Patent Description:
This application relates to the technical field of terminal devices, and in particular, to a router.

A router is a hardware device connecting two or more networks, which is used as a gateway between the networks. The router is a specialized intelligent network device reading an address in each data packet and then deciding how to transmit the address.

In the conventional technology, the router includes a housing and an antenna connected to one end of the housing. A rotary shaft seat is disposed on one end of the housing. A shaft pin is inserted through the rotary shaft seat. One end of the antenna is sleeved on the shaft pin to realize hinged connection to the housing. A cable in the housing connected to a circuit board is electrically connected to an interior of the antenna through a threading hole on the rotary shaft seat, so as to realize normal transmission of an electrical signal between the circuit board and the antenna.

<CIT> discloses an antenna container structure. <CIT> discloses a wireless router antenna. <CIT> discloses a multifunctional wireless router. <CIT> discloses an antenna device for performing satellite communication and ground communications. <CIT> discloses a wireless data terminal device.

This application provides a router. A rotary shaft seat of the router is invisible when viewed from a front of the router.

In one aspect, this application provides a router comprising a housing, at least one rotary shaft seat, and an antenna, wherein the rotary shaft seat is disposed on one end of the housing, a shaft pin is inserted through the rotary shaft seat, one end of the antenna is movably sleeved on the shaft pin, and an other end of the antenna is located on a side of a front of the housing; and a shielding portion extends from an end of the housing where the rotary shaft seat is disposed, the shielding portion and the housing are integrally formed as a whole, the rotary shaft seat is located on a side of the shielding portion facing a back of the housing, and an end of the shielding portion away from the housing extends to at least a side of the rotary shaft seat away from the housing, and wherein the router further comprises two ribs disposed opposite to each other, wherein the two ribs respectively extend from two ends of the shielding portion toward a side where the rotary shaft seat is disposed; and the ribs shield at least the shaft pin on two sides of the rotary shaft seat, wherein the router is configured such that the antenna can be stored on the front of the housing.

In this application, the shielding portion extends outward from the end of the housing where the rotary shaft seat is disposed, the rotary shaft seat is disposed on a side of the shielding portion facing the back of the housing, and the end of the shielding portion away from the housing extends to at least the side of the rotary shaft seat away from the housing. Therefore, a front of the rotary shaft seat is shielded by the shielding portion. In addition, the rotary shaft seat is disposed on an inner side of the shielding portion. In this way, external debris such as dust is prevented from entering a threading hole in the rotary shaft seat from the front of the router, thereby preventing contamination or damage to a cable in the rotary shaft seat.

The router further includes two ribs disposed opposite to each other. The two ribs respectively extend from two ends of the shielding portion toward a side where the rotary shaft seat is disposed. The ribs shield at least the shaft pin on two sides of the rotary shaft seat.

In this application, the ribs are disposed at the two ends of the shielding portion and shield at least the shaft pin on the two sides of the housing. In this way, a user cannot see the shaft pin from the side of the router, thereby further improving an aesthetic degree of an appearance of the router.

Optionally, a plurality of antennas are disposed. The plurality of antennas are spaced apart from each other in a first extending direction of the housing. Each of the antennas is connected to the housing by using the corresponding rotary shaft seat. In this way, it can be ensured that each antenna can be stably rotated around the rotary shaft seat and can be stably switched between a stored state and a used state.

Optionally, the antenna includes an antenna body and two hangers bent from one end of the antenna body to a direction of the rotary shaft seat. The two hangers are respectively sleeved on the shaft pin on the two ends of the rotary shaft seat. An avoidance opening is formed between each of the hangers and the antenna body. The avoidance opening is configured for the antenna body to avoid the shielding portion in a case that the antenna body rotates toward a surface of the housing. Therefore, the antenna is not affected by the shielding portion when during rotation around the rotary shaft seat. In this way, it can be ensured that the antenna body of the antenna can be stably rotated to the outer surface of the housing, thereby achieving effective storing of the antenna.

Optionally, the antenna further includes a transition portion connected between the hangers and the antenna body. The hangers and the antenna body are located on a same side of the transition portion. The hangers, the transition portion, and an inner wall of the antenna body form the avoidance opening. A distance between the hangers and the antenna body is greater than or equal to a thickness of the shielding portion.

In this application, the transition portion is disposed between the hangers and the antenna body, and the hangers and the antenna body are disposed on the same side of the transition portion. That is to say, the hangers are disposed at a hook end of the antenna. In this way, during rotation of an end of the antenna away from the rotary shaft seat toward the housing, the shielding portion gradually extends into the avoidance opening between the hangers and the antenna body, until the antenna body of the antenna is rotated to an upper surface of the housing. By means of the above arrangement, the antenna is not be affected by the shielding portion in an entire storing process, and the hangers can be stably sleeved on the shaft pin on the two ends of the rotary shaft seat during the rotation of the antenna, thereby ensuring stable connection between the antenna and the housing. In addition, the hangers and the antenna body are disposed on the same side of the transition portion. Therefore, a size of a connecting end of the antenna in a width direction is further reduced, thereby reducing a size of the router. Moreover, when distances between the hangers and the antenna body are equal to the thickness of the shielding portion, the avoidance opening between the hangers and the antenna body can cause the shielding portion to be effectively avoided, and the size of the antenna in the width direction is reduced. Therefore, a width of the router in the used state is reduced. In addition, an excessively large height of the router caused by an excessively large distance between the antenna and the upper surface of the housing when the antenna is stored above the housing is avoided. In this way, the router can be stored more effectively.

Optionally, the antenna further includes a first reinforcing member. Two ends of the first reinforcing member are respectively connected to inner surfaces of the two hangers. A first threading hole is formed on the rotary shaft seat, and a second threading hole is formed on the first reinforcing member. The second threading hole is in communication with the first threading hole and an antenna cavity of the antenna body. The antenna further includes a second reinforcing member. Two ends of the second reinforcing member are respectively connected to sides of the two hangers close to the antenna body. An end of the first reinforcing member close to the antenna body is connected to the second reinforcing member.

In this application, the first reinforcing member and the second reinforcing member are disposed between the inner surfaces of the two hangers to enhance structural strength of the two hangers. For example, when the hangers are disposed on the hook end of the antenna, the two hangers are independent of each other. Since the first reinforcing member is disposed, stability of the mechanical structures of the two hangers is improved, and it is ensured that the two hangers can be stably sleeved on the shaft pin on the two sides of the rotary shaft seat. In this way, stable connection is achieved between the antenna and the shaft pin. In addition, the second threading hole is formed in the first reinforcing member. In this way, the cable extending through the first threading hole in the rotary shaft seat can enter the antenna cavity of the antenna body through the second threading hole, thereby achieving effective feeding for the antenna body. Moreover, an end of the first reinforcing member close to the antenna body is connected to the second reinforcing member. In this way, structural strength of the first reinforcing member and the second reinforcing member is increased, thereby further improving the structural stability of the hangers on the two sides of the first reinforcing member and the second reinforcing member.

