KR20150083463A - Antenna device - Google Patents

Abstract

In an antenna device, according to one of various embodiments of the present disclosure, the antenna device comprises: an antenna module; an RRH (Radio Remote Head) which receives signals from the antenna module and a base station; an attaching and detaching module and an antenna module which detachably fixates the RRH to the antenna module by enabling the RRH to move toward a first direction and toward a second direction which is an opposite direction to the first direction; and a connecting module which is provided on a surface in opposite to the RRH to each other and electrically connects the antenna module to the RRH.

Description

ANTENNA DEVICE,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an antenna apparatus, and more particularly, to an antenna apparatus capable of attaching and detaching an RRH (Radio Remote Head) for receiving a signal from an antenna and a base station.

BACKGROUND ART [0002] As wireless mobile communication services become popular, an antenna device that provides a wireless network environment capable of providing a more stable service has been spread and expanded. Particularly, wireless mobile communication service is using 4G mobile communication technology based on LTE (Long Term Evolution) which enables various data signals to be transmitted and received through 2G (2 Generation) through 3G, which enabled only a wire communication. The antenna device for 4G mobile communication is installed together with the existing 3G to share the installation location. However, a 3G repeater (hereinafter referred to as a '3G RRH') that receives signals from a 3G antenna and a base station, which is connected to an antenna based on 3G, and a 4G antenna, And 4G repeaters (hereinafter referred to as " 4G RRHs (Radio Remote Heads) ") that receive signals from base stations are formed separately from each other.

An antenna device having such a structure is required to separate the entire antenna from the outer wall for replacement due to malfunction or failure of the RRH. Accordingly, not only the mobile communication service signal for 4G is cut off but also the signal for the mobile communication service of the 3G antenna 11a, which is well used, is cut off, and the existing 3G mobile communication service can not be used.

 An antenna device according to an embodiment of the present disclosure is intended to provide an antenna device in which an RRH is integrally formed with an antenna module, and an RRH can easily be mounted on and dismounted from an antenna module.

In addition, the antenna device according to the embodiment of the present disclosure is intended to provide an antenna device capable of facilitating the electrical detachment of the antenna module and the RRH when the RRH is detached from the antenna module.

Thus, an antenna device according to one of the various embodiments of the present disclosure includes: An antenna device comprising: an antenna module; An RRH (Radio Remote Head) for receiving signals from the antenna module and the base station; A detachable module for detachably fixing the RRH to the antenna module by allowing the RRH to move in a first direction and a second direction perpendicular to the first direction; And a connection module that is provided on mutually facing surfaces of the antenna module and the RRH, and electrically connects the RRH and the antenna module.

The antenna device according to the embodiment of the present invention as described above can form the RRH as one body with the antenna module, thereby facilitating the fastening of the outer wall of the antenna device.

Also, in the antenna device fastened to the outer wall, the RRH can be easily attached and detached from the antenna module, so that there is an advantage that the RRH can be easily replaced due to malfunction or failure.

Also, connection of the connection module for electrical coupling between the RRH and the antenna module can be facilitated.

In addition, the antenna device of the present disclosure has a blind mating structure in which the terminals of the connection module for electrically connecting the RRH and the antenna module are not exposed to the outside, so that a stable connection structure can be maintained, There is an advantage that it can be improved.

FIG. 1 is a view showing a state in which an antenna device according to an embodiment of the present disclosure is installed on an outer wall 10. FIG.
Fig. 2 is a perspective view showing a state in which the antenna device according to the first embodiment of the present invention is installed on the outer wall 10. Fig.
3 is a view illustrating a guide unit coupled to a rear surface of an antenna module in an antenna apparatus according to an embodiment of the present disclosure.
4 is a view showing a first guide fixing portion in an antenna device according to an embodiment of the present disclosure.
5 is a view showing a second guide fixing portion in an antenna device according to an embodiment of the present disclosure.
6 is a view illustrating a state in which a sliding portion is provided in an RRH in an antenna apparatus according to an embodiment of the present disclosure.
7 is a diagram illustrating a connection module in an antenna device according to an embodiment of the present disclosure;
FIGS. 8 and 9 are views showing the actual connection state of the connection module in the antenna device according to the embodiment of the present disclosure.
10 to 12 are views showing the rear surface of the RRH in the antenna apparatus according to the embodiment of the present disclosure.
Figs. 13 and 14 are diagrams showing the driving of the fixing portion of the concealment operating portion in the antenna device according to the embodiment of the present disclosure. Fig.
FIG. 15 is a diagram illustrating a process of attaching and detaching an RRH in an antenna module in an antenna device according to an embodiment of the present disclosure; FIG.

Hereinafter, an embodiment of the antenna of the present disclosure will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the lengths of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. It is also to be understood that the following terms are defined in terms of their functionality in the various embodiments of the present disclosure, which may vary depending on the user, operator's intent or custom. Therefore, definitions of these terms should be made based on the contents throughout this specification.

Further, in describing various embodiments of the present disclosure, ordinal numbers such as 1, 2, and so on are used, but they are for distinguishing objects of the same name from each other, and the order may be arbitrarily set, The preceding description can be applied mutatis mutandis.

Prior to the description of the present disclosure, the first direction X refers to the direction from one side to the other side of the antenna module 110 installed on the outer wall 10, and is indicated in the X-axis direction in the drawings. The second direction Y refers to a direction in which the antenna module 110 and the outer wall 10 provided on the outer wall 10 are opposed to each other. In addition, there is a gravity direction Z perpendicular to the first and second directions, and the direction in which the antenna module 110 is installed on the outer wall 10 is the gravity direction Z, and in the drawings, the direction is indicated by the Z axis direction.

