US3281131A - Carburetting devices for internal combustion engines - Google Patents

Carburetting devices for internal combustion engines Download PDF

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Publication number: US3281131A
Authority: US; United States
Prior art keywords: throttle valve; fuel; pipe; chamber; conduit
Prior art date: 1962-12-27
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.): Expired - Lifetime

Application number

US331221A

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English (en)

Inventor

Mennesson Andre Louis

Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

Societe Industrielle de Brevets et dEtudes SIBE

Original Assignee

Societe Industrielle de Brevets et dEtudes SIBE

Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)

1962-12-27

Filing date

1963-12-17

Publication date

1966-10-25

1963-12-17 Application filed by Societe Industrielle de Brevets et dEtudes SIBE filed Critical Societe Industrielle de Brevets et dEtudes SIBE

1966-10-25 Application granted granted Critical

1966-10-25 Publication of US3281131A publication Critical patent/US3281131A/en

1983-10-25 Anticipated expiration legal-status Critical

Status Expired - Lifetime legal-status Critical Current

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Classifications

- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02M—SUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
- F02M17/00—Carburettors having pertinent characteristics not provided for in, or of interest apart from, the apparatus of preceding main groups F02M1/00 - F02M15/00
- F02M17/08—Carburettors having one or more fuel passages opening in a valve-seat surrounding combustion-air passage, the valve being opened by passing air
- F02M17/09—Carburettors having one or more fuel passages opening in a valve-seat surrounding combustion-air passage, the valve being opened by passing air the valve being of an eccentrically mounted butterfly type
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02D—CONTROLLING COMBUSTION ENGINES
- F02D9/00—Controlling engines by throttling air or fuel-and-air induction conduits or exhaust conduits
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02M—SUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
- F02M1/00—Carburettors with means for facilitating engine's starting or its idling below operational temperatures
- F02M1/16—Other means for enriching fuel-air mixture during starting; Priming cups; using different fuels for starting and normal operation
- F02M1/18—Enriching fuel-air mixture by depressing float to flood carburettor
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02M—SUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
- F02M7/00—Carburettors with means for influencing, e.g. enriching or keeping constant, fuel/air ratio of charge under varying conditions
- F02M7/10—Other installations, without moving parts, for influencing fuel/air ratio, e.g. electrical means
- F02M7/11—Altering float-chamber pressure
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02D—CONTROLLING COMBUSTION ENGINES
- F02D2700/00—Mechanical control of speed or power of a single cylinder piston engine
- F02D2700/02—Controlling by changing the air or fuel supply
- F02D2700/0217—Controlling by changing the air or fuel supply for mixture compressing engines using liquid fuel
- F02D2700/0225—Control of air or mixture supply
- F02D2700/0228—Engines without compressor
- F02D2700/023—Engines without compressor by means of one throttle device
- F02D2700/0233—Engines without compressor by means of one throttle device depending on several parameters

