A fuel injector used to inject fuel into an internal combustion engine may include a valve housing that supports an injector valve, and a magnetic coil that surrounds the valve housing and is used to actuate the valve. The magnetic coil is controlled by a controller that is remote from the fuel injector. The fuel injector includes bus bars that are electrically connected at one end to the magnetic coil, and at an opposed end provide an electrical connection to controller. In some fuel injectors, a plastic overmold is used to support the bus bars relative to the valve housing, and to seal the bus bar from the environment. Since a clip is used to support the bus bars relative to the valve housing during the overmolding process, the overmold may not provide a complete seal between the bus bars and the valve housing. That is, in some fuel injectors there is a chance of leakage of the environment into the injector and/or around the bus bars in the vicinity of the clip. In some fuel injectors, the clip has been provided with a labyrinth seal intended to minimize or eliminate leakage. However, the labyrinth seal provided on the clip is effective under specific over-molding process conditions that may not apply to all fuel injectors. For example, the labyrinth seal provided on the clip may not be effective for some relatively short fuel injectors for reasons related to manufacturing, such as location and orientation of injection of plastic for the overmold of a relatively short fuel injector. In addition, although it is known that an effective seal can be obtained when the tip of the labyrinth is sharp, a labyrinth having a tip that is sharp is difficult to realize from a molding process perspective. Still further, to avoid a damage of the labyrinth during handling and/or transportation, additional measures are required which add cost and complexity to the manufacturing process. Thus, it is desirable to provide a fuel injector having an overmold that supports a bus bar and is leak free regardless of fuel injector size. It is also desirable to provide a clip that secures a bus bar to the fuel injector housing that facilitates formation of the leak free overmold.
In some aspects, a terminal blade for a fuel injector includes include a valve housing that supports an injector valve, and a magnetic coil that surrounds the valve housing and is configured to actuate the valve. The terminal blade is configured to provide an electrical connection between the magnetic coil and an electrical connector. The terminal blade includes an electrically conductive bus bar that is configured to form an electrical connection with the electrical connector and the magnetic coil; and a clip that is connected to the bus bar at a clip first end and to the valve housing at a clip second end. The clip includes a sacrificial portion. The sacrificial portion is configured to part when the terminal blade undergoes an overmolding process in such a way that the clip is separated into multiple portions.
In some embodiments, the sacrificial portion is configured to dissolve when the terminal blade undergoes an overmolding process. In other embodiments, the sacrificial portion is configured to break when the terminal blade undergoes an overmolding process.
In some embodiments, the sacrificial portion is disposed between the clip first end and the clip second end.
In some embodiments, the clip includes an elongate body having a body first end that is secured to the bus bar and a body second end that is opposed to the body first end. The body first end corresponds to the clip first end. The clip includes an elastic portion that is configured to encircle a portion of the valve housing, the elastic portion corresponding to the clip second end. In addition, the clip includes a bridge that connects the body second end to the elastic portion. One of the body and the bridge includes the sacrificial portion.
In some embodiments, the body includes a body mid portion disposed between the body first end and the body second end. The body mid portion includes the sacrificial portion.
In some embodiments, the sacrificial portion is a single connecting structure having a cross sectional dimension that is in a range of 0.2-0.5 times the cross sectional dimension of the body.
In some embodiments, the sacrificial portion includes at least two connecting structures, and cross sectional dimensions of each of the at least two connecting structures have a range of 0.2-0.5 times a cross sectional dimension of the body.
In some embodiments, the sacrificial portion comprises a first connecting structure and a second connecting structure that is spaced apart from the first connecting structure. Each of the first connecting structure and the second connecting structure extends in parallel to a clip body longitudinal axis and providing a mechanical connection between the first end and the second end.
In some embodiments, the bridge comprises the sacrificial portion.
In some embodiments, the bridge has a dimension in a direction parallel to a longitudinal axis of the valve housing that is less than a dimension of the elastic portion in a direction parallel to the longitudinal axis of the valve housing.
In some embodiments, the bridge, including the sacrificial portion, is connected to the elastic portion along an edge of the elastic portion.
