KR102638551B1 - Optical Connector - Google Patents

Abstract

The present invention includes an optical module to which an optical transmission cable is connected, a sub-board to which the optical module is coupled, and a plug assembly to which the sub-board is coupled, wherein the plug assembly includes a plug body accommodating the optical module and the sub-board. The plug body includes a first support groove into which an optical transmission cable is inserted so that the optical transmission cable is connected to each of the optical module and an external device disposed outside the plug assembly, and a first support member in which the first support groove is formed. It relates to an optical connector that includes.

Description

Optical Connector

The present invention relates to an optical connector for transmitting optical signals using an optical transmission cable.

Recent electronic devices are becoming more high-performance, faster, more integrated, smaller, and thinner thanks to the advancement of IT technology. Types of electronic devices include, for example, smartphones, smart TVs, computers, tablet PCs, displays, digital cameras, camcorders, MP3 players, game consoles, navigation devices, etc.

Recent trends in electronic devices require high-speed transmission technology for large-capacity data, such as high-definition and 3D video content, between boards within devices. Accordingly, signal attenuation, noise, EMI/EMC, impedance matching, cross talk, skew, miniaturization of connection wiring, etc. This is emerging as a big issue.

Generally, copper-based wiring, or electrical connectors, are used to transmit data within devices. However, copper wiring not only fails to meet the needs for high-speed, high-capacity data transmission, but also fails to resolve various technical issues in line with recent electronic device trends mentioned above.

Recently, optical wiring technology has been researched and developed as a technology to solve this problem. In other words, optical wiring replaces tens of channels of parallel electrical signal lines with serial optical signal lines, enabling high-speed transmission of large amounts of data.

An optical connector according to the prior art includes a receptacle assembly mounted on a board within a device and a plug assembly coupled to the receptacle assembly. To connect the optical signal line and the board within the device, an optical transmission cable is sometimes connected to the plug assembly. The optical connector according to the prior art has a problem in that the optical transmission cable is easily separated from the plug assembly due to the manufacturer's carelessness or work environment during the manufacturing process.

The present invention was developed to solve the above-mentioned problems and is intended to provide an optical connector that can prevent an optical transmission cable from being easily separated from the plug assembly.

In order to solve the problems described above, the following configuration may be included.

The optical connector according to the present invention may include an optical module to which an optical transmission cable is connected, a sub-board to which the optical module is coupled, and a plug assembly to which the sub-board is coupled. The plug assembly may include a plug body including the optical module and the sub-board. The plug body may include a first support groove into which an optical transmission cable is inserted so that the optical transmission cable is connected to each of the optical module and an external device disposed outside the plug assembly, and a first support member in which the first support groove is formed. You can. The first support member may support the optical transmission cable inserted into the first support groove so that the distance over which the optical transmission cable can move is limited.

According to the present invention, the following effects can be achieved.

The present invention can improve the stability of optical signal transmission by maintaining the optical transmission cable in a firmly connected state.

1 is a schematic perspective view of an optical connector according to the present invention.
Figure 2 is a schematic exploded perspective view of the optical connector according to the present invention.
Figure 3 is a schematic plan view for explaining the first support member, the second support member, the first support groove, the second support groove, and the receiving groove.
Figure 4 is a schematic rear view to explain that the size of the first support groove is formed to be smaller than the size of the optical transmission cable.
Figure 5 is a schematic plan view to explain that the size of the first support groove is smaller than the size of the optical transmission cable.
6(a) and 6(b) are schematic rear views illustrating the pressing member in the optical connector according to the present invention.
Figure 7 is a schematic rear view illustrating that the pressing member includes a curved surface in the optical connector according to the present invention.
Figure 8 is a schematic side view of an embodiment in which the optical connector according to the present invention has a plurality of pressing members.
Figure 9 is a schematic rear view of another embodiment in which the optical connector according to the present invention has a plurality of pressing members.
10 is a schematic plan view illustrating the coupling groove and coupling protrusion in the optical connector according to the present invention.
11 and 12 are schematic plan views illustrating soft locking in the optical connector according to the present invention.
Figure 13 is a schematic side cross-sectional view for explaining the locking member, locking protrusion, and locking groove in the optical connector according to the present invention based on line II of Figure 12.
Figure 14 is a schematic side view for explaining hard locking in the optical connector according to the present invention.
15 is a schematic plan view illustrating hard locking in the optical connector according to the present invention.
Figure 16 is a conceptual plan view for explaining the insertion part, insertion position, and separation position in the optical connector according to the present invention.
FIG. 17 is a schematic plan view showing an enlarged portion A of FIG. 16 to illustrate the first insertion surface and the second insertion surface in the optical connector according to the present invention.
18 is a schematic plan view of a comparative example in which the first insertion surface and the second insertion surface form an obtuse angle to each other.
Figure 19 is a conceptual plan view for explaining the fixing surface and the separation groove in the optical connector according to the present invention.
20 is a conceptual plan view for explaining the elastic part in the optical connector according to the present invention.
Figure 21 is a schematic side view for explaining the first elastic arm, the second elastic arm, and the third elastic arm in the optical connector according to the present invention.

Hereinafter, embodiments of the optical connector according to the present invention will be described in detail with reference to the attached drawings.

Referring to Figures 1 and 2, the optical connector 1 according to the present invention is used to transmit optical signals within or between electronic devices. For example, the optical connector 1 according to the present invention can be applied to display devices, USB cables, HDMI (High Definition Multimedia Interface), etc.

The optical connector (1) according to the present invention includes an optical module (10) to which an optical transmission cable is connected, a sub-board (11) to which the optical module (10) is coupled, and a plug assembly (2) to which the sub-board (11) is coupled. may include.