Definitions

the present invention relates to carburetting devices for internal combustion engines comprising, in their intake pipe, upstream of the main throttle valve actuated yby the driver, an auxiliary throttle valve which opens automatically and gradually as the flow rate of the air passing through said conduit or pipe increases and which controls a metering member serving to ⁇ adjust the How rate of the fuel admitted into said conduit in such manner that the cross section lof the air passage controlled by said auxiliary throttle valve and the cross section of the fuel passage control-led by said metering member are substantially proportional to each other.
the fuel is supplied from a constant level chamber the upper portion of which generally communicates exclusively with the external air, or still better with the carburettor air intake (portion of the intake conduit located upstream of the auxiliary throttle valve), downstream of an air filter.
air and fuel are supplied under the same pressure difference and form a mixture of substantially constant richness.
the chief object of the present invention is to provide a carburetting device of this kind which is better adapted lto meet the requirements of practice and in particular which is such that the richness of the air and fuel mixture is automatically adapted to conditions of operation of the internal combustion engine independent of its temperature.
a first feature of the present invention relates to devices of the above mentioned kind wherein the upper portion of the constant level chamber communicates on the one hand with the external atmosphere (or with the air intake of the carburetting device) and on the other hand with the space existing in the intake conduit between the two throttle valves, means being provided for cutting olf the communication between said chamber and said space.
This feature consists in arranging said means in such manner that they are automatically controlled in accordance with the load of the internal combustion engine and possibly further in accordance with the ow rate of air through the intake pipe.
a second feature of the invention relates to carburetting devices ofthe kind above referred to wherein the auxiliary throttle valve is an eccentrically pivoted flap the axis of rotation of whichdivides it into a small area portion and a large area portion.
This feature consists in providing in the air intake pipe a wall portion surrounding the surface described by the outline of the large area portion of the fiap valve during at least part of the movement thereof, the upper portion of the constant level fuel chamber ⁇ being preferably connected to the portion of the air intake pipe located upstream of the large area portion of the flap valve.
a third feature of the present invention relates to caryburetting devices of the kind :above referred to wherein the fuel metering member consists of a movable needle of non cylindrical shape which limits an Aannular passage for fuel between itself and the inner wall of a calibrated orifice provided in a fixed diaphragm.
This feature consists in mounting said diaphragm between, on the one hand, a resilient ring bearing upon a rigid and fixed element with respect to which the diaphragm has a radial play, and, on the other hand, a rigid adjusting element capable of screwing in or on said fixed element, in such manner that the radial position of the diaphragm with respect to the needle can be determined lby axial displacement of said needle before compression of said ring and that the axial position of the diaphragm with respect to the needle can be determined by screwing of the adjusting element and resilient flattening of said ring, which serves also to ensure fluid-tightness of the path through which fuel flows in the portion of said path located upstream of the diaphragm.
a fourth feature of the present ⁇ invention relates to carburetting devices of the kind above referred to wherein the Vfuel metering member is a needle of noncylindrical shape rigidly carried by a Irod mounted slidable in a tubular guide, which leads on the one side to the air intake and on the other side to a point below the fuel level in the constant level chamber.
This feature consists in providing inside the guide and in an intermediate portion thereof, a ⁇ groove communicating with lthe upper portion of the constant level chamber, so that, if the tubular guide is subjected on the side of the air intake to a pressure lower than on the other side, it is air admitted through said groove (and not fuel) which is sucked in from the constant level chamber to the -air intake through the annular play existing between said rod and its guide.
a fifth feature of the present invention relates to carburetting devices of the kind yabove referred to and consists in that the same block carries at least most of the fuel conduits and of the air mete-ring means and that this block is fixed to the air yintake in suc'h manner that it dips int-oI the constant level chamber while being at -a distance from lthe walls of this chamber, thermally :insulating joints being provided between the block and the air intake and the block and/or the air intake being hollowed out inside their junction zone in such manner as to reduce their mutual contact surface.
FIG. l is a vertical axial section of a carburetting device made according to a first embodiment of the invention.
FIG. 2 is aan elevational View, in the direction of the arrow of FIG. l, of the same carburetting device;
FIG. 3 is a part sectional view showing another position of operation of ⁇ a portion of the device of FIG. l;
