KR102214056B1 - Zig for testing small connector for transmitting super high frequency signal and zig apparatus using the zig - Google Patents

Abstract

The present invention relates to a jig for a small connector test for ultra-high frequency signal transmission and a test jig device using the same. The jig for a small connector test for ultra-high frequency signal transmission is a test jig for testing electrical characteristics of a small connector for ultra-high frequency signal transmission, comprising: an instrument connection unit connected to a transmission/reception signal terminal of an instrument; a printed circuit board for a jig having signal line terminal pads in direct contact with ultra-high frequency signal line terminals of the small connector for the ultra-high frequency transmission and having a signal pattern in which the signal line terminal pads are connected to the instrument connection unit; and a shielding body which performs electromagnetic shielding of the signal pattern of the printed circuit board for the jig, and has a connector accommodating unit for accommodating the small connector for transmitting ultra-high frequency signals connected to the transmission/reception signal terminal of the instrument. According to the present invention, the electrical characteristics of the small connector for the ultra-high frequency signal transmission can be easily tested, and electrical radiation of the signal line formed by a transmission line of the printed circuit board fixed to the test jig can be shielded while providing a low loss transmission line.

Description

A jig for testing a small connector for transmitting ultra-high frequency signals, and a jig apparatus for testing using the same.

The present invention relates to a small multi-connector test jig including an ultra-high frequency signal line, and in particular, a jig for testing a small connector for transmitting ultra-high frequency signals in which a male signal line in a multi-connector is directly connected to a signal line of a printed circuit board, and a test using the same It relates to a jig device for use.

The next-generation 5G mobile communication system communicates through a low frequency band and a high frequency band of several tens of gigahertz, and is used to connect a low frequency band emitter and a module and a high frequency band emitter of tens of gigabytes to a module inside electronic devices such as smartphones. Requires low loss RF cable. Accordingly, it is necessary to minimize the loss of the transmitted signal without being affected by the surrounding environment, and the shielding that does not affect the radiator for other purposes enables electrical measurements to be made for RF cables with excellent electrical characteristics. A separate device is required.

In a conventional PCB connector, a male connector is mounted on a PCB in which a terminal of an electric signal line transmitting an electric signal such as a cable or a wire is covered by a male connector housing. ) It is connected by being inserted into a connector (or socket). At this time, the female connector housing of the female connector is provided with a receiving member for receiving the terminal or pin of the male connector, and leakage current is generated through the receiving member, resulting in signal loss, and limiting the miniaturization of the connector. There is.

To solve this problem, the female connector has only a housing socket that accepts only the male connector housing, and there is no terminal accommodating member for accommodating the male connector housing, and the male connector terminal is used as a terminal pad on the printed circuit board. ) We developed a miniature connector for ultra-high frequency signal transmission that can achieve miniaturization by minimizing signal loss by direct contact and reducing the height of the connector significantly. It is necessary to test the electrical characteristics of the miniature connector for transmitting the ultra-high frequency signal. However, since the miniature connector for transmitting ultra-high frequency signals is small, it is difficult to physically connect directly to a measuring instrument that measures electrical characteristics. Therefore, a separate test jig capable of electromagnetic shielding the ultra-high frequency signal is required to directly connect the small connector for transmitting the ultra-high frequency signal and the measuring device.

The problem to be solved by the present invention is a jig for testing the electrical characteristics of the aforementioned miniature connector for transmitting ultra-high frequency signals, providing a low-loss transmission line and shielding the electrical radiation of a signal pattern of a printed circuit board, transmitting an ultra-high frequency signal. It is to provide a jig for testing small connectors.

Another problem to be solved by the present invention is to provide a jig device for testing a miniature connector for transmitting an ultra-high frequency signal using the jig for testing a miniature connector for transmitting an ultra-high frequency signal.

A test jig for a small connector for transmitting an ultra-high frequency signal according to the present invention for achieving the above technical problem is a test jig for testing the electrical characteristics of a small connector for transmitting an ultra-high frequency signal, comprising: a measuring instrument connection unit connected to a transmission/reception signal terminal of the measuring instrument; A printed circuit board for a jig having signal line terminal pads in direct contact with the ultra high frequency signal line terminals of the miniature connector for ultra high frequency transmission, the signal line terminal pads having a signal pattern connected to the measuring instrument connector; And a shielding body that electromagnetically shields the signal pattern of the printed circuit board for the jig, and has a connector accommodating part for accommodating a miniature connector for transmitting an ultra-high frequency signal connected to the transmission/reception signal terminal of the measuring instrument.