FIG. 1 is a view showing a state in which an antenna device according to an embodiment of the present disclosure is installed on an outer wall 10. FIG. Fig. 2 is a perspective view showing a state in which the antenna device according to the first embodiment of the present invention is installed on the outer wall 10. Fig. 1 and 2, an antenna device 100 according to an embodiment of the present disclosure is installed on an upright support (hereinafter referred to as 'outer wall 10') such as an outer wall 10. The antenna device 100 includes an antenna module 110, a radio remote head (RRH) 120 disposed to face the antenna module 110 and a fixing part Modules 21 and 22, respectively. The antenna device 100 of the present disclosure includes a detachable module 150 and a connection module 160 so that the RRH 120 is detachably installed in the antenna module 110, So that the antenna module 110 and the RRH 120 are blind mated.

The antenna module 110 and the RRH 120 are disposed facing each other face to face. Upper and lower portions of the antenna module 110 are coupled to the fixing modules 21 and 22 and are supported on the outer wall 10 through the fixing modules 21 and 22. [ The RRH 120 is slidably moved in the first direction X and the second direction Y on the side of the detachable module 150 and the connection module 160 is connected to the RRH 120 Has a concealed coupling structure that is concealed when it is moved in a direction in which the antenna module 110 is closely contacted with the antenna module 110 in a second direction, and is electrically coupled in a concealed state.

The antenna module 110 may be an antenna capable of 3G mobile communication service or an antenna capable of 4G mobile communication service. The antenna module 110 is formed to be elongated in the gravity direction Z substantially. The rear surface of the antenna module 110 is fixed to the outer wall 10 by the fixing modules 21 and 22 and the fixing modules 21 and 22 are mounted on the upper and lower sides of the antenna module 110 So as to support the antenna module 110 on the outer wall 10. A connection module 160 electrically connected to an RRH 120 described later is provided on a rear surface of the antenna module 110, that is, a surface provided toward the outer wall 10. [

The RRH (Radio Remote Head) 120 is a module for receiving signals from the antenna module 110 and the base station. The RRH 120 is formed long in the gravity direction Z, similar to the antenna module 110. That is, the RRH 120 is mounted along the Z direction to the rear surface of the antenna module 110. Although not shown, the RRH 120 may be provided with a main board, a power amplifying unit (PAU), a power supply unit (PSU), and a heat sink inside the RRH 120 . The RRH 120 is detachably mounted on the rear surface of the antenna module 110 installed on the outer wall 10. The RRH 120 is positioned between the antenna module 110 and the outer wall 10 and is disposed in the first direction X and the second direction Y in the detachable module 150 provided on the rear surface of the antenna module 110 And has a structure in which it is slidably moved and removed. A connection module 160 electrically connected to the rear surface of the antenna module 110 is disposed on the front surface of the RRH 120. The sliding portion 140 is mounted on the guide portion 130, which will be described later, on the upper and lower sides of the RRH 120, respectively.

The sliding portion 140 is located at the top and bottom of the RRH 120. The sliding portion 140 is slidably mounted on or removed from the antenna module 110, specifically, the guide portion 130, which will be described later. The sliding portion 140 includes first sliding protrusions 141a protruding upward in the upper circumferential surface of the circumferential surface of the RRH 120 and first sliding protrusions 141b protruding upward from the rear surface of the RRH 120 And second sliding protrusions 142a protruding in the direction of the outer wall 10 at the lower portion. The detailed configuration will be described in detail in the description of the configuration of the detachable module 150, which will be described later.

The detachable module 150 is configured to be detachable from the antenna module 110 and the detachable module 150 may include the guide part 130 and the sliding part 140. The detachable module 150 guides the RRH 120 to be slid in the first direction X and the second direction Y on the side of the antenna module 110 and moves the RRH 120 to the antenna module 110 And can be fixed to the rear surface. When the RRH 120 is fixed to the rear surface of the antenna module 110, the attaching / detaching module 150 primarily guides the RRH 120 to move from one side of the antenna module 110 to the other side. When the RRH 120 is guided primarily in the first direction X, the RRH 120 is spaced apart from the rear surface of the antenna module 110 by a predetermined distance. If the RRH 120 is secondarily guided in the second direction Y, that is, in the direction facing the rear side of the antenna module 110, the RRH 120 is positioned at a predetermined distance from the rear surface of the antenna module 110, (110).

As described above, the detachable module 150 may include the guide portion 130 and the sliding portion 140. First, the guide unit 130 is provided on the rear surface of the antenna module 110. The guide unit 130 guides the movement of the RRH 120, specifically, the sliding unit 140 so that the RRH 120 is slidably moved in the first direction X and the second direction Y. [ The guide unit 130 is provided so that the RRH 120 can be closely fixed to the rear surface of the antenna module 110 when the RRH 120 slides in the second direction Y. [

3 is a view illustrating a guide unit coupled to a rear surface of an antenna module in an antenna apparatus according to an embodiment of the present disclosure. Referring to FIG. 3, the guide unit 130 may include a first guide fixing unit 131 and a second guide fixing unit 132. The first guide fixing portion 131 fixes / supports the upper portion of the RRH 120 and guides the sliding movement of the first sliding protrusions 141a described later. The second guide fixing portion 132 fixes / supports the lower portion of the RRH 120 and guides sliding movement of the second sliding protrusions 142a described later.