The optical module 10 is for transmitting optical signals. The optical module 10 may be coupled to the sub-board 11. The optical module 10 may be coupled to the upper surface of the sub-board 11. The upper surface of the sub-substrate 11 faces upward (UD arrow direction, shown in FIG. 2). The optical module 10 may be accommodated inside the plug assembly 2. An optical transmission cable 100 may be connected to the optical module 10. One side of the optical transmission cable 100 may be connected to the optical module 10 and the other side may be connected to an external device (not shown). Accordingly, an optical signal is transmitted between the optical module 10 and the external device through the optical transmission cable 100. One side of the optical transmission cable 100 may be connected to the optical module 10 inside the plug assembly 2. The other side of the optical transmission cable 100 may be connected to the external device outside of the plug assembly 2.

When the optical connector 1 according to the present invention is used as a transmitter, the optical module 10 emits light such as a laser diode, a vertical-cavity surface-emitting laser (VCSEL), etc. It may include elements. When the optical connector 1 according to the present invention is used as a receiving unit, the optical module 10 may include a light receiving element such as a photo diode (PD).

The optical module 10 may include a plurality of optical elements (not shown) to implement multi-channel. The optical elements may be coupled to the sub-substrate 11 so as to be spaced apart from each other along the first axis direction (X-axis direction).

The sub-board 11 is a board for modularizing the optical module 10 and the plug assembly 2. The optical module 10 may be coupled to the sub-board 11. The sub-board 11 may support the optical module 10 so that the optical module 10 and the optical transmission cable 100 are connected. The sub-board 11 may be accommodated inside the plug assembly 2. The sub-board 11 may be a printed circuit board (PCB).

The plug assembly 2 can be connected to the external device through the optical transmission cable 100. The plug assembly 2 can accommodate the optical module 10 and the sub-board 11. The plug assembly 2 can be connected to the external device on a main board (not shown) to which the sub-board 11 is coupled. In this case, the sub-board 11 is a board for modularizing the optical module 10 and the receptacle assembly 3, and the main board is a board for transmitting optical signals to electronic devices.

The plug assembly 2 may include a plug body 21.

The plug body 21 may form the overall shape of the plug assembly 2. The plug body 21 can accommodate the optical module 10 and the sub-board 11. The optical transmission cable 100 may be coupled to the plug body 21. One side of the optical transmission cable 100 may be connected to the optical module 10 accommodated inside the plug body 21, and the other side may be connected to the external device located outside the plug body 21. One side of the optical transmission cable 100 may be inserted into the plug body 21. The optical transmission cable 100 may be inserted into the plug body 21 along a second axis direction (Y-axis direction) perpendicular to the first axis direction (X-axis direction). A plurality of optical transmission cables 100 may be inserted into the plug body 21. The plug body 21 may be formed as a whole in a rectangular parallelepiped shape, but is not limited thereto and may be formed in another shape such as a cylindrical shape as long as the optical transmission cable 100 can be inserted.

Referring to FIG. 3, the plug body 21 may include a first support member 211 and a first support groove 211a.

The first support member 211 supports the optical transmission cable 100 so that the distance over which the optical transmission cable 100 can move is limited. The first support member 211 may be formed on the plug body 21. The first support member 211 may be formed to protrude upward from the lower surface of the plug body 21 (UD arrow direction, shown in FIG. 2). The first support member 211 may form the rear of the plug body 21. The first support member 211 may support the optical transmission cable 100 to limit the distance that the optical transmission cable 100 can move in the outward direction (OD arrow direction, shown in FIG. 3). The outward direction (OD arrow direction) is parallel to the second axis direction (Y-axis direction), from the front of the plug body 21 to the rear of the plug body 21. The direction is toward the corresponding first support member 211.

Accordingly, the optical connector 1 according to the present invention is implemented to limit the distance that the optical transmission cable 100 can move while inserted into the plug body 21 using the first support member 211. , it is possible to increase the connection strength between the optical module 10 and the optical transmission cable 100. Therefore, the optical connector 1 according to the present invention can prevent the optical transmission cable 100 from being easily separated from the optical module 10 by external forces such as external shock, so that the external device and the optical module ( 10) The stability of optical signal transmission between the liver can be improved.

The optical transmission cable 100 can be inserted into the first support groove 211a. The first support groove 211a may be formed in the first support member 211. Accordingly, the optical transmission cable 100 is inserted into the first support groove 211a, thereby passing through the first support member 211 and connecting the optical module 10 located inside the plug body 21 and the The external device located outside the plug body 21 can be connected. As the optical transmission cable 100 is inserted into the first support groove 211a, the first support member 211 is attached to both sides of the optical transmission cable 100 based on the first axis direction (X-axis direction). can support. Accordingly, the first support member 211 may limit the distance that the optical transmission cable 100 can move in the first axis direction (X-axis direction). The first support groove 211a may have an overall rectangular shape, but is not limited thereto and may be formed in a circular shape as long as the optical transmission cable 100 can be inserted. The first support groove 211a may be formed by machining a groove to a certain depth on the upper surface of the first support member 211.

Referring to Figures 4 and 5, the first support groove 211a may be formed in a smaller size than the optical transmission cable 100. Based on the first axis direction (X-axis direction), the length 211aL of the first support groove 211a may be made smaller than the length D of the optical transmission cable 100. The length (D) of the optical transmission cable 100 may correspond to the diameter. Accordingly, the optical transmission cable 100 can be compressed and inserted into the first support groove 211a. That is, the optical transmission cable 100 can be inserted into the first support groove 211a using an interference fit method. Accordingly, the optical connector 1 according to the present invention can increase the coupling force with which the optical transmission cable 100 is coupled to the first support member 211 through the first support groove 211a, and thus the optical transmission The connection between the cable 100 and the optical module 10 can be further strengthened. Therefore, the optical connector 1 according to the present invention can strengthen the prevention force to prevent the optical transmission cable 100 from being easily separated from the optical module 10 by external forces such as external shock.

Referring to FIG. 3, the plug body 21 may include a second support member 212 and a second support groove 212a.

