Patent Description:
With the continuous improvement of living conditions, mobile phones have become essential communication tools for people. In order to meet the requirements of users and improve the market competitiveness of the mobile phones, on one hand, researchers and developers continue to improve the performance of mobile phones; on the other hand, researchers and developers continue to improve and optimize the appearance of mobile phones. Charging sockets are important components for the mobile phones. On one hand, when charging the mobile phones, the mobile phones need to be charged via the charging sockets; on the other hand, it is possible to achieve data transmission between the mobile phones and other devices by means of the charging sockets.

Chinese patent application <CIT> provides an electric connector. The electric connector comprises an insulation body and multiple conductive terminals which are contained in the insulation body, wherein the insulation body is externally coated with a non-metal shell, and an inserting opening is formed by surrounding the non-metal shell and the insulation body. In such a way, a shell is made from a non-metal material, the electromagnetic interference cannot be caused for the radio frequency of a mobile device, the call quality can be ensured, and thus the defects of the prior art can be overcome. In addition, a grounding terminal is inserted into the tail end of the insulation body, the grounding terminal stretches into the inserting opening and is suspended at the inner wall surface of the non-metal shell, the grounding terminal is contacted with the shell of a USB (Universal Serial Bus) plug when a butt-joint USB plug is inserted in the inserting opening, and thus the grounding function of a metal shell in an original product can be replaced.

Chinese patent application <CIT> provides an electrical connector with a terminal module enclosed within an insulative shield wherein the terminal module includes a plurality of terminals embedded within an insulative main body. The insulative main body forms a rear mounting standing part and a front mating tongue part extending forwardly from the rear mounting standing part. The insulative shield forms a rearward step against a forward shoulder of the base portion so as to prevent further forward movement of the base portion relative to the insulative shield. The insulative main body forms a protrusion and the insulative shield forms a securing hole to receive said protrusion for securing the insulative shield and the terminal module together.

US patent application <CIT> provides an electrical connector, comprises: an insulative housing; a plurality of contacts received into the insulative housing and having a plurality of soldering portion extending rearwardly and beyond a rear surface of the insulative housing; a metallic shell enclosing the insulative housing; and a cover formed on a rear end of the insulative housing and the metallic shell and sealed the rear surface of the insulative housing.

PCT patent application <CIT> provides a USB interface and a mobile terminal comprising the USB interface. The mobile terminal is capable of driving other mobile terminals through the USB interface. The USB interface comprises: a USB interface body (<NUM>), a power line plug (<NUM>) externally connected to power lines through insertion parts, and a ground line plug (<NUM>) externally connected to ground lines through insertion parts. The edge of a bottom (<NUM>) of the power line plug and the edge of a bottom (<NUM>) of the ground line plug are fixed to the USB interface body. The power line plug has P insertion parts, and P is greater than or equal to <NUM>; the ground line plug has Q insertion parts, and Q is greater than or equal to <NUM>. The USB interface supports charging with a current greater than <NUM> amperes.

US patent application <CIT> provides an electrical connector includes: an insulative housing including a base and a tongue; an upper and lower rows of contacts secured in the insulative housing and exposed to the tongue; a shielding shell enclosing the insulative housing; and a metal plate situated between the upper row of contacts and the lower rows of contacts; wherein the shielding shell is integrally formed with the metal plate. A related method of making such an electrical connector includes the steps of: inserting a first and second terminal modules into a first and second receiving spaces of a shielding shell, respectively, from a rear of the shielding shell; and insert molding the first and second terminal modules with a planar portion of a metal plate integral with the shielding shell.

The present disclosure is at least to some extent to solve one of the technical problems in the related art. Therefore, the present disclosure provides a mobile terminal, a power adapter, a power interface, and a method for manufacturing the power interface, as set out in the appended set of claims, which may have an advantage of high reliability.

In the power interface of the embodiment of the present disclosure, by arranging the first baffle in the plug shell and arranging the snap-fit flange on the plug body, and fixing the snap-fit flange in the plug shell by the first baffle and the second baffle, the plug body can be fixed in the plug shell to prevent the plug body from moving in an up-down direction of the plug shell, and the plug body can be prevented from being separated from the plug shell. Therefore, when a connection line of a power adapter is inserted into the power interface, the reliability of the connection between the connection line and the power interface may be improved.

Embodiments of the present disclosure will be described in detail below, and examples of the embodiments will be illustrated in the accompanying drawings. The embodiments described below with reference to the drawings are illustrative and are intended to explain the present disclosure, and cannot be construed as a limitation to the present disclosure.

In the description of the present disclosure, it is to be understood that terms such as "up", "down", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", "circumferential", and the like, refer to the orientations and locational relations illustrated in the accompanying drawings. Thus, these terms used here are only for describing the present disclosure and for describing in a simple manner, and are not intended to indicate or imply that the device or the elements are disposed to locate at the specific directions or are structured and performed in the specific directions, which could not to be understood as limiting the present disclosure.

