US3328013A - Carburetor - Google Patents

Description

June 27, 1967 N. M. ROMEO ETAL 3,328,013

CARBURETOR Filed Oct. 22, 1965 L llllllllll 2 Z r 2 mvnu'rons 73 2 3 NEIL M. ROMEO 1 h ARTHUR F. GARSIDE, JR. 9;; a 2 ROBERT J. MILLER q BY WA.

/04 mo ATTORA/Ey 3,328,013 CAREURETOR Neil M. Romeo, St. Clair Shores, Arthur F. Gal-side, In, Southfield, and Robert J. Miller, St. Clair Shores, Mich., assignors to Holley C'arburetor Company, Warren, Mich, a corporation of Michigan Filed Oct. 22, 1965, Ser. No. 501,278 12 Claims. ((31. 261-43) This invention relates generally to carburetors, and more particularly toa carburetor having means to compensate for temporary leaning of the fuel-air mixture supplied to an automotive engine when cornering, acceleration, deceleration or vehicle attitude causes the fuel in the float chamber to move away from the carburetor metering section.

In carburetors to which the invention particularly pertains, a predetermined fuel level is maintained in the fuel bowl by a float controlled fuel inlet valve. Fuel metering is accomplished by the difference between the pressure above the fuel in the float chamber or fuel bowl and the pressure at the fuel discharge orifice within the carburetor induction passage; that is, this pressure differential is employed to force fuel from the fuel bowl, through the fuel metering section and out the main fuel nozzle, for example.

Any vehicle operating condition which causes a disturbance of the fuel level in the bowl to the extent that the level in the fuel passages of the carburetor metering section is lowered renders the pressure differential less effective in forcing fuel from the bowl to the nozzle, thereby temporarily leaning out the mixture and causing a noticeable so-called flat spot or hesitation in engine operation. Of course, a disturbance in the opposite direction causing fuel to move toward the metering section will cause a corresponding richening of the mixture; however, this has not been found to create any noticeable effect on engine operation. That is, the problems appear to occur only when the fuel level disturbance is in the direction to lean out the mixture.

In other words, centrifugal force acting on the fuel during cornering, in effect, subtracts from the vacuum available to draw fuel into the carburetor, resulting in a loss of metering. The fuel column is actually withdrawn from the fuel passages. Furthermore, the effect is not limited to a loss of metering, but it also results in faulty or erratic and inconsistent metering.

Accordingly, a primary object of this invention is to provide means to compensate or correct for temporary lean conditions due to the movement of fuel away from the carburetor fuel metering section.

Another object of the invention is to provide means that will supply additional quantities of fuel only during this temporary leaning out condition.

A still further object of the invention is to provide such a means that will be rendered inoperative during idling or engine shut down conditions, such as when the vehicle is standing on a hill or bank, in which case enrichment might stall the engine or cause a diflicult restart.

Another object of the invention is to provide such means that may be readily incorporated in existing carburetors in a manner to cooperate with and be actuated by other systems thereof.

More specifically, another object of the invention is to provide such means that is operatively connected to the usual power valve system so that operation thereof will not take place during engine shut off or idle, but only when the power valve is open.

A still further object of the invention is to provide such means that discharges the compensating fuel at the nited States Patent 3,328,9l3 Patented June 27, 1967 carburetor venturi, manifold vacuum when the means is operative being too low to draw the additional fuel into the carburetor as quickly as it is needed during the temporary lean condition.

A still further object of the invention is to provide such means that is capable of adjustment so as to enable variation in the amount of additional fuel that is supplied during the temporary leaning condition.

Another object of the invention is to provide such means, with or without a valve mechanism, depending upon the particular carburetor or engine involved.

A still further object of the invention is to provide such means that is relatively easy to install and maintain, and that is dependable and eflicient in operation.

These and other objects and advantages of the inven tion will become readily apparent upon reference to the following specification and the attached drawings wherein:

FIGURE 1 is a cross-sectional view through a carburetor including a preferred embodiment of the invention;

FIGURE 2 is a fragmentary view taken along the plane of line 22 of FIGURE 1, and looking in the direction of the arrows;

FIGURE 3 is an elevational view, with portions thereof cutaway and in cross-section, illustrating the same carburetor shown by FIGURE 1, but including a modification of the invention.