4 is a view showing a first guide fixing portion in an antenna device according to an embodiment of the present disclosure. 4, the first guide fixing part 131 is provided on the rear surface of the antenna module 110 so as to protrude from the rear surface of the antenna module 110. The upper surface fixing modules 21 and 22 and the lower surface fixing module 21, 22). The first guide fixing part 131 is provided on the upper portion of the RRH 120 to slide on the sliding part 140, specifically a first sliding part 141 described later in the first direction X and a sliding movement in the second direction Y ) Guide the sliding movement. A first sliding portion 141 is seated on the first guide fixing portion 131. The first guide fixing part 131 includes a first guide plate 131a for guiding the sliding movement of the first sliding part 141 in the first direction X and the second direction Y, And a first coupling plate 131d that fixes the antenna module 131 to the antenna module 110. [ The first guide plate 131a protrudes from the rear surface of the antenna module 110 toward the outer wall 10. The first guide plate 131a may include a first rail 131b and first grooves 131c. The first rail part 131b guides the sliding movement of the first sliding part 141 in the first direction (X). The first grooves 131c are adjacent to each other along the first rail 131b and are openings drawn in the second direction Y from the first rail 131b. The first grooves 131c guide movement of the first sliding part 141 in the second direction Y. When the first sliding protrusions 141a slid in the first direction X are moved in the second direction Y so as to be drawn into the first grooves 131c, the first sliding protrusions 141c And is seated and fixed to the first groove portions 131c. When the first sliding protrusions 141a and 141a that are seated and fixed in the first groove portions 131c are displaced in the second direction Y so as to be separated from the first groove portions 131c, The sliding protrusions 141a are moved to the first rail part 131b side.

The first groove portions 131c and the first sliding protrusions 141a and the second groove portions 132c and the second sliding protrusions 142a described below are formed along the fastening direction of the RRH 120. [ It can be different in size. Specifically, when three first groove portions 132ca, 132cb, 132cc are provided as in the embodiment of the present disclosure, the first groove portion 132cc (hereinafter referred to as " A first groove portion 132cb (hereinafter referred to as a "first B groove") adjacent to the first A groove 132cc positioned at the very first entry and a first groove portion 132cb The size of the groove portion 132ca (hereinafter, referred to as 'first C groove') gradually increases. That is, the first A groove 132cc has the smallest dimension and the first C groove 132ca has the largest dimension.

The size of the first sliding protrusions 141ac, 141ab, 141aa engaged with the first sliding protrusions 141ac, 141ab, 141aa is firstly referred to as a first sliding protrusion 141ac A first sliding protrusion 141ab adjacent to the first C sliding protrusion 141ac and a first sliding protrusion 141b positioned laterally at the first rail 131b, (Hereinafter, referred to as 'first A-shaped sliding protrusion') is gradually reduced. That is, the first C sliding protrusion 141ac has a relatively largest size, and the first A sliding protrusion 141aa has a relatively smallest size.

It is preferable that the size of the first A-shaped groove 131cc and the size of the first A-shaped sliding protrusion 141aa are equal to each other or substantially the same size so that they can be engaged with each other. It is preferable that the first B-shaped groove 131cb and the first B-shaped sliding protrusion 141ab are provided so as to have the same or substantially similar size and to be able to engage with each other. It is preferable that the first C-shaped groove 131ca and the first C-shaped sliding protrusion 141ac are provided so as to have the same or substantially similar size and to be able to engage with each other.

Accordingly, when the largest first C sliding protrusion 141ac is seated and moved on the first rail 131b, the smallest first A groove 131cc and the adjacent first B groove 131cb pass through. However, the first C sliding protrusion 141ac is the largest in size and has a size different from that of the first A groove 131cc and the first B groove 131cb so that it does not enter the first A groove 131cc and the first B groove 131cb Do not. Therefore, the first C sliding protrusion 141ac passing through the first A groove 131cc and the first B groove 131cb can be seated in the first C groove 131ca.

Likewise, the first B sliding protrusion 141ab is seated on the first rail 131b after the first C sliding protrusion 141ac, and passes through the first A groove 131cc. However, since the first A-shaped groove 131cc is smaller than the first B-shaped sliding protrusion 141ab, the first B-shaped sliding protrusion 141ab moves without being seated in the first A-shaped groove 131cc. When the first B sliding protrusion 141ab is positioned at the position of the first B groove 131cb, the first sliding protrusion 141aa is positioned at the first A groove 131cc. Accordingly, the first B sliding protrusion 141ab can be seated in the first B-groove 131cb, and the first A-shaped sliding protrusion 141aa can be seated in the first A-shaped groove 131cc. That is, the first groove portions 131c and the first sliding protrusions 141a, which are coupled to each other, have the same size, but the size between the neighboring first groove portions 131c, The RRH 120 may be positioned at a precise position on the rear surface of the antenna module 110. [ The first connection part 161 provided on the rear surface of the antenna module 110 and the second connection part 162 of the RRH 120, which are provided on the rear surface of the antenna module 110, Can be accurately engaged with each other.

5 is a view showing a second guide fixing portion in an antenna device according to an embodiment of the present disclosure. 5, the second guide fixing part 132 is spaced apart from the first guide fixing part 131 and is provided on the rear surface of the antenna module 110. Specifically, the second guide fixing portion 132 is located at a lower portion of the rear surface of the antenna module 110. In the embodiment of the present disclosure, the second guide fixing portion 132 is connected to and fixed to the lower fixing module 22, for example. In the antenna device 100 according to one embodiment of the present disclosure, an upper fixing module 21 and a lower fixing module 22 are provided for fixing the antenna module 110. [ The lower fixing module 22 of the two fixing modules 21 and 22 is connected to the second guide fixing part 132 and configured as one body. The lower portion of the antenna module 110 may be fixed to the outer wall 10 by the lower fixing module 22 and the second guide fixing portion 132. [ Further, the second guide fixing portion 132 fixes and supports the lower portion of the RRH 120. The second guide fixing portion 132 is connected to the lower fixing module 22 to fix the antenna module 110 to the outer wall 10 and to support the lower surface of the RRH 120 will be.