In addition, terms such as "first", "second", and the like are used herein for purposes of description, and are not intended to indicate or imply relative importance or significance or to imply the number of indicated technical features. Thus, the feature defined with "first", "second", and the like may include one or more of such a feature. In the description of the present disclosure, "a plurality of" means two or more, such as two, three, and the like, unless specified otherwise.

In the present disclosure, unless specified or limited, otherwise, terms "mounted", "connected", "coupled", "arranged", and the like are used in a broad sense, and may include, for example, fixed connections, detachable connections, or integral connections; may also be mechanical or electrical connections; may also be direct connections or indirect connections via intervening structures; may also be inner communications of two elements, as can be understood by one skilled in the art depending on specific contexts. In the following, a power interface <NUM> may be will be described in embodiments of the present disclosure with reference to <FIG>. It should be understood that, the power interface <NUM> includes an interface configured for charging or data transmission, and may be arranged in a mobile terminal such as a mobile phone, a tablet computer, a laptop, or any other suitable mobile terminal having a rechargeable function. The power interface <NUM> may be electrically connected to a corresponding power adapter to achieve a communication of electrical signals and data signals.

<FIG> illustrate the power interface <NUM>. The power interface <NUM> according to an embodiment of the present disclosure includes a plug shell <NUM>, a plug body <NUM>, and may include intermediate patch <NUM>.

Specifically, a first baffle <NUM> is le arranged in the plug shell <NUM>. The plug body <NUM> is arranged in the plug shell <NUM>. An snap-fit flange <NUM> is arranged on the plug body <NUM>. A second baffle <NUM> is arranged in the plug shell <NUM>, connected to the plug shell <NUM> and spaced apart from the first baffle <NUM>. The snap-fit flange <NUM> is sandwiched between the first baffle <NUM> and the second baffle <NUM>. In this way, the snap-fit flange <NUM> is fixed in the plug shell <NUM> by the first baffle <NUM> and the second baffle <NUM>, and the plug body <NUM> is fixed in the plug shell <NUM>. Thus, the plug body <NUM> may be prevented from moving in an up-down direction of the plug shell <NUM> to prevent the plug body <NUM> from being separated from the plug shell <NUM>. Therefore, when a connection line of a power adapter is inserted into the power interface <NUM>, the reliability of the connection between the connection line and the power interface <NUM> may be improved.

It should be noted that, the power interface <NUM> may be arranged on a mobile terminal, and a battery can be arranged inside the mobile terminal (e.g., a mobile phone, a tablet computer, a notebook computer, etc.). The battery may be charged by an external power source via the power interface <NUM>.

In the power interface <NUM> of the embodiment of the present disclosure, by arranging the first baffle <NUM> in the plug shell <NUM> and arranging the snap-fit flange <NUM> on the plug body <NUM>, and fixing the snap-fit flange <NUM> in the plug shell <NUM> by the first baffle <NUM> and the second baffle <NUM>, the plug body <NUM> can be fixed in the plug shell <NUM> to prevent the plug body <NUM> from moving in the up-down direction of the plug shell <NUM>, and the plug body <NUM> can be prevented from being separated from the plug shell <NUM>. Therefore, when a connection line of a power adapter is inserted into the power interface <NUM>, the reliability of the connection between the connection line and the power interface <NUM> may be improved.

In some embodiments of the present disclosure, the plug shell <NUM> and the second baffle <NUM> may be made of metal, and the second baffle <NUM> may be welded on the plug shell <NUM>. The plug shell <NUM> and the second baffle <NUM> made of metal may have a great structural strength. In this way, it is possible to enhance the structural strength of the power interface <NUM>, and the power interface <NUM> may be prevented from being deformed after a long time of use or after frequent insertion and removal. In addition, since the inner space of the plug shell <NUM> is limited, when the second baffle <NUM> is welded on the plug shell <NUM>, it is possible to simplify the processing and assembling processes, shorten manufacturing cycles, and reduce the manufacturing cost.

In one embodiment, the second baffle <NUM> may be made of stainless steel. In this way, it is possible to avoid the second baffle <NUM> from rusting, and thus the poor contact of the plug body <NUM> with a power adapter due to the rusting of the second baffle <NUM> may be prevented from occurring. Therefore, the reliability of the operation of the power interface <NUM> may be ensured.

In some embodiments of the present disclosure, as shown in <FIG>, a gap <NUM> may be defined between the second baffle <NUM> and the plug shell <NUM>, and an adhesive layer may be arranged in the gap <NUM>. On one hand, the adhesive layer may further bond the second baffle <NUM> with the plug shell <NUM>, to improve the reliability of the connection between the second baffle <NUM> and the plug shell <NUM>. On the other hand, the adhesive layer may have a waterproof function; that is, the adhesive layer may prevent liquid from entering the power interface <NUM> via an open end of the power interface <NUM> and damaging of the circuit board <NUM> inside the power interface <NUM>, and the like, thereby ensuring the reliability of the power interface <NUM>.

