US3469442A - Apparatus for calibrating carburetors - Google Patents

Apparatus for calibrating carburetors Download PDF

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US3469442A
US3469442A US629790A US3469442DA US3469442A US 3469442 A US3469442 A US 3469442A US 629790 A US629790 A US 629790A US 3469442D A US3469442D A US 3469442DA US 3469442 A US3469442 A US 3469442A
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carburetor
fuel
flow
sonic
charge forming
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US629790A
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Alexander W Brueckner
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Ametek Inc
Lynch Corp
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Lynch Corp
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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
    • F02M19/00Details, component parts, or accessories of carburettors, not provided for in, or of interest apart from, the apparatus of groups F02M1/00 - F02M17/00
    • F02M19/01Apparatus for testing, tuning, or synchronising carburettors, e.g. carburettor glow stands

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  • the apparatus is comprised of a stand for supporting the charge forming device, an apparatus for manipulating the charge forming device throttle valve, a fuel delivery and flow measuring unit, a vacuum pump or other structure for inducing an air flow through the charge forming device and a plurality of sonic nozzles and control valves therefor interposed in the flow path between the charge forming device and the vacuum pump.
  • the operation of each of the aforenoted elements is controlled by a master control unit.
  • this master control unit sequentially selects a flow path through one or more of the sonic nozzles, operates the throttle valve positioningrapparatus to maintain sufficient upstream pressure upon the selected nozzle or nozzles to generate a sonic velocity at its throat whereby a finite mass flow rate is established through the charge forming device and senses a reading from the fuel flow measuring unit at this mass flow rate.
  • the master control selects anothermass flow rate by switching the flow through a different sonic nozzle or nozzles and the fuel flow measuring unit measures the fuel flow at this new mass flow rate.
  • the charge forming device is accurately calibrated at a plurality of points, the number of which depends upon the number of test points desired.
  • This invention relates to a method and apparatus for calibrating charge forming devices.
  • a charge forming device such as a carburetor for an internal combustion engine
  • the actual rate of discharge at any point on the carburetors flow curve is a compromise between a lean economy mixture and a richer mixture that assures adequate power reserve.
  • a common test method employs a device known as a flow box in which air is passed through the carburetor induction passage and fuel or a satisfactory equivalent therefor is fed to the carburetor for discharge into the induction passage through the carburetor fuel circuits.
  • a predetermined pressure differential is established across the carburetor at a given throttle setting and the fuel flow is measured and adjusted. If the fuel flow can be adjusted within a predetermined'range, the carburetor is considered to be satisfactory.
  • This test method is not completely satisfactory since the actual mass flow rate through the carburetor will vary from carburetor-to-carburetor even though a given pressure differential is accurately maintained.
  • the recent emphasis upon the reduction of the emission of smog producing constituents from the engine exhaust has necessitated a narrower range of variation in the discharge rate of the carburetor as well as a somewhat leaner overall mixture.
  • the method embodying this invention is particularly adapted for calibrating a charge forming device having an induction passage, a throttle valve for controlling the flow through the induction passage and a fuel discharge circuit for discharging fuel into the induction passage.
  • the fuel discharge circuit also includes at least one adjustable flow device for regulating the rate of fuel discharge.
  • the method comprises the steps of establishing a pressure differential across the inlet and outlet ends of the induction passage for inducing a flow therethrough.
  • the induced fiow is passed through a sonic flow device that has an area wherein the flow is accelerated to the sonic velocity at a predetermined pressure differential.
  • This sonic flow device has the characteristic that the velocity at the area does not exceed the sonic velocity at pressure differentials greater than the aforenoted predetermined pressure differential.
  • the mass flow rate will be directly proportional to the upstream pressure.
  • the throttle valve of the charge forming device is positioned to establish a pressure on one side of the sonic flow device suflicient to attain the sonic velocity and to generate a predetermined mass flow rate through the induction passage of the charge forming device. The discharge rate of the fuel discharge circuit is then measured at this predetermined mass flow rate.
  • An apparatus for performing the aforenoted method is comprised of a vacuum pump for creating the pressure differential and a sonic flow nozzle positioned in a conduit leading from the carburetor to the vacuum pump. Means are provided for measuring the fuel discharge of the carburetor and for adjusting the fuel discharge rate if the fuel discharge varies from within a predetermined range.
  • FIGURE 1 is a partially schematic illustration of a calibration apparatus for a charge forming device, which apparatus embodies this invention.
  • FIGURE 2 is an enlarged cross sectional view of the area encompassed by the circle 2 in FIGURE 1.
  • the reference numeral 11 indicates generally a carburetor or other charge forming device adapted to be calibrated or adjusted by the apparatus and method embodying this invention.
  • the carburetor 11 which may be of any known type, includes an induction passage defined in part by an air horn or inlet 12 and an air outlet flange 13 in which a throttle valve 14 is supported.
  • the carburetor 11 includes conventional fuel discharge circuits and preferably embodies flow adjusting devices for adjusting the fuel flow at idle, ofl idle and full throttle operation.
  • adjusting devices may be needle valves that cooperate with the carbur'etor' fuel discharge passages for regulating the fuel flow, air bleed controls or any other known type of fuel adjusting devices.
  • Fuel is supplied to the various discharge circuits from a float bowl into which fuel is introduced by a fuel inlet fitting 16 in a known manner.
  • the testing apparatus comprises a test stand base 17 defining a cavity 18 in which the mounting flange 13 of the carburetor 11 is adapted to be supported and fixed by a suitable automatic clamping means (not shown).
  • the automatic clamping means maybe of any known type such as one which includes pneumatically operated clamps for fixing the carburetor flange 13 to the stand base 17.
  • locating means are also incorporated either with the clamping means or upon the base 17 for accurately orienting the carburetor 11 with respect to the base 17.
  • the test stand base 17 is formed with an air passage 19 that is adapted to register with th outlet side of the carburetor induction passage and particularly with the portion adjacent the outlet flange 13 when the carburetor is clamped thereupon.
