KR100966109B1 - composite electro-optical connector module - Google Patents

Abstract

[summary]

The present invention provides a plurality of sockets 110 having a through-hole 111 in the longitudinal direction; A plug 112 mounted to the through hole 111 so as to protrude from the tip of the socket 110; A tube 113 inserted into an outer diameter of the plug 112; A first body 120 having a plurality of through holes 121 formed in a longitudinal direction such that the socket 110 is retracted; A cover 122 installed to be in contact with a rear end of the first body 120 but having a plurality of through holes 122a formed at one side thereof so that the rear end of the socket 110 passes; An insulator (130) installed to be in contact with the front end of the first body (120) but having a plurality of through holes (131) formed in a longitudinal direction such that the tube (113) is introduced; The through-hole 141 is provided in the longitudinal direction so that the first body 120 and the insulator 130 are introduced, and the step 140 is provided at the intermediate outer diameter, and the clip 140 having the spiral portion 142 formed at the rear outer diameter thereof. ; Cap 150 is provided with a through hole 151 in the longitudinal direction so that the rear end of the clip 140 is introduced, and the spiral portion 152 is spirally coupled to the spiral portion 142 at the front end of the through hole 151 and ; A coupling 160 having a through hole 161 in the longitudinal direction such that the tip of the clip 140 is inserted therein, and spiral portions 162 and 163 formed on both sides of the outer diameter; A fastener 170 provided with a locking jaw 171 formed at an inner diameter of the spiral portion 172 which is spirally coupled to the spiral portion 163, and a rear end thereof to be in contact with the step 143; A second body 184 mounted inside the through hole 161 and provided with a plurality of through holes 183 in the longitudinal direction; A plurality of sockets 180 inserted into a tip of the through hole 183 but having a through hole 181 in a longitudinal direction; A plug 182 mounted to the through hole 181 and protruding from the tip of the socket 180 to be inserted into the inner diameter of the tube 113; A cover 185 installed to be in contact with a rear end of the second body 184, and having a plurality of through holes 185a formed at one side thereof so as to pass through the rear end of the socket 180; The through hole 191 is provided in the longitudinal direction so that one end of the coupling 160 is inserted therein, and a cap having a spiral portion 192 spirally coupled to the spiral portion 162 at the tip of the through hole 191 ( In order to provide a hybrid photoelectric connector module comprising a 190), the present invention, firstly, it is possible to simultaneously transmit an electrical signal and power as well as an optical signal, so there is no need to have a separate connector as in the prior art economical benefits Secondly, it is effective to create a wide range of applications, and secondly, it can be widely applied to industries such as automobiles, aviation, robots, military, etc., thereby maximizing utilization efficiency and utilization range.

Hybrid, Photoelectric Connectors, Optical Signals, Power, Transmission, Cables, Modules

Description

Composite photoelectric connector module

The present invention relates to a hybrid photoelectric connector module, and more particularly, to a hybrid photoelectric connector module that can transmit an optical signal and power at the same time.

In general, optical connectors are optical communication components for connecting optical fibers to each other. In particular, optical connectors can transmit information safely without being influenced by the external environment, and can accurately guide the designation location while minimizing the loss of transmitted information. It is widely used in the mining industry.

Recently, due to the rapid development of informatization, the frequency of utilization of power as well as optical communication is increasing in ships, military, aviation, automobiles, robots, etc. In contrast, conventional optical connectors simply transmit optical signals by connecting a single core. Since it is not possible to supply the power required for the operation of the equipment at the same time, this is a practically impossible to apply to the industrial field that requires a variety of functions has a problem that the use efficiency and the scope of use is extremely limited.

Moreover, in the related art, connectors for transmitting optical signals and power must be used separately, thereby increasing the economic burden and limiting the usage, which is difficult to systematically manage with maintenance.

The present invention has been invented to solve the above-mentioned conventional problems, and an object thereof is to provide a hybrid photoelectric connector module capable of simultaneously transmitting an optical signal and power.