More specifically, the adhesive layer may be a dispensing layer. Dispensing is a process in which electronic glue, oil or other liquid may be applied to a product by means of painting, potting, or dripping, to allow the product to be adhesive, potted, insulated, fixed, and have a smooth face. On one hand, the dispensing layer may further bond the second baffle <NUM> with the plug shell <NUM> to improve the reliability of the connection between the second baffle <NUM> and the plug shell <NUM>. On the other hand, the dispensing layer may have a waterproof function; that is, the dispensing layer may prevent liquid from entering the power interface <NUM> via an open end of the power interface <NUM> and damaging of the circuit board <NUM> inside the power interface <NUM>, and the like, thereby ensuring the reliability of the power interface <NUM>.

In some embodiments of the present disclosure, as shown in <FIG>, the second baffle <NUM> may extend in a circumferential direction of the plug body <NUM>. On one hand, it is possible to improve the reliability of the connection between the second baffle <NUM> and the plug shell <NUM>; on the other hand, it is also possible to enhance the fixing of the plug body <NUM> by the second baffle <NUM>. In this way it is possible to ensure that the plug body <NUM> is securely fixed in the plug shell <NUM>, and improve the reliability of the connection between a power line of a power adapter and the power interface <NUM>.

Alternatively, a plurality of second baffles <NUM> may be provided, thereby facilitating the processing of the second baffle <NUM>. It should be noted that, the plurality of second baffles <NUM> may be spaced apart from each other along the circumferential direction of the plug shell <NUM>, and the plurality of second baffles <NUM> may also form an annular baffle. The plurality of second baffles <NUM> may be respectively connected to the plug shell <NUM>, in order to fix the plug body <NUM>.

In some embodiments of the present disclosure, as shown in <FIG>, the first baffle <NUM> may also extend in the circumferential direction of the plug body <NUM>. In this way, it is possible to enhance the fixing of the plug body <NUM> by the first baffle <NUM>. Alternatively, a stopping protrusion <NUM> may be arranged on a sidewall face of the first baffle <NUM> that faces towards the second baffle <NUM>,and the stopping protrusion <NUM> may be engaged with the snap-fit flange <NUM>. In this way, the first baffle <NUM> and the second baffle <NUM> may prevent the plug body <NUM> from moving in the up-down direction in the plug shell <NUM>, and may also prevent the plug body <NUM> from shaking in the plug shell <NUM> by the cooperation between the snap-fit flange <NUM> and the stopping protrusion <NUM>, and thus it is possible to ensure the reliability of the operation of the power interface <NUM>.

Referring to <FIG>, the plug body <NUM> is configured to be connected to a circuit board <NUM>, and includes at least a pair of power pins <NUM>. In this embodiment, each pair of power pins includes two sub-pins <NUM> spaced apart from each other in an up-down direction (the up-down direction as shown in <FIG>). The intermediate patch <NUM> may be sandwiched between the two sub-pins <NUM>, and configured to support the sub-pins <NUM>. Therefore, it is possible to avoid poor contact between a connecting line and the power interface <NUM> caused by the movement of the two sub-pins <NUM> which are spaced apart from each other in the up-down direction towards each other when the connection line is inserted into the power interface. In this way, it is possible to ensure the reliability of the connection between the connection line and the power interface <NUM>.

The intermediate patch <NUM> may have a head end close to a front end of the power pin <NUM> (the front end as shown in <FIG>) and a tail end close to a rear end of the power pin <NUM> (the rear end as shown in <FIG>). The tail end may be spaced apart from the plug shell <NUM> and connected to the plug body <NUM>. When designing the tail end being spaced apart from the plug shell <NUM>, it is possible to avoid producing interference with antenna signals, and thus the quality and the speed of signal transmission may be improved. In addition, both the tail end and the plug shell <NUM> may be connected to the plug body <NUM>. In this way, the intermediate patch <NUM>, the plug shell <NUM>, and the plug body <NUM> may be connected to each other, thereby improving the reliability of the connection among the intermediate patch <NUM>, the plug shell <NUM>, and the plug body <NUM>.

In some embodiments of the present disclosure, as shown in <FIG> and <FIG>, a plurality of first pads <NUM> and a plurality of second pads <NUM> may be arranged on the circuit board <NUM>. Each of the plurality of first pads <NUM> and each of the plurality of second pads <NUM> may be spaced apart from each other may be arranged on the circuit board <NUM> of the plug body <NUM>. The plug shell <NUM> may be welded on the first pad <NUM>, and the tail end may be welded on the second pad <NUM>. In this way, the plug shell <NUM> and the intermediate patch <NUM> may be connected to the circuit board <NUM>, thereby firmly fixing the plug body <NUM> to the circuit board <NUM> and preventing the power pin <NUM> of the plug body <NUM> from falling off the circuit board <NUM>, and thus the reliability of the operation of the power interface <NUM> may be ensured.