The shielding body is composed of an upper shielding body and a lower shielding body coupled to the upper shielding body, and the signal pattern of the printed circuit board for the jig is electromagnetically shielded by the combination of the upper shielding body and the lower shielding body, and the ultra-high frequency A connector accommodating portion for accommodating a small connector for signal transmission is formed. The signal pattern of the printed circuit board for a jig may be formed of the microstrip, stripline, coplanar waveguide (CPW), coplanar waveguide with ground (CPWG), or the like. The printed circuit board for the jig includes one of paper phenolic, epoxy, polyimide, thermosetting polyimide resin, Teflon, ceramic, and mixed insulator (composite). The jig printed circuit board has a SIW (Substrate Integrated Waveguide) function to block the leakage current and impedance matching of the signal pattern, and has a plurality of via holes through which the top plating layer and the bottom plating layer are electrically connected. do. The miniature connector for transmitting the ultra-high frequency signal is connected to a single or a plurality of ultra-high frequency signal lines, and has a shielding can that accommodates the single or multiple ultra-high frequency signal line terminals, fixes and protects the ultra-high frequency signal line terminals, and shields electromagnetic waves. (male) connector; And a connector socket installed on a printed circuit board (PCB) and fastened to the male connector by receiving a shielding can of the male connector, and connected to a ground of the printed circuit board, the male The ultra-high frequency signal line terminals of the connector are connected in direct contact with signal line terminal pads formed on the printed circuit board.

In order to achieve the above technical problem, the test jig device for a miniature connector for transmitting an ultra-high frequency signal according to the present invention is a test jig device for testing the electrical characteristics of a miniature connector for transmitting an ultra-high frequency signal, wherein the ultra-high frequency signal is connected to the transmission/reception signal terminal of the measuring instrument. A first test jig having a first connector accommodating portion for accommodating a transmission small connector (first connector); And a second connector accommodating part accommodating a small connector (second connector) for transmitting an ultra-high frequency signal connected to the first connector, and a second test jig connected to a reception signal terminal of a measuring instrument, wherein the first The test jig includes: a first instrument connection part connected to a transmission/reception signal terminal of the instrument; A printed circuit board for a first jig having signal line terminal pads in direct contact with the ultra-high frequency signal line terminals of the first connector and having a signal pattern in which the signal line terminal pads are connected to the measuring instrument connection portion; And a first connector accommodating part which electromagnetically shields the signal pattern of the printed circuit board for the first jig, and accommodates a miniature connector (first connector) for transmitting an ultra-high frequency signal connected to the transmission/reception signal terminal of the measuring instrument. A second measuring instrument connection part including a shielding body, and the second test jig being connected to a reception signal terminal of the measuring instrument; A printed circuit board for a second jig having signal line terminal pads in direct contact with the ultra-high frequency signal line terminals of the second connector and having a signal pattern in which the signal line terminal pads are connected to the second measuring instrument connection portion; And a second connector receiving part that electromagnetically shields the signal pattern of the printed circuit board for the second jig and accommodates a miniature connector (second connector) for transmitting an ultra-high frequency signal connected to the first connector. Includes.

In the jig device for testing a miniature connector for transmitting an ultra-high frequency signal according to the present invention, the first connector and the second connector are connected, and the first connector and the second connector are the first test jig and the second test. When a test jig assembly that is accommodated and mounted in a jig is referred to as a test jig assembly, the jig rail further includes a jig rail variably fixing the jig assembly according to a length of a connection line between the first connector and the second connector, and the jig rail is the A first fixing part for fixing the first test jig of the test jig assembly; A second fixing part fixing the second test jig; And a rail configured to move the second fixing part according to a length of a connecting line between the first connector and the second connector. The first fixing part is characterized in that the position is moved in a vertical direction perpendicular to the moving direction of the second fixing part by the rail.

According to the jig for testing a small connector for transmission of ultra-high frequency signals and a test jig device using the same according to the present invention, the electrical characteristics (S-parameter, insertion loss, crosstalk, radiation pattern, etc.) of the small connector for transmission of ultra-high frequency signals are easily tested. can do.

Further, according to the present invention, it is possible to provide a low-loss transmission line while shielding the electrical radiation of a signal line formed by a transmission line of a printed circuit board mounted on a test jig.