Referring now to the drawings in greater detail, FIG- URE 1 illustrates a carburetor 10 mounted on an engine 12 in a manner such that the fuel bowl portion 14 of the carburetor is to the right of the centerline of the vehicle, when viewed from the rear.

While the invention is adaptable to any carburetor, the particular carburetor 10 shown comprises a lower throttle body portion 16, an intermediate venturi portion 18 having the fuel bowl 14 formed integrally therewith and an upper air horn portion 20' with an integral fuel bowl cover 22, the three section being secured in any suitable manner with gaskets 24 therebetween.

The carburetor 10 contains the usual pivotable choke valve 26, venturi 28 and pivotable throttle valve 20. The main nozzle 32, including a secondary venturi 34, is located in the main venturi, and the passage 36 between the main nozzle 32 and the fuel bowl 14 includes the usual removable main metering jet 38, main well 40 and main well air bleed tube 42, the tube 42 communicating with the internal Pitot tube 44 which also vents the fuel chamber 46 to aircleaner pressure. The main jet 38 and the main well 40 comprise a portion of what is referred to herein as the carburetor metering section 48, it being noted that the metering section is positioned at the wall between the induction passage 50 and the fuel chamber 46.

The carburetor structure described to this point is well known to those skilled in the art so that further explanation of the structure and operation thereof is not required. However, the particular preferred embodiment of the invention shown involves co-operation with the power fuel system; thus, the power fuel system will now be described.

The power fuel system 52 comprises a passage 54 that communicates between the passage 56- that connects the main jet 38 with the main well 40 and the power valve chamber 58. The power valve chamber 58 is formed to provide a valve seat 60, and it contains the power valve 62 urged against the seat 60 by a spring 64 and having an upwardly pointing extension 66. When the valve 62 is open, fuel from the fuel chamber 46, in addition to that supplied through the main jet 38, is supplied to the main 3 well 40, richening the mixture to meet the demand for greater power.

A passage 68 communicating with that portion of the induction passage 50 below the throttle valve 30 extends upwardly and thence to a cylinder 70 containing the movable piston 72, the piston having a stem 73. A compressed coil spring 74 between the abutment 76 on the end of the stem and the spring retainer 78 through which the stem 73 is movable, normally urges the piston 72 downwardly, as shown in dotted lines. The relationship between the stem 73 and the upwardly extending extension 66 on the power valve 62 is such that when the piston is in its lower dotted line position, the power valve is open to supply the additional power fuel. The spring 74 is selected so that normal manifold vacuum is sufficient to draw the piston upwardly to its solid line position; however, when the throttle valve is opened, the response to a demand for power, the manifold vacuum drops sufficiently so that spring 74 moves the stem 73 and piston 72 to their lower position, opening the power valve 62. The above described power valve system is well known in the art, and such a carburetor can be very conveniently modified to incorporate the invention.

Before describing the invention, it should be pointed out that the fuel is normally at some level such as that represented by line XX, this level being maintained by a fuel inlet valve controlled by the float 80, as is well known in the art. This normal level also exists in the main well 40, and the difference between the pressure above the fuel in the chamber 46 and the pressure at the main nozle 32 forces fuel up the main well and into the passage 36 leading to the nozzle.

It will be apparent that when the vehicle is negotiating a relatively sharp left turn, assuming the carburetor to be mounted as shown, the fuel in the chamber 46 assumes some level off the normal level, as represented by the line YY, the slope of the line depending upon the severity of the turn; thus, the vacuum required to draw the fuel up the main well 40 and into the main nozzle 32 is substantially greater than when the fuel level is at XX. However, the vacuum at nozzle 32 does not increase; thus, it is rendered less effective to draw fuel to the main nozzle 32 and the result is a substantial temporary leaning out of the fuel-air mixture to the engine. This leaning out results in a noticeable flat spot or hesitation in engine operation, which is the problem that the invention solves.

