


47


) can be adjusted to bring about stable idling. Once adjustment is complete, a plug


41


is easily inserted to close the end of the control hole


35


.




In this embodiment, the valve stem


4


does not also serve as a throttle valve lever for transmitting the acceleration control. Instead, the cam member


24


is made to take on the function of the throttle valve lever. In addition, the return spring


7


is disposed between the cam member


24


and the boss


52


. This facilitates a reduction in the number of parts and makes it possible to avoid increasing the size of the entire carburetor.




In this embodiment as well, the flow rate characteristic of the fuel can be set arbitrarily by the shape of the cam, the size and shape of the nozzle port


47


, and, in particular, the shape of the tip of the metering pin


21


. The stroke of the metering pin


21


may be set as desired with the cam


25


irrespective of the opening and closing of the throttle valve


3


, and the position of the metering pin


21


relative to the fuel nozzle


11


can be adjusted with the adjustment screw


38


, thereby eliminating design and manufacturing problems and paving the way for downscaling the size of the carburetor as a whole. This effect is similar to that provided by the first embodiment.




In accordance with the present invention, as was described above, the amount of fuel supplied from a fuel nozzle of a single fuel system disposed downstream of the throttle valve of an air intake pathway with a nearly uniform diameter along its entire length, is controlled over the entire operation range of an engine by converting the opening and closing motion of a butterfly throttle valve into linear reciprocal movement of a metering pin. Therefore, with the present invention it is possible to increase the output, to optimize the fuel flow rate, to decrease the size of the entire carburetor, to facilitate design and manufacture, and to obtain a carburetor with excellent performance.




While various preferred embodiments of the invention have been shown for purposes of illustration, it will be understood that those skilled in the art may make modifications thereof without departing from the true scope of the invention as set forth in the appended claims including equivalents thereof.



