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US1510366A - Fuel mixer - Google Patents

Fuel mixer Download PDF

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Publication number
US1510366A
US1510366A US404885A US40488520A US1510366A US 1510366 A US1510366 A US 1510366A US 404885 A US404885 A US 404885A US 40488520 A US40488520 A US 40488520A US 1510366 A US1510366 A US 1510366A
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United States
Prior art keywords
partition
chamber
fuel
engine
tube
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Expired - Lifetime
Application number
US404885A
Inventor
Whiteman James Carlile
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.)
WHITEMAN S SUPURB CARBURETTOR
WHITEMAN'S "SUPURB" CARBURETTOR Co Ltd
Original Assignee
WHITEMAN S SUPURB CARBURETTOR
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Priority to US404885A priority Critical patent/US1510366A/en
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Classifications

    • 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
    • F02M9/00Carburettors having air or fuel-air mixture passage throttling valves other than of butterfly type; Carburettors having fuel-air mixing chambers of variable shape or position
    • F02M9/10Carburettors having air or fuel-air mixture passage throttling valves other than of butterfly type; Carburettors having fuel-air mixing chambers of variable shape or position having valves, or like controls, of elastic-wall type for controlling the passage, or for varying cross-sectional area, of fuel-air mixing chambers or of the entry passage
    • F02M9/106Pneumatic or hydraulic control
    • 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
    • F02M29/00Apparatus for re-atomising condensed fuel or homogenising fuel-air mixture
    • F02M29/04Apparatus for re-atomising condensed fuel or homogenising fuel-air mixture having screens, gratings, baffles or the like
    • 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
    • F02M7/22Other installations, with moving parts, for influencing fuel/air ratio, e.g. having valves fuel flow cross-sectional area being controlled dependent on air-throttle-valve position
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10STECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10S261/00Gas and liquid contact apparatus
    • Y10S261/23Fuel feeding valves
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10STECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10S261/00Gas and liquid contact apparatus
    • Y10S261/58Choke tube having plurality of leaves

Definitions

  • Vthe fuel In some types of carburetter, it has been proposed to vaporize Vthe fuel by passing it from a nozzle in spray form and causing it to then travel over foraminous or roughened surfaces under the inuence of suction from -the engine, whereby the hydro-carbonaceous molecules cling to the mechanical b supporting surfaces in the path of an induced atmospheric current.
  • the lighter particles of hydro-carbon are evaporated and absorbed by the air current, the heavier ones moving over ortravelling along the irregular surfaces, until suflicient thinness or d reduction in density condition they stream.
  • Theobject of the present invention is to provide a carburetion method and apparatus for carrying it into efficient practice, whereby homogeneous mixture of the fuel and air supply is thoroughly effected without unduly retarding the passage of the ,gases through the carburetter, and whereby the resultant mixture is so dryy that maximum engine power and economy are obtained.
  • the process or method consists in Spraying' the fuel into an atmospheric stream induced by suction, in breaking up the globis obtained in which are absorbed by the air ules of hydrocarbon by forcible impact while in atmospheric suspension in distorting the globules by elongation caused through retardation of their accelerated travel towards the source of suction in expanding the globules to bursting point and 'in repeating these steps until the hydrocarbonaceous globules are so thin or reduced in density that they become completely absorbed by Athe air supply and the resultant omogeneous mixture is so dry as compared with the usual fuel mixtures, that'great economy in fuel and increased power 1s obtained.
  • the method consists in subjecting particles of hydro-carbon, whilst in atmospheric suspension and under, ⁇ the inlluence of suction, to forcible impact against a plurality of foraminous surfaces comprising perforated partitions of baille plates arranged in a series of chambers each of which successively increases in area in contradistinction to the progressive reduction in the area ofthe perforations of each successive partition or baffle plate, whereby thorough co-mingling of the gases during the breaking, distortion and expansion of the globules is caused-until they are so thin or reduced in density that complete absorption y the carrying atmosphere obtains and a dry homogeneous mixture is'secured.
  • the atmospheric stream induced through the carburetter by the suction of the engine is automatically regulated according to the loading of the engine, the fuel supply being proportional to and synchronizing with the air supply.