FIG. 4 shows, similarly to FIG. l, a carburetting device made according to a modification
FIG. 5 shows a curve rela-tive to the operation of the carburetting device made according to the present invention
FIG. 6 is a view similar to FIG. 1 of a carburetting device made according to another embodiment of the invention.
FIG. 7 shows a modification of a detail of FIG. 6.
the carbure'tting device includes an intake pipe 1 containing, upstream of the main throttle valve 2 actuated by the driver (through links not shown), 4an auxiliary throttle valve 3 which opens automatically and gradually 'as the flow rate of air passing through said pipe (in the direction of the arrows of FIGS. 1, 4 and 6) increases.
Auxiliary throttle valve 3 controls a fuel mete-ring member 4. Fuel is sucked in toward pipe 1 through a conduit S opening into a portion of said pipe 1 where there is a sub-atmospheric pressure substantially equal to that existing between throttle valves 2 and 3.
the ma-in throttle valve 2 is mounted on a rotating spindle 6.
the auxiliary throttle valve 3 is mounted in the ⁇ air intake 7 which constitutes the upstreamend of pipe 1 and which is protected by an air filter (not shown).
Said auxiliary valve 3 is in the form of a flap eccentrically mounted on a rotating spindle 8.
the eccentricity of said iiap is such that it tends to open under the effect of the :air stream entering through 7, against the action of return means such as a counterweight or, as shown, a spring 9.
flap 3 may be replaced Iby any equivalent t-hrottling member (sliding piston extending transversely to the air intake 7, slide valve subjected to the action of a return spring, and so on).
throttle valve 3 which limits a space 10 together wit-h the other throttle valve 2, serves to keep in said space a sub-atmospheric pressure which is substantially constant or .at least varies as a given function of the flow' rate of air entering pipe 1.
Fuel is fed from a constant level chamber 11 where the fuel level N i-s fixed fby a float 12, this oat con trolling a needle valve 13 mounted in a feed conduit 14. Fuel is drawn from constan-t level chamber 11 through a passage 17, located under the fuel level N in said chamber 11, into a chamber 16, whence it passes, through a calibrated orilice 15, into conduit 5.
the metering member 4 consists of a needle the cross section of which varies along its length and which is carried by a rod 18 slidable in a tubular guide 19.
This guide 19 opens at it upper end into air intake 7, upstream of Hap valve 3, whereas the lower end of guide 19 is located below level N.
Rod 18 is mechanically connected to flap 3 in such manner that the angular displacements of said fiap 3 from its closing position (shown in solid lines in FIGS. 1, 4 and 6) to its maximum opening position produce a sliding displacement of needle 4 with respect to orifice 15, that is to say a variation of the free annular surface of this orifice.
the fuel sucked in through conduit 5 is metered in laccordance with the -fiow rate of the -air stream passing through conduit 1.
conduit opens into space 10 through an orifice 20 so that the fuel metered in orifice 15 by needle 4 is intro-duced by suction into space 10.
conduit 5 might open into a passage bypassing the main throttle valve 2.
conduit 5 opens into a chamber 21 which is subjected to the suction existing in space owing to the provision of an orifice 22 and which is connected with the suction of a pump 23.
This pump delivers fuel, previously metered by needle 4, toward at least one injector 24 opening into intake pipe 1 downstream of the main throtktle valve 2.
the constant level chamber 11 is permanently vented either by connection with the air intake 7 or by connection with space 10, there is maintained in said chamber 11 a constant pressure (which may be subatrnospheric). It is clear that in this case the cross section of the air passage determined by fiap valve 3 in intake pipe 1 and the cross section of the fuel passage determined by needle 4 in orifice 15 are substantially proportional to each other and that the air and fuel thus supplied under the same pressure difference form a mixture of substantially constant richness.
conduit 38 does not open directly into chamber 11 but is branched to conduit 34 in such manner that both of these conduits open through a com-mon orifice 39 into chamber 11.
both of these conduits are provided with calibrated orifices 4f) and 41 respectively, the respective cross sections of which determine the value of the suction, attenuated with respect to that exerted in space 10, which is applied to chamber 11 when conduit 38 is opened.
conduit 38 is provided with a throttling member 42 carried by a diaphragm 43 which limits in casing 44 a chamber 4S connected through a conduit 46 with the portion of pipe 1 located downstream of the main throttle valve 2.
a spring 47 is mounted so as yieldingly to oppose the action of the suction transmitted to diaphragm 43 through conduit 46.
conduit 38 communicates through an orifice 43 with a portion of space 10 located downstream of auxiliary throttle valve 3 whatever be the degree of opening of said valve, whereby the pressure in chamber 11 depends only upon the load.
conduit 38 instead of having its end 48 (FIG. 1) permanently located downstream of the auxiliary throttle valve 3 has its end 48a (FIG. 4) located in such manner that it passes from the downstream side t0 the upstream side of said secondary throttle valve 3 when the latter is gradually opened.