With the above explanation, it will now be seen that the invention may comprise a relatively inexpensive modification of an existing carburetor to provide means to compensate for this temporary lean condition. The modification may include providing a boss 82 on one side of the carburetor body opposite the venturi and a second boss 84 on the outer surface of the fuel bowl 14, the boss 84 being formed to provide a two diameter passage 86 adapted to receive a cylindrical portion 88 of a valve assembly 90.

As seen in FIGURES 1 and 2, the valve assembly 90 comprises a cast or otherwise formed body 92 having pairs of oppositely disposed holes to receive pivot pins 94 and 96. The lower pivot pin 96 has mounted thereon, with the body 92, a lever member 98 having spaced pivot members 100, an upper extension 102 and a lower extension 104. The lower extension 104 is formed to extend over the extension 66 of the power valve 62, and it is preferably formed with an opening 106 through which the power valve extension 66 may extend. The upper pivot pin 94 has pivotally mounted thereon, within the body 92, a second valve operating lever 108, the lower end 110 of the lever overlapping the upper end 102 of the first lever 98 and the upper end thereof having a portion 112 passing through an orifice 114 communicating with the passage 116 in the cylindrical portion 88 to provide a valve seat 118. The passage 116 is plugged at its outer end 120 so as to retain a ball valve 122 loaded by a spring 124, the spring having sufiicient force .to close the ball valve 122 against its seat 118 and to move the levers 108 and 98 to their FIGURE 1 position, except when the power valve 62 is opened by the stem 73 due to the greater force of the spring 74.

A collar 126 is mounted over the end of the externally threaded portion 88 extending through the boss 84, and a cap nut 128 secures the collar against the boss, with sealing gaskets 130 preventing leakage. Aligned passages 132 extend through the boss 84 and the collar 126. A conduit 134 secured to the collar 126 has the other end thereof inserted into a suitably formed opening in the boss 82 on the other side of the carburetor so as to communicate the valve chamber 116 to the venturi 28, through the passage 136 formed in the wall of the carburetor.

With the above construction, it will be apparent that Whenever the fuel is moved away from the metering section 48 of the carburetor, it will assume a position along the line YY, thereby tending to lower the level of the fuel in the main well and covering the orifice 114 which is normally closed by the ball valve 122. This will be true whenever a vehicle, on which the carburetor is mounted as shown, is in a relatively sharp left turn or is parked on a bank that slopes downwardly to the right. The same would be true, of course, if the carburetor was rotated 90 and the vehicle were either accelerated or decelerated.

If the valve assembly 90 were not provide, fuel could be supplied through the conduit 134 to the venturi 28 anytime that the fuel level covered the orifice 114. However, in most cases it has been found that it is undesirable to supply this extra fuel whenever the engine is merely idling, or when the engine is shut down. In the former case, the engine might stall and in the latter case, restarting might be difficult. Thus, the preferred embodiment of the invention includes the valve assembly 90 so that compensating fuel will be supplied only when the following two conditions exist: (a) the fuel is being moved away from the metering section and (b) engine operation is such that the power valve is open.

While it is usually desirable to include the valve assembly 90 in the fuel compensating system, there may, of course, be engines or carburetors that can properly compensate for leaning out due to movements of fuel away from the metering section without the use of such a valve. Thus, a simplified modification of the invention is shown byi IZIGURE 3 wherein a two-port spill assembly is pro- V1 e In FIGURE 3 construction, a member 137 having vertically spaced ports 138 and 140 connected by passages 142 and 144 has the portion 146 containing the passage 144 secured through the passage 148 formed through the boss 84, the protruding end of the portion 146 being threaded so as to enable the connection thereto of a flared tube 150 by means of the threaded fitting 152. The other end of the tube 150 is connected to communicate with a passage 154 through the Wall of the carburetor and into the induction passage 50, either above or below the throttle valve 30, as desired.

It will be noticed in the FIGURE 3 modification that the vertically spaced orifices are both positioned above the normal fuel level XX. One or both the orifices 140 and 138 may be covered by fuel, depending upon the degree of disturbance of the fuel in the fuel bowl to lines YY or YY, for example. Since the fuel supplied through each of the orifices 138 and 140 is additive, more compensating fuel will be provided when both orifices are covered to correct for the more severe leaning out condition. The FIGURE 3 structure could be employed in cases where the engine can tolerate idle and/or shut down enrichment.