The present invention provides a plurality of sockets 110 having a through-hole 111 in the longitudinal direction; A plug 112 mounted to the through hole 111 so as to protrude from the tip of the socket 111; A tube 113 inserted into an outer diameter of the plug 112; A first body 120 having a plurality of through holes 121 formed in a longitudinal direction such that the socket 110 is retracted; A cover 122 installed to be in contact with a rear end of the first body 120 but having a plurality of through holes 122a formed at one side thereof so that the rear end of the socket 110 passes; An insulator (130) installed to be in contact with the front end of the first body (120) but having a plurality of through holes (131) formed in a longitudinal direction such that the tube (113) is introduced; The through-hole 141 is provided in the longitudinal direction so that the first body 120 and the insulator 130 are introduced, and the step 140 is provided at the intermediate outer diameter, and the clip 140 having the spiral portion 142 formed at the rear outer diameter thereof. ; Cap 150 is provided with a through hole 151 in the longitudinal direction so that the rear end of the clip 140 is introduced, and the spiral portion 152 is spirally coupled to the spiral portion 142 at the front end of the through hole 151 and ; A coupling 160 having a through hole 161 in the longitudinal direction such that the tip of the clip 140 is inserted therein, and spiral portions 162 and 163 formed on both sides of the outer diameter; A fastener 170 provided with a locking jaw 171 formed at an inner diameter of the spiral portion 172 which is spirally coupled to the spiral portion 163, and a rear end thereof to be in contact with the step 143; A second body 184 mounted inside the through hole 161 and provided with a plurality of through holes 183 in the longitudinal direction; A plurality of sockets 180 inserted into a tip of the through hole 183 but having a through hole 181 in a longitudinal direction; A plug 182 mounted to the through hole 181 and protruding from the tip of the socket 180 to be inserted into the inner diameter of the tube 113; A cover 185 installed to be in contact with a rear end of the second body 184, and having a plurality of through holes 185a formed at one side thereof so as to pass through the rear end of the socket 180; The through hole 191 is provided in the longitudinal direction so that one end of the coupling 160 is inserted therein, and a cap having a spiral portion 192 spirally coupled to the spiral portion 162 at the tip of the through hole 191 ( 190).

The present invention is the first, because it is possible to transmit not only an optical signal but also an electric signal and power at the same time, there is no need to have a connector separately as in the prior art, there is an effect that can create economic benefits, second, automobile, aviation, robot, By making it widely applicable to industrial fields such as military, there is an effect that can maximize the use efficiency as well as the range of use.

When described in more detail by the accompanying drawings the technical configuration for achieving the object of the present invention as described above are as follows.

1 is an exploded perspective view for showing the structure of the composite photoelectric connector module of the present invention, Figure 2 is a perspective view of the combination for showing the structure of the composite photoelectric connector module of the present invention, Figure 3 is a cross-sectional view taken along line AA of FIG. 4 is a reference diagram for illustrating an installation state of the composite photoelectric connector module of the present invention.

At the rear ends of the sockets 110 and 180, the ends of the plugs 112 and 182 abut each other in the state in which the optical signal transmission line B and the power transmission line C are connected to each other, thereby transmitting the optical signal and power. For both the plugs 112 and 182, half of the plugs are made of optical fiber parules for transmitting optical signals, and the other half are made of copper wires for transmitting power.

In addition, the rear ends of the sockets 110 and 180 may be respectively inserted into the outer diameters of the sockets 110 and 180 to form springs 110a and 180a supported by contact with the covers 122 and 185, respectively. This is to ensure a buffering force capable of returning the sockets 110 and 180 at the same time as the sockets 110 and 180 move backwards when the ends collide with each other during the insertion of the plugs 112 and 182 into the inner diameter.

In this case, the ends of the sockets 110 and 180 extend in diameter so that one end of the springs 110a and 180a come into contact with each other, and the through holes 122a and 185a pass through the rear ends of the sockets 110 and 180 and the spring 110a passes through. The other end of (180a) was made to have a diameter that can be abutted.

On the other hand, the tube 113 serves to guide the position so that both plugs 112 and 182 are inserted therein so that the tip abuts each other.

In particular, the first body 120 and the second body 184 is firmly fixed to both sockets (110, 180), wherein the through holes (121, 183) are formed in accordance with the plurality of plugs (112, 182) range of use Of course.

The insulator 130 not only prevents safety accidents occurring in the process of supplying power in advance, but also aligns the positions of the plugs 112 and 182 to minimize the loss that may occur during the transmission of the optical signal.

At this time, the tube 113 and the insulator 130 are preferably made of rubber or synthetic resin material to prevent electrical short and corrosion.

In addition, the clip 140 is moved inside the coupling 160 in a state where the insulator 130 and the first body 120 are mounted therein so that the ends of the plugs 112 and 182 abut each other. Adjust the position so that

In this case, a locking groove 144 is formed in the longitudinal direction of the tip outer diameter of the clip 140, and a locking jaw 164 inserted into the locking groove 144 protrudes from the inner diameter of the tip of the coupling 160. This is because the locking groove 144 and the locking jaw 164 is fitted to each other, so that the clip 140 and the coupling 160 do not fall back, and the ends of the plugs 112 and 182 abut each other. To derive the correct position.

The caps 150 and 190 may fix the optical signal transmission line B and the power transmission line C so as to prevent shaking while being separated from the rear ends of the sockets 110 and 180.

On the other hand, when the operator rotates the fixture 170 in the state in which the coupling 160 and the fixture 170 is spirally coupled, the step 143 and the locking jaw 171 abut each other, thereby As the clip 140 and the coupling 160 move to the front end, the front ends of the plugs 112 and 182 abut each other.