Optionally, the router further includes an antenna bottom cover. A connecting wall extends from a bottom of each of the two hangers away from the hangers. A blocking wall extends downward from a side wall of the antenna body facing away from the hangers. The two connecting walls, the first reinforcing member, and the blocking wall form a wiring groove. The second threading hole is brought into communication with the antenna cavity of the antenna body through the wiring groove. The antenna bottom cover is disposed at an opening of the wiring groove.

In this application, the antenna bottom cover is disposed on the wiring groove at the bottom of the antenna to seal a bottom opening of the wiring groove. In this way, the cable in the wiring groove is shielded, so that the aesthetic degree of the appearance of the router is improved. In addition, dust or oil on a desktop is prevented from entering the wiring groove and causing contamination or even damage to the cable.

Optionally, a first sliding groove is formed on an inner wall of each of the two connecting walls. The first sliding groove extends from an end of the connecting wall away from the blocking wall toward the blocking wall. A first sliding rail matching the first sliding groove is formed on a side wall of the antenna bottom cover. The first sliding rail is stored in the first sliding groove. In this way, the antenna bottom cover can be conveniently inserted between the two connecting walls, thereby improving assembly efficiency of the antenna bottom cover. In addition, since the first sliding rail is snapped in the first sliding groove, the antenna bottom cover is prevented from moving in an extending direction at a specific angle to the first sliding rail, thereby improving assembly stability of the antenna bottom cover in the wiring groove.

Optionally, a slot is further formed on the inner wall of each connecting wall, and a snap matching the slot is disposed on the side wall of the antenna bottom cover. The snap is snapped in the slot. A protrusion is disposed on an end of the first sliding groove close to the blocking wall. The slot is a recess formed between the protrusion and the blocking wall. The snap is disposed in an extending direction of the first sliding rail. A gap configured for the protrusion to be snapped in is formed between the snap and the first sliding rail. A width of the gap along the extending direction of the first sliding rail is equal to a width of the protrusion.

In this application, the snap is disposed in the extending direction of the first sliding rail, and the slot is disposed in an extending direction of the first sliding groove. In this way, when the snap is snapped into the recess between the protrusion and the blocking wall, the antenna bottom cover is prevented from moving in the extending direction of the first sliding rail. In addition, the width of the gap along the extending direction of the first sliding rail is caused to be equal to the width of the protrusion. In this way, the antenna bottom cover is further prevented from moving in the extending direction of the first sliding groove.

Optionally, at least part of a surface of an end of the snap away from the first sliding rail is configured as an inclined surface, and the inclined surface faces the end away from the first sliding rail. Therefore, the snap can conveniently span the protrusion on one end of the first sliding groove to be snapped into the recess between the protrusion and the blocking wall, thereby improving the efficiency of assembling the antenna bottom cover and the antenna.

Optionally, a second sliding groove is further formed on the inner wall of each of the two connecting walls. The second sliding groove extends from the end of the connecting wall away from the blocking wall to the blocking wall. The second sliding groove is spaced apart from the first sliding groove. A second sliding rail matching the second sliding groove is formed on the side wall of the antenna bottom cover. The second sliding rail is embedded in the second sliding groove. The second sliding rail is configured as an outer edge portion extending outward from a bottom of the antenna bottom cover.

In this application, the second sliding rail and the second sliding groove are respectively disposed on the side wall of the antenna bottom cover and the inner wall of the connecting wall, so as to further improve the efficiency of assembling the antenna bottom cover and the antenna and ensure stability of the antenna bottom cover in an extending direction perpendicular to the second sliding rail. In addition, the second sliding rail is used as the outer edge portion of the antenna bottom cover. Therefore, a groove wall of the second sliding groove close to a bottom end of the connecting wall can effectively block the outer edge portion, thereby protecting the outer edge portion.

Optionally, a first limiting portion and a second limiting portion are disposed on a side of the rotary shaft seat facing the hangers. The first limiting portion is configured to prevent the antenna at a used position from rotating around the shaft pin, so that the antenna does not shake in the used state, thereby ensuring that a signal transmitted by the antenna is more stable. In addition, the first limiting portion that is disposed can further fix the antenna during the rotation of the antenna. That is to say, as long as the hangers of the antenna are rotated to the first limiting portions, the antenna can be ensured to be at the used position. The second limiting portion is configured to prevent the antenna at a stored position from rotating around the shaft pin, so that the antenna can be stably stored on the upper surface of the housing without shaking. The first limiting portion includes a first groove formed on the rotary shaft seat, and the second limiting portion includes a second groove formed on the rotary shaft seat. The first groove and the second groove both extend in a radial direction of the rotary shaft seat. A preset included angle exists between the first groove and the second groove. A protruding portion is formed on a side of each of the two hangers facing the rotary shaft seat. The protruding portion extends into the first groove when the antenna is at the used position, and the protruding portion extends into the second groove when the antenna is at the stored position. The first limiting portion and the second limiting portion are configured as groove structures, and the protruding portions matching the grooves are respectively disposed on the inner walls of the hangers. In this way, the antenna in the used state or the stored state is stabilized, and the structures of the first limiting portion and the second limiting portion are simplified, thereby improving manufacturing and assembly efficiency of the router in this application. In addition, two ends of each of the first groove and the second groove respectively extend to an outer edge of the rotary shaft seat, and two ends of the protruding portion extend to an outer edge of the hanger. In this way, contact areas between the protruding portions of the hangers and the grooves on the rotary shaft seat are increased, so that the hangers can be stabilized in an entire radial direction, thereby improving the stability of the antenna in the used state and the stored state.

Optionally, the housing includes a lower cover and an upper cover disposed on the lower cover. The upper cover and the lower cover form an accommodating cavity of the housing. The shielding portion is disposed on the upper cover.

Terms used in implementations of this application are merely intended to explain specific embodiments of this application rather than limit this application.

Generally, a router includes a housing and an antenna connected to one end of the housing. The antenna is hinged to one end of the housing for storing. Specifically, a rotary shaft seat is fixed on one end of the housing. A shaft pin is disposed on the rotary shaft seat. One end of the antenna is movably sleeved on the rotary shaft seat. In this way, the antenna can be rotated around the shaft pin. When the router is working, one end of the antenna away from the shaft pin may be rotated away from the housing. For example, the antenna is rotated to a position at a right angle to an upper surface of the housing. When the router is in a non-working state, the end of the antenna away from the shaft pin may be rotated to the housing to store the antenna.

