CN218867390U - High-gain multi-port MIMO combined directional antenna - Google Patents

Abstract

The utility model discloses a high-gain multiport MIMO combined directional antenna, which comprises a reflecting plate, wherein a group of 2.5G vibrator seats, two groups of 6G vibrator seats, two groups of 3.5G vibrator seats and a group of 5G vibrator seats are assembled on the reflecting plate; the 2.5G vibrator seat is formed by assembling a 2.5G vibrator plate and a 2.5G guide plate, the 2.5G vibrator plate and the 2.5G guide plate are sleeved on the reflecting plate through M3 nut threads, and the 2.5G vibrator plate and the 2.5G guide plate are arranged in the center of the front face of the reflecting plate; the 6G oscillator seat is formed by assembling a 6G guide plate and a 6G oscillator plate, and the 6G guide plate and the 6G oscillator plate are sleeved on the reflecting plate through M3 nut threads; this high-gain multiport MIMO combination directional antenna through the setting of each subassembly on the reflecting plate, can carry out corresponding improvement to the structure of current product, makes its frequency channel satisfy 4G 5G 6G WiFi-6's requirement, and manufacturing cost obtains sufficient compression, and the organism volume is less relatively simultaneously, has solved the problem that current device index is not up to standard, the organism volume is great simultaneously not convenient for the installation.

Description

High-gain multiport MIMO combined directional antenna

Technical Field

The utility model relates to a directional antenna technical field specifically is a high-gain multiport MIMO makes up directional antenna.

Background

An antenna is a transducer that converts a guided wave propagating on a transmission line into an electromagnetic wave propagating in an unbounded medium (usually free space) or vice versa.

The existing antenna equipment has narrow frequency band and low gain, and the performance indexes of 4G, 5G and 6G, WIFI-6 can not meet the requirements; the production cost of the product is high and the production qualification rate is low.

Therefore, we propose a high gain multi-port MIMO combined directional antenna.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

Not enough to prior art, the utility model provides a high-gain multiport MIMO makes up directional aerial has solved the problem that the current device index is not up to standard, the great not convenient to install simultaneously of organism volume.

(II) technical scheme

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: a high-gain multi-port MIMO combined directional antenna comprises a reflecting plate, wherein a group of 2.5G oscillator seats, two groups of 6G oscillator seats, two groups of 3.5G oscillator seats and a group of 5G oscillator seats are assembled on the reflecting plate.

Preferably, the 2.5G vibrator holder is formed by assembling a 2.5G vibrator plate and a 2.5G directing plate, the 2.5G vibrator plate and the 2.5G directing plate are sleeved on the reflecting plate through M3 nut threads, and the 2.5G vibrator plate and the 2.5G directing plate are arranged in the center of the front surface of the reflecting plate.

Preferably, the 6G oscillator seat is formed by assembling a 6G leading plate and a 6G oscillator plate, the 6G leading plate and the 6G oscillator plate are sleeved on the reflecting plate through M3 nut threads, and the two groups of 6G leading plates and the 6G oscillator plate are respectively arranged on the upper side and the lower side of the left side of the 2.5G oscillator plate and the left side of the 2.5G leading plate.

Preferably, the 3.5G oscillator seat is formed by the assembly of 3.5G oscillator board and 3.5G introduction board, 3.5G oscillator board and 3.5G introduction board pass through M3 nut screw suit on the reflecting plate, and a set of 3.5G oscillator board and 3.5G introduction board set up between two sets of 6G oscillator seats, and another set of 3.5G oscillator board and 3.5G introduction board set up in the upper right angle department of 2.5G oscillator board and 2.5G introduction board.

Preferably, the 5G oscillator seat is formed by 5G leading board and 5G oscillator board assembly, 5G leading board and 5G oscillator board pass through M3 nut screw suit on the lateral wall of reflecting plate, and 5G leading board and 5G oscillator board set up in 2.5G oscillator board and the right lower corner department of 2.5G leading board.