The second guide fixing portion 132 may include a sliding portion 140 mounted on the lower portion of the RRH 120, specifically, a sliding movement of the second sliding protrusions 142a in the first direction X, And guides the sliding movement in the direction (Y). And the second guide fixing portion 132 is seated with the second sliding protrusions 142a. The second guide fixing part 132 includes a second guide fixing part 132 for fixing the second sliding protrusions 142a to the second guide plate 142 for guiding sliding movement in the first direction X and the second direction Y 132a and a second coupling plate 132f for fixing the second guide plate 132a to the antenna module 110. [ The second guide plate 132a protrudes from the rear surface of the antenna module 110 toward the outer wall 10. The second guide plate 132a may include a second rail part 132b and second groove parts 132c. The second rail portion 132b guides sliding movement of the second sliding portion 142 in the first direction X. [ The second grooves 132c are adjacent to each other along the second rail part 132b and are openings drawn in the second direction Y in the second rail part 132b. The second grooves 132c guide movement of the second sliding portion 142 in the second direction. When the second sliding protrusions 142a slid in the first direction X are moved in the second direction Y so as to be drawn into the second grooves 132c, the second sliding protrusions 142c And is seated and fixed to the second groove portions 132c. When the second sliding protrusions 142a that are seated and fixed in the second groove portions 132c are displaced in the second direction Y so as to be detached from the second groove portions 132c, (142a) is moved to the second rail portion (132b) side.

As described above, as the sizes of the first and second sliding protrusions 131c and 141a are different along the fastening direction of the RRH 120, 132c and the second sliding protrusions 142a may be different in size along the direction in which the RRH 120 is fastened. Specifically, in the case where three second grooves 132c are provided as in the embodiment of the present disclosure, the second groove 132cc (hereinafter referred to as " 2A " A second groove portion 132cb (hereinafter referred to as a "second B groove 132cb") adjacent to the second A groove 132cc positioned at the innermost position and a second groove portion 132cb And the size of the second groove portion 132ca (hereinafter referred to as "second C groove 132ca") gradually increases. That is, the second A-groove 132cc has the smallest dimension and the second C-groove 132ca has the largest dimension.

The size of the second sliding protrusions 142a engaging with the second sliding protrusions 142a is firstly referred to as a second sliding protrusion 142ac which is first seated on the second rail 132b. A second sliding protrusion 142ab adjacent to the second sliding protrusion 142ac and a second sliding protrusion 142b positioned at the second lowest position, The second sliding protrusion 142aa, and the second sliding protrusion 142aa) are sequentially reduced in size. That is, the second C sliding protrusion 142ac has a relatively largest size and the second A sliding protrusion 142aa has a relatively smallest size.

In addition, it is preferable that the size of the second A-shaped groove 132cc and the size of the second A-shaped sliding protrusion 142aa are the same or substantially the same size so that they can be engaged with each other. The size of the second B-shaped groove 132cb and the size of the second B-shaped sliding protrusion 142ab may be the same or substantially the same size so that they can be engaged with each other. It is preferable that the second C grooves 132ca and the second C sliding protrusions 142ac are provided so as to have the same or substantially similar size and to be able to engage with each other.

Therefore, when the second largest C sliding protrusion 142ac is seated and moved on the second rail 132b, the second smallest A groove 132cc and the adjacent second B groove 132cb pass through. However, the second C sliding protrusion 142ac is the largest in size and has a size different from that of the second A-shaped groove 132cc and the second B-shaped groove 132cb so as not to enter the second A-shaped groove 132cc and the second B- Do not. Therefore, the second C sliding protrusion 142ac passing through the second A-shaped groove 132cc and the second B-shaped groove 132cb can be seated in the second C-shaped groove 132ca.

Likewise, the second B sliding protrusion 142ab is seated on the second rail portion 132b after the second C sliding protrusion 142ac, and passes through the second A groove 132cc. However, since the second A-shaped groove 132cc is smaller than the second B-shaped sliding protrusion 142ab, the second B-shaped sliding protrusion 142ab moves without being seated in the second A-shaped groove 132cc. When the second B sliding protrusion is placed at the position of the second B groove 132cb, the second A sliding protrusion 142aa is positioned at the position of the second A groove 132cc. Thus, the second B sliding protrusion 142ab can be seated in the second B groove 132cb, and the second A sliding protrusion 142aa can be seated in the second A groove 132cc.

That is, the first grooves 131c, the first sliding protrusions 141a, the second grooves 132c, and the second sliding protrusions 142a described above have the same size as each other. However, the size between the first grooves 131c and the first sliding protrusions 141a are different from each other, and the size between the second grooves 132c and the size between the second sliding protrusions 142c The RRH 120 can be positioned at a precise position on the rear surface of the antenna module 110 according to the sliding movement of the RRH 120. [ The first connection part 161 provided on the rear surface of the antenna module 110 and the second connection part 160 provided on the rear surface of the RRH 120 can be positioned at the rear surface of the antenna module 110, (162) can be accurately engaged. The second guide fixing part 132 may be connected to the lower fixing module 22 and may include side support plates 132d and 132e so as to support the rear surface of the RRH 120. [ The side support plates 132d and 132e are provided on both sides of the second guide plate 132a and are opposed to each other. The side support plates 132d and 132e are coupled between the antenna module 110 and the lower fixing module 22 to form a mounting space for the RRH 120 and fix the antenna module 110 to the outer wall 10. One of the side support plates 132d and 132e is provided with a door portion 132e that is rotated about a rotation axis parallel to the gravity direction Z to turn on and off the side surface of the RRH 120. [ The door portion 132e fixes and supports the RRH 120 and fixes and supports the antenna module 110 to the outer wall 10 when the door portion 132e is closed. Further, when the door portion 132e is rotated, the portion closed by the door portion 132e is exposed and opened so that the RRH 120 can be removed or inserted. The RRH 120 may be detached or mounted through the side surface of the antenna module 110 where the door portion 132e is opened.

