The present disclosure relates generally to a fuel and air charge forming device for a combustion engine.
Many engines utilize a throttle valve to control or throttle air flow to the engine in accordance with a demand on the engine. Such throttle valves may be used, for example, in throttle bodies of fuel injected engine systems. Many such throttle valves include a valve head carried on a shaft that is rotated to change the orientation of the valve head relative to fluid flow in a passage, to vary the flow rate of the fluid in and through the passage. In some applications, the throttle valve is rotated between an idle position, associated with low speed and low load engine operation, and a wide open or fully open position, associated with high speed and/or high load engine operation. Fuel may be provided from a relatively high pressure fuel injector (e.g. fuel pressure of 35 psi or more) for mixing with air to provide to the engine a combustible fuel and air mixture. The high pressure fuel injector which may be carried by or located downstream of the throttle body.
In at least some implementations, a throttle body assembly for a combustion engine includes a throttle body, a throttle valve, a metering valve and a boost venturi. The throttle body has a pressure chamber in which a supply of liquid fuel is received, and a throttle bore with an inlet through which air is received. The throttle valve is carried by the throttle body with a valve head movable relative to the throttle bore to control fluid flow through the throttle bore. The metering valve is coupled to the throttle body, and has a valve element that is movable between an open position wherein fuel may flow into the throttle bore and a closed position where fuel is prevented or substantially prevented from flowing into the throttle bore through the metering valve. The boost venturi is located in the throttle bore and having an inner passage that is open at both ends to the throttle bore. The boost venturi has an opening through which fuel flows into the inner passage when the valve element is in the open position, wherein fuel flows from the pressure chamber to the metering valve under the force of gravity or under a pressure of less than 6 psi.
In at least some implementations, a control module has a housing carried by the throttle body and a circuit board and a controller carried by the housing, and the metering valve is electrically actuated and is coupled to the controller In at least some implementations, the circuit board includes at least part of an ignition control circuit that controls the generation and discharge of power for ignition events in the engine.
In at least some implementations, the metering valve includes a motor or a solenoid that moves the valve element.
In at least some implementations, the throttle body includes an air induction passage that extends from a portion of the throttle bore upstream of a fuel outlet of the metering valve and which communicates with the fuel passage leading to the fuel outlet of the metering valve.
In at least some implementations, a jet or restricted orifice is provided in a fuel flow path from the pressure chamber to inner passage.
In at least some implementations, the metering valve includes a fuel outlet through which fuel flows to the inner passage through a fuel passage, and an air induction passage extends from a portion of the throttle bore upstream of the fuel outlet of the metering valve to the fuel passage to provide air into the fuel passage and a flow of fuel and air to the inner passage.
In at least some implementations, a throttle body assembly for a combustion engine includes a throttle body, a throttle valve, an actuator and a coupler. The throttle body has a pressure chamber in which a supply of liquid fuel is received, and a throttle bore with an inlet through which air is received. The throttle valve is carried by the throttle body and has a valve shaft extending through the throttle bore and a valve head connected to the valve shaft so that the valve head is movable relative to the throttle bore to control fluid flow through the throttle bore. The actuator has a driving member coupled to the throttle valve shaft to move the throttle valve between a first position and a second position. And the coupler has an input bore in which part of the driving member is received and an output bore in which part of the valve shaft is received, wherein the coupler has an axis and the coupler is formed from a material that permits the coupler to flex of bend along an axial length of the coupler.
In at least some implementations, the coupler includes a dividing wall that separates the input bore from the output bore.
In at least some implementations, the coupler includes a projection that extends outwardly from an outer surface of the coupler, and wherein the projection engages the throttle body to support the coupler relative to the throttle body.
In at least some implementations, the coupler includes multiple projections spaced apart along the axial length of the coupler.
In at least some implementations, the coupler has a first portion with a noncylindrical cavity in which the driving member is received, and the coupler has a second portion received within an opening formed in a retaining clip that is coupled to the throttle valve shaft. In at least some implementations, the coupler includes a noncircular distal end that is received in a complementary noncircular cavity in the end of the valve shaft to rotatably couple the actuator to the valve shaft.
In at least some implementations, a throttle body assembly for a combustion engine includes a throttle body, a throttle valve, a control module and an actuator. The throttle body has a pressure chamber in which a supply of liquid fuel is received, and a throttle bore with an inlet through which air is received. The throttle valve is carried by the throttle body with a valve head movable relative to the throttle bore to control fluid flow through the throttle bore. The control module has a housing carried by the throttle body and a circuit board and a controller carried by the housing. And the actuator is coupled to the throttle valve to move the throttle valve between a first position and a second position, the actuator being carried by the module and being controlled at least in part by the controller.