Preferably, twelve groups of self-tapping screw holes which are distributed in a rectangular shape and are opposite in position are formed in the inner side of the outer edge of the reflecting plate, and the reflecting plate is assembled on the waterproof shell through the self-tapping screw holes and the fastening bolt.

(III) advantageous effects

The utility model provides a high-gain multiport MIMO makes up directional aerial. The method has the following beneficial effects:

this high-gain multiport MIMO combination directional antenna through the setting of each subassembly on the reflecting plate, can carry out corresponding improvement to the structure of current product, makes its frequency channel satisfy 4G 5G 6G WiFi-6's requirement, and manufacturing cost obtains sufficient compression, and the organism volume is less relatively simultaneously, is suitable for installation and use, has solved the problem that current device index is not up to standard, the organism volume is great is not convenient for the installation simultaneously.

Drawings

Fig. 1 is a schematic structural view of the present invention;

fig. 2 is a schematic structural diagram of the side view of the present invention.

In the figure: 1. a reflective plate; 2. 2.5G vibrator plate; 3. 2.5G lead to the plate; 4. 3.5G vibrator plate; 5. 3.5G lead to plate; 6. 5G lead-to plate; 7. 5G vibrator plate; 8. 6G lead-to plate; 9. 6G vibrator plate; 10. m3, a nut; 11. and (4) tapping screw holes.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1 and 2, an embodiment of the present invention provides a technical solution: a high-gain multi-port MIMO combined directional antenna comprises a reflecting plate 1, wherein a group of 2.5G oscillator seats, two groups of 6G oscillator seats, two groups of 3.5G oscillator seats and a group of 5G oscillator seats are assembled on the reflecting plate 1;

in the embodiment, it is to be noted that, in the high-gain multi-port MIMO combined directional antenna, the structure of the existing product can be correspondingly improved by setting each component on the reflection plate 1, so that the frequency band of the antenna meets the requirement of 4G/5G/6G/WiFi-6, the production cost is sufficiently compressed, and meanwhile, the size of the antenna body is relatively small, so that the antenna is suitable for installation and use, and the problems that the index of the existing device does not reach the standard, the size of the antenna body is large, and the antenna is inconvenient to install are solved.

In the present embodiment, it should be added that the 2.5G oscillator base is assembled by the 2.5G oscillator boards 2 and the 2.5G director board 3, the 2.5G oscillator boards 2 and the 2.5G director board 3 are screwed on the reflection board 1 by the M3 nut 10, and the 2.5G oscillator boards 2 and the 2.5G director board 3 are disposed at the center of the front surface of the reflection board 1.

In this embodiment, it should be added that the 6G oscillator base is assembled by the 6G directing plate 8 and the 6G oscillator plate 9, the 6G directing plate 8 and the 6G oscillator plate 9 are screwed on the reflection plate 1 through the M3 nut 10, and the two groups of 6G directing plates 8 and 6G oscillator plates 9 are respectively disposed on the upper and lower sides of the left side of the 2.5G oscillator plates 2 and 2.5G directing plates 3.

In this embodiment, it should be added that the 3.5G oscillator base is assembled by the 3.5G oscillator boards 4 and the 3.5G director board 5, the 3.5G oscillator boards 4 and the 3.5G director board 5 are screwed on the reflection board 1 by the M3 nut 10, one set of the 3.5G oscillator boards 4 and the 3.5G director board 5 is disposed between the two sets of 6G oscillator bases, and the other set of the 3.5G oscillator boards 4 and the 3.5G director board 5 is disposed at the upper right corner of the 2.5G oscillator boards 2 and the 2.5G director board 3.

In this embodiment, it should be added that the 5G oscillator base is assembled by the 5G director plate 6 and the 5G oscillator plate 7, the 5G director plate 6 and the 5G oscillator plate 7 are screwed on the side wall of the reflection plate 1 by the M3 nut 10, and the 5G director plate 6 and the 5G oscillator plate 7 are disposed at the lower right corners of the 2.5G oscillator plates 2 and 2.5G director plate 3.