The second support member 212 supports the optical transmission cable 100 so that the distance over which the optical transmission cable 100 can move is limited. The second support member 212 may be formed on the plug body 21. The second support member 212 may be formed to protrude upward from the lower surface of the plug body 21 (UD arrow direction, shown in FIG. 2). The second support member 212 may be spaced apart from the first support member 211 toward the front of the plug body 21. The second support member 212 may support the optical transmission cable 100 to limit the distance that the optical transmission cable 100 can move in the inward direction (ND arrow direction, shown in FIG. 3). The inner direction (ND arrow direction, shown in FIG. 3) is opposite to the outer direction (OD arrow direction, shown in FIG. 3).

Accordingly, the optical connector 1 according to the present invention is implemented to limit the distance that the optical transmission cable 100 can move while inserted into the plug body 21 using the second support member 212. , it is possible to increase the connection strength between the optical module 10 and the optical transmission cable 100. Therefore, the optical connector 1 according to the present invention can prevent the optical transmission cable 100 from being easily separated from the optical module 10 by external forces such as external shock, so that the external device and the optical module ( 10) The stability of optical signal transmission between the liver can be improved.

The optical transmission cable 100 may be inserted into the second support groove 212a. The second support groove 212a may be formed in the second support member 212. Accordingly, the optical transmission cable 100 is inserted into the second support groove 212a, thereby passing through the second support member 212 and connecting the optical module 10 located inside the plug body 21 and the The external device located outside the plug body 21 can be connected. As the optical transmission cable 100 is inserted into the second support groove 212a, the second support member 212 is attached to both sides of the optical transmission cable 100 based on the first axis direction (X-axis direction). can support. Accordingly, the second support member 212 may limit the distance that the optical transmission cable 100 can move in the first axis direction (X-axis direction). The second support groove 212a may have an overall rectangular shape, but is not limited thereto and may be formed in a circular shape as long as the optical transmission cable 100 can be inserted. The second support groove 212a may be formed by machining a groove to a certain depth on the upper surface of the second support member 212.

The second support groove 212a may be formed in a smaller size than the optical transmission cable 100. Accordingly, the optical transmission cable 100 can be compressed and inserted into the second support groove 212a. That is, the optical transmission cable 100 can be inserted into the second support groove 212a using an interference fit method. Accordingly, the optical connector 1 according to the present invention can increase the coupling force with which the optical transmission cable 100 is coupled to the second support member 212 through the second support groove 212a, and thus The connection between the cable 100 and the optical module 10 can be further strengthened. Therefore, the optical connector 1 according to the present invention can strengthen the prevention force to prevent the optical transmission cable 100 from being easily separated from the optical module 10 by external forces such as external shock.

The optical connector 1 according to the present invention is implemented so that different parts of the optical transmission cable 100 are compressed and inserted through the first support groove 211a and the second support groove 212a, so that the optical transmission The coupling force with which the cable 100 is coupled to the first support member 211 and the second support member 212 can be doubly strengthened. Therefore, the optical connector 1 according to the present invention further strengthens the connection between the optical transmission cable 100 and the optical module 10, so that the optical transmission cable 100 is connected to the optical module by an external force such as an external impact. (10) The prevention force to prevent easy separation can be further strengthened.

Referring to Figures 3 to 5, the plug body 21 may include a receiving groove 213 disposed between the first support member 211 and the second support member 212.

The receiving groove 213 accommodates the knot provided in the optical transmission cable 100. Here, a knot means tying the optical transmission cable 100. The receiving groove 213 may be formed in the space between the first support member 211 and the second support member 212. The receiving groove 213 may be formed to have a longer length than the first support groove 211a and the second support groove 212a based on the first axis direction (X-axis direction). Through this, a space capable of accommodating the knot provided in the optical transmission cable 100 can be secured in the receiving groove 213.

Accordingly, the optical connector 1 according to the present invention is implemented so that the receiving groove 213 accommodates the knot provided in the optical transmission cable 100, so that the first support member 211 supports the knot and In addition to limiting the distance that can be moved in the direction (OD arrow direction, shown in FIG. 3), the second support member 212 supports the knot and moves in the inward direction (ND arrow direction, shown in FIG. 3). The possible distance can be limited. Therefore, the optical connector 1 according to the present invention can increase the prevention force of preventing the optical transmission cable 100 from being easily separated from the optical module 10.

Referring to FIGS. 6 to 9, the plug assembly 2 may include a plug cover 22.

The plug cover 22 is coupled to the plug body 21. The plug cover 22 may be coupled to the upper part of the plug body 21 to cover the plug body 21. Therefore, the plug cover 22 can protect the components accommodated inside the plug body 21 from the outside. The plug cover 22 may be formed in a shape corresponding to the plug body 21. For example, the plug cover 22 may be formed in a square plate shape.

Referring to FIG. 6(a), a pressing member 221 may be formed on the plug cover 22.

The pressing member 221 presses the optical transmission cable 100 toward the plug body 21. The pressing member 221 may protrude from the plug body 21 in a downward direction (direction of arrow DD, shown in FIG. 2). The downward direction (direction of arrow DD) is opposite to the upward direction (direction of arrow UD, shown in FIG. 2).

Referring to FIG. 6(b), when the plug cover 22 is coupled to the plug body 21, the pressing member 221 can press the optical transmission cable 100. Accordingly, the optical connector 1 according to the present invention can be implemented to not only increase the coupling force of the optical transmission cable 100 with the plug body 21, but also increase the coupling force with the plug cover 22. . Therefore, the optical connector 1 according to the present invention increases the coupling force of the optical transmission cable 100 with the plug body 21 and the plug cover 22 by the pressing member 221, so that the optical transmission cable ( 100) can be increased to prevent the optical module 10 from being easily separated. The pressing member 221 may be formed as a whole in a square plate shape, but is not limited to this and may be formed in another shape such as a cylindrical shape as long as it is capable of pressing the optical transmission cable 100.

