The invention relates generally to an electronic throttle body having an integrally formed anti-rotation feature, where the anti-rotation feature is formed during a molding or casting process, and without the use of any additional machining processes.
Electronic throttle bodies are generally known, and it is typical for a duct or conduit to be connected to and in fluid communication with the throttle body for directing air into the throttle body, where the throttle body controls the flow of the air into an engine. The conduit is commonly connected to the throttle body through the use of a connector, and the conduit is prevented from rotating relative to the throttle body by some type of anti-rotation feature, which is engaged with the conduit.
Typical throttle bodies have parts which are made as a single component, but certain parts that are formed as part of the throttle body are more complex, and expensive to manufacture. Some of the parts of the throttle body are formed using a casting process, and others are formed using various machining processes. Additional machining processes increase cost, and require additional steps during manufacturing. Some throttle bodies have an anti-rotation feature which is formed during subsequent manufacturing processes, such as machining, or the anti-rotation feature is formed as part of one of several separate components of the throttle assembly, which are assembled together. The use of the subsequent manufacturing processes, or manufacture of several components, increases costs, manufacturing time, and increases the overall complexity of manufacturing the throttle body assembly. Furthermore, throttle body assemblies made of several components assembled together are typically unable to meet stringent packaging requirements.
Accordingly, there exists a need for a throttle body which is simpler to manufacture, and includes an anti-rotation feature that is formed without the use of additional machining processes.
In one embodiment, the present invention is a throttle control assembly which includes a housing, an adapter integrally formed with the housing, an anti-rotation feature integrally formed with the housing and the adapter, and a scallop. The scallop substantially surrounds the anti-rotation feature, and the anti-rotation feature and the scallop are integrally formed with the housing and the adapter during a molding process.
In an embodiment, a housing portion is part of the adapter, and the throttle control assembly includes a central port. Part of the central port extends through the housing portion of the adapter, and part of the central port extends through the housing.
A first groove is integrally formed as part of the adapter, a second groove is integrally formed as part of the housing, and a rib portion is disposed between the first groove and the second groove. The rib portion is formed as part of the adapter, the first groove and the rib portion substantially circumscribe the adapter, and the second groove partially circumscribes the housing.
In an embodiment, a lower wall portion is integrally formed as part of the housing, such that the lower wall portion is adjacent the scallop, and the second groove terminates into the lower wall portion.
A first end of the first groove is adjacent a portion of the scallop, and a second end of the first groove is adjacent a portion of the scallop.
In an embodiment, a portion of the scallop is integrally formed as part of the housing, and a portion of the scallop is integrally formed as part of the adapter.
The anti-rotation feature may be formed using one of several processes. In one embodiment, the scallop is integrally formed with the housing and the adapter during a casting process. In another embodiment, the scallop is integrally formed with the housing and the adapter during a metal injection molding process.
Further areas of applicability of the present invention will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.
The present invention will become more fully understood from the detailed description and the accompanying drawings, wherein:
The following description of the preferred embodiment(s) is merely exemplary in nature and is in no way intended to limit the invention, its application, or uses.
An electronic throttle control assembly having an integrally formed anti-rotation feature according to the present invention in shown in the Figures generally at 10. The assembly 10 includes a throttle body housing 12, and formed as part of the housing 12 is a central port, shown generally at 14, through which air passes during operation of the assembly 10. There is a shaft (not shown) which extends through part of the central port 14, where the shaft is rotatable, and mounted to the shaft is a valve plate (also not shown).
The shaft is mounted in a bore 16 formed as part of the housing 12. The housing 12 also includes a cavity, shown generally at 18, and disposed in the cavity 18 is an actuator (not shown). The actuator is used for controlling a gear assembly, which is then connected to the shaft, thereby controlling the position of the valve plate in the central port 14. Changing the position of the valve plate controls the flow of air through the central port 14.
The assembly 10 also includes an adapter, shown generally at 20, where the adapter 20 is suitable for connection with a conduit. The adapter 20 includes a housing portion 22, and formed as part of the housing portion 22 is an aperture 24, which forms part of the central port 14, and is of a substantially constant inner diameter. The remaining part of the central port 14 is formed as part of and extends through the housing 12. The housing portion 22 also includes a first diameter portion 26 which is adjacent a first tapered portion 28. The housing portion 22 also has a second tapered portion 30 which is adjacent the first diameter portion 26. Each of the tapered portions 28,30 facilitate the connection between a conduit and the throttle control assembly 10.