In at least some implementations, a metering valve is carried by the throttle body and has a valve element that is movable between an open position wherein liquid fuel may flow from the pressure chamber into the throttle bore and a closed position where liquid fuel is prevented or substantially prevented from flowing into the throttle bore through the metering valve, and wherein the metering valve is electrically actuated and controlled at least in part by the controller. In at least some implementations, the metering valve is directly coupled to the housing.
In at least some implementations, the throttle valve includes a throttle valve shaft that is driven for rotation by the actuator, wherein a throttle position sensor is carried at least in part by the shaft for rotation with the shaft, wherein the actuator is electrically actuated, the actuator is controlled by the controller and the actuator has a drive shaft coupled to the throttle valve shaft by a coupler, and wherein at least one of a drive shaft of the actuator or the throttle valve shaft or the coupler extends through the circuit board.
In at least some implementations, a pressure sensor is carried by the circuit board and having an output communicated with the controller. In at least some implementations, the housing includes a tube that extends into a passage of the throttle body that is open to the throttle bore, and the tube is communicated with the pressure sensor so that the pressure sensor is responsive to changes in pressure in the tube.
In at least some implementations, the actuator is a stepper motor and wherein a throttle position sensor is coupled to the throttle valve and to the circuit board so that the rotary position of the throttle valve as determined by the stepper motor can be confirmed by the throttle position sensor. In at least some implementations, the throttle position sensor includes a potentiometer or the throttle position sensor includes a magnet carried by the throttle valve and a magnetically responsive sensor on the circuit board.
In at least some implementations, a throttle body assembly for a combustion engine includes a throttle body having a pressure chamber in which a supply of fuel is received and a throttle bore with an inlet through which air is received, a throttle valve carried by the throttle body with a valve head movable relative to the throttle bore to control fluid flow through the throttle bore, and a metering valve carried by the throttle body. The metering valve may have a valve element that is movable between an open position wherein fuel may flow from the pressure chamber into the throttle bore and a closed position where fuel is prevented or substantially prevented from flowing into the throttle bore through the metering valve.
In some implementations, a boost venturi is provided within the throttle bore to receive some of the air that flows through the throttle bore, and wherein fuel flows into the boost venturi when the metering valve is open. In some implementations, the throttle valve includes a throttle valve shaft that is driven for rotation by an electrically powered actuator and wherein a throttle position sensor is carried at least in part by the shaft for rotation with the shaft. In some implementations, a control module is also provided that has a circuit board including a controller that controls the actuator, and wherein at least one of a drive shaft of the actuator or the throttle valve shaft or a coupler between the drive shaft and throttle valve shaft extends through the circuit board. The actuator may be mounted to or carried by the control module. A coupler may be provided between a drive shaft of the actuator and the throttle valve shaft to transmit rotary motion from the drive shaft to the throttle valve shaft, and the coupler may frictionally engage the throttle body.
In some implementations, a second metering valve is provided and one metering valve provides fuel flow into the throttle bore at a threshold fuel flow rate or below and the other metering valve enables fuel flow into the throttle bore at fuel flow rates above the threshold.
In some implementations, the pressure chamber is at or within 10% of atmospheric pressure when the engine is operating. In some implementations, the pressure chamber is at a superatmospheric pressure of 6 psi or less when the engine is operating.
In some implementations, the throttle body assembly includes a control module that has a circuit board including a controller, and the metering valve is electrically actuated and controlled at least in part by the controller, and the metering valve is carried by the module. In some implementations, the throttle valve includes a throttle valve shaft that is driven for rotation by an electrically powered actuator and the actuator is carried by the module and controlled at least in part by the controller. A pressure sensor may be carried by the module and have an output communicated with the controller.
In at least some implementations, a throttle body assembly for a combustion engine includes a throttle body having a pressure chamber in which a supply of fuel is received and a throttle bore with an inlet through which air is received, a throttle valve carried by the throttle body with a valve head movable relative to the throttle bore to control fluid flow through the throttle bore, a control module carried by the throttle body and having a circuit board and a controller, and an actuator coupled to the throttle valve to move the throttle valve between a first position and a second position. The actuator may be carried by the module and controlled at least in part by the controller.
In some implementations, the assembly includes a metering valve carried by the throttle body and having a valve element that is movable between an open position wherein fuel may flow from the pressure chamber into the throttle bore and a closed position where fuel is prevented or substantially prevented from flowing into the throttle bore through the metering valve, and the metering valve is electrically actuated and controlled at least in part by the controller. In some implementations, the metering valve is directly coupled to the module. In some implementations, the module includes a housing and the metering valve is carried at least in part by the housing.