In some embodiments of the present disclosure, as shown in <FIG>, at least one sub-pin <NUM> includes an expanded portion <NUM>. The expanded portion <NUM> has a cross-sectional area larger than that of a data pin <NUM> of the plug body <NUM>. In this way, the current load of the sub-pins <NUM> can be increased, and the transmission speed of the current improved. In this way, the power interface <NUM> can have a fast charging function, thereby improving the charging efficiency of the battery.

Optionally, as shown in <FIG>, the cross-sectional area of the expanded portion <NUM> may be defined as S, and S ≥ <NUM> mm2. It has been experimentally verified that when S ≥ <NUM> mm2, the current load of the sub-pins <NUM> may be at least 10A. Therefore, the charging efficiency can be improved by increasing the current load of the sub-pins <NUM>. After further tests, when S=<NUM> mm2, the current load of the sub-pins <NUM> may be 12A or more, which can improve charging efficiency.

Furthermore, as shown in <FIG>, a thickness of the sub-pin <NUM> may be defined as D, and <NUM> ≤ D ≤ <NUM>. It has been experimentally verified that when <NUM> ≤ D ≤ <NUM>, the current load of the sub-pins <NUM> is at least 10A. In this way, it is possible to improve the charging efficiency by increasing the current load of the sub-pins <NUM>. After further tests, when D=<NUM>, the current load of the sub-pins <NUM> may be greatly increased, and the current load of the sub-pins <NUM> is 12A or more, thereby improving the charging efficiency.

Referring to <FIG>, each sub-pin <NUM> may have a contact surface configured to be electrically connected to a power adapter. In a width direction of the sub-pin <NUM> (i.e. the left-right direction shown in <FIG>), a width of the contact surface may be defined as W, which meets <NUM> ≤ W ≤ <NUM>. It has been experimentally verified that when <NUM> ≤ W ≤ <NUM>, the current load of the sub-pin <NUM> is at least <NUM> A. In this way, it is possible to improve the charging efficiency by increasing the current load of the sub-pins <NUM>. After further tests, when W = <NUM>, the current load of the sub-pin <NUM> may be greatly increased, and the current load of the sub-pins <NUM> is 12A or more, thereby improving the charging efficiency.

According to some embodiments of the present disclosure, referring to <FIG>, the expanded portion <NUM> may be located in the middle of the sub-pin <NUM>. In this way, the arrangement of the sub-pins <NUM> and the data pins <NUM> may be optimized, and the space of the power interface <NUM> may be fully utilized. Therefore, the compactness and the rationality of the configuration of the power interface <NUM> may be improved.

Furthermore, as shown in <FIG>, a recess <NUM> is defined in the expanded portion <NUM> at a position that is close to the front end of the sub-pin <NUM>. It should be noted that, when the power interface <NUM> performs the fast charging function, the sub-pin <NUM> with the expanded portion <NUM> is used to carry a large charging current. When the power interface <NUM> performs the normal charging function, the recess <NUM> defined in the expanded portion <NUM> prevents the sub-pin <NUM> from getting into contact with a corresponding pin of a power adapter. In this way, the power interface <NUM> in this embodiment can be applied to different power adapters. For example, when the power interface <NUM> performs the fast charging function, the power interface <NUM> can be electrically connected to a corresponding power adapter with the fast charging function. When the power interface <NUM> performs the normal charging function, the power interface <NUM> can be electrically connected to a corresponding normal power adapter. It should be noted that, the fast charging function herein may refer to a charging state in which the charging current is greater than or equal to <NUM>. 5A, and the normal charging may refer to a charging state in which the charging current is less than <NUM>.

In some embodiments of the present disclosure, as shown in <FIG> and <FIG> and <FIG>, the power interface <NUM> includes an encapsulation member <NUM>, and the intermediate patch <NUM> and the plug body <NUM> are wrapped by the encapsulation member <NUM>. The encapsulation member <NUM> may be made of electrically insulative and heat-conductive material. The encapsulation member <NUM> is configured to fix the intermediate patch <NUM>, the power pins <NUM> and the data pins <NUM> of the plug body <NUM>, thereby ensuring the reliability of the connection between the connection line of the power adapter and the power interface <NUM>. The encapsulation member <NUM> includes a first encapsulation portion <NUM> and a second encapsulation portion <NUM>. The first encapsulation portion <NUM> and the second encapsulation portion <NUM> match with and cooperate with each other. More specifically, the second encapsulation portion <NUM> may define a plurality of receiving grooves <NUM>, and a plurality of embedding protrusions <NUM> may be arranged on the first encapsulation portion <NUM>. The plurality of receiving grooves <NUM> may be in one-to-one correspondence with the plurality of embedding protrusions <NUM>, and cooperate with the plurality of embedding protrusions <NUM>. In this way, the reliability of the connection between the first encapsulation portion <NUM> and the second encapsulation portion <NUM> may be improved.

