CN210468076U - Massive MIMO array antenna - Google Patents

Abstract

The utility model provides a large-scale MIMO array antenna, which comprises an antenna component, a radio frequency component electrically connected with the antenna component and a connecting component; the antenna assembly comprises an antenna packaging device, a reflecting plate arranged in the antenna packaging device and an antenna array arranged on the front surface of the reflecting plate; the radio frequency assembly is installed on the outer side of the antenna packaging device through a connecting assembly and is positioned on one side, back to the antenna array, of the reflector plate. The utility model discloses in, the antenna module with radio frequency assembly independently encapsulates respectively, the antenna module with radio frequency assembly carries out fixed connection through coupling assembling, has removed the antenna module with radio frequency assembly integration encapsulation is favorable to the equipment, dismantlement and the maintenance of antenna, has reduced the degree of difficulty of construction, and the reliability is high moreover, and the cost is lower.

Description

Massive MIMO array antenna

Technical Field

The utility model relates to the field of antenna technology, especially, relate to a large-scale MIMO array antenna.

Background

With the deep development of mobile communication networks, the demands of users on mobile communication data and the mobile communication data rate are explosively increased, and various hot-spot coverage scenes are endless. Research on fifth generation mobile communication technology has been developed, and a corresponding large-scale MOMO antenna array has been developed. And in particular, the determination of the 5G spectrum, has further facilitated and accelerated the commercial progress of fifth generation mobile communication networks. The 2.6GHz band is determined as the frequency spectrum used by the fifth generation mobile communication network, so that the 16T16R array antenna becomes a new massive MIMO antenna array form.

However, the existing 5G antenna unit is usually packaged integrally with the radio frequency unit, i.e. the 5G antenna unit is packaged in the radio frequency unit, and this packaging manner is inconvenient for assembly and disassembly. Meanwhile, the operation reliability and the barrier-free operation time (MTBF) of the active equipment are less than those of a passive antenna, the integrated packaging mode is not beneficial to subsequent maintenance and repair, and the antenna or the radio frequency unit is independently upgraded and replaced, and the overall replacement brings about the rise of the maintenance cost. The integrated packaging of the active device and the antenna makes heat dissipation difficult, even seriously affects the reliability of the system, brings great challenges to the design of the antenna and the radio frequency device and the reliability of materials, and greatly increases the product cost. In addition, the antenna unit and the radio frequency unit are packaged together, so that the thickness of a product is increased, and the wind resistance of the side face is increased.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a extensive MIMO array antenna convenient to installation.

In order to achieve the above object, the present invention provides the following technical solutions:

a massive MIMO array antenna comprises an antenna assembly and a radio frequency assembly electrically connected with the antenna assembly, and further comprises a connecting assembly; the antenna assembly comprises an antenna packaging device, a reflecting plate arranged in the antenna packaging device and an antenna array arranged on the front surface of the reflecting plate; the radio frequency assembly is installed on the outer side of the antenna packaging device through a connecting assembly and is positioned on one side, back to the antenna array, of the reflector plate.

Preferably, the connecting assembly comprises a first connecting piece and a second connecting piece, the first connecting piece is fixed on the outer side of the antenna packaging device and located on one side, back to the antenna array, of the reflector plate, the second connecting piece is fixed on the radio frequency assembly, and the first connecting piece and the second connecting piece are detachably connected through a fastener.

Preferably, one end of the first connecting piece is fixedly connected with the outer side of the antenna packaging device, the other end of the first connecting piece is bent upwards after extending a certain distance away from the direction of the antenna packaging device, one end of the second connecting piece is fixedly connected with the radio frequency assembly, the other end of the second connecting piece comprises a horizontal part extending towards the direction of the antenna packaging device and a bending part bending downwards after extending a certain distance, the side face of one end of the first connecting piece bending upwards is mutually abutted with one side of the bending part of the second connecting piece, and the first connecting piece and the second connecting piece are detachably connected through a fastening piece.

Preferably, a U-shaped opening is formed in the end portion of the first connecting piece, which is bent upwards, the width of the horizontal portion is smaller than or equal to that of the U-shaped opening, the horizontal portion of the second connecting piece is embedded in the U-shaped opening, and one side of the bent portion of the second connecting piece, which is close to the radio frequency component, abuts against one side of the first connecting piece, which is bent upwards and one side of the first connecting piece, which is close to the antenna packaging device.