In this embodiment, it should be added that twelve sets of tapping screw holes 11 are formed on the inner side of the outer edge of the reflector 1, which are distributed in a rectangular shape and are opposite in position, and the reflector 1 is assembled on the waterproof housing through each set of tapping screw holes 11 and the fastening bolt.

The utility model discloses a theory of operation and use flow: when the device is needed to work, each vibrator seat is assembled at a corresponding position on the outer wall of the reflecting plate 1 through the M3 nut 10, then the reflecting plate 1 and all components on the reflecting plate are assembled in the waterproof shell through the self-tapping screw hole 11 and the fastening bolt, the installation and operation are relatively convenient and fast, the adaptability is strong, the frequency band of the reflecting plate meets the requirement of 4G/5G/6G/WiFi-6, and the production cost is sufficiently compressed.

The basic principles and the main features of the invention and the advantages of the invention have been shown and described above, it will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, but that the invention may be embodied in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (6)

1. A high gain multi-port MIMO combined directional antenna, characterized by: the vibration isolator comprises a reflecting plate (1), wherein a group of 2.5G vibrator seats, two groups of 6G vibrator seats, two groups of 3.5G vibrator seats and a group of 5G vibrator seats are assembled on the reflecting plate (1).

2. A high gain multi-port MIMO combined directional antenna as claimed in claim 1, wherein: 2.5G oscillator seat is formed by 2.5G oscillator board (2) and 2.5G lead to board (3) assembly, 2.5G oscillator board (2) and 2.5G lead to board (3) and pass through M3 nut (10) screw thread suit on reflecting plate (1), and 2.5G oscillator board (2) and 2.5G lead to board (3) and set up in the positive center department of reflecting plate (1).

3. A high gain multi-port MIMO combined directional antenna as claimed in claim 1, wherein: 6G oscillator seat is drawn to board (8) and 6G oscillator board (9) by 6G and is formed by the assembly, 6G is drawn to board (8) and 6G oscillator board (9) and is passed through M3 nut (10) screw thread suit on reflecting plate (1), and two sets of 6G are drawn to board (8) and 6G oscillator board (9) and are set up respectively at 2.5G oscillator board (2) and 2.5G and draw to the left upper and lower both sides of board (3).

4. A high gain multi-port MIMO combined directional antenna as claimed in claim 1, wherein: 3.5G oscillator seat is formed by 3.5G oscillator board (4) and 3.5G lead to board (5) assembly, 3.5G oscillator board (4) and 3.5G lead to board (5) through M3 nut (10) screw thread suit on reflecting plate (1), and is a set of 3.5G oscillator board (4) and 3.5G lead to board (5) and set up between two sets of 6G oscillator seats, and another group 3.5G oscillator board (4) and 3.5G lead to board (5) and set up in 2.5G oscillator board (2) and 2.5G lead to the upper right angle department of board (3).

5. A high gain multi-port MIMO combined directional antenna as claimed in claim 1, wherein: 5G oscillator seat is led to board (6) and 5G oscillator board (7) by 5G and is formed by the assembly, 5G leads to board (6) and 5G oscillator board (7) and passes through M3 nut (10) screw thread suit on the lateral wall of reflecting plate (1), and 5G leads to board (6) and 5G oscillator board (7) and sets up in 2.5G oscillator board (2) and 2.5G and lead to the right lower corner department of board (3).

6. A high gain multi-port MIMO combined directional antenna as claimed in claim 1, wherein: twelve groups of tapping screw holes (11) which are distributed in a rectangular shape and are opposite in position are formed in the inner side of the outer edge of the reflecting plate (1), and the reflecting plate (1) is assembled on the waterproof shell through the tapping screw holes (11) and the fastening bolts in a threaded mode.

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