US1906982A - Carburetor - Google Patents

Carburetor Download PDF

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US1906982A
US1906982A US487206A US48720630A US1906982A US 1906982 A US1906982 A US 1906982A US 487206 A US487206 A US 487206A US 48720630 A US48720630 A US 48720630A US 1906982 A US1906982 A US 1906982A
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reservoir
fuel
suction
carburetor
air
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US487206A
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Linga Torbjorn
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02MSUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
    • F02M7/00Carburettors with means for influencing, e.g. enriching or keeping constant, fuel/air ratio of charge under varying conditions
    • F02M7/12Other installations, with moving parts, for influencing fuel/air ratio, e.g. having valves
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02MSUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
    • F02M1/00Carburettors with means for facilitating engine's starting or its idling below operational temperatures
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02MSUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
    • F02M1/00Carburettors with means for facilitating engine's starting or its idling below operational temperatures
    • F02M1/16Other means for enriching fuel-air mixture during starting; Priming cups; using different fuels for starting and normal operation
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02MSUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
    • F02M7/00Carburettors with means for influencing, e.g. enriching or keeping constant, fuel/air ratio of charge under varying conditions
    • F02M7/10Other installations, without moving parts, for influencing fuel/air ratio, e.g. electrical means
    • F02M7/11Altering float-chamber pressure
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02MSUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
    • F02M2700/00Supplying, feeding or preparing air, fuel, fuel air mixtures or auxiliary fluids for a combustion engine; Use of exhaust gas; Compressors for piston engines
    • F02M2700/43Arrangements for supplying air, fuel or auxiliary fluids to a combustion space of mixture compressing engines working with liquid fuel
    • F02M2700/4302Arrangements for supplying air, fuel or auxiliary fluids to a combustion space of mixture compressing engines working with liquid fuel whereby air and fuel are sucked into the mixture conduit
    • F02M2700/4335Transport devices
    • F02M2700/4338Acceleration pumps

Definitions

  • One object of the present invention is to provide a practical carburetor of the socalled self-feed type for internal-combustion engines, which requires no separate vacuumgank or pump to supply the carburetor with uel.
  • the new carburetor is capable of lifting or elevating liquid fuel from a supply located at a level lower than that of the carburetor, as from a supply-tank positioned at the rear of an automobile which is a common and usual construction atthe present time.
  • a further aim of the invention is to supply a carburetor construction of this character, which, by a simple change or adjustment of a spring, may be regulated as to its fuel-lifting capacity to conform to the requirements of 'the particular installation, since it is not feasible or desirable to make a carburetor with a fuel-elevating power greatly in excess of that needed for the particular installation, as an increase in such lifting capacity necessitates an augmented depression or suction in the carburetor with a resulting loss of volumetric efliciency.
  • Another object of the invention is to produce a carburetor which has the lowest permissible suction or depression in its mixingchamber in order to secure maximum power out of the associated engine, especially at high speeds.
  • Still a further purpose is to make such a construction with low suction and at the same Q time have adequate suction to lift the fuel the required height'from the supply to the carburetor-bowl or fuel-reservoir.
  • Added purposes of the invention are to supply a carburetor with a relatively small restriction against inflowing air, with simple and efficient means for adjusting or controlling the fuel-air ratio for low, intermediate and high engine speeds, with effective and uncomplicated means for enriching the mixture, as well as increasing the air velocity through the venturi, during engine acceleration, with an economizer for automatically providing a leaner mixture at part-open throttle than with fully open throttle, and withmeans for enriching the mixture during the starting numerals have been employed to designate of the engine and while it is warming up, the construction being such that all air entering the carburetor must pass through a single entry passage which may, if desired, be pro vided with an air-cleaner or filter.
  • Figure 1 is a central, vertical, longitudinal section through the carburetor on line 11 of Figure 2;
  • Figure 2 is a horizontal section through the construction on line 22 of Figure 1;
  • Figure 3 is a fragmentary, vertical section on line 33 of Figure 2;
  • Figure 4 is a horizontal section on line 44 of Figure 3;
  • Figure 5 is a horizontal section on line 5 5 of Figure 3;
  • Figure 6 is a vertical section on line ,66 of Figure 2.
  • Figure 7 is a vertical section on line 77 of Figure 2.
  • the carburetor body characterized as a whole 11, has an air entrance or intake opening 12 through which air may flow or be drawn into the main or mixing chamber 13 occupied in part by a Venturi-tube 14, the upper end of compartment 13 being fitted with the usual throttlevalve 15 and the opening 12 being equipped with an auxiliary-air or choke valve 16.
  • the floatchamber or fuel reservoir or compartment 21 of the carburetor is composed of a main body or bowl 22 and a top cap or closure 23 held thereon by screws 24, 24, the border of a flexible diaphragm 25, such as a cloth treated with linseed oil, which divides the interior of the compartment into two chambers, being clamped between the marginal flanges of the two co-operating elements 22 and 23.
  • Fuel is admitted into the bowl 22 through an inlet-pipe 26 connected to a lower fuelsupply tank, not shown, the infeed of such fuel being governed and regulated to maintain a constant fuel level in the bowl, by a valve 27, a lever 28 on which the valve is mounted, and a float 29 underlying the lever, all of which is of usual construction.
  • fuel-bowl 22 has a centrallydisposed, hollow bearing 31 upstanding from its bottom wall and around this is a coiled spring 32, as nearly as possible of equal strength throughout its working range, resting at its lower end on the floor of the bowl and pressing at its upper end against the underside of the diaphragm, holes 33 being provided through the lower part of the wall of member 31 to allow the passage of the fuel therethrough into the inner chamber 34, which, as explained below, forms part of a dashpot structure.
  • a hollow plug 35 is screwed into the bottom wall of the bowl and the member 31, its upper, open end being equipped with a bushing or ring 36 having a central, calibrated opening'or port 37 through it, the lower part of the plug having lateral openings 38 connecting its interior chamber 30 with a as sage 39 communicatin with the inside 0 the lower end of an upright tube 41 above a screw-threaded plug 42 screwed into the body of the carburetor, a manually-adjustable, metering needle-valve 43 co-operating with the aperture at the lower endv of the tube and regulating the size of the free opening between passage 39 and the inside of the tube.
  • Such tube 41 is located in a larger, up right, cylindrical chamber 40 provided in the central part of the carburetor body, the top end of the tube being closed but with lateral openings 43 through its side walls just below the end closure.
  • Y chamber 40 is joined by a conduit 44 to passage 19 of the Venturi structure.
  • Tube 41 extends above the liquid level in reservoir 22 to prevent the drainage or siphoning off of its contents.
  • a plunger 45 Fixed to the diaphragm and movable up and down therewith as the diaphragm flexes is a plunger 45 slidable in the interior of the bearlng-member 31, the plunger or piston constituting part of the dash-pot mechanism referred to above.
