A portable electronic device may have a sealed connector secured within a device housing. The sealed connector may have a metal shell. A plastic contact housing may be insert molded within the shell. conductive signal contacts may be laterally spaced in the contact housing. An elastomeric gasket may be assembled or compression molded onto the metal shell. Left and right metal brackets may be welded onto the metal shell to moisture-seal latch windows. A water-resistant sealing layer may be attached to the bottom plate of the metal shell to moisture-seal alignment rail windows. The sealed connector may be pressed against the device housing to place the gasket in a compressed state. The connector may be secured to the device housing by screwing down the metal brackets to a circuit board assembled within the housing while the gasket is in the compressed state.
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9. A connector, comprising:
a metal shell having top and bottom plates that are connected by left and right side portions, wherein the bottom plate of the metal shell has at least one through-hole; and
a flexible sheet of polymer attached to the bottom plate that moisture-seals the at least one through-hole.
1. A connector, comprising:
a metal shell, wherein the metal shell has top and bottom plates that are connected by left and right side portions, wherein the left side portion has a left latch hole, and wherein the right side portion has a right latch hole; and
left and right sealing structures that are attached respectively to the left and right side portions, wherein the left and right sealing structures each have a protruding portion that forms a cup and wherein the left and right sealing structures respectively moisture-seal the left and right latch holes.
15. A connector comprising:
a metal shell;
an insert molded plastic contact housing within the metal shell;
a plurality of conductive signal contacts that are insert molded into the plastic contact housing, wherein a left side portion of the metal shell has a left latch hole and wherein a right side portion of the metal shell has a right latch hole; and
left and right sealing structures that are attached respectively to the left and right side portions, wherein the left and right sealing structures each have a protruding portion that forms a cup and wherein the left and right sealing structures respectively moisture-seal the left and right latch holes.
2. The connector defined in
3. The connector defined in
5. The connector defined in
6. The connector defined in
7. The connector defined in
8. The connector defined in
a substantially rectangular compression molded gasket on the metal shell.
11. The connector defined in
12. The connector defined in
13. The connector defined in
14. The connector defined in
a substantially rectangular compression molded gasket on the metal shell.
16. The connector defined in
17. The connector defined in
18. The connector defined in
a sheet of polymer attached to the bottom plate that moisture-seals the alignment rail windows.
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This relates generally to sealed connectors, and more particularly, to moisture-sealed connectors for electronic devices such as portable electronic devices.
Handheld electronic devices and other portable electronic devices are becoming increasingly popular. Examples of handheld devices include handheld computers, media players, cellular telephones, and hybrid devices that include the functionality of multiple devices of this type.
Portable electronic devices such as handheld electronic devices may contain complex electronic circuitry in a compact area. Electronic components such as memory, processors, and other circuits are highly sensitive to moisture. Too much moisture can create unintended low resistance connections between nodes that are meant to be at different voltages making the circuits perform unpredictably or malfunction. Circuits may also be adversely affected by exposure to dust or other contaminants. Because portable electronic devices may not always be operated in a controlled environment, they may be more prone to be exposed to moisture, dust, or other contaminants than stationary electronic devices.
Portable electronic devices often have connectors that can mate with external mating connectors. A connector in a conventional portable electronic device may be constructed by pressing pins into holes in a plastic contact housing. The plastic contact housing is then fit into a stainless steel shell. The plastic housing with the stainless steel shell can be mounted within a port opening in the housing of the portable electronic device. A conventional connector formed in this way has multiple junctions that are not fully sealed. This is because the interfaces in these junctions are only held in contact with each other by a friction fit. Friction-fit junctions allow liquids and other contaminants to intrude into the interior of the housing.
One friction-fit junction that may be present is the interface between the connector pins and the plastic contact housing. Another friction-fit junction that may be present is the interface between the plastic contact housing and the stainless steel shell. Yet another friction-fit junction that may be present is the interface between the stainless steel shell and the housing of the portable electronic device. The stainless steel shell has male plug latch windows (holes) and alignment rails that are used to form a connection with the external mating connector. The process of forming the alignment rails creates alignment rail windows (holes). The friction-fit interfaces, the latch windows, and the alignment rail windows are not sealed and represent possible conduits through which undesirable moisture and debris can infiltrate the portable electronic device.
It would therefore be desirable to be able to provide electronic devices with connectors that can more effectively prevent moisture infiltration.
Electronic devices may be provided with sealed connectors. A moisture-sealed connector can help prevent moisture infiltration into a device interior.
A portable electronic device may have a sealed connector that is used as a data port. The sealed connector may be adapted to connect to a mating connector such as a plug on a cable or accessory. The connector may have contact leads (“contacts”). A shot of thermoplastic material may be injected within a metal shell using an insert molding process to form a plastic contact housing that is molded around the contact leads. There may be multiple (e.g., 30) laterally spaced contacts in a connector. The interface between the metal shell and the thermoplastic contact housing is sealed by mechanical bonds.
