Interconnect receptacles for receiving plugs of a corresponding type are commonly installed in a variety of computing devices such as personal computers, laptops, tablets, smartphones, televisions, etc. Many of these are made in compliance with a corresponding standard such a UNIVERSAL SERIAL BUS (USB), DISPLAYPORT, or HIGH-DEFINITION MULTIMEDIA INTERFACE (HDMI) specification which limits properties such as physical dimensions, electrical shielding, and various durability test results so that a corresponding standard plug can be used in conjunction with any manufacturer's receptacle and result in a consistent experience for the user. As a result, substantially altering the materials and components of a receptacle while maintaining compliance with the corresponding standard can be difficult.
In recent years, a wide variety of computing devices have been manufactured with colored external surfaces other than a typical metallic color such as silver or gold. However, due to requirements such as electrical or radio shielding set by the corresponding standard, interconnect receptacles installed in a colored computing device generally remain metal with at most a metallic finish or plating applied to visible surfaces such as an inner surface and outer rim. Particularly in high-end devices, this mismatch of colors can lead to unsightly clashing to a discerning user, or else limit the color options of the computing device to metallic colors such as silver or black, in order to have a consistent appearance that is customizable and cosmetically pleasing for the user.
Provided is a plastic-lined interconnect receptacle configured to receive a plug therein. The interconnect receptacle may include a tongue with pins applied thereon for electrical contact with the plug, a metal shell comprising a plurality of inner walls configured to surround at least a portion of the tongue, and a plastic liner positioned inside the metal shell to cover at least three of the inner walls. With such an interconnect receptacle, a color of the plastic liner may be an external color of a computing device in which the interconnect receptacle is installed while maintaining compliance with a specification such as UNIVERSAL SERIAL BUS or DISPLAYPORT.
This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used to limit the scope of the claimed subject matter. Furthermore, the claimed subject matter is not limited to implementations that solve any or all disadvantages noted in any part of this disclosure.
The receptacle 10 may comprise a tongue 16 with pins 18A, 18B applied thereon for electrical contact with the plug 12. In this example, the pins 18A may be USB 2.0 pins for transfer according to USB 2.0/1.x and the pins 18B may be USB 3.0 pins for transfer according to USB 3.0/3.1. It will be appreciated that portions of the pins 18A, 18B may be embedded within the tongue 16 and portions may be positioned on a surface thereof. The receptacle 10 may be in a horizontal mounting position, with the tongue 16 extending horizontally. The receptacle 10 may further include a metal shell 20 (see
The receptacle 10 may further include a plastic liner 22 positioned inside the metal shell 20 to cover at least three of the inner walls 20A-20D. An enlarged view of just the liner 22 is shown in
In addition, the plastic liner 22 may extend a full length of an interior of the metal shell 20, where “length” is used to mean the dimension along which the plug 12 is inserted via the entrance. As can be seen in
After injection molding, the plastic liner 22 may be inserted into to the metal shell 20 using interlocking parts; for example, the liner 22 may be formed with tabs 22D that fit in slots 2011 of the shell 20. The receptacle 10 may be soldered to a printed circuit (i.e., printed circuit board (PCB) or flexible printed circuit (FPC)) such as a motherboard using a reflow process which may result in a portion of the liner 22 softening and rehardening. When choosing materials for the liner 22, robustness of the liner 22 during the reflow process to solder the receptacle 10 to the PCB is one factor to be considered. The reflow process may raise temperatures to around 200-250° C. for 10 minutes, for example, depending on the materials used. The melting temperature of the material of the liner 22 therefore must allow the liner 22 to withstand such conditions if undesirable deformation is to be avoided. A liquid crystal polymer (LCP) exhibits an easy flow and can be injected at low pressure and temperature; however, areas where the injected LCP flow fronts combine to form weld lines may be notably weak, and the LCP's ability to flow at lower temperatures may result in worse deformation during reflow. Further, coloring agents may oxidize in the reflow process and fail to maintain their original and intended colors. For example, plastics colored a bright blue or red may come out of a reflow oven brown.
The plastic liner 22 may instead be formed of a material including nylon. Compared to LCP, nylon does not flow as easily as it typically requires a higher temperature and a much higher injection pressure; however, the weld lines are stronger and it also survives better (i.e., deforms less) when exposed to high temperatures. To further lower the chance and extent of deformation, the thin walls of the liner 22 may be held in place by the tabs 22D during the reflow process and thereby maintain their proper shape.