It should be apparent from the above description of construction and operation that the invention provides novel means to accomplish the stated objectives. While a preferred embodiment is shown operative in conjunction with the power valve system, it is conveivable that the valve assembly thereof could be operated in conjunction with some other fuel system, such as accelerating pump system, or with some predetermined degree of throttle open. The main objective in the preferred embodiment being to prevent valve opening when the engine is idle or shut down. It is also apparent that other modifications are possible; for example, the FIGURE 1 and 3 embodiments could easily be combined to provide a plurality of valved ports.

It should be noted that the structure of the invention is such that an existing carburetor can be modified at the plant to incorporate the features of the invention merely by drilling a passage to the carburetor induction passage and a passage through the wall of the fuel bowl opposite the fuel metering section of the carburetor. The parts required for the invention are very simple and inexpensive, and they fit into the existing carburetor structure without in any way effecting the operation of the prior systems to the' carburetor. For example, the spill orifices are so small, as compared to the Pitot tube vent, that continuous bleed of air does not change the pressure above the fuel in the bowl, and the metering characteristics of the carburetor are not effected. The structure of the invention is also particularly adapted for so-called aftermarket sales so that any vehicle owner can purchase a modification kit for his carburetor.

The invention has been described in sufficient detail to enable anyone skilled in the art to practice the same, and no limitations are intended, except as recited in the following claims.

What we claim as our invention is:

1. In combination with an internal combustion engine for use in a vehicle, a carburetor mounted on such engine and comprising a body having an induction passage, a fuel reservoir chamber adjacent said induction passage, said reservoir comprising an undivided single compartment such that all of the fuel therein acts as a single fluid body, fuel metering means disposed between said induction passage and said fuel chamber, means for maintaining a predetermined normal fuel level in said chamber, a passage leading from the side of said fuel chamber opposite said metering means and towards a side of said engine and at a point above said predetermined fuel level to said induction passage, a valve located in the fuel reservoir end of said passage and means for opening said valve under a condition of engine operation other than idle.

2. A device such as that recited in claim 1, wherein said latter means closes said valve when the engine is shut down.

3. A device for an internal combustion engine driving a vehicle, said carburetor comprising a body formed to provide an induction passage having a venturi restriction with a main nozzle the-rein, a choke valve upstream of said venturi, a throttle valve downstream of said venturi, a fuel reservoir chamber adjacent said induction passage, said reservoir comprising an undivided single compartment such that all of the fuel therein acts as a single fluid body, means for maintaining a predetermined normal fuel level in said reservoir chamber, a first fuel passage between said reservoir chamber and said main nozzle, said fuel passage being positioned between said induction passage and said reservoir chamber, a power system including a valve controlling a separate passage for supplying additional fuel to said fuel passage, means for operating said power valve, a second fuel passage between said reservoir chamber at a point above said predetermined fuel level and said induction passage, a valve for opening and closing said second fuel passage, and an operative connection between said power valve operating means and said valve for said second fuel passage.

4. A carburetor for an internal combustion engine driving a vehicle, said carburetor comprising a body formed to provide an induction passage having a venturi restriction with a :main nozzle therein, a choke valve upstream of said venturi, a throttle valve downstream of said venturi, a fuel reservoir chamber adjacent said induction passage, said reservoir comprising an undivided single compartment such that all of the fuel therein acts as a single fluid body, means for maintaining a predetermined fuel level in said reservoir chamber, a first fuel passage between said reservoir chamber and said main nozzle, said fuel passage being positioned between said induction passage and said reservoir chamber, a power valve for supplying additional fuel to said fuel passage, means for operating said power valve, a second fuel passage between said reservoir chamber at a point above said predetermined fuel level and said induction passage, a valve for opening and closing said second fuel passage, and an operative connection between said power valve operating means and said valve for said second fuel passage for opening said valve only when said power valve is opened.