During designing of a conventional router, the rotary shaft seat is exposed outside the housing and the antenna, and a user can see the rotary shaft seat from a conventional viewing angle (from a front of the router). As a result, the appearance of the entire router is affected, thus degrading user experience.

To resolve the above problem, in the embodiments of this application, a shielding portion extends outward from the end of the housing where the rotary shaft seat is disposed, and the rotary shaft seat is disposed on an inner side of the shielding portion. Therefore, a front of the rotary shaft seat is shielded by the shielding portion. In this way, the rotary shaft seat is invisible in the conventional viewing angle, that is, a viewing angle from the front of the router, thereby improving an aesthetic degree of an appearance of the entire router.

A structure of the router in the embodiments of this application is described in detail below.

<FIG> is a schematic front view of a router in a working state according to an embodiment of this application. <FIG> is a schematic side view of the router in the working state according to an embodiment of this application. <FIG> is an exploded view of <FIG>. <FIG> is a partially enlarged view of I in <FIG>.

Referring to <FIG>, an embodiment of this application provides a router <NUM>. The router may include a housing <NUM>, at least one rotary shaft seat <NUM> (referring to <FIG>), and at least one antenna <NUM>.

Referring to <FIG>, a front of the router <NUM> is specifically a surface of the router <NUM> seen in a g direction. In other words, the front of the router <NUM> is a side of the router <NUM> facing away from a platform such as a desktop when the router <NUM> is placed on the platform in a used state.

Referring to <FIG> and <FIG>, a cross-sectional shape of the housing <NUM> may be any shape such as a rectangle, a square, or a circle. In this embodiment of this application, that the cross-sectional shape of the housing <NUM> is specifically a rectangle is used as an example for description. A length direction of the housing <NUM> may be a direction indicated by an arrow x in <FIG>, and a width direction of the housing <NUM> may be a direction indicated by an arrow y in <FIG>.

Referring to <FIG>, the housing <NUM> may include a lower cover <NUM> and an upper cover <NUM> disposed on the lower cover <NUM>. The lower cover <NUM> and the upper cover <NUM> form an accommodating cavity of the housing <NUM>. Electronic elements of the router <NUM> such as a circuit board are disposed in the accommodating cavity.

Referring to <FIG>, the rotary shaft seat <NUM> in this embodiment of this application is disposed on one end of the housing <NUM>. For example, the rotary shaft seat <NUM> is connected to a long side of the housing <NUM>.

The rotary shaft seat <NUM> may be detachably fixed to the housing <NUM> by means of snapped connection or threaded connection. For example, an extended plate <NUM> may be disposed on one end of the upper cover <NUM> of the housing <NUM> toward the lower cover <NUM>. The rotary shaft seat <NUM> is detachably fixed to the extended plate <NUM> by means of the snap connection or the threaded connection, so as to facilitate independent replacement of the rotary shaft seat <NUM>. Certainly, in some examples, the rotary shaft seat <NUM> may be integrally formed on one end of the housing <NUM>, so as to simplify an assembly process of the router <NUM>.

<FIG> is a schematic structural diagram of the rotary shaft seat in <FIG>. <FIG> is an assembled diagram of the rotary shaft seat in <FIG> and an antenna. Referring to <FIG>, a shaft pin <NUM> may be inserted through the rotary shaft seat <NUM> in this embodiment of this application, and both ends of the shaft pin <NUM> respectively extend out of two ends of the rotary shaft seat <NUM>. As shown in <FIG>, one end of the antenna <NUM> is movably sleeved on the shaft pin <NUM>, and an other end of the antenna <NUM> is located on a side of the front of the housing <NUM>. In this way, the antenna <NUM> can be rotated around the shaft pin <NUM>. It may be understood that the shaft pin <NUM> and the rotary shaft seat <NUM> are fixed. For example, the shaft pin <NUM> does not rotate around an axis of the shaft pin in the rotary shaft seat <NUM>. For example, the shaft pin <NUM> may be fixed in the rotary shaft seat <NUM> by using a key slot.

The other end of the antenna <NUM> is an end of the antenna <NUM> away from the rotary shaft seat <NUM>.

<FIG> is a schematic structural diagram of the antenna in <FIG>. <FIG> is a partially enlarged view of II in <FIG>. Referring to <FIG>, the antenna <NUM> in this embodiment of this application may include an antenna body <NUM> and two hangers <NUM> bent from one end of the antenna body <NUM> toward the rotary shaft seat <NUM>. The two hangers <NUM> are disposed opposite to each other. As shown in <FIG> and <FIG>, mounting holes <NUM> are respectively formed on the two hangers <NUM>. The shaft pin <NUM> on two sides of the rotary shaft seat <NUM> are respectively inserted through the corresponding mounting holes <NUM>, so that the two hangers <NUM> are inserted through the shaft pin <NUM>.

<FIG> is a schematic structural diagram of the router in a stored state according to an embodiment of this application. Referring to <FIG>, when the antenna <NUM> is required to be stored, the antenna body <NUM> of the antenna <NUM> is rotated to cause the end of the antenna body <NUM> away from the hangers <NUM> to rotate toward the housing <NUM>, until the antenna body <NUM> is stored at a position close to an upper surface a of the housing <NUM> (referring to <FIG>). When the antenna <NUM> is in the stored state, the antenna body <NUM> of the antenna <NUM> can come into contact with the upper surface a of the housing <NUM> (shown in <FIG>), or may be at a specific distance from the upper surface a of the housing <NUM>.

When the antenna <NUM> is required to be used, the antenna body <NUM> of the antenna <NUM> may be rotated away from the housing <NUM> (referring to <FIG> and <FIG>). A specific included angle may exist between the antenna <NUM> and the upper surface a of the housing <NUM>. The included angle may be an acute angle, a right angle, or an obtuse angle.

During the rotation of the antenna <NUM> in this embodiment of this application, the hangers <NUM> of the antenna <NUM> rotate stably around the shaft pin <NUM>, thereby achieving stable rotation of the antenna <NUM>.

It should be noted that the upper surface a of the housing <NUM> is specifically a side of the housing <NUM> facing away from a platform such as a desktop when the router <NUM> is placed on the platform. The front of the housing <NUM> is the upper surface a of the housing <NUM>, that is, the surface of the housing <NUM> seen in the g direction in <FIG>. A side of the housing <NUM> facing away from the upper surface a is a back of the housing <NUM>.

In this embodiment of this application, the shaft pin <NUM> includes one shaft pin. In some other examples, the shaft pin <NUM> may include two shaft pins. The two shaft pins <NUM> are respectively inserted through the two ends of the rotary shaft seat <NUM>, and the two hangers <NUM> of the antenna <NUM> are respectively sleeved on the shaft pins <NUM> on the two sides of the rotary shaft seat <NUM>.