  • Such plunger has a centrally-arranged, screw-threaded opening accommodating a manually-adjustable threaded rod or screw 46 having a hollow, lower part 47 to which at 48 is fastened the upper end of a flexible wire 49, the space in the adjustment screw section 47 being large enough to permit flexure or side movement of the wire.
  • the lower end of such wire carries a tapered valve or calibrated metering element 51 occupying the port or opening 37, so that, as the diaphragm flexes, such element will open the port 37 more or less.
  • a lever-arm 52 The rounded, split end of a lever-arm 52 is located between a nut 53, above the diaphragm and forming part of the means for fastening the sliding plunger to the diaphragm, and a disc 54 hearing on the top of the lever-arm and between which and the knurled head of the screw 46 a spring 55 is employed.
  • Such lever-arm 52 is fixedly mounted, as by screws 60, on a roclvshaft 56 capable of turning in a longitudinally-recessed, eccentric sleeve or hearing 57 having bearings 58, 58 in the walls of the carburetor.
  • One protruding end of shaft 56 has an arm 59 rigid therewith joined by a link 61 to an arm 62 fastened on the end of the shaft 63 of the auxiliary-air admission valve 16.
  • the eccentric hearing or sleeve. 57 may be turned to lower the position of the fulcrum shaft 56, and this is accomplished by means of an arm 64 on one end of the sleeve 57 to which a check or operating wire 65 is connected, the usual spring 66 being employed to restore the wire, arm, and sleeve to normal position as soon as released by the operator after the choking has been completed. 2
  • the fuel bowl or reservoir 21 is connected through a small hole 71 to a small chamber 72 which is in communication through a port- 73 with chamber 40 and through another small orifice 74 with the carburetor mixingchamber 13, such space 72 also connecting through a metered passage 75 ( Figure 5) with a right-angle condu t '76. 77 leading down into the fuel-bowl below the fuel-level therein and with another passage 78, 79, 81, 82 leading to one of the bearings 83 for the shaft 84 of the throttle-valve 15.
  • Such shaft 84 is longitudinally slotted or recessed at 85 in such relation or position, that, when the throttle-valve is closed (see Figure 3), the ports of passages 82 and 85 communication with chamber 13 through the connecting conduits 78, 79, 81, 82, 83.
  • the compartment above the diaphragm 25, as is shown in Figure 6, is joined through a hole 86 and an upright tube 87 to a passage 88 connecting with the air conduit 17, Whereby any air entering the compartment above the diaphragm is drawn through the opening 12, and, if the latter is provided with an air-cleaner or filter, all air entering the carburetor is filtered or freed from dust and the like.
  • spring 32 When the engine with which the carburetor is associated is at rest, spring 32 maintains the diaphragm at its upper position of flexure, thereby closing the auxiliary air-admission valve 16 by reason of the specified mechanical connection between the diaphragm and the shaft of such valve through the co-operating parts 52, 56, 59, 61, 62, 63,
  • the diaphragm will be flexed downwardly against the action of spring 32, such bending of the diaphragm opening the auxiliary-air valve 16 more or less, and, obviously, there will be a balanced position of the parts for every throttle opening and en-- gine speed.
  • the suction in the fuel-bowl 22 is sufficient to lift the incoming fuel from the lower supply tank to keep the carburetor properly charged with fuel at the desired level
  • the degree of sub-atmospheric condition in the fuel-bowl depends upon the strength of spring 32 and by adjusting such spring, or by simply using a stronger or weaker one, the fuel lift capacity of the carburetor may be made to meet any particular requirement.
  • the construction of the carburetor is such, with respect to the structure, size, strength and association of its parts, that, by the automatic operation of the auxiliary air-ad mission valve, the suction in the fuel reservoir is maintained substantially unvarying, and the suction at the outlet of the reservoir is kept practically constant, except that the latter suction is increased during engine acceleration and during full or nearly-full open throttle position.
  • the depression or suction at the top of the venturi in chamber 13 is 14 inches, and if the opening 74 were closed, the depression in both the fuel-reservoir 21 and chamber 30 would be 49 inches (14X3 assuming a venturi efficiency of 3 Passage 74 being open, however, a small stream of air flows in through it from chamber 13 and down through opening 73 and on into the Venturi at 19.
  • this air was under a depression of 14 inches, but its passage through the small orifice 74 causes a further drop of 26 inches giving a depression of 40 inches in chamber 72 and in the fuel-reservoir 21.
  • This 8 inch head is practically constant or unvarying throughout the range of action of the carburetor, except during acceleration and fully open throttle, and accordingly, it becomes necessary to provide a variable fuel opening, that is, a metering device which will automatically enlarge or increase the free opening of the fuel orilice, which function is performed by the diaphragm-actuated, tapered, metering pin or valve 51.
  • the diaphragm will llex downwardly, carrying the tapered pin with it, thereby increasing the opening at orilice 257.
  • the calibrated orifice 71 will retard such air discharge, because it is very small, and, consequently, the air pressure under the diaphragm cannot immediately equalize itself with the pressure in the small chamber 72, with the result that the pressure will be somewhat higher in the fuelbowl, and this relative increase of pressure will force fuel out through passage 77 up conduit 76,
  • the downward travel of the pilot or plunger will also have a slight retarding effect, due to the dash-pot action, as well as a slight direct effect in enriching the mixture.
  • the diaphragm During deceleration the diaphragm will move upwardly and air will be supplied to the space beneath it through the orifices 71 and 75, 77, thus allowing the diaphragm to flex upwardly more freely than downwardly.
  • a fuel mixture 20 to 24% leaner than the maximum torque mixture is the most economical to employ, and, therefore, a carburetor should have automatic means for changing the mixture ratio between partly-open and fully-open throttle-valve.
  • A- practical and economical carburetor should have automatic means to effect a mixture ratio change as the throttle-valve moves from about 7/8ths open to fully open positional passage is usedto connect the chamber- 72 to the main-chamber 13 of the carburetor,
  • this supplemental passage is opened and closed by the movement of the throttle-valve.
  • the chamber 72 is additionally connected to the main chamber 13 throughthe then connected passages 78,
  • any dust which it may carry along with it can in no way find entrance into the reservoir with resulting objectionable clogging effects.
