This invention relates to an accelerator control apparatus for motor vehicles in general and more particularly for an accelerator control apparatus for an electronic drive control system for a motor vehicle having an internal combustion engine.
BACKGROUND OF INVENTIONConventional control of an accelerator in an internal combustion engine involves a series of links and linkages from a foot pedal in the passenger compartment of a motor vehicle to the butterfly valve or throttle blade in the air intake of the engine. To provide "feel" to the pedal and to return the throttle blade to idle, one or more heavy springs are positioned in the control chain of the accelerator to the throttle blade. Each link, spring and pivot position provides a source for misadjustment and failure. Failure because of corrosion and dirt between the pivot surfaces and the coils of the springs and misadjustment because of wear and looseness in the connection of the links.
SUMMARY OF THE INVENTIONDrive-by-wire or electronic throttle control is a concept where the motion of the foot pedal or accelerator control in the operator compartment of the vehicle is transferred by electrical signals to an actuator for moving the butterfly valve. The actuator in most instances is a d.c. motor which rotates the throttle blade from a substantially closed throttle position to a wide open throttle position. Positioning is determined in a servo controlled manner.
The communication between the accelerator control and the actuator in electronic throttle control is by means of signal wires and not heavy control links and linkages. The accelerator control is an apparatus which is mounted in the passenger compartment and to an operator it must have the "feel" and "operation" of a conventional accelerator apparatus in a non-electronic throttle controlled vehicle.
It is a principal advantage of the accelerator control apparatus of the present embodiment to transfer the rotation of the accelerator by means of electrical signals to the actuator on the throttle body of the internal combustion engine.
It is a further advantage of the accelerator control apparatus of the present embodiment to provide an apparatus that has the "feel" and "operation" of a conventional accelerator apparatus.
It is yet another advantage of the accelerator control apparatus of the present embodiment to provide an enclosed control apparatus shielded from external dirt and other means causing malfunction of the various elements of the apparatus.
These and other advantages will become apparent from the accelerator control apparatus for an electronic drive control system for an internal combustion engine having housing for an accelerator pedal control means. A shaft means is journalled in the housing and is coupled through a coupling means to the accelerator means. At least one bias spring means is mounted on the shaft means with one end of the spring means coupled to the accelerator pedal control means and the other end of the bias spring means secured to the housing to bias the accelerator pedal control means in a first position or home position.
A pedal sensor switch means responsive to the accelerator pedal for generating a first electrical signal indicative of the pedal in its first position and operable to operate a third electrical signal when the pedal is in any second position.
A position sensor means is positioned in the housing and is operable to generate a second electrical signal to indicate when the position of the accelerator pedal control means rotates from its first position to any other of a number of second positions. As used herein, any position other than a first position is a second position. The sensor means generates an electrical signal which is transmitted to the actuator on the throttle body.
In the overall system, the electronic control can sense the position of both the position sensor and the pedal sensor and provide one of many checks to determine operation of the accelerator control apparatus.
Many other objects and purposes of the invention will be clear from the following detailed description of the drawings.
BRIEF DESCRIPTION OF THE DRAWINGSIn the drawings:
FIG. 1 is a block diagrammatic schematic of an electronic throttle control system illustrating the relationship of the accelerator control apparatus with the other elements of the system.
FIG. 2 is a plan view of the accelerator control apparatus with parts broken away for clarity.
FIG. 3 is one end view of the accelerator control apparatus taken alongline 3--3 in FIG. 2.
FIG. 4 is the other end view of the accelerator control apparatus taken alongline 4--4 in FIG. 2 and illustrating the end of the shaft means.
FIG. 5 is a sectional view taken alongline 5--5 in FIG. 2; and
FIG. 6 is a graphic representation of the relationship of the angular movement of the accelerator pedal and the response of the position sensor.
DESCRIPTION OF THE PREFERRED EMBODIMENTFIG. 1 is schematic block diagram of a portion of a motor vehicle illustrating the relationship among the several elements of an electronic throttle control system. In theoccupant compartment 10 there is theaccelerator control apparatus 12 of the present invention. This is illustrated mounted to thefloor 14 of theoccupant compartment 10. Anelectric wire cable 16 connects theaccelerator control apparatus 12 to an electronic control unit or ECU 18 which contains the electronic logic for operating the electronic throttle control system. This ECU 18 may be a dedicated ECU in that it only controls the throttle or it may be a part of a large engine or vehicle control system ECU.