In one suitable arrangement, a U-shaped silicone gasket may be assembled on the metal shell to seal top and side portions of the metal shell. Pressure sensitive adhesive (PSA) may be applied to a bottom plate of the metal shell to attach the sealed connector to the device housing.
In another suitable arrangement, a silicone gasket may be used to seal the top, bottom, and side portions of the metal shell. The silicone gasket may be molded directly onto the metal shell using a compression molding process and may have the shape of a rectangular ring.
The sealed connector may have latch windows. The latch windows may be sealed using metal brackets with corresponding latch cups that are welded directly to the metal shell. The latch windows may also be sealed using elastomeric sealing members (e.g., the sealing members may be integral parts of a U-shaped silicone gasket).
The sealed connector may have alignment rail windows. The alignment rail windows may be sealed by attaching a water-resistant sealing layer to the bottom plate of the metal shell to seal the alignment rail windows against moisture.
The connector may be mounted within a device housing. When assembled, the sealing member in the connector may press against the walls of the device housing to compress the gasket and to seal the interface between the connector and the device housing.
A printed circuit board within the device may have screw holes. The connector may have left and right metal brackets. The left and right metal brackets may have screw holes that correspond to the screw holes in the circuit board. Corresponding screws may be inserted into the screw holes to secure the sealed connector within the device housing while the gasket is in a compressed state.
Further features of the connector, its nature and various advantages will be more apparent from the accompanying drawings and the following detailed description.
The present invention relates to sealed connectors for electronic devices.
The electronic devices may be portable electronic devices such as laptop computers or small portable computers of the type that are sometimes referred to as ultraportables. Portable electronic devices may also be somewhat smaller devices. Examples of smaller portable electronic devices include wrist-watch devices, pendant devices, headphone and earpiece devices, and other wearable and miniature devices. With one suitable arrangement, the portable electronic devices may be wireless electronic devices.
The wireless electronic devices may be, for example, handheld wireless devices such as cellular telephones, media players with wireless communications capabilities, handheld computers (also sometimes called personal digital assistants), remote controllers, global positioning system (GPS) devices, and handheld gaming devices. The wireless electronic devices may also be hybrid devices that combine the functionality of multiple conventional devices. Examples of hybrid portable electronic devices include a cellular telephone that includes media player functionality, a gaming device that includes a wireless communications capability, a cellular telephone that includes game and email functions, and a portable device that receives email, supports mobile telephone calls, has music player functionality and supports web browsing. These are merely illustrative examples.
An illustrative portable electronic device in accordance with an embodiment of the present invention is shown in
Device 10 may have device housing 12. Device housing 12, which is sometimes referred to as a case, may be formed from any suitable materials including, plastic, glass, ceramics, metal, or other suitable materials, or a combination of these materials.
Device housing 12 may have a display such as display 14 that is formed on a top face of housing 12. Display 14 may be a liquid crystal display (LCD), an organic light emitting diode (OLED) display, an electronic ink display, or any other suitable display. The outermost surface of display 14 may be formed from one or more plastic or glass layers.
In the example of
If desired, touch screen functionality may be integrated into display 14 or may be provided using a separate touch pad device. Display screen 14 is merely one example of an input-output device that may be used with electronic device 10. If desired, electronic device 10 may have other input-output devices. Suitable user input interface devices for electronic device 10 include buttons (e.g., alphanumeric keys, power on-off, power-on, power-off, and other specialized buttons, etc.), a touch pad, pointing stick, or other cursor control device, a microphone for supplying voice commands, or any other suitable interface for controlling device 10. For example, electronic device 10 may have user input interface devices such as touch pad 16 and button 18. In one suitable arrangement, touch pad 16 may surround button 18 (see, e.g.,
A user of electronic device 10 may supply input commands using user input interface devices such as touch screen 14, touch pad 16, and button 18. Although shown as being formed on the top face of electronic device 10 in the example of
Device 10 may have audio and video jacks (e.g., jack 20) that allow device 10 to interface with external components.
Data ports in device 10 such as port 22 may include power pins to recharge a battery within device 10 or to operate device 10 from a direct current (DC) power supply, data pins to exchange data with external components such as a personal computer or peripheral, audio-visual jacks to drive headphones, a monitor, or other external audio-video equipment. Port 22 may be used as an input-output port (e.g., when connecting device 10 to a mating dock connected to a computer or other electronic device). Port 22 may have a sealed connector such as moisture-sealed data port connector 24. Connector 24 may be a 30-pin data port female connector (e.g., a jack) that receives a mating 30-pin data port male connector (e.g., a plug). Port 22 and sealed connector 24 may sometimes be referred to as a dock connector. Connector 24 may be sealed (e.g., moisture-sealed) sufficiently with respect to the walls of housing 12 to prevent ingress of moisture, dust, dirt, or other debris that could cause electronic device 10 to malfunction.