In order to prevent the hangers <NUM> from disengaging from movable ends of the shaft pin <NUM> (ends away from the rotary shaft seat <NUM>), stopping portions (not shown) may be disposed on outer ends of the shaft pin <NUM>. Sizes of outer contours of the stopping portions are greater than radial dimensions of the mounting holes <NUM> on the hangers <NUM>. In this way, the hangers <NUM> are limited between the stopping portions and one end of the rotary shaft seat <NUM>.

Referring to <FIG>, a shielding portion <NUM> extends from the end (referring to <FIG>) of the housing <NUM> in this embodiment of this application where the rotary shaft seat <NUM> is disposed. The shielding portion <NUM> and the housing <NUM> are integrally formed as a whole. For example, the shielding portion <NUM> is disposed on a long side of the housing <NUM> toward the antenna <NUM>, and the rotary shaft seat <NUM> is located on a side of the shielding portion <NUM> facing the back of the housing <NUM> (referring to <FIG>).

In this embodiment of this application, the shielding portion <NUM> extends outward from the end of the housing <NUM> where the rotary shaft seat <NUM> is disposed, and the rotary shaft seat <NUM> is disposed on the side of the shielding portion <NUM> facing the back of the housing <NUM>. Therefore, the front of the rotary shaft seat <NUM> is shielded by the shielding portion <NUM>. In this way, the rotary shaft seat <NUM> is invisible in the conventional viewing angle (the viewing angle in the direction of g in <FIG>), thereby improving the aesthetic degree of the appearance of the entire router <NUM>.

The shielding portion <NUM> may alternatively be integrated with the upper cover <NUM> of the housing <NUM> as a whole. In this way, not only strength of the connection between the shielding portion <NUM> and the housing <NUM> is enhanced, but also the assembly efficiency of the router <NUM> is improved. In addition, the shielding portion <NUM> and the housing <NUM> that are integrally formed causes the front of the router <NUM> to be more even and aesthetic.

Referring to <FIG>, during actual application, a first threading hole <NUM> is further formed in the rotary shaft seat <NUM>. A cable (not shown in the figure) drawn from the circuit board inside the housing <NUM> may enter an antenna cavity <NUM> of the antenna <NUM> through the first threading hole <NUM>. For example, the antenna body <NUM> of the antenna <NUM> is a hollow structure. The cable may be drawn out from the first threading hole <NUM> and enter the antenna cavity <NUM> of the antenna body <NUM> to feed the antenna body <NUM> of the antenna <NUM>. In this way, a signal in the router <NUM> is transmitted through the antenna body <NUM> of the antenna <NUM> in a form of an electromagnetic wave.

In this embodiment of this application, the rotary shaft seat <NUM> is disposed on an inner side of the shielding portion <NUM>, so that external debris such as dust is prevented from entering the first threading hole <NUM> in the rotary shaft seat <NUM> from the front of the router <NUM>. In this way, contamination or damage to the cable in the rotary shaft seat <NUM> is prevented, and the first threading hole <NUM> is also prevented from being blocked by dust or the like.

During specific configuration, a width by which the shielding portion <NUM> in this embodiment of this application extends toward the antenna <NUM> may be <NUM> to <NUM>. The width of the shielding portion <NUM> is distance between an end of the shielding portion <NUM> close to the housing <NUM> and an end close to the antenna <NUM>. In some examples, the width of the shielding portion <NUM> may be set to a suitable value, such as <NUM>, <NUM>, <NUM>, or <NUM>.

A gap exists between an end of the shielding portion <NUM> in this embodiment of this application away from the housing <NUM> and the antenna <NUM>. For example, the end of the shielding portion <NUM> away from the housing <NUM> is spaced apart from the antenna body <NUM> of the antenna <NUM> to reserve an activity space for the antenna <NUM> to rotate. Therefore, when the antenna <NUM> is rotated toward the upper surface a of the housing <NUM>, the shielding portion <NUM> is not knocked or squeezed. In this way, structural stability of the shielding portion <NUM> is ensured, thereby improving a service life of the router <NUM>, and the shielding portion <NUM> can stably shield the rotary shaft seat <NUM>.

In addition, a thickness of the shielding portion <NUM> in this embodiment of this application may be <NUM> to <NUM>. For example, the thickness of the shielding portion <NUM> may be set to a suitable value, such as <NUM>, <NUM>, <NUM>, or <NUM>. The thickness of the shielding portion <NUM> is distance between a side of the shielding portion <NUM> located on the upper surface a of the housing <NUM> and a side of the shielding portion <NUM> facing away from the upper surface a of the housing <NUM>.

In this embodiment of this application, the antenna <NUM> may include one antenna. For example, one antenna <NUM> is disposed on the long side of the housing <NUM>. In order to shield the rotary shaft seat <NUM> between the antenna <NUM> and the housing <NUM>, a shielding portion <NUM> may be disposed at a position on the housing <NUM> close to the rotary shaft seat <NUM>. The shielding cover is disposed above the rotary shaft seat <NUM>. The above of the rotary shaft seat <NUM> is specifically a side of the rotary shaft seat <NUM> facing the front of the router <NUM>. In other examples, two ends of the shielding portion <NUM> may extend to two ends of the housing <NUM> disposed along the first extending direction, so as to ensure effective shielding of the front of the rotary shaft seat <NUM>.

The first extending direction is specifically an extending direction of the end of the housing <NUM> where the shielding portion <NUM> is disposed. For example, when the shielding portion <NUM> is disposed on the long side of the housing <NUM>, the first extending direction is a length direction of the housing <NUM> (the direction x in <FIG>).

In some examples, a plurality of antennas <NUM> may be disposed (referring to <FIG>). The plurality of antennas <NUM> are spaced apart from each other in the first extending direction of the housing <NUM>. For example, the plurality of antennas <NUM> are spaced apart from each other on the long side of the housing <NUM> along the direction x. Each antenna <NUM> is connected to the housing <NUM> by using the corresponding rotary shaft seat <NUM>. In this way, it can be ensured that each antenna <NUM> can be rotated stably around the rotary shaft seat <NUM>, so that each antenna <NUM> can be stably switched between the stored state and the used state.

Two ends of the shielding portion <NUM> in this embodiment of this application respectively extend to the two ends of the housing <NUM> along the first extending direction. For example, a shielding portion <NUM> is disposed on the long side of the housing <NUM>, and two ends of the shielding portion <NUM> extend to two sides of the housing <NUM> along the length direction. In this way, not only it is ensured all rotary shaft seats <NUM> can be shielded by the shielding portion <NUM>, but also a process of manufacturing the shielding portion <NUM> on the housing <NUM> is simplified, thereby improving manufacturing efficiency of the entire router <NUM>. For example, the plurality of rotary shaft seats <NUM> can be shielded by assembling only one shielding portion <NUM> on one end of the housing <NUM> at one time.