As shown in <FIG>, the head end may define a through hole <NUM>, and a reinforcing rib <NUM> may be arranged in the through hole <NUM>. In this way, it is possible to not only save the material of the intermediate patch <NUM>, but also improve the structural strength of the intermediate patch <NUM> by arranging the reinforcing rib <NUM> in the through hole <NUM>.

In some embodiments of the present disclosure, as shown in <FIG>, the reinforcing rib <NUM> may extend in the left-right direction. In this way, the structural strength of the intermediate patch <NUM> may be enhanced. Of course, the present disclosure may not be limited thereto. For example, the reinforcing rib <NUM> may extend in the front-rear direction, or an extending direction of the reinforcing rib <NUM> may be at an angle to the left-right direction, as long as the structural strength of the intermediate patch <NUM> may be enhanced.

In some embodiments of the present disclosure, as shown in <FIG>, a reinforcing protrusion <NUM> that protrudes away from the plug body <NUM> may be arranged at the head end. The reinforcing protrusion <NUM> may increase area of the contact surface between the intermediate patch <NUM> and the encapsulation member <NUM>, enhance the adhesion between the intermediate patch <NUM> and the encapsulation member <NUM>, and make the connection between the intermediate patch <NUM> and the encapsulation member <NUM> more stable. In this way, the intermediate patch <NUM> and the plug body <NUM> may be better fixed together by the encapsulation member <NUM>.

Alternatively, as shown in <FIG>, the reinforcing protrusion <NUM> may be located on at least one of a side wall face and a front end face of the head end. For example, in the example shown in <FIG>, the front end face of the head end may be provided with the reinforcing protrusion <NUM>, and a left side wall face in the left of the head end may be also provided with the reinforcing protrusion <NUM>. In this way, it is possible to increase the contact surface between the intermediate patch <NUM> and the encapsulation member <NUM>, enhance the adhesion between the intermediate patch <NUM> and the encapsulation member <NUM>, and make the connection between the intermediate patch <NUM> and the encapsulation member <NUM> more stable. In this way, the intermediate patch <NUM> and the plug body <NUM> may be better fixed together by the encapsulation member <NUM>.

As shown in <FIG>, in order to increase the flexibility of the intermediate patch <NUM>, a notch <NUM> may be defined in the middle of the intermediate patch <NUM>. In this way, when the intermediate patch <NUM> is shifted upwardly or downwardly, the intermediate patch <NUM> may quickly return back to the original position due to the notch <NUM>, which facilitates the connection between the connection line of the power adapter and the power interface <NUM> next time.

In some embodiments of the present disclosure, as shown in <FIG>, a crimping <NUM> may be arranged at the tail end, and one of the pair of power pins <NUM> may be configured to be wrapped by the crimping <NUM>. On one hand, the crimping <NUM> may increase the contact area between the intermediate patch <NUM> and the encapsulation member <NUM>, enhance the adhesion between the intermediate patch <NUM> and the encapsulation member <NUM>, and make the connection between the intermediate patch <NUM> and the encapsulation member <NUM> more stable, thereby better fixing the intermediate patch <NUM> and the plug body <NUM> together by the encapsulation member <NUM>. On the other hand, the crimping <NUM> may provide a protection to the power pin <NUM>.

In addition, as shown in <FIG>, the tail end may define a through hole <NUM>. In this way, it is possible to further save the material of the intermediate patch <NUM>. Of course, in order to ensure the structural strength of the intermediate patch <NUM>, a reinforcing rib <NUM> may also be arranged in the through hole <NUM>.

Referring to <FIG>, the power interface <NUM> according to embodiments of the present disclosure is described in details. It is noted that, the following description only is exemplary, and is not limitation to the present disclosure.

For convenience to describe, an example where the power interface <NUM> is implemented as a Type-C interface is described. The Type-C interface may also be called an USB Type-C interface. The Type-C interface belongs to a type of an interface, and is a new data, video, audio and power transmission interface specification developed and customized by the USB (Universal Serial Bus) standardization organization to solve the drawbacks present for a long time that the physical interface specifications of the USB interface are uniform, and that the power can only be transmitted in one direction.

The Type-C interface may have the following features: all devices supporting the Type-C interface, a standard device may declare its willing to occupy a VBUS (that is, a positive connection wire of a traditional USB) to another device through a CC (Configuration Channel) pin in the interface specification. The device having a stronger willing may eventually output voltages and currents to the VBUS, while the other device may accept the power supplied from the VBUS bus, or the other device may still refuse to accept the power; however, it does not affect the transmission function. In order to use the definition of the bus more conveniently, a Type-C interface chip (such as LDR6013) may generally classify devices into four types: DFP (Downstream-facing Port), Strong DRP (Dual Role Power), DRP, and UFP (Upstream-facing Port). The willingness of these four types to occupy the VBUS may gradually decrease.