  • the atmospheric stream and molecules of hydro-carbon carried thereby pass to an atomizing and gas expansion chamber divided by a plurality of perforated partitions or batHe plates into a series of progressively enlarged compartments, the perforations in the partitions or baille plates being arranged in staggered relationship and progressively reduced in area as the area of the respective compartments increases.
  • the means employed for controlling the supply of hydro- Carbon fuel are operated by the air stream or supply caused by the suction of the engine. The quantity of air and fuel is therefore proportionate at all speeds.
  • Figure 1 is a part sectional view in vertical section of a carburetter according to the invention, .portions being broken away for convenience of illustration.
  • Figure 2 is a part sectional perspective detail view showing a delivery tube, jet tube, and distributing tube assembled.
  • Figure 3 is a part sectional perspective view of an atomizing and gas expansion chamber provided with an annular heating space.
  • Figure 4 is a plan of a generating and feed chamber.
  • Figure 5 is a side elevation of the generating and feed chamber. An access plate has been removed and portions have been broken away for convenience of illustration.
  • Figure 6 is a perspective View of an inclined shutter and a pivot pin and lever thereof.
  • Figure 7 is a sectional detail view of a toothed pinionand a stuffing box encircling the spindle thereof.
  • the invention includes a float chamber 2 having therein a float 3 suitably controlling a fuel duct 4.
  • the duct 4 communicates with a sump 5 formed in a base element 6.
  • a 4pinion recess 7 above is a nut recess 8 having around its circumference an upstanding jointing shoulder 9.
  • the base element 6 has threaded thereon a nut 10 closing the sump 5.
  • the bottom 23 of a generating and feed chamber 24 Mounted upon and secured by screws or the like to the base element 6 is the bottom 23 of a generating and feed chamber 24.
  • the bottom 23 is provided with a jointing recess 25 having therein a jointing ring 26 and accommodating the jointin shoulder 9 of the base element.
  • ber 24 is a removable access plate 27. Upstanding from the upper end of the chamber 24 is a jointing shoulder 28 around which is a jointing flange 29. Passing through one side of the chamber 24 is an air intake branch 30 having near its outer end an outflow wall 31.
  • Threaded into the threaded hole formed in the bottom 23 of the chamber 24 is the threaded lower end 32 of a jet tube 33. Carried by the lower end 32 is a nut 34 accommodated in the ⁇ recess 8-of the base element 6. Formed between the jet tube 33 and the delivery tube 2O is an annular fuel space indicated at 35.
  • a distributing tube or sleeve 36 Slidably embracing the tube 33 is a distributing tube or sleeve 36 having a closed upper end 37. Carried by the upper end 37 is a regulating needle valve having a head 38 provided with a lateral groove 39. Below the head 38 is a body portion 40 threaded into the closed upper end 37 of the tube 36. Integral with the body portion 40 is a shank or modulating pin 41. This descends into the open upper end of the delivery tube 20. Formed in the upper end of the distributing tube 36 is a plurality of exi-t slots 42. Carried by the lower end of the tube or sleeve 36 is a pair of collars 43.
  • each pin is carried by the inner end of a lever 45 the outer end of which is preferably formed integral with the lower end of an inclined shutter 46l
  • Carried bythe lower end of each shutter 46 is a pivot pin 47 extendinglaterally across and mounted in the feed chamber 24.
  • the upper end of each shutter 46 is provided with a gullet 48 whereby the pair of shutters embrace the upper end of the distributing tube or sleeve 36.
  • Carried by each shutter 46 is a stud 49.
  • Encircling each stud 49 is the inner end of an adjustable helical spring 50.
  • the outer end of each spring 50 is controlled by an adjusting screw 51 carried by the feed chamber 24.
  • the two shutters 46 control the passage of an atmospheric stream induced through the chamber 24 from the intake branch 30 by t-he suction of the engine.
  • the shutters vibrate or oscillate according to the running of the engine and' by their inclination direct the atmospheric current towards the exit slots 42 past which it travels at intensified velocity.
  • the flange 52 Secured by screws or the like to the ⁇ iange 29 of the feed chamber 24 is 'the flange 52 of an atomizing and as expansion chamber.
  • the bottom of t. e gas chamber is provided with a jointing recess 53 accommodating the jointing'shoulder 28 of the feed chamber 24.