Claims
  • 1. A carburetor comprisingan air intake pathway having a nearly uniform diameter along its entire length, a butterfly throttle valve that opens and closes the air intake pathway, a metering pin having a tip thereof inserted into a fuel nozzle opening into the air intake pathway, and a fuel control member linearly reciprocating the metering pin in response to the opening and closing operation of the throttle valve, the fuel control member having an actuating member that reciprocates linearly.
  • 2. The carburetor of claim 1 wherein the fuel control member further comprisesa cam member coupled to a valve stem of the throttle valve, wherein the actuating member is operably coupled to the cam member, the metering pin is coupled to the actuating member and reciprocates linearly following the opening and closing operation of the throttle valve to control the amount of fuel supplied from the fuel nozzle to the air intake pathway.
  • 3. The carburetor of claim 2 wherein the cam member comprises an arc-shaped cam face and wherein the actuating member makes constant contact with the cam face.
  • 4. The carburetor of claim 2, wherein the actuating member has a metering pin retaining member.
  • 5. The carburetor of claim 3, wherein the actuating member has a contact portion in contact with the cam face.
  • 6. The carburetor of claim 5, wherein the contact portion is supported on a body of the carburetor by a rotation locking means.
  • 7. The carburetor of claim 5, wherein the contact portion is biased against the cam face under the force of a spring.
  • 8. The carburetor of claim 4, wherein the retaining member has an open-ended, tube shape and is disposed in a region on the outside of the cam member.
  • 9. The carburetor of claim 8, further comprising an adjustment screw screwed into the inside of the retaining member to adjust the insertion depth of the metering pin into the fuel nozzle.
  • 10. The carburetor of claim 2, wherein the actuating member has a contact portion and comprises a following member arranged along the surface of the side of a body of the carburetor on the side where the cam member is disposed.
  • 11. The carburetor of claim 10, wherein the actuating member has a retaining member, which is secured to the following member and is received in a retaining hole provided in the body.
  • 12. The carburetor of claim 11, wherein the actuating member further comprises a rotation locking means.
  • 13. The carburetor of claim 12, wherein the rotation locking means includes legs provided on both ends of the following member and inserted into receiving holes provided in the body.
  • 14. The carburetor of claim 12, wherein the rotation locking means includes a forked member formed on one end of the following member and coupled with a minimal gap to a boss of the valve stem.
  • 15. The carburetor of claim 4, wherein the end of the retaining member is sealed with a plug.
  • 16. The carburetor of claim 2, wherein the cam member serves as a throttle lever attached to the valve stem so that acceleration control is transmitted to and opens or closes the throttle valve.
  • 17. A fuel control member for carburetor having an air intake pathway and a butterfly throttle valve, comprisinga cam member couplable to a valve stem of a throttle valve of a carburetor, and an actuating member operably coupled to the cam member and a metering pin, the actuating member reciprocates linearly following the opening and closing operation of a throttle valve of a carburetor to control the amount of fuel supplied from a fuel nozzle to an air intake pathway.
  • 18. The carburetor of claim 17 wherein the cam member comprises an arc-shaped cam face and wherein the actuating member makes constant contact with the cam face.
  • 19. The carburetor of claim 17, wherein the actuating member has a metering pin retaining member.
  • 20. The carburetor of claim 18, wherein the actuating member has a contact portion in contact with the cam face.
  • 21. The carburetor of claim 20, wherein the contact portion is supportable on a body of a carburetor by a rotation locking means.
  • 22. The carburetor of claim 20, wherein the contact portion is biased against the cam face under the force of a spring.
  • 23. The carburetor of claim 19, wherein the retaining member has an open-ended, tube shape and is disposed in a region on the outside of the cam member.
  • 24. The carburetor of claim 23, further comprising an adjustment screw screwed into the inside of the retaining member to adjust the insertion depth of the metering pin into the fuel nozzle.
  • 25. The carburetor of claim 17, wherein the actuating member has a contact portion and comprises a following member positionable along the surface of a side of a body of a carburetor where the cam member is disposed.
  • 26. The carburetor of claim 25, wherein the actuating member has a retaining member, which is secured to the following member and is receivable in a retaining hole provided in a body of a carburetor.
  • 27. The carburetor of claim 26, wherein the actuating member further comprises a rotation locking means.
  • 28. The carburetor of claim 27, wherein the rotation locking means includes legs provided on both ends of the following member and inserted into receiving holes provided in a body of a carburetor.
  • 29. The carburetor of claim 27, wherein the rotation locking means includes a forked member formed on one end of the following member and coupled with a minimal gap to a boss of a valve stem of a throttle valve of a carburetor.
  • 30. A carburetor comprisingan air intake pathway having a nearly uniform diameter along its entire length, a butterfly throttle valve that opens and closes the air intake pathway, a metering pin having a tip thereof inserted into a fuel nozzle opening into the air intake pathway, and a fuel control member linearly reciprocating the metering pin in response to the opening and closing operation of the throttle valve, the fuel control member having a cam member coupled to a valve stem of the throttle valve, and an actuating member having a contact portion and having a following member arranged along the surface of the side of a body of the carburetor on the side where the cam member is disposed, the actuating member being operably coupled to the cam member, the metering pin is coupled to the actuating member and reciprocates linearly following the opening and closing operation of the throttle valve to control the amount of fuel supplied from the fuel nozzle to the air intake pathway, wherein the actuating member has a retaining member, which is secured to the following member and is received in a retaining hole provided in the body, wherein the actuating member further comprises a rotation locking means, wherein the rotation locking means includes legs provided on both ends of the following member and inserted into receiving holes provided in the body.
  • 31. A carburetor comprisingan air intake pathway having a nearly uniform diameter along its entire length, a butterfly throttle valve that opens and closes the air intake pathway, a metering pin having a tip thereof inserted into a fuel nozzle opening into the air intake pathway, and a fuel control member linearly reciprocating the metering pin in response to the opening and closing operation of the throttle valve, the fuel control member having a cam member coupled to a valve stem of the throttle valve, and an actuating member having a contact portion and having a following member arranged along the surface of the side of a body of the carburetor on the side where the cam member is disposed, the actuating member being operably coupled to the cam member, the metering pin is coupled to the actuating member and reciprocates linearly following the opening and closing operation of the throttle valve to control the amount of fuel supplied from the fuel nozzle to the air intake pathway, wherein the actuating member has a retaining member, which is secured to the following member and is received in a retaining hole provided in the body, wherein the actuating member further comprises a rotation locking means, wherein the rotation locking means includes a forked member formed on one end of the following member and coupled with a minimal gap to a boss of the valve stem.
Priority Claims (1)
Number Date Country Kind
2001-064448 Mar 2001 JP
CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation of application Ser. No. 10/094,263, which was filed on Mar. 8, 2002 and issued as U.S. Pat. No. 6,631,889, and which is fully and expressly incorporated herein by reference.

US Referenced Citations (10)
Number Name Date Kind
2595720 Snyder May 1952 A
2986381 Jones May 1961 A
3013779 Kalert, Jr. et al. Dec 1961 A
3215413 Szwargulski et al. Nov 1965 A
3559963 Cedarholm Feb 1971 A
3680846 Bickhaus et al. Aug 1972 A
4177225 Berkbigler Dec 1979 A
4481152 Kobayashi et al. Nov 1984 A
5537979 Nuti Jul 1996 A
6394424 Pattullo et al. May 2002 B2
Foreign Referenced Citations (3)
Number Date Country
49-17682 May 1974 JP
55-69748 May 1980 JP
58-101253 Jun 1983 JP
Continuations (1)
Number Date Country
Parent 10/094263 Mar 2002 US
Child 10/446918 US