The DFP may correspond to an adapter, and may continuously output voltages to the VBUS. The Strong DRP may correspond to a mobile power, and may give up outputting voltages to the VBUS only when the strong DRP encounters the adapter. The DRP may correspond to a mobile phone. Normally, the DRP may expect other devices to supply power to itself. However, when encountering a device that may have a weaker willingness, the DRP may also output the voltages and currents to the device. The UFP will not output electrical power externally. Generally, the UFP is a weak battery device, or a device without any batteries, such as a Bluetooth headset. The USB Type-C interface may support the insertions both from a positive side and a negative side. Since there are four groups of power sources and grounds on both sides (the positive side and the negative side), the power supported by USB Type-C interface may be greatly improved.

The power interface <NUM> in this embodiment may be applied to a power adapter with the fast charging function, or a normal power adapter. The fast charging herein may refer to a charging state in which a charging current is greater than <NUM>. The normal charging herein may refer to a charging state in which the charging current is less than or equal to <NUM>. That is, when the power interface <NUM> is charged by the power adapter with the fast charging function, the charging current is greater than or equal to <NUM>. 5A, or the rated output power is no less than 15W. When the power interface <NUM> is charged by the normal power adapter, the charging current is less than <NUM>. 5A, or the rated output power is less than 15W.

More specifically, as shown in <FIG>, the power interface <NUM> includes a plug shell <NUM>, a plug body <NUM>, an intermediate patch <NUM>, and an encapsulation member <NUM>. The plug body <NUM> may be arranged in the plug shell <NUM>, configured to be connected to the circuit board <NUM>, and may include four pairs of power pins <NUM>. Each pair of power pins <NUM> includes two sub-pins <NUM> spaced apart from each other in the up-down direction. The intermediate patch <NUM> may be sandwiched between the two sub-pins <NUM>, such that it is possible to avoid poor contact between the connecting line and the power interface <NUM> caused by the movement of the two sub-pins <NUM> which are spaced apart from each other in the up-down direction towards each other. The intermediate patch <NUM> and the plug body <NUM> are wrapped by the encapsulation member <NUM>.

In this case, the encapsulation member <NUM> may be made of electrically insulative and heat-conductive material. The encapsulation member <NUM> is configured to fix the intermediate patch <NUM>, the power pins <NUM> and the data pins <NUM> of the plug body <NUM>, thereby ensuring the reliability of the connection between the connection line of the power adapter and the power interface <NUM>. As shown in <FIG>, <FIG> and <FIG>, the encapsulation member <NUM> includes a first encapsulation portion <NUM> and a second encapsulation portion <NUM>. The second encapsulation portion <NUM> may define a plurality of receiving groove <NUM>, and the first encapsulation portion <NUM> may include a plurality of embedding protrusions <NUM>. The plurality of receiving grooves <NUM> may be in one-to-one correspondence with the plurality of embedding protrusions <NUM>, and cooperate with the plurality of embedding protrusions <NUM>. In this way, the reliability of the connection between the first encapsulation portion <NUM> and the second encapsulation portion <NUM> may be improved.

As shown in <FIG>, the intermediate patch <NUM> may have a head end close to a front end of the power pin <NUM> and a tail end close to a rear end of the power pin <NUM>. The head end may define a through hole <NUM>, and a reinforcing rib <NUM> may be arranged in the through hole <NUM>. The reinforcing rib <NUM> may extend in the left-right direction. In this way, the material of the intermediate patch <NUM> may be saved, and the structural strength of the intermediate patch <NUM> may be enhanced. The head end and the left side wall face may have a reinforcing protrusion <NUM> that protrudes away from the plug body <NUM>. The reinforcing protrusion <NUM> may increase the area of the contact surface between the intermediate patch <NUM> and the encapsulation member <NUM>, enhance the adhesion between the intermediate patch <NUM> and the encapsulation member <NUM>, and make the connection between the intermediate patch <NUM> and the encapsulation member <NUM> more stable. In this way, the intermediate patch <NUM> and the plug body <NUM> may be better fixed together by the encapsulation member <NUM>.

As shown in <FIG>, a notch <NUM> may be defined in the middle of the intermediate patch <NUM>. In this way, when the intermediate patch <NUM> is shifted upwardly or downwardly, the intermediate patch <NUM> may quickly return back to the original position. A crimping <NUM> may be arranged at the tail end, and one of the pair of power pins <NUM> may be configured to be wrapped by the crimping <NUM>. The crimping <NUM> may increase the contact surface between the intermediate patch <NUM> and the encapsulation member <NUM>, and provide a protection to the power pin <NUM>. The tail end may have a widened portion <NUM>, and the widened portion <NUM> may define a through hole <NUM>, which further saves the material of the intermediate patch <NUM>.