1 is a perspective view showing an embodiment of a jig device for testing a small connector for transmitting an ultra-high frequency signal according to the present invention.
2 is an exploded perspective view showing an embodiment of a jig for testing a small connector for transmitting an ultra-high frequency signal according to the present invention.
3 is a view for explaining a printed circuit board for a jig in an embodiment of a jig for testing a small connector for transmitting an ultra-high frequency signal according to the present invention.
4 is a diagram illustrating a close contact connection between a measuring instrument connection part and a shielding body in an embodiment of a jig for testing a small connector for transmitting an ultra-high frequency signal according to the present invention.
FIG. 5 is a diagram illustrating a combination of a printed circuit board for a jig and a measuring instrument connection in an embodiment of a jig for testing a small connector for transmitting an ultra-high frequency signal according to the present invention.
Figure 6 shows that in an embodiment of a jig for testing a small connector for transmitting an ultra-high frequency signal according to the present invention, a small connector for transmitting an ultra-high frequency signal is mounted on a printed circuit board for a jig.
FIG. 7 shows that the first connector and the second connector are mounted on the printed circuit board for the first and second jig in one embodiment of the jig device for testing a small connector for transmitting an ultra-high frequency signal according to the present invention.
8 is a first connector and a second connector on the printed circuit board for the first and second jig to which the first and second measuring instrument connection parts are respectively coupled in an embodiment of the jig device for testing a small connector for transmitting an ultra-high frequency signal according to the present invention. It shows that the connector is installed.
9A shows another embodiment of a signal pattern formed on a printed circuit board for a jig of a jig for testing a small connector for transmitting an ultra-high frequency signal according to the present invention.
9B shows an enlarged view of an enlarged connection portion of a jig printed circuit board connected to a connector connection portion in another embodiment of a jig for testing a small connector for transmitting an ultra-high frequency signal according to the present invention.
FIG. 10 shows another embodiment in which a printed circuit board, a measuring instrument connection, and a lower shielding body of a jig for testing a small connector for transmitting an ultra-high frequency signal according to the present invention by applying the signal pattern shown in FIGS. 9A and 9B are combined.
11 shows another embodiment of a signal pattern formed on a printed circuit board of a jig device for testing a small connector for transmitting an ultra-high frequency signal according to the present invention.
12 shows another embodiment of a jig for testing a small connector for transmitting an ultra-high frequency signal according to the present invention.
13 shows an embodiment in which a jig device for testing a small connector for transmitting an ultra-high frequency signal according to the present invention is mounted on a jig rail and fixed.
14 is an example of a test connector, which is a connector to be tested in the present invention, showing a state before the male connector and the connector socket mounted on the PCB are fastened.
15 is an example of a test connector, showing a state after the male connector and the connector socket mounted on the PCB are fastened.
16 is a bottom perspective view of the male connector and the connector socket of the test connector as viewed from the bottom.
17 is an exploded perspective view of an example of a connector socket of a test connector.
18 shows an example of elements constituting the male connector of the test connector.
19 shows an example of a plurality of coaxial cables that can be connected to the male connector of the test connector.
20 is a cross-sectional view taken along line VII-VII of the male connector shown in FIG. 14.
21 is a cross-sectional view taken along line VIII-VIII of the male connector shown in FIG. 14.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Since the embodiments described in the present specification and the configurations shown in the drawings are only preferred embodiments of the present invention, and do not represent all the technical spirit of the present invention, various equivalents that can replace them at the time of the present application And it should be understood that there may be variations.

1 is a perspective view showing an embodiment of a jig device for testing a small connector for transmitting an ultra-high frequency signal according to the present invention. An embodiment (1) of a jig device for testing a miniature connector for transmitting an ultra-high frequency signal according to the present invention includes a first test jig 10-a and a second test jig 10-b.

The first test jig 10-a includes a first connector accommodating portion 112-a for accommodating a miniature connector (first connector, 20-a) for transmitting an ultra-high frequency signal to be tested. The first connector 20-a is connected to a transmission/reception signal terminal (not shown) of a measuring instrument through a printed circuit board. The second test jig 10-b includes a second connector accommodating portion 112-b for accommodating a small connector (second connector, 20-b) for transmitting an ultra-high frequency signal to be tested. The second connector 20-b has one end connected to the first connector 20-a, and the other end connected to the reception signal terminal of the measuring instrument through a printed circuit board.