FIG. 4 shows in solid lines the position of throttle valve 3 for which orifice 48a is downstream thereof and, in dot-and-dash lines, the position of said valve 3 for which orifice 48a is going to pass from the downstream side to the upstream side thereof.
FIG. 5 shows a curve obtained by plotting in abscissas the number of revolution per minute V of the engine and in ordinates the richnesses a of the fuel and air mixture to be supplied to the engine, this richness being for instance the ratio of the weight of fuel to the weight of air in the mixture.
orifice 48a passes from the downstream to the upstream side of the auxiliary throttle valve 3. In this case it is no longer the suction existing in space 10, but a pressure increasing up to that existing in air intake 7 that is transmitted through conduit 38. Everything therefore takes place as if throttling member 42 gradually entered into action and the mixture is gradually enriched from the partial loads (AB') to the full load (CD) without discontinuity between these two ranges of operation.
a throttling member 42a mounted in reverse fashion with respect to the throttling member 42 of the above described embodiments (FIGS. l, 3 and 4), that is to say adapted to close conduit 38 when the load is low and to open it (as shown by FIG. 6) when the load is high.
the load is determined by the pressure existing downstream of the main throttle valve 2.
the means for controlling throttle member 42a are then identical to those for controlling the throttle member 42 of FIGS. l, 3 and 4, with the difference that spring 47 tends to open said member 42a whereas it tended to close throttle member 42.
the load is supposed to be indicated by the angular position of the main throttle valve 2.
the spindle 6 of said valve 2 carries, fixed thereon, a lever 49 adapted to bear upon throttle member 42a, which is carried by a diaphragm 43a subjected to the action of a spring 47a urging throttle member 42a toward the closed position.
conduit 38 may open into space It) through an oriiice 48 located downstream of auxiliary throttle valve 3 whatever be the degree of opening thereof, whereby the pressure in chamber 11 depends only upon the load.
conduit 38 opens, as shown in dotted lines, through an orifice 48h positioned in such manner that it passes from the upstream side to the downstream side of throttle valve 3 when said valve is gradually opened.
throttling member 42a For low and medium loads of the engine (that is to say when the degree of opening of the main throttle valve 2 is small or medium), throttling member 42a is brought into play by the suction transmitted to chamber 45 (FIG. 6) or by spring 47a (FIG. 7), so that chamber 11 1s subjected to the pressure in the air intake 7 transmitted through conduit 34. The mixture admitted to the engine is normal. On the contrary, for high loads, throttling member 42a is brought out of action by spring 47 (FIG. 6) or by lever 49 (FIG. 7) so that chamber 11 is subjected to a suction attenuated with respect to that existing in space 10. The mixture fed to the engine is leaner.
conduit 38 ends at 48 (FIG. 6) this reduction of the richness of the mixture is obtained suddenly, for a given limit of the load. On the contrary, if conduit 38 opens at 4811, this reduction of the richness is obtained gradually in a manner such as disclosed by the line portion BC of FIG. 5.
the richness of the fuel and air mixture fed to the engine is exactly adapted, in all ⁇ circumstances to the operation of the engine.
very simple tests will enable anyone skilled in the art to determine in what direction the richness of fuel and -air mixture is to vary as a function of the load and whether the air How rate is to cooperate in controlling this variation.
intake pipe 1 is provided with a wall portion 25 forming the geometrical envelope of the outline of the larger portion S of auxiliary throttle valve 3 when it is moved as shown by FIGS. l, 4 and 6.
auxiliary throttle valve 3 As the whole edge of the portion S of throttle valve member 3 remains very close to wall portion 25, lthe air streams along this edge remain always perpendicular to the portion S of the throttle valve, that is to say their angle of incidence is constant. The opening torque is lthus given an increased total value. As a consequence, the angular opening of auxiliary throttle valve 3 is much more accurate and more characteristic of the air flow rate value. Furthermore, it is then possible to use return means, such as spring 9, which are more power-ful and consequently easier to provide since less influenced by frictional resistances.
the auxiliary throttle valve consists of an eccentrically pivoted flap 3 and the fuel metering member of a needle 4 limiting, in a calibrated tone 15 provided in diaphragm 26, an annular passage for the fuel, this needle being rigid with a rod 18 mounted slidable in a rectilinear guide.
Rod 18 is connected t-o iap 3 through an arm 2'7 xed to the portion s of flap 3, a connecting rod 28 pivoted to said arm 27 and a ballandsocket joint 29 serving to connect rod 28 to rod 18.
the tolerances of manufacture are such that the position of diaphragm 26 along the axis of rod 1S is not determined initially in an accurate manner. This lack of accuracy inuences the law of variation of the yfuel ow ⁇ rate as a function of the angular position of ap 3. Furthermore, the radial position of diaphragm 26 is also lacking in accuracy with respect to needle 4, which risks being wedged in the diaphragm after it has been driven therein.