Referring to FIG. 7, the pressing member 221 may include a pressing surface 221a that contacts the optical transmission cable 100. The pressure surface 221a may be formed to have a curved surface. In this case, the contact area between the pressing member 221 and the optical transmission cable 100 increases through the pressing surface 221a, so that the plug body 21 and the plug cover ( 22), the binding force can be further increased. Accordingly, the optical connector 1 according to the present invention is implemented such that the pressing member 221 is formed to form a curved surface, thereby providing a preventing force to prevent the optical transmission cable 100 from being easily separated from the optical module 10. can be increased.

Referring to Figures 8 and 9, a plurality of pressing members 221 may be formed on the plug cover 22. The pressing members 221 formed on the plug cover 22 may press different parts of the optical transmission cable 100. The pressing members 221 may be arranged to be spaced apart from each other on the plug body 21. Accordingly, compared to the case where the optical connector 1 according to the present invention has only one pressing member 221, the optical transmission cable 100 has a coupling force between the plug body 21 and the plug cover 22. By being implemented to be further increased, the ability to prevent the optical transmission cable 100 from being easily separated from the optical module 10 can be increased.

The pressing member 221 may be formed at a position corresponding to the first support groove 211a. The pressing member 221 and the first support groove 211a may be formed to have the same length based on the first axis direction (X-axis direction). By combining the plug cover 22 with the plug body 21, the pressing member 221 can be inserted into the first support groove 211a. Accordingly, the optical connector 1 according to the present invention not only limits the distance that can be moved in the first axis direction (X-axis direction) of the optical transmission cable 100 through the first support groove 211a, The coupling force between the optical transmission cable 100, the plug body 21, and the plug cover 22 can be increased. Therefore, the optical connector 1 according to the present invention can increase the prevention force of preventing the optical transmission cable 100 from being easily separated from the optical module 10.

Additionally, the pressing member 221 may be formed at a position corresponding to the second support groove 212a. By combining the plug cover 22 with the plug body 21, the pressing member 221 can be inserted into the second support groove 212a. Accordingly, the optical connector 1 according to the present invention not only limits the distance that can be moved in the first axis direction (X-axis direction) of the optical transmission cable 100 through the second support groove 212a, The coupling force between the optical transmission cable 100, the plug body 21, and the plug cover 22 can be increased. Therefore, the optical connector 1 according to the present invention can increase the prevention force of preventing the optical transmission cable 100 from being easily separated from the optical module 10.

In the optical connector 1 according to the present invention, different parts of the optical transmission cable 100 are inserted through the first support groove 211a and the second support groove 212a, so that the optical connector 1 is connected to the first axis direction (X axis). In addition to doubly limiting the distance that can be moved in either direction, the optical transmission cable 100 may be implemented so that the coupling force between the plug body 21 and the plug cover 22 is further increased. Accordingly, the optical connector 1 according to the present invention can be further strengthened in preventing the optical transmission cable 100 from being easily separated from the optical module 10.

Referring to FIG. 10, the plug assembly 2 may include a coupling groove 214 formed in the plug body 21. In this case, a coupling protrusion 11a inserted into the coupling groove 214 may be formed on the sub-board 11. By inserting the coupling protrusion 11a into the coupling groove 214, the sub-board 11 can be fixed to the plug body 21. To this end, the length 214L of the coupling groove 214 may be formed to be equal to the length 11aL of the coupling protrusion 11a based on the second axis direction (Y-axis direction). Accordingly, the optical connector 1 according to the present invention is implemented so that the sub-board 11 is fixed to the plug body 21, thereby preventing the optical transmission cable 100 from being easily separated from the optical module 10. Prevention capabilities can be further strengthened.

The length 214L of the coupling groove 214 may be formed to be longer than the length 11aL of the coupling protrusion 11a. Accordingly, the optical connector 1 according to the present invention is implemented so that the coupling groove 214 and the sub-board 11 have a tolerance while limiting the distance at which the sub-board 11 can move, thereby enabling assembly. The ease of use can be improved. Therefore, the optical connector 1 according to the present invention can improve the ease of processing the coupling groove 214 and the sub-board 11.

Referring to FIG. 11, an optical connector according to an embodiment of the present invention may include a receptacle assembly 3.

The receptacle assembly (3) is coupled to the plug assembly (2). The receptacle assembly (3) is for electrical connection with the plug assembly (2). The receptacle assembly 3 may be formed as a whole into a rectangular parallelepiped, but is not limited thereto, and may be formed in another shape such as a cylindrical shape as long as it can be coupled to the plug assembly 2. In this way, the optical connector 1 according to the present invention can be implemented as a separate configuration of the receptacle assembly 3 and the plug assembly 2.

Referring to FIGS. 11 and 12 , the receptacle assembly 3 may include a receptacle body 31.

The receptacle body 31 may form the overall shape of the receptacle assembly 3. The receptacle body 31 may be combined with the plug body 21. The receptacle body 31 may be formed in a shape corresponding to the plug body 21. For example, the receptacle body 31 may be formed as a whole in a rectangular parallelepiped shape, but is not limited thereto and may be formed in another shape such as a cylindrical shape as long as it can be combined with the plug assembly 2.

Referring to FIGS. 11 to 13, in the optical connector according to an embodiment of the present invention, the receptacle assembly 3 and the plug assembly 2 may be coupled by a soft locking method. To this end, the plug assembly 2 and the receptacle assembly 3 may include the following configuration.

First, the receptacle assembly 3 may include a locking member 32 and a locking protrusion 33.

The locking member 32 may be coupled to the receptacle body 31. The locking member 32 may be elastically and movably coupled to the receptacle body 31. The locking member 32 may be movably coupled to the receptacle body 31 in the third axis direction (Z-axis direction). The third axis direction (Z-axis direction) refers to a direction perpendicular to each of the first axis direction (X-axis direction) and the second axis direction (Y-axis direction). The locking member 32 may be in contact with the plug body 21 when the receptacle assembly 3 and the plug assembly 2 are coupled.

