KR102251907B1 - Board mounting coaxial connector - Google Patents

Abstract

The present invention relates to a broadband coaxial connector, and more specifically, to a board-mounted coaxial connector having a broadband frequency characteristic by improving a transition characteristic between a coaxial transmission line of a coaxial connector and a transmission line of a substrate.
The present invention is a coaxial connector mounted on a board, comprising a hollow cylindrical outer conductor and a central conductor formed on the inner side of the outer conductor and a dielectric body surrounded by the outer conductor and the central conductor. A first terminal portion in contact with the terminal; a first extension portion connected to the first terminal portion and extending in the axial direction of the outer conductor; an L-shaped portion connected to the first extension portion and bent in the radial direction of the outer conductor; and an L-shaped portion And a second extension part connected to and extending in the radial direction, and a second terminal part connected to the second extension part and connecting the center conductor to the circuit of the substrate, and the dielectric material is a cylindrical dielectric surrounding the first extension part Is a coaxial connector characterized in that it extends to a part of the L-shaped portion, and has an air dielectric gap in the horizontal direction with the substrate. The first extension part has a TEM (Transverse Electric and Magnetic) propagation mode, and the second extension part has a Quasi-TEM propagation mode with a transmission line structure on the same substrate as the Microstip Line, resulting in rapid propagation mode change in the L-shaped part. Therefore, by extending the dielectric of the first extension part to have a buffer propagation mode, which is an intermediate step between TEM and Quasi-TEM propagation modes, in the L-shaped part, a certain part of the air dielectric gap is formed in the horizontal direction with the substrate to obtain broadband electrical characteristics. It relates to a coaxial connector.

Description

Board mounting coaxial connector

The present invention generally relates to an electrical connector, and more specifically, to a coaxial connector having a broadband frequency characteristic by improving the transition characteristics of the board-mounted coaxial connector.

Various wireless communication systems are rapidly increasing due to the increase of mobile communication and military communication. Most wireless communication systems are connected by coaxial transmission lines that transmit microwaves. The coaxial transmission line is composed of a central conductor and an outer shield, and the central conductor and an outer shield are separated by a dielectric. In order to transmit microwaves on a printed circuit board, radio waves must be applied to an RF transmission line on a board such as a microstrip or a strip line.

Vertically mounted SMA (Sub-Miniature Series A) connectors for applying radio waves to RF transmission lines began to be used at low frequencies from 1963. In accordance with the demand for continuous high-speed transmission in the market, boards that can be used at 10GHz or higher have been developed, and board-mounted connectors have also been developed. 1 shows a conventional general-purpose board-mounted coaxial connector operating below 10 GHz.

Recently, printed circuit boards are more complex, and the frequency used in digital circuits has reached a speed of more than 40 GHz. For this reason, designers of both analog and digital circuits need a lot of time to study the design parameters of high-frequency coaxial input terminals, output terminals, and test terminals. The parameters of the printed circuit board are changed according to the electrical and mechanical performance standards. Therefore, one coaxial connector design cannot accommodate all the size, thickness, or dielectric constant of all printed circuit boards. It is impractical for many companies to develop all of the specialized coaxial connectors for different printed circuit board models.

In order to realize the broadband frequency characteristic by solving the transition structure between the coaxial connector for board mounting and the transmission lines of various printed circuit boards, it is necessary to change the transition structure of the entire coaxial connector suitable for the transition characteristic of the coaxial connector for the board.

The present invention is to minimize the problem of impedance mismatch caused by different substrates when a coaxial connector having a structure in which the central conductor is bent in an approximately L-shape is mounted on a printed circuit board having different dielectric constants and structures. It is to provide a coaxial connector with excellent characteristics.

In order to solve the above problems, the coaxial connector of the present invention includes a hollow cylindrical outer conductor, a central conductor formed inside the outer conductor, and a dielectric surrounded by the outer conductor and the central conductor, and is mounted on a board. As, the center conductor has a cylindrical shape, a first terminal portion in contact with a terminal of the connector, a first extension portion connected to the first terminal portion and extending in the axial direction of the outer conductor, and a diameter of the outer conductor connected to the first extension portion An L-shaped portion bent in the direction, a second extension portion connected to the L-shaped portion and extending in a radial direction, and a second terminal portion connected to the second extension portion and connecting the center conductor to the circuit of the substrate, and the dielectric material, It is characterized in that the cylindrical dielectric surrounding the first extension portion extends to a part of the L-shaped portion, and has a void, which is an air dielectric, in a horizontal direction with the substrate.