Thecable 16 also connects both the ECU 18 and theaccelerator control apparatus 12 to thethrottle actuator 20 mounted on thethrottle body 22 on theengine 24 for controlling the rotation of thethrottle blade 26. The electronic throttle system is also called a "drive-by-wire" system since the connection between the driver and thethrottle blade 26 is by means of electric wires orcable 16 and not rigid linkages.
As illustrated in FIG. 1, theaccelerator pedal 28, as it is rotated by the engine operator, moves between two extreme positions. The first position "A", which is one extreme position.Iadd., .Iaddend.is the normal position or at rest position which is when the vehicle engine is idling and operator is not actuating theaccelerator 28. The other extreme position "B", which is just one of many second positions, is in the preferred embodiment defined by theaccelerator pedal 28 bottoming on thefloor 14 of the vehicle. Of course, this position can be limited by other means which do not require theaccelerator pedal 28 to reach the floor. As used herein, any position other than the first position is a second position.
FIG. 2 is a plan view of the acceleratorcontrol apparatus housing 44 with thetop cover 30 removed to show the relationship of the several elements ofapparatus 12. There is illustrated the accelerator pedal control means 32, more particularly the arm from thepedal 28 to theapparatus 12, the coupling means 34, a shaft means 36, a bias spring means 38, a position sensor means 40 and a pedal sensor switch means 42. The arm from thepedal 28 is received in the pedal coupling means 34 and secured there by suitable fastening means such as brazing or pinning. As previously stated, the normal position of theaccelerator control apparatus 12 is with the accelerator pedal control means .[.34.]. .Iadd.32 .Iaddend.not being actuated and the pedal coupling means in the upper position "A" as illustrated in solid lines in FIG. 3.
The coupling means 34, in the preferred embodiment, is secured to the shaft means 36 which is journalled in thehousing 44. The coupling means 34 has aslot 46 with parallel sides matching the end profile of the shaft means 36 and it is through this slot that the coupling means 34 rotates the shaft means 36 in response to the pivoting of thepedal 28 by the operator.
Secured to the other end of the shaft means 36 is a sensor actuator means 48 which when rotated actuates both the position sensor means 40 and the pedal sensor switch means 42. The actuator means 48 is secured to the shaft means 36 for rotation therewith by means of aslot 50 with parallel sides which matches the end profile of the shaft means 36. Additionally, the actuator means 48 is prevented from coming off the shaft means by suitable fastening means 52.
The actuator means 48, in the preferred embodiment has two actuation surfaces as illustrated in FIG. 4. Thefirst actuation surface 54 is a paddle-like surface which operates to depress the actuator of the pedal sensor switch means 42. Thesecond actuation surface 56 is another paddle-like surface which bears against alever 58 for operating the position sensor means 40.
The pedal sensor switch means 42 in the preferred embodiment is a normally closed switch that is open when the actuator means 48 is in its normal position and generates a first electrical signal and as soon as the actuator means 48 is rotated by the shaft means 36, thefirst actuation surface 54 moves away from the switch actuator causing the switch contacts to close generating a third electrical signal.
An alternative to the normally closed switch is a pedal pressure sensor means 57 which is actuated by "foot-on" pressure being applied to theaccelerator pedal 28. In the alternative, this sensor could respond to the rotation of the coupling means 34 or shaft means 36.
The position sensor means 40 in the preferred embodiment is a rotary switch wherein its angular displacement is adaptable to generate a second electrical signal indicative of such displacement. In the preferred embodiment, such a position sensor means 40 may be that described in U.S. Pat. No. 4,355,293 issued on October 19, 1982 to Barry J. Driscoll and entitled "Electrical Resistance Apparatus Having Integral Shorting Protection" which is assigned to a common assignee and is incorporated herein by reference.
The position sensor means 40 is essentially a variable resistance and as thelever 58 is rotated, wipers inside the sensor means 40 move across a resistance. There are three wire leads to the sensor, one lead is generally a voltage power lead and is connected to one end of the variable resistance, a second lead is connected to the wipers and a third lead is connected to the other end of the variable resistance and is generally a ground lead. As thelever 58 is rotated, the lead connected to the wipers has an output voltage signal relative to the position of the wipers on the variable resistance.