In addition, recently developed nylon polymers have a much higher color stability during both the reflow process and under ultraviolet (UV) exposure. Using such a polymer, color shifts caused by UV exposure may be tested to preemptively shift the colors used and thereby prevent degradation of the appearance of the receptacle 10 over time. In addition, using inorganic coloring agents may reduce the color shift arising from the reflow process. The color stability of the pigments may be further improved by controlling the environment of the reflow process to have very low oxygen levels, for example, no more than 1,200 ppm. The plastic liner 22 may also be formed of a fiber-reinforced plastic including glass fibers. For example, the fiber-reinforced plastic may include 10-40% glass fibers added to the abovementioned nylon. The glass fibers, when the flow is modeled to strategically set their orientation, may have the effect of increasing the strength of the plastic, allowing the liner 22 to be made as thin as possible to fit within the metal shell 20 and still meet tolerance requirements of the associated interconnect specification. When incorporating the liner 22, a net change to interference of the receptacle 10 compared to a typical unlined receptacle may be substantially zero, such that signal integrity requirements of the corresponding specification are met. Approximately 10-40% glass fibers may be sufficient to maintain compliance for the USB-A receptacle 10, with approximately 35% exhibiting better performance; however, other receptacle types may exhibit better performance with different fill percentages, as will be discussed below. In this case, since the tongue 16 and the liner 22 may be formed of the same material, approximately 35% represents a balance between the stability benefit to the liner 22 and the signal integrity detriment to the tongue 16 which holds the pins 18A, 18B.
The receptacle 110 may also comprise a tongue 116 with pins 118 applied thereon for electrical contact with the plug. In this example, the pins 118 may include pins for transfer according to USB 2.0, 3.0, and/or 3.1 the shell 120 may include one or more tabs 1201 to interlock with one or more slots 122K formed in the liner 122. One or more of the pins 118 may further allow transfer of data for display according to a DISPLAYPORT specification.
The plastic liner 122 may also be formed of a fiber-reinforced plastic including glass fibers. However, the USB-C receptacle 110 may be configured to run at up to THUNDERBOLT 3 speeds of 40 Gbps, which is higher than the speed of the USB-A receptacle 10 at around 5 Gbps. Higher glass fiber fill percentages may result in increased sturdiness of the plastic, which is beneficial for thin or easily stressed portions, but also may result in more interference and therefore lower signal integrity where signals are intended to pass through, for example, in the tongue 116. Therefore, to maintain an effective signal integrity while still maintaining structural stability of the liner 122, the fiber-reinforced plastic used in both the tongue 116 and the liner 122 of the receptacle 110 may include 10-25% glass fibers, with approximately 20% exhibiting better performance.
The receptacle 210 may also comprise a tongue 216 with pins 218 applied thereon for electrical contact with the plug. The receptacle 210 may further include a metal shell 220 (see
In the MDP receptacle 210, the plastic liner 222 and the tongue 216 may be integrally formed of the same material. An enlarged view of just the liner 222 (with tongue 216) is shown in
As with the receptacle 10, when manufacturing the receptacle 210, the plastic liner 222 may be injection molded and inserted into the metal shell 220 using interlocking parts. In this case, the liner 222 may include one or more tabs 222D to interlock with one or more slots 22011 formed in the shell 220 as the interlocking parts. The liner 222 may also be formed of a fiber-reinforced plastic including glass fibers. However, while the USB-C receptacle 110 may be configured to run at up to THUNDERBOLT 3 speeds of 40 Gbps and the USB-A receptacle 10 may run at up to around 5 Gbps, the MDP receptacle 210 may be configured to run at up to around 10 Gbps. Therefore, maintaining signal integrity is not as difficult for the MDP receptacle 210 as for the USB-C receptacle 110, and the fiber-reinforced plastic of the receptacle 110 may thus include 10-40% glass fibers to maintain compliance with a DISPLAYPORT specification, with approximately 35% exhibiting better performance.
