JP3188799U - Combined small diameter dual frequency omnidirectional antenna - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a combined small-diameter dual-frequency omnidirectional antenna having a small downward tilt angle of an antenna and a small degree of incongruity, high consistency, strong interference resistance, and a simple structure in an operating wave stage. offer. A printing plate, a microstrip omnidirectional pendulum 5, a metal circular tube pendulum in which a printing plate and a microstrip omnidirectional pendulum are placed, and a plastic strut are included, and the metal circular tube pendulum is a plastic strut. It is fixed to the printing board via a screw, and the plastic support is fixed to the printing board via a screw. In addition, the microstrip omnidirectional pendulum has two half-wave pendulums, two half-wave pendulums have four pendulum arms, and the four pendulum arms are directly connected at adjacent ends. The two half-wave pendulums are placed in parallel, have a metal microstrip ground wire 6 between the two half-wave pendulums, and the distance from the metal microstrip ground wire to the two half-wave pendulums is equal. [Selection diagram] Fig. 1

Description

  The present invention is related to the antenna device technical field, and more specifically, to a combined small-diameter dual-frequency omnidirectional antenna.

  In the current communication system, there are cross feed, center feed and shunt feed as the feed system between the omnidirectional antenna units covered by the outdoor housing estate signal. The cross feed has a narrow antenna width, the lower tilt angle of the antenna does not match, the design of different tilt angles is relatively complicated, the matching of the standing wave ratio is not good, the gain is low instead However, there is a disadvantage that the side ripple is large instead, and the circularity of the horizontal diagram is different at each frequency, which affects the coverage. A regular shunt feed has a large antenna volume, a lot of cables, a complicated arrangement of wires, a large loss, limiting the antenna to reach very high gain, poor roundness, and production It has the disadvantages of being complicated, inconsistent and expensive. All omnidirectional antennas currently covered by outdoor housing estate signals are of a single frequency, and different communication nets require different antennas and sites for a single communication network, resulting in wasted resources.

  The purpose of the present invention is to solve the shortage of current technology, simple structure, convenient manufacture, high precision, low cost, light weight, high performance combined small diameter dual frequency An omnidirectional antenna is provided.

  In order to achieve the above object, the present invention provides a technical solution comprising a metal circular pendulum, a printing plate, a microstrip omnidirectional pendulum placed in the metal circular pendulum and a plastic support. Adopted.

  To further explain the above plan, the microstrip omnidirectional pendulum has two half-wave pendulums, the two half-wave pendulums include four pendulum arms, and the four pendulum arms are adjacent to each other. Connect directly to the other end and ground.

  The above two half-wave pendulums are placed in parallel, leaving a distance from each other.

  The metal half-strip pendulum is grounded by a metal microstrip ground line, and the distance from the metal microstrip ground line to the two half-wave pendulums is the same.

  The four arms of the two half-wave pendulums are directly connected to the metal microstrip ground line at adjacent ends, and the inner and outer ends of the pendulum arm are separated from the metal ground line by a certain distance.

  There is a rectangular microstrip that is grounded between the two metal tube pendulums.

  The microstrip omnidirectional pendulum feeds directly via the microstrip transmission line on one side of the printing plate, and a feed hole has a metal hole connecting the microstrip omnidirectional pendulum and the transmission line.

  The metal tube pendulum and the microstrip omnidirectional pendulum are aligned with each other, and the distance from the inner wall of the metal tube pendulum to the arm of the omnidirectional pendulum is increased.

  The feed method of the above metal tube pendulum is coupled and fed through the pendulum of the printing plate.

  The metal pendulum is positioned on a printing plate supported by a plastic support.

  A microstrip coplanar waveguide is connected between the two metal tube pendulums.

As an effect achieved by the present invention by adopting the above technical solution,
1. The present invention includes one metal tube and one new microstrip pendulum, the microstrip pendulum is placed in the middle of the metal tube and connected by a coplanar waveguide between the two units. Simplify, increase accuracy, greatly reduce production cost, small antenna diameter, convenient installation, strong interference resistance, simple structure, low cost, two different It has the beauty of being able to use a single antenna and station for communication networks of different frequencies.
2. One unit of the present invention has a dual-frequency omnidirectional antenna formed by one metal tube and two U-shaped microstrip pendulums. Dual frequency antenna can adjust the distance and gap between the outer metal circular tube and microstrip omni-directional pendulum and adjust the distance between two wave stages, forming a unit of ultra broadband antenna It proved that the change of the downward tilt angle of the vertical beam of the antenna in the working wave stage is small, the degree of non-circularity is small, the consistency is high, the gain is high, and the design of many units is facilitated.