Preferably, one end of the first connecting piece is fixedly connected with the antenna packaging device, the other end of the first connecting piece is provided with a boss, one end of the second connecting piece is fixedly connected with the radio frequency assembly, and the other end of the second connecting piece is provided with a containing groove for containing the boss.

Preferably, one end of the first connecting piece is fixedly connected with the antenna packaging device, the other end of the first connecting piece is provided with a T-shaped buckle, one end of the second connecting piece is fixed with the radio frequency assembly, and the other end of the second connecting piece is provided with a T-shaped groove matched with the T-shaped buckle.

Preferably, a gap exists between the antenna assembly and the radio frequency assembly.

Preferably, the antenna assembly further comprises a phase shifter, a feed network and a calibration network module; the antenna array comprises a plurality of subarray units which are arranged in an array mode, and each subarray unit comprises at least one radiation unit; the phase shifter and the feed network are used for parallelly connecting all the radiating units of the sub-array units together and feeding the radiating units together; the calibration network module is respectively connected with the plurality of subarray units through transmission cables, the calibration network module is provided with at least one second radio frequency port and at least one calibration radio frequency port, and the second radio frequency port and the calibration radio frequency port are connected with the radio frequency assembly through feeder connectors.

Preferably, the feeder connector is disposed on a side of the antenna packaging device close to the radio frequency component, and the antenna component is electrically connected to the radio frequency component through the feeder connector.

Preferably, the number of the radio frequency components is at least two, and the at least two radio frequency components are arranged on the outer side of the antenna packaging device in an up-down or left-right mode.

Compared with the prior art, the utility model discloses a scheme has following advantage:

the utility model discloses an among the extensive MIMO array antenna, the antenna module with the radio frequency subassembly independently encapsulates respectively, the radio frequency subassembly passes through coupling assembling detachably and installs in the antenna packaging hardware outside of antenna module, has removed the antenna module with radio frequency subassembly integration encapsulation is favorable to the equipment, the dismantlement and the maintenance of antenna, has reduced the degree of difficulty of construction, and the windage is little moreover, the radiating effect is good to the reliability is high, and the cost is lower.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

fig. 1 is a perspective view of a massive MIMO array antenna according to an embodiment of the present invention;

fig. 2 is a schematic diagram of a sub-array unit array according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a sub-array unit of the array antenna according to the present invention;

fig. 4 is a schematic view of an installation structure of a radio frequency module and an antenna module according to an embodiment of the present invention;

fig. 5 is a schematic view of an installation structure of a radio frequency module and an antenna module according to an embodiment of the present invention;

fig. 6 is an enlarged view of a portion a of fig. 5 according to the present invention;

fig. 7 is a schematic view of an installation structure of a radio frequency module and an antenna module according to a second embodiment of the present invention;

fig. 8 is an enlarged view of fig. 7 at B of the present invention;

fig. 9 is a schematic view of an installation structure of a radio frequency module and an antenna module according to a third embodiment of the present invention;

fig. 10 is an enlarged view of fig. 9 at C.

Reference numerals: 1. an antenna assembly; 11. an antenna packaging device; 111. a back plate; 112. a housing; 12. a subarray unit; 13. a phase shifter and a feed network; 14. calibrating the network module; 141. a second radio frequency port; 2. a radio frequency component; 3. a connecting assembly; 31. a first connecting member; 311. a first bent portion; 312. a U-shaped opening; 313. a boss; 314. t-shaped buckles; 32. a second connecting member; 321. a horizontal portion; 322. a second bent portion; 323. a threaded hole; 324. accommodating grooves; 325. a T-shaped groove; 33. a fastener; 4. a feeder line connector; 5. a feeder line; 6. engineering holding poles; 7. and (7) mounting frames.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below by referring to the drawings are exemplary only for explaining the present invention, and should not be construed as limiting the present invention.

It will be understood by those within the art that, unless expressly stated otherwise, the terms "comprises" and/or "comprising," when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. It will be understood that when an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. As used herein, the term "and/or" includes all or any element and all combinations of one or more of the associated listed items.

The first embodiment is as follows:

as shown in fig. 1 to 4, the utility model relates to a large-scale MIMO array antenna, including antenna module 1 and with radio frequency module 2 that antenna module 1 electricity is connected, radio frequency module 2 through coupling assembling 3 with antenna module 1 fixed connection.