  • a carburetor for use with an internalcombustion engine, the combination of an air and fuel mixing structure acted upon by the carburetor suction, means to admit air to said structure, a fuel-reservoir having an inlet and an outlet, a conduit connecting said reservoir-outlet to, and subjected to an increased suction effected by, said structure, means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintain the fuel-level in said reservoir substantially constant, means to apply suction to the interior of said reservoir in lesser degree than that applied to the reservoir-outlet through said conduit, whereby to lift the fuel from said supply into said reservoir by the suction therein at the same time permitting the delivery of the reservoir fuel to said mixing structure through said conduit by reason of the specified suction difference in, and at the outlet of, said reservoir, means to permit auxiliary air to flow through the carburetor, an air-valve controlling the admission of such auxiliaryair, and means governing said auxiliary air-valve and maintaining the respective suctions in said fuel reservoir
  • a carburetor for use with an'internalcombustion engine, the combination of an air and fuel mixing structure acted upon by the carburetor suction, means to admit air to said structure, a fuel-reservoir having an inlet and an outlet, a conduit connecting said reservoiroutlet to, and subjected to an increased suction effected by, said structure, means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintain the fuel-level in said reservoir substantially constant, means to apply suctionto the interior of said reservoir in lesserv degree than that applied to the reservoir-outlet through said conduit, whereby to lift the fuel from said supply into said reservoir by the suction therein at the sametime permitting the delivery of the reservoir fuel to said mixing structure through said conduit by reason of the specified suction difference in,
  • said reservoir means to' permit auxiliary air to flow through the carburetor, an air-valve controlling the admission of such auxiliary 'air, and means acted upon by the suction in said reservoir controlling said auxiliary air-valve to maintain the increased suction in said reservoir substantially uniform;
  • a carburetor for use with an internalcombustion engine, the combination of an air and fuel mixing structure acted upon by the carburetor suction, means to admit air to said structure, a fuel-reservoir having an inlet and an outlet, a conduit connecting said reservoir-outlet to, and subjected to an increased suction effected by, said structure, means to convey fuel from a supply lower than said reservoir to the inlet of, the latter, means to maintain the fuel-level in said reservoir substantially constant, means to apply suction to the interior of said reservoir in lesser degree than that applied to the reservoir-outlet through said conduit, whereby to lift the fuel from said supply into said reservoir by the suction therein at the same time permitting the delivery of the reservoir fuel to said mixing structure through said conduit by reason of the specified suction difference in, and at the outlet of, said reservoir, means to admit auxiliary air into the carburetor, an air-valve controlling the admission of such auxiliary air, means governing said auxiliary air-valve and maintaining the respective suctions in said reservoir and in said
  • a carburetor for use with an internalcombustion engine, the combination of an air and fuel mixing structure acted upon by the carburetor suction, means toadmit air to said structure, a fuel-reservoir having an inlet and an outlet, a conduit connecting said reservoir-outlet to, and subjected to an increased suction effected by, said structure, a
  • a carburetor for use with an internaleombustion engine, the combination of an air and fuel mixing structure acted upon by the carburetor suction, means to admit air to said structure, a fuel-reservoir having an inlet and an outlet, a conduit connecting said reservoiroutlet to, and subjected to an increased suction effected by, said structure, a manuallyadjustable needle-valve insaid conduit, means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintain the fuel-level in-said reservoir substantially constant, means to apply suction to the interior of said reservoir in lesser degree than that applied to the reservoir-outlet through said conduit, whereby til lift the fuel from saidsupply into said reservoir by the suction therein at the same time permitting the delivery of the reservoir fuel to said mixing structure through said conduit by reason of the specified suction difference in, and at the outlet of, said reservoir, a valve controlvoir-outlet, and means acted upon by the suction in said reservoir controlling the operation of said delivery-val
  • a carburetor adapted for use with an internal-combustionengine, the combination of a mixing-chamber adapted to be subjected .by, saidstructure, means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintain a substantially constant fuel-levelv in said reservoir, the carburetor having a passage connecting said conduit with the interior of said reservoir both above and below the liquidlevel therein and a bleeder-port for said pas-.
  • a suction less than that at the reservoir-outlet, prevails in said reservoir to lift the fuel into said reservoir from said supply at the same time permitting delivery of the fuel through said outlet by reason of the suction difference in, and at the outlet of, said reservoir, a valve controlling the outlet of said reservoir, and means to operate said valve includinga'diaphragm in said fuel- (reservoir and adapted to flex under the action of the reservoir suction, whereby under certain conditions fuel may be forced out of said reservoir through said passage into said conduit to temporarily enrich the fuel mixture.
  • a carburetor adapted for use with an internal-combustionengine, the combination of a-mixing-chamber adapted to be subjected to the suction'of the engine, an air and fuel mixing structure associated with said chamber, means to admit air to said structure, a
  • said structure means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintain a substantially constant fuel-level in said reservoir, the carburetor having a passage connecting said conduit with the interior of said reservoir and bleeder-port means for said passage,
  • a mixing-chamber adapted to be subjected to the suction of the engine, an air and fuel mixing structure associated with said chamber, means to admit air to said structure, a fuel-reservoir having an inlet and an outlet, a conduit connecting said reservoir-outlet to, and subjected to an increased suction effected by, said structure, means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintain a substantially constant fuel-level in said reservoir, the carburetor having a passage connecting said conduit with the interior of said reservoir and a normally open and a normally closed bleeder-port connecting said passage with said mixing-chamber, whereby a suction, less than that at the reservoir-outlet,
  • a carburetor adapted for use with an internal-combustion engine, the combination of a mixing-chamber adapted to besub- 'jected to the suction of the engine, an air and fuel mixing structure in said chamber, means prevails in said reservoir to lift the fuel into to admit air to said structure, a fuel-reservoir'having an inlet and an outlet, a conduit connectingsaid reservoir outlet to, and subjected to an increasedsuction effected by, said structure, means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintaina substantially constant fuel-level in said reservoir, the carburetor having a passage connecting said conduit with the interior of said reservoir and a bleeder-port connecting said passage with said" mixing chamber, whereby a suction, less than that at the reservoir-outlet, prevails in said reservoir to lift the fuel into said reservoir from said supply at the same time permitting delivery of the fuel through said outlet by reason of the suction difference in, andat the outlet of, said reservoir, a valve controlling said
  • a fuel reservoir having an inlet and an outlet, avconduit connecting said reservoir-outlet to, and subjected to an increased suction effected by, said structure, means to convey fuel from a supply lower than said reservoir to the inlet thereof, means to maintain a substantially constant fuel-level in said reservoir, the carburetor having a passage connecting said conduitwith the interior of the reservoir and a bleeder-port connecting said passage with a source of pressure greater than that therein, whereby a suction, less than that at the reservoir-outlet, prevails in said reservoir to lift the fuel tliereinto from said supply at the same time permitting delivery of the fuel through said outlet by reason of the suction difference in, and at the outlet of, said reservoir, and means to operate said auxiliary air-valve including a diaphragm in said reservoir above the fuel therein and adapted to flex under the action of the reservoir suction, the carburetor having an air vent connecting said air-entrance with the space above said diaphragm.