6 is a view illustrating a state in which a sliding portion is provided in an RRH in an antenna apparatus according to an embodiment of the present disclosure. 6, the sliding portion 140 is provided on the RRH 120 and is slid in the first direction X and the second direction Y in engagement with the guide portion 130, . The sliding portion 140 is installed at the upper portion and the lower portion of the RRH 120, respectively. The sliding portion 140 is mounted on the first guide portion 131 and the second guide portion 132 located at the upper and lower portions of the antenna module 110 and is slidingly moved. The sliding part 140 may include a first sliding module 141 and a second sliding module 142 coupled to the first and second guide parts 131 and 132.

The first sliding module 141 is positioned around the upper portion of the RRH 120 and may include a first support portion 141b and first sliding protrusions 141a.

The first support portion 141b is coupled to the upper periphery of the RRH 120, and the first sliding protrusions 141a are provided adjacent to each other on one side. The first support portion 141b is elongated in the first direction X and is fastened to the upper surface of the RRH 120. [ In the present disclosure, the first support portion 141b is fastened to the RRH 120 using a fastening member such as a screw, for example.

The first sliding protrusions 141a protrude from one surface of the first support portion 141b and protrude upward from the upper portion of the RRH 120. [ In one embodiment of the present disclosure, three first sliding protrusions 141a are provided on the first support portion 141b. In addition, the number of the first groove portions 131c, into which the first sliding protrusions 141a are inserted and fixed, may also be provided adjacent to each other along the first rail portion 131b. However, the number of the first sliding protrusions 141a and the number of the first groove portions 131c are not limited thereto. The number of the first sliding protrusions 141a and the number of the first grooves 131c may be determined by a coupling force or a supporting force between the antenna module 110 and the RRH 120 or a sliding force between the guide portion 130 and the sliding portion 140 It can be changed and modified in consideration of movement and seating. In the embodiment of the present disclosure, the first sliding protrusions 141a are mounted on the upper portion of the RRH 120 while being provided on the first supporting portion 141b. However, the present invention is not limited thereto, The sliding protrusions 141a may be provided directly on the upper surface of the RRH 120. [ That is, the first support portions 141b may be provided on the RRH 120 in a state where the first support portions 141b are provided with the first sliding protrusions 141a, but the first support portions 141b may not be provided The first sliding protrusions 141a may be coupled to the upper surface of the RRH 120 so that the first sliding protrusions 141a are adjacent to each other. The first sliding protrusions 141a protrude from the upper surface of the first support portion 141b and are rotatably supported on the first support portion 141b about a rotation axis parallel to the gravity direction Z do. The first sliding protrusions 141a are rotated so that when the first sliding protrusions 141a are seated on the guide portion 130 to be slid and moved, the first sliding protrusions 141a are moved in the gravity direction Z, it is possible to facilitate the sliding movement in the first rail part 131b and the first groove parts 131c.

The second sliding module 142 is located at the lower rear of the RRH 120 and may include a second support portion 142b and second sliding protrusions 142a.

The second support portion 142b is coupled to the lower portion of the rear side of the RRH 120 in a first direction X and the second sliding protrusions 142a are adjacent to one side thereof. In the present disclosure, the second support portion 142b is fastened to the lower rear portion of the RRH 120 by using a fastening member such as a screw.

The second sliding protrusions 142a protrude from one surface of the second support portion 142b and protrude from the rear surface of the RRH 120 in a direction opposite to the second direction Y in the direction of the outer wall 10. [ In one embodiment of the present disclosure, three second sliding protrusions 142a are provided on the second support portion 142b. In addition, the number of the second groove portions 132c, into which the second sliding protrusions 142a are inserted and fixed, may also be provided adjacent to each other along the second rail portion 132b. However, the number of the second sliding protrusions 142a and the number of the second groove portions 132c are not limited thereto. The number of the second sliding protrusions 142a and the number of the second grooves 132c may be determined by a coupling force or a supporting force between the antenna module 110 and the RRH 120 or a sliding force between the guide portion 130 and the sliding portion 140 It can be changed and modified in consideration of movement and seating. Although the second sliding protrusions 142a are mounted on the lower rear surface of the RRH 120 in a state in which the second sliding protrusions 142b are provided in the embodiment of the present disclosure, the present invention is not limited thereto. For example, the second sliding protrusions 142a may be provided directly under the rear surface of the RRH 120. That is, the second support portion 142b may be provided on the RRH 120 while the second support portion 142b is provided with the second sliding protrusions 142a, but the second support portion 142b may not be provided The second sliding protrusions 142a may be coupled to the lower portion of the rear surface of the RRH 120 in the first direction X so that the second sliding protrusions 142a are adjacent to each other in the first direction X, Or variations. The second sliding protrusions 142a protrude from one side of the second supporting portion 142b and are rotatably mounted on the second supporting portion 142b about a rotation axis parallel to the second direction Y do. The second sliding protrusions 142a are rotatably provided so that when the second sliding protrusions 142a are seated on the guide portion 130 and are slidingly moved and seated therebetween, the second sliding protrusions 142a are moved in the second direction It is possible to facilitate the sliding movement in the second rail part 132b and the second groove parts 132c while rotating around the rotation axis parallel to the Y direction.