The router <NUM> in this embodiment of this application further includes two ribs <NUM> (referring to <FIG>) disposed opposite to each other. The two ribs <NUM> respectively extend from the two ends of the shielding portion <NUM> toward a side where the rotary shaft seat <NUM> is disposed. The ribs <NUM> shields at least one side of the shaft pin <NUM> on the two sides of the housing <NUM>.

Specifically, the shaft pin <NUM> is disposed on each outermost rotary shaft seat <NUM> on one end of the housing <NUM>. The ribs <NUM> in this embodiment of this application can shield one side of each outermost shaft pin <NUM>, to hide the shaft pin <NUM> from the side of the router <NUM>. In this way, when a user observes the router <NUM> from the side of the router <NUM>, that is, from a short side of the housing <NUM>, the shaft pins <NUM> on the two ends of the housing <NUM> is invisible, thereby further improving the aesthetic degree of the appearance of the router <NUM>.

In some examples, the ribs <NUM> may extend to be flush with a bottom of the rotary shaft seat <NUM>, or the ribs <NUM> may extend to be lower than the bottom of the rotary shaft seat <NUM>, so that the two outermost rotary shaft seats <NUM> of the housing <NUM> are shielded by inner sides of the ribs <NUM>. In this way, all of the rotary shaft seats <NUM> are located between the two ribs <NUM>, and the user cannot observe all of the rotary shaft seats <NUM> from the side of the router <NUM>.

The shielding portion <NUM> and the ribs <NUM> are all disposed, so that the front and the side of the rotary shaft seat <NUM> are shielded. In this way, not only user experience is improved, but also all of the rotary shaft seats <NUM> are protected.

In this embodiment of this application, the movable end of the antenna <NUM>, that is, the end away from the rotary shaft seat <NUM> is easily interfered by the shielding portion <NUM> during rotation toward the housing <NUM>. For example, the shielding portion <NUM> may hinder the rotation of the antenna <NUM>. To avoid the above situation, an avoidance opening <NUM> (referring to <FIG>) may be formed between the hangers <NUM> and the antenna body <NUM> of the antenna <NUM>. The avoidance opening <NUM> is configured for the antenna body <NUM> of the antenna <NUM> to avoid the shielding portion <NUM> during rotation toward the surface of the housing <NUM>.

For example, during rotation of the antenna body <NUM> of the antenna <NUM> toward the upper surface a of the housing <NUM>, the shielding portion <NUM> may be moved into the avoidance opening <NUM> until the antenna body <NUM> reaches a stored position (shown in <FIG>). Therefore, the antenna <NUM> is not affected by the shielding portion <NUM> during rotation around the rotary shaft seat <NUM>. In this way, it can be ensured that the antenna body <NUM> of the antenna <NUM> can be stably rotated to the outer surface of the housing <NUM>, thereby achieving effective storing of the antenna <NUM>.

Specifically, the avoidance opening <NUM> is a space sandwiched between the hangers <NUM> and the antenna body <NUM>. During specific configuration, included angles between the hangers <NUM> and the antenna body <NUM> may be set as acute angles (not shown in the figure), and extending directions of the hangers <NUM> may be enlarged. In this way, when the antenna body <NUM> of the antenna <NUM> is rotated toward the stored position, the shielding portion <NUM> can completely enter the space between the hangers <NUM> and the antenna body <NUM>, and the stable connection between the hangers <NUM> and the shaft pin <NUM> is ensured.

In some examples, a transition portion <NUM> (referring to <FIG>) may be further disposed between the hangers <NUM> and the antenna body <NUM>. For example, two ends of the transition portion <NUM> are respectively connected to the antenna body <NUM> and the hangers <NUM>. The hangers <NUM> and the antenna body <NUM> are located on a same side of the transition portion <NUM>. The hangers <NUM>, the transition portion <NUM>, and an inner wall of the antenna body <NUM> form the avoidance opening <NUM>.

The arrangement of the transition portion <NUM> causes the end of the antenna <NUM> close to the rotary shaft seat <NUM> form a hook end. That is to say, the end of the antenna <NUM> returns toward the end of the antenna <NUM> away from the rotary shaft seat <NUM>. The hangers <NUM> are located on the hook end. In this way, during the rotation of the end of the antenna <NUM> away from the rotary shaft seat <NUM> toward the housing <NUM>, the shielding portion <NUM> gradually extend into the avoidance opening <NUM> between the hangers <NUM> and the antenna body <NUM>, until the antenna body <NUM> of the antenna <NUM> is rotated to the upper surface a of the housing <NUM>.

By means of the above arrangement, the antenna <NUM> is not affected by the shielding portion <NUM> in an entire storing process, and the hangers <NUM> can be stably sleeved on the shaft pin <NUM> on the two ends of the rotary shaft seat <NUM> during the rotation of the antenna <NUM>, thereby ensuring stable connection between the antenna <NUM> and the housing <NUM>.

In addition, the hangers <NUM> and the antenna body <NUM> are disposed on the same side of the transition portion <NUM>. Therefore, a size of a connecting end of the antenna <NUM> in a width direction is further reduced, thereby reducing a size of the router <NUM>.

During specific configuration, the antenna body <NUM> and the hangers <NUM> may be perpendicular to the transition portion <NUM>. That is to say, the hangers <NUM> and the antenna body <NUM> are parallel to each other. In this way, it is further ensured that the antenna <NUM> can avoid the shielding portion <NUM> during the rotation, and stability of the hangers <NUM> on the side of the rotary shaft seat <NUM> can be ensured.

The distances between the hangers <NUM> and the antenna body <NUM> may be equal to the thickness of the shielding portion <NUM>. For example, when the thickness of the shielding portion <NUM> is <NUM>, the distances between the hangers <NUM> and the antenna <NUM> may be a suitable value such as <NUM>, <NUM>, or <NUM>. In this way, the avoidance opening <NUM> between the hangers <NUM> and the antenna body <NUM> can cause the shielding portion <NUM> to be effectively avoided. When the distances between the hangers <NUM> and the antenna <NUM> are equal to the thickness of the shielding portion <NUM>, a size of the antenna <NUM> in the width direction is reduced, thereby reducing a width of the router <NUM> in the used state (an extended length of the router along the direction y in <FIG>). In addition, an excessively large height of the router <NUM> caused by an excessively large distance between the antenna <NUM> and the upper surface a of the housing <NUM> when the antenna <NUM> is stored above the housing <NUM> is avoided. In this way, the router <NUM> can be stored more effectively.