  • a carburetor for use with an internal-combustion engine, the combination of an air and fuel mixing structure acted upon by the carburetor suction, means to admit air to said structure, a fuel-reservoir having an inletand an outlet, a conduit connecting said reservoir-outlet to, and subjectedto an increased suction effected by, said structure, means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintain the fuel-level in said reservoir substantially constant, means to apply suction to the interior of said reservoirin lesser degree than that applied to the reservoir-outlet through said conduit, whereby. to
  • a carburetor for use with an internal-combustion engine, the combination of an air and fuel mixing structure acted upon by the carburetor suction, means to admitair to said structure, a fuel-reservoir having an inlet and an outlet, a conduit connecting said reservoir-outlet to, and subjected to an increased suction effected by, said structure, means to convey-fuel from a-supply lower han said reservoir to the inlet of the latter,
  • a carburetor for use with an internal-combustion engine, the combination of an air and fuel mixing structure acted upon by the carburetor suction, means to admit air to said structure, a fuel-reservoir having an inlet and an outlet, a conduit connecting said reservoir-outlet to, and subjected to an increased suction effected by, said structure, means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintain the fuel-level in said reservoir substantially constant, means to apply suction to the interior of said reservoir in lesser degree than that applied to the reservoir-outlet through said conduit, whereby to lift the fuel from said supply into said reservoir by the suction therein at the same time permitting the delivery of the reservoir fuel to said mixing structure through said conduit by reason of the specified suction difference in, and at the outlet of, said reservoir, a diaphragm in said reservoir acted upon by the suction therein, a spring opposing fiexure of the diaphragm in response to such suction action, a valve controlling the delivery

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Control Of The Air-Fuel Ratio Of Carburetors (AREA)

Description

May 2, 1933 LINGA I Q 1,906,982
I I CARBURETOR Filed Oct. 8, 1930 3 Sheets-Sheet '1 7 T. LING A CARBURE'I'OR Filed Oct. 8, 1930 3 Sheets-Sheet 2 May 2, 1933.. T. LINGA 1,906,982
CARBURETOR Filed Oct. 8, 1930 3 Sheets-Sheet 3 patented ay 2, 1933 TORBJ'GRN LINGA, 0F KOKOMO, INDIANA CARBURETOR Application filed October 8, 1930. Serial No. 487,206.
One object of the present invention is to provide a practical carburetor of the socalled self-feed type for internal-combustion engines, which requires no separate vacuumgank or pump to supply the carburetor with uel.
That isto say, the new carburetor is capable of lifting or elevating liquid fuel from a supply located at a level lower than that of the carburetor, as from a supply-tank positioned at the rear of an automobile which is a common and usual construction atthe present time.
A further aim of the invention is to supply a carburetor construction of this character, which, by a simple change or adjustment of a spring, may be regulated as to its fuel-lifting capacity to conform to the requirements of 'the particular installation, since it is not feasible or desirable to make a carburetor with a fuel-elevating power greatly in excess of that needed for the particular installation, as an increase in such lifting capacity necessitates an augmented depression or suction in the carburetor with a resulting loss of volumetric efliciency.
Another object of the invention is to produce a carburetor which has the lowest permissible suction or depression in its mixingchamber in order to secure maximum power out of the associated engine, especially at high speeds.
Still a further purpose is to make such a construction with low suction and at the same Q time have adequate suction to lift the fuel the required height'from the supply to the carburetor-bowl or fuel-reservoir.
Added purposes of the invention are to supply a carburetor with a relatively small restriction against inflowing air, with simple and efficient means for adjusting or controlling the fuel-air ratio for low, intermediate and high engine speeds, with effective and uncomplicated means for enriching the mixture, as well as increasing the air velocity through the venturi, during engine acceleration, with an economizer for automatically providing a leaner mixture at part-open throttle than with fully open throttle, and withmeans for enriching the mixture during the starting numerals have been employed to designate of the engine and while it is warming up, the construction being such that all air entering the carburetor must pass through a single entry passage which may, if desired, be pro vided with an air-cleaner or filter. To enable those acquainted with this art to understand the invention fully, both from structural and functional standpoints, in the accompanying drawings, forming a part of this specification, and to which reference should be had in connection with the following detailed description, a present, preferred embodiment of the invention has been shown in detail, and, for simplicity, like reference the same structural elements throughout the several views.
In these drawings Figure 1 is a central, vertical, longitudinal section through the carburetor on line 11 of Figure 2;
Figure 2 is a horizontal section through the construction on line 22 of Figure 1;
Figure 3 is a fragmentary, vertical section on line 33 of Figure 2;
Figure 4 is a horizontal section on line 44 of Figure 3;
Figure 5 is a horizontal section on line 5 5 of Figure 3; I
Figure 6 is a vertical section on line ,66 of Figure 2; and
Figure 7 is a vertical section on line 77 of Figure 2.
Referring to these drawings, it will be readily perceived that the carburetor body, characterized as a whole 11, has an air entrance or intake opening 12 through which air may flow or be drawn into the main or mixing chamber 13 occupied in part by a Venturi-tube 14, the upper end of compartment 13 being fitted with the usual throttlevalve 15 and the opening 12 being equipped with an auxiliary-air or choke valve 16.
An air-passage 17- conneets with the opening or conduit 12 outwardly beyond the auxiliary-air valve 16 and delivers its air into the lower, flaring end 18 of the Venturi construction, which, as is fully shown, is mounted in the lower wall of the carburetor and projects up into the chamber 13 with an annular, intermediate opening or port 19 through which the fuel may be entrained or sucked into the Venturi appliance.
The floatchamber or fuel reservoir or compartment 21 of the carburetor is composed of a main body or bowl 22 and a top cap or closure 23 held thereon by screws 24, 24, the border of a flexible diaphragm 25, such as a cloth treated with linseed oil, which divides the interior of the compartment into two chambers, being clamped between the marginal flanges of the two co-operating elements 22 and 23.
Fuel is admitted into the bowl 22 through an inlet-pipe 26 connected to a lower fuelsupply tank, not shown, the infeed of such fuel being governed and regulated to maintain a constant fuel level in the bowl, by a valve 27, a lever 28 on which the valve is mounted, and a float 29 underlying the lever, all of which is of usual construction.
Internally, fuel-bowl 22 has a centrallydisposed, hollow bearing 31 upstanding from its bottom wall and around this is a coiled spring 32, as nearly as possible of equal strength throughout its working range, resting at its lower end on the floor of the bowl and pressing at its upper end against the underside of the diaphragm, holes 33 being provided through the lower part of the wall of member 31 to allow the passage of the fuel therethrough into the inner chamber 34, which, as explained below, forms part of a dashpot structure.
