Integrated fuel delivery and electronic powertrain control module and method of manufacture

Abstract
An integrated control and fuel delivery system having an intake manifold that receives a portion of an airflow and delivers air to an engine and a fuel spacer that receives the air from the intake manifold. The fuel spacer includes a wiring harness. A control module is disposed on the fuel spacer adjacent to the intake manifold of the engine.
Description




BACKGROUND OF THE INVENTION




1. Field of Invention




The present invention relates generally to a fuel delivery system for internal combustion engines. More particularly, the present invention relates to a multi-functional fuel delivery system.




2. Related Art




Internal combustion engines used in automobiles and the like employ sophisticated engine control technologies making use of a variety of sensors and actuators in communication with powertrain control module circuitry. Engine control provided by these systems may provide increased performance, reduced emissions and higher reliability in the operation of the vehicle.




The powertrain control module (PCM) circuitry may be located near the vehicle fire wall to provide a secure mounting of the circuitry away from the high temperature components of engine and allow communication with driver instrumentation in the passenger compartment.




The PCM communicates with a variety of sensors on or close to the engine, for example, sensors for air mass flow, engine temperature, throttle position, engine speed and crankshaft position. The PCM, in receiving these sensor signals, produces actuator signals used to control fuel injectors, ignition coils and the like.




Many of the delivery system assemblies are often rigidly attached to the engine in close proximity to one another and have a number of rigid connections between the various components of the different systems. Therefore, access to one system assembly often requires the difficult disengagement of a number of rigid connections as well as removal of a number of components to gain access to the desired components.




BRIEF SUMMARY OF THE INVENTION




One aspect of the present invention regards an integrated control and fuel delivery system having an intake manifold that receives a portion of an airflow and delivers air to an engine and a fuel spacer that receives the air from the intake manifold. The fuel spacer includes a wiring harness. A control module is disposed on the fuel spacer adjacent to the intake manifold of the engine.




Another aspect of the present invention regards an integrated control and fuel delivery system for a vehicle having an engine and an intake manifold that receives a portion of an airflow. The integrated control and fuel delivery system includes a fuel spacer having a casting, a wiring harness connected to the casting, a fuel rail and a over-mold mated to the casting, the wiring harness and the fuel rail. The fuel spacer is disposed between the intake manifold and the engine. The integrated control and fuel delivery system also includes a PCM disposed on the fuel spacer in an airflow that is received by the intake manifold. The PCM is in communication with the wiring harness.




In another aspect, a method of producing an over-molded fuel spacer by placing a casting, a fuel rail, and a wiring harness into an injection molding tool. The injection molding tool over-molds the casting, the fuel rail and the wiring harness with a glass filled nylon material.




Each aspect of the present invention provides the advantages of reducing the number of parts count and providing weight savings. In addition, by moving the PCM to an “on-engine” location, the cost and complexity of the vehicle wiring harness is reduced.




Additional embodiments and advantages of the present invention will become apparent from the following description and the appended claims when considered with the accompanying drawing.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1A

shows a cross-sectional view of an embodiment of an integrated powertrain control system (IPCS), according to the present invention;





FIG. 1B

shows a perspective view of the IPCS of

FIG. 1A

;





FIG. 2

shows an exploded view of an embodiment of a fuel spacer, according to the present invention;





FIG. 3

shows a perspective view of the fuel spacer of

FIG. 2

; and





FIG. 4

shows a front view of the IPCS of

FIG. 1A

disposed between an embodiment of an engine and an intake manifold, according to the present invention.











DETAILED DESCRIPTION OF THE INVENTION





FIG. 1A

shows a cross-sectional view of an embodiment of an integrated powertrain control system (“IPCS”)


100


. The IPCS


100


includes a fuel spacer


102


and a powertrain control module


103


(“PCM”) disposed on the fuel spacer


102


. In a preferred embodiment, the fuel spacer


102


is attached to an engine


401


having one or more cylinders, as shown in FIG.


4


. The fuel spacer


102


is attached above the cylinders. An upper intake manifold


104


is attached to the top of the fuel spacer


102


such that PCM


103


is adjacent to both the upper intake manifold


104


and an airflow received by the upper intake manifold


104


. There are many components near the upper intake manifold


104


. Integration into a single system may reduce the part count and simplify final assembly.

FIG. 1B

shows a perspective view of the IPCS


100


of FIG.


1


A. As shown in

FIG. 1B

, the PCM


103


has a wiring harness connector


111


.





FIG. 2

shows an exploded view of an embodiment of fuel spacer


102


, according to the present invention. The fuel spacer


102


includes a casting


220


, a fuel rail


105


, a wiring harness


106


connected to the casting


220


and an over-mold


221


mated to the casting


220


and the wiring harness


106


.