The following detailed description of certain embodiments and best mode will be set forth with reference to the accompanying drawings, in which:
Referring in more detail to the drawings,
The assembly 10 includes a throttle body 18 that has a throttle bore 20 with an inlet 22 through which air is received into the throttle bore 20 and an outlet 24 connected or otherwise communicated with the engine (e.g. an intake manifold 26 thereof). The inlet 22 may receive air from an air filter (not shown), if desired, and that air may be mixed with fuel provided from a fuel metering valve 28 carried by or communicated with the throttle body 18. The intake manifold 26 generally communicates with a combustion chamber or piston cylinder of the engine during sequentially timed periods of a piston cycle. For a four-stroke engine application, as illustrated, the fluid may flow through an intake valve and directly into the piston cylinder. Alternatively, for a two-stroke engine application, typically air flows through the crankcase (not shown) before entering the combustion chamber portion of the piston cylinder through a port in the cylinder wall which is opened intermittently by the reciprocating engine piston.
The throttle bore 20 may have any desired shape including (but not limited to) a constant diameter cylinder or a venturi shape (
Referring to
The fuel metering valve 28 (
In the example shown, the valve seat 86 is defined within the cavity 76 of the throttle body 18 and may be defined by a feature of the throttle body or by a component inserted into and carried by the throttle body. Also in the example shown, the valve seat 86 is defined by a metering jet 88 carried by the throttle body 18. The jet 88 may be a separate body press-fit or otherwise installed into the cavity 76 and having a passage or orifice 90 through which fuel at the inlet 66 to the metering valve 28 flows before reaching the valve seat 86 and valve element 68. The flow area of passages downstream of the jet 88 may be greater in size than the minimum flow area of the jet so that the jet provides the maximum restriction to fuel flow through the metering valve 28. Instead of or in addition to the jet 88, a passage of suitable size may be drilled or otherwise formed in the throttle body 18 to define a maximum restriction to fuel flow through the metering valve 28. Use of a jet 88 may facilitate use of a common throttle body design with multiple engines or in different engine applications wherein different fuel flow rates may be needed. To achieve the different flow rates, different jets having orifices with different effective flow areas may be inserted into the throttle bodies while the remainder of the throttle body may be the same. Also, different diameter passages may be formed in the throttle body 18 in addition to or instead of using a jet 88, to accomplish a similar thing.
Fuel that flows through the valve seat 86 (e.g. when the valve element 68 is removed from the valve seat by retraction of the armature 84), flows to the metering valve outlet 70 for delivery into the throttle bore 20. In at least some implementations, fuel that flows through the outlet 70 is directed into the boost venturi 36, when a boost venturi 36 is included in the throttle bore 20. In implementations where the boost venturi 36 is spaced from the outlet 70, an outlet tube 92 (
Fuel may be provided from a fuel source to the metering valve inlet 66 and, when the valve element 68 is not closed on the valve seat 86, fuel may flow through the valve seat and the metering valve outlet 70 and to the throttle bore 20 to be mixed with air flowing therethrough and to be delivered as a fuel and air mixture to the engine. The fuel source may provide fuel at a desired pressure to the metering valve 28. In at least some implementations, the pressure may be ambient pressure or a slightly superatmospheric pressure up to about, for example, 6 psi above ambient pressure.
To provide fuel to the metering valve inlet 66, the throttle body 18 may include a pressure chamber 100 (
To maintain a desired level of fuel in the pressure chamber 100, the valve 108 is moved relative to the valve seat 110 by the actuator 112 (e.g. a float in the example shown) that is received in the pressure chamber and responsive to the level of fuel in the pressure chamber. The float 112 may be buoyant in fuel and pivotally coupled to the throttle body 118 and the valve 108 may be connected to the float 112 for movement as the float moves in response to changes in the fuel level within the pressure chamber 100. When a desired maximum level of fuel is present in the pressure chamber 100, the float 112 has been moved to a position in the pressure chamber wherein the valve 108 is engaged with and closed against the valve seat 110, which closes the fuel inlet 104 and prevents further fuel flow into the pressure chamber 100. As fuel is discharged from the pressure chamber 100 (e.g. to the throttle bore 20 through the metering valve 28), the float 112 moves in response to the lower fuel level in the pressure chamber and thereby moves the valve 108 away from the valve seat 110 so that the fuel inlet 104 is again open. When the fuel inlet 104 is open, additional fuel flows into the pressure chamber until a maximum level is reached and the fuel inlet 104 is again closed.