A hollow plug 35 is screwed into the bottom wall of the bowl and the member 31, its upper, open end being equipped with a bushing or ring 36 having a central, calibrated opening'or port 37 through it, the lower part of the plug having lateral openings 38 connecting its interior chamber 30 with a as sage 39 communicatin with the inside 0 the lower end of an upright tube 41 above a screw-threaded plug 42 screwed into the body of the carburetor, a manually-adjustable, metering needle-valve 43 co-operating with the aperture at the lower endv of the tube and regulating the size of the free opening between passage 39 and the inside of the tube.
Such tube 41 is located in a larger, up right, cylindrical chamber 40 provided in the central part of the carburetor body, the top end of the tube being closed but with lateral openings 43 through its side walls just below the end closure.
As is clearly shown, the lower portion of Y chamber 40 is joined by a conduit 44 to passage 19 of the Venturi structure.
Tube 41 extends above the liquid level in reservoir 22 to prevent the drainage or siphoning off of its contents.
Fixed to the diaphragm and movable up and down therewith as the diaphragm flexes is a plunger 45 slidable in the interior of the bearlng-member 31, the plunger or piston constituting part of the dash-pot mechanism referred to above.
Such plunger has a centrally-arranged, screw-threaded opening accommodating a manually-adjustable threaded rod or screw 46 having a hollow, lower part 47 to which at 48 is fastened the upper end of a flexible wire 49, the space in the adjustment screw section 47 being large enough to permit flexure or side movement of the wire.
The lower end of such wire carries a tapered valve or calibrated metering element 51 occupying the port or opening 37, so that, as the diaphragm flexes, such element will open the port 37 more or less.
The rounded, split end of a lever-arm 52 is located between a nut 53, above the diaphragm and forming part of the means for fastening the sliding plunger to the diaphragm, and a disc 54 hearing on the top of the lever-arm and between which and the knurled head of the screw 46 a spring 55 is employed.
Such lever-arm 52 is fixedly mounted, as by screws 60, on a roclvshaft 56 capable of turning in a longitudinally-recessed, eccentric sleeve or hearing 57 having bearings 58, 58 in the walls of the carburetor.
One protruding end of shaft 56 has an arm 59 rigid therewith joined by a link 61 to an arm 62 fastened on the end of the shaft 63 of the auxiliary-air admission valve 16.
It will, therefore, be clear that as the diaphragm flexes up and down the auxiliary or choke valve 16 will be correspondingly rocked to open or close it more or less.
In order that the diaphragm may be allowed to bend in greater degree, as when starting the engine, before opening the anxil iary valve 16, the eccentric hearing or sleeve. 57 may be turned to lower the position of the fulcrum shaft 56, and this is accomplished by means of an arm 64 on one end of the sleeve 57 to which a check or operating wire 65 is connected, the usual spring 66 being employed to restore the wire, arm, and sleeve to normal position as soon as released by the operator after the choking has been completed. 2
The fuel bowl or reservoir 21 is connected through a small hole 71 to a small chamber 72 which is in communication through a port- 73 with chamber 40 and through another small orifice 74 with the carburetor mixingchamber 13, such space 72 also connecting through a metered passage 75 (Figure 5) with a right-angle condu t '76. 77 leading down into the fuel-bowl below the fuel-level therein and with another passage 78, 79, 81, 82 leading to one of the bearings 83 for the shaft 84 of the throttle-valve 15.
Such shaft 84 is longitudinally slotted or recessed at 85 in such relation or position, that, when the throttle-valve is closed (see Figure 3), the ports of passages 82 and 85 communication with chamber 13 through the connecting conduits 78, 79, 81, 82, 83.
The compartment above the diaphragm 25, as is shown in Figure 6, is joined through a hole 86 and an upright tube 87 to a passage 88 connecting with the air conduit 17, Whereby any air entering the compartment above the diaphragm is drawn through the opening 12, and, if the latter is provided with an air-cleaner or filter, all air entering the carburetor is filtered or freed from dust and the like.
The novel and improved carburetor func tions substantially as follows:
When the engine with which the carburetor is associated is at rest, spring 32 maintains the diaphragm at its upper position of flexure, thereby closing the auxiliary air-admission valve 16 by reason of the specified mechanical connection between the diaphragm and the shaft of such valve through the co-operating parts 52, 56, 59, 61, 62, 63,
and, under these circumstances, there is no open air entrance except through the relamum enginedemand, and may exceed 1 to 4 at idling.
The reason for this variation is that the suction amplifying ability of the venturi decreases as greater quantities of liquid fuel flow into it.
It will be readily seen, however, that notwithstanding this variation in the suctionaugmenting effect of the venturi due to the variation of the fuel flow, and notwithstanding that one venturi might differ somewhat from another venturi, due to a more or less exactness in their manufacture, the suction in the fuel-bowl 21 is always maintained constant to the same extent as the strength of the spring 32 is constant throughout its working range, and therefore a substantially constant predetermined suction is maintained in the fuel-bowl for lifting fuel from the lower level. The suction in the mixing chamber, however, will vary to the same extent as thesuction-augmenting factor of the venturi varies and inversely therewith.
'This depression or sub-atmospheric pressure condition is not only present in chamber 30 and at its fuel-port 37, but it will also reach the upper part of the inside of the fuel-bowl 22 through the openings 73, 72, 71, yet, at this point, the depression or suction will be' reduced by reason of the presence or action of the small bleeder-port 74, or, stated somewhat differently, the suction exerted at the port 37 will be sufliciently greater than that in the fuel-bowl above the liquid level, that a fuel flow will be brought about through the calibrated port or orifice 37 into the venturi and its proper mixture with the air.
During the operation of the engine, due to the depression created in the fuel cup or bowl 22, the diaphragm will be flexed downwardly against the action of spring 32, such bending of the diaphragm opening the auxiliary-air valve 16 more or less, and, obviously, there will be a balanced position of the parts for every throttle opening and en-- gine speed.
It is 'to be understood that the suction in the fuel-bowl 22 is sufficient to lift the incoming fuel from the lower supply tank to keep the carburetor properly charged with fuel at the desired level The degree of sub-atmospheric condition in the fuel-bowl, therefore, depends upon the strength of spring 32 and by adjusting such spring, or by simply using a stronger or weaker one, the fuel lift capacity of the carburetor may be made to meet any particular requirement.
The construction of the carburetor is such, with respect to the structure, size, strength and association of its parts, that, by the automatic operation of the auxiliary air-ad mission valve, the suction in the fuel reservoir is maintained substantially unvarying, and the suction at the outlet of the reservoir is kept practically constant, except that the latter suction is increased during engine acceleration and during full or nearly-full open throttle position.
I have, therefore, provided a carburetor having sufficient suction to lift the fuel into the reservoir and at the same time having a relatively-small depression in the mixingchamber which assures a maximum of power from the engine.
Vere a spring acting on the diaphragm selected which provided a depression in the fuel cup or bowl corresponding to a column of 40 inches of water and a depression in the carburetor mixing-chamber 13 of 14 inches, the corresponding condition in chamber 30 would be'48 inches.