  • a conduit 21 extends from the passage 19 terminates in a plurality of branch conduits 22, 23 and 24.
  • Sonic nozzles 25, 26 and 27 are interposed in the passages 22, 23 and 24, respectively, upstream of solenoid operated valves 31, 32 and 33. Downstream of the valves 31, 32 and 33 the passages 22, 23 and 24 merge in a common passage 34 that extends to a vacuum pump 35.
  • a throttle valve control unit 36 is supported on the mounting portion 17 and has an operating member 37 that is adapted to be automatically connected to the throttle linkage of the carburetor 11 for operating the throttle valve 14.
  • the throttle valve control unit 36 may comprise any form of hydraulic, pneumatic or electrical servo unit that is operative to maintain an accurate position of the operating member 37 and throttle valve 14 in response to a given signal.
  • the end of the operating member 37 adjacent the throttle valve linkage may be provided with any known form of automatic clamping device to effect an automatic connection to the throttle valve linkage.
  • a fuel control circuit including a fuel feed and flow measuring device 38 delivers fuel to the carburetor 11 by means of a fuel conduit 39 that is connected to the fuel inlet fitting 16.
  • the device 38 may be of any known type and preferably incorporates a flow meter that will accurately measure extremely small liquid flows and which may be of any known type.
  • any known form of automatic clamping device is provided for automatically coupling the conduit 39 to the carburetor fuel inlet fitting 16.
  • a fuel discharge adjusting device 41 is provided with one or more adjusting arms 42 that are adapted to coact with the fuel flow adjusting devices of the carburetor 11, there preferably being one such adjusting arm 42 for each fuel adjustment of the carburetor 11.
  • the adjusting device 41 may be of any known type and preferably includes a structure such as a hydraulic or pneumatic solenoid for moving the adjusting arm 42 into registry with the respective fuel flow adjusting device of the carburetor 11. If the fuel flow adjusting device is a conventional needle valve, a screw driver like tool may be supported at the outer end of the adjusting arm 42 for registry with the slotted end of the needle valve.
  • the adjusting device 41 may include a form of stepping solenoid for incrementally locating the adjusting arm 42 if a needle valve is employed.
  • the solenoid valves 31, 32, 33, the vacuum pump 35, the throttle adjusting servo 36, the fuel feed and flow measuring device 38 and the fuel discharge adjusting devices 41 are each connected in circuit to a computer or other master control device, indicated generally by the reference numeral 43, as will become more apparent as this description proceeds.
  • FIGURE 2 is a cross sectional view of the sonic nozzle 25 which is comprised of a convergent section 45, a minimum area throat 46 and a divergent section 47.
  • any increase in pressure on the upstream side of the nozzle 25 will not causean increase in th throat velocity.
  • the mass flow rate through the nozzle 25 will be directly related to the upstream pressure.
  • the use of the sonic nozzle 25, therefore, permits the mass flow rate through the carburetor induction passage to be accurately determined at a given downstream pressure so long as this pressure is suflicient to maintain sonic velocity through the nozzle 25..
  • the use of the sonic nozzles has the further advantage that they will not permit pulsations of the vacuum pump 35 to be transmitted back to the carburetor induction passage.
  • sonic nozzles By employing a plurality of such sonic nozzles in parallel flow circuit with the carburetor 11, it is possible to accurately control the mass flow rate through the carburetor, depending upon which of the sonic nozzles is interposed in the flow path through the carburetor induction passage.
  • One sonic nozzle may be employed for each point at which the carburetor 11 is to be tested or, alternatively, a number of such nozzles may be used in parallel flow circuits. This latter embodiment permits a greater number of test points with a given number of sonic nozzles. Since the mass flow rate is accurately de termined, the exact fuel-air ratio discharged by the carburetor may be accurately measured by the device 38 which measures the fuel flow through the carburetor 11. Appropriate adjustment of the fuel discharge circuit being tested under these conditions will permit accurate control of the fuel discharge of the carburetor.
  • a liquid to simulate the fuel flow other than gasoline.
  • the high volatility of gasoline fuels might, in some instances, cause false readings due to vaporization within the sonic nozzles.
  • Any well known test fluid may be used for this purpose.
  • the same fluid will be used to calibrate the production carburetor as that used during the recording of the flow data of the master carburetor.
  • the control device 43 actuates the vacuum pump 35 by means of a control circuit, indicated schematically by the reference numeral 51.
  • the vacuum pump 35 will create a pressure differential across the carburetor 11 from its air horn 12 to its discharge flange 13 that is preferably greater than the pressure differential at the extreme range to be tested.
  • the first carburetor circuit to be tested normally the idle circuit, is operated by closing the solenoid valves 32 and 33 and opening the solenoid valve 31 through schematically indicated circuits interconnecting the respective solenoid valves to the control device 43. The flow through the carburetor 11 will then pass from the conduit 21 through the branch passage 22 and sonic nozzle 25 to the vacuum pump 35.
  • a pressure indicating device 52 is connected to the conduit 21 upstream of the branch passages 22, 23 and 24 by means of a conduit 53.
  • the pressure indicating device 52 is in circuit with the control device 43 as shown schematically at 54. If desired, a similar pressure connection may extend from the conduit 34 to the control device 43 to measure the pressure differential across the respective sonic nozzles. Such a connection may not be. required if the output of the vacuum pump 35 is constant since in that case the device 52 will reflect the pressure differential.
  • the throttle valve controlling servo 36 and its actuating member 37 perform no function and the throttle valve 14 remains in its normal idle position. This should establish a predetermined pressure upon the pressure sensing device 52 which is indicative of the pressure differential across the sonic nozzle 25.
  • the sonic nozzle 25 is designed so that this pressure differential exceeds the predetermined critical pressure at which the flow through its throat exceeds the sonic velocity of the fluid flowing. If the critical pressure differential is not attained, the idle position of the carburetor throttle valve 14 may be appropriately adjusted.