The casting


220


includes an air-carrier member


222


and bolt-holes


223


. The casting


220


is used to facilitate airflow into and out of the engine block via the upper intake manifold


104


(FIG.


1


B). The casting


220


is also used to dissipate heat from the PCM


103


. Typically, the casting


220


is an aluminum casting, although cast iron or other casting may be used. Aluminum is used because of aluminum's high thermo conductivity. Thus, the aluminum casting


220


may be used as a heat sink.




The wiring harness


106


includes an ignition coil connector


107


, a fuel injector connector


108


and a PCM connector


224


. In the present invention, the ignition coil connector


107


, the fuel injector connector


108


and the PCM connector


224


are integrated connectors and are further described below. The wiring harness


106


may be connected to the underside of the casting


220


by clips or other connectors on the wiring harness


106


. In the present invention, the wiring harness


106


is connected to the underside of the casting by the injection mold process described below. The wiring harness


106


may also include other connectors for connecting to various other types of components, such as those attached to a standard wiring harness. The wiring harness


106


electrically connects an ignition coil


110


and a fuel injector


109


to the PCM


103


by connecting the wiring harness connector


111


to the PCM connector


224


; however, the wiring harness


106


may be wired directly into the PCM


103


thereby alleviating the need for wiring harness connector


111


and PCM connector


224


.

FIG. 1B

shows the wiring harness


106


electrically connected to six ignition coils


110


, to six fuel injectors


109


, and to the PCM


103


via the wiring harness connector


111


; however, the present invention may be designed to accommodate any number of ignition coils


110


and fuel injectors


109


. There is a one-to-one correspondence to the number of fuel injectors


109


, ignition coils


110


and the number of cylinders in the engine


401


. Typically, the wiring harness


106


is an integrated silicone over-molded wiring harness; however, other types of wiring harnesses may be used, such as an integrate urethane over-molded wiring harness, a standard wiring harness, wiring harnesses later developed. Ignition coil


110


, fuel injector


109


and the fuel rail


105


operate in a well known manner.





FIG. 3

shows an embodiment of the final assembly of fuel spacer


102


. The fuel spacer


102


is assembled using a molding process. The molding process includes placing the aluminum casting


220


, the fuel rail


105


and the silicone over-molded wiring harness


106


into an injection molding tool and over-molding this assembly with the over-mold


221


. Two fuel rails


105


are typically placed within the injection molding tool. Typically, the over-mold


221


is made of a glass filled nylon material; however the over-mold


221


may be made of any high temperature polymer or other material.




The fuel injector connector


108


, the ignition coil connector


107


and the PCM connector


224


are integrated connectors. Using integrated connectors allows for easy assembly onto the engine block and connection to the appropriate part. Integrated connectors also improve reliability because electrical connections are made to the appropriate parts when the fuel spacer


102


is installed. Other connectors may be used also, such as those attached to a standard wiring harness.




During the molding process, a heat-sinking area


301


is created on an upper portion of the fuel spacer


102


by leaving a section of the aluminum casting


220


uncovered, for attachment of the PCM


103


. Final assembly of the IPCS


100


will now be discussed.




Referring to

FIGS. 1A

,


1


B,


3


, and


4


the fuel spacer


102


is placed over a cylinder of the engine


401


such that the air-carrier member


222


is arranged in general proximity with a respective cylinder, thus, allowing air to flow through the manifold


104


, the fuel spacer


102


into each of the cylinders of the engine


401


. The intake manifold


104


is placed on top of the fuel spacer


102


. The upper intake manifold


104


and fuel spacer


102


are bolted to the engine by driving bolts through the intake manifold


104


, through the bolt-holes


223


and into the engine. Typically, there are two bolt-holes


223


per air carrier member


222


. The bolt-holes


223


accept fastener bolts that are used to connect the upper intake manifold


104


and the fuel spacer


102


to the engine


401


. Since a gasket may be inserted between the fuel spacer


102


and the engine


401


the fastener bolts provide a proper seal but other bolts may be used.




The PCM


103


is attached to the fuel spacer


103


on the heat sinking area


301


. The PCM


103


controls the electrical devices in a vehicle or associated with engine control. The PCM


103


is typically attached by using threaded fasteners. Four fasteners ensure good surface contact between the PCM


103


and the heat-sinking area


301


but fewer or more fasteners may be used. Additionally, a thermally conductive tape may be used between the PCM


103


and the heat-sinking area


301


to further ensure good thermal conductivity. The IPCS


100


may be designed to use either a super integration concept of flexible flatwire substrates, a more conventional style of PCM's using a thick film substrate, such as, FR


4


or ceramic, or other now known or better developed substrates.