The locking protrusion 33 may be coupled to the locking member 32. The locking protrusion 33 may protrude from the locking member 32. For example, the locking protrusion 33 may be formed in such a way that its size decreases as it protrudes in the downward direction (direction of arrow DD, shown in FIG. 13). The stopping protrusion 33 may be formed to have a sharp tip pointing downward (in the direction of arrow DD). The stopping protrusion 33 may be formed to protrude in the downward direction (direction of arrow DD) through a bending process.

Next, the plug assembly 2 may include a locking groove 215.

The locking groove 215 may be formed in the plug body 21. The locking protrusion 33 may be inserted into the locking groove 215. When the locking protrusion 33 is inserted into the locking groove 215, the plug body 21 can support the locking protrusion 33. In Figure 11, the locking groove 215 is shown in the shape of a rectangular parallelepiped, but it is not limited to this and can be formed in other shapes, such as a cylindrical shape, as long as the locking protrusion 33 can be inserted.

Accordingly, the optical connector 1 according to the present invention can be implemented to facilitate coupling between the receptacle assembly 3 and the plug assembly 2 using the locking protrusion 33 and the locking groove 215. there is.

Looking specifically at the process of coupling the plug assembly 2 and the receptacle assembly 3 by soft locking, the process is as follows.

First, as shown in FIG. 11, when the plug assembly 2 and the receptacle assembly 3 are separated, the plug assembly 2 can move in the insertion direction (ID arrow direction). The insertion direction (ID arrow direction) is from the rear side of the plug body 21 to the front side of the plug body 21. The insertion direction (ID arrow direction) may be the same as the inner direction (ND arrow direction) of FIG. 3. When the plug assembly 2 is inserted into the receptacle assembly 3, the stopping protrusion 33 may be supported on the plug body 21, as shown in FIG. 13. At this time, the locking member 32 can elastically move in the upward direction (UD arrow direction, shown in FIG. 13) of the plug body 21. When the plug assembly 2 is further moved in the insertion direction (ID arrow direction) into the receptacle assembly 3, the locking protrusion 33 may be inserted into the locking groove 215. At this time, the locking member 32 can move in the downward direction (direction of arrow DD, shown in FIG. 13) of the plug body 21 by restoring force due to elastic force. Accordingly, the plug assembly 2 and the receptacle assembly 3 can be coupled to each other.

Next, as shown in FIG. 12, when the plug assembly 2 and the receptacle assembly 3 are coupled, the plug assembly 2 can move in the separation direction (SD arrow direction). The separation direction (SD arrow direction) is opposite to the insertion direction (ID arrow direction). The separation direction (SD arrow direction) may be the same direction as the outer direction (OD arrow direction) of FIG. 3. The locking protrusion 33 can be moved upward (in the direction of arrow UD) so that the plug assembly 2 can be separated from the receptacle assembly 3. As the locking protrusion 33 moves in the upward direction (UD arrow direction), the locking protrusion 33 may be released from the locking groove 215. When the insertion of the locking protrusion 33 from the locking groove 215 is released, the locking protrusion 33 is supported on the plug body 21 as shown in FIG. 13, so the locking member 32 is It can move elastically in the upward direction (UD arrow direction, shown in FIG. 13). When the plug assembly (2) is completely separated from the receptacle assembly (3), the locking member (32) returns to the position before the plug assembly (2) and the receptacle assembly (3) were coupled by restoring force due to elastic force. You can come back.

Accordingly, the optical connector 1 according to the present invention can be implemented so that the plug assembly 2 and the receptacle assembly 3 can be coupled to each other using the soft locking method described above. Therefore, the optical connector 1 according to the present invention can implement the plug assembly 2 and the receptacle assembly 3 as separate configurations, and can easily connect the plug assembly 2 and the receptacle assembly 3. There are advantages to combining them.

In the above description, the plug assembly 2 moves in the insertion direction (ID arrow direction) or the separation direction (SD arrow direction), but the scope is not limited thereto and the receptacle assembly 3 moves or the plug The assembly 2 and the receptacle assembly 3 may move simultaneously.

Referring to Figures 14 and 15, in the optical connector according to an embodiment of the present invention, the receptacle assembly 3 and the plug assembly 2 may be coupled by a hard locking method. To this end, the plug assembly 2 and the receptacle assembly 3 may include the following configuration.

First, the receptacle assembly 3 may include an insertion groove 311.

The insertion groove 311 may be formed in the receptacle body 31. The insertion groove 311 may be formed to penetrate the receptacle body 31. The plug assembly 2 may be coupled to the insertion groove 311. The insertion groove 311 may be formed as a whole in a rectangular parallelepiped shape, but is not limited to this, and may be formed in another shape such as a cylindrical shape as long as the plug assembly 2 can be coupled thereto.

Next, the plug assembly 2 may include an insertion portion 23.

The insertion portion 23 may be coupled to the plug body 21. The insertion portion 23 may be inserted into the insertion groove 311. By inserting the insertion portion 23 into the insertion groove 311, the receptacle body 31 can support the insertion portion 23. The insertion portion 23 may be coupled to the plug body 21 to be movable between an insertion position (IP) inserted into the insertion groove 311 and a spaced position (SP) spaced apart from the insertion groove 311. there is. The insertion portion 23 can elastically move between the insertion position (IP) and the separation position (SP).

Referring to FIG. 16, the insertion part 23 may include an insertion member 231, a fixing member 232, and a connecting member 233.

The insertion member 231 may be inserted into the insertion groove 311. The insertion member 231 can couple the plug assembly 2 and the receptacle assembly 3 while being inserted into the insertion groove 311. The insertion member 231 may protrude to the outside of the plug body 21 to be inserted into the insertion groove 311. The insertion member 231 may be elastically movable between the insertion position (IP) and the separation position (SP). In Figure 16, the solid line indicates the insertion position (IP), and the dotted line indicates the separation position (SP).