2 is an exploded perspective view showing an embodiment of a jig for testing a small connector for transmitting an ultra-high frequency signal according to the present invention. The small connector test jig 10 for ultra-high frequency signal transmission according to the present invention shown in FIG. 2 is used as a first test jig 10-a and a second test jig 10-b shown in FIG. 1 do.

The jig 10 for testing a miniature connector for transmitting an ultra-high frequency signal according to the present invention includes a measuring instrument connection 140, a printed circuit board 130 for the jig, and shielding bodies 110 and 120. The measuring instrument connection unit 140 is connected to a transmission/reception signal terminal (not shown) of the measuring instrument. The shielding body (110, 120) is composed of an upper shielding body (110) and a lower shielding body (120) coupled to the upper shielding body (110), and the combination of the upper shielding body (110) and the lower shielding body (120). By electromagnetic shielding the signal pattern, which is a transmission line formed on the printed circuit board for the jig 130, and a connector receiving portion 112 for accommodating a miniature connector for transmitting an ultra-high frequency signal connected to the transmission and reception signal terminal of the measuring instrument.

3 shows a printed circuit board 130 for a jig in an embodiment of a jig for testing a small connector for transmitting an ultra-high frequency signal according to the present invention, and reference numeral 131 denotes the upper surface of the printed circuit board 130 for a jig, Reference numeral 132 denotes the bottom of the printed circuit board 130 for a jig. On the upper surface 131 of the printed circuit board 130, signal line terminal pads 133 that directly contact the ultra-high frequency signal line terminals of the miniature connectors 20-a and 20-b for transmitting ultra-high frequency signals to be tested are formed. The signal line terminal pads 133 are provided with signal patterns 134 on the PCB, which serve as a transmission line for connecting to the measuring instrument connection unit 140. In addition, microstrip shielding walls 136-1, 136-2, and 136-3 may be formed to electrically prevent cross talk and to isolate signal lines. In addition, a number of via holes (137-1, 137-2, 137-3) block the impedance matching of the transmission line (signal pattern) and leakage current (leak radiation), and a substrate integrated waveguide (SIW) for noise shielding. ) Function and also serves as an electrical connection between the top plating layer and the bottom plating layer. In addition, a chamfer 138 may be formed on the bottom surface 132 of the printed circuit board 130 for a jig for impedance matching between the transmission line and the measuring instrument connection 140.

The material of the jig printed circuit board 130 may be any one of paper phenolic, epoxy, polyimide, thermosetting polyimide resin, Teflon, ceramic, and mixed insulator (composite). . In addition, the signal patterns 134 serving as transmission lines of the printed circuit board 130 for the jig are in the form of a microstrip, a stripline, a coplanar waveguide (CPW), a coplanar waveguide with ground (CPWG), etc. Can be formed.

4 is a diagram illustrating a close connection between the measuring instrument connection 140 and the shielding bodies 110 and 120 in an embodiment of a jig for testing a small connector for transmitting an ultra-high frequency signal according to the present invention. Referring to FIG. 4, a shape 116 is formed on a contact surface of the shielding bodies 110 and 120 in contact with the measuring instrument connecting portion 140 to be closely connected with the measuring instrument connecting portion 140 for impedance matching of signal lines.

5 is a view showing that the printed circuit board 130 for the jig and the measuring instrument connection 140 are combined in an embodiment of the jig for testing a small connector for transmitting an ultra-high frequency signal according to the present invention, (a) is a printed circuit for a jig The top surface 131 of the substrate 130 is shown, and (b) shows the bottom surface 132 of the printed circuit board 130 for a jig.

FIG. 6 shows that in one embodiment of a jig for testing a small connector for transmitting an ultra-high frequency signal according to the present invention, a small connector 150 for transmitting an ultra-high frequency signal is mounted on a printed circuit board for a jig. Referring to FIG. 6, (a) is a top view of a jig printed circuit board 130 equipped with a miniature connector 150 for transmitting ultra-high frequency signals, and (b) is a jig print on the lower shielding body 120. It shows that the circuit board 130 is installed, and the miniature connector 150 for transmitting an ultra-high frequency signal is mounted on the printed circuit board 130 for a jig.

