The invention generally relates to an apparatus for heating the air/fuel mixture entering the cylinders of an internal combustion engine. More particularly, the invention relates to an electric heater having a one-piece housing adapted for mounting to the air intake system of an engine.
The air/fuel mixture entering the cylinders of an internal combustion engine is commonly heated to increase fuel economy and responsiveness to starting as well as to decrease pollutant discharge. One type of intake heating device generally includes a housing or frame disposed between a fuel delivery device and an air intake manifold. Another type of intake heating device is mounted within an open cavity of an intake manifold. After this second type of heating device is mounted on the intake, the heater and intake subassembly is subsequently mounted to an engine. In the aforementioned devices, current is passed through a heating coil or grid to increase the temperature of the surrounding air as it passes into a combustion chamber of the engine.
While the aforementioned heaters generally address cold starting and fuel economy issues, other concerns remain. For example, access to the prior art heaters is obtained only after the intake manifold is removed from the engine. Retro-fitting an existing vehicle not originally equipped with a heater is similarly difficult. In addition, prior art heaters have been specifically constructed to package within a given geometry and function only with a certain power system. As a result, many heater components were proliferated in order to meet varying customer needs. Furthermore, many prior heater designs exhibit unsatisfactory vibration resistance. These heaters may not continue to properly function after being fitting to a vehicle and subjected to repeated impact loading due to road inputs as the vehicle is used.
Accordingly, in view of the above concerns as well as the manufacturer's ever present desire to reduce manufacturing costs and complexity, a need exists for a robust air heater having a one-piece housing that may be installed within a vehicle intake air system without removing the intake manifold.
The present disclosure relates to a heating device for use in an internal combustion engine having an intake defining a passage. The intake includes an opening in communication with the passage. The heating device includes a one-piece housing having a mounting flange portion and a first leg portion positioned substantially parallel to and spaced apart from a second leg portion. The mounting flange is adapted to mount to the intake and cover the opening. The heating element is coupled to the one-piece housing and positioned between the first and second leg portions. The heating element is positioned in a heat transfer relation with the passage to thereby heat air flowing through the passage.
Further areas of applicability will become apparent from the description provided herein. It should be understood that the description and specific examples are intended for purposes of illustration only and are not intended to limit the scope of the present disclosure.
The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way.
The disclosure relates to an air heating device for use in an internal combustion engine. More particularly, the heating device includes a one-piece housing that retains one or more heating elements and heating element holders in predetermined positions relative to the housing.
In addition to the above advantages, the present invention provides an air heater that is integratable into the air intake system of a diesel engine and, more particularly, within a passageway of an air intake tube. This unique configuration of the air heater, including the heater housing, provides enhanced heater durability. The design also provides improved mounting flexibility over traditional bolt-on heater designs.
The air heater of the present invention will now be described in greater detail with reference to
As best illustrated in
Wave springs 42, also preferably formed of stainless steel, are disposable within channel 32 to engage end wall 38. Thermal and electric insulators 44 are disposable within channel 32 to engage and capture springs 42 between end wall 38 and insulators 44. Those skilled in the art will appreciate that wave springs 42 urge insulators 44 away from end wall 38 and into engagement with stops 46 which extend inwardly into channel 32 from side walls 34 and 36. Insulators 44 include cavities 48 to accommodate and position heating element 28 therewithin. It is contemplated that insulators 44 may be formed of a ceramic material known in the art to provide the desired thermal and electrical insulating properties.
Second holder 26 is configured substantially similarly to first holder 24. Accordingly, like elements are enumerated to include similar reference numerals increased by 100. Those skilled in the art will appreciate that the configuration and interrelation of channel 132, side walls 134 and 136, end wall 138, tabs 140, end faces 141, wave springs 142, insulators 144, stops 146 and cavities 148 are substantially the same as the corresponding components described in relation to first holder 24.
Housing 12 includes a “U” shaped frame portion 50 integrally formed with mounting flange 14. Frame portion 50 includes a first leg 52 and a second leg 54 having ends interconnected by a third leg 56. The opposite ends of first leg 52 and second leg 54 are interconnected by flange 14. Each of first leg 52, second leg 54 and third leg 56 are shaped as substantially right rectangular parallelepipeds integrally formed with one another and mounting flange 14 to define a window 58.
First leg 52 includes a generally “C” shaped first recess 60 inwardly extending from a first face 62. First recess 60 is defined by a seat 64, a first wall 66, a second wall 68 and a third wall 70 interconnecting first wall 66 and second wall 68. Third wall 70 includes a pair of apertures 72 extending therethrough. A portion of each aperture 72 is defined by a retaining wall 74.
Second leg 54 includes a second recess 76 shaped substantially similarly to first recess 60. Second recess 76 also inwardly extends from first face 62. Second recess 76 includes a seat 78, a first wall 80, a second wall 82 and a third wall 84 interconnecting first wall 80 and second wall 82. Third wall 84 includes a pair of apertures 86 extending through second leg 54. Each aperture 86 includes a retaining wall 88.
Housing 12 is preferably constructed from materials such as aluminum A380 and ADC10 that may be die cast to form one-piece housing 12. In one embodiment, none of the exterior surfaces of housing 12 require machining. Specifically, the walls defining first recess 60 as well as the walls defining second recess 76 remain in a “net-shaped” or “as-cast” condition throughout heater assembly and use.
Alternatively, housing 12 may be constructed using a powdered metal sintering process such that first leg 52, second leg 54, third leg 56 and mounting flange are integrally formed with one another to define one-piece housing 12.