diaphragm 26 is set between, on the one hand, a ring 30 of rubber -or any other resilient material which is not attacked by the fuel, said ring bearing upon a rigid and xed element 31, and, on the other hand, a rigid adjustment member 32 adapted to screw in or on fixed element 31, the whole being such that diaphragm 26 has a radial play (that is to say a play in the horizontal direction in FIGS. 1 and 6) with respect to element 31.
fixed element 31 may consist of a block in which are provided conduits 5 and 17 and guide 19 :and adjusting member 32 may consist of a plug provided with external screw threads and screwed in block 31.
the radial position of diaphragm 26 with respect to needle 4 can be determined, before compression of ring 36, by driving needle 4 into the diaphragm. Then the axial position of diaphragm 26 with respect to needle 4 can be determined by screwing of plug 32. and resilient attening of ring 30, which varies the width of the annular space limited inside the diaphragm by needle 4, for a given position thereof. Ring 30 also serves to ensure liquidtightness of the position of chamber 16 located upstream of the diaphragm whatever be the adjustment position of said di-aphragm.
tubular guide 19 is subjected to a pressure lower on the sid-e of lair intake 7 then on that of constant level -chamber 11.
fuel might be sucked in from said chamber 11 into air intake 7 through the annular play existing between rod 18 and its guide 19, which would interfere with the good operation of the engine.
the orifice 40 of conduit 34 is located in the portion of intake pipe 1 located upstream of the portion S of flap valve 3, preferably at a distance from the wall of air intake 7.
this portion S of iiap 3 practically does not allow air to pass along wall portion 25, the pressure existing in said portion of pipe 1 is purely static without any dynamic effect: thus the pressure existing in chamber 11 is not influenced by the disturbances due to variations of the air ow rate in intake pipe 1, outside ofthe action of orifices 48a and 48b.
the carburetting device is fixed to the engine through a flange 35 which is generally located close to throttle valve 2.
a flange 35 which is generally located close to throttle valve 2.
the heat developed in the engine is transmitted to pipe 1 and might be transmitted to block 31, thus producing the formation of fuel vapor bubbles in conduits 5 or 17.
These bubbles might interfere with the operation of the engine and in particular produce an irregular operation at low speeds, that is to say for low flow rates of fuel.
block 31 is xed to the air intake 7 of pipe 1 in such manner as to dip into chamber 11 while b-eing ⁇ at a distance from the walls thereof, a thermally insulating joint 36 being provided between block 31 :and pipe 1. Furthermore, block 31 and/ or pipe 1 are provided with recesses 37 inside their joining zone so as to reduce to a minimum their surface of contact through joint 36 and consequently the transmission of heat toward element 31.
a carburetting device for an internal combustion engine which comprises, in combination, an air intake pipe, a main throttle valve in said pipe, an auxiliary throttle valve in said pipe, located upstream of said main throttle valve, said auxiliary throttle valve being responsive to the opening thrust thereon of the air -stream owing through said pipe, means f-or resiliently urging said auxiliary throttle valve toward the closed position thereof, a constant level fuel chamber, fuel feed means for leading fuel from said chamber to said pipe, means operatively connected with said auxiliary throttle valve for metering the ow of fuel through said fuel feed means so that the cross section afforded to air by said auxiliary throttle valve through said pipe and that afforded to fuel through said fuel feed means are substantially proportional to each other, means for placing the upper portion of said constant level fuel ⁇ chamber in communication with the atmosphere, a casing fixed in position with respect to said pipe, a resiliently mounted deformable diaphragm partition dividing said casing into two chambers, a rst one and a second one, a first conduit connecting said
a carburetting device for 'an internal combustion engine which comprises, in combination, an air intake pipe, a main throttle valve in said pipe, an auxiliary throttle valve in said pipe, located upstream of said main throttle valve, said auxiliary throttle valve being responsive to the opening thrust thereon of the ai-r stream owing through said pipe, means for resiliently urging said auxiliary throttle valve tow-ard the closed position thereof, a constant level fuel chamber, yfuel feed means for leading fuel from said chamber to said pipe, means operatively connected with said -auxiliary throttle valve for metering the ow of fuel through said fuel feed means so that the cross section afforded to lair by said auxiliary throttle valve through said pipe and that afforded to fuel through said fuel feed means are substantially proportional to each other, mean-s for placing the upper portion of said constant level fuel chamber in communication with the atmosphere, a casing fixed in position with respect to 'said pipe, a resiliently mounted deformable diaphragm partition dividing said casing into two chambers, a first one land a second