Plastic contact housing 28 may be surrounded by a metal shell such as metal shell 26. Metal shell 26 may have parallel top and bottom plates that are connected by left and right side portions. Metal shell 26 may have latch windows (holes) such as latch windows 34 on the left and right side portions of shell 26 and alignment rail windows (holes) such as alignment rail windows 36 on the bottom plate of shell 26. Latch windows 34 are openings that allow the mating connector to secure itself to connector 24. Alignment rail windows 36 are byproducts of alignment rails 37 that are bent up from the bottom plate of metal shell 26. The alignment rails may provide physical guidance for the mating connector.
Connector 24 may be placed within device housing 12. Potential ingress areas include gaps between contacts 30 and plastic contact housing 28 (sometimes referred to herein as contact stitching gaps), gaps between metal shell 26 and plastic contact housing 28 (sometimes referred to herein as shell-to-insulator gaps), gaps between metal shell 26 and housing 12 (sometimes referred to herein as shell-to-housing gaps 32), latch windows 34, and rail alignment windows 36. These potential ingress areas represent locations associated with connector 24 where moisture could potentially enter device 10. It is therefore generally desirable to provide ways of moisture-sealing these ingress areas.
Mounting structures such as left metal bracket 38 and right metal bracket 40 may be attached to metal shell 26. Brackets 38 and 40 may, for example, be welded to metal shell 26. Brackets 38 and 40 may include holes such as screw holes (see, e.g., hole 39). The screw holes may be positioned over a substrate such as printed circuit board (PCB) 42. Circuit board 42 may be a rigid PCB, a flexible circuit board (e.g., a flex circuit), a rigid-flex circuit board, or other types of substrate. Screws such as screw 44 may be used to secure connector 24 to circuit board 42 that is mounted within device housing 12.
Sealed connector 24 may be formed using an injection molding process such as an insert molding process. Injection molding is a manufacturing process for producing parts from thermoplastic materials. Suitable thermoplastics for injection molding can be formed from polymers that assume a liquid (moldable) state when heated and that solidify to a solid plastic state when sufficiently cooled. Thermoplastic materials that may be used for forming connector 24 may include polyethylene, polypropylene, and other polymers suitable for use in injection molding techniques.
At step 49, shell 26 and pins 30 may be held in place by holding structure 48. Pins 30, which may also sometimes be referred to as contact leads or contacts, may each be formed from a thin piece of conductor (e.g., copper, plated copper, brass, or any suitable metal). Mold 50 may be placed around shell 26 so that mold 50 forms a mold cavity that is inside shell 26 and that surrounds pins 30. A shot of pelletized thermoplastic material (e.g., thermoplastic granules or “resin”) may be added to hopper 52. The material may be gravity fed into a screw-type plunger 54 (or an injection ram) that is heated by heating unit 56. The heat generated by unit 56 and the rotation of the screw in plunger 54 result in elevated temperatures and a shearing action on the thermoplastic pellets that causes the pellets to melt into molten plastic. Screw rotation in plunger 54 may push the molten plastic towards the mold cavity. Mold 50 may have an opening through which nozzle 58 may be inserted to connect with the mold cavity. Plunger 54 may inject the molten plastic into the mold cavity through nozzle 58. The molten plastic may be injected with a high enough pressure to completely fill the mold cavity.
When the mold cavity has been completely filled, the molten plastic may be cooled by running water through channels in mold 50. The plastic that solidifies within the mold cavity forms plastic contact housing (insulator) 28 that molds around pins 30. This process is referred to as insert molding, because thermoplastic is injected into a mold cavity around an insert piece (i.e., pin 30). At the completion of the cooling cycle, mold 50 may be released. Metal shell 26 with the inserted-molded plastic contact housing may be ejected (step 51).
The top and bottom plates of metal shell 26 may be parallel to axes 60 and 60′ respectively. It may be desirable to form the top and bottom plates of shell 26 to be slightly angled from one another to facilitate the release of mold 50. For example, axes 60 may be drafted 0.25 degrees from axes 60′. Any other desirable angle may be used. Axes 60 and 60′ may be parallel, if desired.
A tightly sealed mechanical bond may be formed when the insert structures are formed of a different material than the resin. For example, a mechanical bond may be formed between metal shell 26 (e.g., a metal casing) and plastic contact housing 28 (e.g., a plastic housing). To achieve a well-formed mechanical bond, metal shell 26 may be provided with a surface capable of retaining the encased plastic housing under normal conditions (e.g., normal operating temperatures and stresses). The mechanical bond between metal shell 26 and plastic contact housing 28 and the mechanical bond between plastic contact housing 28 and pins 30 (e.g., the metal insert pieces of the connector) may form interfaces that sufficiently seal the shell-to-insulator gaps and the contact stitching gaps from moisture, respectively.
