KR101189820B1 - OPTICAL-PCBs CONNECTOR - Google Patents

Abstract

The present invention relates to an optical PCB embedded optical connector for making an optical connection between an optical PCC optical signal module and an optical waveguide stacked in the optical PCC.
The optical PCB embedded optical connector according to the present invention is capable of transmitting an optical signal and includes a plurality of first optical signal transmission cores arranged to extend in one direction, so that the first optical signal transmission core can receive an optical signal. A first block having a first coupling surface exposed at one end thereof, and a plurality of second optical signal transmission cores extending in a direction crossing the optical signal transmission cores of the first block; A second block having a second coupling surface in contact with the first coupling surface such that the optical signal transmission cores are interconnected to enable transmission of the optical signal; and the first and second optical signal transmission cores are mutually optical signals. Fixing means for fixing the first and second blocks to each other to maintain a close state to enable the transmission of.
The optical PCB embedded optical connector according to the present invention can transmit an optical signal between the optical signal module and the electronic components without loss on the optical PCB, and can be applied to a miniaturized electronic product by minimizing the volume required for installation. have.

Description

Fiber Optic Flush Optical Connector {OPTICAL-PCBs CONNECTOR}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical PCB buried optical connector, and more particularly, to an optical PCB buried optical connector for making an optical connection between an optical PCB optical signal module and an optical waveguide stacked in the optical PCB.

As integrated circuit (IC) technology is advanced and its operation speed and integration scale are improved, high performance of microprocessors and large capacity of memory chips are becoming very fast. As a result, next-generation information and communication systems consisting of large parallel computers or terabit-class asynchronous transmission mode switching systems that transmit large amounts of information at high speeds require more signal processing capabilities. Required.

However, the conventional device has a limitation in speeding up the signal and increasing the density of the wiring because the transfer of information between the board and the board or a relatively short distance such as the chip and the chip is mainly performed by the electrical signal, and the signal due to the wiring's own resistance Delay is becoming a problem. In addition, since the high speed of signal transmission and the high density of wiring act as a cause of noise generation due to electromagnetic interference, countermeasures are also required.

Recently, an optical waveguide capable of transmitting and receiving a signal with light using a polymer polymer and glass fiber as a means to solve this problem has been inserted into a PCB, which is called an electro-optical circuit board (EOCB). These optical backplanes are mixed with electrical signals and optical signals, and high-speed data communication is transmitted as optical signals in the same board, and in the device, copper plate circuit patterns can be converted to electrical signals for data storage / signal processing. It means the board | substrate which inserted the optical waveguide and the glass plate in the formed state.

In order to transmit and receive a signal through light, a connector using an optical fiber is installed between an optical signal module and a transmission body which transmits or transmits a signal from the optical signal module. In the related art, a signal transmission direction is changed or stepped. In the part, it was necessary to install a connection block to connect a separate optical fiber that refracts light or extends in a changed direction.

Therefore, when the refractive index is changed or the optical loss occurs in the connection portion, there was a problem that the optical signal is not transmitted normally.

The present invention has been made to solve the above problems, and the optical signal transmission between the optical signal module and the electronic components in the optical PC by enabling the optical signal transmission without optical loss even at the point where the direction of the optical waveguide is changed. It is an object of the present invention to provide an optical PCB buried optical connector that can be accurately made.

In order to achieve the above object, an optical PCB buried optical connector according to the present invention is capable of transmitting an optical signal and includes a plurality of first optical signal transmission cores arranged to extend in one direction, and the first optical signal transmission core is optical A first block having a first coupling surface exposed at one end thereof to receive a signal, and a plurality of second optical signal transmission cores extending in a direction crossing the optical signal transmission cores of the first block; A second block having a second coupling surface in contact with the first coupling surface such that the first and second optical signal transmission cores are interconnected to enable optical signal transmission; and the first and second optical signals It is provided with a fixing means for fixing the first and second blocks to each other so that the transfer core can maintain the state in close contact to enable the transmission of the optical signals to each other.