7 is a diagram illustrating a connection module in an antenna device according to an embodiment of the present disclosure; FIGS. 8 and 9 are views showing the actual connection state of the connection module in the antenna device according to the embodiment of the present disclosure. 7 to 9, a connection module 160 for electrically connecting the antenna module 110 and the RRH 120 to each other is provided on the rear surface of the antenna module 110 and the front surface of the RRH 120 module . The connection module 160 includes a first connection part 161 and a second connection part 162.

The first connection part 161 protrudes from the rear surface of the antenna module 110 and the second connection part 162 protrudes from the RRH 120 and is in close contact with the first connection part 161. The second connection portion 162 is linearly moved to the first connection portion 161 by the driving of the external fixing module 170 to be described later in a state in which the first connection portion 161 and the second connection portion 162 are in close contact with each other, do. Also, by driving the external fixing module 170, the fixing portion 163 rotates to be caught by the engaging portion 164, and the first connecting portion 161 can be kept fixed to the second connecting portion 162 .

The first connection portion 161 may include a first terminal portion 161b and a first housing 161a. The first housing 161a is provided around the first terminal portion 161b to surround the first terminal portion 161b. The first housing 161a covers the first terminal portion 161b and protrudes from the rear surface of the antenna module 110. [ The first housing 161a is inserted into the second housing 162a of the second connection portion 162 and fixed.

The first terminal portion 161b protrudes from the rear surface of the antenna module 110. The terminal portion of the second connection portion 162 to be described later (hereinafter referred to as a second terminal portion 162b) may be rotated along the screw surface, And can be linearly moved in the second direction. The first terminal portion 161b is electrically connected to the second terminal portion 162b by moving the second terminal portion 162b in a linear direction toward the first terminal portion 161b. The first terminal portion 161b is opposed to the second terminal portion 162b of the second connection portion 162 when the RRH 120 is in close contact with the rear surface of the antenna module 110. [ When the external fixing module 170 to be described later is driven while the first terminal portion 161b and the second terminal portion 162b are opposed to each other, the second terminal portion 162b is linearly moved toward the first terminal portion 161b, 2 terminal portion 162b. The first terminal portion 161b and the second terminal portion 162b are electrically connected to each other by driving the external fixing module 170 in a direction opposite to the first terminal portion 161b and the second terminal portion 162b, The electrical coupling between the two ends can be broken.

The second connection portion 162 may include a second terminal portion 162b and a second housing 162a.

The second housing 162a is provided to cover the second terminal portion 162b around the periphery of the second terminal portion 162b. The second housing 162a is in close contact with the first housing 161a so that the first terminal portion 161b and the second terminal portion 162b are electrically connected to each other in a state of being hermetically sealed by the first and second housings 161a and 162a. Or the connection is released.

As mentioned above, on the inner side of the second terminal portion 162b, a thread is formed which can be engaged with the thread provided on the outer surface of the first terminal portion 161b. The second terminal portion 162b is linearly moved in the second direction X while rotating along the thread of the outer surface of the first terminal portion 161b according to the driving of the external fixing module 170 to be described later. The second terminal portion 162b is moved in the second direction X so that the second terminal portion 162b can be electrically coupled to the first terminal portion 161b or can be separated from the first terminal portion 161b.

10 to 12 are views showing the rear surface of the RRH in the antenna apparatus according to the embodiment of the present disclosure. Figs. 13 and 14 are diagrams showing the driving of the fixing portion of the concealment operating portion in the antenna device according to the embodiment of the present disclosure. Fig. 10 to 14, the first housing 161a and the second housing 162a can be driven to connect or disconnect the electrical connection of the first and second terminal portions 161b and 162b in a state in which the first housing 161a and the second housing 162a are in close contact with each other 162c, 162d, 162e, 162f, 162g, 162h, 162n, 162m.

The shielding operation portions 162c, 162d, 162e, 162f, 162g, 162h, 162n, and 162m drive the second terminal portion 162b to the first terminal portion 161b side through the side surface of the RRH 120 to enable electrical connection 162d, 162h, 162n, 162m for fixing the driving portions 162d, 162e and the state in which the second terminal portion 162b is moved toward the first terminal portion 161b.

The driving units 162d and 162e are coupled with the first terminal unit 161b and the second terminal unit 162b without visually confirming the driving according to the driving of the external fixing module 170. [ That is, the first terminal portion 161b and the second terminal portion 162b are held by the first housing 161a and the second housing 162a in close contact with the first housing 161a and the second housing 162a, It is not exposed to the outside. Accordingly, the driving units 162d and 162e linearly move the second terminal unit 162b toward the first terminal unit 161b while being surrounded by the first housing 161a and the second housing 162a, and the second terminal unit 162b, To the first terminal portion 161b, or to release the engagement.

The driving portions 162c and 162d are provided inside the second housing 162a and include first and second gear portions 162c and 162d for driving the second terminal portion 162b toward the first terminal portion 161b And a groove 162c is formed in the second housing 162a so that the first gear portion 162c provided inside the second housing 162a can be driven from the outside of the RRH 120. [

The first gear portion 162e is formed long inside the second housing 162a in the Y-axis direction and rotates about the Y-axis by the external fixing module 170 on the rotation axis. The end of the first gear portion 162e is connected to the groove 162c of the second housing 162a. Thus, the external fixing module 170 is inserted into the groove 162c and coupled with the first gear portion 162e.

The second gear portion 162d is provided around the end of the end portion of the second terminal portion 162b and is engaged with the first gear portion 162e. The second gear portion 162d is provided so as to linearly move the second terminal portion 162b in the X axis direction while rotating the X axis about the rotation axis as the first gear portion 162e rotates.