a carburet-ting device for an internal combustion engine which comprises, in combination, an air intake pipe, a main throttle valve in said pipe, ⁇ an auxiliary 4throttle valve in said pipe, located upstream of said main throttle valve, said auxiliary throttle rvalve being responsive to the opening thrust thereon of the air flowing through said pipe, means for resiliently urging said auxiliary throttle valve toward the closed position thereof, a constant level fuel chamber, fuel feed means for leading fuel from said chamber to said pipe, means operatively connected with said .auxiliary throttle valve for metering the ow of fuel through said fuel feed means so that the cross section afforded to air by said auxiliary throttle valve through said pipe and that afforded to fuel through said fuel feed means are substantially proportional to each other, means for placing the upper portion of said constant level fuel chamber in communication with the atmosphere, a casing fixed in position with respect to said pipe, a resiliently mounted deformable diaphragm partition dividing said casing into two chambers, a first one and a second one, a first conduit connecting said first chamber with
a c-arburetting device for an internal combustion engine which comprises, in combination, an air intake pipe, ra main throttle valve in said pipe, ran auxiliary throttle valve in said pipe, located upstream of said main throttle valve, said auxiliary throttle valve bein-g responsive to the opening thrust thereon of the air stream flowing through said pipe, means for resiliently urging said auxiliary throttle valve toward the closed position thereof, .a constant level fuel chamber, fuel feed means for leading fuel from said chamber to said pipe, means operatively connected with said auxiliary throttle valve for metering the liow of fuel through said fuel feed means so that the cross section afforded to yair by said auxiliary throttle valve through said pipe .and that afforded to fue-l through said fuel feed means are substantially proportional to each other, means for placing the upper portion of said constant level fuel chamber in communication with the atmosphere, a casing fixed in position with respect to said pipe, said casing having a resilient wall, Ian arm rigid with said main throttle valve bearing against said resilient wall so as to deform it inwardly more and more
a carburetting device for an internal combustion engine which comprises, in combination, an air intake pipe, a main throttle valve in said pipe, an auxiliary throttle valve in said pipe, located upstream of said main throttle valve, said auxiliary throttle valve lbeing responsive to the opening thrust thereon of the ⁇ air stream flowing through -said pipe, means for resiliently urging said auxiliary throttle valve toward the closed position thereof, a constant level fuel chamber, fuel feed means for leading fuel from said chamber to said pipe, means operatively connected with said auxiliary throttle valve for metering the flow of fuel through said fuel feed means so that the cross section afforded to :air by said auxiliary throttle valve through said pipe land that afforded to fuel through said fuel feed means .are substantially proportional to each other, means for placing the upper portion of said constant level fuel chamber in communication with the atmosphere, a casing fixed in position with respect to said pipe, said casing having a resilient wall, an arm rigid with said main throttle valve bearing against said resilient wall so as to deform it inward-ly more land more as said main throttle valve is being
a carburet-ting device for yan internal combustion engine which comprises, in combination, an air intake pipe, a main throttle valve in said pipe, ⁇ an auxiliary throttle valve in said pipe, located upstream of said main throttle valve, said auxiliary throttle valve being responsive to the opening thrust thereon of the air stream flowing thro/ugh said pipe, means for resiliently urging said auxiliary throttle valve toward the closed position thereof, a constant level fuel chamber, fuel feed means for leading fuel from said chamber rto said pipe, means operatively connected with said auxiliary throttle valve for metering the flow of fuel through said fuel feed means so that the cross section 'afforded to air by said auxiliary throttle valve through said pipe and that afforded to fuel through said fuel feed means are substantially proportional to each other, means for placing the upper portion of said constant level fuel chamber in communication with the external atmosphere, means for placing the upper portion of said constant level chamber in communication with the portion of said intake pipe between said two throttle valves and means for automatically controlling said last mentioned means in response 4both to variations of the load of said engine and 'to
a carburetting device for an internal combustion engine which comprises, in combination, an air intake pipe, a main throttle valve in said pipe, :an :auxiliary throttle valve in said pipe upstream of said main throttle valve, said auxiliary throttle valve being responsive to the opening thrust thereon of the air stream flowing through said pipe, means for resiliently urging said auxiliary throttle valve toward the closed position thereof, a fuel chamber, a fuel feed cond-uit opening into said pipe, a supporting element fixed with respect to said pipe and .provided with a fue-l passage connecting said fuel chamber with said fuel feed conduit, -a needle slidably guided witli respect to said element and operatively connected with said auxiliary throttle valve, a portion of said needle forming the inner wall of :a portion of said passage, a rigid element having a hollow portion coaxially surrounding a portion of said needle, said rigid element being carried by said supporting element adjustably in the direction of said needle, an :annular diaphragm formed as a separate unit surrounding said needle, a resilient ring mounted