  • a delivery neck 54 integral with which is an outwardly inclined or flared wall 55 having ated in the neck 54 of at its upper end an internal circumferential Shoulder 56 above which is an internal thread 57.
  • a lower perforated partition 58 Disposed within the atomizing and gas expansion chamber is a lower perforated partition 58 above which is an intermediate perforated partition or partitions 59. Above the intermediate partitions 59 and resting upon the internal shoulder 56 is an upper perforated partition 60. It will be observed ( Figure 3) that the perforations 158 in the lower partitions 58 are of larger area than the perforations 159 in the intermediate partitions 59. The perforations are smaller in each successive partition until, in the upper parti-tion 60, the perforations 160 have reached the smallest area. The perforations are disposed in staggered relationship thereby preventing any particle of hydro-carbon having a clear passage from the delivery neck 54 to the upper partition 60.
  • a tie bolt 6l Uniting the perforated partitions is a tie bolt 6l provided with a retention nut 62. Carried by the tie bolt and disposed between the partitions 58, 59 and 60 and spacing them apart is a pluralit of tubular distance pieces 63. rIhe num r of partitions employed may be varied.
  • a removable cap or dome 64 having around its lower end an external thread indicated at 65. Passing from the cap or dome 64 is a gas outlet branch 66 forming an induction port 67.
  • the gas outlet branch 66 is provided with a Hange by which it is suitably secured to the manifold of the engine. isposed in the branch 66 is a spindle 69 carrying a suitable throttle valve 70 which may, if desired, be situthe gas chamber.
  • a mixing, breaking and stretching compartment 7l Formed by the neck 54 of the gas chamber, between the lower end thereof and the lower perforated parti-tion 58, is a mixing, breaking and stretching compartment 7l.
  • a multiplication and expansion compartment 72 Formed within the gas chamber, between the lower perforated partition 58 and the intermediate perforated partition 59 above it, is a multiplication and expansion compartment 72. A similar compartment is formed between each intermediate perforated partition 59 and the partition 59 or above it as the case may be.
  • a mixture delivery compartment 73 Formed within the cap or dome 64, above the upper perforated partition 60, is a mixture delivery compartment 73 communicating with the gas outlet branch 66 and controlled by the throttle valve 70.
  • the gas expansion chamber may be provided with a jacket or outer shell 74.
  • Communicating with the annular heating space 75 thus formed around the chamber is an inlet pipe 76 and an outlet pipe 77. rlhe inlet pipe receives hot exhaust ases from the exhaust pipe or silencer of t e engine.
  • hot gases may be delivered back to the engine exhaust pipe or silencer by the outlet pipe 77.
  • the jacket 74 and heating space 75 provide a simple means for heating the atomizing and gas expansion chamber.
  • gasoline or other fuel is delivered to the float chamber 2 the flow of fuel to and from the chamber being controlled by the float 3 in any ordinary manner.
  • the fuel passes through the duct 4 into the sump 5 and through the inlet holes 2l rising in the delivery tube 20. lt also rises in the annular space 35 inside the jet tube 33.
  • the height attained by the spirit depends upon the level of the float 3 in the float chamber 2 as is usual in carburetters.
  • the lever 17 is operated causing the pinion 16 to rotate and engage the collars lt of the delivery tube 2O which is lowered in relation to the needle shank 4l.
  • An excess flow of fuel is thus permitted to pass from the tube 2O in order that the engine may lreceive the rich mixture necessary for starting.
  • the carburetter now operates automatically'.
  • An air current or stream is induced by the suction of the engine through the air intake branch 30 and passes upwardly beneath the shutters 46 maintaining them open according to the suction and therefore .the loading of the engine and against the inuence of the helical springs 50.
  • the atmospheric stream is directed by the pair of inclined shutters towards the restricted space formed around and between the upper end of the distributing tube 36 and the upper ends of Ithe shutters.
  • the velocity of the air as it passes the exit slots 42 is therefore increased.
  • the distributing tube or sleeve 36 rises or falls according to the movement of the shutters 46, the air and gasoline or other fuel being automatically proportioned.
  • the slots 42 are opened or are covered by the upper end of the jet tube 33.