7 is a diagram showing that in an embodiment of a jig device for testing a small connector for transmitting an ultra-high frequency signal according to the present invention, the first connector and the second connector are mounted on the printed circuit board for the first and second jig, (a) Is a top view of the first connector and the second connector mounted on the printed circuit board for the first and second jig in one embodiment of the jig device for testing a small connector for transmission of ultra-high frequency signals according to the present invention, (b) is It is a bottom view. 1 and 7, a first connector 20-a for testing electrical characteristics (S-parameter, insertion loss, crosstalk, and radiation pattern) is provided on the printed circuit board 130-a for a jig. It is mounted, and the second connector 20-b for testing electrical characteristics is mounted on the printed circuit board 130-b for the first jig. In addition, the first connector 20-a and the second connector 20-b are connected through a transmission medium 25 for transmitting an ultra-high frequency signal, for example, a coaxial cable. In addition, dielectric patterns 135-a and 135-b are formed on the bottom of the jig printed circuit boards 130-a and 130-b to insulate between signal lines serving as transmission lines for transmitting signals. 8 is a first connector and a second connector on the printed circuit board for the first and second jig to which the first and second measuring instrument connection parts are respectively coupled in an embodiment of the jig device for testing a small connector for transmitting an ultra-high frequency signal according to the present invention. It shows that the connector is installed, (a) is the top view and (b) is the bottom view.

On the other hand, when testing the electrical characteristics (S-parameter, insertion loss, crosstalk, radiation pattern) of a small connector for transmitting ultra-high frequency signals, the small connector for transmitting ultra-high frequency signals is small, so it is difficult to physically connect directly with a measuring instrument that measures electrical characteristics. . Therefore, in order to directly connect the small connector for transmitting ultra-high frequency signals and the measuring instrument, a printed circuit board for the jig is placed in order to secure a physical space to which the instrument signal terminals can be connected, and a measuring instrument connection to which the instrument signal terminal is connected to the printed circuit board for the jig is provided. do. At this time, the signal line terminal pad formed on the printed circuit board and the measuring instrument connection part have a signal pattern serving as a transmission line formed on the printed circuit board for a jig.

9A shows another embodiment of a signal pattern formed on a printed circuit board of a jig for testing a small connector for transmitting an ultra-high frequency signal according to the present invention, and FIG. 9B is another example of a jig for testing a small connector for transmitting an ultra-high frequency signal according to the present invention. In the embodiment, the printed circuit board for a jig is an enlarged view of a connection part connected to a connector connection part.

9A and 9B, the printed circuit board 190 to which the measuring instrument connection 194 is coupled in the small connector test jig for transmitting an ultra-high frequency signal according to the present invention is a signal line terminal pad 192 formed on the printed circuit board for the jig. In the -2) and the measuring instrument connection 194, a signal pattern 192-1, which functions as a transmission line, may be formed on the jig printed circuit board 192 in a radial form. In the present invention, if a physical space in which the signal terminal of the measuring instrument and the signal line terminal pad formed on the jig printed circuit board can be connected can be secured, a measuring instrument connection part for connecting the signal terminal of the measuring instrument and a signal wire terminal formed on the jig printed circuit board It is not limited to the shape of the signal pattern 192-1 between pads. Reference numeral 196 denotes an enlarged connection portion of the jig printed circuit board connected to the connector connection portion.

FIG. 10 shows another embodiment in which a printed circuit board, a measuring instrument connection, and a lower shielding body of a jig for testing a small connector for transmitting an ultra-high frequency signal according to the present invention by applying the signal pattern shown in FIGS. 9A and 9B are combined. 11 shows another embodiment of a signal pattern formed on a printed circuit board of a jig device for testing a small connector for transmitting an ultra-high frequency signal according to the present invention.

12 shows another embodiment of a jig for testing a small connector for transmitting an ultra-high frequency signal according to the present invention. Referring to FIG. 12, (a) shows a perspective view of a jig 610 for testing a miniature connector for transmitting an ultra-high frequency signal having two transmission lines for an ultra-high frequency signal. (b) shows the upper surface 611 of the printed circuit board for the jig with the small connector 616 for transmitting the ultra-high frequency signal to be tested in the test jig 610 for the small connector for transmitting ultra-high frequency signals with two transmission lines, and the measuring instrument connection ( 614), and (c) is the bottom surface 612 of the printed circuit board for the jig equipped with the small connector 616 for transmitting the ultra-high frequency signal to be tested in the test jig 610 for the small connector for transmitting ultra-high frequency signals having two transmission lines. ) And the measuring instrument connection 614 are shown.