  • the fuel flow meter 38 sends a signal to the control device 43 by means of an interconnecting circuit indicated schematically by the reference numeral 55. This condition is thus recorded by the control device 43.
  • the control device 43 then closes the solenoid valve 31 and opens the solenoid valve 32 through the respective circuits.
  • the flow from the carburetor 11 will then pass through the sonic nozzle 26 which like the sonic nozzle 25 is designed to experience sonic flow at its throat at a predetermined pressure differential, which is established by the pressure differential corresponding to that attained when the throttle valve 14 is at its normal off-idle position.
  • the throttle valve 14 is then automatically moved to this position by means of the servo device 36 which is connected in circuit to the control device 43 as shown schematically at 56.
  • the pressure sensing device 52 returns a signal to the control device 43 to indicate when this throttle opening has been reached.
  • the fuel flow meter 38 returns a signal to the control device 43 via circuit 55, thus indicating the fuel flow of the master carburetor at the off-idle position.
  • the control device 43 then closes the solenoid valve 32 and opens the solenoid valve 33 through the appropriate circuits so that the flow through the carburetor 11 subsequently passes through the sonic nozzle 27.
  • the sonic nozzle 27 is designed so that the sonic velocity will be reached at a critical pressure differential equivalent to that generated by opening the throttle valve 14 to its wide open position.
  • the control device 43 then actuates the throttle actuating servo 36 through circuit 56 to move the throttle valve 14 to its wide open position. When this position is reached and after the fuel flow is stabilized, the fuel flow meter 38 returns the signal for recording to the control device 43.
  • the control device 43 now contains the accurate information of the fuel flow of the master carburetor at idle, off-idle and full throttle positions.
  • the master carburetor is released from the test apparatus either automatically or manually. Each carburetor coming off of the production line of the type corresponding to the master then may be positioned upon the test stand 17.
  • the control device 43 automatically actuates the clamping mechanism, fuel adjustment mechanisms 41, fuel feed and measuring device 39 and the throttle valve actuating servo 36 in the manner previously described.
  • the fuel feed device and flow measuring device 28 delivers the same liquid to the carburetor 11 as was used in conjunction with the recordal of the data from the master carburetor. Visual tests for fuel leakage may then be made and any fluid leakage from the carburetor 11 will enter the cavity 18 for return to its source.
  • the test procedure is initiated by the control device 43.
  • the solenoid valve 31 is first opened with the solenoid valves 32, 33- being closed and the vacuum pump 35 is started in operation.
  • the throttle valve 14 is held in its normal idle position and assuming the desired pressure signal is indicated by the pressure sensing device 52, the first fuel test will be initiated.
  • the fuel flow measuring device 38 sends a signal to the control device 43 by the circuit 56 indicating accurately the amount of fuel flowing through the idle fuel discharge circuit of the charge forming device 11. If the stablized fuel flow is within a predetermined range of that of the master carburetor, the control circuit 43 will pass to the next test.
  • the fuel adjustment device 41 which is in circuit with the control 43, as indicated schematically by the reference numeral 61, will be actuated. A single increment adjustment in the idle fuel discharge is made and flow continues to pass through the sonic nozzle 27. After the flow again stabilizes, the fuel flow measuring device 38 will return a signal to the control device 43 by the circuit 55. If the desired fuel flow is now present, the control device 43 will pass to the next test. If not, a further adjustment will be made by the fuel adjusting device 41. If sufficient adjustment cannot be made by the device 41 to bring the carburetor 11 into specification, it will be rejected. Assuming that the adjustment can be made, the device will pass to the next fuel test and so on in the manner previously described.
  • the vacuum pump 35 and sonic nozzles 25, 26 and 27 are positioned downstream of the charge forming device 11. It should be readily apparent that other arrangements are possible so long as a pressure differential is obtained across the carburetor 11 and that each of the sonic nozzles experiences the amount of mass air flow through the carburetor induction passage. The depicted relationship is preferred, however, since it most closely approximates the actual conditions to which the carburetor is exposed.
  • any type of flow devices such as orifice plates, may be employed so long as they have the characteristic that a sonic velocity is attained at a predetermined pressure differential and this velocity is not exceeded at higher pressure differentials.
  • variable area orifice or flow nozzle may be provided that will have sonic characteristics at each of the predetermined points.
  • the characteristics of these sonic flow devices will permit accurate measurement of the mass flow rate even though there may be some variations in the pressure differential generated by the vacuum pump. Any pulsations generated by the vacuum pump 35 will not be transmitted back to the induction passage of the carburetor 11 due to the interpositioning of the sonic nozzles between the vacuum pump 35 and the carburetor 11.
  • the specific sequence of test points may be varied without departing from the invention.
  • the control device 43 may control a number of different test stands and the information regarding the performance of the master carburetor may be recorded on any type of memory unit for subsequent use.
  • a test apparatus for calibrating a charge forming device having an induction passage, a throttle valve for controlling the flow through the induction passage and a fuel discharge circuit for discharging fuel into the induction passage, said test apparatus being effective to calibrate the charge forming device by measuring the airfuel ratio discharged from the induction passage and including at least one adjustable means for regulating the amount of discharge of the fuel discharge circuit, said apparatus comprising a base adapted to support a charge forming device, air conduit means adapted to register with the induction passage of the supported charge forming device, means for creating a pressure differential in said air conduit means for inducing flow through the charge forming device induction passage, said air conduit means having a plurality of branch passages defining parallel flow paths, valve means for selectively controlling the air flow through said branch passages, a sonic flow device interposed in each of said branch passages downstream of the charge forming device induction passage, each of said sonic flow devices having an area wherein the flow velocity at said area is equal to the sonic velocity of the fluid flowing therethrough at
  • test apparatus as set forth in claim 1 wherein the base forms a portion of the air conduit means and is in registry with the outlet end of the charge forming device induction passage, the means for creating the pressure differential in said air conduit means comprising a vacuum pump positioned downstream of the branch passages.