Adjacent the second tapered portion 30 is a first groove 32, adjacent the first groove 32 is a rib portion 34, and adjacent the rib portion 34 is a second groove 36. Integrally formed with the housing 12 and the adapter 20 is an anti-rotation feature 38, which protrudes from the housing 12, and is adjacent the housing portion 22.
During assembly, the housing portion 22 is inserted into an end portion of the conduit, and the tapered portions 28,30 and anti-rotation feature 38 provide proper alignment between the housing portion 22 and the conduit during the assembly process at the facility where the throttle control assembly 10 is manufactured.
Integrally formed with the housing 12 and the adapter 20 is a scallop, shown generally at 40. Part of the scallop 40 is adjacent a first end 42A of the first groove 32, and a first end 44A of the rib portion 34. Part of the scallop is also adjacent a second end 42B of the first groove 32, and a second end 44B of the rib portion 34. An end portion 46 of the second groove 36 also terminates into a lower wall 62, which is adjacent a portion of the scallop 40. The grooves 32,36 and rib portion 34 are also used for connecting the conduit to the assembly 10. The grooves 32,36 are able to receive a snap ring, clip, or some other type of connecting device for securing the conduit to the assembly 10.
The throttle control assembly 10 is formed using various manufacturing processes. The housing 12, second groove 36, anti-rotation feature 38, and scallop 40 are formed during a casting process.
Once the casting process is complete, various portions of the throttle control assembly 10 have yet to be formed. A machining process is then used to form the housing portion 22, the first groove 32, and the rib portion 34. The scallop 40 provides adequate space which allows for various tooling to be used as part of the machining process to form the housing portion 22, the first groove 32, and the rib portion 34. The second groove 36 partially circumscribes the housing 12, and the first groove 32 and the rib portion 34 almost completely circumscribe the housing portion 22, with the exception of the areas occupied by the anti-rotation feature 38 and the scallop 40.
The second groove 36 (formed during the casting process) does not entirely circumscribe the housing 12. An outer portion 48 partially circumscribes the housing 12 in an area along the outside of the housing 12 (where the second groove 36 was not formed during the casting process), such that the outer portion 48 is adjacent a part of the rib portion 34 in a similar manner to the second groove 36. The outer portion 48 is formed during the machining process along with the housing portion 22, the first groove 32, and the rib portion 34. Part of the outer portion 48 extends along the outside of the housing 12 in an area where the portion having the cavity 18 is integrally formed with the housing 12. Another part of the outer portion 48 also extends along the outside of the housing 12 along an area where a gear housing 50 is integrally formed with the housing 12.
An axis 52 extends through the central port 14, and the anti-rotation feature 38 may be formed during the casting process at many possible locations along the outer surface of the housing 12.
The anti-rotation feature 38 being formed during the casting process, and the entire throttle control assembly 10 being formed as a single component, reduces the number of steps in the manufacturing process of the throttle control assembly 10, reducing manufacturing cost. Furthermore, during the casting process, the anti-rotation feature 38 may be formed along the line of draw within the die cast tool, such that the shape of the anti-rotation feature 38 does not have an effect on the removal of any tool inserts, tool sliders, or the separation of the mold components once the casting process is complete.
Furthermore, the dimensions of the anti-rotation feature 38 may be varied to be suitable for various packaging and design requirements, as well as different types of conduits having different connecting devices.
While it has been described above that the housing 12, second groove 36, anti-rotation feature 38, and scallop 40 are formed during a casting process, it is within the scope of the invention that these components may be formed during other types of processes as well, such as, but not limited to, metal injection molding and 3D printing.
The description of the invention is merely exemplary in nature and, thus, variations that do not depart from the gist of the invention are intended to be within the scope of the invention. Such variations are not to be regarded as a departure from the spirit and scope of the invention.
This application claims the benefit of provisional application 62/638,648, filed Mar. 5, 2018. The disclosure of the above application is incorporated herein by reference.
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62638648 | Mar 2018 | US |