As shown in simplified form using dotted lines, the computing device 1 may comprise a processor 3 configured to execute instructions stored in memory 5. The processor 3 may include one or more central processing unit (CPU) or graphics processing unit (GPU), for example. The memory 5 may include semiconductor memory (e.g., RAM, EPROM, EEPROM, etc.), magnetic memory (e.g., hard-disk drive, MRAM, etc.), volatile, nonvolatile, dynamic, static, read/write, read-only, random-access, sequential-access, location-addressable, file-addressable, and/or content-addressable devices. Alternatively, the processor 3 and memory 5 may be combined into a system-on-a-chip (SOC) or program- and application-specific integrated circuit (PASIC/ASIC) if the computing device 1 uses minimal processing power on its own—for example, the computing device may be an external hard drive or a USB charging hub operated with firmware. The computing device 1 may comprise a printed circuit board 7 operatively connected to the processor 3, and an interconnect receptacle 10 (110, 210), mounted on the printed circuit 7, configured to receive a plug 12 (see
As discussed above in greater detail with reference to
The interconnect receptacle 10 (110, 210) may be compliant with a UNIVERSAL SERIAL BUS or DISPLAYPORT specification, among others. Accordingly, a color of the plastic liner 22 (122, 222) may be an external color of the computing device 1, as shown in
With reference to
At 1210 the method 1200 may include assembling the interconnect receptacle from at least the metal shell, the plastic liner, a tongue arranged inside the plastic liner and the metal shell, and pins formed on the tongue for electrical contact with a plug. As discussed above, depending on the type and configuration of the receptacle, the tongue may be integrally or separately formed with the liner. In addition, the tongue and the liner may be formed of the same material, in the same color. At 1212 the method 1200 may include mounting the interconnect receptacle on a printed circuit such as a PCB or FPC using a reflow process. As discussed above, the reflow process may include heating the receptacle to approximately 200-250° C. for approximately 10 minutes such that the plastic liner may partially soften and reharden when solder melts and reforms to adhere the receptacle to the printed circuit. The printed circuit may be installed in a computing device such as the one shown in
The subject matter of the present disclosure is further described in the following paragraphs. One aspect provides an interconnect receptacle configured to receive a plug therein, the interconnect receptacle comprising a tongue with pins applied thereon for electrical contact with the plug, a metal shell comprising a plurality of inner walls configured to surround at least a portion of the tongue, and a plastic liner positioned inside the metal shell to cover at least three of the inner walls. In this aspect, the plastic liner and the tongue may be integrally formed of the same material. In this aspect, the plastic liner and the tongue may be separately formed of the same material of the same color. In this aspect, the plurality of inner walls of the metal shell may include a top, a bottom, and two sides, and the plastic liner may cover the two sides and at least one of the top and the bottom. In this aspect, the plastic liner may be injection molded and inserted into the metal shell. In this aspect, the plastic liner may be formed of a material including nylon. In this aspect, the plastic liner may be formed of a fiber-reinforced plastic including glass fibers. In this aspect, the fiber-reinforced plastic may include 10-40% glass fibers. In this aspect, the interconnect receptacle may be compliant with a UNIVERSAL SERIAL BUS specification. In this aspect, the interconnect receptacle may be compliant with a DISPLAYPORT specification. In this aspect, the metal shell may include joined upper and lower shells. In this aspect, a thickness of the plastic liner may be 0.3-0.8 mm. In this aspect, the interconnect receptacle may be installed in a computing device and a color of the plastic liner may be an external color of the computing device. In this aspect, the plastic liner may extend a full length of an interior of the metal shell. In this aspect, side walls of the plastic liner may be thicker than a bottom of the plastic liner.
According to another aspect, a computing device is provided. The computing device may comprise a processor configured to execute instructions stored in memory, a printed circuit operatively connected to the processor, and an interconnect receptacle, mounted on the printed circuit, configured to receive a plug therein. The interconnect receptacle may comprise a tongue with pins applied thereon for electrical contact with the plug, a metal shell comprising a plurality of inner walls configured to surround at least a portion of the tongue, and a plastic liner positioned inside the metal shell to cover at least three of the inner walls. In this aspect, a color of the plastic liner may be an external color of the computing device. In this aspect, the interconnect receptacle may be compliant with a UNIVERSAL SERIAL BUS or DISPLAYPORT specification. In this aspect, the plastic liner and the tongue may be formed of the same material.
According to another aspect, a method of manufacturing an interconnect receptacle configured to receive a plug therein is provided. The method may comprise preparing a fiber-reinforced plastic including nylon and glass fibers, injection molding the fiber-reinforced plastic to form a plastic liner, joining the plastic liner to an interior of a metal shell comprising a plurality of inner walls using interlocking parts, assembling the interconnect receptacle from at least the metal shell, the plastic liner, a tongue arranged inside the plastic liner and the metal shell, and pins formed on the tongue for electrical contact with a plug, and mounting the interconnect receptacle on a printed circuit using a reflow process.
It will be understood that the configurations and/or approaches described herein are exemplary in nature, and that these specific embodiments or examples are not to be considered in a limiting sense, because numerous variations are possible. The specific method described herein may represent one or more of any number of strategies. As such, various acts illustrated and/or described may be performed in the sequence illustrated and/or described, in other sequences, in parallel, or omitted. Likewise, the order of the above-described processes may be changed.
The subject matter of the present disclosure includes all novel and non-obvious combinations and sub-combinations of the various processes, devices, and configurations, and other features, functions, acts, and/or properties disclosed herein, as well as any and all equivalents thereof.
This application claims priority to U.S. Provisional Patent Application No. 62/479,215 filed Mar. 30, 2017, the entirety of which is hereby incorporated herein by reference.
Number | Date | Country | |
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62479215 | Mar 2017 | US |