  • the quantity of fuel passing through the vertical passageway 22 of the delivery tube 20 may be regulated, according to the size of the engine, by substituting needle valves having Shanks 4l of varying sizes and these Shanks may be tapered. Should the carburetter flood or require to be flooded for any reason the overflow of spirit is retained within the air intake branch 30 by the out-flow Wall 31.
  • the particles or globules of hydro-carbon strike forcibly against the lower perforated partition 58. Some of the globules may pass through the perforations in the partition. These will encounter the intermediate partition 59 immediately above the lower partition 58.
  • the perforations in ⁇ the partitions are arranged in irregular or staggered relationship for this purpose.
  • a globule sufficiently thinned or reduced will, like a small bubble, eventually burst by frictional contact in the air stream, but, on account of the reduction in the sizes of the a ertures in each succeeding partition and t e staggered relationship of the apertures, any globule that may pass through an aperture in any partition will encounter a succeeding partition and be broken into a mass of globulets each of which is in turn elon ated and expanded and reduced in denslty. Or it will burst in attempting to pass through an aperture. Close observa.
  • a method of carburetion which consists in subjecting the globules of a hydrocarbon vapor wl'ulst suspended in an atmospheric stream and under the iniiuence of suction to a breaking action by forcible impact, to elongation by frictional retardation, and to enlargement by natural expansion in a series of inter-communicating compartments of progressively increased area, until the hydro-carbon particles are so reduced in density as to be absorbedby the atmospheric stream., and delivering the dry homogeneous mixture obtained into a compartment of still greater area in direct communication with the source of suction. .y
  • a method of carburetion which consists in projecting into a compartment a hydrocarbon vapor suspended in an air stream induced by suction, and subjecting the par.- ticles of hydro-carbon to a breaking action by forcible impact, an elongating action by friction and an enlarging action by expansion, multiplying the breaking, elongating and enlarging actions by delivering l the gases through a series of inter-communicating compartments of progressively increas- -ing area, andvsubjectin the gases to heat during the treatment, Wereby a dry homogeneous mixture is obtained.
  • an atomizing and gas expansion chamber divided into a plurality of inter-communicating compartments each successively of increased transverse dimension while of uniform vertical dimension by a series of superimposed or spaced perforated partitions,.the perforations of apertures of said partitions gradually reducing in area from one end of said chamber to the other, for the purpose specied.
  • an atomizing and gas expansion chamber having therein a plurality of super-imposed perforated partitions, the area of each partition being eater than that of the partition preceding 1t whilst the apertures in each partition are of less area than those formed in the partition preceding it and are staggered in relation thereto.
  • a'n atomizing and gas expansion chamber consistin in an outwardly inclined or ared wal a removable cap or dome carried by the chamber above the wall, a gas outlet branch communicating with the cap or dome, and a plurality of super-imposed perforated partitions disposed within the chamber and forming therein a series of super-imposed compartments inter-communicating with each other through the apertures in the partitions, the area of each partition being 'greater than the area of that precedi it and the perforations in each partition eing of less area than those in the partition preceding it and being staggered in relation thereto.

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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

Sept. 30 1924.,
3,510,366 .1. c. WHITEMAN FUEL,` MIXER Filed Aug. 2O 1920 2 Sheets-Shes?. l
Sept. 30. 1924,` lll .1. c. WHITEMAN FUEL MIXER Filed Aug. 20 '3920 2 SheetS-Shee. 2
Patented Sept. 30, i924.,
UNITED STATS PATENT @FFHQE.
JAMES CARLILE WHITEMAN,
OF CHRISTCHURCH, NEW ZEALAND, ASSIGNOR T WHITEMANS SUPURB CARBURETTOR COMPANY LIMITED, OT SYDNEY, NEW
SOUTH WALES, AUSTRALIA.
FUEL MIXER.
Application led August 20, 1920. Serial No. 404,885.