Another suitable approach for forming connector 24 is shown in
A shot of pelletized thermoplastic material (e.g., thermoplastic granules or “resin”) may be injected into the mold cavity formed by mold 50′ to form plastic contact housing 28 as described in connection with
Mold 50′ may subsequently be released. Contacts 30 may be inserted into contact stitching holes 62 manually or automatically with suitable assembly equipment (step 55). Inserting contacts 30 into holes 62 in this way may form tight friction-fit interfaces between contacts 30 and plastic contact housing 28. Sealing the contact stitching gaps using this approach may be acceptable provided that the risk for liquid ingress through the contact stitching gaps is relatively low compared to the risk for moisture ingress through the shell-to-insulator gaps.
In summary, the mechanical bond between metal shell 26 and plastic contact housing 28 and the friction-fit between contacts 30 and plastic contact housing 28 may form interfaces that satisfactorily seal the shell-to-insulator gaps and the contact stitching gaps from moisture, respectively (step 57).
Metal shell 26 may have through holes such as through holes 46, as shown in
Shell-to-housing gaps 32 (see, e.g.,
An elastomeric sealing structure such as U-shaped gasket 80 may be formed using a compression molding process, as shown in
At step 77, control structure 74 may move upper molding structure 68 downwards so that upper molding structure 68 comes in contact with lower molding structure 70. Lowering structure 68 in this way may cause layer 66 to bend into an upside down “U” configuration (when viewed from the front). Upper and lower molding structures 68 and 70 may compressively mold layer 66 into U-shaped gasket 80. Once molded into a U shape, gasket 80 will generally retain its shape upon release of the molding structures (step 79). Heat need not be required in the compression molding process.
Gasket 80 may be assembled onto metal shell 26 to create a seal along the top and side portions of shell 26, as shown in
Another suitable elastomeric sealing structure that may be used to moisture-seal connector 24 is gasket 102. An elastomeric sealing structure such as O-shaped gasket 102 may be formed using the compression molding process, as shown in
At step 93, the upper molding structure may be lowered until it comes into contact with the top plate of metal shell 26, the lower molding structure may be raised until it comes into contact with the bottom plate of shell 26, and the middle molding structure may be pushed until it comes into contact with plastic contact housing 28. Pushing structure 92 in the direction of arrow 98 way may remove a center portion of layer 66 to form a substantially rectangular ring (O-shaped) gasket such as gasket 102. Molding structures 88, 90, and 92 may be used to compressively mold gasket 102 in the directions of arrows 100. Gasket 102 may be formed and molded directly onto shell 26 without requiring an additional assembly step. Gasket 102 may retain its molded shape after molding and may remain attached to shell 26 upon release of the molding structures (step 95).
Gasket 102 may create a seal along all four edges of metal shell 26, as shown in
Other potential high-risk ingress areas include latch windows 34 (described in connection with
The right latch window may be sealed by an elastomeric sealing member such as elastomeric sealing member 80-R. Sealing member 80-R may sometimes be referred to as a silicone boot. As with protrusion 110, sealing member 80-R may form a cup that receives the latches on the male plug while also sealing the right latch window. Sealing member 80-R may be formed as part of a gasket of the type described in connection gasket 80 of
These techniques to seal the latch windows are merely illustrative. If desired, the right latch window may be sealed by a metal bracket with a latch receiving cup or the left latch window may be sealed by an elastomeric sealing member such as elastomeric sealing member 80-L (which may also be formed as part of gasket 80). In general, metal brackets having latch receiving cups and/or silicone boots may be used to seal latch windows 34.
Alignment rail windows 36 described in connection with
To prevent moisture from entering device 10 through the alignment rail windows, a water-resistant sealing layer such as water-resistant mylar film 112 may be used to cover the bottom plate of shell 26, as shown in
Sealed connector 24 may be moisture-sealed using any desired combination of the various techniques described in connection with
For example, consider a scenario in which the high risk areas for liquid ingress include the shell-to-housing gaps, the latch windows, and the alignment rail windows. Sealed connector 24 in this scenario may be formed using silicone gasket 102 of the type described in connection with
Consider another scenario in which the high risk areas for liquid ingress include the shell-to-insulator gaps, the shell-to-housing gaps, and the latch windows. Sealed connector 24 in this scenario may be formed using the insert-molding process described in connection with
The foregoing is merely illustrative of the principles of this invention and various modifications can be made by those skilled in the art without departing from the scope and spirit of the invention.
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