The pressure chamber 100 may also serve to separate liquid fuel from gaseous fuel vapor and air. Liquid fuel will settle into the bottom of the pressure chamber 100 and the fuel vapor and air will rise to the top of the pressure chamber where the fuel vapor and air may flow out of the pressure chamber through the vent 102 (and hence, be delivered into the intake manifold and then to an engine combustion chamber). In the example shown, the valve element 108 is slidably received within a passage 114 leading to the valve seat 110. To reduce a pressure differential that may exist across the valve seat 110 (e.g. due to the vent 102 communicating with the intake manifold), and to facilitate breaking any fluid surface tension or other force that may be present and tend to cause the valve 108 to stick to the valve seat 110, a cross vent passage 116 (
The pressure chamber 100 may be defined at least partially by the throttle body 18, such as by a recess formed in the throttle body, and a cover 118 carried by the throttle body. An outlet 120 of the pressure chamber 100 leads to the metering valve inlet 66. So that fuel is available at the metering valve 28 at all times when fuel is within the pressure chamber 100, the outlet 120 may be an open passage without any intervening valve, in at least some implementations. The outlet 120 may extend from the bottom or a lower portion of the pressure chamber so that fuel may flow under atmospheric pressure to the metering valve 28. A filter or screen 122 (
In use of the throttle body assembly 10, fuel is maintained in the pressure chamber 100 as described above and thus, in the outlet 120 and the metering valve inlet 66. When the metering valve 28 is closed, there is no, or substantially no, fuel flow through the valve seat 86 and so there is no fuel flow to the metering valve outlet 70 or to the throttle bore 20. To provide fuel to the engine, the metering valve 28 is opened and fuel flows into the throttle bore 20, is mixed with air and is delivered to the engine as a fuel and air mixture.
The timing and duration of the metering valve opening and closing may be controlled by a suitable microprocessor or other controller. The fuel flow (e.g. injection) timing, or when the metering valve 28 is opened during an engine cycle, can vary the pressure signal at the outlet 70 and hence the differential pressure across the metering valve 28 and the resulting fuel flow rate into the throttle bore 20. Further, both the magnitude of the engine pressure signal and the airflow rate through the throttle valve 52 change significantly between when the engine is operating at idle and when the engine is operating at wide open throttle. In conjunction, the duration that the metering valve 28 is opened for any given fuel flow rate will affect the quantity of fuel that flows into the throttle bore 20.
In general, the engine pressure signal within the throttle bore 20 at the fuel outlet 70 (or the end of the tube 92 if a tube is provided) is of higher magnitude at engine idle than at wide open throttle. On the other hand, the pressure signal at the fuel outlet 70 (or the end of tube 92) generated by the air flow through the throttle bore 20 and boost venturi 36 is of higher magnitude at wide open throttle than at idle. The relative engine operating condition can be determined in different ways, including by an engine speed sensor and/or a throttle valve position sensor 124.
In the example shown in
In the example shown, the throttle position sensor 124 is at one end of the throttle valve shaft 56 and the throttle valve actuator 60 (e.g. the motor 62 or valve lever 64) is at the other end. In such an arrangement, both ends of the throttle valve 52 may be accessible from the exterior of the throttle body 18, and may have components mounted thereto such that a retainer for the throttle valve shaft 56 is positioned between the ends of the shaft. In the implementations shown, for example in
In at least some implementations, a stepper motor 62 may be used to actuate the throttle valve 52 and the rotary position of the stepper motor may be used to determine the throttle valve 52 position, if desired. For example, a controller used to actuate the stepper motor 62 may track the rotary position of the stepper motor and that may be used to determine the throttle valve 52 position. With a stepper motor actuating the throttle valve 52, it may still be desirable to include a separate throttle position sensor to provide feedback for use in actuating the throttle valve 52 for improved throttle valve control and position determination.
Further, at least in implementations without a valve lever 64 coupled to the throttle shaft 56, stops 140, 142 for the idle and wide open throttle positions may be carried by the throttle body 18 and arranged to be engaged by the valve head 54. As shown in at least
As noted above, the throttle valve 52 position may be used as one factor in the determination of engine fuel demand, which fuel demand is satisfied by opening the metering valve and permitting fuel to flow into the throttle bore 20. The fuel flow rate is a function of the pressure acting on the fuel, including the pressure upstream of the metering valve 28 (e.g. in the pressure chamber 100) and the pressure downstream of the metering valve (e.g. in the throttle bore 20). In at least some implementations, the metering valve 28 is opened during a portion of the engine cycle which may, but need not include the intake stroke, and a subatmospheric pressure prevails in the throttle bore 20. Hence, with the pressure chamber 100 at or near atmospheric pressure and a subatmospheric pressure in the throttle bore 20 during at least a portion of the time that the metering valve 28 is open, the differential pressure causing fuel to flow into the throttle bore 20 is greater than one atmosphere. For example, if the pressure chamber 100 is at atmospheric pressure and the pressure at the fuel outlet 70 when the metering valve is open is 3 psi below atmospheric pressure, then the total or net pressure acting on the fuel would be one atmosphere plus 3 psi in terms of absolute pressure. Even during a compression engine stroke (wherein a combustion chamber becomes smaller), the air flow through the venturi can provide a negative or subatmospheric pressure in the throttle bore 20. The pressure within the throttle bore 20 could be measured by a sensor or the information could be provided in a lookup table, map or other stored data collection as a function of certain operating parameters (e.g. engine speed and throttle position). This information may be provided to the controller that actuates the metering valve to control operation of the metering valve as a function of certain engine operating parameters.