In addition, as shown in <FIG>, <FIG> and <FIG>, the tail end may be spaced apart from the plug shell <NUM> and connected to the plug body <NUM>. In this way, it is possible to avoid producing interference with the antenna signals, and thus the quality and the speed of signal transmission may be ensured. A plurality of first pads <NUM> and a plurality of second pads <NUM> may be arranged on the circuit board <NUM>. Each of the plurality of first pads <NUM> and each of the plurality of second pads <NUM> may be spaced apart from each other may be arranged on the circuit board <NUM> of the plug body <NUM>. The plug shell <NUM> may be welded on the first pad <NUM>, and the tail end may be welded on the second pad <NUM>. In this way, the plug shell <NUM> and the intermediate patch <NUM> may be connected to the circuit board <NUM>, thereby firmly fixing the plug body <NUM> to the circuit board <NUM> and preventing the power pins <NUM> of the plug body <NUM> from separating from the circuit board <NUM>, and thus the reliability of the operation of the power interface <NUM> may be ensured.

As shown in <FIG>, at least one sub-pin <NUM> includes an expanded portion <NUM>. The expanded portion <NUM> has a cross-sectional area larger than that of a data pin <NUM> of the plug body <NUM>. In this way, the current load of the sub-pins <NUM> is increased, and the transmission speed of the current is improved. A recess <NUM> is defined in the expanded portion <NUM> at a position that is close to the front end of the sub-pin <NUM>. When the power interface <NUM> performs the fast charging function, the sub-pin <NUM> with the expanded portion <NUM> is used to carry a large charging current. When the power interface <NUM> performs the normal charging function, the recess <NUM> on the expanded portion <NUM> prevents the sub-pin <NUM> from getting into contact with a corresponding pin of a power adapter.

In this case, as shown in <FIG>, a thickness of the sub-pin <NUM> may be defined as D, and the cross-sectional area of the expanded portion <NUM> may be defined as S. It has been experimentally verified that, when D=<NUM> and S=<NUM> mm2, the current load of the sub-pins <NUM> is at least 12A, thereby improving the charging efficiency. Furthermore, as shown in <FIG>, when W = <NUM>, the current load of the sub-pins <NUM> is at least 14A, thereby improving the charging efficiency.

Furthermore, as shown in <FIG>, a first baffle <NUM> is arranged in the plug shell <NUM>, and an snap-fit flange <NUM> is arranged on the second encapsulation portion <NUM>. The power interface <NUM> further includes a second baffle <NUM>. The second baffle <NUM> is arranged in the plug shell <NUM>, connected to the plug shell <NUM>, and spaced apart from the first baffle <NUM>. The snap-fit flange <NUM> is sandwiched between the first baffle <NUM> and the second baffle <NUM>. In this way, the second encapsulation portion <NUM> is fixed in the plug shell <NUM> by the first baffle <NUM> and the second baffle <NUM>, thereby fixing the plug body <NUM> in the plug shell <NUM>, and preventing the plug body <NUM> from moving in the up-down direction of the plug shell <NUM>.

In this case, the first baffle <NUM> and the second baffle <NUM> may be made of metal, and the second baffle <NUM> may be made of stainless steel. The second baffle <NUM> may be connected to the plug shell <NUM> by means of spot welding. The plug shell <NUM> and the second baffle <NUM> made of metal may have a great structural strength. In this way, it is possible to enhance the structural strength of the power interface <NUM>. In addition, since the inner space of the plug shell <NUM> is limited, when the second baffle <NUM> is welded on the plug shell <NUM>, it is possible to simplify the processing and assembling processes, shorten manufacturing cycles, and reduce the manufacturing cost. A gap <NUM> may be defined between the second baffle <NUM> and the plug shell <NUM>, and a dispensing layer may be arranged in the gap <NUM>. On one hand, the dispensing layer may further bond the second baffle <NUM> with the plug shell <NUM> to improve the reliability of the connection between the second baffle <NUM> and the plug shell <NUM>. On the other hand, the dispensing layer may have a waterproof function; that is, the dispensing layer may prevent liquid from entering the power interface <NUM> via an open end of the power interface <NUM> and damaging of the circuit board <NUM> inside the power interface <NUM>, and the like, thereby ensuring the reliability of the power interface <NUM>. In this embodiment, a pair of second baffles <NUM> may be provided. The pair of second baffles <NUM> may extend in the circumferential direction of the plug shell <NUM>. The pair of second baffles <NUM> may form an annular baffle. In this way, the reliability of the connection between the second baffle <NUM> and the plug shell <NUM> may be enhanced, and the structure of the second baffle <NUM> may be simplified.