In some embodiments, body includes a body longitudinal axis that extends between the body first end and the body second end. The body is elongated along a body longitudinal axis. The body longitudinal axis extends in parallel to a longitudinal axis of the valve housing, and the bridge extends in a direction perpendicular to the body longitudinal axis.
In some embodiments, the bus bar has a bus bar first end and a bus bar second end, and the clip body first end is fixed to the bus bar at a location that is disposed between the bus bar first end and the bus bar second end.
In some embodiments, the clip comprises two sacrificial portions.
In some aspects, a fuel injector assembly includes a valve housing; and a valve stem that is disposed in the valve housing and moveable relative to an inner surface of the valve housing along a valve housing longitudinal axis. The fuel injector assembly includes a magnetic coil that surrounds the valve housing and is used to actuate the valve stem; and a terminal blade that is configured to provide an electrical connection between the magnetic coil and an external connector. The terminal blade includes an electrically conductive bus bar that is configured to form an electrical connection with the external connector and the magnetic coil; and a clip that is connected to the bus bar at a clip first end and to the valve housing at a clip second end. The clip includes a sacrificial portion. The sacrificial portion is configured to part, for example by dissolving or breaking, when the terminal blade undergoes an overmolding process in such a way that the clip is separated into multiple portions.
In some embodiments, the clip includes an elongate body having a body first end that is secured to the bus bar and a body second end that is opposed to the body first end. The body first end corresponds to the clip first end. The clip includes an elastic portion that is configured to encircle a portion of the valve housing, the elastic portion corresponding to the clip second end, and a bridge that connects the body second end to the elastic portion. One of the body and the bridge includes the sacrificial portion.
In some embodiments, the body includes a body mid portion disposed between the body first end and the body second end. The body mid portion includes the sacrificial portion.
In some embodiments, the bridge comprises the sacrificial portion.
In some embodiments, the clip comprises two sacrificial portions.
In some embodiments, the fuel injector assembly includes an overmold that encases the clip and a portion of the bus bar. The overmold and the clip are formed of the same material.
In some embodiments, the fuel injector assembly includes an overmold that encases the clip and a portion of the bus bar. The overmold is formed of a first material, and the clip is formed of a second material. A melting temperature of the second material is less than or equal to a melting temperature of the first material.
In some aspects, a method of manufacturing a fuel injector is disclosed. The method includes the following method steps: Providing a partially assembled fuel injector that includes a valve housing, a valve stem movable within the valve housing and a magnetic coil surrounding the valve housing; Providing a terminal blade that comprises: an electrically conductive bus bar that is configured to form an electrical connection with an electrical connector and the magnetic coil; and a clip that is connected to the bus bar at a clip first end and to the valve housing at a clip second end, the clip including a sacrificial portion, the sacrificial portion configured to part, for example by dissolving, when the terminal blade undergoes an overmolding process; Securing the terminal blade to the valve housing using the clip; Electrically connecting the bus bar to the magnetic coil; and Overmolding portions of the terminal blade and the valve housing with a plastic coating in such a way that the portions are encased and the sacrificial portion is parted.
In some embodiments, the step of overmolding portions of the terminal blade and the valve housing includes using an injection molding process to encase the portions in a plastic coating, and the plastic coating and the clip are formed of the same material.
In some embodiments, the step of overmolding portions of the terminal blade and the valve housing includes using an injection molding process to encase the portions in a plastic coating. The plastic coating is formed of a first material, the clip is formed of a second material, and a melting temperature of the second material is less than or equal to a melting temperature of the first material.
In some embodiments, the step of overmolding portions of the terminal blade and the valve housing with a plastic coating comprises injecting a plastic into a mold that surrounds a portion of the fuel injector including the clip, and a direction of injection of the plastic into the mold is perpendicular to a longitudinal axis of the valve housing.
In some aspects, a terminal blade for a fuel injector assembly includes a sacrificial portion that melts, dissolves or otherwise is removed during the manufacturing process step of applying an overmold to the fuel injector assembly. As a result, the overmold, which supports the bus bar relative to the fuel injector housing and provides an electrical connector housing, also forms a leak-free seal with respect to the valve housing of the fuel injector, whereby moisture is prevented from contacting the bus bar.
A method of manufacturing a fuel injector using a terminal blade having a sacrificial portion is also described.