Referring to FIG. 17, a first insertion surface 2311 and a second insertion surface 2312 may be formed in the insertion member 231.

The first insertion surface 2311 may be inserted into the insertion groove 311. The first insertion surface 2311 may be inserted into the insertion groove 311 to limit the distance that the insertion member 231 can move in the second axis direction (Y-axis direction).

The second insertion surface 2312 may be combined with the first insertion surface 2311. The second insertion surface 2312 may be formed in the insertion member 231 to be arranged parallel to the receptacle body 31 based on the second axis direction (Y-axis direction). The second insertion surface 2312 may limit the distance that the insertion member 231 can move in the first axis direction (X-axis direction).

The second insertion surface 2312 and the first insertion surface 2311 may be formed in the insertion member 231 to form an acute angle with each other. Accordingly, in the optical connector 1 according to the present invention, the plug assembly 2 and the receptacle assembly 3 can be firmly coupled to each other. Looking at this in detail, it is as follows.

First, as shown in FIG. 18, in the case of the comparative example in which the first insertion surface 2311 and the second insertion surface 2312 form an obtuse angle with each other, the insertion member 231 is attached to the insertion portion 23. Even in the inserted state, if the plug assembly 2 moves in the separation direction (SD arrow direction), the insertion portion 23 may be released along the first insertion surface 2311. Therefore, there is a risk that the plug assembly 2 and the receptacle assembly 3 may be separated and electric signals may not be transmitted between them.

Next, as shown in FIG. 17, when the first insertion surface 2311 and the second insertion surface 2312 form an acute angle with each other, the plug assembly 2 is moved in the separation direction (SD arrow direction). Even if it moves, the insertion part 23 may remain inserted into the insertion groove 311 and its movement may be restricted. Accordingly, the optical connector 1 according to the present invention is implemented so that the first insertion surface 2311 and the second insertion surface 2312 form an acute angle with each other, so that the plug assembly 2 and the receptacle assembly 3 ) can be firmly combined with each other. Therefore, the optical connector according to the present invention can improve the stability of electric signal transmission between the plug assembly (2) and the receptacle assembly (3).

Even when the first insertion surface 2311 and the second insertion surface 2312 are perpendicular to each other, the insertion part 23 moves while being inserted into the insertion groove 311. This may be limited. Therefore, the optical connector 1 according to the present invention is implemented so that the first insertion surface 2311 and the second insertion surface 2312 form a right angle to each other, thereby limiting the movement of the insertion portion 23. .

The fixing member 232 may be coupled to the plug body 21. The fixing member 232 may support the insertion portion 23 when the insertion member 231 moves between the insertion position (IP) and the separation position (SP). The insertion part 23 can move between the insertion position IP and the separation position SP based on the fixing member 232. The fixing member 232 may be inserted into the plug body 21 to support the insertion portion 23.

The connecting member 233 may be coupled to each of the insertion member 231 and the fixing member 232. The connecting member 233 is connected to the insertion member 231 so that the insertion member 231 elastically moves between the insertion position (IP) and the separation position (SP) based on the fixing member 232. It may be coupled to each of the fixing members 232. When the connecting member 233 is pressed, the insertion member 231 coupled to the connecting member 233 may be positioned at the spaced position SP. When the pressure on the connecting member 233 is released, the insertion member 231 coupled to the connecting member 233 may be positioned at the insertion position IP.

Referring to FIG. 19, the plug body 21 is coupled so that the insertion portion 23 moves elastically to the spaced position SP and moves to the insertion position IP with a restoring force due to elastic force. It may include member 216.

The insertion portion 23 may be coupled to the coupling member 216. The coupling member 216 may be formed on the plug body 21.

The coupling member 216 may include a fixing surface 2161 and a spaced groove 2162.

The fixing surface 2161 may be formed on the plug body 21. The fixing surface 2161 may support the fixing member 232. The fixing surface 2161 may support the fixing member 232 so that the connecting member 233 moves elastically between the insertion position IP and the separation position SP. The fixing surface 2161 may limit the distance that the connecting member 233 can move so as not to exceed the elastic force of the connecting member 233.

The spacing groove 2162 can accommodate the connecting member 233 moving to the spacing position (SP). The spacing groove 2162 may provide a space for the connecting member 233 to move to the spacing position SP. The spacing groove 2162 may be formed in the plug body 21. The spacing groove 2162 may be formed between the fixing surface 2161 and the insertion portion 23.

Looking at the process in which the plug assembly 2 and the receptacle assembly 3 are coupled by hard locking, the process is as follows.

First, as shown in FIG. 14, when the plug assembly 2 and the receptacle assembly 3 are separated, the plug assembly 2 can move in the insertion direction (ID arrow direction). When the plug assembly 2 is inserted into the receptacle assembly 3, the connecting member 233 can be moved to the spaced position SP so that the insertion member 231 is inserted into the insertion groove 311. there is. When the plug assembly 2 moves further in the insertion direction (ID arrow direction) into the receptacle assembly 3, the connecting member 233 moves to the insertion position IP due to a restoring force due to the elastic force. The insertion member 231 is inserted into the insertion groove 311. The connecting member 233 may be accommodated in the spacing groove 2162 to move between the insertion position (IP) and the spacing position (SP). At this time, the fixing surface 2161 may limit the distance that the connecting member 233 can move to the separation position (SP) in order to prevent it from exceeding the elastic force. Accordingly, the insertion part 23 is inserted into the insertion groove 311, and the receptacle body 31 supports the insertion part 23. In this way, the plug body 21 and the receptacle assembly 3 can be coupled to each other.