In the atomization of hydro-carbons in the presence of air for the purpose of proh vlding an air and fuel mixture as fuel for internal combustion engines it is highly desirable to thoroughly co-mingle the air and fuel during their passage from the gasoline or other spirit supply, and it is well recognized that upon efficient vaporization and complete absorption of the hydro-carbons by the air supply largely depends the dryness of the resultant mixture and consequent economical consumption and engine power derived. Y
In some types of carburetter, it has been proposed to vaporize Vthe fuel by passing it from a nozzle in spray form and causing it to then travel over foraminous or roughened surfaces under the inuence of suction from -the engine, whereby the hydro-carbonaceous molecules cling to the mechanical b supporting surfaces in the path of an induced atmospheric current. The lighter particles of hydro-carbon are evaporated and absorbed by the air current, the heavier ones moving over ortravelling along the irregular surfaces, until suflicient thinness or d reduction in density condition they stream.
Theobject of the present invention is to provide a carburetion method and apparatus for carrying it into efficient practice, whereby homogeneous mixture of the fuel and air supply is thoroughly effected without unduly retarding the passage of the ,gases through the carburetter, and whereby the resultant mixture is so dryy that maximum engine power and economy are obtained.
Briefly the process or method consists in Spraying' the fuel into an atmospheric stream induced by suction, in breaking up the globis obtained in which are absorbed by the air ules of hydrocarbon by forcible impact while in atmospheric suspension in distorting the globules by elongation caused through retardation of their accelerated travel towards the source of suction in expanding the globules to bursting point and 'in repeating these steps until the hydrocarbonaceous globules are so thin or reduced in density that they become completely absorbed by Athe air supply and the resultant omogeneous mixture is so dry as compared with the usual fuel mixtures, that'great economy in fuel and increased power 1s obtained.
More specifically the method consists in subjecting particles of hydro-carbon, whilst in atmospheric suspension and under,` the inlluence of suction, to forcible impact against a plurality of foraminous surfaces comprising perforated partitions of baille plates arranged in a series of chambers each of which successively increases in area in contradistinction to the progressive reduction in the area ofthe perforations of each successive partition or baffle plate, whereby thorough co-mingling of the gases during the breaking, distortion and expansion of the globules is caused-until they are so thin or reduced in density that complete absorption y the carrying atmosphere obtains and a dry homogeneous mixture is'secured. The greater the speed of the engine the greater are the forces of disruption and the impact of the hydro-carbon particles against the partitions and against each other, and the rier is the mixture passing to the engine. In the apparatus provided the atmospheric stream induced through the carburetter by the suction of the engine is automatically regulated according to the loading of the engine, the fuel supply being proportional to and synchronizing with the air supply. The atmospheric stream and molecules of hydro-carbon carried thereby pass to an atomizing and gas expansion chamber divided by a plurality of perforated partitions or batHe plates into a series of progressively enlarged compartments, the perforations in the partitions or baille plates being arranged in staggered relationship and progressively reduced in area as the area of the respective compartments increases. The means employed for controlling the supply of hydro- Carbon fuel are operated by the air stream or supply caused by the suction of the engine. The quantity of air and fuel is therefore proportionate at all speeds.
The features of novelty are more particularly pointed out in the appended claims.
Referrin to the drawings which form part of th1s` specification:-
Figure 1 is a part sectional view in vertical section of a carburetter according to the invention, .portions being broken away for convenience of illustration.
Figure 2 is a part sectional perspective detail view showing a delivery tube, jet tube, and distributing tube assembled.
Figure 3 is a part sectional perspective view of an atomizing and gas expansion chamber provided with an annular heating space.
Figure 4 is a plan of a generating and feed chamber.
Figure 5 is a side elevation of the generating and feed chamber. An access plate has been removed and portions have been broken away for convenience of illustration.
Figure 6 is a perspective View of an inclined shutter and a pivot pin and lever thereof.
Figure 7 is a sectional detail view of a toothed pinionand a stuffing box encircling the spindle thereof.
The invention includes a float chamber 2 having therein a float 3 suitably controlling a fuel duct 4. The duct 4 communicates with a sump 5 formed in a base element 6. Provided in the element 6 is a 4pinion recess 7 above which is a nut recess 8 having around its circumference an upstanding jointing shoulder 9. The base element 6 has threaded thereon a nut 10 closing the sump 5.
Passing into the base element 6 is the threaded inner end 11 of'a stufling box 12 containing suitable packinof 13 compressed by a threaded gland 14. Passing through the stuiiing box 12 and gland 14 is a spindle 15 upon the inner end of which is mounted a toothed inion 16 accommodated in the recess 7. ounted upon .the outer end of Vthe spindle 15 is a suitable control lever 17.
