WO2024101801A1 - Receptacle connector and plug connector - Google Patents

Abstract

Disclosed is a receptacle connector. A receptacle connector according to one aspect of the present invention may comprise: a receptacle insulating body made of an electrically insulating material; a receptacle shield member made of a conductive material and coupled to the edge of the receptacle insulating body; and a receptacle contact unit conductively connected to the outside, wherein the receptacle contact unit may include a receptacle-compatible contact for transmitting an RF signal or a general signal.

Description

Receptacle Connectors and Plug Connectors

The present invention relates to receptacle connectors and plug connectors.

A B2B connector (board to board connector) is for internal connection between a board and a module and includes corresponding receptacle connectors and plug connectors.

Each of these receptacle connectors and plug connectors is connected to a different board. When the receptacle connector and plug connector are physically coupled to each other, different boards can be electrically connected to each other and transmit signals.

At this time, each of the receptacle connector and plug connector is configured to transmit various types of signals simultaneously using one connector.

For example, each of the receptacle connector and the plug connector includes a signal contact for transmitting a general signal, an RF contact for transmitting both RF signals, and a shield contact to prevent interference between the general signal and the RF signal.

However, in order to transmit various RF signals through one connector, the number of RF contacts included in one connector must be increased, so there is a limit to which the overall size of each receptacle connector and plug connector must also be increased.

The present invention is intended to solve the above problems, and the purpose of the present invention is to provide a receptacle connector and a plug connector that can increase the number of RF contacts while maintaining the same size as the existing one.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned can be clearly understood by those skilled in the art from the description below.

According to one aspect of the present invention, an island made of an electrically insulating material and formed to have a predetermined height in the center and a receiving groove recessed at a certain depth along the outer circumferential surface of the island are spaced at a certain distance from the island so that a receiving groove can be formed. a receptacle insulating body including an edge portion spaced apart from each other and formed to surround the island portion; a receptacle shield member made of a conductive material and coupled to the edge portion along the edge of the receptacle insulating body; and a receptacle contact portion coupled to the receptacle insulating body and electrically connected to the outside, wherein the receptacle contact portion includes a receptacle RF contact for transmitting an RF signal, a receptacle signal contact for transmitting a general signal, and an RF It includes a receptacle compatible contact for transmitting a signal or general signal and a receptacle shield contact for electrical shielding, wherein the receptacle compatible contact includes a receptacle RF contact and a receptacle signal spaced apart along the first longitudinal axis direction. Located between the contacts, it is spaced apart to face another receptacle signal contact along a second axis direction in the width direction, and the receptacle shield contact is a contact for receptacle compatibility with the receptacle RF contact spaced apart along the first axis direction. and between the receptacle compatible contact and the receptacle signal contact spaced apart along the first axis direction, and between the receptacle compatible contact and another receptacle signal contact spaced apart along the second axis direction. Provides a receptacle connector to be placed.

According to another aspect of the present invention, a closed loop-shaped protrusion made of an electrically insulating material and protruding at a predetermined height in the center, a first seating groove recessed to a predetermined depth inside the protrusion, and an outer peripheral surface of the protrusion. A plug insulating body including a second seating groove that is recessed at a certain depth along the; a plug shield member made of a conductive material and coupled to surround an edge of the plug insulating body; and a plug contact portion coupled to the plug insulating body and electrically connected to the outside, wherein the plug contact portion includes a plug RF contact for transmitting an RF signal, a plug signal contact for transmitting a general signal, and an RF It includes a plug-compatible contact for transmitting a signal or general signal and a plug shield contact for electrical shielding, wherein the plug-compatible contact includes a plug RF contact and a plug signal spaced apart along the first longitudinal axis. It is located between the contacts and spaced apart to face another plug signal contact along a second width axis direction, and the plug shield contact is a plug compatible contact with the plug RF contact spaced apart along the first axis direction. and between the plug compatible contact and the plug signal contact spaced apart along the first axis direction, and between the plug compatible contact and another plug signal contact spaced apart along the second axis direction. A plug connector is provided.

According to the above configuration, the receptacle connector and plug connector according to the present invention can transmit various signals by easily increasing the number of RF contacts according to the usage environment while maintaining the same size as before.

The effects of the present invention are not limited to the effects described above, and should be understood to include all effects that can be inferred from the configuration of the invention described in the detailed description or claims of the present invention.

Figure 1 is a diagram showing a combined state of a receptacle connector and a plug connector according to an embodiment of the present invention.

FIG. 2 is a diagram showing a state in which the receptacle connector and plug connector in FIG. 1 are separated.

Figure 3 is a cross-sectional view taken along the line A-A of Figure 1.

Figure 4 is a diagram showing a receptacle connector according to an embodiment of the present invention.

FIG. 5 is a view showing a state in which the insulating body, shield member, and contact portion in FIG. 4 are separated.

Figure 6 is a top view of Figure 4.

FIG. 7 is a view showing a state in which the shield member in FIG. 6 has been removed.

FIG. 8 is a diagram illustrating the contact portion in FIG. 5, showing the shield contact separated from the RF contact and signal contact.

FIG. 9 is a diagram illustrating an excerpt of the fifth receptacle shield contact in FIG. 8.

Figure 10 is a plan view showing the arrangement relationship between contacts constituting the receptacle contact portion in the receptacle connector according to an embodiment of the present invention.

Figure 11 is a diagram showing Figure 10 rotated by 180 degrees.

Figure 12 is a cross-sectional view taken along line B-B of Figure 6.

Figure 13 is a cross-sectional view taken along line C-C of Figure 6.

Figure 14 is a view showing the third edge of the receptacle connector according to an embodiment of the present invention cut away.

Figure 15 is a diagram showing a plug connector according to an embodiment of the present invention.

FIG. 16 is a view showing a state in which the insulating body, shield member, and contact portion in FIG. 15 are separated.

Figure 17 is a plan view of Figure 15.

FIG. 18 is a view showing a state in which the shield member in FIG. 17 has been removed.

FIG. 19 is a diagram illustrating the contact portion of FIG. 16 with the shield contact separated from the RF contact and signal contact.

FIG. 20 is a diagram illustrating an eighth plug shield contact in FIG. 19.

Figure 21 is a plan view showing the arrangement relationship between contacts constituting the plug contact portion in the plug connector according to an embodiment of the present invention.

Figure 22 is a diagram showing Figure 21 rotated by 180 degrees.

FIG. 23 is a cross-sectional view taken in the D-D direction of FIG. 17.

Figure 24 is a view of the second edge of the plug connector according to an embodiment of the present invention cut away.

Figure 25 is a plan view showing a circuit board that can be applied to a receptacle connector and a plug connector, respectively, according to an embodiment of the present invention.

FIG. 26 is a diagram schematically showing the detailed configuration of the shield pattern portion in FIG. 25.

FIG. 27 is a diagram schematically showing the transmission area divided by the shield pattern portion in FIG. 25.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. The present invention may be implemented in many different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention, parts not related to the description have been omitted in the drawings, and identical or similar components are given the same reference numerals throughout the specification.

The words and terms used in this specification and claims are not to be construed as limited in their usual or dictionary meanings, but according to the principle that the inventor can define terms and concepts in order to explain his or her invention in the best way. It must be interpreted with meaning and concepts consistent with technical ideas.

Additionally, the upper surface used in the present specification and claims may refer to the surface viewed from the top based on FIGS. 4 and 15, and the lower surface may refer to the surface viewed from the bottom based on FIGS. 4 and 15.

In addition, the first axis direction used in the present specification and claims may mean a direction parallel to the x-axis in FIGS. 4 and 15, and the second axis direction may mean a direction parallel to the y-axis in FIGS. 4 and 15. may mean, and the third axis direction may mean a direction parallel to the z-axis in FIGS. 4 and 15.

In addition, the longitudinal direction used in the present specification and claims may refer to the first axis direction or a direction parallel to the x-axis in FIGS. 4 and 15, and the width direction may refer to the second axis direction or the direction parallel to the x-axis in FIGS. 4 and 15. It may refer to a direction parallel to the y-axis, and the thickness direction and height direction may refer to the third axis direction or the direction parallel to the z-axis in FIGS. 4 and 15.

The connector 1000 according to an embodiment of the present invention may be a B2B connector that is physically coupled to each other and electrically connects two different boards.

That is, the connector 1000 according to an embodiment of the present invention may include a receptacle connector 100 and a plug connector 200 that are physically coupled to each other as shown in FIGS. 1 to 3.

In this case, the receptacle connector 100 may be mounted on one module board (not shown), and the plug connector 200 may be mounted on another module board (not shown), and the receptacle When the connector 100 and the plug connector 200 are physically coupled to each other, the module board on which the receptacle connector 100 is mounted and the module board on which the plug connector 200 is mounted can be electrically connected to each other.

In the present invention, the receptacle connector 100 and the plug connector 200 may be provided to have shapes corresponding to each other so that they can be physically coupled to each other. That is, the receptacle connector 100 may include an island portion 112 protruding at a certain height in the center and a receiving groove 113 formed to surround the island portion 112, and the plug connector 200 may include the A protrusion 211 formed in a closed loop shape at a position corresponding to the island 112, a first seating groove 212 formed inside the protrusion 211, and along the outer peripheral surface of the protrusion 211. It may include a second seating groove 213 formed.

Accordingly, when the receptacle connector 100 and the plug connector 200 are coupled to each other, the island portion 112 can be inserted into the first seating groove 212, and the protrusion 211 is formed in the receiving groove ( 113).

At this time, each of the receptacle connector 100 and the plug connector 200 according to an embodiment of the present invention can transmit an RF (Radio Frequency) signal and a general signal simultaneously, and the number of RF contacts for transmitting the RF signal can be increased. Alternatively, the number of signal contacts for transmitting general signals can be increased.

Through this, each of the receptacle connector 100 and plug connector 200 according to an embodiment of the present invention can easily increase the number of RF contacts according to the usage environment while maintaining the same size as before, thereby providing various RF signals. It can be delivered.

To this end, the receptacle connector 100 according to an embodiment of the present invention may include a receptacle insulating body 110, a receptacle shield member 120, and a receptacle contact portion 130, as shown in FIGS. 4 to 6. You can.

The receptacle insulating body 110 may be made of an electrically insulating material and may define the overall appearance of the receptacle connector 100.

That is, the receptacle insulating body 110 includes a first edge (111a), a second edge (111b), a third edge (111c), and a fourth edge (111d) as shown in FIGS. 5 and 7. It may have an approximately rectangular parallelepiped shape.

Here, the second edge (111b) may be an edge spaced apart from the first edge (111a) along the first axis direction, and the third edge (111c) may be a second edge perpendicular to the first axis direction. It may be an edge spaced apart from the second edge 111b along the axial direction, and the fourth edge 111d is spaced apart from the third edge 111c along the first axis direction and moves in the second axis direction. Accordingly, it may be an edge spaced apart from the first edge 111a.

Additionally, the receptacle insulating body 110 may include a receiving groove 113 for physical coupling with the plug connector 200.

That is, as shown in FIGS. 4 and 5, the receptacle insulating body 110 has an island portion 112 protruding from the bottom 118 at a central portion at a certain height, and is spaced apart from the island portion 112 at a predetermined distance. It may include an edge portion 114 formed to surround the island portion 112, and the receiving groove 113 defines an outer peripheral surface of the island portion 112 between the island portion 112 and the edge portion 114. Accordingly, the intrusion can be formed at a certain depth.