In some aspects, a self-supporting electrical conductor includes an electrically conductive element that is configured to electrically connect a first electrical component to a second electrical component, and a clip that is configured to support the element relative to a device. The clip includes a clip first end that is connected to the element, a clip second end is configured to mount on the device, and a sacrificial portion disposed between the clip first end and the clip second end. An overmold encapsulates at least a portion of the clip and the element. In addition, the sacrificial portion is configured to part, for example by dissolving or breaking, when the self-supporting electrical conductor undergoes an overmolding process to provide the overmold, the parting occurring in such a way that the clip is separated into multiple portions.
Referring to
The valve housing 4 is an elongate, generally tubular structure. A first end 6 of the valve housing 4 provides a fuel connection nipple 10, and a second, opposed end 8 of the valve housing 4 provides a valve seat 12 and opening (not shown). An inner surface of the valve housing 4 defines a fuel duct 14 that extends between the fuel connection nipple 10 and the valve seat 12.
The solenoid 16 includes a magnetic coil 18 wound on a coil brace, and a magnetic sleeve 20 that surrounds the magnetic coil 18. The magnetic sleeve 20 is fixed to an outer surface of the valve housing 4 at a location disposed between the connection nipple 10 and the valve opening provided in the valve seat 12. An armature 24 is moveable in reaction to the magnetic coil 18 along the longitudinal axis 38 of the valve housing 4 and is permanently connected to a valve needle 26, which in turn is connected to the ball 9a of the valve 9.
The overmold 40 is formed of an electrically insulating material such as plastic, and includes an annular portion 42 that encircles a circumference of the valve housing 4 at a location between the magnetic sleeve 20 and the connection nipple 10, and a connector portion 44 that protrudes outward from the annular portion 42. The connector portion 44 includes a shroud 46 that surrounds a first end 68 of the bus bar 62, and is configured to receive the external connector therein. When the external connector is received within the connector shroud 46, an electrical connection is provided between the magnetic coil 18 and an electronic control unit (not shown). The electronic control unit controls the magnetic coil 18, and thus also controls fuel distribution from the fuel injector 2.
Referring to
The clip 80 is free of a labyrinth seal and includes an elongate body 82 that is secured to the bus bar 62, an elastic portion 100 that forms a mechanical connection with the valve housing 4, and a bridge 120 that extends between, and mechanically connects, the body 82 to the elastic portion 100.
The clip body 82 has a generally cylindrical shape and includes a body first end 84, and a body second end 86 that is opposed to the body first end 84. The body first end 84 is also referred to herein as the clip first end. The body 82 includes body mid portion 88 that is disposed between the body first end 84 and the body second end 86. In addition, the body 82 includes a longitudinal axis 90 that passes through the body first end 84, the body mid portion 88 and the body second end 86. The body first end 84 is overmolded onto the mid portion 72 of the bus bar 62 at a location adjacent to the second bend 76. The body first end 84 is overmolded onto the bus bar 62 in such a way that the body 82 is fixed to the bus bar mid portion 72, and the bus bar mid portion 72 extends in a direction that is perpendicular to the body longitudinal axis 90. In this configuration, the bus bar first end 68 overlies the body 82 and is angled relative to the body longitudinal axis 90. In addition, the bus bar second end 70 protrudes in a direction away from the body 82 in a direction that is generally parallel to the body longitudinal axis 90.
The elastic portion 100 is an arcuate band 102 that encircles a portion of the circumference of the valve housing 4. The band 102 includes a first end 104, a second end 106, and a mid portion 108 disposed between the first and second ends 104, 106. The elastic portion 100 has elastic properties, extends over an arc length that is greater than 180 degrees and less than 270 degrees, and is dimensioned to grip the outer surface of the valve housing 4. By this configuration, the clip 80 is elastically retained in a desired position relative to the valve housing 4. At each of the first and second ends 104, 106, the outward-facing surface 110 of the band 102 includes a protrusion 112 that provides a key that engages with the overmold 40. The elastic portion 100 is also referred to herein as the clip second end.