To assemble air heater 10, heater module 20 is first sub-assembled and positioned relative to housing 12 to align heater module 20 with window 58. In the free state, end wall 38 of first holder 24 is spaced apart from end wall 138 of second holder 26 a distance greater than the separation between third wall 70 of first recess 60 and third wall 84 of second recess 76. Accordingly, to position heater module 20 within window 58, a compressive force is applied to first holder 24 and second holder 26 to compress wave springs 42 and wave springs 142. During application of the compressive force, first holder 24 is axially positioned within first recess 60 while second holder 26 is axially translated into position within second recess 76.
Heater module 20 is translated within window 58 until side wall 36 of first holder 24 contacts seat 64 and side wall 136 of second holder 26 contacts seat 78. During the assembly process, tabs 40 engage third wall 70. Similarly, tabs 140 engage third wall 84. Once end faces 41 of tabs 40 clear retaining walls 74, tabs 40 enter apertures 72. End faces 141 of tabs 140 are also translated to clear retaining walls 88 to allow tabs 140 to snap into apertures 86. At this time, end walls 38, 138 are biasedly engaged with third walls 70, 84, respectively.
Once heater module 20 is coupled to housing 12 as described, movement of heater module 20 relative to housing 12 is resisted in a first direction by seats 64 and 78. Relative movement between heater module 20 and housing 12 in an opposite direction is restricted by the engagement of end faces 41 with retaining walls 74 as well as end faces 141 with retaining walls 88. Wave springs 42 and 142 provide a biasing force to ensure that tabs 40 and 140 remain positioned within apertures 72 and 86.
Air heater 10 includes a first terminal having a bolt 90a and a nut 90b and a second terminal having a bolt 92a and nut 92b. First terminal 90a is electrically insulated from housing 12 with insulators 91 while second terminal 92a is electrically coupled thereto. An electrical path is formed by connecting one lead of a power source to first terminal 90a while a second power source lead is coupled to ground which includes housing 12. In this manner, a series electrical path exists between first terminal 90a and second terminal 92a to selectively energize heating element 28.
Once assembled, air heater 10 is coupled to air intake tube 16 (
One-piece housing 202 includes a flange 204, a first leg 206, a second leg 208, a third leg 210 and a boss 212. Each of elements 204 through 212 are integrally formed with one another to define one-piece housing 202. First leg 206, third leg 210, second leg 208, boss 212 and flange 204 form a frame circumscribing a window 214. First leg 206 includes a first set of apertures 216 and a second set of apertures 218 extending therethrough. Each aperture 216 is substantially “D” shaped having a retaining wall 220. Similarly, each aperture 218 is “D” shaped having a retaining wall 222. Second leg 208 includes a first set of apertures 224 each having a retaining wall 226. A second set of apertures 228 each having a retaining wall 230 also extend through second leg 208. A first rib 232 extends along the length of first leg 206 and radially inwardly protrudes from a wall 234. A first recess 236 inwardly extends from a face 237 extending along one edge of first leg 206, third leg 210, second leg 208 and boss 212. First recess 236 is defined by a first wall 238, a second wall 240, wall 234 and a seat 242 as provided by one surface of rib 232.
A second recess 250 (
Another rib 260 radially inwardly extends from second leg 208. A third recess 262 is defined by a seat 264, a first wall 266, a second wall 268 and a third wall 270 which interconnects first wall 266 and second wall 268. Third recess 262 inwardly extends from face 237.
A fourth recess 271 is formed in second leg 208 and inwardly extends from surface 252. Fourth recess 271 is defined by a seat 272, a first wall 274, a second wall (not shown) and a third wall 276 interconnecting first wall 274 and the second wall. Apertures 228 extend through third wall 276.
Third leg 210 includes a first aperture 280 and a second aperture 282 extending therethrough for receipt of second terminals 92a and 92a′, respectively. Mounting flange 204 includes a first aperture 284 and a second aperture 286 extending therethrough for receipt of first terminals 90a and 90a′, respectively. As previously described in relation to one-piece housing 12, one-piece housing 202 may also be constructed by die casting, a powered metal sintering or any number of other metal forming processes. Furthermore, it is contemplated that each of the surfaces of one-piece housing 202 may be initially formed as “net-shaped” surfaces not requiring subsequent machining operations. First heater module 20 and second heater module 20′ include surfaces contacting the “net-shaped,” “as-cast” or “as-formed” surfaces.
In similar fashion to the assembly process described in relation to air heater 10, first heater module 20 is sub-assembled and a compressive force is added to displace first holder 24 toward second holder 26. First heater module 20 is positioned within window 214 until the first and second holders engage seats 242 and 264. At this time, end faces 41 and 141 are positioned adjacent to retaining walls 220 and 226, respectively.
Second heater module 20′ is coupled to one-piece housing 202 in a similar manner. Once second heater module 20′ is properly positioned within window 214, end faces 41′ and 141′ are positioned within apertures 228 and 218 and adjacent to retaining walls 230 and 222, respectively. Therefore, both first heater module 20 and second heater module 20′ are coupled to one-piece housing 202 such that relative movement between the heater modules and the housing is restricted.
The heater embodiment depicted in
Furthermore, the foregoing discussion discloses and describes merely exemplary embodiments of the present invention. One skilled in the art will readily recognize from such discussion, and from the accompanying drawings and claims, that various changes, modifications and variations may be made therein without department from the spirit and scope of the invention as defined in the following claims.
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20070193562 A1 | Aug 2007 | US |