Here, the island portion 112 may have a bar shape extending a certain length along the first axis direction, and the receiving groove 113 and the edge portion 114 may be formed to surround the entire circumference of the island portion 112. The receiving groove 113 may be formed to be recessed from the upper surface of the receptacle insulating body 110 at a certain depth.

In this case, the receptacle shield member 120 may be coupled to the edge portion 114 to surround the edge of the receptacle insulating body 110, and the receptacle contact portion 130 may be electrically conductive to the outside. It may be coupled to the receptacle insulating body 110.

For example, the receptacle contact portion 130 may be coupled to the receptacle insulating body 110 so that a portion of the receptacle contact portion 130 is exposed at least at one of the island portion 112, the bottom surface of the receiving groove 113, and the edge portion 114. You can.

Accordingly, when the receptacle connector 100 is coupled to the plug connector 200, the island portion 112 can be inserted into the first seating groove 212 of the plug connector 200, and the receptacle shield member 120 may be in contact with the plug shield member 220, and the receptacle contact portion 130 may be in contact with the plug contact portion 230.

Through this, the receptacle connector 100 and the plug connector 200 can be electrically connected to each other.

At this time, the receptacle insulating body 110 is located inside each corner (111a, 111b, 111c, 111d) and is formed to penetrate the bottom 118 with a predetermined area so as to penetrate the bottom surface of the receiving groove 113. may include a cutout 115, and a portion of one or more receptacle contacts of the receptacle contact parts 130 may be exposed to the outside through the cutout 115.

For example, as shown in FIGS. 6 and 7, the cut portion 115 is located inside the first edge 111a and is formed on the bottom of the receiving groove 113. -1), a second cut portion 115-2 formed on the bottom of the receiving groove 113 and located inside the second edge 111b, and inside the third edge 111c. A third cut portion 115-3 formed on the bottom of the receiving groove 113 and a fourth cut portion 115-3 formed on the bottom of the receiving groove 113 and located inside the fourth edge 111d. It may include an incision 115-4.

In addition, the receptacle insulating body 110 may further include penetrating portions 116-1 and 116-2 formed with a predetermined area to penetrate the edge portion 114, and the edge portion of the receptacle contact portion 130. Some of the receptacle contacts coupled to the portion 114 may be exposed to the outside through the through portions 116-1 and 116-2.

Here, the penetrating portions 116-1 and 116-2 may be formed to penetrate both the edge portion 114 and the bottom portion 118 while being open on one side.

For example, as shown in FIGS. 6 and 7, the penetrating portions 116-1 and 116-2 are located between the first edge 111a and the second edge 111b and extend along the third axis direction. The edge portion 114 is located between the first penetrating portion 116-1 formed to penetrate the portion 114 and the third edge 111c and the fourth edge 111d along the third axis direction. It may include a second penetration part 116-2 formed to penetrate, and each of the first penetration part 116-1 and the second penetration part 116-2 may be formed so that one side is open. .

Accordingly, when the receptacle connector 100 according to an embodiment of the present invention is mounted on a board (see 300 in FIG. 25), the operator may use the first to fourth cutouts 115-1 to 115-4, The state in which the receptacle contact part 130 is mounted on the substrate 300 can be easily confirmed through the first through part 116-1 and the second through part 116-2.

At this time, the receptacle insulating body 110 may further include a support portion 117 extending from the edge portion 114 to cross the penetration portions 116-1 and 116-2. Such support portion 117 As shown in FIG. 13, when the receptacle shield member 120 is coupled to the edge portion 114, one end may be in contact with the receptacle shield member 120.

Through this, the support portion 117 can reinforce the strength of the receptacle insulating body 110.

For example, the support portion 117 may have a cross-sectional area of a certain length and a certain height and may extend along the second axis direction from the edge portion 114 to cross the penetrating portions 116-1 and 116-2. there is.

That is, the support portion 117 may be formed to have a cross-sectional area with a constant length and a constant height along a longitudinal direction parallel to the first axis and a height direction parallel to the third axis, and a width direction parallel to the second axis. It may extend from the edge portion 114 to extend in a planar manner while crossing the penetrating portions 116-1 and 116-2 along .

Accordingly, in the receptacle connector 100 according to an embodiment of the present invention, even if the receptacle insulating body 110 includes penetrating portions 116-1 and 116-2 with one side open, the insulating body 110 of the receptor is Because the strength can be reinforced through the support portion 117 that contacts the receptacle shield member 120 while crossing the through portions 116-1 and 116-2, external force is applied to the through portions 116-1 and 116-2. Even if this is applied, the possibility of damage to the receptacle insulating body 110 due to external force may be reduced.

The receptacle shield member 120 can prevent damage to the receptacle insulating body 110 due to excessive pressure when coupled with the plug connector 200 and can shield electromagnetic waves flowing in from the outside.

Additionally, the receptacle shield member 120 may shield electromagnetic waves generated from the receptacle contact portion 130 coupled to the receptacle insulating body 110.

For this purpose, the receptacle shield member 120 may be made of a metal material, but is not limited thereto, and various known materials may be applied as long as they have a predetermined strength and conductivity.

Such a receptacle shield member 120 may be provided to surround the entire edge of the receptacle insulating body 110.

That is, the receptacle shield member 120 may include a closed loop-shaped body 122 with an empty space formed in the center so as to surround the entire edge of the receptacle insulating body 110, as shown in FIG. 12. As shown, the body 122 may be coupled to the edge portion 114 along the edge portion 114.

Accordingly, when the receptacle connector 100 according to an embodiment of the present invention is coupled with the plug connector 200, the receptacle shield member 120 is in contact with the plug shield member 220 at the plug connector 200. By being energized, a ground can be formed together with the receptacle shield contact 134, which will be described later.

At this time, the receptacle shield member 120 may include extension parts 124-1 and 124-2 elastically deformably extending from the body 122, as shown in FIGS. 4 to 6.

Such extension parts 124-1 and 124-2 are elastically deformed by an external force as shown in FIG. 14 and are separated from the body 122 in the receiving groove 113 so that they can be placed in the receiving groove 113. ) can be extended to the side.

For example, the extension portion 124-1 is located between the first receptacle RF contact 131-1 and the fourth receptacle RF contact 131-4 spaced apart along the second axis direction and is connected to the body ( It may be formed to extend from 122) toward the receiving groove 113.

In addition, the extension portion 124-2 is located between the second receptacle RF contact 131-2 and the third receptacle RF contact 131-3 spaced apart along the second axis direction and is connected to the body 122. ) may be formed to extend from the receiving groove 113 side.

Accordingly, when the receptacle connector 100 and the plug connector 200 are coupled as shown in FIG. 3, the extension portions 124-1 and 124-2 are inserted into the receiving groove 113. It may be in direct contact with the shield contacts 234-1 and 234-2 of 200).

That is, the extension portion 124-1 formed to be located between the first receptacle RF contact 131-1 and the fourth receptacle RF contact 131-4 is the first plug shield contact of the plug connector 200 ( 234-1), and the extension portion 124-2 formed to be located between the second receptacle RF contact 131-2 and the third receptacle RF contact 131-3 is the plug connector ( It may be in direct contact with the second plug shield contact 234-2 of 200).

Through this, when the receptacle connector 100 and the plug connector 200 are coupled, the receptacle shield member 120 is connected to the shield contacts 234-1, 234 of the plug connector 200 through the extension portions 124-1 and 124-2. -2) Since the contact area can be expanded, the electrical shielding performance can be improved while ensuring contact stability by increasing the contact area.

Through this, the receptacle connector 100 according to an embodiment of the present invention has electromagnetic waves generated from the receptacle RF contacts 131, which will be described later, disposed around the receptacle shield member 120 and the receptacle shield contact 134. Interference with signals from circuit components can be prevented.

In addition, the receptacle connector 100 according to an embodiment of the present invention is capable of protecting itself from circuit components disposed around the receptacle connector 100 in an electronic device through the receptacle shield member 120 and the receptacle shield contact 134. Electromagnetic waves can be prevented from interfering with RF signals transmitted by the receptacle RF contacts 131.

Accordingly, the receptacle connector 100 according to an embodiment of the present invention uses the receptacle shield member 120 and the receptacle shield contact 134 to provide EMI (Electro Magnetic Interference) shielding performance and/or EMC (Electro Magnetic Compatibility). Performance can be improved.

The receptacle contact portion 130 may be coupled to the receptacle insulating body 110 and may be electrically connected to the outside.

That is, the receptacle contact portion 130 may be arranged in a predetermined pattern along the first direction in the receptacle insulating body 110, and may be connected to the contact or substrate of the plug connector 200 (see 300 in FIG. 25) and It may be coupled to the receptacle insulating body 110 so that a portion is exposed to the outside so that it can be contacted.

Such a receptacle contact portion 130 can form an electrical contact with the plug contact portion 230 of the plug connector 200 when combined with the plug connector 200, and is connected to the receptacle insulating body 110 through insert molding. ) can be formed integrally with.

At this time, the receptacle contact unit 130 may be configured to simultaneously transmit an RF (Radio Frequency) signal and a general signal. Depending on the usage environment, the number of RF contacts 131 for transmitting the RF signal may be increased or the general signal may be increased. The number of signal contacts 132 for transmitting signals can be easily increased.

That is, the receptacle connector 100 according to an embodiment of the present invention can easily increase the total number of RF contacts 131 that can transmit RF signals while maintaining the same size as the existing one, thereby transmitting more diverse RF signals. You can.

In addition, the receptacle connector 100 according to an embodiment of the present invention can easily increase the total number of contacts 131 capable of transmitting RF signals while maintaining the same size as before, thereby enabling the receptacle connector 100 to be fully mounted. ) can reduce the total number of uses.

For example, the receptacle connector 100 according to an embodiment of the present invention can implement 5 to 6 RF contacts 131 while maintaining a size of 1 cm in length and 0.8 cm in width or less.

To this end, the receptacle contact unit 130 may further include compatible contacts in addition to the RF contacts and signal contacts used in typical RF connectors.

That is, the receptacle connector 100 according to an embodiment of the present invention includes a receptacle RF contact 131 for transmitting an RF signal, a receptacle signal contact 132 for transmitting a general signal, and It may include a receptacle compatible contact 133 that is used as an RF contact for transmitting an RF signal or as a signal contact for transmitting a general signal.

In addition, the receptacle contact portion 130 may further include a receptacle shield contact 134 for electrically shielding the receptacle RF contact 131, the receptacle signal contact 132, and the receptacle compatible contact 133 from each other. there is.

Accordingly, when the receptacle compatible contact 133 is used as an RF contact for transmitting an RF signal, the receptacle connector 100 according to an embodiment of the present invention maintains the same size while maintaining a larger number of RF contacts. By securing (131), more diverse RF signals can be transmitted.

To this end, the receptacle RF contact 131 includes a first receptacle RF contact 131-1 disposed adjacent to the first edge 111a as shown in FIGS. 7 and 10, and a second edge ( A second receptacle RF contact (131-2) disposed adjacent to 111b), a third receptacle RF contact (131-3) disposed adjacent to the third corner (111c), and adjacent to the fourth corner (111d) It may include a fourth receptacle RF contact (131-4) disposed in a similar manner.