The antenna assembly 1 includes an antenna packaging device 11, a reflector plate disposed in the antenna packaging device 11, an antenna array disposed on the front surface of the reflector plate, a phase shifter and feed network 13, and a calibration network module 14.

Preferably, the antenna package device includes a back plate 111 and a housing 112 connected to the back plate 111. The back plate 111 is made of, for example, sheet metal, so that it has a large structural strength. The reflective plate is fixed on the back plate 111.

The antenna array comprises a plurality of sub-array units 12 arranged in an array, wherein each sub-array unit 12 comprises at least one radiation unit, and the radiation units are preferably dual-polarization radiation units so as to radiate signals in orthogonal polarization directions. In order to facilitate feeding and make the antenna have a better directional diagram, the dual-polarized radiation units of each sub-array unit 12 feed in parallel, and the feed line ends in the same polarization direction in the sub-array units 12 are integrated into one first radio frequency port, that is, one sub-array unit 12 has two first radio frequency ports.

The phase shifter and feed network 13 is used for feeding all the radiating elements of the sub-array element 12 together in parallel and collectively, and is used for controlling the amplitude and phase of the sub-array element 12.

The calibration network module 14 is electrically connected to the plurality of sub-array units 12 through transmission cables, and specifically, the calibration network module 14 is electrically connected to the radiation units of the sub-array units 12 through a feed network and a phase shifter in sequence. The calibration network module 14 has at least one second rf port 141 and at least one calibration rf port, a feeder connector 4 for electrically connecting the antenna assembly 1 and the rf assembly 2 is disposed through the back plate 111, and the second rf port 141 and the calibration rf port are electrically connected to the rf assembly 2 fixed outside the antenna packaging apparatus 11 through the feeder connector 4. Preferably, the radio frequency assembly 2 may be connected to the feeder connector 4 by a feeder 5 or by blind insertion.

The feeder line connector 4 may be a plurality of second rf ports 141 integrated cluster connectors and a plurality of calibration rf ports integrated cluster connectors, and the two bundled feeder line connectors 4 are connected to the rf component 2, and the feeder line connector 4 may also be a single second rf port 141 and a single calibration rf port.

Preferably, the feeder line connector 4 is a bent structure, and when the radio frequency component 2 is connected to the feeder line connector 4 through the feeder line 5, the bending amplitude of the feeder line 5 is minimum, so that the damage to the feeder line 5 can be reduced, and meanwhile, the required length of the feeder line 5 can be shorter.

The radio frequency assembly 2 is installed outside the antenna packaging device 11 through a connecting assembly 3, and is located on one side of the reflector plate, which faces away from the antenna array.

Preferably, the radio frequency module 2 is mounted outside the antenna packaging device 11 through at least one, for example, four, connecting assemblies 3, and the four connecting assemblies 3 are disposed at four corner positions of the rectangular radio frequency module 2, thereby ensuring that the radio frequency module 2 is stably and fixedly mounted on the antenna packaging device 11 of the antenna assembly 1.

Preferably, after the radio frequency module 2 is fixed to the antenna packaging device 11 of the antenna assembly 1, a gap exists between the radio frequency module 2 and the antenna assembly 1, and the gap is reserved between the radio frequency module 2 and the antenna assembly 1, so that ventilation and heat dissipation are facilitated, and side wind resistance is reduced.

As shown in fig. 1, two radio frequency components 2 are provided, two radio frequency components 2 may be arranged on the outer side of the antenna packaging device 11, the feeder connector 4 is provided between two radio frequency components 2, and the connectors of the two radio frequency components 2 are both opposite to the feeder connector 4 provided between the two radio frequency components 2, so that when the two radio frequency components 2 are connected with the feeder connector 4 through the feeder 5, the required length of the feeder 5 is short, and transmission loss is reduced; by arranging the two independent radio frequency assemblies 2, the whole radio frequency assemblies 2 can be thinner, the side wind resistance is further reduced, and the assembly and disassembly are convenient.

In another embodiment, the two radio frequency assemblies 2 may be arranged side by side on the outer side of the antenna packaging apparatus 11.