As illustrated in the FIGURES, there is a bias spring means 38 which is a torsion spring having one end secured to thehousing 44 and a second end coupled to the accelerator pedal control means 32. The coils of the bias spring means 38 surround the shaft means 36 but do not inhibit its rotation. The function of the bias spring means 38 is to bias the accelerator pedal control means 32 in its normal position "A". As the accelerator pedal control means 32 is rotated, the bias spring means 38 applies an opposite rotational force to the accelerator pedal control means 32 giving the requisite "feel" to the vehicle operator. When theaccelerator pedal 28 is released, the bias spring means 38 operates to return theaccelerator pedal 28 to its normal position. For redundancy, the bias spring means 38 may have more than one spring, with each having sufficient torsional force to return theaccelerator pedal 28 to its normal position.
Another element of theacceleration control apparatus 12 which affects "feel" is friction. To mimic the "feel" of a rigid linkage actuatated system and to aid the driver in holding theaccelerator pedal 28 in a given position even on the bumpiest roads a controlled amount of hysteresis or frictional force is provided in theapparatus 12. A second bias means orcompression spring 60 is positioned over the shaft means 36 between the coupling means 34 and thehousing 44. By a fastening means 62 or threaded member such as a nut, the ends of the shaft means 36 are drawn against thesurfaces 64,66 of thehousing 44 or an intermediate washer means 68. The more thespring 60 is compressed, the greater is the force normal to the surface of thehousing 44 and washer means 68 the greater is the frictional force. In the preferred embodiment thehousing 44 and/or the intermediate washer means 68 is fabricated from an aramid fiber composition, a "highly orientated polyethylene", or a long glass fiber nylon. This material gives a non-abrasive wear resistance to the normal forces applied by thecompression spring 60 and operates to extend the operational life of theaccelerator control apparatus 12.
Thehousing 44, in the preferred embodiment, is fabricated in such a manner to place the several groupings of elements in substantially enclosed pockets or volumes in order to keep dirt and other foreign articles from interferring. In particular each end of the shaft means 36 may terminate in one suchenclosed pocket 70 which is formed by thehousing 44 and one or more outside covers 72.
FIG. 6 is a graphic representation of the adjustment of theaccelerator control apparatus 12 and the .[.the.]. position sensor means 40. The actuator means 48 is so positioned so that in its normal position "A", the output of the position sensor means 40 is at one of the voltage extremes; shown here as ground. In actual practice thetotal arc 74 of rotation of the accelerator pedal control means 32 is approximately forty degrees and as illustrated on the graph this range is from the normal position "A" to part way up the slope of the position sensor means 40 output. This feature is needed for repeatability and also makes the assembly of theapparatus 12 much simpler and hence not as expensive.
Another feature provided in the design of thehousing 44 is a built-instop 76 defining the normal position "A". Thestop 76 bears against the coupling means 34 in the normal position. As previously mentioned the extreme second position "B" may be limited by the pedal 28 against thefloor 14 of the vehicle or in the alternative, the housing may also have a second built-in stop surface, not shown, to control the rotational movement of the accelerator pedal control means 28 or the coupling means 34.
The pedal sensor switch means 42, being a normally closed switch, can be used to check the position of theaccelerator pedal 28. The output of the switch can be compared with the position sensor means 40 and the integrity of theapparatus 12 may be determined. For instance if the pedal sensor switch means 42 is open and the position sensor means 40 is generating an output voltage that is not the normal position voltage, this is an indication of a mismatch in the system and the ECU will determine the action to take. Conversely, if the pedal sensor switch means 42 fails and is in a closed position when the position sensor means 40 is in the normal position "A", this is an indication of a mismatch.
Another mismatch indication is when the output of the position sensor means 40 is at the opposite extreme voltage from the normal position voltage level. This might indicate a shorted position sensor means 40. Still another mismatch that can be detected by comparing the outputs of the position sensor means 40 and the pedal sensor switch means 42 is that with a normally closed switch, a broken wire can be distinguished from a "foot-on" condition on theaccelerator pedal 28.
There has thus been described anaccelerator control apparatus 12 for an electronic drive control system for aninternal combustion engine 24 having anenclosed housing 44 for an accelerator pedal control means 32. The accelerator pedal control means 32 provides the "feel" to the vehicle operator necessary for successful vehicle operation and provides diagnostic capability to determine the integrity of theapparatus 12. In the overall system, an electronic control can sense the position of both the position sensor means 40 and the pedal sensor switch means 42 and provide one of many checks to determine operation of theaccelerator control apparatus 12.
Many changes and modifications in the above described embodiment of the invention can, of course, be carried out without departing from the scope thereof. Accordingly, that scope is intended to be limited only by the scope of the appended claims.