  • a test apparatus as set forth in claim 1 further including means for adjusting the adjustable fuel discharge means of the charge forming device when the means for measuring the fuel flow indicates a deviation from a predetermined range.
  • a test apparatus as set forth in claim 1 further including throttle valve actuating means for positioning the throttle valve of the supported charge forming device and means for coordinating the operation of the selected valve means and said throttle valve actuating means for positioning the charge forming device throttle valve to maintain a pressure upon one side of the respective sonic flow device sufiicient to establish sonic flow therethrough.
  • a test apparatus as set forth in claim 4 further including means for adjusting the adjustable fuel discharge means of the charge forming device when the means for measuring the fuel flow indicates a deviation from a predetermined range.

Description

- Sept; 30, 1969 A. w. BRUECKNER 3,469,442
APPARATUS FOR CALIBRATING CARBURETORS Filed April 10. 1967 INVENTOR.
-- zxmmr 1115 2210670 United States Patent O 3,469,442 APPARATUS FOR CALIBRATING 'CARBURETORS Alexander W. Brueckner, Farmington, Mich., assignor to Lynch Corporation, a corporation of Indiana Filed Apr. 10, 1967, Ser. No. 629,790 Int. Cl. G01m 13/02 US. Cl. 73118 5 Claims ABSTRACT OF THE DISCLOSURE This application discloses a method and apparatus for accurately calibrating and adjusting charge forming devices for internal combustion engines. The apparatus is comprised of a stand for supporting the charge forming device, an apparatus for manipulating the charge forming device throttle valve, a fuel delivery and flow measuring unit, a vacuum pump or other structure for inducing an air flow through the charge forming device and a plurality of sonic nozzles and control valves therefor interposed in the flow path between the charge forming device and the vacuum pump. The operation of each of the aforenoted elements is controlled by a master control unit. In operation, this master control unit sequentially selects a flow path through one or more of the sonic nozzles, operates the throttle valve positioningrapparatus to maintain sufficient upstream pressure upon the selected nozzle or nozzles to generate a sonic velocity at its throat whereby a finite mass flow rate is established through the charge forming device and senses a reading from the fuel flow measuring unit at this mass flow rate. After accom plishing the aforenoted test at a given mass flow rate, the master control selects anothermass flow rate by switching the flow through a different sonic nozzle or nozzles and the fuel flow measuring unit measures the fuel flow at this new mass flow rate. Thus, the charge forming device is accurately calibrated at a plurality of points, the number of which depends upon the number of test points desired.
BACKGROUND OF THE INVENTION This invention relates to a method and apparatus for calibrating charge forming devices.
As is well known, the function of a charge forming device such as a carburetor for an internal combustion engine is to deliver an accurate fuel-air mixture throughout the power and speed range ofthe associated engine. The actual rate of discharge at any point on the carburetors flow curve is a compromise between a lean economy mixture and a richer mixture that assures adequate power reserve. In order to insure that a production carburetor will give satisfactory performance, it is conventionalpractice to test all of the carburetors produced. A common test method employs a device known as a flow box in which air is passed through the carburetor induction passage and fuel or a satisfactory equivalent therefor is fed to the carburetor for discharge into the induction passage through the carburetor fuel circuits. A predetermined pressure differential is established across the carburetor at a given throttle setting and the fuel flow is measured and adjusted. If the fuel flow can be adjusted within a predetermined'range, the carburetor is considered to be satisfactory. This test method is not completely satisfactory since the actual mass flow rate through the carburetor will vary from carburetor-to-carburetor even though a given pressure differential is accurately maintained. In addition, the recent emphasis upon the reduction of the emission of smog producing constituents from the engine exhaust has necessitated a narrower range of variation in the discharge rate of the carburetor as well as a somewhat leaner overall mixture. Also, it is preferable if not imperative that all carburetors 3,469,442 Patented Sept. 30, 1969 from the production line be tested. Previous test methods and apparatus have not lent themselves to testing. The calibration of all production carburetors eliminates or substantially reduces the necessity for subsequent adjustment when the carburetor is assembled onto its associated engine.
It is, therefore, a principal object of this invention to provide an improved method and apparatus for calibrating charge forming devices.
It is another object of this invention to provide an automatic device for calibrating carburetors over a wide range and at a plurality of different points.
It is a further object of this invention to provide a method and apparatus for calibrating charge forming devices that accomplishes a more accurate adjustment.
SUMMARY OF THE INVENTION The method embodying this invention is particularly adapted for calibrating a charge forming device having an induction passage, a throttle valve for controlling the flow through the induction passage and a fuel discharge circuit for discharging fuel into the induction passage. The fuel discharge circuit also includes at least one adjustable flow device for regulating the rate of fuel discharge. The method comprises the steps of establishing a pressure differential across the inlet and outlet ends of the induction passage for inducing a flow therethrough. The induced fiow is passed through a sonic flow device that has an area wherein the flow is accelerated to the sonic velocity at a predetermined pressure differential. This sonic flow device has the characteristic that the velocity at the area does not exceed the sonic velocity at pressure differentials greater than the aforenoted predetermined pressure differential. In addition, once sonic flow is established through the device, the mass flow rate will be directly proportional to the upstream pressure. The throttle valve of the charge forming device is positioned to establish a pressure on one side of the sonic flow device suflicient to attain the sonic velocity and to generate a predetermined mass flow rate through the induction passage of the charge forming device. The discharge rate of the fuel discharge circuit is then measured at this predetermined mass flow rate.
An apparatus for performing the aforenoted method is comprised of a vacuum pump for creating the pressure differential and a sonic flow nozzle positioned in a conduit leading from the carburetor to the vacuum pump. Means are provided for measuring the fuel discharge of the carburetor and for adjusting the fuel discharge rate if the fuel discharge varies from within a predetermined range.