The situation may be explained as follows:
The depression or suction at the top of the venturi in chamber 13 is 14 inches, and if the opening 74 were closed, the depression in both the fuel-reservoir 21 and chamber 30 would be 49 inches (14X3 assuming a venturi efficiency of 3 Passage 74 being open, however, a small stream of air flows in through it from chamber 13 and down through opening 73 and on into the Venturi at 19.
To start with, this air was under a depression of 14 inches, but its passage through the small orifice 74 causes a further drop of 26 inches giving a depression of 40 inches in chamber 72 and in the fuel-reservoir 21.
The air in passing through the larger port 73 undergoes another pressure reduction of 8 inches, makingthe depression in 40, 4:1, 39, 38, 30,48 inches, and, finally, there is an additional small pressure drop of about one inch, caused by the air passing through the opening 19 into the venturi, which balances the system, thus accounting for the full 49 inches.
There is now provided a depression of 40 inches in the fuel-bowl 21 and of 48 inches in chamber 30, affording a head of 8 inches for establishing and maintaining the fuel flow into the venturi.
This 8 inch head is practically constant or unvarying throughout the range of action of the carburetor, except during acceleration and fully open throttle, and accordingly, it becomes necessary to provide a variable fuel opening, that is, a metering device which will automatically enlarge or increase the free opening of the fuel orilice, which function is performed by the diaphragm-actuated, tapered, metering pin or valve 51.
At its lower, larger end such pin or valve 51 is just enough smaller than the orifice 37 to slip through it, and the fuel-feed adjustment for engine idling is effected by raising or lowering the tapered-pin by manipulation of its adjustment screw .1-(3.
Any irregularities in the parts are com pensated for by the capacity of the pin to shift sidewise by reason of its flexible mounting on the small wire.
As the throttle-valve is opened, the diaphragm will llex downwardly, carrying the tapered pin with it, thereby increasing the opening at orilice 257.
There would be no dilliculty in calibrating such tapered metering pin or valve to give a uniform or unvarying gaseous mixture throughout the whole range of operatiombut it has been found to be more practical and satisfactory to calibrate the metering pin to produce a progressively richer mixture as it descends, for example, over rich at the highest speed, which can be reduced to proper and correct leanness by the manually-adjustable needle-valve =13, which will affect the richness of the high speed mixture without having any considerable or material effect on the fuel-air ratio of the idling mixture because the free opening around such high speed needle 43 is very large.
An enriched mixture for starting the engine, and during its warming up period, is
provided b the operator pulling the arm 64 forwardly y means of the rod or wire 65, that is toward the air-intake end of the carburetor, which operation lowers the center of shaft 56 and changes the relative position of the auxiliary air-valve 16 and the metering pin or valve 51, the latter being lowered by such operation.
An internal-combustion engine requires a rich mixture for quick and positive acceleration and it also needs sufiicient air velocity through the venturi or mixing-chamber to atomize or break up the fuel properly, and, in this new construction, these results are obtained as follows:
When the throttle-valve is quickly opened, the diaphragm will move downwardly, but to allow this action, some of the air between the diaphragm and the surface of the fuel in the bowl or reservoir must escape.
The calibrated orifice 71 will retard such air discharge, because it is very small, and, consequently, the air pressure under the diaphragm cannot immediately equalize itself with the pressure in the small chamber 72, with the result that the pressure will be somewhat higher in the fuelbowl, and this relative increase of pressure will force fuel out through passage 77 up conduit 76,
through the calibrated orifice 7 5 into chamber 72, and from there it will pass through opening 73 into the main fuel passage or conduit and 44.
This temporarily-supplied, supplemental fuel will provide the required mixture enrichment for acceleration.
Such downward movement of the diaphragm will, as explained, be retarded, and, as a result, the opening of the auxiliary airvalve 16 will be correspondingly delayed, thereby effecting a momentary increased suction or depression in the carburetor and an augmented air velocity through the venturi.
The downward travel of the pilot or plunger will also have a slight retarding effect, due to the dash-pot action, as well as a slight direct effect in enriching the mixture.
During deceleration the diaphragm will move upwardly and air will be supplied to the space beneath it through the orifices 71 and 75, 77, thus allowing the diaphragm to flex upwardly more freely than downwardly.
A fuel mixture 20 to 24% leaner than the maximum torque mixture is the most economical to employ, and, therefore, a carburetor should have automatic means for changing the mixture ratio between partly-open and fully-open throttle-valve.
If the operator opens the throttle-valve completely, it signifies that he wishes all the power that the engine is capable of producing, and, in such a case, economy-is a secondary and insignificant consideration.
\Vhen, however, the operator partly closes the throttle, it is evident that he does not require the full power of the engine, and, in that instance, economy becomes of prime value.
A- practical and economical carburetor should have automatic means to effect a mixture ratio change as the throttle-valve moves from about 7/8ths open to fully open positional passage is usedto connect the chamber- 72 to the main-chamber 13 of the carburetor,
is capable.
and this supplemental passage is opened and closed by the movement of the throttle-valve.
During the last eighth of the opening movement of the throttle valve the chamber 72 is additionally connected to the main chamber 13 throughthe then connected passages 78,
7 9, 81, 82 and 85 thus efiecting a richer mixture to assure full power of which the engine For all other positions of thethrottl'eva'lve this Suppiementa'ry or anxfliary let and an outlet, a conduit connecting said nection is closed.
It will be noted that the carburetor has but a single air entrance 12, and, therefore, all
air which enters it must pass through such opening, which, if desired, may be provlded with an air cleaner or stralner, and, 1n this connection, it will be observed that the air which enters the conduit 17, that which passes by the auxiliary air-valve 16, and that,
'relatively to the smallest diameter of the .in-
terior of the venturi to assure adequate air velocity through the venturi with consequent full aspiration and to reduce the depression to Q a minimum in passage 17 to provide proper pressure conditions in the fuel-bowl above the diaphragm with which the conduit 17 is di cated to its interior through the hole 71. ,5 Inasmuch as little of such air flowing sition.
through orifice 74 enters the fuel-reservoir, any dust which it may carry along with it can in no way find entrance into the reservoir with resulting objectionable clogging effects. -Under extreme conditions, it may be desirable temporarily, or perhaps momentarily, to rock the eccentric sleeve 57 sufiiciently so that one of its shoulders will engage the underside of the lever arm 52 and prevent the descent of the latter, but, even under such circumstances, the diaphragm and the valve 51 which" it carries can descend under the action of the suction by reason of the presence of spring 55 between the top of the arm and the head'of the adjustment screw 46.
In such anase, the diaphragm could not open the auxiliary air-valve until the sleeve 57 were rocked back from such extreme po- Those skilled in this art will readily undermay be incorporated in the structure illustrated and described without departure from the heart and essence of the invention and JVitllOllt the sacrifice of any of its substantial benefits and advantages.