Engaging the toothed pinion 16 are collars 18 carried by the lower closed end 19 of a delivery tube 20 having an open upper end. Formed in the tube 20 are inlet holes or apertures 21 communicating with a vertical passageway 22.
Mounted upon and secured by screws or the like to the base element 6 is the bottom 23 of a generating and feed chamber 24. The bottom 23 is provided with a jointing recess 25 having therein a jointing ring 26 and accommodating the jointin shoulder 9 of the base element. Formed tiirough the bottom 23, concentrically with the jointing recess 25, is a threaded hole. Secured by screws or the like to oney side of the cham.
ber 24 is a removable access plate 27. Upstanding from the upper end of the chamber 24 is a jointing shoulder 28 around which is a jointing flange 29. Passing through one side of the chamber 24 is an air intake branch 30 having near its outer end an outflow wall 31.
Threaded into the threaded hole formed in the bottom 23 of the chamber 24 is the threaded lower end 32 of a jet tube 33. Carried by the lower end 32 is a nut 34 accommodated in the` recess 8-of the base element 6. Formed between the jet tube 33 and the delivery tube 2O is an annular fuel space indicated at 35.
Slidably embracing the tube 33 is a distributing tube or sleeve 36 having a closed upper end 37. Carried by the upper end 37 is a regulating needle valve having a head 38 provided with a lateral groove 39. Below the head 38 is a body portion 40 threaded into the closed upper end 37 of the tube 36. Integral with the body portion 40 is a shank or modulating pin 41. This descends into the open upper end of the delivery tube 20. Formed in the upper end of the distributing tube 36 is a plurality of exi-t slots 42. Carried by the lower end of the tube or sleeve 36 is a pair of collars 43.
Engaging the collars 43 are opposite pins 44. Each pin is carried by the inner end of a lever 45 the outer end of which is preferably formed integral with the lower end of an inclined shutter 46l Carried bythe lower end of each shutter 46 is a pivot pin 47 extendinglaterally across and mounted in the feed chamber 24. The upper end of each shutter 46 is provided with a gullet 48 whereby the pair of shutters embrace the upper end of the distributing tube or sleeve 36. Carried by each shutter 46 is a stud 49. Encircling each stud 49 is the inner end of an adjustable helical spring 50. The outer end of each spring 50 is controlled by an adjusting screw 51 carried by the feed chamber 24. The two shutters 46 control the passage of an atmospheric stream induced through the chamber 24 from the intake branch 30 by t-he suction of the engine. The shutters vibrate or oscillate according to the running of the engine and' by their inclination direct the atmospheric current towards the exit slots 42 past which it travels at intensified velocity.
Secured by screws or the like to the {iange 29 of the feed chamber 24 is 'the flange 52 of an atomizing and as expansion chamber. The bottom of t. e gas chamber is provided with a jointing recess 53 accommodating the jointing'shoulder 28 of the feed chamber 24. Above the flange 52 is a delivery neck 54 integral with which is an outwardly inclined or flared wall 55 having ated in the neck 54 of at its upper end an internal circumferential Shoulder 56 above which is an internal thread 57.
Disposed within the atomizing and gas expansion chamber is a lower perforated partition 58 above which is an intermediate perforated partition or partitions 59. Above the intermediate partitions 59 and resting upon the internal shoulder 56 is an upper perforated partition 60. It will be observed (Figure 3) that the perforations 158 in the lower partitions 58 are of larger area than the perforations 159 in the intermediate partitions 59. The perforations are smaller in each successive partition until, in the upper parti-tion 60, the perforations 160 have reached the smallest area. The perforations are disposed in staggered relationship thereby preventing any particle of hydro-carbon having a clear passage from the delivery neck 54 to the upper partition 60. Uniting the perforated partitions is a tie bolt 6l provided with a retention nut 62. Carried by the tie bolt and disposed between the partitions 58, 59 and 60 and spacing them apart is a pluralit of tubular distance pieces 63. rIhe num r of partitions employed may be varied.