The first gear portion 162e and the second gear portion 162d may be formed of a rack gear and a pinion gear, a pair of spur gears, or a worm gear. However, the engagement of the first gear portion 162e and the second gear portion 162d is not limited to this, and the second gear portion may be driven by driving the first gear portion to move the second terminal portion 162b to the first terminal portion 161b, and the structure or form or structure of the structure can be changed as much as possible.

The fixed portions 162f, 162g, 162h, 162n and 162m are parallel to the inner surface of the second housing 162a and are connected to the driving portions 162d and 162e, specifically the first gear portion 162e, And is rotated or rotated according to the rotation of the gear portion 162e to release the engagement. The fixed portions 162f, 162g, 162h, 162n, and 162m may include a first fixed gear 162n and a second fixed gear 162m that mesh with each other, a retaining ring 162f, and a pin 162g. The first fixed gear 162n is configured to rotate according to the rotation of the external fixing module 170. The second fixed gear 162m meshes with the first fixed gear 162n and rotates about a rotation axis parallel to the rotation axis of the first fixed gear 162n. The latching ring 162f is provided on the outer surface of the second fixed gear 162m and rotates in accordance with the rotation of the second fixed gear 162m to catch or release the pin 162g. When the second terminal portion 162b is electrically connected to the first terminal portion 161b by the driving of the external fixing module 170, the latching ring 162f is caught and fixed to the pin 162g so that the terminal portions 161b and 162b ) Can be maintained.

 FIG. 15 is a diagram illustrating a process of attaching and detaching an RRH in an antenna module in an antenna device according to an embodiment of the present disclosure; FIG. The operation of attaching and detaching the RRH 120 to the antenna module 110 in a state where the antenna device 100 is supported on the outer wall 10 will be described with reference to FIG. The upper part of the antenna module 110 is supported on the outer wall 10 by the upper fixing module 21 and the lower part of the antenna module 110 is fixed on the outer wall 10 And is supported on the outer wall 10 by a second guide fixing portion 132 coupled to the lower fixing module 22. When the antenna module 110 is fixed to the outer wall 10, a space for mounting the RRH 120 is formed between the antenna module 110 and the outer wall 10.

The first slide protrusions 131b protruded from the rear surface of the antenna module 110 are inserted between the first rail portion 131b of the first guide fixing portion 131 and the second rail portion 132b of the second guide fixing portion 132 141a and the second sliding protrusions 142a are received, and the RRH 120 is slidably moved in a first direction X by applying a force.

The first sliding protrusions 141a and the second sliding protrusions 142a slide in the first and second rails 131b and 132b, respectively. When the RRH 120 is positioned opposite to the rear surface of the antenna module 110, the first sliding protrusions 141a are positioned in the first grooves 131c and the second sliding protrusions 142a are positioned in the first grooves 131c. 2 groove portions 132c. The first sliding protrusions 141a are seated in the first grooves 131c when the RRH 120 is applied with a force in the rear direction (referred to as the second direction Y) of the antenna module 110, The protrusions 142a are seated in the second grooves 132c and the RRH 120 is moved to the rear surface of the antenna module 110 so that the connection module 160 is in close contact with each other.

Specifically, the first housing 161a and the second housing 162a are seated and sealed so that the first terminal portion 161b and the second terminal portion 162b provided therein are not exposed to the outside. The first terminal portion 161b and the second terminal portion 162b are spaced apart from each other by a predetermined distance and are positioned before the electrical connection. The external fixing module 170 is drawn through the groove 162c on the side surface of the second housing 162a to drive the first gear portion 162e and 163b. The second gear portion 162d connected to the first gear portion 162e is rotated and the second terminal portion 162b is connected to the first terminal portion 162b by rotating the first gear portion 162e by driving the external fixing module 170. [ The second terminal portion 162b is moved to the first terminal portion 161b side so that the second terminal portion 162b is electrically coupled to the first terminal portion 161b. Further, the external fixed module 170 is driven to rotate the first fixed gear 162n. The second fixed gear 162m is rotated in accordance with the rotation of the first fixed gear 162n to move the retaining ring 162f coupled to the second fixed gear 162m to the pin 162g side, Is fixed to the pin 162g.

In this manner, the connection module 160 has a blind mating structure, so that it is possible to maintain the stable connection as well as the protection of the terminal portions. The door portion 132e of the second guide fixing portion 132 connected to the lower fixing module 22 is turned off so that the RRH 120 can be supported on the rear surface of the antenna module 110. [

The operation of separating the RRH 120 coupled to the rear surface of the antenna module 110 from the antenna module 110 will be described. First, the side of the RRH 120 is opened by rotating the door portion 132e. The external fixing module 170 is drawn into the second connecting portion 162 and concretely the groove 162c of the second housing 162a to release the fixing of the fixing portions 162f, 162g, 162h, 162n, 162m, After releasing the engagement of the portions 162f, 162g, 162h, 162n, and 162m, the second terminal portion 162b is moved from the first terminal portion 161b to release the electrical coupling.

First, the external fixing portions 162f, 162g, 162h, 162n, and 162m are driven to release the engagement of the retaining ring 162f caught by the pin 162g. Specifically, the external fixing module 170 is connected to the first fixed gear 162n to rotate the first fixed gear 162m. The second fixed gear 162m rotates in accordance with the rotation of the first fixed gear 162n and the retaining ring 162f connected to the second fixed gear 162m is released from the pin 162g.