BRIEF DESCRIPTION OF THE DRAWINGS FIGURE 1 is a partially schematic illustration of a calibration apparatus for a charge forming device, which apparatus embodies this invention.
FIGURE 2 is an enlarged cross sectional view of the area encompassed by the circle 2 in FIGURE 1.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT OF THE INVENTION In th drawings the reference numeral 11 indicates generally a carburetor or other charge forming device adapted to be calibrated or adjusted by the apparatus and method embodying this invention. The carburetor 11, which may be of any known type, includes an induction passage defined in part by an air horn or inlet 12 and an air outlet flange 13 in which a throttle valve 14 is supported. In addition, the carburetor 11 includes conventional fuel discharge circuits and preferably embodies flow adjusting devices for adjusting the fuel flow at idle, ofl idle and full throttle operation. These adjusting devices may be needle valves that cooperate with the carbur'etor' fuel discharge passages for regulating the fuel flow, air bleed controls or any other known type of fuel adjusting devices. Fuel is supplied to the various discharge circuits from a float bowl into which fuel is introduced by a fuel inlet fitting 16 in a known manner.
The testing apparatus comprises a test stand base 17 defining a cavity 18 in which the mounting flange 13 of the carburetor 11 is adapted to be supported and fixed by a suitable automatic clamping means (not shown). The automatic clamping means maybe of any known type such as one which includes pneumatically operated clamps for fixing the carburetor flange 13 to the stand base 17. Preferably, locating means are also incorporated either with the clamping means or upon the base 17 for accurately orienting the carburetor 11 with respect to the base 17. The test stand base 17 is formed with an air passage 19 that is adapted to register with th outlet side of the carburetor induction passage and particularly with the portion adjacent the outlet flange 13 when the carburetor is clamped thereupon.
A conduit 21 extends from the passage 19 terminates in a plurality of branch conduits 22, 23 and 24. Sonic nozzles 25, 26 and 27 are interposed in the passages 22, 23 and 24, respectively, upstream of solenoid operated valves 31, 32 and 33. Downstream of the valves 31, 32 and 33 the passages 22, 23 and 24 merge in a common passage 34 that extends to a vacuum pump 35.
A throttle valve control unit 36 is supported on the mounting portion 17 and has an operating member 37 that is adapted to be automatically connected to the throttle linkage of the carburetor 11 for operating the throttle valve 14. The throttle valve control unit 36 may comprise any form of hydraulic, pneumatic or electrical servo unit that is operative to maintain an accurate position of the operating member 37 and throttle valve 14 in response to a given signal. The end of the operating member 37 adjacent the throttle valve linkage may be provided with any known form of automatic clamping device to effect an automatic connection to the throttle valve linkage.
A fuel control circuit including a fuel feed and flow measuring device 38 delivers fuel to the carburetor 11 by means of a fuel conduit 39 that is connected to the fuel inlet fitting 16. The device 38 may be of any known type and preferably incorporates a flow meter that will accurately measure extremely small liquid flows and which may be of any known type. In addition, any known form of automatic clamping device is provided for automatically coupling the conduit 39 to the carburetor fuel inlet fitting 16.
A fuel discharge adjusting device 41 is provided with one or more adjusting arms 42 that are adapted to coact with the fuel flow adjusting devices of the carburetor 11, there preferably being one such adjusting arm 42 for each fuel adjustment of the carburetor 11. The adjusting device 41 may be of any known type and preferably includes a structure such as a hydraulic or pneumatic solenoid for moving the adjusting arm 42 into registry with the respective fuel flow adjusting device of the carburetor 11. If the fuel flow adjusting device is a conventional needle valve, a screw driver like tool may be supported at the outer end of the adjusting arm 42 for registry with the slotted end of the needle valve. The adjusting device 41 may include a form of stepping solenoid for incrementally locating the adjusting arm 42 if a needle valve is employed.
The solenoid valves 31, 32, 33, the vacuum pump 35, the throttle adjusting servo 36, the fuel feed and flow measuring device 38 and the fuel discharge adjusting devices 41 are each connected in circuit to a computer or other master control device, indicated generally by the reference numeral 43, as will become more apparent as this description proceeds.
7 4 OPERATION Before discussing specifically the detailed operation of the disclosed apparatus and method, a discussion of its principle of operation appears to be in order. An important feature of the invention is the use of the sonic nozzles 25, 26 and 27 for accurately establishing predetermined mass flow rates through the tested carburetor. FIGURE 2 is a cross sectional view of the sonic nozzle 25 which is comprised of a convergent section 45, a minimum area throat 46 and a divergent section 47. As is well known, at a critical pressure differential across the nozzle 25, the fluid flowing through the nozzle will be accelerated to its sonic velocity at the throat 46. Pressure differentials greater than this critical pressure differential will not increase the velocity at the throat 46. Once the sonic velocity is obtained at the throat 46, any increase in pressure on the upstream side of the nozzle 25 will not causean increase in th throat velocity. In addition, the mass flow rate through the nozzle 25 will be directly related to the upstream pressure. The use of the sonic nozzle 25, therefore, permits the mass flow rate through the carburetor induction passage to be accurately determined at a given downstream pressure so long as this pressure is suflicient to maintain sonic velocity through the nozzle 25..The use of the sonic nozzles has the further advantage that they will not permit pulsations of the vacuum pump 35 to be transmitted back to the carburetor induction passage.
By employing a plurality of such sonic nozzles in parallel flow circuit with the carburetor 11, it is possible to accurately control the mass flow rate through the carburetor, depending upon which of the sonic nozzles is interposed in the flow path through the carburetor induction passage. One sonic nozzle may be employed for each point at which the carburetor 11 is to be tested or, alternatively, a number of such nozzles may be used in parallel flow circuits. This latter embodiment permits a greater number of test points with a given number of sonic nozzles. Since the mass flow rate is accurately de termined, the exact fuel-air ratio discharged by the carburetor may be accurately measured by the device 38 which measures the fuel flow through the carburetor 11. Appropriate adjustment of the fuel discharge circuit being tested under these conditions will permit accurate control of the fuel discharge of the carburetor.