The antenna packaging device 11 is further provided with a mounting rack 7 used for fixing the antenna assembly 1 and the radio frequency assembly 2 on the engineering holding pole 6, one end of the mounting rack 7 is fixedly connected with the antenna packaging device 11, and the other end of the mounting rack 7 is fixed on the engineering holding pole 6. The two ends of the mounting rack 7 can be arranged in a relatively rotating mode so as to adjust the included angle between the antenna assembly 1 and the holding pole 6 and further adjust the mechanical downward inclination angle of the antenna.

Referring to fig. 5 and 6, in the present embodiment, the connecting assembly 3 includes a first connecting member 31, a second connecting member 32, and a fastening member 33 for fixing the first connecting member 31 and the second connecting member 32 relatively.

One end of the first connecting member 31 is fixed to one side of the back plate 111 close to the radio frequency assembly 2, the other end of the first connecting member 31 extends horizontally for a distance close to the radio frequency assembly 2 and then is bent upwards to form a first bent portion 311, and the first bent portion 311 is provided with a connecting hole (not numbered in the figure, the same applies below); one end of the second connecting member 32 is fixedly connected to the rf component 2, the other end of the second connecting member 32 has a horizontal portion 321 extending horizontally toward the antenna packaging device 11 and a second bending portion 322 extending from the horizontal portion 321 for a certain distance and then bending downward, and the second bending portion 322 is also provided with a connecting hole; one side of the first bent portion 311 and one side of the second bent portion 322 are abutted against each other, the fastening member is a bolt, and the bolt penetrates through the connecting holes of the first bent portion 311 and the second bent portion 322 to fasten the first connecting member 31 and the second connecting member 32 together.

Preferably, a U-shaped opening 312 is formed at a top end of the first bending portion 311, a width of the horizontal portion 321 of the second connecting member 32 is smaller than or equal to a width of the U-shaped opening 312, and the horizontal portion 321 of the second connecting member 32 is embedded in the U-shaped opening 312 and supported by the first bending portion 311. One side of the second bending portion 322 close to the radio frequency component 2 abuts against one side of the first bending portion 311 close to the antenna packaging device 11, so that the second connecting member 32 is hung on the first connecting member 31, and the radio frequency component 2 is fixed outside the antenna packaging device 11.

Preferably, the connecting hole of the second bending portion 322 is a threaded hole 323, and the bolt penetrates through the connecting hole of the first connecting member 32 and is in threaded connection with the threaded hole 323, so that the first connecting member 31 and the second connecting member 32 can be conveniently and fixedly connected by the bolt, and meanwhile, the fixing stability of the first connecting member 31 and the second connecting member 32 can be ensured.

Example two:

as shown in fig. 7 and 8, the difference from the first embodiment is that: a boss 313 is arranged on one side of the first connecting piece 31 close to the second connecting piece 32, an accommodating groove 324 for accommodating the boss 313 is formed on one side of the second connecting piece 32 close to the first connecting piece 31, the boss 313 is embedded in the accommodating groove 324, the fastening piece 33 is a bolt, the bolt penetrates through the accommodating groove 324 and is in threaded connection with the boss 313 to fix the first connecting piece 31 and the second connecting piece 32, and then the radio frequency component 2 is fixed on the antenna component 1.

Example three:

as shown in fig. 9 and 10, the difference from the first embodiment is that: a T-shaped buckle 314 is arranged on one side of the first connecting piece 31 close to the second connecting piece 32, a T-shaped groove 325 matched with the T-shaped buckle 314 is arranged on one side of the second connecting piece 32 close to the first connecting piece 31, the T-shaped buckle 314 is connected with the T-shaped groove 325 and can slide relative to the T-shaped groove 325, the fastening piece 33 is a bolt, the bolt penetrates through the T-shaped groove 325 and is in threaded connection with the T-shaped buckle 314 to fix the relative positions of the first connecting piece 31 and the second connecting piece 32, and further the radio frequency component 2 is fixed on the antenna component 1.

To sum up, the utility model discloses a large-scale MIMO array antenna has following advantage:

1. the utility model discloses a separately encapsulate antenna module 1 and radio frequency subassembly 2, alleviate the big, the overweight problem of weight of size that whole production brought effectively, be convenient for production, transportation and installation and maintenance, great improvement production and availability factor, practice thrift the cost.