In implementations that include a boost venturi 36, the pressure signal at the fuel outlet 70 is related to the pressure within the boost venturi 36 in the area of the fuel outlet into the boost venturi 36. The boost venturi 36 may improve the pressure signal at engine idle by increasing the velocity of a relatively low flow rate of air and thereby providing a larger pressure drop at the fuel outlet 70. At idle, as noted above, the engine pressure signal is relatively large and may dominate the pressure drop created by the airflow through the boost venturi 36. Nevertheless, the increased airflow velocity in the boost venturi 36 may facilitate mixing of the air and fuel and delivery of the fuel to the engine compared to a system wherein the fuel is discharged into a lower velocity airflow. This may prevent fuel from pooling or collecting in the throttle bore 20 and provide a more consistent fuel and air mixture to the engine at low engine speeds and loads at which the fluid flow rate to the engine is relatively low and hence, the engine may be relatively sensitive to changes in the fuel and air mixture.
To improve airflow through the boost venturi 36 when the throttle valve 52 is in its idle position and near the idle position, the throttle valve 52 may include a flow director arranged to increase airflow through the venturi. In the example shown, the flow director includes an opening 150 (
Additionally, when the throttle valve 52 is opened off idle, and a greater flow rate of air is provided through the throttle bore 20, the boost venturi 36 may provide a more consistent and less turbulent air flow at the fuel outlet. Air flow within the throttle bore 20 can become turbulent as the air flows around the throttle valve head 54 and shaft 56. The air flow through the boost venturi 36 may be more uniform as the air flows through the converging inlet portion 38 and the throat 40. Further, the boost venturi 36 may be located within the throttle bore 20 so that it is aligned with air flowing into the throttle bore 20 as the throttle valve 52 is initially rotated off idle. Hence, the boost venturi 36 may receive air flow at idle, throttle positions off idle and as the throttle valve 52 rotates toward and to its wide open position, and the boost venturi 36 may provide a steadier state of air flow to the area of the fuel outlet 70 to provide a more consistent pressure signal at the fuel outlet and a more consistent mixing of fuel and air. Hence, the fuel and air mixture to the engine may be more consistent and the operation of the engine more consistent as a result.
Next, while one metering valve 28 is shown in the throttle body assembly 10 of
Whether one or more than one metering valve is used, one or more separate fuel passages may be communicated with any one and up to each metering valve to cool the metering valves which may operate at a relatively high voltage (e.g. 8 to 12 volts) and have a cycle rate wherein higher than desired heat may be generated. Such fuel passages are called cooling passages 166 herein, and as shown in
Further, as shown in
As shown in
In the example where a fuel tube 92 extends into a boost venturi 36, the induction passage 172 may extend into or communicate with the fuel tube (as shown in dashed lines in
In addition to or instead of a jet or other flow controller, the flow rate through the induction passage 172 may be controlled at least in part by a valve. The valve could be located anywhere along the passage 172, including upstream of the inlet of the passage. In at least one implementation, the valve may be defined at least in part by the throttle valve shaft. In this example, the induction passage 172 intersects or communicates with the throttle shaft bore so that air that flows through the induction passage flows through the throttle shaft bore before the air is discharged into the throttle bore. A void, like a hole or slot, may be formed in the throttle valve shaft 56 (e.g. through the shaft, or into a portion of the periphery of the shaft), as generally shown by the hole 173 illustrated in dashed lines in
As noted above, the throttle body may also be configured to operate with fuel supplied at a positive or superatmospheric pressure. In at least some implementations, the fuel in the throttle body 18 may be provided by a fuel pump 190 (
In at least some implementations, the fuel pump 190 is an impulse pump driven by pressure pulses from the engine (e.g. the engine intake manifold). One suitable type of an impulse pump may include a diaphragm actuated by the engine pressure pulses to pump fuel through inlet and outlet valves as the diaphragm oscillates or reciprocates. With such a fuel pump 190, when the metering valve 28 is closed the pump does not pump fuel and no bypass of fuel is needed at the pressure regulator 192. If a positive displacement fuel pump is used, such as a gerotor fuel pump, then the pressure regulator may include a bypass passage through which fuel at an excess pressure is returned to the fuel tank, or to some other portion of the system upstream of the pressure regulator. Other pumps may include a diaphragm pump operated mechanically or electrically by some engine subsystem or a controller.