That is, the first receptacle RF contact (131-1) and the fourth receptacle RF contact (131-4), the second receptacle RF contact (131-2) and the third receptacle RF contact (131-3) are They may be arranged adjacent to and spaced apart from each other along a two-axis direction, and may include the first receptacle RF contact (131-1) and the second receptacle RF contact (131-2), the fourth receptacle RF contact (131-4), and The third receptacle RF contact 131-3 may be spaced apart along the first axis direction.

In this case, the first receptacle RF contact 131-1 and the fourth receptacle RF contact 131-4, which are adjacent to and spaced apart from each other along the second axis direction, are the first receptacle RF contact 131-1. and the first receptacle shield contact 134-1 disposed between the fourth receptacle RF contact 131-4.

Similarly, the second receptacle RF contact 131-2 and the third receptacle RF contact 131-3 arranged adjacent to and spaced apart from each other along the second axis direction are the second receptacle RF contact 131-2 and It may be electrically shielded through the second receptacle shield contact 134-2 disposed between the third receptacle RF contacts 131-3.

In addition, the receptacle signal contact 132 is a first receptacle disposed between the first receptacle RF contact 131-1 and the second receptacle RF contact 131-2 along the first axis direction. A second receptacle signal contact disposed between the signal contact 132-1 and the fourth receptacle RF contact 131-4 and the third receptacle RF contact 131-3 along the first axis direction. It may include (132-2).

Here, each of the first receptacle signal contact 132-1 and the second receptacle signal contact 132-2 may be provided as one, but a plurality of them may be grouped to form one receptacle signal contact 132.

In this case, the first receptacle signal contact 132-1 is electrically shielded from the first receptacle RF contact 131-1 through the third receptacle shield contact 134-3 and is connected to the fourth receptacle shield contact ( It can be electrically shielded from the second receptacle RF contact (131-2) through 134-4).

Similarly, the second receptacle signal contact 132-2 is electrically shielded from the fourth receptacle RF contact 131-4 through the third receptacle shield contact 134-3 and is connected to the fourth receptacle shield contact 134-3. It can be electrically shielded from the third receptacle RF contact (131-3) through (134-4).

That is, the third receptacle shield contact 134-3 is provided to have a certain length and electrically shields the first receptacle signal contact 132-1 and the first receptacle RF contact 131-1 while being connected to the second receptacle. It may be disposed on the receptacle insulating body 110 along the second axis direction to electrically shield the signal contact 132-2 and the fourth receptacle RF contact 131-4.

In addition, the fourth receptacle shield contact (134-4) is provided to have a certain length and electrically shields the first receptacle signal contact (132-1) and the second receptacle RF contact (131-2) and acts as a contact for the second receptacle. It may be disposed on the receptacle insulating body 110 along the second axis direction to electrically shield the signal contact 132-2 and the third receptacle RF contact 131-3.

At this time, the receptacle compatible contact 133 is disposed adjacent to one of the two receptacle RF contacts 131 spaced apart along the first axis direction and is connected to the receptacle shield contact 134. It can be disposed on the receptacle insulating body 110 so as to be electrically shielded from the receptacle RF contacts 131 disposed adjacent to each other.

In addition, the receptacle compatible contact 133 may be disposed on the receptacle insulating body 110 so as to be electrically shielded from both the receptacle signal contact 132 and the receptacle RF contact 131 through the receptacle shield contact 134. there is.

In addition, the receptacle compatible contact 133 may be provided to have the same shape as the receptacle signal contact 132.

For example, the receptacle compatibility contact 133 may include a first receptacle compatibility contact 133-1 and a second receptacle compatibility contact 133-2.

Additionally, each of the first receptacle compatible contact 133-1 and the second receptacle compatible contact 133-2 may be provided to have the same shape as the receptacle signal contact 132.

Here, as shown in FIG. 10, the first receptacle compatible contact 133-1 is located between the first receptacle RF contact 131-1 and the second receptacle RF contact 131-2 and It may be placed adjacent to the first receptacle signal contact 132-1 along the 1-axis direction.

In addition, as shown in FIG. 10, the second receptacle compatible contact 133-2 is located between the third receptacle RF contact 131-3 and the fourth receptacle RF contact 131-4. It may be placed adjacent to the second receptacle signal contact 132-2 along the 1-axis direction.

That is, in the receptacle connector 100 according to an embodiment of the present invention, the first receptacle RF contact 131-1, the first receptacle signal contact 132-1, and the first receptacle compatible contact 133-1. and the second receptacle RF contact 131-2 may be sequentially arranged along the first axis direction.

Similarly, in the receptacle connector 100 according to an embodiment of the present invention, the fourth receptacle RF contact (131-4), the second receptacle compatible contact (133-2), and the second receptacle signal contact (132-2) ) and the third receptacle RF contact 131-3 may be sequentially arranged along the first axis direction.

In this case, the first receptacle compatible contact 133-1 is arranged to surround the first receptacle compatible contact 133-1 through the receptacle shield contact 134. The first receptacle signal contact ( 132-1), the second receptacle signal contact 132, and the second receptacle RF contact 131-2 may all be disposed on the receptacle insulating body 110 to be electrically shielded.

In addition, the second receptacle compatible contact 133-2 is arranged to surround the second receptacle compatible contact 133-2 through the receptacle shield contact 134. The first receptacle signal contact 132- 1), it may be disposed on the receptacle insulating body 110 so as to be electrically shielded from both the second receptacle signal contact 132 and the fourth receptacle RF contact 131-4.

To this end, the receptacle shield contact 134 shields the first receptacle signal contact 132-1 and the first receptacle compatible contact 133-1, as shown in FIG. 10, while providing the first receptacle compatible contact. a fifth receptacle shield contact 134-5 arranged to shield the contact 133-1 and the second receptacle signal contact 132-2, the first receptacle signal contact 132-1, and A sixth receptacle shield arranged to shield the second receptacle compatible contact (133-2) and the second receptacle compatible contact (133-2) and the second receptacle signal contact (132-2). It may further include a contact 134-6.

At this time, each of the fifth receptacle shield contact 134-5 and the sixth receptacle shield contact 134-6 has a first portion disposed parallel to the first axis direction as shown in FIGS. 8 to 10 ( 134-5a, 134-6a) and second parts 134-5b, 134-6b extending from the first parts 134-5a, 134-6a so as to be parallel to the second axis direction. there is.

Through this, the first parts (134-5a, 134-6a) can electrically shield the receptacle compatible contact 133 and the receptacle signal contact 132 disposed adjacent to each other along the second axis direction, The second portions 134-5b and 134-6b may electrically shield the receptacle compatible contact 133 and the receptacle signal contact 132 disposed adjacent to each other along the first axis direction.

That is, the first portion 134-5a of the fifth receptacle shield contact 134-5 electrically connects the first receptacle compatible contact 133-1 and the second receptacle signal contact 132-2. It can be shielded, and the second part (134-5b) of the fifth receptacle shield contact (134-5) is connected to the first receptacle compatible contact (133-1) and the first receptacle compatible contact (133-1) arranged adjacently along the first axis direction. 1 The receptacle signal contact (132-1) can be electrically shielded.

In addition, the first portion (134-6a) of the sixth receptacle shield contact (134-6) electrically connects the second receptacle compatible contact (133-2) and the first receptacle signal contact (132-1). It can be shielded, and the second part (134-6b) of the sixth receptacle shield contact (134-6) is connected to a second receptacle compatible contact (133-2) and a second receptacle compatible contact (133-2) disposed adjacently along the first axis direction. 2 The receptacle signal contact (132-2) can be electrically shielded.

Here, the first portions 134-5a and 134-6a may be formed in a plate shape with a predetermined area and may be arranged to be located on the island portion 112. Additionally, the second parts 134-5b and 134-6b may be formed to have a shape that is bent at least once so that they can be arranged along the receiving groove 113 and the edge portion 114.

Accordingly, the first receptacle compatible contact 133-1 has four sides through the receptacle shield member 120, the fourth receptacle shield contact 134-4, and the fifth receptacle shield contact 134-5. It can be placed on the receptacle insulating body 110 so that all are shielded, and the second receptacle compatible contact 133-2 is connected to the receptacle shield member 120, the third receptacle shield contact 134-3, and the sixth receptacle shield contact 134-3. It can be placed on the receptacle insulating body 110 so that all four sides are shielded through the receptacle shield contact 134-6.

That is, each of the first receptacle compatible contact 133-1 and the second receptacle compatible contact 133-2 is shielded on all four sides through the receptacle shield member 120 and the receptacle shield contact 134. By being placed on the receptacle insulating body 110, it can function as a signal contact for transmitting a general signal as well as an RF contact for transmitting an RF signal.

Through this, the receptacle connector 100 according to an embodiment of the present invention maintains the same size as the existing one, but the total number of contacts that can function as RF contacts through the receptacle compatible contact 133 can be adjusted depending on the usage environment. It can be easily increased.

In addition, in the receptacle connector 100 according to an embodiment of the present invention, the first receptacle compatible contact 133-1 and the second receptacle compatible contact 133-2 are each arranged to be spaced apart along the first axis direction. Since it is placed adjacent to one of the two receptacle RF contacts 131, the amount of use of the receptacle shield contact 134 used to shield all four sides can be minimized.

That is, when the first receptacle compatible contact 133-1 is disposed between the first receptacle signal contact 132-1 and the second receptacle RF contact 131-2, the first receptacle compatible contact ( 133-1) may share the fourth receptacle shield contact 134-4 for electrical shielding with the second receptacle RF contact 131-2.

Similarly, when the second receptacle compatible contact (133-2) is disposed between the second receptacle signal contact (132-2) and the fourth receptacle RF contact (131-4), the second receptacle compatible contact ( 133-2) may share the third receptacle shield contact 134-3 for electrical shielding with the fourth receptacle RF contact 131-4.

Accordingly, the receptacle connector 100 according to an embodiment of the present invention electrically shields the receptacle compatible contact 133 from other contacts so that the receptacle compatible contact 133 can function as an RF contact. By minimizing the amount of shield contact used, the production cost can be lowered while satisfying the electrical shielding required to implement the RF contact.

At this time, when the receptacle compatibility contact 133 includes a first receptacle compatibility contact 133-1 and a second receptacle compatibility contact 133-2, the first receptacle compatibility contact 133-1 ) and the second receptacle compatible contact 133-2 may be arranged to be spaced apart from each other along the first axis direction and positioned at an asymmetrical position with respect to the first axis.

In addition, the first receptacle compatible contact 133-1 and the second receptacle compatible contact 133-2 are arranged in an asymmetrical position with respect to the first axis and are positioned relative to the virtual center point O. They may be arranged to be located diagonally from each other.

That is, as shown in FIG. 10, the first receptacle signal contact 132-1 and the first receptacle compatible contact 133-1 disposed adjacent to each other along the first axis direction are aligned in the first axis direction. Accordingly, the second receptacle compatible contact 133-2 and the second receptacle signal contact 132-2 may be arranged to be positioned diagonally from each other based on a virtual center point.

In this case, the fifth receptacle shield contact 134-5 and the sixth receptacle shield contact 134-6 may also be arranged to be located diagonally from each other with respect to the virtual center point.

In addition, the first receptacle RF contact 131-1 and the third receptacle RF contact 131-3 may be arranged to be positioned diagonally from each other with respect to a virtual center point, and the fourth receptacle RF contact 131 -4) and the second receptacle RF contact 131-2 may also be arranged to be located diagonally from each other based on the virtual center point.