In the first block, two substrate fixing holes for fixing the first block to the substrate are formed to be spaced apart from each other by a predetermined distance, and the first optical signal transmission core is formed such that 12 are arranged in a line between the fixing holes. In addition, it is preferable to further include a matching gel coated on the contact portions of the first and second coupling surfaces to increase the transmission rate of the optical signal.

The fixing means includes a fixing protrusion inserted into a fastening hole formed in each of the first and second blocks, and the first and second coupling surfaces of the first and second blocks are in close contact with each other by connecting the fixing protrusions to each other. It may include a fixing plate to pull in the direction.

In addition, the fixing means includes first and second fixing pins protruding outward from the first and second blocks, respectively, and first and second through holes formed to penetrate the first and second fixing pins. It may be provided, the first and second fixing pins may be formed to include a traction member capable of elastic deformation to be pulled in a direction close to each other to maintain a close contact between the first and second coupling surface.

The optical PCB embedded optical connector according to the present invention can transmit an optical signal between the optical signal module and the electronic components without loss on the optical PCB, and can be applied to a miniaturized electronic product by minimizing the volume required for installation. have.

1 is a perspective view showing a first embodiment of an optical PC embedded buried optical connector according to the present invention;
Figure 2 is an exploded perspective view of the optical PCB buried optical connector of Figure 1,
3 is an exploded perspective view illustrating a board mounting state of the optical PCB embedded optical connector of FIG. 1;
4 is a cross-sectional view of FIG.
5 is a perspective view showing another embodiment of the fixing means,
Figure 6 is an exploded perspective view showing a second embodiment of the optical PCB buried optical connector according to the present invention,
7 is a cross-sectional view of FIG.
8 is an exploded perspective view showing a third embodiment of an optical PC embedded buried optical connector according to the present invention;
9 is a cross-sectional view of FIG. 8.

Hereinafter, an optical PC embedded embedded optical connector (hereinafter referred to as an “optical connector”) according to the present invention will be described in more detail with reference to the accompanying drawings.

1 to 4 show one embodiment of the optical connector 100 according to the present invention.

The optical connector 100 of the present embodiment includes first and second blocks 110 and 120 coupled to each other, and fixing means 140 for fixing the first and second blocks 110 and 120.

The first block 110 is installed vertically with respect to the mounting target substrate 10 and fixes the first optical signal transmission core 111 and the first block 110 to the mounting target substrate 10. A mounting hole 112 for fastening with the optical signal device 30 to receive or transmit the optical signal is formed. In addition, a first coupling surface 113 is formed at one side of the first block 110.

The first block 110 is formed so that the mounting hole 112 penetrates the upper and lower surfaces of the first block 110, and is compatible with the general substrate 10 and the optical signal elements 30. The distance between them is 4.6 cm. The separation distance of the mounting hole 112 may be variously formed according to the shape and the fixture of the substrate 10 and the device 30.

The first optical signal transmission cores 111 are arranged in a line between the mounting holes 112 and extend in a direction penetrating the upper and lower surfaces of the first block 110. A plurality of insertion holes are drilled in the first block 110 so that the first optical signal transmission core 111 can be inserted, and the first optical signal transmission core 111 is inserted into the insertion hole.

The first coupling surface 113 is formed at the bottom of the first block 110, the first block 110 is coupled to the second block 120 so that the left and right width gradually increases as it extends from the bottom to the top. The side surface is formed to be inclined, and the inclined surface becomes the first coupling surface 113.

A lower end of the first optical signal transmission core 111 is exposed on the first coupling surface 113, and the optical signal can be connected to the second optical signal transmission core 121 of the second block 120 to be described later. Polish the exposed cross section so that it can be connected. Preferably, the angle of the first engagement surface 113 is about 45 °.

The second block 120 is to be coupled to the first block 110, the second coupling surface 122 is formed to be coupled to the first coupling surface 113 on one side. One side of the second block 120 is formed to be inclined so that the upper and lower thicknesses become thicker as it extends from one end coupled to the first block 110 to the other end, and the inclined surface is the second coupling surface 122. do.