In at least some implementations, as shown in
From the pressure regulator 192, the fuel may flow at a generally constant superatmospheric pressure to the pressure chamber 196 (
In at least some implementations, the throttle body provides a pressure chamber in which a supply of fuel is maintained. The fuel in the chamber provides head pressure that augments fuel flow in the throttle body and the mixing of fuel with air before a fuel and air mixture is delivered to the engine. Hence, some positive pressure is provided on the fuel rather than subatmospheric pressure being used to pull or draw fuel through an orifice or the like. Hence, fuel may be delivered even if the engine is not operating as the pressure head acting on the fuel can cause fuel flow without an engine pressure signal being applied to the fuel. Further, the fuel metering may include a valve that is selectively opened and closed during an engine cycle to allow fuel flow when opened and prevent or substantially inhibit fuel flow when closed, and this selective valve operation may happen at engine idle or wide open throttle operation. Further, air is mixed with fuel after the fuel has flowed through the metering valve(s) rather than having a fuel and air mixture metered.
Further, at least some implementations of the throttle body do not include a pressure regulator and instead operate at ambient pressure, with a pressure head acting on the fuel, as noted above. Hence, gravity and the fuel level in a pressure chamber set the approximate pressure for fuel delivery, in combination with a pressure signal in the throttle bore. In at least some implementations, a fuel pump or other source of fuel at a positive or superatmospheric pressure is not needed.
In at least some implementations, the metering valves are arranged so that fuel flows into the metering valve generally axially aligned with the valve seat and valve element, and fuel is discharged from the metering valve outlet generally radially outwardly and radially outwardly spaced from the inlet. Further, the outlet from the metering valve may be delivered to the throttle bore through relatively large passages (large flow areas) with a jet or maximum flow restriction for the fuel provided upstream of the throttle bore and, in some implementations, upstream of the metering valve. Air flow in the throttle bore, and within a boost venturi in at least some implementations, is used to mix fuel and air and reduce the size of fuel droplets delivered to the engine. Fuel may be delivered into the throttle bore through a single orifice in at least some implementations, and through one orifice per metering valve in at least certain other embodiments (e.g. one orifice for a low speed metering valve and a separate orifice for a high speed metering valve).
Further, the pressure chamber may act as a vapor separator and may be carried by the throttle body as opposed to a remotely located vapor separator coupled to the throttle body or a fuel injector by tubes or hoses. Thus, the vapor separator may be located close to the location where fuel is discharged into the throttle bore which, among other things, can reduce the likelihood of vapor forming downstream of the separator.
In at least some implementations, the area of the metering valve inlet to the area of the metering valve outlet has a ratio of between about 0.05 to 2:1 (including implementations with a fuel metering jet that defines the minimum inlet flow area). Further, fuel flow through the metering valves may be in the range of about 0.1 to 30 lb/hr, and the throttle bodies disclosed herein may be used with engines having a power output of, for example, between about 3 to 40 horsepower. And with the pressure chamber including a float and a vent, the throttle body may be used with engines that remain within about 30 degrees of horizontal.
Further, in at least some implementations, a microprocessor or other controller may control numerous functions via internal software instructions which apply a fuel grid map, matrix or look up table (as examples without limitation) in response to the sensed actual position of the throttle valve 52, engine rpm and crankshaft angular position in order to select a desired moment to open, and determine the opening duration of a metering valve 28 for delivery of fuel into the throttle bore 20. The microprocessor may also vary the engine spark ignition timing to control engine operation in addition to controlling fuel flow to the engine.