It should be noted that the distances between the hangers <NUM> and the antenna body <NUM> are minimum distances between side surfaces of the hangers <NUM> facing the antenna body <NUM> and a side surface of the antenna body <NUM> facing the hangers <NUM>. In addition, a width c of the antenna <NUM> (referring to <FIG>) is a distance between the side of the antenna <NUM> facing the housing <NUM> and the side away from the housing <NUM>.

The hangers <NUM> in this embodiment of this application each include an inner surface and an outer surface disposed opposite to each other and an outer edge surface d (referring to <FIG>) located between the inner surface and the outer surface. The inner surfaces of the hangers <NUM> are surfaces of the two hangers <NUM> facing each other. In this embodiment of this application, at least part of the outer edge surfaces d of the hangers <NUM> toward the movable end of the antenna <NUM> may be configured as an arcuate surface.

When the movable end of the antenna <NUM> is rotated toward or away from the housing <NUM>, the hangers <NUM> are rotated under the shielding portion <NUM>. Since at least part of the outer edge surfaces of the hangers <NUM> is configured as an arcuate surface, it can be ensured that the hangers <NUM> can smoothly pass by a bottom surface of the shielding portion <NUM> without causing damage to the bottom surface of the shielding portion <NUM> during the rotation.

To enhance the structural stability of the two hangers <NUM>, the antenna <NUM> in this embodiment of this application may further include a first reinforcing member <NUM> (referring to <FIG>). Two ends of the first reinforcing member <NUM> are respectively connected to the inner surfaces of the two hangers <NUM>. In other words, the two hangers <NUM> are connected by the first reinforcing member <NUM> to enhance the structural strength of the two hangers <NUM>.

For example, when the hangers <NUM> are disposed on the hook end of the antenna <NUM>, the two hangers <NUM> are independent of each other. Since the first reinforcing member <NUM> is disposed, the stability of the mechanical structures of the two hangers <NUM> is enhanced, and it is ensured that the two hangers <NUM> can be stably sleeved on the shaft pin <NUM> on the two sides of the rotary shaft seat <NUM>. In this way, stable connection is achieved between the antenna <NUM> and the shaft pin <NUM>.

<FIG> is a rear view of <FIG>. <FIG> is a cross-sectional view taken along line A-A <FIG>. <FIG> is a partially enlarged view of <FIG>. Referring to <FIG>, a second threading hole <NUM> is formed in the first reinforcing member <NUM>. The second threading hole <NUM> is in communication with the first threading hole <NUM> and the antenna cavity <NUM> of the antenna body <NUM>. In this way, a cable extending through the first threading hole <NUM> in the rotary shaft seat <NUM> can enter the antenna cavity <NUM> of the antenna body <NUM> through the second threading hole <NUM>, thereby achieving effective feeding for the antenna body <NUM>.

The two ends of the first reinforcing member <NUM> may be fixed to the inner plate surfaces of the two hangers <NUM> by means of snap connection, so as to facilitate disassembly of the first reinforcing member <NUM>. Certainly, the first reinforcing member <NUM> may alternatively be integrally formed with the two hangers <NUM>. In this way, not only strength of the connection between the hangers <NUM> and the first reinforcing member <NUM> is increased, but also components of the antenna <NUM> are reduced, thereby improving the assembly efficiency of the antenna <NUM>.

During specific configuration of the second threading hole <NUM>, at least part of a hole wall of the second threading hole may be configured as an arcuate structure (referring to <FIG>). In this way, the hole wall of the second threading hole <NUM> matches an outer surface of the cable more effectively, thereby preventing wear of the cable caused by long-term contact between the hole wall of the second threading hole <NUM> and the cable. In addition, a radial dimension of the second threading hole <NUM> may be equal to a radial dimension of the cable, so as to ensure that the cable does not shake in the second threading hole <NUM>, thereby improving stability of a path of the cable.

To further enhance the structural stability of the two hangers <NUM>, the antenna <NUM> in this embodiment of this application may further include a second reinforcing member <NUM> (referring to <FIG>). Two ends of the second reinforcing member <NUM> are respectively connected to the sides of the two hangers <NUM> close to the antenna body <NUM>.

During specific configuration, the first reinforcing member <NUM> and the second reinforcing member <NUM> may be reinforcing plates connected between the two hangers <NUM>.

An end of the first reinforcing member <NUM> close to the antenna body <NUM> is connected to the second reinforcing member <NUM>. In this way, structural strength of the first reinforcing member <NUM> and the second reinforcing member <NUM> is increased, thereby further improving the structural stability of the hangers <NUM> on the two sides of the first reinforcing member <NUM> and the second reinforcing member <NUM>.

Referring to <FIG>, in this embodiment of this application, the cable drawn out from the rotary shaft seat <NUM> passes through the second threading hole <NUM> of the first reinforcing member <NUM> into a bottom of the first reinforcing member <NUM>, and then enter the antenna cavity <NUM> of the antenna body <NUM> of the antenna <NUM> from the bottom of the first reinforcing member <NUM>.

<FIG> is an assembled diagram of the antenna in <FIG> and an antenna bottom cover. <FIG> is an exploded view of <FIG>. <FIG> is a partial schematic structural diagram of the antenna in <FIG>.

Referring to <FIG>, to store and limit the cable at the bottom of the first reinforcing member <NUM>, connecting walls <NUM> may extend from the bottoms of the two hangers <NUM> away from the hangers <NUM>, and a blocking wall <NUM> may extend downward from a side wall of the antenna body <NUM> facing away from the hangers <NUM>. The two connecting walls <NUM>, the first reinforcing member <NUM>, and the blocking wall <NUM> form a wiring groove <NUM>. The second threading hole <NUM> is brought into communication with the antenna cavity <NUM> of the antenna body <NUM> through the wiring groove <NUM>. In this way, the cable drawn out from the second threading hole <NUM> is stably stored in the wiring groove <NUM>. In addition, a groove wall of the wiring groove <NUM> also shields the cable. Therefore, a user cannot observe the cable located at the bottom of the first reinforcing member <NUM> from the side of the router <NUM>.

In a possible implementation, an antenna bottom cover <NUM> (referring to <FIG> and <FIG>) may be disposed on a notch of the wiring groove <NUM> to seal a bottom opening of the wiring groove <NUM>. In this way, the cable in the wiring groove <NUM> is shielded, and the aesthetic degree of the appearance of the router <NUM> is improved. In addition, dust or oil on a desktop is prevented from entering the wiring groove <NUM> and causing contamination or even damage to the cable. In addition, the antenna bottom cover <NUM> that is disposed further prevents a flexible circuit board located in the antenna cavity <NUM> from falling out of the wiring groove <NUM>.