The PCM


103


may include a circuit board, active or passive integrated circuits, such as a microprocessor or an application specific integrated circuit. The PCM


103


is typically covered by metal or high temperature plastic.




In a preferred embodiment, the PCM


103


is located adjacent to the upper intake manifold


104


. The PCM


103


is protected from the high temperatures in the area adjacent to the upper intake manifold


104


because the in-molded aluminum casting


220


acts as a heat sink. Furthermore, by placing the PCM


103


adjacent to the upper intake manifold


104


, the PCM


103


is able to use the airflow flowing into the upper intake manifold


104


as the heat-dissipating medium. As stated above, placing the IPCS


100


in this area allows additional sensor/actuator integration, such as integration of electronic throttle body, EGR, fuel pressure sensors, sensors for air mass flow, engine temperature, engine speed and crankshaft position.




The foregoing detailed description is merely illustrative of several physical embodiments of the invention. Physical variations of the invention, not fully described in the specification, may be encompassed within the purview of the claims. Accordingly, any narrower description of the elements in the specification should be used for general guidance, rather than to unduly restrict any broader descriptions of the elements in the following claims.



Claims
  • 1. An integrated control and fuel delivery system, comprising:an intake manifold that receives a portion of an airflow and delivers air to an engine; and a fuel spacer that receives said air from said intake manifold; said fuel spacer comprising a wiring harness; a control module disposed on said fuel spacer adjacent to said intake manifold of said engine; wherein said control module is connected to said wiring harness.
  • 2. The integrated control and fuel delivery system of claim 1, wherein said control module comprises a powertrain control module.
  • 3. The integrated control and fuel delivery system of claim 1, wherein said fuel spacer comprises,a casting; said wiring harness connected to said casting; and an over-mold mated to said casting and said wiring harness.
  • 4. The integrated powertrain control system as claimed in claim 1, wherein said fuel spacer comprises a fuel rail.
  • 5. The integrated control and fuel delivery system of claim 1, wherein said fuel spacer is disposed between said engine and said intake manifold.
  • 6. The integrated control and fuel delivery system of claim 1, wherein said intake manifold is an upper intake manifold.
  • 7. The integrated control and fuel delivery system of claim 3, wherein said over-mold comprises a glass filled nylon over-mold.
  • 8. The integrated control and fuel delivery system of claim 1, wherein said fuel spacer comprises two fuel rails.
  • 9. The integrated control and fuel delivery system of claim 3, wherein said casting comprises an aluminum casting.
  • 10. The integrated control and fuel delivery system of claim 1, wherein said wiring harness comprises a powertrain control module connector, an ignition coil connector, and a fuel injector connector.
  • 11. The integrated control and fuel delivery system of claim 10, wherein said powertrain control module is in electrical communication with said powertrain control module connector, said ignition coil connector and said fuel injector connector.
  • 12. The integrated control and fuel delivery system of claim 1, wherein said wiring harness comprises urethane.
  • 13. The integrated control and fuel delivery system of claim 1, wherein said wiring harness comprises silicone.
  • 14. The integrated control and fuel delivery system of claim 3, wherein said casting comprises an air-carrier member.
  • 15. The integrated control and fuel delivery system of claim 3, comprising a heat-sinking area on an upper surface of said fuel spacer.
  • 16. The integrated control and fuel delivery system of claim 15, wherein said control module is disposed on said heat-sinking area.
  • 17. The integrated control and fuel delivery system of claim 1, wherein said control module is disposed in said airflow.
  • 18. An integrated control and fuel delivery system for a vehicle having an engine and an intake manifold that receives a portion of an airflow, comprising:a fuel spacer, comprising: a casting; a wiring harness connected to said casting; a fuel rail; and an over-mold mated to said casting, said wiring harness, and said fuel rail; said fuel spacer disposed between said intake manifold and said engine; a control module in communication with said wiring harness; wherein said control module is disposed on said fuel spacer in said airflow.
  • 19. The integrated control and fuel delivery system of claim 18, wherein said control module is a powertrain control module.
  • 20. A method of producing an over-molded fuel spacer, comprising:placing a casting, a fuel rail and a wiring harness into an injection molding tool; and over-molding said casting, said fuel rail and said wiring harness with a glass filled nylon material.
  • 21. The method of claim 20 wherein said casting comprises aluminum.
  • 22. The method of claim 20 wherein said wiring harness comprises urethane.
  • 23. The method of claim 20 wherein said wiring harness comprises silicone.
  • 24. The method of claim 20 wherein said wiring harness further comprises a powertrain control module connector, an ignition coil connector, and a fuel injector connector.
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Entry
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