As noted above, the throttle valve 52 may be controlled by an electrically powered actuator 60 including, for example, various rotary motors like a stepper motor 62. The motor 62 may be coupled to the throttle valve shaft 56 in any desired way. One example connection is shown in
Further, as shown in
A different coupler 271 between the throttle valve shaft and drive motor is shown in
Either or both of the coupler 271 and the clip 274 may accommodate some misalignment between the drive shaft 264 and the throttle valve shaft 56, as well as damp vibrations and the like. With this arrangement, a throttle valve position sensor may be included between the drive motor 62 and throttle valve shaft 56, with the coupler 271 carrying a magnet 280 that rotates with the coupler. The magnet 280 may be axially retained on the coupler 271 in any suitable way, and is shown as being carried within a cavity of a motor cover 282, and may be retained in the other direction by the clip 274, if desired. Further, the magnet 280 could be on an opposite side of the circuit board 130 as the motor 62. For example, the magnet 280 could be on the side of the circuit board 130 closer to the throttle bore 20 and the motor housing could be located at the other side of the circuit board. A magnetically responsive sensor (e.g. 128) could be in any location suitable to detect the changing magnetic field caused by rotation of the magnet. Even with a motor or other actuator in which the rotational position can be determined with suitable accuracy, in at least some implementations, a separate throttle position sensor may be desirable to account for any twisting of a coupler or other element between the actuator and throttle valve, and/or to provide a separate indication of throttle valve position for improved accuracy and/or to enable the position as determined from the actuator to be verified or double checked, which may permit any error in the reported position of the actuator or the throttle valve to be corrected.
A different coupling between the motor 62 and throttle valve shaft 56 is shown in
As shown in
As shown in
Other sensors may also be used and communicated with the microprocessor 306, and may be directly mounted on the circuit board 130. For example, as shown in
The motor, metering valve(s), and sensors may be coupled to the circuit board by themselves, that is, without any of the other components mounted on the circuit board, or in any combination including some or all of these components as well as other components not set forth herein. As noted above, the circuit board may include at least part of an ignition control circuit that controls the generation and discharge of power for ignition events in the engine, including the timing of the ignition events. And that circuit may include the microprocessor 306 so that the same microprocessor may control the ignition circuit, the throttle valve position and the metering valve(s) position. Of course, more than one microprocessor or controller may be provided, and they may be on the same or different circuit boards, as desired. In at least some implementations, all of various combinations of these components are in the same control module for ease of assembly and use with the throttle body and with the engine and the vehicle or tool with which the engine is used.
In at least some implementations, the ignition circuit may include one or more coils located adjacent to a flywheel that includes one or more magnets. Rotation of the flywheel moves the magnets relative to the coils (commonly a primary, secondary and/or a trigger coil) and induces an electrical charge in the coils. The ignition circuit may also include other elements suitable to control the discharge of electricity to a spark plug (as in either an inductive ignition circuit or a capacitive discharge ignition circuit) and/or to store energy generated in the coils (such as in a capacitive discharge ignition circuit). However, a microprocessor need not be included in the assembly that includes the coil. Instead, the microprocessor (e.g. 306) associated with the charge forming device, which may be operable to communicate with and/or control one or more devices associated with the throttle valve as noted herein, may also control the timing of ignition events, for example, by controlling one or more switches associated with the assembly including the coils and located adjacent to or carried by the engine. Hence, the coils may be separately located relative to the throttle body and its control module, yet controlled by the throttle body control module. In addition, sensors or signals may be provided from the assembly including the coils to the control module and controller 306 for improved control of the ignition timing, among other reasons. Without intending to limit the possibilities, such signals may relate to temperature of the assembly including the coils or of the engine, such signals may relate to engine speed and/or such signals may relate to engine position (e.g. crank angle). Still further, the energy induced in the coils may be used to power one or more of the microprocessor 306, a throttle valve actuator, a metering valve actuator, a fuel injector, and the like. In this way, the two modules (one with the coils at the engine and the other at or associated with the throttle body) may enjoy an efficient and symbiotic relationship.
In at least some implementations, the engine speed may be controlled by the module with a combination of the throttle valve position and ignition timing, both of which may be controlled by the microprocessor 306, which may be included within the module 300 as noted above. The throttle valve position affects the flow rate of air and fuel to the engine, and the ignition timing can be advanced or retarded (or certain ignition events may be skipped altogether) to vary the engine power characteristics, as is known. Hence, the system can control both throttle valve position and ignition timing to control the flow rate of a combustible air and fuel mixture to the engine and when the combustion event occurs within an engine cycle.