The bridge 120 is a rigid structure that extends, and provides a mechanical connection, between the elastic portion mid portion 108 and the body second end 86. The bridge 120 includes a first end 122 that is joined to the body 82, a second end that is joined to the elastic portion 100 and a mid portion 126 that is disposed between the bridge first end 122 and the bridge second end 124. The bridge 120 is formed integrally with the elastic portion 100 and the body 82, and extends in a direction perpendicular to the body longitudinal axis 90. As a result, the bridge 120 serves to offset the body 82 from the valve housing 4 in a direction that is perpendicular to the valve housing longitudinal axis 38. In other words, the bridge 120 serves to offset the body 82 from the valve housing 4 in a direction that is radially outward relative to an outer surface of the valve housing 4.
The bridge 120 is generally rectangular in shape, and has a length dimension that extends in parallel with the body longitudinal axis 90, a height dimension that extends perpendicular to the body longitudinal axis 90 and parallel to a radius of the valve housing 4, and a width dimension that extends perpendicular to the body longitudinal axis 90 and the radius of the valve housing 4. When the clip 80 is viewed in a side view (e.g., in the direction of arrow 48 of
In the illustrated embodiment, the clip 80 and the brace 78 are formed of the same material, for example, an insulating material such as plastic, whereas the pins 64, 64 are formed of an electrically conductive material such as metal.
The clip 80 of the terminal blade 60 is used to hold the bus bar 62 in a desired orientation and position relative to the valve housing 4 during a manufacturing step that precedes the overmolding step in which the overmolding is applied to the valve housing 4. For example, in some embodiments, the clip 80 supports the bus bar 62 during a welding step of the injector manufacturing process in which the bus bar second end 70 is welded to the magnetic coil 18. Once the weld has been achieved, the position of the bus bar 62 is fixed relative to the fuel injector 2 and the clip 80 is no longer required. In recognition of the fact that the clip 80 is not required for positioning and stabilization of the bus bar 62 following the welding step, the clip 80 includes the sacrificial portion 50 that parts during the process of forming the overmold 40. In this embodiment, the sacrificial portion dissolves during the process of overmolding. Since the sacrificial portion 50 dissolves during the overmolding process, the clip 80 is separated into a bus bar portion 61 and a clip portion 81 (
In the embodiment illustrated in
In some embodiments, the sacrificial portion 50 is a rigid rod 92 of uniform diameter that extends between, and physically connects, the body first end 84 and the body second end 86. Shoulders 96, 98 are disposed at the transition in diameter between the sacrificial portion 50 and the respective body first and second ends 84, 86. In other embodiments, the transition between the sacrificial portion 50 and the respective body first and second ends 84, 86 may be rounded. In the illustrated embodiment, the sacrificial portion 50 is concentric with the clip body 82.
The diameter of the sacrificial portion 50 is set so that during the process of overmolding, the sacrificial portion 50 dissolves and/or is otherwise severed due to the temperature and/or mass flow of the plastic used to form the overmold 40 as it is injected under high pressure in the vicinity of the terminal blade 60.
Referring to
Referring to
Referring to
After the terminal blade 60 is secured to the valve housing 4, the method includes electrically connecting the bus bar 62 to the magnetic coil 18 (step 206). For example, in some embodiments, the second end 70 of each pin 64, 66 is welded to a portion of the magnetic coil 18. As previously discussed, once the weld has been made, the position of the bus bar 62 is fixed relative to the fuel injector 2 and the clip 80 is no longer required.
Following the step of electrically connecting the bus bar 62 to the magnetic coil 18, portions of the terminal blade 60 and the valve housing 4 are overmolded with a plastic coating (step 208). As a result of this step, the plastic overmold 40 is formed on the valve housing 4. In particular, the annular portion 42 surrounds a circumferences of the valve housing 4 at a location adjacent to the solenoid 16 in such a way that the bus bar second end 70 including the weld and the bus bar mid portion 72 are encased in plastic. The bus bar first end 68 is exposed, but is surrounded by the shroud 46 of the connector portion 44. In addition, the entire clip 80 is encased in the annular portion of plastic coating.