Referring now specifically to the operation of the disclosed device, information is fed into the control unit 43 of the test apparatus from a standard, accurately calibrated carburetor that has the desired flow characteristics as determined by dynamometer and other testing. This master carburetor is positioned upon the test apparatus as shown in FIGURE 1 of the drawings. When so positioned, the automatic clamping mechanism (not shown) is actuated to lock the carburetor to the test stand base 17, the fuel conduit 39 is automatically coupled to the carburetor inlet fitting 16 and the throttle valve actuating device 37 is automatically engaged with the throttle lever. The fuel adjusting devices 42 need not be connected to the master carburetor when its flow data is being registered by the control unit 43. Any suitable structure for accomplishing these automatic engagements may be provided depending upon the type of carburetor being tested and various other factors. Alternatively, these connections may be made manually.
When operating the described test apparatus, it is preferable to use a liquid to simulate the fuel flow other than gasoline. The high volatility of gasoline fuels might, in some instances, cause false readings due to vaporization within the sonic nozzles. Any well known test fluid may be used for this purpose. Preferably, the same fluid will be used to calibrate the production carburetor as that used during the recording of the flow data of the master carburetor.
When the master carburetor 11 is in place, the control device 43 actuates the vacuum pump 35 by means of a control circuit, indicated schematically by the reference numeral 51. The vacuum pump 35 will create a pressure differential across the carburetor 11 from its air horn 12 to its discharge flange 13 that is preferably greater than the pressure differential at the extreme range to be tested. The first carburetor circuit to be tested, normally the idle circuit, is operated by closing the solenoid valves 32 and 33 and opening the solenoid valve 31 through schematically indicated circuits interconnecting the respective solenoid valves to the control device 43. The flow through the carburetor 11 will then pass from the conduit 21 through the branch passage 22 and sonic nozzle 25 to the vacuum pump 35. A pressure indicating device 52 is connected to the conduit 21 upstream of the branch passages 22, 23 and 24 by means of a conduit 53. The pressure indicating device 52 is in circuit with the control device 43 as shown schematically at 54. If desired, a similar pressure connection may extend from the conduit 34 to the control device 43 to measure the pressure differential across the respective sonic nozzles. Such a connection may not be. required if the output of the vacuum pump 35 is constant since in that case the device 52 will reflect the pressure differential.
During the idle test, the throttle valve controlling servo 36 and its actuating member 37 perform no function and the throttle valve 14 remains in its normal idle position. This should establish a predetermined pressure upon the pressure sensing device 52 which is indicative of the pressure differential across the sonic nozzle 25. The sonic nozzle 25 is designed so that this pressure differential exceeds the predetermined critical pressure at which the flow through its throat exceeds the sonic velocity of the fluid flowing. If the critical pressure differential is not attained, the idle position of the carburetor throttle valve 14 may be appropriately adjusted. After a predetermined time interval to permit the fuel flow to stabilize, the fuel flow meter 38 sends a signal to the control device 43 by means of an interconnecting circuit indicated schematically by the reference numeral 55. This condition is thus recorded by the control device 43.
The control device 43 then closes the solenoid valve 31 and opens the solenoid valve 32 through the respective circuits. The flow from the carburetor 11 will then pass through the sonic nozzle 26 which like the sonic nozzle 25 is designed to experience sonic flow at its throat at a predetermined pressure differential, which is established by the pressure differential corresponding to that attained when the throttle valve 14 is at its normal off-idle position. The throttle valve 14 is then automatically moved to this position by means of the servo device 36 which is connected in circuit to the control device 43 as shown schematically at 56. The pressure sensing device 52 returns a signal to the control device 43 to indicate when this throttle opening has been reached. After the predetermined time delay necessary to permit fuel flow to stabilize, the fuel flow meter 38 returns a signal to the control device 43 via circuit 55, thus indicating the fuel flow of the master carburetor at the off-idle position.
The control device 43 then closes the solenoid valve 32 and opens the solenoid valve 33 through the appropriate circuits so that the flow through the carburetor 11 subsequently passes through the sonic nozzle 27. The sonic nozzle 27 is designed so that the sonic velocity will be reached at a critical pressure differential equivalent to that generated by opening the throttle valve 14 to its wide open position. The control device 43 then actuates the throttle actuating servo 36 through circuit 56 to move the throttle valve 14 to its wide open position. When this position is reached and after the fuel flow is stabilized, the fuel flow meter 38 returns the signal for recording to the control device 43. The control device 43 now contains the accurate information of the fuel flow of the master carburetor at idle, off-idle and full throttle positions. Although the operation described has assumed the use of a separate sonic nozzle for each calibration point,
it is to be understood that additional tests points may be obtained through the use of groups of nozzles in parallel flow paths or through the use of additional nozzles.
After the data is recorded by the control device 43, the master carburetor is released from the test apparatus either automatically or manually. Each carburetor coming off of the production line of the type corresponding to the master then may be positioned upon the test stand 17. The control device 43 automatically actuates the clamping mechanism, fuel adjustment mechanisms 41, fuel feed and measuring device 39 and the throttle valve actuating servo 36 in the manner previously described. As has been previously noted, the fuel feed device and flow measuring device 28 delivers the same liquid to the carburetor 11 as was used in conjunction with the recordal of the data from the master carburetor. Visual tests for fuel leakage may then be made and any fluid leakage from the carburetor 11 will enter the cavity 18 for return to its source. After the visual leakage test has been made and passed, the test procedure is initiated by the control device 43. The solenoid valve 31 is first opened with the solenoid valves 32, 33- being closed and the vacuum pump 35 is started in operation. The throttle valve 14 is held in its normal idle position and assuming the desired pressure signal is indicated by the pressure sensing device 52, the first fuel test will be initiated. The fuel flow measuring device 38 sends a signal to the control device 43 by the circuit 56 indicating accurately the amount of fuel flowing through the idle fuel discharge circuit of the charge forming device 11. If the stablized fuel flow is within a predetermined range of that of the master carburetor, the control circuit 43 will pass to the next test. If not, the fuel adjustment device 41 which is in circuit with the control 43, as indicated schematically by the reference numeral 61, will be actuated. A single increment adjustment in the idle fuel discharge is made and flow continues to pass through the sonic nozzle 27. After the flow again stabilizes, the fuel flow measuring device 38 will return a signal to the control device 43 by the circuit 55. If the desired fuel flow is now present, the control device 43 will pass to the next test. If not, a further adjustment will be made by the fuel adjusting device 41. If sufficient adjustment cannot be made by the device 41 to bring the carburetor 11 into specification, it will be rejected. Assuming that the adjustment can be made, the device will pass to the next fuel test and so on in the manner previously described.