Next, as shown in FIG. 15, when the plug assembly 2 and the receptacle assembly 3 are coupled, the plug assembly 2 can move in the separation direction (SD arrow direction). The insertion portion 23 may be pressed so that the plug assembly 2 can be separated from the receptacle assembly 3. As the insertion portion 23 is pressed, the connecting member 233 moves to the spaced position SP, and the insertion member 231 can be released from the insertion groove 311. When the plug body 21 is completely separated from the receptacle body 31, the connecting member 233 is positioned at the insertion position IP due to a restoring force due to elastic force.

Accordingly, the optical connector 1 according to the present invention can be implemented so that the plug assembly 2 and the receptacle assembly 3 are coupled to each other using the hard locking method described above. Accordingly, the optical connector 1 according to the present invention can implement the plug assembly 2 and the receptacle assembly 3 as separate configurations, and unless the insertion portion 23 is pressed, the plug assembly 2 ) and the receptacle assembly 3 are implemented so that they are not separated from each other, so there is an advantage in that the plug assembly 2 and the receptacle assembly 3 can be firmly coupled.

In the above description, the plug assembly 2 moves in the insertion direction (ID arrow direction) or the separation direction (SD arrow direction), but the scope is not limited thereto and the receptacle assembly 3 moves or the plug The assembly 2 and the receptacle assembly 3 may move simultaneously.

Referring to FIG. 20, the plug assembly 2 may include an elastic portion 24.

The elastic portion 24 may be coupled to the plug body 21. The elastic part 24 can move the insertion part 23 to the spaced position SP. The elastic part 24 may press the insertion part 23 so that the insertion part 23 elastically moves to the spaced position SP. When the elastic part 24 presses the insertion part 23, the connecting member 233 moves in the first axis direction (X-axis direction). The elastic portion 24 may include an elastic lever 24a to press the connecting member 233. The operator can move the elastic portion 24 so that the elastic portion 24 presses the insertion portion 23 by pressing the elastic lever 24a. The elastic lever (24a) may be coupled to the plug body (21).

Referring to FIG. 21, the elastic portion 24 may include a first elastic arm 241, a second elastic arm 242, and a third elastic arm 243.

The first elastic arm 241 may be coupled to the plug body 21. One side of the first elastic arm 241 may be positioned higher than the other side based on the third axis direction (Z-axis direction). The third axis direction (Z-axis direction) refers to an axis direction perpendicular to each of the first axis direction (X-axis direction) and the second axis direction (Y-axis direction). For example, the first elastic arm 241 may be arranged parallel to the third axis direction (Z-axis direction).

The second elastic arm 242 may be coupled to each of the first elastic arm 241 and the third elastic arm 243. One side and the other side of the second elastic arm 242 may be located at the same height based on the third axis direction (Z-axis direction). For example, the second elastic arm 242 may be arranged parallel to the second axis direction (Y-axis direction).

The third elastic arm 243 may be coupled to the second elastic arm 242. One side of the third elastic arm 243 may be positioned higher than the other side based on the third axis direction (Z-axis direction). For example, the third elastic arm 243 may be arranged parallel to the third axis direction (Z-axis direction). The third elastic arm 243 may be connected to the elastic lever 24a. The third elastic arm 243 may move as the elastic lever 24a moves.

Here, the second elastic arm 242 may be arranged in a different direction from each of the first elastic arm 241 and the third elastic arm 243. For example, the first elastic arm and the third elastic arm may be arranged in a direction parallel to each other, and the second elastic arm may be arranged in a direction perpendicular to each of the first elastic arm and the third elastic arm. . Accordingly, the optical connector 1 according to the present invention can achieve the following effects.

First, the optical connector 1 according to the present invention uses the first elastic arm 241, the second elastic arm 242, and the third elastic arm 243 to form the entire elastic portion 24. It can be implemented to further increase the length. Therefore, the optical connector 1 according to the present invention can further increase the elastic force and restoring force of the elastic portion 24. Accordingly, the optical connector 1 according to the present invention can smoothly move the insertion portion 23 between the separation position (SP) and the insertion position (IP) using the elastic portion 24, Hard locking performance can be improved.

Second, the optical connector 1 according to the present invention uses the first elastic arm 241, the second elastic arm 242, and the third elastic arm 243 to form the entire elastic portion 24. Although the length can be increased, the second elastic arm 242 is disposed in a different direction from each of the first elastic arm 241 and the third elastic arm 243, so that the second elastic arm 242 moves in the second axis direction (Y-axis direction). ) It is possible to reduce the length of the elastic portion 24 based on . Therefore, the optical connector 1 according to the present invention has the advantage that the elastic portion 24 can be implemented to have sufficient elastic force and can be miniaturized.

The first elastic arm 241, the second elastic arm 242, and the third elastic arm 243 may be formed integrally. In this case, the elastic portion 24 can be formed by bending a single plate. Accordingly, the optical connector 1 according to the present invention can increase the overall length of the elastic portion 24 and also facilitate the processing of the elastic portion 24.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and it is commonly known in the technical field to which the present invention pertains that various substitutions, modifications and changes can be made without departing from the technical spirit of the present invention. It will be clear to those who have the knowledge of.

1: Optical connector 2: Plug assembly
3: Receptacle assembly 21: Plug body
22: plug cover 23: insertion part
24: elastic portion 31: receptacle body
32: Locking member 33: Locking protrusion
10: optical module 11: sub-board
100: Optical transmission cable

Claims (18)