13 shows an embodiment in which a jig device for testing a small connector for transmitting an ultra-high frequency signal according to the present invention is mounted on a jig rail and fixed. 13, in FIG. 1, the first connector 20-a and the second connector 20-b are connected, and the first connector 20-a and the second connector 20-b are When the test jig assembly (1) is received and mounted in the 1 test jig (10-a) and the second test jig (10-b), the jig rail (2) is connected to the first connector (20-a). The second connector 20-b is connected, and the jig assembly 1 is variably fixed according to the length of the signal transmission medium 25 for transmitting signals.

The jig rail 2 includes a first fixing part 710 fixing the first test jig 10-a of the test jig assembly 1 and a second fixing part 710 fixing the second test jig 10-b. 720) and a rail 730 for moving the second fixing part according to the length of the connecting line between the first connector and the second connector. The first fixing part 710 may be moved in a vertical direction 732 perpendicular to the moving direction 731 of the second fixing part 720 by the rail 730. Although the length of the signal transmission medium 25 connecting the first connector 20-a and the second connector 20-b through the jig rail 2 is varied, the test jig device can be fixed according to the length, Even if the test jig is displaced in the vertical direction, the test jig device can be fixed according to the state that it has moved up and down.

Meanwhile, in the present invention, a small connector for transmitting an ultra-high frequency signal to be tested for electrical characteristics will be described. A small connector for transmitting an ultra-high frequency signal (hereinafter, referred to as a test connector) as a test object in the test jig and test jig device according to the present invention connects a single or multiple ultra-high frequency signal lines and a printed circuit board (PCB) for transmitting an ultra-high frequency signal. A PCB connector, comprising a male connector and a connector socket. The male connector is connected to the single or multiple microwave signal lines, and includes a male connector housing for receiving the single or multiple ultra high frequency signal line terminals and fixing and protecting the ultra high frequency signal line terminals. The connector socket is installed on the printed circuit board (PCB), accommodates the male connector housing, and is fastened to the male connector. In this case, the ultra-high frequency signal line terminals of the male connector may be connected in direct contact with signal line terminal pads formed on the printed circuit board.

14 is an example of a test connector, showing a state before the male connector 20 and the connector socket 225 mounted on the PCB 215 are fastened. 15 is an example of a test connector, showing a state after the male connector 20 and the connector socket 225 mounted on the PCB 215 are fastened. 2 and 3, the housings 270, 280, and 290 of the male connector connected to the cable 240 are inserted into the connector socket 225 mounted on the PCB 125 to be fastened. At this time, the connection between the PCB and the cable 240 is in direct contact with the cable terminal formed on the bottom of the male connector and the circuit signal line terminal pad formed on the PCB 215.

16 is a bottom perspective view of the male connector 20 and the connector socket 225 of the test connector as viewed from the bottom. 17 is an exploded perspective view of an example of a test connector and a connector socket 225 mounted on the PCB 215. 16 and 17, a signal line terminal 255 of a cable is formed on the bottom of the male connector 20. The connector socket 225 may have a fastening portion 222 that is fastened with a male connector 20, and surface mount devices (SMDs) that are surface mounted on a surface of a printed circuit board (PCB, 215). ) Method or through the PCB through SIP (single in-line package), DIP (dual in-line package), QIP (quad in-line package), etc. can be mounted, and the PCB surface mounting method and penetration method are mixed Can be mounted. In addition, the connector socket 225 may be formed integrally with a PCB rather than a separate component.

When the housings (270, 280, 290) of the male connector 20 are inserted into and fastened to the connector socket 225 mounted on the PCB 125, the cable signal line terminal 255 accommodates the cable signal line terminal 255. It is in direct contact with the terminal pad 214 of the circuit signal line formed on the PCB 215 without passing through a member. As shown in FIG. 16, the connector socket 225 mounted on the PCB 125 is simplified by removing the receiving member accommodating the cable signal line terminal 260, thereby simplifying the connector socket, and the height of the connection with the male connector. It can be downsized by minimizing. The small connector for ultra-high frequency signal transmission according to the present invention can connect electrical signals including RF signals and power sources to signals or power on the PCB, and table PCs, laptop PCs, 5G smartphones, home appliances (TVs, refrigerators, washing machines, etc.) Home appliances) and other electronic devices requiring miniaturization.