In the described test apparatus, the vacuum pump 35 and sonic nozzles 25, 26 and 27 are positioned downstream of the charge forming device 11. It should be readily apparent that other arrangements are possible so long as a pressure differential is obtained across the carburetor 11 and that each of the sonic nozzles experiences the amount of mass air flow through the carburetor induction passage. The depicted relationship is preferred, however, since it most closely approximates the actual conditions to which the carburetor is exposed. In addition, although nozzles have been illustrated, any type of flow devices such as orifice plates, may be employed so long as they have the characteristic that a sonic velocity is attained at a predetermined pressure differential and this velocity is not exceeded at higher pressure differentials. Alternatively, a variable area orifice or flow nozzle may be provided that will have sonic characteristics at each of the predetermined points. The characteristics of these sonic flow devices will permit accurate measurement of the mass flow rate even though there may be some variations in the pressure differential generated by the vacuum pump. Any pulsations generated by the vacuum pump 35 will not be transmitted back to the induction passage of the carburetor 11 due to the interpositioning of the sonic nozzles between the vacuum pump 35 and the carburetor 11. It is also to be understood that the specific sequence of test points may be varied without departing from the invention. It should also be apparent that the control device 43 may control a number of different test stands and the information regarding the performance of the master carburetor may be recorded on any type of memory unit for subsequent use.
Various other changes and modifications may be made without departing from the spirit and scope of the invention, as defined by the appended claims.
What is claimed is:
1. A test apparatus for calibrating a charge forming device having an induction passage, a throttle valve for controlling the flow through the induction passage and a fuel discharge circuit for discharging fuel into the induction passage, said test apparatus being effective to calibrate the charge forming device by measuring the airfuel ratio discharged from the induction passage and including at least one adjustable means for regulating the amount of discharge of the fuel discharge circuit, said apparatus comprising a base adapted to support a charge forming device, air conduit means adapted to register with the induction passage of the supported charge forming device, means for creating a pressure differential in said air conduit means for inducing flow through the charge forming device induction passage, said air conduit means having a plurality of branch passages defining parallel flow paths, valve means for selectively controlling the air flow through said branch passages, a sonic flow device interposed in each of said branch passages downstream of the charge forming device induction passage, each of said sonic flow devices having an area wherein the flow velocity at said area is equal to the sonic velocity of the fluid flowing therethrough at a respective critical pressure differential and which velocity does not exceed said sonic velocity at a greater pressure differential than said respective critical pressure differential, and means for measuring the fuel flow through the discharge circuit of the charge forming device.
2. A test apparatus as set forth in claim 1 wherein the base forms a portion of the air conduit means and is in registry with the outlet end of the charge forming device induction passage, the means for creating the pressure differential in said air conduit means comprising a vacuum pump positioned downstream of the branch passages.
3. A test apparatus as set forth in claim 1 further including means for adjusting the adjustable fuel discharge means of the charge forming device when the means for measuring the fuel flow indicates a deviation from a predetermined range. 1
4. A test apparatus as set forth in claim 1 further including throttle valve actuating means for positioning the throttle valve of the supported charge forming device and means for coordinating the operation of the selected valve means and said throttle valve actuating means for positioning the charge forming device throttle valve to maintain a pressure upon one side of the respective sonic flow device sufiicient to establish sonic flow therethrough.
5. A test apparatus as set forth in claim 4 further including means for adjusting the adjustable fuel discharge means of the charge forming device when the means for measuring the fuel flow indicates a deviation from a predetermined range.