Accordingly, when the receptacle connector 100 according to an embodiment of the present invention is coupled to the plug connector 200, even if the directions of both ends parallel to the first axis direction are changed, the receptacle connector 100 sequentially moves along the first axis direction. The arrangement relationship between the RF contact 131, the signal contact 132, the compatible contact 133, and the shield contact 134 arranged as can be maintained.

That is, even if the receptacle connector 100 according to an embodiment of the present invention is rotated 180 degrees with respect to the virtual center point as shown in FIG. 11, the third receptacle RF contact 131-3 in the rotated state , fourth receptacle shield contact (134-4), second receptacle signal contact (132-2), sixth receptacle shield contact (134-6), second receptacle compatible contact (133-2), third receptacle shield. The contact (134-3) and the fourth receptacle RF contact (131-4) are the first receptacle RF contact (131-1), the third receptacle shield contact (134-3), and the first receptacle RF contact (131-1) before being rotated by 180 degrees. 1 receptacle signal contact (132-1), fifth receptacle shield contact (134-5), first receptacle compatible contact (133-1), fourth receptacle shield contact (134-4) and second receptacle RF contact ( It can be changed to the same position as 131-2).

Likewise, even if the receptacle connector 100 according to an embodiment of the present invention is rotated 180 degrees with respect to the virtual center point as shown in FIG. 11, the first receptacle RF contact 131-1 and the third receptacle shield Contact (134-3), first receptacle signal contact (132-1), fifth receptacle shield contact (134-5), first receptacle compatible contact (133-1), fourth receptacle shield contact (134-4) ) and the second receptacle RF contact (131-2) is the third receptacle RF contact (131-3), the fourth receptacle shield contact (134-4), and the second receptacle signal contact (131-2) before being rotated 180 degrees. 132-2), the sixth receptacle shield contact (134-6), the second receptacle compatible contact (133-2), the third receptacle shield contact (134-3), and the fourth receptacle RF contact (131-4) Each can be changed to the same location.

Through this, the receptacle connector 100 according to an embodiment of the present invention eliminates the coupling directionality of both ends parallel to the first axis direction when coupled with the plug connector 200, thereby preventing misalignment of contacts according to the coupling direction and The same problem can be prevented at the source.

Meanwhile, as described above, the receptacle contact portion 130 may be formed integrally with the receptacle insulating body 110 through insert molding, and one or more receptacle contacts of the receptacle contact portion 130 may be partially formed through the incision. It may be exposed to the outside through the unit 115.

For example, each of the first receptacle shield contact 134-1 and the first receptacle RF contact 131-1 may be arranged such that one end is exposed to the first cutout 115-1, and the second receptacle shield contact 134-1 Each of the receptacle shield contact 134-2 and the second receptacle RF contact 131-2 may be arranged such that one end is exposed to the second cutout 115-2.

In addition, each of the second receptacle shield contact 134-2 and the third receptacle RF contact 131-3 may be arranged such that one end is exposed to the third cutout 115-3, and the first receptacle Each of the shield contact 134-1 and the fourth receptacle RF contact 131-4 may be arranged such that one end is exposed to the fourth cutout 115-4.

In this case, as shown in FIG. 12, the end of the first receptacle shield contact 134-1 and the first receptacle RF contact 131- are each exposed to the outside through the first cutout 115-1. The end of 1) may be a cut surface, and the end of the first receptacle shield contact 134-1 and the fourth receptacle RF contact 131-4 are each exposed to the outside through the fourth cut 115-4. ) The end may be a cut surface.

Here, the first receptacle RF contact (131-1), the first receptacle shield contact (134-1), and the fourth receptacle RF contact (131-4) are separated into three parts by cutting one member. It may have been formed.

That is, in a state where the conductive member made of one member is integrated with the receptacle insulating body 110, the conductive member has a portion corresponding to the first cutout 115-1 and the fourth cutout 115-2. Each piece can be cut through this cutting process.

Accordingly, the ends formed as cut surfaces of the first receptacle shield contact 134-1 and the first receptacle RF contact 131-1 may be exposed to the outside through the first cut portion 115-1, End portions formed as cut surfaces of the first receptacle shield contact 134-1 and the fourth receptacle RF contact 131-4 may be exposed to the outside through the fourth cut portion 115-4.

Similarly, the ends of the second receptacle shield contact 134-2 and the ends of the second receptacle RF contact 131-2, respectively exposed to the outside through the second cut portion 115-2, may be cut surfaces. The end of the second receptacle shield contact 134-2 and the end of the third receptacle RF contact 131-3, respectively exposed to the outside through the third cut 115-3, may be cut surfaces. , the second receptacle RF contact (131-2), the second receptacle shield contact (134-2), and the third receptacle RF contact (131-3) are separated into three parts by cutting one member. It may have been formed.

Meanwhile, the plug connector 200 according to an embodiment of the present invention, like the above-described receptacle connector 100, is configured so that the number of RF contacts 231 can be easily increased depending on the usage environment while maintaining the same size as before. It can be.

To this end, the plug connector 200 according to an embodiment of the present invention may include a plug insulating body 210, a plug shield member 220, and a plug contact portion 230, as shown in FIGS. 15 to 16. You can.

The plug insulating body 210 may be made of an electrically insulating material and may define the overall appearance of the plug connector 200.

That is, as shown in FIGS. 15 and 18, the plug insulating body 210 has a bottom 217 and a closed loop shape in which the central portion of the bottom 217 protrudes at a certain height along the third axis. It may include a protrusion 211 and an outer wall portion 214 that is spaced apart from the protrusion 211 at a predetermined distance and protrudes at a certain height along the third axis direction along the edge of the bottom portion 217.

At this time, the protrusion 211 may have a closed loop shape including a first edge 211a, a second edge 211b, a third edge 211c, and a fourth edge 211d.

Here, the second edge 211b may be an edge of the protrusion 211 spaced apart from the first edge 211a along the first axis direction, and the third edge 211c may be an edge of the first axis. It may be an edge of the protrusion 211 spaced apart from the second edge 211b along a second axis direction perpendicular to the direction, and the fourth edge 211d is the third edge along the first axis direction. It may be an edge of the protrusion 211 that is spaced apart from (211c) and spaced apart from the first edge 211a along the second axis direction.

Accordingly, the plug insulating body 210 has a first seating groove 212 formed at a certain depth into the inside of the protrusion 211 defined through the first edge 211a to the fourth edge 211d. , It may include a second seating groove 213 that is recessed to a certain depth along the outer peripheral surface of the protrusion 211 defined through the first edge 211a to the fourth edge 211d.

In this case, the plug shield member 220 may be coupled to the outer wall portion 214 to surround the edge of the plug insulating body 210, and the plug contact portion 230 may be electrically connected to the outside. It can be coupled to the plug insulating body 210.

For example, the plug contact portion 230 is insulated so that at least one portion of the protrusion 211, the bottom surface of the first seating groove 212, and the bottom surface of the second seating groove 213 is exposed. It may be coupled to the body 210.

Accordingly, when the receptacle connector 100 is coupled to the plug connector 200, the island portion 112 of the receptacle connector 100 can be inserted into the first seating groove 212, and the receptacle shield member (220) may be inserted into the second seating groove 213, and the receptacle shield member 220 may be in contact with the plug shield member 220 when inserted into the second seating groove 213. You can. Additionally, the plug contact portion 230 may be in contact with the receptacle contact portion 130.

Through this, the plug connector 200 and the plug connector 200 may be electrically connected to each other.

At this time, the plug insulating body 210 may include incisions 215-1 and 215-2 located inside the protrusion 211 and formed through a predetermined area on the bottom surface of the first seating groove 212. One or more plug contacts of the plug contact portions 230 may be arranged so that a portion of them is exposed to the outside through the cutouts 215-1 and 215-2.

For example, as shown in FIGS. 17 and 18, the cut portions 215-1 and 215-2 are located inside the protrusion 211 and close to the first edge 211a and the fourth edge 211d. A first cut portion 215-1 formed on the bottom surface of the first seating groove 212, and located inside the protrusion 211, the second edge 211b and the third edge 211c. It may include a second cut portion 215-2 formed on the bottom surface of the first seating groove 212 nearby.

In addition, the plug insulating body 210 may further include openings 216-1 and 216-2 formed with a predetermined area, and some of the plug contacts coupled to the protrusion 211 among the plug contact parts 230 are may be exposed to the outside through the openings 216-1 and 216-2.

Here, the openings 216-1 and 216-2 may be formed to cut both the outer wall portion 214 and the bottom portion 217 while opening one side.

For example, as shown in FIG. 18, the openings 216-1 and 216-2 are located between the first edge 211a and the second edge 211b and form a bottom surface of the second seating groove 213. A second opening formed to penetrate the bottom surface of the second seating groove 213 is located between the first opening 216-1 and the third edge 211c and the fourth edge 211d. It may include an opening 216-2.

Accordingly, when the plug connector 200 according to an embodiment of the present invention is mounted on a board (see 300 in FIG. 25), the operator cuts the first cut part 215-1 and the second cut part 215-1. 2), the state in which the plug contact part 230 is mounted on the board can be easily confirmed through the first opening 216-1 and the second opening 216-2.

The plug shield member 220 can prevent damage to the plug insulating body 210 due to excessive pressure when coupled with the plug connector 200 and can shield electromagnetic waves flowing in from the outside.

Additionally, the plug shield member 220 can shield electromagnetic waves generated from the plug contact portion 230 coupled to the plug insulating body 210.

For this purpose, the plug shield member 220 may be made of a metal material, but is not limited thereto, and various known materials may be applied as long as they have a predetermined strength and conductivity.

Such a plug shield member 220 may be provided to surround the entire edge of the plug insulating body 210.

That is, the plug shield member 220 may be formed in a closed loop shape with an empty space formed in the center so as to surround the entire edge of the plug insulating body 210, as shown in FIGS. 23 and 24. It may be coupled to the outer wall portion 214.

Accordingly, when the plug connector 200 according to an embodiment of the present invention is coupled with the receptacle connector 100, the plug shield member 220 contacts the receptacle shield member 120 of the receptacle connector 100. By being energized, a ground can be formed together with the shield contacts 234, which will be described later.

Through this, the plug connector 200 according to an embodiment of the present invention allows electromagnetic waves generated from plug RF contacts 231, which will be described later, to be disposed around the plug shield member 220 and the plug shield contact 234. Interference with signals from circuit components can be prevented.

In addition, the receptacle connector 200 according to an embodiment of the present invention is capable of protecting itself from circuit components disposed around the plug connector 200 in an electronic device through the plug shield member 220 and the plug shield contact 234. Electromagnetic waves can be prevented from interfering with RF signals transmitted by the plug RF contacts 231.

Accordingly, the plug connector 200 according to an embodiment of the present invention uses the plug shield member 220 and the plug shield contact 234 to provide EMI (Electro Magnetic Interference) shielding performance and/or EMC (Electro Magnetic Compatibility). Performance can be improved.

The plug contact portion 230 may be coupled to the plug insulating body 210 and may be electrically connected to the outside.

That is, the plug contact portion 230 may be arranged in a predetermined pattern along the first direction in the plug insulating body 210, and may be positioned at positions corresponding to the above-described receptacle contact portion 130. You can.