The inclination angles of the first and second coupling surfaces 113 and 122 may correspond to each other to maintain a state in which the first and second coupling surfaces 113 and 122 are in close contact with each other.

The second optical signal transmission cores 121 extend along the horizontal direction in the second block 120.

The second optical signal transmission core 121 is inserted into a plurality of insertion holes which are punctured along the horizontal direction in the second block 120, and one end exposed through the second coupling surface 122 is the first optical signal. It is polished to be connected to the signal transmission core 111.

When the first and second coupling surfaces 113 and 122 are in close contact with each other, the first and second optical signal transmission cores and the second optical signal transmission cores 121 are in close contact with each other, thereby enabling optical signal transmission. Since the extending directions of the second optical signal transmission cores 111 and 121 are orthogonal to each other, the optical signal is refracted at 90 ° at the connection portions of the first and second optical signal transmission cores 111 and 121 to transmit a signal.

Matching gel is applied between the contact portions of the first and second optical signal transmission cores 111 and 121 to minimize the loss of the optical signal.

The first and second optical signal transmission cores 111 and 121 may be inclined to correspond to the mating surfaces of the first and second blocks 110 and 120 so that the ends of the first and second optical signal transmission cores 111 and 121 are refracted in a direction orthogonal to each other so that transmission may be performed. Therefore, the height of the optical connector 100 can be minimized.

The second block 120 is connected to the optical signal waveguide member 20 having a plurality of optical fiber cores connected to the second optical signal transmission core 121, and the second block 120 is the optical signal waveguide member 20. The end portion may be formed to have various coupling structures for coupling with it.

The fixing means 140 is for fixing the first and second blocks 110 and 120 to each other.

As described above, since the optical signals are transmitted and refracted on the coupling portions of the first and second optical signal transmission cores 111 and 121 to which the optical signals are interconnected, the first and second optical signal transmission cores 111 and 121 should be easily maintained in close contact with each other. The transmission failure of the optical signal does not occur.

Therefore, the fixing means 140 fixes the first and second blocks 110 and 120 in close contact with each other.

The fixing means 140 of the present embodiment includes a first fixing part 141 and a second fixing part 146.

The first fixing part 141 is formed on the main support member 142 which is formed in a 'b' shape so as to contact the rear surface of the first block 110 and the lower surface of the second block 120, and both ends of the support member. The auxiliary support member 143 is formed to contact the side surfaces of the first and second blocks 110 and 120, and the first and second fixing protrusions 144 and 145 protruding from the auxiliary support member 143.

The first and second fastening holes 114 and 123 are formed in the side surfaces of the first block 110 and the second block 120, respectively, and the first and second fixing protrusions 144 and 145 are respectively formed. The first block 110 and the second block 120 are fixed to each other by being inserted into the first and second fastening holes 114 and 123.

The second fixing part 146 includes a fixing plate 147 formed in a 'b' shape so as to contact the front surface of the first block 110 and the upper surface of the second block 120, and the fixing plate 147. And third and fourth fixing protrusions 148 and 149.

Third and fourth fastening holes 115 and 124 are formed on the front surface of the first block 110 and the upper surface of the second block 120, respectively, and the third and fourth fixing protrusions 148 and 149 are formed in a third shape. As the fixing plate 147 is installed in the first and second blocks 110 and 120 to be inserted into the fourth fastening holes 115 and 124, the fixing state of the first and second blocks 110 and 120 is also fixed by the second fixing part 146. maintain.

In this case, the third fastening hole is formed to be inclined downward as it extends from the front to the rear of the first block 110, and the fourth fastening hole is toward the first block 110 as it extends from the top surface to the bottom surface of the third block. The first and second blocks 110 and 120 are separated when the second fixing part 146 is installed by forming the second fixing part 146 so as to be inclined, and the third and fourth fixing protrusions 148 and 149 fastened thereto are also inclined to correspond thereto. It is desirable to be able to receive force in the direction.

5 shows another embodiment of the fixing means 160.

The fixing means 160 of the present embodiment includes first and second fixing pins 161 and 162 which are formed to protrude outwards from each other on both sides of the first block 110 and the second block 120, and the The first and second fixing pins 161 and 162 may include a towing member 165 installed therethrough.