I claim: 1.- In a carburetor for use with an internalcombustion engine, the combination of an air and fuel mixing structure actedupon by the stand that many minor mechanical changes carburetor suction, means to admit air to said structure, a fuel-reservoir having an inreservoir-outlet to, and subjected to an increased suction effected by, said structure,
means to convey-fuel from a supply lower thansaid reservoir to the inlet of the latter,
means to maintain the fuel-level in said resduit by reason of the specified suction difi'er- I ence in, and at the outlet of, said reservoir,
means to permit auxiliary air to flow through the carburetor, an air-valve controlling the admission of such auxiliary air, and means governing said auxiliary air-valve and maintaining the respective suctions in said fuel reservoir and said reservoir outlet substantially unvarying.
2. In a carburetor for use with an internalcombustion engine, the combination of an air and fuel mixing structure acted upon by the carburetor suction, means to admit air to said structure, a fuel-reservoir having an inlet and an outlet, a conduit connecting said reservoir-outlet to, and subjected to an increased suction effected by, said structure, means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintain the fuel-level in said reservoir substantially constant, means to apply suction to the interior of said reservoir in lesser degree than that applied to the reservoir-outlet through said conduit, whereby to lift the fuel from said supply into said reservoir by the suction therein at the same time permitting the delivery of the reservoir fuel to said mixing structure through said conduit by reason of the specified suction difference in, and at the outlet of, said reservoir, means to permit auxiliary air to flow through the carburetor, an air-valve controlling the admission of such auxiliaryair, and means governing said auxiliary air-valve and maintaining the respective suctions in said fuel reservoir and said conduit substantially unvarying, the carburetor having a single air-entrance through which both specified air supplies flow.
3. In a carburetor for use with an'internalcombustion engine, the combination of an air and fuel mixing structure acted upon by the carburetor suction, means to admit air to said structure, a fuel-reservoir having an inlet and an outlet, a conduit connecting said reservoiroutlet to, and subjected to an increased suction effected by, said structure, means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintain the fuel-level in said reservoir substantially constant, means to apply suctionto the interior of said reservoir in lesserv degree than that applied to the reservoir-outlet through said conduit, whereby to lift the fuel from said supply into said reservoir by the suction therein at the sametime permitting the delivery of the reservoir fuel to said mixing structure through said conduit by reason of the specified suction difference in,
and at the outlet of, said reservoir, means to' permit auxiliary air to flow through the carburetor, an air-valve controlling the admission of such auxiliary 'air, and means acted upon by the suction in said reservoir controlling said auxiliary air-valve to maintain the increased suction in said reservoir substantially uniform;
4. In a carburetor for use with an internalcombustion engine, the combination of an air and fuel mixing structure acted upon by the carburetor suction, means to admit air to said structure, a fuel-reservoir having an inlet and an outlet, a conduit connecting said reservoir-outlet to, and subjected to an increased suction effected by, said structure, means to convey fuel from a supply lower than said reservoir to the inlet of, the latter, means to maintain the fuel-level in said reservoir substantially constant, means to apply suction to the interior of said reservoir in lesser degree than that applied to the reservoir-outlet through said conduit, whereby to lift the fuel from said supply into said reservoir by the suction therein at the same time permitting the delivery of the reservoir fuel to said mixing structure through said conduit by reason of the specified suction difference in, and at the outlet of, said reservoir, means to admit auxiliary air into the carburetor, an air-valve controlling the admission of such auxiliary air, means governing said auxiliary air-valve and maintaining the respective suctions in said reservoir and in said conduit substantially uniform, a valve controlling the delivery of fuel through said reservoir-outlet, and means acted upon by the suction in said reservoir controlling the operation of said fuel-delivery valve.
5. In a carburetor for use with an internalcombustion engine, the combination of an air and fuel mixing structure acted upon by the carburetor suction, means toadmit air to said structure, a fuel-reservoir having an inlet and an outlet, a conduit connecting said reservoir-outlet to, and subjected to an increased suction effected by, said structure, a
manually-adjustable needle-valve in said conduit, means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintain the fuel-level in said reservoir substantially constant, means to apply suction to the interior of said reservoir in lesser degree than that applied to the reservoir-outlet through said conduit, whereby to lift the fuel from said supply into said reservoir by the suction therein at the same time permitting the delivery of the reservoir fuel to said mixing structure through said conduit by reason of the specified suction difference in, and at the outlet of, said reservoir, a valve controlling the delivery of fuel through said reservoir-outlet, and means acted upon by suction in the carburetor controlling the operation of said delivery-valve.
6. In a carburetor for use with an internaleombustion engine, the combination of an air and fuel mixing structure acted upon by the carburetor suction, means to admit air to said structure, a fuel-reservoir having an inlet and an outlet, a conduit connecting said reservoiroutlet to, and subjected to an increased suction effected by, said structure, a manuallyadjustable needle-valve insaid conduit, means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintain the fuel-level in-said reservoir substantially constant, means to apply suction to the interior of said reservoir in lesser degree than that applied to the reservoir-outlet through said conduit, whereby til lift the fuel from saidsupply into said reservoir by the suction therein at the same time permitting the delivery of the reservoir fuel to said mixing structure through said conduit by reason of the specified suction difference in, and at the outlet of, said reservoir, a valve controlvoir-outlet, and means acted upon by the suction in said reservoir controlling the operation of said delivery-valve.
7 In a carburetor adapted for use with an internal-combustionengine, the combination of a mixing-chamber adapted to be subjected .by, saidstructure, means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintain a substantially constant fuel-levelv in said reservoir, the carburetor having a passage connecting said conduit with the interior of said reservoir both above and below the liquidlevel therein and a bleeder-port for said pas-.
sage, whereby a suction, less than that at the reservoir-outlet, prevails in said reservoir to lift the fuel into said reservoir from said supply at the same time permitting delivery of the fuel through said outlet by reason of the suction difference in, and at the outlet of, said reservoir, a valve controlling the outlet of said reservoir, and means to operate said valve includinga'diaphragm in said fuel- (reservoir and adapted to flex under the action of the reservoir suction, whereby under certain conditions fuel may be forced out of said reservoir through said passage into said conduit to temporarily enrich the fuel mixture. v
8. In a carburetor adapted for use with an internal-combustionengine, the combination of a-mixing-chamber adapted to be subjected to the suction'of the engine, an air and fuel mixing structure associated with said chamber, means to admit air to said structure, a
fuel-reservoir having aninlet and an outlet,
a conduit connecting said reservoir-outlet to,
and subjected to an increased suction effected by, said structure, means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintain a substantially constant fuel-level in said reservoir, the carburetor having a passage connecting said conduit with the interior of said reservoir and bleeder-port means for said passage,
whereby a suction, less than that at the reservoir-outlet, prevails in said reservoir, tolift the fuel into said reservoir from said supply at the same time permitting delivery of the fuel through said outlet by reason-of the suclatter range only of the opening movement of said throttle-valve to vary said bleederport means to enrich the fuel mixture.