Additionally, the plug contact portion 230 may be coupled to the plug insulating body 210 so that a portion of the plug contact portion 230 is exposed to the outside so that it can contact the contact of the receptacle connector 100 or the substrate.

For example, the plug contact portion 230 may form an electrical contact with the receptacle contact portion 130 of the receptacle connector 100 when coupled to the receptacle connector 100, and the plug may be insulated through insert molding. It may be formed integrally with the body 210.

At this time, the plug contact unit 230 may be configured to simultaneously transmit an RF (Radio Frequency) signal and a general signal, similar to the above-described receptacle connector 100, and may be configured as an RF contact for transmitting an RF signal depending on the usage environment. You can easily increase the number of (231) or signal contacts (232) to transmit general signals.

That is, the plug connector 200 according to an embodiment of the present invention can transmit more diverse RF signals by easily increasing the total number of contacts 231 that can transmit RF signals while maintaining the same size as before. there is.

In addition, the plug connector 200 according to an embodiment of the present invention can easily increase the total number of contacts 231 capable of transmitting RF signals while maintaining the same size as before, thereby enabling the plug connector 200 to be fully mounted. ) can reduce the total number of uses.

For example, the plug connector 200 according to an embodiment of the present invention can implement 5 to 6 RF contacts 231 while maintaining a size of 1 cm in length and 0.8 cm in width or less.

To this end, the plug contact unit 230 may further include compatible contacts in addition to the RF contacts and signal contacts used in typical RF connectors.

That is, the plug connector 200 according to an embodiment of the present invention includes a plug RF contact 231 for transmitting an RF signal, a plug signal contact 232 for transmitting a general signal, and It may include a plug-compatible contact 233 that is used as an RF contact for transmitting an RF signal or as a signal contact for transmitting a general signal.

In addition, the plug contact unit 230 may further include a plug shield contact 234 for electrically shielding the plug RF contact 231, plug signal contact 232, and plug compatible contact 233 from each other. there is.

Accordingly, when the plug compatible contact 233 is used as an RF contact for transmitting an RF signal, the plug connector 200 according to an embodiment of the present invention maintains the same size while maintaining a larger number of RF contacts. By securing (231), more diverse RF signals can be transmitted.

To this end, the plug RF contact 231 is a first plug RF contact 231-1 disposed adjacent to the first edge 211a, as shown in FIGS. 18 and 21, and the second edge ( A second plug RF contact 231-2 disposed adjacent to 211b), a third plug RF contact 231-3 disposed adjacent to the third corner 211c, and adjacent to the fourth corner 211d. It may include a fourth plug RF contact (231-4) arranged in a similar manner.

That is, the first plug RF contact (231-1) and fourth plug RF contact (231-4), and the second plug RF contact (231-2) and third plug RF contact (231-3) are They may be arranged adjacent to and spaced apart from each other along a two-axis direction, and may include the first plug RF contact 231-1 and the second plug RF contact 231-2, the fourth plug RF contact 231-4, and The third plug RF contact 231-3 may be spaced apart along the first axis direction.

In this case, the first plug RF contact 231-1 and the fourth plug RF contact 231-4, which are adjacent to and spaced apart from each other along the second axis direction, are the first plug RF contact 231-1. and the first plug shield contact 234-1 disposed between the fourth plug RF contacts 231-4.

Similarly, the second plug RF contact 231-2 and the third plug RF contact 231-3 arranged adjacent to and spaced apart from each other along the second axis direction are the second plug RF contact 231-2 and It can be electrically shielded through the second plug shield contact 234-2 disposed between the third plug RF contacts 231-3.

In addition, the plug signal contact 232 is a first plug disposed between the first plug RF contact 231-1 and the second plug RF contact 231-2 along the first axis direction. A second plug signal contact disposed between the signal contact 232-1 and the fourth plug RF contact 231-4 and the third plug RF contact 231-3 along the first axis direction. It may include (232-2).

Here, each of the first plug signal contact 232-1 and the second plug signal contact 232-2 may be provided as one, but a plurality of them may be grouped to form one plug signal contact 232.

In this case, the first plug signal contact 232-1 is electrically shielded from the first plug RF contact 231-1 through the third plug shield contact 234-3 and forms a fourth plug shield contact ( It can be electrically shielded from the second plug RF contact 231-2 through 234-4).

Similarly, the second plug signal contact 232-2 is electrically shielded from the third plug RF contact 231-3 through the fifth plug shield contact 234-5 and is connected to the sixth plug shield contact (234-5). It can be electrically shielded from the fourth plug RF contact 231-4 through 234-6).

That is, each of the third plug shield contact 234-3 and the sixth plug shield contact 234-6 is provided to have a certain length and is attached to the plug insulating body 210 at a certain distance along the second axis direction. can be placed.

In addition, each of the fourth plug shield contact 234-4 and the fifth plug shield contact 234-5 is provided to have a certain length and is attached to the plug insulating body 210 to be spaced at a certain distance along the second axis direction. can be placed.

Here, each of the third plug shield contact 234-3 and the sixth plug shield contact 234-6 may be arranged such that one end is exposed to the outside through the first cut portion 215-1, Each of the fourth plug shield contact 234-4 and the fifth plug shield contact 234-5 may be arranged such that one end is exposed to the outside through the second cut portion 215-2.

At this time, the plug compatible contact 233 is disposed adjacent to one of the two plug RF contacts 231 spaced apart along the first axis direction and is connected to the plug shield contact 234. It can be disposed on the plug insulating body 210 so as to be electrically shielded from the plug RF contacts 231 disposed adjacent to each other.

In addition, the plug compatible contact 233 can be disposed on the plug insulating body 210 to be electrically shielded from both the plug signal contact 232 and the plug RF contact 231 through the plug shield contact 234. there is.

In addition, the plug compatible contact 233 may be provided to have the same shape as the plug signal contact 232.

For example, the plug compatible contact 233 may include a first plug compatible contact 233-1 and a second plug compatible contact 233-2.

Additionally, each of the first plug compatible contact 233-1 and the second plug compatible contact 233-2 may be provided to have the same shape as the plug signal contact 232.

Here, as shown in FIG. 21, the first plug compatible contact 233-1 is located between the first plug RF contact 231-1 and the second plug RF contact 231-2 and is the first plug compatible contact 233-1. It may be placed adjacent to the first plug signal contact 232-1 along the 1-axis direction.

In addition, as shown in FIG. 21, the second plug compatible contact 233-2 is located between the third plug RF contact 231-3 and the fourth plug RF contact 231-4 and It may be placed adjacent to the second plug signal contact 232-2 along the 1-axis direction.

That is, in the plug connector 200 according to an embodiment of the present invention, the first plug RF contact 231-1, the first plug signal contact 232-1, and the first plug compatible contact 233-1. and the second plug RF contact 231-2 may be sequentially arranged along the first axis direction.

Similarly, in the plug connector 200 according to an embodiment of the present invention, the fourth plug RF contact 231-4, the second plug compatible contact 233-2, and the second plug signal contact 232-2 ) and the third plug RF contact 231-3 may be sequentially arranged along the first axis direction.

In this case, the first plug compatible contact 233-1 is arranged to surround the first plug compatible contact 233-1 through the plug shield contact 234. The first plug signal contact ( 232-1), the second plug signal contact 232, and the second plug RF contact 231-2 may all be disposed on the plug insulating body 210 to be electrically shielded.

In addition, the second plug compatible contact 233-2 is arranged to surround the second plug compatible contact 233-2 through the plug shield contact 234. The first plug signal contact 232- 1), it may be disposed on the plug insulating body 210 so as to be electrically shielded from both the second plug signal contact 232 and the fourth plug RF contact 231-4.

To this end, the plug shield contact 234 shields the first plug signal contact 232-1 and the first plug compatible contact 233-1 as shown in FIG. 21 and provides the first plug compatible contact 233-1. A seventh plug shield contact 234-7 arranged to shield the contact 233-1 and the second plug signal contact 232-2, the first plug signal contact 232-1, and An eighth plug shield arranged to shield the second plug compatible contact (233-2) and the second plug compatible contact (233-2) and the second plug signal contact (232-2). It may further include a contact 234-8.

At this time, each of the seventh plug shield contact 234-7 and the eighth plug shield contact 234-8 has a first portion disposed parallel to the first axis direction as shown in FIGS. 19 to 21 ( 234-7a, 234-8a) and second parts 234-7b, 234-8b extending from the first parts 234-7a, 234-8a so as to be parallel to the second axis direction. there is.

Through this, the first portions 234-7a and 234-8a can electrically shield the plug compatible contact 233 and the plug signal contact 232 disposed adjacent to each other along the second axis direction, The second portions 234-7b and 234-8b may electrically shield the plug compatible contact 233 and the plug signal contact 232 disposed adjacent to each other along the first axis direction.

That is, the first portion 234-7a of the seventh plug shield contact 234-7 electrically connects the first plug compatible contact 233-1 and the second plug signal contact 232-2. It can be shielded, and the second part (234-7b) of the seventh plug shield contact (234-7) is connected to the first plug compatible contact (233-1) and the first plug compatible contact (233-1) arranged adjacently along the first axis direction. 1 The plug signal contact 232-1 can be electrically shielded.

Additionally, the first portion 234-8a of the eighth plug shield contact 234-8 electrically connects the second plug compatible contact 233-2 and the first plug signal contact 232-1. It can be shielded, and the second part (234-8b) of the eighth plug shield contact (234-8) is connected to a second plug compatible contact (233-2) and a second plug compatible contact (233-2) disposed adjacently along the first axis direction. 2 The plug signal contact 232-2 can be electrically shielded.

Here, the first parts (234-7a, 234-8a) may be provided in a bar shape with a predetermined length, and the second parts (234-7b, 234-8b) may be provided with the first part (234-7b, 234-8b). A certain length may be extended from the end of 7a, 234-8a).

In addition, the second parts 234-7b and 234-8b may be fixed to the plug insulating body 210 and may be provided to have a shape that is bent at least once.

Through this, the second parts (234-7b, 234-8b) fixed to the plug insulating body 210 are arranged along the first seating groove 212, the protrusion 211, and the second seating groove 213. It can be.

Accordingly, the first plug compatible contact 233-1 has four sides through the plug shield member 220, the fourth plug shield contact 234-4, and the seventh plug shield contact 234-7. It can be placed on the plug insulating body 210 so that all are shielded, and the second plug compatible contact 233-2 is connected to the plug shield member 220, the sixth plug shield contact 234-6, and the eighth plug shield contact 234-6. It can be placed on the plug insulating body 210 so that all four sides are shielded through the plug shield contact 234-8.

That is, each of the first plug compatible contact 233-1 and the second plug compatible contact 233-2 is shielded on all four sides through the plug shield member 220 and the plug shield contact 234. When placed, it can function as a signal contact for transmitting general signals as well as an RF contact for transmitting RF signals.

Through this, the plug connector 200 according to an embodiment of the present invention maintains the same size as the existing one, but the total number of contacts that can function as RF contacts through the plug compatible contact 233 can be adjusted depending on the usage environment. It can be easily increased.

In addition, in the plug connector 200 according to an embodiment of the present invention, the first plug compatible contact 233-1 and the second plug compatible contact 233-2 are each arranged to be spaced apart along the first axis direction. Since it is placed adjacent to one of the two plug RF contacts 231, the amount of plug shield contact 234 used to shield all four sides can be minimized.