The coaxial connector of the present invention described above has a TEM (Transverse Electric and Magnetic) propagation mode with a center conductor structure surrounded by a circular dielectric in the first extension part, and the second extension part has a substrate such as Microstip Line. As the transmission line structure on the top has a Quasi-TEM propagation mode, rapid propagation mode conversion occurs in the L-shaped part, so the dielectric of the first extension part is extended to have a buffer propagation mode that is an intermediate step between TEM and Quasi-TEM propagation mode in the L-shaped part. As a result, a certain portion of the air dielectric gap is formed in the horizontal direction with the substrate, so that a broadband electrical characteristic can be obtained.

According to the present invention, by simplifying the center conductor and improving the structure of the dielectric, when connecting with a transmission line on a printed circuit board different from a coaxial connector, productivity is increased by using a simple cylindrical center conductor, and also at a broadband frequency. It can be used in a broadband by mitigating the electrical characteristic sensitivity.

1 is a board-mounted coaxial connector according to the prior art
2 is a coaxial connector after mounting with a board for mounting a board according to a preferred embodiment of the present invention
3 is a coaxial connector used in an embodiment of the present invention
4 is a cross-sectional view of a coaxial connector used in an embodiment of the present invention.
5 is a dielectric shape of the present invention
6 is a front view of a coaxial connector used in an embodiment of the present invention
7 is a schematic cross-sectional view of a transition structure of a coaxial connector used in an embodiment of the present invention.
8 is a simulation result according to the variables of FIG. 7
9 is a manufacturing measurement result of the coaxial connector used in the embodiment of the present invention

A preferred embodiment of the board-mounted coaxial connector according to the present invention will be described in detail with reference to the accompanying drawings, and results of actual manufacturing and measurement of the same will be described.

2 shows a state after the board-mounted coaxial connector 1 of the present invention is mounted on the board 2. The coaxial connector 1 is mounted on the board 2 so as to be perpendicular to the surface of the board 2. In order to apply a radio wave to the coaxial connector 1 mounted on the board 2, the coaxial connector that is mated with the coaxial connector 1 is fastened to perform electrical connection between the circuits formed on the board 2.

Fig. 3 is a single unit shape of the outer conductor 10, the central conductor 20, and the dielectric 30 constituting the coaxial connector 1 in a state in which the central conductor 20 is insulated from the outer conductor 10 And the coaxial connector 1 after assembly is shown.

4 is a cross-sectional view of the coaxial connector 1. The coaxial connector 1 includes an outer conductor 10, a central conductor 20, and a dielectric 30 that supports the central conductor 20 in a state insulated from the outer conductor 10. The external conductor 10 serves as a main body of the coaxial connector 1 and serves as an electrical function such as grounding, and a function of fixing to the substrate 2. In the external conductor 10, a fastening part 11, which is coupled with a mating connector corresponding terminal of the coaxial connector 1, is located at the top, and a mounting part 12, which is mounted with the board 2, is located at the bottom. The outer conductor 10 is formed into a hollow cylindrical shape by cutting a metal bar. High-precision cutting is required for use in a broadband frequency of 10 GHz or higher.

The central conductor 20 is located at the center of the inner core of the hollow cylindrical outer conductor 10, which is surrounded by a dielectric 30. The central conductor 20 is formed in the shape of an L-shaped rod.

In Fig. 4, the center conductor 20 is a first terminal portion 20a in contact with the terminal of the mating connector, a first extension portion 20b connected to the first terminal portion 20a and extending in the axial direction of the outer conductor 10. ), the L-shaped portion 20c connected to the first extension portion 20b and bent in the radial direction of the outer conductor 10, the second extended portion 20d connected to the L-shaped portion 20c and extending in the radial direction And it is provided with the 2nd terminal part 20e which connects to the 2nd extension part 20d and connects the center conductor 20 to the circuit of the board|substrate 2. The center conductor 20 is formed by pressing or cutting, and the second terminal portion 20e may be formed in a plane. The center conductor 20 is plated with gold to reduce contact and insertion loss between terminals.