5. A carburetor for an internal combustion engine driving a vehicle, said carburetor comprising a body formed to provide an induction passage, a first fuel system including a fuel discharge orifice discharging into said induction passage, a fuel reservoir chamber adjacent said induction passage, said reservoir comprising an undivided single compartment such that all of the fuel therein acts as a single fluid body, means for maintaining a predetermined fuel level in said reservoir chamber, a first fuel passage between said reservoir chamber and said orifice, said fuel passage being positioned between said induction passage and said reservoir chamber, a second fuel system for supplying additional fuel to said induction passage, during a selected engine operating condition, means responsive to said condition for operating said fuel system, a second fuel passage between said reservoir chamber at a point above said predetermined fuel level and said induction passage, a valve for opening and closing said second fuel passage, and a connection between said second fuel system operating means and said valve for said second fuel passage for opening said valve only when said second fuel system is in operation.

6. In combination with an internal combustion engine for use in a vehicle, a carburetor mounted on such engine and comprising a body formed to provide an induction passage, a throttle valve in said induction passage, a fuel chamber having means to maintain a predetermined fuel level therein, said reservoir comprising an undivided single compartment such that all of the fuel therein acts as a single fluid body, fuel supply and metering means between said induction passage and said fuel chamber, a passage leading from said fuel chamber at a point above said predetermined fuel level and toward a side of said engine to said induction passage and valve means controlling said passage inresponse to throttle position.

7. In combination with an internal combustion engine for use in a vehicle, a carburetor mounted on said engine and comprising a body formed to provide an induction passage, a throttle valve in said induction passage, a fuel chamber having means to maintain a predetermined fuel level therein, said reservoir comprising an undivided single compartment such that all of the fuel therein acts as a single fluid body, fuel supply and metering means between said induction passage and said fuel chamber, a passage leading from said fuel chamber at a point above said predetermined fuel level and towards a side of said engine to said induction passage and valve means controlling said passage in response to engine vacuum.

8. In combination with an internal combusion engine for use in a vehicle, a carburetor mounted on such engine and comprising a body formed to provide an induction passage, a throttle valve in said induction passage, a fuel chamber having means to maintain a predetermined fuel level therein, said reservoir comprising an undivided single compartment such that all of the fuel therein acts as a single fluid body, fuel supply and metering means between said induction passage and said fuel chamber, a passage leading from said fuel chamber at a point above said predetermined fuel level and towards a side of said engine to said induction passage and valve means controlling said passage in response to carburetor vacuum.

9. An internal combustion engine carburetor, comprising a body formed to provide an induction passage, a venturi in said induction passage, a main nozzle at said venturi, a choke valve upstream of said venturi, a throttle valve downstream of said venturi, a fuel reservoir chamber adjacent said induction passage, said reservoir comprising an undivided single compartment such that all of the fuel therein acts as a single fluid body, means for maintaining a predetermined fuel level in said chamber, a first fuel passage between said fuel reservoir chamber and said main nozzle, said first passage including a main jet and a main well, a power fuel system including a second fuel passage between said chamber and said main well, a spring-loaded valve controlling said second fuel passage, vacuum piston and spring means for opening said power valve only in response to engine vacuum indicative of an increased engine load, an opening in a wall of said fuel reservoir chamber opposite said main well and at a point above said predetermined fuel level, a third passage formed through a wall of said carburetor to said induction passage, a conduit between said opening and said third passage, a spring-loaded valve to close said opening and means operatively connected to said piston and spring power fuel system operating means in a manner to open said valve when said power valve is open and to close said valve when said power valve is closed.

10. In combination with an internal combustion engine for use in a vehicle, a carburetor mounted on such engine and having an induction passage and a fuel reservoir in which a predetermined normal fuel level is maintained, said fuel reservoir comprising an undivided single compartment such that all of the fuel therein acts as a single fluid body, fuel metering means positioned at the end of said fuel reservoir adjacent said induction passage and subject to lean metering when fuel in said reservoir is displaced so as to lower said level adjacent said metering means as on cornering of said vehicle, and means to compensate for lean metering due to such disturbances in said fuel level, said means comprising a passage between the carburetor induction passage and the end of said fuel reservoir opposite said metering means and towards a side of said engine at a point sufficiently above the normal fuel level therein so that lean metering would occur if said point were covered with fuel, said pass-age being effective to convey additional amounts of fuel to said induction passage when the fuel reservoir end thereof is covered with fuel due to such leaning disturbances in said fuel level and valve means controlling said passage and operative to prevent fuel flow in said passage when said engine is shut down or idling.