That is, when the first plug compatible contact 233-1 is disposed between the first plug signal contact 232-1 and the second plug RF contact 231-2, the first plug compatible contact ( 233-1) may share the fourth plug shield contact 234-4 for electrical shielding with the second plug RF contact 231-2.

Likewise, when the second plug compatible contact 233-2 is disposed between the second plug signal contact 232-2 and the fourth plug RF contact 231-4, the second plug compatible contact ( 233-2) may share the sixth plug shield contact 234-6 for electrical shielding with the fourth plug RF contact 231-4.

Accordingly, the plug connector 200 according to an embodiment of the present invention electrically shields the plug compatible contact 233 from other contacts so that the plug compatible contact 233 can function as an RF contact. By minimizing the amount of shield contact used, the production cost can be lowered while satisfying the electrical shielding required to implement the RF contact.

At this time, when the plug compatible contact 233 includes a first plug compatible contact 233-1 and a second plug compatible contact 233-2, the first plug compatible contact 233-1 ) and the second plug compatible contact 233-2 may be arranged to be spaced apart from each other along the first axis direction and positioned at an asymmetrical position with respect to the first axis.

In addition, the first plug compatible contact 233-1 and the second plug compatible contact 233-2 are arranged in asymmetric positions with respect to the first axis and are positioned relative to the virtual center point O. They may be arranged to be located diagonally from each other.

That is, as shown in FIG. 21, the first plug signal contact 232-1 and the first plug compatible contact 233-1 disposed adjacent to each other along the first axis direction are aligned in the first axis direction. Accordingly, the second plug compatible contact 233-2 and the second plug signal contact 232-2 may be arranged to be positioned diagonally from each other based on a virtual center point.

In this case, the seventh plug shield contact 234-7 and the eighth plug shield contact 234-8 may also be arranged to be located diagonally from each other with respect to the virtual center point.

In addition, the first plug RF contact 231-1 and the third plug RF contact 231-3 may be arranged to be located diagonally from each other with respect to a virtual center point, and the fourth plug RF contact 231-3 -4) and the second plug RF contact 231-2 may also be arranged to be located diagonally from each other based on the virtual center point.

Accordingly, when the plug connector 200 according to an embodiment of the present invention is coupled to the plug connector 200, even if the directions of both ends parallel to the first axis direction are changed, the plug connector 200 sequentially moves along the first axis direction. The arrangement relationship between the RF contact 231, the signal contact 232, the compatible contact 233, and the shield contact 234 arranged as can be maintained.

That is, even if the plug connector 200 according to an embodiment of the present invention is rotated 180 degrees with respect to the virtual center point as shown in FIG. 22, the third plug RF contact 231-3 in the rotated state , fifth plug shield contact (234-5), second plug signal contact (232-2), eighth plug shield contact (234-8), second plug compatible contact (233-2), sixth plug shield. The contact 234-6 and the fourth plug RF contact 231-4 are the first plug RF contact 231-1, the third plug shield contact 234-3, and the first plug RF contact 231-1 before being rotated 180 degrees. 1 plug signal contact (232-1), 7th plug shield contact (234-7), 1st plug compatible contact (233-1), 4th plug shield contact (234-4) and 2nd plug RF contact ( It can be changed to the same position as 231-2).

Likewise, even if the plug connector 200 according to an embodiment of the present invention is rotated 180 degrees with respect to the virtual center point as shown in FIG. 22, the first plug RF contact 231-1 and the third plug shield Contact (234-3), first plug signal contact (232-1), seventh plug shield contact (234-7), first plug compatible contact (233-1), fourth plug shield contact (234-4) ) and the second plug RF contact (231-2) is the third plug RF contact (231-3), the fifth plug shield contact (234-5), and the second plug signal contact (231-2) before being rotated 180 degrees. 232-2), the 8th plug shield contact (234-8), the 2nd plug compatible contact (233-2), the 6th plug shield contact (234-6), and the 4th plug RF contact (231-4) Each can be changed to the same location.

Through this, the plug connector 200 according to an embodiment of the present invention eliminates the coupling directionality of both ends parallel to the first axis direction when coupled with the receptacle connector 100, thereby preventing misalignment of contacts according to the coupling direction and The same problem can be prevented at the source.

Meanwhile, the plug contact portion 230 may be formed integrally with the plug insulating body 210 through insert molding, and one or more plug contacts of the plug contact portion 230 may have a portion of the cutout portion 215-1,215. -2) Alternatively, it may be arranged to be located within the openings 216-1 and 216-2.

For example, the seventh plug shield contact 234-7 is connected to the plug insulating body 210 so that the first portions 234-7a and 234-8a are exposed to the first cut portion 215-1. It can be arranged, and each of the third plug shield contact 234-3 and the sixth plug shield contact 234-6 has one end of the plug insulation body 210 exposed to the first cutout 215-1. ) can be placed in.

In addition, the eighth plug shield contact 234-8 is disposed on the plug insulating body 210 so that the first portions 234-7a and 234-8a are exposed to the second cut portion 215-2. It may be that the fourth plug shield contact 234-4 and the fifth plug shield contact 234-5 each have one end of the plug insulating body 210 exposed to the second cutout 215-2. can be placed in

In addition, each of the first plug signal contact 232-1, the seventh plug shield contact 234-7, and the first plug compatible contact 233-1 has one end connected to the first opening 216-1. It may be disposed on the plug insulating body 210 to be exposed, and each of the second plug compatible contact 233-2, the eighth plug shield contact 234-8, and the second plug signal contact 232-2 may be disposed on the plug insulating body 210 so that one end is exposed to the second opening 216-2.

Accordingly, when the plug connector 200 according to an embodiment of the present invention is mounted on a board (see 300 in FIG. 25), the operator cuts the first cut part 215-1 and the second cut part 215-1. 2), the state in which the plug contact part 230 is mounted on the board can be easily confirmed through the first opening 216-1 and the second opening 216-2.

At this time, at least some of the plug contacts of the plug contact portions 230 may be disposed along the first axis direction and coupled to the plug insulating body 210 to enable elastic deformation by external force.

For example, in the seventh plug shield contact 234-7, the first part 234-7a extending from the second part 234-7b is arranged to be located within the first cutout 215-1. 24, the first part 234-8a extending from the second part 234-8b in the eighth plug shield contact 234-8 is the second cutout ( It can be arranged to be located within 215-2).

In addition, the first plug shield contact 234-1 is located between the first plug RF contact 231-1 and the fourth plug RF contact 231-4 and has one end 234-1a connected to the first plug RF contact 231-1 and the fourth plug RF contact 231-4. It may be disposed on the protrusion 211 to enable elastic deformation along the first axis direction within the first seating groove 212.

Similarly, the second plug shield contact 234-2 is located between the second plug RF contact 231-2 and the third plug RF contact 231-3 and has one end 234-2a at the It may be disposed on the protrusion 211 to enable elastic deformation along the first axis direction within the first seating groove 212.

Through this, when the plug connector 200 and the receptacle connector 100 are coupled to each other, the seventh plug shield contact 234-7 disposed in the first cut portion 215-1 as shown in FIG. 3 The first parts (234-7a, 234-8a) of can be maintained in contact with the first parts (234-7a, 234-8a) of the sixth receptacle shield contact 234 through elastic deformation, The first portions (234-7a, 234-8a) of the eighth plug shield contact (234-8) disposed in the second cut portion (215-2) are elastically deformed to form the fifth receptacle shield contact (234). ) can be maintained in contact with the first parts (234-7a, 234-8a).

Likewise, when the plug connector 200 and the receptacle connector 100 are coupled to each other, as shown in FIG. 3, one end 234-1a of the first plug shield contact 234-1 undergoes elastic deformation. It is possible to maintain contact with the first receptacle shield contact 234 of the receptacle connector 100 inserted into the first seating groove 212.

In addition, when the plug connector 200 and the receptacle connector 100 are coupled to each other, one end 234-2a of the second plug shield contact 234-2 is elastically deformed into the first seating groove ( It may be maintained in contact with the second receptacle shield contact 234 of the receptacle connector 100 inserted into 212).

Accordingly, the plug connector 200 according to an embodiment of the present invention connects the receptacle through a plurality of plug shield contacts 234-1, 234-2, 234-7, and 234-8 arranged to enable elastic deformation along a first direction. By increasing the electrical conductivity with the connector 100, electromagnetic wave shielding performance can be further improved.

Meanwhile, the connector 1000 according to an embodiment of the present invention may further include a board 300 on which the above-described receptacle connector 100 or plug connector 200 is mounted, and the board 300 is It may include a plurality of transmission areas 330 partitioned by a shield pattern portion 310 formed on at least one surface.

For example, the substrate 300 may include a shield pattern portion 310 formed in a predetermined pattern on at least one surface as shown in Figure 25, and as shown in Figures 26 and 27, the plurality of transmission Each of the areas 330 may be a transmission area that is electrically shielded from each other through the shield pattern portion 310.

Here, the plurality of transmission areas 330 may include an RF signal transmission area 331 for transmitting an RF signal and a general signal transmission area 332 for transmitting a general signal, and the plurality of transmission areas 330 may further include a compatible transmission area 333 for transmitting RF signals or general signals.

In this case, each of the RF signal transmission area 331, the general signal transmission area 332, and the compatible transmission area 333 may be electrically shielded from each other through the shield pattern portion 310.

In particular, the compatible transmission area 333 can be electrically shielded through the RF signal transmission area 331 and the general signal transmission area 332 and the shield pattern portion 310 disposed around it.

Accordingly, even if the compatible transmission area 333 is arranged to be located between the RF signal transmission area 331 and the general signal transmission area 332, the compatible transmission area 333 is transmitted through the shield pattern portion 310. Since it can be electrically shielded from all other neighboring transmission areas 330, any one selected among general signals and RF signals can be smoothly transmitted.

Through this, the compatible transmission area 333 can serve as an RF signal transmission area for transmitting RF signals or as a general signal transmission area for transmitting general signals.

In this case, the above-described receptacle connector 100 may be mounted on one side of the substrate 300, and the receptacle contact portion 130 in the receptacle connector 100 is formed on one side of the substrate 300. It may be arranged to correspond to a plurality of transmission areas 330.

That is, when the receptacle connector 100 is mounted on the board 300, the receptacle RF contact 131 in the receptacle connector 100 is located in the RF signal transmission area 331 and is in contact with the board 300. It can be electrically connected, and the receptacle signal contact 132 can be electrically connected to the substrate 300 while located in the general signal transmission area 332, and the receptacle compatible contact 133 is located in the compatible transmission area. It may be located at (333) and electrically connected to the substrate 300.

In addition, when the receptacle connector 100 is mounted on the board 300, the receptacle shield contact 134 and the receptacle shield member 120 in the receptacle connector 100 are directly mounted on the shield pattern portion 310. It can be.

Accordingly, as described above, even if the receptacle compatibility contact 133 is arranged to be located between the receptacle RF contact 131 and the receptacle signal contact 132, the receptacle compatibility contact 133 is connected to the shield pattern portion ( 310) and the receptacle shield contact 134 and the receptacle shield member 120, which are electrically connected to the shield pattern portion 310, can be electrically shielded from all other contacts arranged adjacent to each other, thereby making the receptacle compatible. The contact 133 can smoothly transmit any one signal selected from a general signal and an RF signal.