In Fig. 4, a cylindrical dielectric 30 is interposed between the outer conductor 10 and the first extension portion 20b of the central conductor 20 to support the central conductor 20, and the outer conductor 10 and the center An air dielectric 31 is formed between the L-shaped portion 20c of the conductor 20 and the second extension portion 20d. A cylindrical dielectric 30 surrounding the first extension portion 20b is formed to have a void, which is an air dielectric 31, in a horizontal direction with the substrate 2 which is extended and mounted to a part of the L-shaped portion 20c. The spacing between the substrate 2 and the dielectric 30 is optimized to have a broadband transmission characteristic.

5 is a cylindrical dielectric 30 surrounding the first extension part 20b is extended to a part of the L-shaped part 20c, and two out of the diameter of the cylindrical dielectric 30 at the end of the extended cylinder It is formed to have the above-described columnar dielectric protrusion 30a. In a coaxial line requiring a characteristic of 40 GHz or higher, impedance fluctuations are sensitive due to variations in shape, so the gap difference between the substrate 2 and the dielectric 3 can be minimized with the dielectric protrusion 30a.

6 is a front view of the coaxial connector 1 viewed from the direction in which the second terminal portion 20e is located. The dielectric 30 having the dielectric protrusion 30a is formed so as to surround a part of the central conductor 20, so that the dielectric 30 functions to stably fix the central conductor 20.

7 is a cross-sectional view for a simulation experiment. When the air dielectric 31 surrounding the center conductor 20 and the second terminal portion 20c has a certain height on the substrate 2, the L-shaped portion 20c of the center conductor 20 When the distance between the dielectric 30 and the air dielectric 31 of the substrate 2 was set to h, and a three-dimensional electromagnetic field simulation was performed, the simulation result as shown in FIG. 8 was obtained. In the case of h=0.17 in FIG. 8, as a result of indicating the optimum transition structure characteristic, it has an S11 reflection characteristic of -20dB or less in DC ~ 67GHz. 9 is a measurement result of mounting the coaxial connector 1 on the board 2. As a result of the measurement, it has an S11 reflection characteristic of -10dB or less at DC ~ 67GHz. In the case of a board-mounted coaxial connector, if the measured result during board mounting is -10dB, it is evaluated as a usable connector, so the manufactured coaxial connector (1) can be called an ultra-wideband connector.

This is a center conductor structure surrounded by a circular dielectric in the first extension part 20b of the center conductor 20 and has a TEM (Transverse Electric and Magnetic) propagation mode, and the second extension part 20d of the center conductor 20 ) Has a Quasi-TEM propagation mode with a transmission line structure on the same substrate as the Microstip Line, and a rapid propagation mode change occurs in the L-shaped part (20c). By extending the dielectric of the first extension part 20b so as to have a buffer propagation mode, a certain portion of the void, which is the air dielectric 31, is formed in a horizontal direction with the substrate, thereby obtaining broadband electrical characteristics.

1: coaxial connector 2: board
10: external conductor 11: fastening part
12: Mounting unit
20: center conductor 20a: first terminal portion
20b: first extension part 20c: L-shaped part
20d: second extension part 20e: second terminal part
30: dielectric 30a: dielectric protrusion
31: air dielectric

Claims (2)

A coaxial connector mounted on a board, comprising a hollow cylindrical outer conductor, a central conductor formed inside the outer conductor, and a dielectric body surrounded by the outer conductor and the central conductor,
The central conductor,
A first terminal portion in contact with a terminal of the mating connector and connected to the first terminal portion,
A first extension part extending in the axial direction of the outer conductor,
An L-shaped part connected to the first extension part and bent in a radial direction of the outer conductor,
A second extension part connected to the L-shaped part and extending in the radial direction,
A second terminal portion connected to the second extension portion and connecting the center conductor to the circuit of the substrate,
The dielectric is,
A coaxial connector, characterized in that the cylindrical dielectric surrounding the first extension part has an air dielectric gap in a horizontal direction with the substrate on which the L-shaped part is extended and mounted.
The method of claim 1,
Coaxial, characterized in that the cylindrical dielectric surrounding the central conductor of the first extension part extends to a part of the L-shaped part, and has at least two pillar-shaped protrusions outside the diameter of the cylindrical dielectric at the end of the extended cylindrical part. connector.

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