Another implementation of a fuel and air charge forming device 320, which may be a throttle body, is shown in
In more detail, fuel from a source (e.g. fuel tank) enters the throttle body through a fuel inlet 324 in a cover 326 that is fixed to the main throttle body 18. From the fuel inlet, the fuel flows to the fuel pump 322 through a pump inlet passage 328 that is formed in the main body 18. The fuel pump 322 in this example includes a fuel pump diaphragm 330 trapped about its periphery between a pump cover 332 and the main body 18 or another component. A pressure chamber 334 is defined on one side of the diaphragm 330 and is communicated with engine pressure pulses via a pressure signal inlet 336 that may be defined in a fitting formed in the pump cover 332. A suitable conduit may be coupled to the fitting 336 at one end, and may communicate with the engine intake manifold, engine crankcase, or another location from which engine pressure pulses may be communicated to the pressure chamber. The other side of the diaphragm 330 defines a fuel chamber 338 with the main body. Fuel enters the fuel chamber 338 through an inlet valve 340 and fuel exits the fuel chamber under pressure through an outlet valve (not shown). The inlet and outlet valves may be separate from the fuel pump diaphragm, or one or both of them may be integrally formed with the diaphragm, such as by flaps in the diaphragm that move relative to separate valve seats in response to a pressure differential across the flaps. In at least some implementations, as shown in
The untrapped central portion of the diaphragm 330 moves in response to a differential pressure across it. When the central portion of the diaphragm 330 is moved toward the cover 332, the fuel chamber 338 volume increases and the pressure therein decreases which opens the inlet valve 340 and admits fuel into the fuel chamber. When the central portion of the diaphragm 330 moves away from the cover 332, the volume of the fuel chamber 338 is decreased and the pressure therein is increased. This pumps fuel out of the fuel chamber under pressure and through the outlet valve. The fuel pump 322 may be constructed and may operate similarly to a diaphragm fuel pump used, for example, in certain carburetors.
The fuel discharged from the fuel chamber 338 flows into a pump outlet passage 346 that may be formed at least in part in the main body 18. From the pump outlet passage 346, the fuel flows into a pressure chamber 348 which may be similar to the pressure chamber 196 described above with regard to
Fuel in the pressure chamber 348 is communicated with a fuel pressure regulator 356 which may also be carried by the main body 18, other body associated with the main body, or it may be remotely located and coupled to the pressure chamber 348 by a suitable conduit. The pressure regulator 356 may be of any desired construction, and may be as set forth in described above with regard to
Fuel in the pressure chamber 348 is also communicated with a fuel metering valve 370 through a pressure chamber outlet passage 372 which may, if desired, be formed fully or partially within the main body 18. The metering valve 370 is received within a bore 374 of the main body 18 that intersects the fuel outlet passage 372 and has an outlet port that leads to or is directly open to the throttle bore 20. A valve seat or metering orifice 376 of the valve bore 374 is between the fuel outlet passage 372 and the outlet port or throttle bore 20 so that the flow of fuel to the throttle bore is controlled or metered by the valve 370. The metering valve 370 may be of any desired construction including but not limited to the valves already described herein.
In at least some implementations, the metering valve 370 may include a body axially movable relative to the valve seat 376 or within a tapered orifice to alter the flow area of the valve and hence, the flow rate of fuel through the valve and to the throttle bore 20. In the example shown, the valve body includes a needle 378 at its distal end that extends through the valve seat 376, and the valve body includes a shoulder adapted to engage the valve seat to limit or prevent fuel flow through the valve seat when the valve is in a closed position. Axial movement of the valve body may be controlled by an actuator 380, which may be electrically powered. The actuator 380 may be or include a solenoid, or it may be a motor such as but not limited to the types of motors listed herein above with regard to at least the throttle valve actuator(s). In at least some implementations, the motor 380 rotates the valve body which may include external threads that are engaged with threads formed in the bore 374 so that such body rotation causes the valve body to move axially relative to the valve seat 376. The motor 380 could instead linearly advance and/or retract the body relative to the valve seat. The motor may be driven by a controller, such as a microprocessor 306 as set forth above. Because the fuel at the metering valve 370 is under pressure, it will flow into the throttle bore 20 as long as fuel is present and the shoulder is not engaged with the valve seat, and no fuel injector or the like is required, at least in certain implementations.
As shown in
While the forms of the invention herein disclosed constitute presently preferred embodiments, many others are possible. It is not intended herein to mention all the possible equivalent forms or ramifications of the invention. It is understood that the terms used herein are merely descriptive, rather than limiting, and that various changes may be made without departing from the spirit or scope of the invention.
This application is a continuation of U.S. patent application Ser. No. 16/094,945 filed Oct. 19, 2018, which is a national phase of PCT/US2017/028913, filed Apr. 21, 2017 and claims the benefit of U.S. Provisional Application Ser. No. 62/479,103 filed on Mar. 30, 2017 and 62/325,489 filed Apr. 21, 2016. The entire contents of these priority applications are incorporated herein by reference in their entireties.
Number | Date | Country | |
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62479103 | Mar 2017 | US | |
62325489 | Apr 2016 | US |
Number | Date | Country | |
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Parent | 16094945 | Oct 2018 | US |
Child | 17355895 | US |