The first baffle <NUM> may also extend in the circumferential direction of the plug body <NUM>. In this way, it is possible to enhance the fixing of the plug body <NUM> by the first baffle <NUM>. A stopping protrusion <NUM> may be arranged on a sidewall face of the first baffle <NUM> that faces towards the second baffle <NUM>, and the stopping protrusion <NUM> may be engaged in engaging groove <NUM> between two adjacent snap-fit flanges <NUM>. In this way, it is possible to prevent the plug body <NUM> from shaking in the plug shell <NUM> by the cooperation between the snap-fit flange <NUM> and the stopping protrusion <NUM>, and thus it is possible to ensure the reliability of the operation of the power interface <NUM>.

A method for manufacturing the power interface <NUM> according to an embodiment of the present disclosure will now be described with reference to <FIG>. Herein, the power interface <NUM> is the power interface <NUM> described above.

The method for manufacturing the power interface <NUM> according to an embodiment of the present disclosure comprises:.

The plug shell <NUM> at the S10 may be an injection molded part, and the first baffle <NUM> may be injected on the inner face of the plug shell <NUM>, which may facilitate the processing of the plug shell <NUM> and the first baffle <NUM>. At the S30, the second baffle <NUM> may be connected to the plug shell <NUM> by means of spot welding. The spot welding may be a quick and economical connection method in which the weldments may be welded to each other on the contact surface at the joint between the weldments by individual welding spots.

Furthermore, a gap <NUM> may be defined between the second baffle <NUM> and the plug shell <NUM>. The method for manufacturing the power interface <NUM> may further include: arranging an adhesive layer in the gap <NUM>, such that the second baffle <NUM> and the plug shell may be closely bonded with each other, and liquid may be prevent from entering the power interface <NUM>.

A mobile terminal according to an embodiment of the present disclosure includes the power interface <NUM> as described above. The mobile terminal realizes the transmission of electrical signals and data signals via the power interface <NUM>. For example, the mobile terminal may be electrically connected to the power adapter through the power interface <NUM> to implement a charging or data transmission function.

In the mobile terminal according to an embodiment of the present disclosure, by arranging the first baffle <NUM> in the plug shell <NUM> and arranging the snap-fit flange <NUM> on the plug body <NUM>, and fixing the snap-fit flange <NUM> in the plug shell <NUM> by the first baffle <NUM> and the second baffle <NUM>, the plug body <NUM> can be fixed in the plug shell <NUM> to prevent the plug body <NUM> from moving in the up-down direction of the plug shell <NUM>, and the plug body <NUM> can be prevented from being separated from the plug shell <NUM>. Therefore, when a connection line of a power adapter is inserted into the power interface <NUM>, the reliability of the connection between the connection line and the power interface <NUM> may be improved.

A power adapter according to an embodiment of the present disclosure includes the power interface <NUM> as described above. The mobile terminal realizes the transmission of electrical signals and data signals via the power interface <NUM>.

Claim 1:
A power interface for a mobile terminal, comprising:
a plug shell (<NUM>), wherein a first baffle (<NUM>) is arranged in the plug shell (<NUM>);
an encapsulation member (<NUM>), wherein the encapsulation member (<NUM>) comprises a first encapsulation portion (<NUM>) and a second encapsulation portion (<NUM>), and the first encapsulation portion (<NUM>) and the second encapsulation portion (<NUM>) are configured to match with and cooperate with each other;
a plug body (<NUM>), arranged in the plug shell (<NUM>) and wrapped by the encapsulation member (<NUM>), wherein a snap-fit flange (<NUM>) disposed on the second encapsulation portion (<NUM>) is arranged on the plug body (<NUM>); and
a second baffle (<NUM>), located in the plug shell (<NUM>) and connected to the plug shell (<NUM>), wherein the second baffle (<NUM>) is spaced apart from the first baffle (<NUM>), the snap-fit flange (<NUM>) is sandwiched between the first baffle (<NUM>) and the second baffle (<NUM>);
wherein the plug body (<NUM>) is configured to be connected to a circuit board (<NUM>) and comprises at least one pair of power pins (<NUM>) and a plurality of data pins (<NUM>), and each pair of power pins (<NUM>) comprises a pair of sub-pins (<NUM>) spaced apart from each other in an up-down direction; the encapsulation member (<NUM>) is configured to fix the at least one pair of power pins (<NUM>) and the plurality of data pins (<NUM>);
characterized in that at least one of the pair of sub-pins (<NUM>) comprises an expanded portion (<NUM>), and the expanded portion (<NUM>) has a cross-sectional area larger than that of each of the plurality of data pins (<NUM>) of the plug body (<NUM>) to increase a current load of the at least one of the pair of sub-pins (<NUM>);
a recess (<NUM>) is defined in the expanded portion (<NUM>) at a position that is close to an end of the at least one of the pair of sub-pins (<NUM>) away from the second baffle (<NUM>).