On the other hand, examples of single or multiple ultra-high-frequency signal lines that are connected through a test connector and transmit ultra-high-frequency signals include coaxial cables, wires, FFC (Flexible Flat Cable), FPC (Flexible Printed Circuit), S-teflon, etc. There may be, but is not limited to the above example, all signal lines for transmitting electric signals may be included. 18 shows a coaxial cable 30 as an example of an electric signal line that can be connected to the male connector 20 of the test connector. Referring to Figure 18, the coaxial cable 30 is an inner conductor 210 used as a signal line, shields electromagnetic waves of the inner conductor 210, and an outer conductor 230 made of aluminum, copper, etc., an inner conductor It consists of a dielectric 220 that insulates and separates the outer conductor 230 from 210 and an outer jacket (jacket) that protects the outer conductor 230. The inner conductor can be used from DC to microwave and millimeter wave, and it can transmit ultra-high frequency signals of about 50GHz or more.

FIG. 19 shows an example of elements constituting the male connector 20 of the test connector, and the male connector 20 includes a coaxial cable 30 and shielding cans 270, 280, 290, and , It may further include an adapter unit 40. The coaxial cable 30 has a shell 240, an outer conductor 230 and a dielectric 220 partially stripped. The outer conductor 130 of the coaxial cable 30 may be connected to the shielding cans 270, 280, and 290. The shielding cans 270, 280, 290 accommodate, protect and fix the coaxial cable 30, and shield electromagnetic waves generated from the inner conductor 210 of the coaxial cable. The shielding cans 270, 280, and 290 may be configured by combining the lower shielding member 270, the upper shielding member 280, and the front shielding unit 290, respectively, but the lower shielding member 270 and the upper shielding member ( At least two of the 280 and the front shielding member 290 may be integrally formed, or the lower shielding member 270, the upper shielding member 280, and the front shielding member 290 may be integrally formed with one shielding member.

The adapter part 40 is made of a plurality of adapters, and the adapter 42 facilitates the connection of the inner conductor 210 of the coaxial cable 30 with the circuit signal line terminal pad 214 formed on the PCB 215 The shielding can (270, 280, 290) is formed in a shape that can be easily shielded, and consists of a conductor portion (250) and a dielectric portion (260). One end of the conductor part 250 is connected by being in contact with the signal line terminal pad 214 of the PCB 215, and the other end of the signal line 210, which is an inner conductor of the coaxial cable 30, is received and connected. When the inner conductor, which is the signal line of the cable, is received and connected to the adapter 42, the end of the conductor part 250 becomes the cable signal line terminal 255 of FIG. 4 and contacts the signal line terminal pad 214 of the PCB 215 And connected.

The dielectric part 260 serves to separate the conductor part 250 and the shielding cans 270, 280, and 290 when the conductor part 250 is accommodated in the shielding can.

The inside of the shielding cans 270, 280, 290 is provided with an adapter accommodating portion 272 having a cylindrical shape in which the adapters 42 connected in correspondence with the inner conductors 210 of a single or a plurality of coaxial cables can be accommodated. And, the adapter receiving portion 272 is the adapter 42 is accommodated and when the lower shielding can 270, the upper shielding can 280 and the front shielding can 290 are combined, each adapter is separated from each other and shielded from the shielding wall ( wall) is formed.

FIG. 20 is a cross-sectional view taken along line VII-VII of the male connector shown in FIG. 14, and FIG. 21 is a cross-sectional view taken along line VII-VII of the male connector shown in FIG. 14. 20 and 21, coaxial cables 210, 220, 230 240 and adapters 250, 260 are received, protected and shielded by shielding cans 270, 280, 290, and male connectors 20 Is inserted into the connector socket 225 mounted on the PCB 215 and fastened. In particular, FIG. 21 shows that when the lower shielding can 270, the upper shielding can 280, and the front shielding can 290 are combined, a shielding wall 275 that is separated from each other and shielded by each adapter is formed.

On the other hand, the test connector can maximize the shielding of electromagnetic waves of signal lines when coaxial cables are used as signal lines. Specifically, the shielding cans 270, 280, and 290 of the male connector 20 are connected to the outer conductor 230 of the coaxial cable 30. The conductor connector socket 215 is connected to the ground of the PCB 215. When the male connector 20 is inserted into the connector socket 225 mounted on the PCB 215 and fastened, the shielding cans 270 and 280 of the male connector 20 connected to the outer conductor 230 of the coaxial cable 30 The 290 is connected by contact with the connector socket 225 connected to the ground of the PCB 215, thereby maximizing the shielding of the signal line terminal of the male connector that directly contacts the terminal pad 214 of the PCB 215.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those of ordinary skill in the art will appreciate that various modifications and other equivalent embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the attached registration claims.