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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)
Control Of Throttle Valves Provided In The Intake System Or In The Exhaust System (AREA)

US331221A 1962-12-27 1963-12-17 Carburetting devices for internal combustion engines Expired - Lifetime US3281131A (en)

Applications Claiming Priority (1)

Application Number	Priority Date	Filing Date	Title
FR919893A FR1352897A (fr)	1962-12-27	1962-12-27	Perfectionnements apportés aux dispositifs de carburation pour moteurs à combustion interne

Publications (1)

Publication Number	Publication Date
US3281131A true US3281131A (en)	1966-10-25

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Family Applications (1)

Application Number	Title	Priority Date	Filing Date
US331221A Expired - Lifetime US3281131A (en)	1962-12-27	1963-12-17	Carburetting devices for internal combustion engines

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US (1)	US3281131A (de)
BR (1)	BR6355509D0 (de)
DE (1)	DE1281748B (de)
ES (1)	ES294850A1 (de)
FR (1)	FR1352897A (de)
GB (1)	GB993825A (de)
SE (1)	SE303901B (de)

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
US3493217A (en) *	1966-12-16	1970-02-03	John Dashwood Farley	Carburettors
US3695592A (en) *	1970-06-08	1972-10-03	Bendix Corp	Plate-type air valve carburetor
US4117046A (en) *	1977-07-07	1978-09-26	Toyota Jidosha Kogyo Kabushiki Kaisha	Variable-venturi carburetor
US4158567A (en) *	1973-07-09	1979-06-19	Toppan Printing Co., Ltd.	Method of screen gravure photoengraving
US4298549A (en) *	1979-10-29	1981-11-03	Woodworth Carburetor Corp. Of Nevada	Carburetor
US4359433A (en) *	1979-07-28	1982-11-16	Bosch & Pierburg System Ohg	Constant-pressure carburetor

Families Citing this family (7)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
US3307837A (en) *	1965-09-13	1967-03-07	Bendix Corp	Enrichment device for air valve carburetor
IT995212B (it) *	1972-08-29	1975-11-10	Bosch Gmbh Robert	Impianto di dosaggio del carburante per motori a combustione interna
FR2329860A1 (fr) *	1975-10-31	1977-05-27	Sibe	Perfectionnements aux dispositifs de carburation
DE2638666A1 (de) *	1976-08-27	1978-03-02	Volkswagenwerk Ag	Kraftstoff-einspritzeinrichtung
JPS5382932A (en) *	1976-12-29	1978-07-21	Toyota Motor Corp	Variable venturi type carburetor
DE2900459A1 (de) *	1979-01-08	1980-07-17	Volkswagenwerk Ag	Einrichtung zur kontinuierlichen einspritzung eines aus kraftstoff und luft bestehenden gemisches in die ansaugleitung einer brennkraftmaschine
US5133905A (en) *	1989-10-26	1992-07-28	Walbro Corporation	Fuel metering method and apparatus

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US1586683A (en) *	1917-03-12	1926-06-01	Stromberg Motor Devices Co	Carburetor
US1948135A (en) *	1931-08-25	1934-02-20	Zenith Detroit Corp	Carburetor
US2029142A (en) *	1933-03-15	1936-01-28	Wemhoner Wilhelm	Carburetor for combustion engines
US2082293A (en) *	1935-06-12	1937-06-01	Linga Torbjorn	Carburetor
US2443464A (en) *	1943-06-07	1948-06-15	R D Fageol Co	Carburetor
US2598450A (en) *	1938-06-09	1952-05-27	Bendix Prod Corp	Carburetor
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US3037751A (en) *	1959-07-20	1962-06-05	Tillotson Mfg Co	Charge forming method and apparatus
US3078079A (en) *	1960-06-29	1963-02-19	Gen Motors Corp	Air valve carburetor
US3093699A (en) *	1961-01-30	1963-06-11	Acf Ind Inc	Carburetor
US3147320A (en) *	1961-05-16	1964-09-01	Enginering Res And Applic Ltd	Carburetors
US3207491A (en) *	1961-07-07	1965-09-21	Bendix Corp	Fuel metering device for carburetors

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DE668515C (de) *	1935-07-19	1938-12-05	Torbjorn Linga	Selbstsaugender Vergaser
FR46567E (fr) *	1935-07-26	1936-07-10		Dispositif pour la réalisation d'économies de combustible dans les carburateurs des moteurs à explosion
FR1302537A (fr) *	1961-07-17	1962-08-31	Sibe	Perfectionnements apportés aux dispositifs de carburation pour moteurs à combustion interne

1962
- 1962-12-27 FR FR919893A patent/FR1352897A/fr not_active Expired
1963
- 1963-12-13 DE DES88713A patent/DE1281748B/de active Pending
- 1963-12-17 US US331221A patent/US3281131A/en not_active Expired - Lifetime
- 1963-12-19 BR BR155509/63A patent/BR6355509D0/pt unknown
- 1963-12-23 SE SE14443/63A patent/SE303901B/xx unknown
- 1963-12-23 GB GB50693/63A patent/GB993825A/en not_active Expired
- 1963-12-26 ES ES294850A patent/ES294850A1/es not_active Expired