Through this, the receptacle compatible contact 133 is placed in the compatible transmission area 333 so that all four sides are shielded through the receptacle shield member 120, the receptacle shield contact 134, and the shield pattern portion 310. As a result, it can serve as a signal contact for transmitting general signals as well as an RF contact for transmitting RF signals.

Similarly, the plug connector 200 described above may be mounted on one side of the board 300, and in the plug connector 200, the plug contact portion 230 may be formed on one side of the board 300. They can be arranged to correspond to the transmission areas 330.

That is, when the plug connector 200 is mounted on the board 300, the plug RF contact 231 in the plug connector 200 is located in the RF signal transmission area 331 and is in contact with the board 300. It can be electrically connected, and the plug signal contact 232 can be electrically connected to the substrate 300 while located in the general signal transmission area 332, and the plug compatible contact 233 is located in the compatible transmission area. It may be located at (333) and electrically connected to the substrate 300.

In addition, when the plug connector 200 is mounted on the board 300, the plug shield contact 234 and the plug shield member 220 in the plug connector 200 are directly mounted on the shield pattern portion 310. It can be.

Accordingly, as described above, even if the plug compatible contact 233 is disposed between the plug RF contact 231 and the plug signal contact 232, the plug compatible contact 233 is connected to the shield pattern portion ( 310) and the plug shield contact 234 and the plug shield member 220, which are electrically connected to the shield pattern portion 310, can be electrically shielded from all other contacts arranged adjacent to each other, thereby making the plug compatible. The contact 233 can smoothly transmit any one signal selected from a general signal and an RF signal.

Through this, the plug compatible contact 233 is placed in the compatible transmission area 333 so that all four sides are shielded through the plug shield member 220, plug shield contact 234, and shield pattern portion 310. As a result, it can serve as a signal contact for transmitting general signals as well as an RF contact for transmitting RF signals.

To this end, the substrate 300 includes a shield pattern portion 310 and a connection pattern portion 320 formed at a position that does not overlap the shield pattern portion 310, as shown in FIGS. 25 to 27. It can be done, and each of the shield pattern portion 310 and the connection pattern portion 320 may be a conductive pattern formed of a conductive material to be exposed to the outside on one surface of the substrate 300.

As a non-limiting example, each of the shield pattern portion 310 and the connection pattern portion 320 may be a copper foil pattern formed on one surface of the substrate 300 to be exposed to the outside.

In this case, the entire area of the substrate 300 may be divided into a plurality of transmission areas 330 by the shield pattern portion 310, and the connection pattern portion 320 may be divided into a plurality of transmission areas 330. ) can be arranged to be located in each.

For example, the shield pattern portion 310 includes an edge pattern 311 formed along the edge of the substrate 300, as shown in FIG. 26, and a first shield pattern formed along the first axis direction ( 312) and a second shield pattern 313 formed along the second axis direction.

In this case, the first shield pattern 312 may be provided as one, but may include a plurality of horizontal patterns 312-1, 312-2, and 312-3 arranged along the first axis direction. , the plurality of horizontal patterns 312-1, 312-2, and 312-3 may electrically shield two transmission areas arranged adjacent to each other along the second axis direction.

Additionally, the second shield pattern 313 may include a plurality of vertical patterns (313-1, 313-2, 313-3, 313-4, 313-5, 313-6), and the plurality of vertical patterns (313-1, 313-2, 313-6). 3,313-4,313-5,313-6) can electrically shield two transmission areas arranged adjacent to each other along the first axis direction.

Here, the first shield pattern 312 and the second shield pattern 313 may be a part where the receptacle shield contact 134 or the plug shield contact 234 is connected, and the border pattern 311 may be a portion of the receptacle shield contact 134 or the plug shield contact 234. It may be a part where the shield member 120 or the plug shield member 220 is connected.

Accordingly, a plurality of transmission areas 330 may be formed on one side of the substrate 300, each partitioned so that the four sides are completely surrounded by the shield pattern portion 310, as shown in FIG. 27.

For example, the plurality of transmission areas 330 include a first RF signal transmission area 331-1, a first general signal transmission area 332-, which are sequentially arranged along the first axis direction as shown in FIG. 27. 1), may include a first compatible transmission area (333-1) and a second RF signal transmission area (331-2), wherein the first RF signal transmission area (331-1) and the first general signal transmission area (332-1), the first compatible transmission area (333-1), and the second RF signal transmission area (331-2) each include the border pattern 311, the first shield pattern 312, and the second shield pattern ( 313) can be electrically shielded from each other.

In addition, the plurality of transmission areas 330 include a fourth RF signal transmission area 331-4 and a second compatible transmission area 333-2, which are sequentially arranged along the first axis as shown in FIG. 27. , may include a second general signal transmission area (332-2) and a third RF signal transmission area (331-3), the fourth RF signal transmission area (331-4), and a second compatible transmission area (333). -2), the second general signal transmission area (332-2) and the third RF signal transmission area (331-3) each include the border pattern 311, the first shield pattern 312, and the second shield pattern 313. ) can be electrically shielded from each other.

Here, the fourth RF signal transmission area (331-4) is arranged along the second axis direction and is electrically shielded through the first RF signal transmission area (331-1) and the first shield pattern (312). It can be, and the third RF signal transmission area (331-3) is arranged along the second axis direction and electrically transmits through the second RF signal transmission area (331-2) and the first shield pattern (312). can be shielded.

Accordingly, each of the plurality of transmission areas 330 can be formed so that its four sides are completely surrounded by the border pattern 311, the first shield pattern 312, and the second shield pattern 313.

In this case, the connection pattern portion 320 may be arranged to be located in each of the plurality of transmission areas 330 as described above.

For example, the connection pattern portion 320 is located within the first connection pattern 321 formed on one side of the substrate 300 so as to be located within the RF signal transmission area 331 and within the general signal transmission area 332. It may include a second connection pattern 322 formed on one side of the substrate 300 and a third connection pattern 323 formed on one side of the substrate 300 so as to be located within the compatible transmission area 333. Each of the first connection pattern 321, the second connection pattern 322, and the third connection pattern 323 is configured such that the receptacle connector 100 or the plug connector 200 is mounted on the board 300. In this case, they can be connected to corresponding contacts.

Accordingly, when the receptacle connector 100 or plug connector 200 is mounted on one side of the board 300, the above-described receptacle RF contact 131 or plug RF contact 231 is connected to the first contact through a solder member. 1 may be connected to the connection pattern 321, and the above-described receptacle signal contact 132 or plug signal contact 232 may be connected to the second connection pattern 322 through a solder member, and the above-described receptacle The compatible contact 133 or plug compatible contact 233 may be connected to the third connection pattern 323 via a solder member.

Through this, when the receptacle connector 100 is mounted on one surface of the board 300, each of the receptacle contact parts 130 is smoothly electrically connected to the shield pattern part 310 or the connection pattern part 320. It may be, and even if the receptacle compatibility contact 133 is arranged to be located between the receptacle RF contact 131 and the receptacle signal contact 132, the receptacle compatibility contact 133 may be connected to the shield pattern portion 310, The receptacle compatible contact 133 can be electrically shielded from all other contacts located adjacent to each other while located within the compatible transmission area 333 through the receptacle shield contact 134 and the receptacle shield member 120. can smoothly transmit any one signal selected among general signals and RF signals.

Similarly, when the plug connector 200 is mounted on one surface of the board 300, each of the plug contact parts 230 is smoothly electrically connected to the shield pattern part 310 or the connection pattern part 320. It can be, and even if the plug compatible contact 233 is arranged to be located between the plug RF contact 231 and the plug signal contact 232, the plug compatible contact 233 may be connected to the shield pattern portion 310, The plug compatible contact 233 can be electrically shielded from all other contacts located adjacent to each other while located within the compatible transmission area 333 through the plug shield contact 234 and the plug shield member 220. can smoothly transmit any one signal selected among general signals and RF signals.

Although the embodiments of the present invention have been described, the spirit of the present invention is not limited to the embodiments presented in this specification, and those skilled in the art who understand the spirit of the present invention can add or change components within the scope of the same spirit. , deletion, addition, etc., other embodiments can be easily proposed, but this will also be said to fall within the scope of the present invention.

Claims (18)

1. The island portion 112 is made of an electrically insulating material and is formed to have a predetermined height in the center, and a receiving groove 113 that is recessed to a certain depth along the outer circumferential surface of the island portion 112. ) and a receptacle insulating body 110 including an edge portion 114 formed to surround the island portion 112 while being spaced at a predetermined distance;

   A receptacle shield member 120 made of a conductive material and coupled to the edge portion 114 along the edge of the receptacle insulating body 110; and

   It is coupled to the receptacle insulating body 110 and includes a receptacle contact portion 130 that is electrically connected to the outside,

   The receptacle contact portion 130,

   A receptacle RF contact 131 for transmitting an RF signal, a receptacle signal contact 132 for transmitting a general signal, a receptacle compatible contact 133 for transmitting an RF signal or a general signal, and a receptacle for electrical shielding. Includes a receptacle shield contact (134),

   The receptacle compatible contact 133 is,

   A receptacle signal contact 132-2 located between the receptacle RF contact 131-2 and the receptacle signal contact 132-1, which are spaced apart along the first axis direction in the longitudinal direction, and which are different along the second axis direction in the width direction. ) are spaced apart to face the

   The receptacle shield contact 134 is,

   Between the receptacle RF contact (131-2) and the receptacle compatible contact (133-1) spaced apart along the first axis direction,

   Between the receptacle compatible contact (133-1) and the receptacle signal contact (132-1) spaced apart along the first axis direction,

   A receptacle connector disposed between the receptacle compatible contact (133-1) and another receptacle signal contact (132-2) spaced apart along the second axis direction.
2. According to paragraph 1,

   The receptacle insulating body 110 includes a first edge (111a), a second edge (111b) spaced apart from the first edge (111a) along the first axis direction, and a second edge (111b) perpendicular to the first axis direction. A third edge (111c) spaced apart from the second edge (111b) along the axial direction and a first edge (111c) spaced apart from the third edge (111c) along the first axis direction ( It includes a fourth edge (111d) spaced apart from 111a),

   The receptacle RF contact 131 is,

   A first receptacle RF contact (131-1) disposed adjacent to the first corner (111a), a second receptacle RF contact (131-2) disposed adjacent to the second corner (111b), and the third corner It includes a third receptacle RF contact (131-3) disposed adjacent to (111c) and a fourth receptacle RF contact (131-4) disposed adjacent to the fourth corner (111d),

   The receptacle signal contact 132 is,

   A first receptacle signal contact (132-1) disposed between the first receptacle RF contact (131-1) and the second receptacle RF contact (131-2) along the first axis direction, and the first receptacle signal contact (132-1) It includes a second receptacle signal contact (132-2) disposed between the third receptacle RF contact (131-3) and the fourth receptacle RF contact (131-4) along the 1-axis direction,

   The receptacle compatible contact 133 is,

   A first receptacle signal contact (132-1) located between the first receptacle RF contact (131-1) and the second receptacle RF contact (131-2) and disposed adjacent to the first receptacle signal contact (132-1) along the first axis direction. 1 The second receptacle signal is located between the receptacle compatible contact (133-1), the third receptacle RF contact (131-3), and the fourth receptacle RF contact (131-4) along the first axis direction. A receptacle connector including a second receptacle compatible contact (133-2) disposed adjacent to the contact (132-2).
3. According to paragraph 2,