After the engagement of the fixing portions 162f, 162g, 162h, 162n and 162m is released, the driving portion 162 is driven through the external fixing module 170 to electrically connect the first terminal portion 161b and the second terminal portion 162b Release the binding. The external fixing module 170 is drawn into the groove 163c to be coupled to the first gear portion 162e and rotated. As the first gear portion 162e rotates, the second gear portion 162d rotates in the direction opposite to the first direction and rotates the second terminal portion 162b in the opposite direction to the first. The second terminal portion 162b is linearly moved in a direction away from the first terminal portion 161b while rotating in the opposite direction to the first direction. The second terminal portion 162b is disconnected from the first terminal portion 161b and is electrically disconnected from the second terminal portion 162b.

In this state, the RRH 120 is pulled in the second direction Y away from the antenna module 110 and pulled out in the first direction X on the outer side from the side of the antenna module 110. That is, the RRH 120 is moved in the second direction (Y) and the first direction (X). When the RRH 120 is pulled in the second direction Y, the first sliding protrusions 141a are disengaged from the first grooves 131c and positioned on the first rail part 131b, The first grooves 142a are separated from the second grooves 132c and positioned on the second rail part 132b. In this state, when the RRH 120 is pulled in the first direction X, the first sliding protrusions 141a are slid along the first rail part 131b, and the second sliding protrusions 142a are moved 2 rail part 132b and the RRH 120 is released from the detachable module 150. [

The antenna device 100 according to an embodiment of the present disclosure is configured such that at the rear surface of the antenna module 110 the RRH 120 is slidably moved in the first direction X and the second direction Y, And can be easily attached and detached. In addition, since the connection module 160 is provided in the facing direction of the RRH 120 and the antenna module 110 and the hermetically coupled structure is provided, the coupling strength of the first and second terminal portions 161b and 162b is improved, It is possible to protect the first and second terminal portions 161b and 162b from being coupled with each other in an external environment or the like.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

100: antenna device 110: antenna module
120: RRH 130: guide portion
140: sliding part 150: attaching / detaching module
160: connection module 170: external fixing module

Claims (12)

In the antenna device,
An antenna module;
An RRH (Radio Remote Head) for receiving signals from the antenna module and the base station;
A detachable module detachably fixing the RRH to the antenna module by allowing the RRH to move in a first direction and a second direction perpendicular to the first direction; And
And a connection module provided on mutually facing surfaces of the antenna module and the RRH, the connection module electrically connecting the RRH and the antenna module.
The mobile terminal according to claim 1,
A guide unit provided on a rear surface of the antenna module and guiding the RRH in the first direction and the second direction and fixing the RRH according to the second sliding movement; And
And a sliding portion that is provided to the RRH and is mounted on the guide portion and slidably moved in the first direction and the second direction.
3. The apparatus according to claim 2,
A first guide fixing part provided on the rear surface of the antenna module and supporting and coupling the upper surface of the RRH; And
And a second guide fixing part coupled between the antenna module and the fixing module, fixing the antenna module, and supporting and coupling the lower surface of the RRH.
The method of claim 3,
The first guide fixing portion
A first rail portion protruding from the rear surface of the antenna module and guiding the sliding movement of the sliding portion in the first direction;
And a plurality of first groove portions for moving the sliding portion in the second direction to seat and fix the sliding portion,
The second guide fixing portion
A second rail part fixed between the fixed module and the antenna module and guiding the sliding movement of the sliding part in the first direction;
And a plurality of second grooves for moving the sliding portion in the second direction to seat and fix the sliding portion.
5. The method of claim 4,
Wherein the second guide fixing part has a side support plate facing each other between the antenna module and the fixing module,
And the side support plate is rotatably provided to open and close the mounting space of the RRH.
The sliding device according to claim 4,
A plurality of first sliding protrusions mounted on an upper circumferential surface of the RRH, sliding along the first rail portion, and being seated and fixed in the first grooves; And
And a plurality of second sliding protrusions protruding toward the outer wall toward a rear surface of the RRH and slidingly moved along the second rail portion and being seated and fixed in the second grooves.
The method according to claim 6,
The first sliding protrusions are protruded in the gravity direction and are rotatable around a rotation axis parallel to the gravity direction,
Wherein the second sliding protrusions are protruded in a direction perpendicular to the gravity direction and are rotatable about a rotation axis parallel to a direction perpendicular to the gravity direction.
The method according to claim 6,
The first grooves have different sizes of the first grooves adjacent to each other along the first rail,
And the second grooves have different sizes of the second grooves adjacent to each other along the second rail.
9. The method of claim 8,
The first grooves and the second grooves sequentially increase in size along the fastening direction of the RRH,
The first sliding protrusions and the second sliding protrusions are sequentially reduced in size along the fastening direction,
The first sliding protrusion and the second sliding protrusion are seated in the first and second recesses corresponding to the size of the first sliding protrusion and the second sliding protrusion according to the sliding movement of the RRH.
2. The apparatus of claim 1,
A first connection part protruding from a rear surface of the antenna module;
A second connection part protruding from the front surface of the RRH and being positioned opposite to the first connection part and coming into close contact with the RRH in the second direction sliding movement; And
And a concealment operating portion provided on a side surface of the second connection portion and electrically connecting the first connection portion in an adhered state to the second connection portion.
11. The method of claim 10,
Wherein the first connection part and the second connection part are in close contact with each other while the RRH is slidingly moved in the second direction to the antenna module,
Wherein the second connection portion is moved on the first connection portion by driving the concealment operation portion, and the first connection portion and the second connection portion are electrically connected to each other.
[12] The apparatus of claim 11,
A terminal portion electrically connected to the first connection portion;
A first driving unit for moving the terminal unit in the forward and backward directions for moving the terminal unit; And
And a second driving unit connected to the first driving unit and exposed to the outside to drive the first driving unit.

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