At this time, the outer diameter of the fixture 170 and the cap (150, 190) was knurled (not shown) processing so that the operator can easily rotate.

Therefore, in the present invention, the hybrid photoelectric connector module 100 is fixed to the operator by the optical signal transmission line (B) and the power transmission line (C) connected to the rear ends of the sockets 110 and 180 as shown in FIG. When the 170 is rotated, the clip 140 in contact with the locking jaw 171 is moved, and at the same time, the ends of the plugs 112 and 182 are brought into contact with each other to be coupled to each other so that the optical signal transmission line B and the power transmission line are coupled. Through (C), power can be smoothly supplied with the optical signal.

As described above, the embodiment of the present invention has been described in detail, but the scope of the present invention is not limited thereto, and the scope of the present invention is included to the extent that the present invention is substantially equivalent to the embodiment of the present invention. Of course it will.

1-An exploded perspective view showing the structure of the present invention composite photoelectric connector module.

Fig. 2-A perspective view showing the structure of the present invention composite photoelectric connector module.

3-2 is a cross-sectional view taken along the line A-A.

4-Reference cross-sectional view for showing an installation state of the composite photoelectric connector module of the present invention.

Explanation of symbols on the main parts of the drawings

100: the present invention composite photoelectric connector module

110: socket 110a: spring

111: through

112: plug 113: tube

120: first body 121: through-hole

122: cover 122a: through hole

130: insulator 131: through hole

140: clip 141: through

142: spiral portion 143: step

144: hanging groove

150: cap 151: through

152: spiral

160: coupling 161: through hole

162, 163: spiral portion 164: locking jaw

170: fixture 171: locking jaw

172: spiral

180: socket 180a: spring

181: through

182: plug 183: through hole

184: second body 185: cover

185a: through

190: Cap 191: through hole

192: spiral

A: Cable B: Optical Signal Transmission Line

C: power transmission line

Claims (4)

A plurality of sockets 110 having a through hole 111 in a longitudinal direction; A plug 112 mounted to the through hole 111 so as to protrude from the tip of the socket 110; A tube 113 inserted into an outer diameter of the plug 112; A first body 120 having a plurality of through holes 121 formed in a longitudinal direction such that the socket 110 is retracted; A cover 122 installed to be in contact with a rear end of the first body 120 but having a plurality of through holes 122a formed at one side thereof so that the rear end of the socket 110 passes; An insulator (130) installed to be in contact with the front end of the first body (120) but having a plurality of through holes (131) formed in a longitudinal direction such that the tube (113) is introduced; The through-hole 141 is provided in the longitudinal direction so that the first body 120 and the insulator 130 are introduced, and the step 140 is provided at the intermediate outer diameter, and the clip 140 having the spiral portion 142 formed at the rear outer diameter thereof. ; Cap 150 is provided with a through hole 151 in the longitudinal direction so that the rear end of the clip 140 is introduced, and the spiral portion 152 is spirally coupled to the spiral portion 142 at the front end of the through hole 151 and ; A coupling 160 having a through hole 161 in the longitudinal direction such that the tip of the clip 140 is inserted therein, and spiral portions 162 and 163 formed on both sides of the outer diameter; A fastener 170 provided with a locking jaw 171 formed at an inner diameter of the spiral portion 172 which is spirally coupled to the spiral portion 163, and a rear end thereof to be in contact with the step 143; A second body 184 mounted inside the through hole 161 and provided with a plurality of through holes 183 in the longitudinal direction; A plurality of sockets 180 inserted into a tip of the through hole 183 but having a through hole 181 in a longitudinal direction; A plug 182 mounted to the through hole 181 and protruding from the tip of the socket 180 to be inserted into the inner diameter of the tube 113; A cover 185 installed to be in contact with a rear end of the second body 184, and having a plurality of through holes 185a formed at one side thereof so as to pass through the rear end of the socket 180; The through hole 191 is provided in the longitudinal direction so that one end of the coupling 160 is inserted therein, and a cap having a spiral portion 192 spirally coupled to the spiral portion 162 at the tip of the through hole 191 ( 190. A hybrid photoelectric connector module comprising: 190). 2. The hybrid photoelectric connector according to claim 1, wherein both of the plugs (112, 182) are made of optical fiber parules for transmitting optical signals, and the other half are made of copper wire for transmitting power. module. 2. The hybrid photoelectric connector according to claim 1, wherein the outer ends of the sockets 110 and 180 have springs 110a and 180a supported in contact with the covers 122 and 185 while being inserted in the longitudinal direction. module. The locking jaw of claim 1, wherein the locking groove 144 is formed in the longitudinal direction of the tip outer diameter of the clip 140, and the locking jaw is inserted into the locking groove 144 in the tip inner diameter of the coupling 160. Composite photoelectric connector module, characterized in that protruding (164).

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