   The first receptacle compatible contact 133-1 is connected to the first receptacle signal contact 132-1, the second receptacle signal contact 132, and the second receptacle RF contact 131 through the receptacle shield contact 134. -2) is placed in the receptacle insulating body 110 so as to be electrically shielded,

   The second receptacle compatible contact 133-2 is connected to the first receptacle signal contact 132-1, the second receptacle signal contact 132, and the fourth receptacle RF contact 131 through the receptacle shield contact 134. -4) and are disposed on the receptacle insulating body 110 so as to be electrically shielded,

   The first receptacle compatible contact (133-1) and the second receptacle compatible contact (133-2) are receptacles arranged to be spaced apart from each other along the first axis direction and located at an asymmetrical position with respect to the first axis. connector.
4. According to paragraph 2,

   The first receptacle signal contact 132-1 and the first receptacle compatible contact 133-1 arranged adjacent to each other along the first axis direction are the second receptacles arranged adjacent to each other along the first axis direction. A receptacle connector arranged to be located diagonally from the compatible contact (133-2) and the second receptacle signal contact (132-2) with respect to the virtual center point (O).
5. According to paragraph 2,

   The receptacle shield contact 134 is,

   a first receptacle shield contact (134-1) for shielding the first receptacle RF contact (131-1) and the fourth receptacle RF contact (131-4) spaced apart along the second axis direction, and the second receptacle shield contact (134-1) A second receptacle shield contact (134-2) for shielding the second receptacle RF contact (131-2) and the third receptacle RF contact (131-3) spaced apart along the axial direction, and the first receptacle RF contact (131-1) and the first receptacle signal contact (132-1) while shielding the fourth receptacle RF contact (131-4) and the second receptacle compatible contact (133-2). The third receptacle shield contact (134-3) disposed along the second axis direction, shielding the second receptacle RF contact (131-2) and the first receptacle compatible contact (133-1) while shielding the third receptacle shield contact (134-3) disposed along the second axis direction. A fourth receptacle shield contact (134-4) disposed along the second axis direction to shield the receptacle RF contact (131-3) and the second receptacle signal contact (132-2), and the first receptacle To shield the first receptacle compatible contact (133-1) and the second receptacle signal contact (132-2) while shielding the signal contact (132-1) and the first receptacle compatible contact (133-1). A fifth receptacle shield contact (134-5) arranged so as to shield the first receptacle signal contact (132-1) and the second receptacle compatible contact (133-2) while shielding the second receptacle compatible contact. A receptacle connector including (133-2) and a sixth receptacle shield contact (134-6) disposed to shield the second receptacle signal contact (132-2).
6. According to clause 5,

   Each of the fifth receptacle shield contact (134-5) and the sixth receptacle shield contact (134-6) includes first portions (134-5a, 134-6a) arranged parallel to the first axis direction, and the first portion (134-5a, 134-6a) It includes second parts (134-5b, 134-6b) extending from the first parts (134-5a, 134-6a) parallel to the two-axis direction,

   The first portions 134-5a and 134-6a electrically shield the receptacle compatible contact 133 and the receptacle signal contact 132 disposed along the second axis direction,

   The second portion (134-5b, 134-6b) is a receptacle connector that electrically shields the receptacle compatible contact 133 and the receptacle signal contact 132 disposed along the first axis direction.
7. According to clause 5,

   The receptacle insulating body 110 includes a first cut portion 115-1 located inside the first edge 111a and formed through a predetermined area on the bottom surface of the receiving groove 113,

   The first receptacle shield contact (134-1) and the first receptacle RF contact (131-1) are receptacle connectors arranged so that one end formed as a cut surface is exposed to the first cut portion (115-1).
8. According to paragraph 2,

   The receptacle shield member 120 includes a body 122 coupled to the edge portion 114 of the receptacle insulating body 110 so as to surround the edge of the receptacle insulating body 110, and It includes extension parts (124-1, 124-2) extending elastically and deformably toward the receiving groove (113),

   The extension parts (124-1, 124-2) are between the first receptacle RF contact (131-1) and the fourth receptacle RF contact (131-4) spaced apart along the second axis direction and the second receptacle RF. A receptacle connector formed to be located between the contact (131-2) and the third receptacle RF contact (131-3).
9. According to paragraph 1,

   The receptacle insulating body 110 includes penetrating portions 116-1 and 116-2 formed with a predetermined area to penetrate the edge portion 114, and the edge crossing the penetrating portions 116-1 and 116-2. It further includes a support portion 117 extending from the portion 114 and contacting the receptacle shield member 120,

   The support portion 117 has a cross-sectional area of a certain length and a certain height and extends along the second axis direction from the edge portion 114 to cross the penetration portions 116-1 and 116-2.
10. According to paragraph 1,

    The receptacle compatible contact 133 is a receptacle connector provided to have the same shape as the receptacle signal contact 132.
11. A closed loop-shaped protrusion 211 made of an electrically insulating material and protruding at a certain height in the center, a first seating groove 212 and the protrusion 211 recessed to a certain depth inside the protrusion 211. A plug insulating body 210 including a second seating groove 213 formed at a certain depth along the outer peripheral surface of;

    A plug shield member 220 made of a conductive material and coupled to surround an edge of the plug insulating body 210; and

    It is coupled to the plug insulating body 210 and includes a plug contact portion 230 that is electrically connected to the outside,

    The plug contact portion 230 is,

    A plug RF contact 231 for transmitting an RF signal, a plug signal contact 232 for transmitting a general signal, a plug compatible contact 233 for transmitting an RF signal or a general signal, and a plug for electrical shielding. Includes plug shield contact 234,

    The plug compatible contact 233 is,

    A plug signal contact 232-2 located between the plug RF contact 231-2 and the plug signal contact 232-1, which are spaced apart along the first axis direction in the longitudinal direction, and another plug signal contact 232-2 along the second axis direction in the width direction. ) are spaced apart to face the

    The plug shield contact 234 is,

    Between the plug RF contact (231-2) and the plug compatible contact (233-1) spaced apart along the first axis direction,

    Between the plug compatible contact (233-1) and the plug signal contact (232-1) spaced apart along the first axis direction,

    A plug connector disposed between the plug compatible contact (233-1) and the other plug signal contact (232-2) spaced apart along the second axis direction.
12. According to clause 11,

    The protrusion 211 has a first edge 211a, a second edge 211b spaced apart from the first edge 211a along the first axis direction, and a second axis direction perpendicular to the first axis direction. A third edge 211c is spaced apart from the second edge 211b, and a first edge 211a is spaced apart from the third edge 211c along the first axis direction. It includes a fourth edge 211d that is spaced apart,

    The plug RF contact 231 is,

    A first plug RF contact 231-1 disposed adjacent to the first corner 211a, a second plug RF contact 231-2 disposed adjacent to the second corner 211b, and the third corner It includes a third plug RF contact (231-3) disposed adjacent to (211c) and a fourth plug RF contact (231-4) disposed adjacent to the fourth corner (211d),

    The plug signal contact 232 is,

    A first plug signal contact 232- disposed on the protrusion 211 to be located between the first plug RF contact 231-1 and the second plug RF contact 231-2 along the first axis direction. 1) and a second plug signal contact 232-2 disposed between the third plug RF contact 231-3 and the fourth plug RF contact 231-4 along the first axis direction. Includes,

    The plug compatible contact 233 is,

    A first plug located between the first plug RF contact 231-1 and the second plug RF contact 231-2 and disposed adjacent to the first plug signal contact 232-1 along the first axis direction. 1 The second plug signal located between the plug compatible contact 233-1 and the third plug RF contact 231-3 and the fourth plug RF contact 231-4 along the first axis direction. A plug connector including a second plug compatible contact (233-2) disposed adjacent to the contact (232-2).
13. According to clause 12,

    The first plug compatible contact 233-1 is connected to the first plug signal contact 232-1, the second plug signal contact 232, and the second plug RF contact 231 through the plug shield contact 234. -2) is disposed on the plug insulating body 210 to be electrically shielded,

    The second plug compatible contact 233-2 is connected to the first plug signal contact 232-1, the second plug signal contact 232, and the fourth plug RF contact 231 through the plug shield contact 234. -4) and are disposed on the plug insulating body 210 so as to be electrically shielded,

    The first plug compatible contact 233-1 and the second compatible contact 233-2 are a plug connector arranged to be spaced apart from each other along the first axis direction and positioned at an asymmetrical position with respect to the first axis. .
14. According to clause 12,

    The first plug signal contact 232-1 and the first plug compatibility contact 233-1 arranged adjacent to each other along the first axis direction are the second plug arranged adjacent to each other along the first axis direction. A plug connector arranged to be located diagonally from the compatible contact 233-2 and the second plug signal contact 232-2 with respect to a virtual center point.
15. According to clause 12,

    The plug shield contact 234 is,

    a first plug shield contact 234-1 for shielding the first plug RF contact 231-1 and the fourth plug RF contact 231-4 arranged to be spaced apart along the second axis direction; and the second plug RF contact 234-1. A second plug shield contact (234-2) for shielding the second plug RF contact (231-2) and the third plug RF contact (231-3) spaced apart along the axial direction, and the first plug RF contact (231-1) and a third plug shield contact 234-3 for shielding the first plug signal contact 232-1, the first plug compatible contact 233-1, and the second plug A fourth plug shield contact (234-4) for shielding the RF contact (231-2), and a fourth plug shield contact (234-4) for shielding the third plug RF contact (231-3) and the second plug signal contact (232-2). A fifth plug shield contact (234-5) and a sixth plug shield contact (234-6) for shielding the fourth plug RF contact (231-4) and the second plug compatible contact (233-2). and, while shielding the first plug signal contact 232-1 and the first plug compatible contact 233-1, the first plug compatible contact 233-1 and the second plug signal contact 232 -2) while shielding the seventh plug shield contact 234-7, the first plug signal contact 232-1, and the second plug compatible contact 233-2. A plug connector including a second plug compatible contact (233-2) and an eighth plug shield contact (234-8) disposed to shield the second plug signal contact (232-2).
16. According to clause 15,

    Each of the seventh plug shield contact 234-7 and the eighth plug shield contact 234-8 includes first portions 234-7a and 234-8a disposed parallel to the first axis direction, and the first portion 234-7a and 234-8a. It includes second parts (234-7b, 234-8b) extending from the first parts (234-7a, 234-8a) parallel to the two-axis direction,

    The first portions 234-7a and 234-8a electrically shield the plug compatible contact 233 and the plug signal contact 232 disposed along the second axis direction,

    The second portion (234-7b, 234-8b) is a plug connector that electrically shields the plug compatible contact 233 and the plug signal contact 232 disposed along the first axis direction.
17. According to clause 16,

    The plug insulating body 210 has a first cut portion 215-1 and a second cut portion 215-1, which are located inside the protrusion 211 and are respectively formed through a predetermined area on the bottom surface of the first seating groove 212. Includes an incision 215-2,

    The first portions 234-7a and 234-8a of the seventh plug shield contact 234-7 are located at least partially within the first cutout 215-1 to enable elastic deformation by external force. It is placed,

    The first portions 234-7a and 234-8a of the eighth plug shield contact 234-8 are located at least partially within the second cutout 215-2 to enable elastic deformation by external force. Plug connector positioned.
18. According to clause 11,

    The plug compatible contact 233 is a plug connector provided to have the same shape as the plug signal contact 232.

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