11. A carburetor for an internal combustion engine application wherein the carburetor fuel level is subject to disturbances such as may result from cornering of a vehicle, said carburetor comprising a body having an induction passage with a venturi restriction, a main fuel nozzle positioned in said passage near said venturi, a fuel reserto ca voir on said body adjacent said induction passage, said fuel reservoir comprising an undivided single compartrnent such that all of the fuel therein acts as a single fluid body, a first passage between said reservoir and said main nozzle, means for normally maintaining a predetermined fuel level in said reservoir, a power fuel system for supplying additional fuel to said engine, a second passage having the inlet end thereof open to said reservoir a predetermined distance above said predetermined fuel level such that said inlet end would be covered by fuel during a disturbance in the normal fuel level in said reservoir and its other discharge end open to said induction passage, said second passage providing means for conveying additional fuel to said induction passage when the fuel level in said reservoir is disturbed sufficiently to cover said inlet end of said second passage and valve means controlling said passage and operative to close said passage when said power fuel system is inoperative.

12. In combination with an internal combustion engine for use in a vehicle, a carburetor mounted on such engine and comprising a body having an induction passage, a fuel discharge orifice in said passage, a fuel reservoir on said body adjacent said induction passage, said fuel reservoir comprising an undivided single compartment such that all of the fuel therein acts as a single fluid body, a first passage between said reservoir and said orifice, means for maintaining a predetermined normal fuel level in said reservoir, a second passage having the inlet end thereof terminating in said reservoir and towards a side of said engine a predetermined distance above said predetermined normal fuel level such that said inlet end would be covered by fuel during a disturbance in the normal fuel level in said reservoir and its other discharge end terminating in said induction passage, said second passage supplying additional fuel to said induction passage when the fuel level in said reservoir is disturbed sufficiently to cover said inlet end of said second passage and valve means controlling said passage and being operative to at times prevent flow through said passage in response to a selected engine operating condition.

References Cited UNITED STATES PATENTS 2,232,085 2/1941 Mennesson 26172 X 2,261,234 11/1941 DeLancey 25178 X 2,267,688 12/ 1941 Landon 25178 X 2,537,347 1/1951 Hieger et al 26 1--72 X 2,873,957 2/ 1959 Lunn 26169 2,878,683 3/1959 Huthsing et a1. 251232 X 3,249,345 4/ 1966 Gast 26139 FOREIGN PATENTS 148,224 10/ 1921 Great Britain.

HARRY B. THORNTON, Primary Examiner.

T. R. MILES, Assistant Examiner.

Claims (1)

1. IN COMBINATION WITH AN INTERNAL COMBUSTION ENGINE FOR USE IN VEHICLE, A CARBURETOR MOUNTED ON SUCH ENGINE AND COMPRISING A BODY HAVING AN INDUCTION PASSAGE, A FUEL RESERVOIR CHAMBER ADJACENT SAID INDUCTION PASSAGE, SAID RESERVOIR COMPRISING AN UNDIVIDED SINGLE COMPARTMENT SUCH THAT ALL OF THE FUEL THEREIN ACTS AS A SINGLE FLUID BODY, FUEL METERING MEANS DISPOSED BETWEEN SAID INDUCTION PASSAGE AND SAID FUEL CHAMBER, MEANS FOR MAINTAINING A PREDETERMINED NORMAL FUEL LEVEL IN SAID CHAMBER, A PASSAGE LEADING FROM THE SIDE OF SAID FUEL CHAMBER OPPOSITE SAID METERING MEANS AND TOWARDS A SIDE OF SAID ENGINE AND AT A POINT ABOVE SAID PREDETERMINED FUEL LEVEL TO SAID INDUCTION PASSAGE, A VALVE LOCATED IN THE FUEL RESERVOIR END OF SAID PASSAGE AND MEANS FOR OPENING SAID VALVE UNDER A CONDITION OF ENGINE OPERATION OTHER THAN IDLE.

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