In some embodiments, the overmold is achieved using an injection molding process. During the injection molding process, the plastic used to form the overmold 40 is injected into an overmold tool (not shown) that surrounds the valve housing 4 and terminal blade 60. The plastic is molten and injected under high pressure into the overmold tool in a direction perpendicular to the valve housing longitudinal axis 38 at a location that is generally aligned with the clip body 82 and/or bridge 120. Thus, during plastic injection, molten plastic flows toward and then around the clip 80. In the illustrated embodiment, the material used to form the clip 80 is the same as the material used to form the overmold 40, whereby the melting temperature of the clip 80 is the same as the melting temperature of the overmold 40. The presence of the molten overmold plastic as it is injected around the body mid portion 88 results in melting of the sacrificial portion 50. In addition, flow of the high pressure injected material exerts pressure against the sacrificial portion 50 that facilitates its dissolution. As a result of the dissolution of the sacrificial portion 50, the clip 80 is divided into two separate portions 61, 81. The space previously occupied by the sacrificial portion 50 becomes occupied by the overmold material, allowing the overmold 40 to effectively encase portions of the bus bar 62 and the valve housing 4, and seal the bus bar 62 from the environment.
The results of the dissolution of the sacrificial portion 50, 150 of the terminal blade 60, 160 are schematically illustrated in
The results of the dissolution of the sacrificial portion 250 of the terminal blade 260 are schematically illustrated in
Although in the illustrated embodiment, the plastic material used to form the overmold 40 is the same plastic material that is used to form the clip 80, the fuel injector 2 is not limited to this configuration. For example, in some embodiments, the overmold 40 is formed of a first material and the clip 80 is formed of a second material. The melting temperature of the second material is less than or equal to the melting temperature of the first material to facilitate melting of the sacrificial portion 50 during the overmolding step. When the melting temperature of the second material used to form the clip 80 is less than the melting temperature of the first material used to form the overmold 40, it is advantageous to form the brace 78 of a material that is the same as the first material or has a melting temperature that is higher than that of the first material.
Although in the illustrated embodiments, the clip 80 includes a single sacrificial portion 50, 150, 250, which may be disposed at either at the body 82 or the bridge 120, it is contemplated that the clip 80 may include more than one sacrificial portion, for example including a sacrificial portion at each of the body 82 and the bridge 120. Moreover, the location of the sacrificial portion 50, 150, 250 is not limited to a mid portion 88 of the clip body 82 or the mid portion 126 of the bridge 120. Instead, the sacrificial portion 50, 150, 250 may be located anywhere along the clip 80 as long as the sacrificial portion 50, 150, 250 does not contact the bus bar 62. The position and geometry of the sacrificial portion 50, 150, 250 are determined by the overmold tool and the final overmold process.
Although the terminal blade having a sacrificial portion is illustrated herein with respect to providing an electrical connection between the solenoid and an external connector of a fuel injector, the terminal blade is not limited to this application. For example, in some embodiments, a self-supporting electrical conductor may be used to provide an electrical connection. In particular, the self-supporting electrical conductor includes an electrically conductive element that is configured to electrically connect a first electrical component to a second electrical component. The self-supporting electrical conductor includes a clip that is configured to support the element relative to a device. The clip has a sacrificial portion disposed between the opposed ends of the clip. In addition, the self-supporting electrical conductor has an overmold that encapsulates at least a portion of the clip and the element. As in the previous embodiments, the sacrificial portion is configured to part when the self-supporting electrical conductor undergoes an overmolding process to provide the overmold, and the parting occurs in such a way that the clip is separated into multiple portions.
Selective illustrative embodiments of the fuel injector assembly including the terminal blade and the method of manufacturing the fuel injector are described above in some detail. It should be understood that only structures considered necessary for clarifying certain features of the assembly and method have been described herein. Other conventional structures, and ancillary and auxiliary components of the assembly and method are assumed to be known and understood by those skilled in the art. Moreover, while working examples of the assembly and method have been described above, the assembly and method are not limited to the working examples described above, but various design alterations may be carried out without departing from the terminal blade, fuel injector assembly and method as set forth in the claims.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2020/085192 | 12/9/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2021/122188 | 6/24/2021 | WO | A |
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Entry |
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International Search Report corresponding to International Patent Application No. PCT/EP2020/085192, mailed Feb. 24, 2021 (4 pages). |
Number | Date | Country | |
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20230011415 A1 | Jan 2023 | US |
Number | Date | Country | |
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62949530 | Dec 2019 | US |