Above the atomizing and gas expansion chamber is a removable cap or dome 64 having around its lower end an external thread indicated at 65. Passing from the cap or dome 64 is a gas outlet branch 66 forming an induction port 67. The gas outlet branch 66 is provided with a Hange by which it is suitably secured to the manifold of the engine. isposed in the branch 66 is a spindle 69 carrying a suitable throttle valve 70 which may, if desired, be situthe gas chamber. Formed by the neck 54 of the gas chamber, between the lower end thereof and the lower perforated parti-tion 58, is a mixing, breaking and stretching compartment 7l. Formed within the gas chamber, between the lower perforated partition 58 and the intermediate perforated partition 59 above it, is a multiplication and expansion compartment 72. A similar compartment is formed between each intermediate perforated partition 59 and the partition 59 or above it as the case may be. Formed within the cap or dome 64, above the upper perforated partition 60, is a mixture delivery compartment 73 communicating with the gas outlet branch 66 and controlled by the throttle valve 70.
ln the modification shown in Figure 3 the gas expansion chamber may be provided with a jacket or outer shell 74. Communicating with the annular heating space 75 thus formed around the chamber is an inlet pipe 76 and an outlet pipe 77. rlhe inlet pipe receives hot exhaust ases from the exhaust pipe or silencer of t e engine. The
hot gases may be delivered back to the engine exhaust pipe or silencer by the outlet pipe 77. The jacket 74 and heating space 75 provide a simple means for heating the atomizing and gas expansion chamber.
Wit-h this invention gasoline or other fuel is delivered to the float chamber 2 the flow of fuel to and from the chamber being controlled by the float 3 in any ordinary manner. The fuel passes through the duct 4 into the sump 5 and through the inlet holes 2l rising in the delivery tube 20. lt also rises in the annular space 35 inside the jet tube 33. The height attained by the spirit depends upon the level of the float 3 in the float chamber 2 as is usual in carburetters.
To start an engine equipped with the invention the lever 17 is operated causing the pinion 16 to rotate and engage the collars lt of the delivery tube 2O which is lowered in relation to the needle shank 4l. An excess flow of fuel is thus permitted to pass from the tube 2O in order that the engine may lreceive the rich mixture necessary for starting. The carburetter now operates automatically'. An air current or stream is induced by the suction of the engine through the air intake branch 30 and passes upwardly beneath the shutters 46 maintaining them open according to the suction and therefore .the loading of the engine and against the inuence of the helical springs 50. The atmospheric stream is directed by the pair of inclined shutters towards the restricted space formed around and between the upper end of the distributing tube 36 and the upper ends of Ithe shutters. The velocity of the air as it passes the exit slots 42 is therefore increased. The distributing tube or sleeve 36 rises or falls according to the movement of the shutters 46, the air and gasoline or other fuel being automatically proportioned. As the tube 36 rises or falls upon the jet tube 33, and the shutters 46 correspondingly open or close, the slots 42 are opened or are covered by the upper end of the jet tube 33. The quantity of fuel passing through the vertical passageway 22 of the delivery tube 20 may be regulated, according to the size of the engine, by substituting needle valves having Shanks 4l of varying sizes and these Shanks may be tapered. Should the carburetter flood or require to be flooded for any reason the overflow of spirit is retained within the air intake branch 30 by the out-flow Wall 31.
As the vapor from the exit slots 42 is carried upwardly in the air stream induced through the intake branch 30, the particles or globules of hydro-carbon strike forcibly against the lower perforated partition 58. Some of the globules may pass through the perforations in the partition. These will encounter the intermediate partition 59 immediately above the lower partition 58. The perforations in` the partitions are arranged in irregular or staggered relationship for this purpose. When the globules strike a partition each is immediately broken by the force of the impact into a series of globulets. The globulets stretch, on account of them being in contact with the partition and under the influence of suction, and elongation continues whilst each globulet is searching for an aperture in the partition through which it may| pass. When an elongated globulet passes through an aperture in a partition it is, on account of the inclination of the Wall 55, carried rapidly forward in an enlarged compartment by the induced air stream. After passing through a partition and entering a larger compartment the distorted globulet assumes an approximate sphere and expands. The original globule has now obviously been reduced to a series of globulets the density of each of which has been reduced first through distortion by elongation and secondly by expansion. A globule sufficiently thinned or reduced will, like a small bubble, eventually burst by frictional contact in the air stream, but, on account of the reduction in the sizes of the a ertures in each succeeding partition and t e staggered relationship of the apertures, any globule that may pass through an aperture in any partition will encounter a succeeding partition and be broken into a mass of globulets each of which is in turn elon ated and expanded and reduced in denslty. Or it will burst in attempting to pass through an aperture. Close observa. tion and experimentation has shown that the process or method or carburetion according to the invention is most eiective as each particle of hydro-carbon is so reduced during its passage through the atomizing and gas expansion chamber that, when the delivery compartment 73 is reached, it has become completely absorbed by the air stream. A dry homogeneous mixture is thereby obtained and passes in this condition to the induction port 67.