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US1586683A (en) *	1917-03-12	1926-06-01	Stromberg Motor Devices Co	Carburetor
US1948135A (en) *	1931-08-25	1934-02-20	Zenith Detroit Corp	Carburetor
US2029142A (en) *	1933-03-15	1936-01-28	Wemhoner Wilhelm	Carburetor for combustion engines
US2082293A (en) *	1935-06-12	1937-06-01	Linga Torbjorn	Carburetor
US2598450A (en) *	1938-06-09	1952-05-27	Bendix Prod Corp	Carburetor
US2443464A (en) *	1943-06-07	1948-06-15	R D Fageol Co	Carburetor
US2796243A (en) *	1955-05-16	1957-06-18	Gen Motors Corp	Carburetor
US3037751A (en) *	1959-07-20	1962-06-05	Tillotson Mfg Co	Charge forming method and apparatus
US3078079A (en) *	1960-06-29	1963-02-19	Gen Motors Corp	Air valve carburetor
US3093699A (en) *	1961-01-30	1963-06-11	Acf Ind Inc	Carburetor
US3147320A (en) *	1961-05-16	1964-09-01	Enginering Res And Applic Ltd	Carburetors
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* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
US3493217A (en) *	1966-12-16	1970-02-03	John Dashwood Farley	Carburettors
US3695592A (en) *	1970-06-08	1972-10-03	Bendix Corp	Plate-type air valve carburetor
US4158567A (en) *	1973-07-09	1979-06-19	Toppan Printing Co., Ltd.	Method of screen gravure photoengraving
US4117046A (en) *	1977-07-07	1978-09-26	Toyota Jidosha Kogyo Kabushiki Kaisha	Variable-venturi carburetor
US4359433A (en) *	1979-07-28	1982-11-16	Bosch & Pierburg System Ohg	Constant-pressure carburetor
US4298549A (en) *	1979-10-29	1981-11-03	Woodworth Carburetor Corp. Of Nevada	Carburetor

Also Published As

Publication number	Publication date
SE303901B (de)	1968-09-09
ES294850A1 (es)	1964-05-01
BR6355509D0 (pt)	1973-03-13
FR1352897A (fr)	1964-02-21
DE1281748B (de)	1968-10-31
GB993825A (en)	1965-06-02

Publication	Publication Date	Title
US3281131A (en)	1966-10-25	Carburetting devices for internal combustion engines
US2377607A (en)	1945-06-05	Method and apparatus for forming a charge
US2382625A (en)	1945-08-14	Manifold injection carburetor
US2392055A (en)	1946-01-01	Carburetor of the fuel injection type
US4530805A (en)	1985-07-23	Flow regulating carburetors
US2318216A (en)	1943-05-04	Variable fuel orifice carburetor
US3742922A (en)	1973-07-03	Multi carburetor system of variable area venturi type with auxiliary fuel supply system
US2899948A (en)	1959-08-18	groves
US2456603A (en)	1948-12-14	Fuel supply system
US3259378A (en)	1966-07-05	Carburetors for internal combustion engines
US2426741A (en)	1947-09-02	Charge forming device
US2915053A (en)	1959-12-01	Fuel injection system
US3198497A (en)	1965-08-03	Carburetors for internal combustion engines
US3188062A (en)	1965-06-08	Carburetor
US2399077A (en)	1946-04-23	Power limiting carburetor
US2679835A (en)	1954-06-01	Carburetor
US2400415A (en)	1946-05-14	Automatic fuel control
US2749898A (en)	1956-06-12	Fuel injection control
US3841612A (en)	1974-10-15	Altitude and temperature compensated carburetor
GB2043784A (en)	1980-10-08	Variable-venturi carburettor having low machine flow characteristics
US2601975A (en)	1952-07-01	Carburetor
US2394664A (en)	1946-02-12	Control apparatus
US2368995A (en)	1945-02-06	Governor
US3131681A (en)	1964-05-05	Spark advance system
US1883809A (en)	1932-10-18	Carburetor

US3281131A - Carburetting devices for internal combustion engines - Google Patents

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Cited By (6)

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Citations (12)

Family Cites Families (4)

Patent Citations (12)

Cited By (6)

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