An optical module (10) connected to an optical transmission cable;
A sub-board 11 to which the optical module 10 is coupled; and
It includes a plug assembly (2) to which the sub-board (11) is coupled,
The plug assembly 2 includes a plug body 21 that accommodates the optical module 10 and the sub-board 11,
The plug body 21 includes a first support groove 211a into which an optical transmission cable is inserted so that the optical transmission cable is connected to each of the optical module 10 and an external device disposed outside the plug assembly 2, and the first support groove 211a. It includes a first support member 211 in which one support groove 211a is formed,
The first support member 211 supports the optical transmission cable so that the movable distance of the optical transmission cable inserted into the first support groove 211a is limited,
The first support groove 211a is formed in a smaller size than the optical transmission cable,
An optical connector, characterized in that an optical transmission cable is compressed and inserted into the first support groove (211a). According to paragraph 1,
The plug body 21 has a second support member 212 spaced apart from the first support member 211, and is disposed between the first support member 211 and the second support member 212. It includes a receiving groove 213,
The receiving groove 213 accommodates a knot provided in the optical transmission cable,
The first support member 211 supports the knot accommodated in the receiving groove 213 to limit the movable distance of the optical transmission cable in an outward direction toward the outside of the plug assembly 2,
The second support member (212) is an optical connector characterized in that it supports the knot received in the receiving groove (213) so that the movable distance of the optical transmission cable is limited in the inner direction opposite to the outer direction. According to paragraph 1,
The plug body 21 includes a second support member 212 spaced apart from the first support member 211, and a second support groove 212a formed in the second support member 212,
The second support member 212 supports the optical transmission cable so that the movable distance of the optical transmission cable inserted into the second support groove 212a is limited,
An optical connector, characterized in that different parts of an optical transmission cable are inserted into each of the second support groove (212a) and the first support groove (211a). delete According to paragraph 1,
The plug assembly (2) includes a plug cover (22) coupled to the plug body (21),
A pressing member 221 protruding toward the plug body 21 is formed on the plug cover 22,
The pressing member (221) is an optical connector characterized in that it presses the optical transmission cable toward the plug body (21). According to clause 5,
The pressing member 221 includes a pressing surface 221a that contacts the optical transmission cable,
The optical connector is characterized in that the pressure surface (221a) is formed to form a curved surface. According to clause 5,
The optical connector is characterized in that the pressing member (221) is formed at a position corresponding to the first support groove (211a). According to clause 5,
The plug body 21 includes a second support member 212 spaced apart from the first support member 211, and a second support groove 212a formed in the second support member 212,
The optical connector is characterized in that the pressing member (221) is formed at a position corresponding to the second support groove (212a). According to clause 5,
A plurality of pressing members 221 are formed on the plug cover 22,
The optical connector is characterized in that the pressing members 221 are arranged to be spaced apart from each other to press different parts of the optical transmission cable. According to paragraph 1,
The plug assembly (2) includes a coupling groove (214) formed in the plug body (21),
A coupling protrusion 11a into which the coupling groove 214 is inserted is formed on the sub-board 11,
The optical connector is characterized in that the coupling protrusion (11a) is inserted into the coupling groove (214) so that the sub-board (11) is fixed to the plug body (21). According to paragraph 1,
It further includes a receptacle assembly (3) to which the plug assembly (2) is coupled,
The plug assembly (2) includes a locking groove (215) formed in the plug body (21),
The receptacle assembly 3 includes a receptacle body 31 coupled to the plug body 21, a locking member 32 elastically movably coupled to the receptacle body 31, and the locking member 32. It includes a locking protrusion (33) protruding from,
The locking member 32 moves downward when the locking protrusion 33 is inserted into the locking groove 215 and moves upward when the locking protrusion 33 is supported on the plug body 21. An optical connector characterized in that it is coupled to the receptacle body (31). According to paragraph 1,
It further includes a receptacle assembly (3) to which the plug assembly (2) is coupled,
The plug assembly (2) includes an insertion portion (23) coupled to the plug body (21),
The receptacle assembly 3 includes an insertion groove 311 into which the insertion portion 23 is inserted,
The insertion portion 23 is coupled to the plug body 21 so as to be movable between an insertion position (IP) inserted into the insertion groove 311 and a spaced position (SP) spaced apart from the insertion groove 311. Featured optical connector. According to clause 12,
The insertion portion 23 includes an insertion member 231 to be inserted into the insertion groove 311, a fixing member 232 coupled to the plug body 21, and the fixing member 232 as the reference. A connection member 233 coupled to each of the insertion member 231 and the fixing member 232 so that the insertion member 231 moves elastically between the insertion position (IP) and the separation position (SP). An optical connector characterized in that. According to clause 12,
The insertion portion 23 includes an insertion member 231 to be inserted into the insertion groove 311,
The insertion member 231 is formed with a first insertion surface 2311 inserted into the insertion groove 311, and a second insertion surface 2312 coupled to the first insertion surface 2311,
An optical connector, wherein the first insertion surface 2311 and the second insertion surface 2312 form an acute angle with each other. According to clause 12,
The insertion portion 23 includes an insertion member 231 to be inserted into the insertion groove 311,
The insertion member 231 is formed with a first insertion surface 2311 inserted into the insertion groove 311, and a second insertion surface 2312 coupled to the first insertion surface 2311,
An optical connector, wherein the first insertion surface 2311 and the second insertion surface 2312 form a right angle to each other. According to clause 13,
The plug body 21 includes a coupling member 216 to which the insertion portion 23 is coupled,
The coupling member 216 includes a fixing surface 2161 that supports the fixing member 232 so that the connecting member 233 moves elastically between the insertion position (IP) and the separation position (SP), and the An optical connector comprising a spaced groove (2162) for accommodating the connecting member (233) moving to the spaced position (SP). According to clause 13,
The plug assembly (2) includes an elastic portion (24) that presses the insertion portion (23) so that the insertion portion (23) moves to the spaced position (SP),
The elastic portion 24 includes a first elastic arm 241 coupled to the plug body 21, a second elastic arm 242 coupled to the first elastic arm 241, and the second elastic arm ( It includes a third elastic arm (243) coupled to 242),
The second elastic arm (242) is an optical connector, characterized in that it is arranged in a different direction from each of the first elastic arm (241) and the third elastic arm (243). According to clause 17,
The first elastic arm 241 and the third elastic arm 243 are arranged in parallel directions,
The second elastic arm (242) is an optical connector characterized in that it is arranged in a direction perpendicular to each of the first elastic arm (241) and the third elastic arm (243).

Images