References Cited UNITED STATES PATENTS 3,434,341 3/1969 Zaske 73-118 2,755,663 7/1956 Smith et al 73-116 1,103,882 7/1914 Kidder 733 2,597,231 5/1952 Edelen 73-118 2,790,320 4/1957 Salko et al. 73-3 JERRY W. MYRACLE, Primary Examiner US. Cl. X.R. 73-4
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Cited By (20)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3631709A (en) * 1970-04-06 1972-01-04 Neptune Meter Co High-speed calibration of liquid flow meters
US3831440A (en) * 1971-11-22 1974-08-27 F Monnet Apparatus for monitoring carburetors or other gasoline-consumption devices
US4041777A (en) * 1973-03-08 1977-08-16 Karl Weiss - Giessen, Fabrik Elektrophysikalischer Geraete, Werk Lindenstruth Method and apparatus for testing carburetors
US4047426A (en) * 1975-08-01 1977-09-13 Honda Giken Kogyo Kabushiki Kaisha Sonic nozzle apparatus in a carburetor flow testing machine
US4224823A (en) * 1979-02-15 1980-09-30 General Motors Corporation Fuel system flow process
US4269062A (en) * 1979-10-10 1981-05-26 Colt Industries Operating Corp. Method for gauging fluid flow
US4312222A (en) * 1979-07-03 1982-01-26 Volkswagenwerk Aktiengesellschaft Apparatus for testing the volume of fluid medium flowing through variable cross-section throttle
US4645174A (en) * 1985-05-16 1987-02-24 American Meter Company Mounting arrangement for a critical flow device
US4706492A (en) * 1986-06-16 1987-11-17 Chevron Research Company Method and apparatus for determining real gas effects in critical flow nozzles
US4753095A (en) * 1986-06-16 1988-06-28 Chevron Research Company Method for determining real gas effects in critical flow nozzles
US4823591A (en) * 1987-11-05 1989-04-25 Horiba Instruments Incorporated Calibration method for exhaust mass flow measuring system
US5267467A (en) * 1992-07-27 1993-12-07 Ford Motor Company Mass air flow sensor two temperature production line test apparatus
US5299447A (en) * 1992-07-13 1994-04-05 Ford Motor Company Air flow manifold system for providing two different mass air flow rates to a mass air flow sensor production calibration station
US5307667A (en) * 1992-07-13 1994-05-03 Ford Motor Company Response time test apparatus for a mass air flow sensor
US5548990A (en) * 1993-07-15 1996-08-27 Northedge; Ronald Methods and systems for calibrating flow meters
US5808188A (en) * 1996-05-01 1998-09-15 Chriswell; Shawn Darrell Flowbench and air flow measurement and calibration procedure
US6200819B1 (en) 1995-09-29 2001-03-13 Horiba Instruments, Inc. Method and apparatus for providing diluent gas to exhaust emission analyzer
DE19604417C5 (en) * 1996-02-07 2011-06-22 Roppelt, Helmut, 76694 Method and device for determining the concentration of pollutants in exhaust gases, in particular in exhaust gases of motor vehicles
US10794333B2 (en) 2017-08-09 2020-10-06 Weaver Intellectual Property, LLC General aviation carburetor testing and analysis device
US11473532B2 (en) 2017-08-09 2022-10-18 Weaver Intellectual Property, LLC General aviation carburetor testing with turbocharger and analysis device

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US2597231A (en) * 1950-04-19 1952-05-20 Carter Carburetor Corp Carburetor flow testing apparatus
US2755663A (en) * 1953-03-16 1956-07-24 Gen Motors Corp Engine test air supply system
US2790320A (en) * 1954-01-11 1957-04-30 Acf Ind Inc Pneumatic flow-measuring device for fuel jets
US3434341A (en) * 1966-07-28 1969-03-25 Holley Carburetor Co Carburetor test equipment

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US1103882A (en) * 1914-01-03 1914-07-14 John F Kidder Volumetric meter-tester.
US2597231A (en) * 1950-04-19 1952-05-20 Carter Carburetor Corp Carburetor flow testing apparatus
US2755663A (en) * 1953-03-16 1956-07-24 Gen Motors Corp Engine test air supply system
US2790320A (en) * 1954-01-11 1957-04-30 Acf Ind Inc Pneumatic flow-measuring device for fuel jets
US3434341A (en) * 1966-07-28 1969-03-25 Holley Carburetor Co Carburetor test equipment

Cited By (21)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3631709A (en) * 1970-04-06 1972-01-04 Neptune Meter Co High-speed calibration of liquid flow meters
US3831440A (en) * 1971-11-22 1974-08-27 F Monnet Apparatus for monitoring carburetors or other gasoline-consumption devices
US4041777A (en) * 1973-03-08 1977-08-16 Karl Weiss - Giessen, Fabrik Elektrophysikalischer Geraete, Werk Lindenstruth Method and apparatus for testing carburetors
US4047426A (en) * 1975-08-01 1977-09-13 Honda Giken Kogyo Kabushiki Kaisha Sonic nozzle apparatus in a carburetor flow testing machine
US4224823A (en) * 1979-02-15 1980-09-30 General Motors Corporation Fuel system flow process
US4312222A (en) * 1979-07-03 1982-01-26 Volkswagenwerk Aktiengesellschaft Apparatus for testing the volume of fluid medium flowing through variable cross-section throttle
US4269062A (en) * 1979-10-10 1981-05-26 Colt Industries Operating Corp. Method for gauging fluid flow
AU582413B2 (en) * 1985-05-16 1989-03-23 American Meter Company Mounting arrangement for a critical flow device
US4645174A (en) * 1985-05-16 1987-02-24 American Meter Company Mounting arrangement for a critical flow device
US4706492A (en) * 1986-06-16 1987-11-17 Chevron Research Company Method and apparatus for determining real gas effects in critical flow nozzles
US4753095A (en) * 1986-06-16 1988-06-28 Chevron Research Company Method for determining real gas effects in critical flow nozzles
US4823591A (en) * 1987-11-05 1989-04-25 Horiba Instruments Incorporated Calibration method for exhaust mass flow measuring system
US5307667A (en) * 1992-07-13 1994-05-03 Ford Motor Company Response time test apparatus for a mass air flow sensor
US5299447A (en) * 1992-07-13 1994-04-05 Ford Motor Company Air flow manifold system for providing two different mass air flow rates to a mass air flow sensor production calibration station
US5267467A (en) * 1992-07-27 1993-12-07 Ford Motor Company Mass air flow sensor two temperature production line test apparatus
US5548990A (en) * 1993-07-15 1996-08-27 Northedge; Ronald Methods and systems for calibrating flow meters
US6200819B1 (en) 1995-09-29 2001-03-13 Horiba Instruments, Inc. Method and apparatus for providing diluent gas to exhaust emission analyzer
DE19604417C5 (en) * 1996-02-07 2011-06-22 Roppelt, Helmut, 76694 Method and device for determining the concentration of pollutants in exhaust gases, in particular in exhaust gases of motor vehicles
US5808188A (en) * 1996-05-01 1998-09-15 Chriswell; Shawn Darrell Flowbench and air flow measurement and calibration procedure
US10794333B2 (en) 2017-08-09 2020-10-06 Weaver Intellectual Property, LLC General aviation carburetor testing and analysis device
US11473532B2 (en) 2017-08-09 2022-10-18 Weaver Intellectual Property, LLC General aviation carburetor testing with turbocharger and analysis device

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