An outer end of the antenna bottom cover <NUM> is connected to the two connecting walls <NUM>, the first reinforcing member <NUM>, and the blocking wall <NUM>. In this way, the antenna bottom cover <NUM> is assembled to the bottom of the antenna <NUM> more stably.

<FIG> is a schematic structural diagram of the antenna bottom cover in <FIG>. Referring to <FIG>, during specific assembly of the antenna bottom cover <NUM> to inner surfaces of the connecting walls <NUM>, a first sliding groove <NUM> may be formed on an inner wall of each of the two connecting walls <NUM>, and the first sliding groove <NUM> extends from an end of the connecting wall <NUM> away from the blocking wall <NUM> toward the blocking wall <NUM>. Correspondingly, as shown in <FIG>, a first sliding rail <NUM> matching the first sliding groove <NUM> is formed on a side wall of the antenna bottom cover <NUM>. The first sliding rail <NUM> is stored in the first sliding groove <NUM>. The assembly of the antenna bottom cover <NUM> can be completed merely by causing the first sliding rail <NUM> of the antenna bottom cover <NUM> to slide into the first sliding groove <NUM> from one end of the first sliding groove <NUM>.

By means of the first sliding rail <NUM> and the first sliding groove <NUM> that are disposed, the antenna bottom cover <NUM> can be conveniently inserted between the two connecting walls <NUM>, thereby improving assembly efficiency of the antenna bottom cover <NUM>. In addition, since the first sliding rail <NUM> is snapped in the first sliding groove <NUM>, the antenna bottom cover <NUM> is prevented from moving in an extending direction at a specific angle to the first sliding rail <NUM>, thereby improving assembly stability of the antenna bottom cover <NUM> in the wiring groove <NUM>. For example, the first sliding rail <NUM> is snapped in the first sliding groove <NUM>. In this way, the antenna bottom cover <NUM> can be prevented from moving in a direction perpendicular to the first sliding rail <NUM>, thereby preventing the antenna bottom cover <NUM> from disengaging from the bottom opening of the wiring groove <NUM>.

To enhance the assembly stability of the antenna bottom cover <NUM>, a width of the first sliding rail <NUM> may be set to be equal to a width of the first sliding groove <NUM>. In this way, a side wall of the first sliding rail <NUM> can be closely attached to the groove wall of the first sliding groove <NUM>, so that the first sliding rail <NUM> is more stable in the first sliding groove <NUM>.

During specific configuration of the first sliding groove <NUM> in this embodiment of this application, a recess may be formed on the inner surface of the connecting wall <NUM>. Alternatively, a protruding strip <NUM> may extend from the inner surface of the connecting wall <NUM> toward inside of the wiring groove <NUM>, and a recess formed between the protruding strip <NUM> and the connecting wall <NUM> may be used as the first sliding groove <NUM>. The arrangement of the first sliding groove <NUM> is not specifically limited in this embodiment of this application.

<FIG> is a rotated cross-sectional view of <FIG>. Referring to <FIG>, a slot <NUM> may be further formed on the inner wall of each connecting wall <NUM>, a snap <NUM> matching the slot <NUM> is disposed on the side wall of the antenna bottom cover <NUM>, and the snap <NUM> is snapped in the slot <NUM>. By means of the arrangement, not only the stability of the antenna bottom cover <NUM> between the two connecting walls <NUM> is improved, but also the connection structure between the antenna bottom cover <NUM> and the connecting walls <NUM> is simplified, thereby improving the efficiency of assembling the antenna bottom cover <NUM> to the bottom of the antenna <NUM>.

A protrusion <NUM> is disposed on an end of the first sliding groove <NUM> close to the blocking wall <NUM>, and the slot <NUM> on the connecting wall <NUM> may be a recess formed between the protrusion <NUM> and the blocking wall <NUM>. The snap <NUM> may be disposed in an extending direction of the first sliding rail <NUM>, and a gap e (shown in <FIG>) for snapping the protrusion <NUM> is formed between the snap <NUM> and the first sliding rail <NUM>. In this way, when the antenna bottom cover <NUM> is slid toward the inside of the wiring groove <NUM>, the snap <NUM> in the extending direction of the first sliding rail <NUM> spans the protrusion <NUM> to be snapped into the recess between the protrusion <NUM> and the blocking wall <NUM>, thereby preventing the antenna bottom cover <NUM> from moving in the extending direction of the first sliding rail <NUM>.

It may be understood that, when the snap <NUM> is snapped into the recess between the protrusion <NUM> and the blocking wall <NUM>, the protrusion <NUM> in the connecting wall <NUM> is snapped into the gap e between the snap <NUM> and the first sliding rail <NUM>. A width of the gap e along the extending direction of the first sliding rail <NUM> may be equal to a width of the protrusion <NUM>. In this way, the antenna bottom cover <NUM> is further prevented from moving in the extending direction of the first sliding groove <NUM>.

During specific configuration of the snap <NUM> in this embodiment of this application, the snap may be a bump extending outward from the side wall of the antenna bottom cover <NUM>. The bump may be integrally formed with the antenna bottom cover <NUM>.

In addition, at least part of a surface of an end of the snap <NUM> away from the first sliding rail <NUM> may be configured as an inclined surface n (referring to <FIG>). The inclined surface n faces an end away from the first sliding rail <NUM>. For example, a side of the bump disposed on the antenna bottom cover <NUM> away from the first sliding rail <NUM> forms the inclined surface n. A lower end of the inclined surface n is away from the first sliding rail <NUM>, and an upper end of the inclined surface n is close to the first sliding rail <NUM>. In this way, the bump can conveniently span the protrusion <NUM> on one end of the first sliding groove <NUM> to be snapped into the recess between the protrusion <NUM> and the blocking wall <NUM>, thereby improving efficiency of assembling the antenna bottom cover <NUM> and the antenna <NUM>.

It should be noted that, a distance between a top surface of the lower end of the inclined surface n and a side surface of the antenna bottom cover <NUM> is less than a distance between a top surface of a high end of the inclined surface n and the side surface of the antenna bottom cover <NUM>.

In a possible implementation, a second sliding groove <NUM> (referring to <FIG>) may be further formed on the inner walls of each of the two connecting walls <NUM>. The second sliding groove <NUM> extends from the end of the connecting wall <NUM> away from the blocking wall <NUM> to the blocking wall <NUM>.

The second sliding groove <NUM> is spaced apart from the first sliding groove <NUM>. For example, the first sliding groove <NUM> is disposed close to the first reinforcing member <NUM>, and the second sliding groove <NUM> is disposed away from the first reinforcing member <NUM>. A second sliding rail <NUM> matching the second sliding groove <NUM> is formed on the side wall of the antenna bottom cover <NUM>, and the second sliding rail <NUM> is embedded in the second sliding groove <NUM>, so as to further improve the efficiency of assembling the antenna bottom cover <NUM> and the antenna <NUM>, and ensure stability of the antenna bottom cover <NUM> in an extending direction perpendicular to the second sliding rail <NUM>.