9. in a carburetor adapted for use with an lnternal-combustion engine, the. combination of a mixing-chamber adapted to be subjected to the suction of the engine, an air and fuel mixing structure associated with said chamber, means to admit air to said structure, a fuel-reservoir having an inlet and an outlet, a conduit connecting said reservoir-outlet to, and subjected to an increased suction effected by, said structure, means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintain a substantially constant fuel-level in said reservoir, the carburetor having a passage connecting said conduit with the interior of said reservoir and a normally open and a normally closed bleeder-port connecting said passage with said mixing-chamber, whereby a suction, less than that at the reservoir-outlet,
said reservoir from said supply atthe same time permittingdelivery of the fuel through said outlet by reason of the suction difference 1n, and at the outlet of, said reservoir, a throttle-valve for the carburetor, and means op- 'erated during the latter range of the opening movement of said throttle-valve opening said normally closed bleeder-port to enrich the fuel mixture. I I 10. In a carburetor adapted for use with an internal-combustion engine, the combination of a mixing-chamber adapted to besub- 'jected to the suction of the engine, an air and fuel mixing structure in said chamber, means prevails in said reservoir to lift the fuel into to admit air to said structure, a fuel-reservoir'having an inlet and an outlet, a conduit connectingsaid reservoir outlet to, and subjected to an increasedsuction effected by, said structure, means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintaina substantially constant fuel-level in said reservoir, the carburetor having a passage connecting said conduit with the interior of said reservoir and a bleeder-port connecting said passage with said" mixing chamber, whereby a suction, less than that at the reservoir-outlet, prevails in said reservoir to lift the fuel into said reservoir from said supply at the same time permitting delivery of the fuel through said outlet by reason of the suction difference in, andat the outlet of, said reservoir, a valve controlling said reservoir-outlet, and means to operate said valve including a diaphragm 1n said reservoir above 'its fuel and adapted to flex under the action of the reservoir sucmixingchamber adapted to be subjected to the suction of the engine, an air and fuelmixing structure associated with said chamber, means to admit air from said entrance to said structure, means to admitauxiliary air from said entrance to said chamber, avalve controlling the admission of such auxiliary air,
a fuel reservoir having an inlet and an outlet, avconduit connecting said reservoir-outlet to, and subjected to an increased suction effected by, said structure, means to convey fuel from a supply lower than said reservoir to the inlet thereof, means to maintain a substantially constant fuel-level in said reservoir, the carburetor having a passage connecting said conduitwith the interior of the reservoir and a bleeder-port connecting said passage with a source of pressure greater than that therein, whereby a suction, less than that at the reservoir-outlet, prevails in said reservoir to lift the fuel tliereinto from said supply at the same time permitting delivery of the fuel through said outlet by reason of the suction difference in, and at the outlet of, said reservoir, and means to operate said auxiliary air-valve including a diaphragm in said reservoir above the fuel therein and adapted to flex under the action of the reservoir suction, the carburetor having an air vent connecting said air-entrance with the space above said diaphragm.
12. In a carburetor for use with an internal-combustion engine, the combination of an air and fuel mixing structure acted upon by the carburetor suction, means to admit air to said structure, a fuel-reservoir having an inletand an outlet, a conduit connecting said reservoir-outlet to, and subjectedto an increased suction effected by, said structure, means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintain the fuel-level in said reservoir substantially constant, means to apply suction to the interior of said reservoirin lesser degree than that applied to the reservoir-outlet through said conduit, whereby. to
lift the fuel from said supply into said reservoir by the suction therein at the same time permitting the delivery of the reservoir fuel to said mixing structure through said conduit by reason of the specified suction difference in, and at the outlet of, said reservoir, a valve controlling the delivery of fuel through said reservoir-outlet, and means acted upon by the suction in said reservoir controlling the operation of said valve, said fuel delivery valve having a flexible connection with said controlling means.
13. In a carburetor for use with an internal-combustion engine, the combination of an air and fuel mixing structure acted upon by the carburetor suction, means to admitair to said structure, a fuel-reservoir having an inlet and an outlet, a conduit connecting said reservoir-outlet to, and subjected to an increased suction effected by, said structure, means to convey-fuel from a-supply lower han said reservoir to the inlet of the latter,
suction to the interior of said reservoir in lesser degree than that applied to the reser-' voir-outlet through said conduit, whereby to lift the fuel from said supply into said reservoir by the suction therein at the same time permitting the delivery of the reservoir fuel to said mixing structure through said conduit by reason of the specified suction difference in, and at the outlet of, said reservoir, means to admit auxiliaryair into the carburetor, an air-valve controlling the admission of such auxiliary air, a valve controlling the delivery of fuel through said reservoiroutlet, means acted upon by the suction in said reservoir governing said auxiliary airvalve, controlling the operation of said fuel delivery valve, and maintaining the specified suctions substantially uniform, and means to vary the relation between said auxiliary airvalve and said fuel delivery valve to permit an enriched mixture.
14. In a carburetor for use with an internal-combustion engine, the combination of an air and fuel mixing structure acted upon by the carburetor suction, means to admit air to said structure, a fuel-reservoir having an inlet and an outlet, a conduit connecting said reservoir-outlet to, and subjected to an increased suction effected by, said structure, means to convey fuel from a supply lower than said reservoir to the inlet of the latter, means to maintain the fuel-level in said reservoir substantially constant, means to apply suction to the interior of said reservoir in lesser degree than that applied to the reservoir-outlet through said conduit, whereby to lift the fuel from said supply into said reservoir by the suction therein at the same time permitting the delivery of the reservoir fuel to said mixing structure through said conduit by reason of the specified suction difference in, and at the outlet of, said reservoir, a diaphragm in said reservoir acted upon by the suction therein, a spring opposing fiexure of the diaphragm in response to such suction action, a valve controlling the delivery of fuel through said reservoir-outlet, and a dash-pot construction retarding the flexure of said diaphragm.
In witness whereof I have hereunto set I my hand.-
- TORBJORN LINGA.
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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2589536A (en) * 1944-12-14 1952-03-18 Carbonaro Marius Clement Feeding of internal-combustion engines
US4034727A (en) * 1974-12-24 1977-07-12 Nissan Motor Co., Ltd. Automotive engine carburetor

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2589536A (en) * 1944-12-14 1952-03-18 Carbonaro Marius Clement Feeding of internal-combustion engines
US4034727A (en) * 1974-12-24 1977-07-12 Nissan Motor Co., Ltd. Automotive engine carburetor

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