1: test jig assembly 10: test jig
10-a: first test jig 10-b: second test jig
110: upper shielding body 112: connector receiving part
112-a: first connector demand part 112-b: second connector receiving part
116: measuring instrument connection part contact shape 120: lower shielding body
130: printed circuit board for jig 131: upper surface of printed circuit board for jig
132: bottom of the printed circuit board for jig 133: signal line terminal pad
134: PCB signal pattern 135-1, 135-2: PCB dielectric section
136-1, 136-2, 136-3: microstrip shielding wall
137-1, 137-2: via hole 138: chamfer
140: measuring instrument connection part 140-a: first measuring instrument connection part
140-b: second measuring instrument connection 150: test target connector
190: Printed circuit board combined with measuring instrument connection
192-1: PCB signal pattern 192-2: Signal line terminal pad
194: measuring instrument connection part 196: measuring instrument connection part
610: test jig 611: upper surface of the jig printed circuit board
612: bottom of printed circuit board for jig 614: measuring instrument connection
616: connector to be tested 710: first fixing unit
720: second fixed government 730: rail
731: horizontal movement direction line 732: vertical movement direction line
2: Zig rail 20-a: 1st connector
20-b: second connector 25: signal transmission medium
20: male connector 210: inner conductor (signal line)
214: PCB terminal pad 215: printed circuit board (PCB)
220: dielectric 222: fastening part
225: connector socket 230: external conductor (shielding)
240: outer sheath (jacket) 250: adapter conductor
260: adapter dielectric part 270: lower shielding can
272: adapter receiving part 280: upper shielding can
290: front shielding can 30: coaxial cable
40: adapter part (internal conductor accommodating part) 42: adapter
50: coaxial cable connected with adapter 60: coaxial cable without strip

Claims (9)

delete delete delete delete delete delete In a test jig device for testing the electrical characteristics of a miniature connector for transmitting an ultra-high frequency signal,
A first test jig having a first connector accommodating portion accommodating a miniature connector (first connector) for transmitting an ultra-high frequency signal connected to a transmission/reception signal terminal of a measuring instrument; And
A second connector accommodating part accommodating a small connector (second connector) for transmitting an ultra-high frequency signal connected to the first connector, and a second test jig connected to a reception signal terminal of a measuring instrument,
The first test jig
A first measuring instrument connection part connected to the transmitting and receiving signal terminal of the measuring instrument;
A printed circuit board for a first jig having signal line terminal pads in direct contact with the ultra-high frequency signal line terminals of the first connector and having a signal pattern in which the signal line terminal pads are connected to the measuring instrument connection portion; And
The first shielding includes a first connector receiving portion for electromagnetically shielding the signal pattern of the printed circuit board for the first jig and accommodating a miniature connector (first connector) for transmitting an ultra-high frequency signal connected to the transmission/reception signal terminal of the measuring instrument Including the body,
The second test jig is
A second measuring instrument connection part connected to the receiving signal terminal of the measuring instrument;
A printed circuit board for a second jig having signal line terminal pads in direct contact with the ultra-high frequency signal line terminals of the second connector and having a signal pattern in which the signal line terminal pads are connected to the second measuring instrument connection portion; And
A second shielding body that electromagnetically shields the signal pattern of the printed circuit board for the second jig and has a second connector accommodating portion accommodating a miniature connector (second connector) for transmitting an ultra-high frequency signal connected to the first connector. Including,
When the first connector and the second connector are connected, and the first connector and the second connector are accommodated and mounted in the first test jig and the second test jig, the test jig assembly Further comprising a jig rail for variably fixing the jig assembly according to the length of the connecting line between the first connector and the second connector,
The jig rail is
A first fixing part fixing the first test jig of the test jig assembly;
A second fixing part fixing the second test jig; And
A jig device for testing a miniature connector for ultra-high frequency signal transmission, comprising: a rail configured to move the second fixing portion according to a length of a connecting line between the first connector and the second connector. delete The method of claim 7, wherein the first fixing unit
A jig device for testing a miniature connector for ultra-high frequency signal transmission, characterized in that the position is moved in a vertical direction perpendicular to the moving direction of the second fixing part by the rail.

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