It is explanatory drawing of the printing board microstrip pendulum of this invention. It is three-dimensional explanatory drawing of the antenna of this invention. It is a solid and cross-sectional explanatory drawing of the antenna of this invention.

  As shown in FIG. 1, the present invention is a combined small-diameter dual-frequency omnidirectional antenna, including a printing plate 1, a metal circular pendulum 2, a plastic support 3, a microstrip omnidirectional pendulum 5, and the above microstrip omnidirectional The pendulum 5 has two half-wave pendulums, the two half-wave pendulums are placed in parallel, the four pendulum arms are directly connected at one end and grounded, and between the two half-wave pendulums There is a metal microstrip ground line 6 that connects directly to the pendulum, and the microstrip omnidirectional pendulum 5 and the metal microstrip ground line 6 are in the same plane of the printing plate 1. Microstrip omnidirectional pendulum 5 feeds directly via microstrip feeder line 7 on the other side of printing plate 1, and metal hole 8 serves as a feed point between feeder line 7 and microstrip omnidirectional pendulum 5 Then, a signal is input to the antenna through the microstrip feeder line 7, and the microstrip feeder line 7 between the two units is connected via the microstrip coplanar waveguide transmission line 9. Between the two microstrip omnidirectional pendulums 5 is a rectangular microstrip metal ground plane.

  As shown in Figs. 2 and 3, the printing plate 1 is placed in the metal tube pendulum 2, and there is a certain gap between the microstrip omnidirectional pendulum 5 and the metal tube pendulum 2, so that the microstrip omnidirectional The energy of the pendulum 5 is directly coupled to the metal tube pendulum, the center of the metal tube pendulum 2 and the center of the microstrip omnidirectional pendulum are aligned, and the metal tube pendulum 2 is connected to the printing plate 1 by the plastic support 3 Positioned, the plastic support 3 is fixed to the printing plate with screws 4.

  The above embodiment is an optimum embodiment of the present invention, and can be further modified and improved by ordinary engineers in the field without departing from the concept of the present invention. Needless to say, it belongs to the scope of protection of the device.

1 Printing board
2 Metal circular pendulum
3 Plastic prop
4 Screw
5 Microstrip omnidirectional pendulum
6 Metal microstrip wire
7 Microstrip feeder wire
8 Feed points
9 Microstrip coplanar waveguide transmission line

Claims (10)

  A combined small-diameter dual-frequency omnidirectional antenna comprising a metal circular pendulum, a printing plate, a microstrip omnidirectional pendulum placed in the metal circular pendulum and a plastic support.   The above-mentioned microstrip omnidirectional pendulum has two half-wave pendulums, the two half-wave pendulums have four pendulum arms, and the four pendulum arms are directly connected at adjacent ends and grounded. A combined small-diameter dual-frequency omnidirectional antenna as set forth in claim 1.   Two half-wave pendulums are placed in parallel, leaving a distance between them. The combined small diameter described in claim 2, characterized in that the metal microstrip ground wire is grounded between the two half wave pendulums, and the distance from the metal microstrip ground wire to the two half wave pendulums is the same. Dual frequency omnidirectional antenna.   The four arms of the above two half-wave pendulums are directly connected to the metal microstrip ground wire at adjacent ends, and there is a certain distance from the inside and outside of the pendulum arm to the metal ground wire. A combined small diameter dual frequency omnidirectional antenna as claimed in claim 3.   2. A combined small diameter dual frequency omnidirectional antenna as claimed in claim 1 wherein there is a rectangular microstrip grounded between two metal circular pendulums.   The above-mentioned microstrip omnidirectional pendulum feeds directly via the microstrip transmission line on one side of the printing board, but there is a metal hole connecting the microstrip omnidirectional pendulum and the microstrip transmission line at the feed point. A combined small diameter dual frequency omnidirectional antenna as claimed in claim 1 characterized by the above.   2. A combination formula as set forth in claim 1, characterized in that there is a distance from the inner wall of the metal tube pendulum to the arm of the microstrip omnidirectional pendulum with the center of the metal tube pendulum and the microstrip omnidirectional pendulum centered. Small diameter dual frequency omnidirectional antenna.   The combined small-diameter dual-frequency omnidirectional antenna according to claim 1, wherein the feed method of the metal circular tube pendulum is fed by being coupled with a printing plate pendulum.   2. A combined small diameter dual frequency omnidirectional antenna as set forth in claim 1 wherein said metal pendulum is positioned on a printing plate by a plastic post.   2. A combined small-diameter dual-frequency omnidirectional antenna as set forth in claim 1, wherein the two metal tube pendulums are connected by a microstrip coplanar waveguide.

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