The second sliding rail <NUM> is configured as an outer edge portion extending from the bottom of the antenna bottom cover <NUM>. Therefore, a groove wall of the second sliding groove <NUM> close to the bottom end of the connecting wall effectively blocks the outer edge portion, thereby protecting the outer edge portion. In this way, the outer edge portion of the antenna bottom cover <NUM> is effectively prevented from being knocked by an external object.

In addition to the above connection manners, the antenna bottom cover <NUM> in this embodiment of this application may alternatively be fixed in the wiring groove <NUM> by means of bonding or screw connection. The manners of connection between the antenna bottom cover <NUM> and the connecting wall <NUM> as well as the blocking wall <NUM> are not specifically limited in this embodiment of this application.

A first limiting portion <NUM> and a second limiting portion <NUM> (referring to <FIG>) are disposed on a side of the rotary shaft seat <NUM> in this embodiment of this application facing the hangers <NUM>. For example, in this embodiment of this application, the first limiting portion <NUM> and the second limiting portion <NUM> are disposed on each two opposite end surfaces of the rotary shaft seat <NUM>.

The first limiting portion <NUM> is configured to prevent the antenna <NUM> at a used position from rotating around the shaft pin <NUM>, so that the antenna <NUM> does not shake in the used state, thereby ensuring that a signal transmitted by the antenna <NUM> is more stable. In addition, the first limiting portion <NUM> that is disposed can further fix the antenna <NUM> during the rotation of the antenna. That is to say, as long as the hangers <NUM> of the antenna <NUM> are rotated to the first limiting portions <NUM>, the antenna <NUM> can be ensured to be at the used position, so that positioning of the antenna <NUM> at the used position is more rapid and accurate.

The second limiting portion <NUM> is configured to prevent the antenna <NUM> at a stored position from rotating around the shaft pin <NUM>, so that the antenna <NUM> can be stably stored on the upper surface a of the housing <NUM> without shaking. In addition, the second limiting portion <NUM> that is disposed further fixes the antenna <NUM> that is stored. That is to say, the antenna <NUM> can be stored merely by rotating the hangers <NUM> of the antenna <NUM> to the second limiting portion <NUM>. Therefore, accurate and efficient fixing of the antenna <NUM> at the stored position is achieved.

During specific implementation, the first limiting portion <NUM> may include a first groove formed on the rotary shaft seat <NUM>, and the second limiting portion <NUM> includes a second groove formed on the rotary shaft seat <NUM>. The first groove and the second groove both extend along a radial direction of the rotary shaft seat <NUM>. A preset included angle exists between the first groove and the second groove. A protruding portion <NUM> is formed on a side of each of the two hangers <NUM> facing the rotary shaft seat <NUM>. The protruding portion <NUM> extends into the first groove when the antenna <NUM> is at the used position, and the protruding portion <NUM> extends into the second groove when the antenna <NUM> is at the stored position.

For example, when the antenna <NUM> is required to be stored, the antenna <NUM> starts to be rotated, so that the protruding portion <NUM> on the inner surface of the hanger <NUM> is first disengaged from the first groove, and then the movable end of the antenna <NUM> is continuously rotated toward the upper surface a of the housing <NUM> until the antenna <NUM> encounters a stop. That is to say, the protruding portion <NUM> is snapped into the second groove on the rotary shaft seat <NUM>. In this way, storing of the antenna <NUM> is completed. When the antenna <NUM> is required to be used, the movable end of the antenna <NUM> starts to be rotated away from the housing <NUM>, so that the protruding portion <NUM> on the hanger <NUM> is disengaged from the second groove, and then the antenna <NUM> is further rotated until the antenna <NUM> encounters a stop. That is to say, the protruding portion <NUM> is snapped into the first groove, and the rotation of the antenna <NUM> is stopped. At this time, the antenna <NUM> is at the used position.

A specific value of the preset included angle between the first groove and the second groove may be adjusted according to an actual requirement for the stored position and the used position of the antenna <NUM>. For example, the preset included angle between the first groove and the second groove may be a right angle. Therefore, the antenna <NUM> can reach the used position merely by means of rotation by <NUM>° from the stored position.

In this embodiment of this application, the first limiting portion <NUM> and the second limiting portion <NUM> are configured as groove structures, and the protruding portions <NUM> (referring to <FIG>) matching the grooves are respectively disposed on the inner walls of the hangers <NUM>. In this way, the antenna <NUM> in the used state or the stored state is stabilized, and the structures of the first limiting portion <NUM> and the second limiting portion <NUM> are simplified, thereby improving manufacturing and assembly efficiency of the router <NUM> in this embodiment of this application.

Two ends of each of the first groove and the second groove respectively extend to an outer edge of the rotary shaft seat <NUM>, and
two ends of the protruding portion <NUM> extend to an outer edge of the hanger <NUM>. In this way, contact areas between the protruding portions <NUM> of the hangers <NUM> and the grooves on the rotary shaft seat <NUM> are increased, so that the hangers <NUM> can be stabilized in an entire radial direction, thereby improving the stability of the antenna <NUM> in the used state and the stored state.

In the description of the embodiments of this application, it should be noted that, unless otherwise explicitly specified and defined, the terms "mount", "connect", and "connection" should be understood in a broadest sense, for example, fixed connection, indirect connection by a medium, or internal communication between two elements or an interaction relationship between the two elements. A person of ordinary skill in the art may understand the specific meanings of the foregoing terms in the embodiments of this application according to specific situations.

Claim 1:
A router (<NUM>) comprising a housing (<NUM>), at least one rotary shaft seat (<NUM>), and an antenna, wherein
the rotary shaft seat is disposed on one end of the housing, a shaft pin is inserted through the rotary shaft seat, one end of the antenna is movably sleeved on the shaft pin, and an other end of the antenna is located on a side of a front of the housing; and
a shielding portion (<NUM>) extends from an end of the housing where the rotary shaft seat is disposed, the shielding portion and the housing are integrally formed as a whole, the rotary shaft seat is located on a side of the shielding portion facing a back of the housing, and an end of the shielding portion away from the housing extends to at least a side of the rotary shaft seat away from the housing, and
wherein the router further comprises two ribs disposed opposite to each other, wherein the two ribs respectively extend from two ends of the shielding portion toward a side where the rotary shaft seat is disposed; and
the ribs shield at least the shaft pin on two sides of the rotary shaft seat,
wherein the router is configured such that the antenna can be stored on the front of the housing.