2. The utility model discloses through setting up radio frequency subassembly 2 into two, can make radio frequency subassembly 2 whole thinner, effectively utilized antenna back space, greatly practiced thrift the space resource that the antenna installation needs, improved the space reuse rate of antenna, realized the miniaturized design of antenna effectively, practiced thrift the cost; additionally the utility model discloses a set radio frequency subassembly 2 to two to can arrange about or about with radio frequency subassembly 2 according to the model adaptability of antenna, the holistic space utilization of the effective utilization antenna that can be great has reduced the installation degree of difficulty of antenna, can adapt to multiple antenna installation environment, great saving the antenna use and the cost of installation.

3. The utility model discloses in, leave the clearance between radio frequency assembly 2 and antenna module 1, be favorable to antenna module 1 and radio frequency assembly 2's natural draft heat dissipation, improved the reliability of system to greatly reduced product cost. Leaving a gap between the radio frequency assembly 2 and the antenna assembly 1 also greatly reduces side wind resistance.

The foregoing is only a partial embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims (10)

1. A massive MIMO array antenna comprising an antenna assembly and a radio frequency assembly electrically connected to the antenna assembly, characterized in that: the device also comprises a connecting component;

the antenna assembly comprises an antenna packaging device, a reflecting plate arranged in the antenna packaging device and an antenna array arranged on the front surface of the reflecting plate;

the radio frequency assembly is installed on the outer side of the antenna packaging device through a connecting assembly and is positioned on one side, back to the antenna array, of the reflector plate.

2. The massive MIMO array antenna of claim 1, wherein: the coupling assembling is including being fixed in the antenna packaging hardware outside just is located the reflecting plate is back to the first connecting piece of antenna array one side and is fixed in second connecting piece on the radio frequency subassembly, first connecting piece with the connection can be dismantled to the second connecting piece.

3. The massive MIMO array antenna of claim 2, wherein: one end of the first connecting piece is fixedly connected with the antenna packaging device, the other end of the first connecting piece extends towards the direction far away from the antenna packaging device and is bent upwards to form a first bent part, one end of the second connecting piece is fixedly connected with the radio frequency assembly, the other end of the second connecting piece comprises a horizontal part extending towards the direction of the antenna packaging device and a second bent part formed by bending the horizontal part downwards, and the first bent part and the second bent part are detachably connected through a fastening piece.

4. The massive MIMO array antenna of claim 3, wherein: the first bending part is provided with a U-shaped opening, the horizontal part is embedded in the U-shaped opening, and one side of the second bending part, which is close to the radio frequency component, abuts against one side of the first bending part, which is close to the antenna packaging device.

5. The massive MIMO array antenna of claim 2, wherein: one end of the first connecting piece is fixedly connected with the antenna packaging device, the other end of the first connecting piece is provided with a boss, one end of the second connecting piece is fixedly connected with the radio frequency assembly, and the other end of the second connecting piece is provided with a containing groove used for sleeving the boss.

6. The massive MIMO array antenna of claim 2, wherein: one end of the first connecting piece is fixedly connected with the antenna packaging device, the other end of the first connecting piece is provided with a T-shaped buckle, one end of the second connecting piece is fixed with the radio frequency assembly, and the other end of the second connecting piece is provided with a T-shaped groove matched with the T-shaped buckle.

7. The massive MIMO array antenna of claim 1, wherein: a gap exists between the antenna assembly and the radio frequency assembly.

8. The massive MIMO array antenna of claim 1, wherein: the antenna assembly further comprises a phase shifter, a feed network and a calibration network module;

the antenna array comprises a plurality of subarray units which are arranged in an array mode, and each subarray unit comprises at least one radiation unit;

the phase shifter and the feed network are used for parallelly connecting all the radiating units of the sub-array units together and feeding the radiating units together;

the calibration network module is respectively connected with the plurality of subarray units through transmission cables, the calibration network module is provided with at least one second radio frequency port and at least one calibration radio frequency port, and the second radio frequency port and the calibration radio frequency port are connected with the radio frequency assembly through feeder connectors.

9. The massive MIMO array antenna of claim 8, wherein: the feeder joint is arranged on one side, close to the radio frequency component, of the antenna packaging device, and the antenna component is electrically connected with the radio frequency component through the feeder joint.

10. The massive MIMO array antenna of claim 9, wherein: the radio frequency components are arranged at least two and are arranged at the outer side of the antenna packaging device in an up-down or left-right mode.

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