First and second through holes 166 and 167 are formed at both ends of the towing member 165 so that the first and second fixing pins 161 and 162 may be installed therethrough. The second through holes 166 and 167 are formed of a material that is elastically deformable so as to be elastically biased in a direction closer to each other.

The first and second fixing pins 161 and 162 may have a rod member 163 having a predetermined diameter extending from the first and second blocks 110 and 120, and may be relative to the rod member 163 at an end of the rod member 163. It includes a large diameter head member 164.

In addition, the first and second through holes 166 and 167 of the traction member 165 include an expansion hole 168 through which the head member 164 passes, and an expansion hole 168 on one side of the expansion hole 168. It is in communication with and has a reduction hole (169) having a diameter corresponding to the diameter of the rod member (163).

The reduction hole 169 is formed in the direction in which the first and second fixing pins 161 and 162 are towed by the towing member 165. When the towing member 165 is mounted, the reduction hole 169 is provided through the head member through the expansion hole 168. After the 164 is inserted, the rod member 163 is caught in the reduction hole 169 to maintain the traction state, and the traction member 165 is connected to the first and second fixing pins 161 and 162 by the head member 164. Do not deviate from the

In the connector according to the present invention, since the first and second optical signal transmission cores 111 and 121 extending in the orthogonal direction are connected to each other to enable transmission of optical signals, the overall height of the optical connector 100 can be minimized. It can maximize the utilization of small home appliances.

6 and 7 show another embodiment of the optical connector 100 according to the present invention.

The optical connector 100 of the present exemplary embodiment further includes a light refractive member 170 installed at a connection portion between the first block 110 and the second block 120.

Mounting grooves recessed inward in portions where the first and second optical signal transmission cores 111 and 121 are formed in the first and second coupling surfaces 113 and 122 of the first block 110 and the second block 120. 125 are formed, and the light refraction member 170 is installed in the mounting groove 125.

The optical refraction member 170 refracts the optical signal transmitted from the first optical signal transmission core 111 to be incident on the second optical signal transmission core 121, and the first and second optical signal transmission cores 111 and 121. The optical signal is refracted between the two beams to enable the transmission of the optical signal.

8 shows another embodiment of an optical connector 200.

The optical connector 200 of the present exemplary embodiment also includes first and second blocks 210 and 220, wherein the first coupling surface 211 formed in the first block 210 has an angle α with respect to the bottom surface installed on the substrate. Is formed to be 7 to 9 degrees.

Of course, the end portion of the optical signal transmission core 212 installed in the first block 210 is also polished in an inclined state together with the first coupling surface 211.

The second inclined surface 221 of the second block 220 has an angle β of 81 to 83 ° with respect to the side surface extending upward from the end of the first block 210 to be in close contact with the first coupling surface 211. ) And the second optical signal transmission core 222 provided therein is also polished so that the end thereof corresponds to the second coupling surface 221.

Thus, when the angle at the connecting portion where the first and second optical signal transmission cores 212 and 222 are connected to each other is 7 to 9 °, the loss of the optical signal is the least, especially the first block 210 installed on the substrate. By lowering the height of the inclined surface is 7 ~ 9 ° it is possible to lower the overall height of the optical connector 200.

Since the remaining components of the present embodiment are the same as the first embodiment, a detailed description thereof will be omitted.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100; Fiber Optic Flush Optical Connector
110; First block
111; A first optical signal transmission core 113; First engagement surface
120; Second block
121; A second optical signal transfer core 122; Second engagement surface
140; Fixing means
141; First fixing portion 146; Second fixing part
160; Fixing means
161,162; First and second fixing pins 165; Towing member
170; Photorefractive members