Having now described my invention what I claim as new and desire to secure by Letters Patent is 1. A method of carburetion which consists in subjecting the globules of a hydrocarbon vapor wl'ulst suspended in an atmospheric stream and under the iniiuence of suction to a breaking action by forcible impact, to elongation by frictional retardation, and to enlargement by natural expansion in a series of inter-communicating compartments of progressively increased area, until the hydro-carbon particles are so reduced in density as to be absorbedby the atmospheric stream., and delivering the dry homogeneous mixture obtained into a compartment of still greater area in direct communication with the source of suction. .y
2. A method of carburetion which consists in projecting into a compartment a hydrocarbon vapor suspended in an air stream induced by suction, and subjecting the par.- ticles of hydro-carbon to a breaking action by forcible impact, an elongating action by friction and an enlarging action by expansion, multiplying the breaking, elongating and enlarging actions by delivering l the gases through a series of inter-communicating compartments of progressively increas- -ing area, andvsubjectin the gases to heat during the treatment, Wereby a dry homogeneous mixture is obtained.
8. In a carburetter, an atomizing and gas expansion chamber divided into a plurality of inter-communicating compartments each successively of increased transverse dimension while of uniform vertical dimension by a series of superimposed or spaced perforated partitions,.the perforations of apertures of said partitions gradually reducing in area from one end of said chamber to the other, for the purpose specied.
4. In a carburetter, an atomizing and gas expansion chamber having therein a plurality of super-imposed perforated partitions, the area of each partition being eater than that of the partition preceding 1t whilst the apertures in each partition are of less area than those formed in the partition preceding it and are staggered in relation thereto.
5. In a carburetter, a'n atomizing and gas expansion chamber consistin in an outwardly inclined or ared wal a removable cap or dome carried by the chamber above the wall, a gas outlet branch communicating with the cap or dome, and a plurality of super-imposed perforated partitions disposed within the chamber and forming therein a series of super-imposed compartments inter-communicating with each other through the apertures in the partitions, the area of each partition being 'greater than the area of that precedi it and the perforations in each partition eing of less area than those in the partition preceding it and being staggered in relation thereto.
In testimony whereof I aiiix my signature.
` JAMES CARLILE WHITEMAN.
Witness:
Gnou. MoCLAs'rNER.
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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2600733A (en) * 1950-12-06 1952-06-17 Standard Oil Co Gas mixing apparatus
US2704659A (en) * 1955-03-22 fuchs
US3069146A (en) * 1960-08-30 1962-12-18 Soroban Engineering Inc Variable venturi carburetor
US3342462A (en) * 1966-02-23 1967-09-19 Gen Motors Corp Fuel system
US3752451A (en) * 1972-01-21 1973-08-14 Pollution Control Ind Inc Fuel metering device for internal combustion engine
US4283355A (en) * 1979-09-24 1981-08-11 Pollution Controls Industries, Inc. Carburetor

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2704659A (en) * 1955-03-22 fuchs
US2600733A (en) * 1950-12-06 1952-06-17 Standard Oil Co Gas mixing apparatus
US3069146A (en) * 1960-08-30 1962-12-18 Soroban Engineering Inc Variable venturi carburetor
US3342462A (en) * 1966-02-23 1967-09-19 Gen Motors Corp Fuel system
US3752451A (en) * 1972-01-21 1973-08-14 Pollution Control Ind Inc Fuel metering device for internal combustion engine
US4283355A (en) * 1979-09-24 1981-08-11 Pollution Controls Industries, Inc. Carburetor

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