Claims (7)

delete delete The first optical signal transmission core has a plurality of first optical signal transmission cores arranged to extend and extend along one direction, and has a first coupling surface exposed at one end thereof so that the first optical signal transmission core can receive the optical signal. A first block;
And a plurality of second optical signal transmission cores extending in a direction crossing the optical signal transmission cores of the first block, wherein the first and second optical signal transmission cores are interconnected to enable optical signal transmission. A second block having a second engaging surface in contact with the first engaging surface;
And fixing means for fixing the first and second blocks to each other so that the first and second optical signal transmission cores may be in close contact with each other so as to transmit optical signals.
And a matching gel coated on the contact portions of the first and second coupling surfaces to increase the transmission rate of the optical signal. The first optical signal transmission core has a plurality of first optical signal transmission cores arranged to extend and extend along one direction, and has a first coupling surface exposed at one end thereof so that the first optical signal transmission core can receive the optical signal. A first block;
And a plurality of second optical signal transmission cores extending in a direction crossing the optical signal transmission cores of the first block, wherein the first and second optical signal transmission cores are interconnected to enable optical signal transmission. A second block having a second engaging surface in contact with the first engaging surface;
And fixing means for fixing the first and second blocks to each other so that the first and second optical signal transmission cores may be in close contact with each other so as to transmit optical signals.
The fixing means includes a fixing protrusion inserted into a fastening hole formed in each of the first and second blocks, and the first and second coupling surfaces of the first and second blocks are in close contact with each other by connecting the fixing protrusions to each other. The optical PCB embedded optical connector comprising a fixing plate towing in the direction. The first optical signal transmission core has a plurality of first optical signal transmission cores arranged to extend and extend along one direction, and has a first coupling surface exposed at one end thereof so that the first optical signal transmission core can receive the optical signal. A first block;
And a plurality of second optical signal transmission cores extending in a direction crossing the optical signal transmission cores of the first block, wherein the first and second optical signal transmission cores are interconnected to enable optical signal transmission. A second block having a second engaging surface in contact with the first engaging surface;
And fixing means for fixing the first and second blocks to each other so that the first and second optical signal transmission cores may be in close contact with each other so as to transmit optical signals.
The fixing means may include first and second fixing pins protruding outwardly from the first and second blocks, respectively;
First and second through holes formed to penetrate the first and second fixing pins are provided, and the first and second fixing pins are pulled in a direction in which the first and second fixing pins are closer to each other, and thus, between the first and second coupling surfaces. An optical PC-embedded optical connector, characterized in that it comprises a traction member capable of elastic deformation to maintain the close state of the contact. The first optical signal transmission core has a plurality of first optical signal transmission cores arranged to extend and extend along one direction, and has a first coupling surface exposed at one end thereof so that the first optical signal transmission core can receive the optical signal. A first block;
And a plurality of second optical signal transmission cores extending in a direction crossing the optical signal transmission cores of the first block, wherein the first and second optical signal transmission cores are interconnected to enable optical signal transmission. A second block having a second engaging surface in contact with the first engaging surface;
And fixing means for fixing the first and second blocks to each other so that the first and second optical signal transmission cores may be in close contact with each other so as to transmit optical signals.
Mounting grooves are formed in the first and second coupling surfaces of the first and second blocks to expose the first and second optical signal transmission cores.
And an optical refraction member which is mounted in the mounting groove and further includes an optical refraction member that refracts the optical signal when the optical signal is transmitted between the first and second optical signal transmission cores to facilitate signal transmission. Optical connector. The first optical signal transmission core has a plurality of first optical signal transmission cores arranged to extend and extend along one direction, and has a first coupling surface exposed at one end thereof so that the first optical signal transmission core can receive the optical signal. A first block;
And a plurality of second optical signal transmission cores extending in a direction crossing the optical signal transmission cores of the first block, wherein the first and second optical signal transmission cores are interconnected to enable optical signal transmission. A second block having a second engaging surface in contact with the first engaging surface;
And fixing means for fixing the first and second blocks to each other so that the first and second optical signal transmission cores may be in close contact with each other so as to transmit optical signals.
The first coupling surface extends inclined at 7 to 9 ° with respect to the bottom surface of the first block, the second block extends upwardly so that the second coupling surface can be coupled to the first coupling surface An optical PC-embedded optical connector, which extends at an angle of 81 to 83 ° with respect to the side surface.

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