KR101844298B1 - Multi-channel transmission and receiving module - Google Patents

Abstract

The present invention relates to a multi-channel transmitting and receiving module. The module comprises: an induction part changing an optical signal direction, wherein a plurality of optical line parts embedded in a cable part are individually inserted; a transmission part transmitting or receiving an optical signal transmitted through the induction part; and a main board part connected to the transmission part and a connector and having a circuit for transmitting an image signal. Accordingly, the module can improve assemblability and productivity.

Description

[0001] MULTI-CHANNEL TRANSMISSION AND RECEIVING MODULE [0002]

The present invention relates to a multichannel transmission / reception module, and more particularly, to a multichannel transmission / reception module that improves assemblability and productivity, and can selectively replace damaged parts to reduce maintenance costs.

In general, a fiber-based signal transmission method widely used for long-distance communication is widely used for high-capacity digital meteor transmission including a high-definition digital video display device requiring high-speed and high-density data transmission due to advantages such as broadband and electromagnetic interference- .

However, in the conventional optical fiber-based signal transmission system, all the chips that can be driven are mounted on a single printed circuit board, so that it is difficult to align them simultaneously. In particular, when all the driving elements are mounted on a single printed circuit board, it is difficult to evaluate the reliability of individual optical signals. Therefore, there is a need to improve this.

BACKGROUND ART [0002] The background art of the present invention is disclosed in Korean Patent Laid-Open Publication No. 2015-0023199 (titled "HDMI cable with optical fiber unit", published on May 05, 2015).

It is an object of the present invention to provide a multichannel transmission / reception module that improves the assemblability and productivity and selectively uses damaged parts to reduce maintenance costs.

The multi-channel transceiver module according to the present invention includes: an induction unit in which a plurality of optical line units embedded in a cable unit are individually inserted and the optical signal direction is changed; A transmitter for transmitting or receiving an optical signal transmitted through the guide; And a circuit board connected to the transmission unit and the connector and having a circuit for transmitting a video signal.

The multi-channel transceiver module according to the present invention includes: an induction unit in which a plurality of optical line units embedded in a cable unit are individually inserted and the optical signal direction is changed; A transmitter for transmitting or receiving an optical signal transmitted through the guide; A periodic plate connected to the transmission unit by a connector and having a circuit for transmitting an image signal; And a socket unit connected to the plurality of signal line units incorporated in the cable unit and connected to the periodic plate unit to transmit an electric signal of the signal line unit.

The multi-channel transceiver module according to the present invention includes: an induction unit in which a plurality of optical line units embedded in a cable unit are individually inserted and the optical signal direction is changed; A transmitter for transmitting or receiving an optical signal transmitted through the guide; A periodic plate connected to the transmission unit by a connector and having a circuit for transmitting an image signal; A socket unit connected to the plurality of signal line units built in the cable unit individually and connected to the period plate unit to transmit an electric signal of the signal line unit; A cover portion in which the guide portion, the transfer portion, the period plate portion, the socket portion, and the cable portion are inserted; And a terminal portion connected to the periodic plate portion and connected to the image means through the cover portion.

The guide portion includes an induction housing portion; A guide tube portion formed in the guide housing portion and connected to the optical line portions to transmit an optical signal; An induction lens unit formed on the induction housing unit and arranged to align an optical signal transmitted through the induction tube unit; And an induction filter unit formed in the induction housing unit and changing an optical signal direction.

And the guide lens unit is integrally formed with the guide housing unit.

And the guide lens unit is mounted on the guide housing part.

The transmitter includes a transmitter plate mounted to the guide and connected to the periodic plate; A transmission element part that is surface mounted on the transmitter plate part and transmits or receives an optical signal; And a heat dissipation unit coupled to the transmitter plate unit to emit heat.

Wherein the transmission substrate portion comprises: a rigid substrate portion mounted on the guide portion; And a flexible substrate portion connected to the rigid substrate portion and bent to be connected to the periodic plate portion.

Wherein the transmission substrate portion is composed of a plurality of transmission tube portions each corresponding to the guide tube portion that is partitioned, and the transmission element portion is mounted on each of the transmitter plate portions.

And a plurality of the transmission element portions corresponding to the guide tube portions partitioned are mounted on one of the transmitter plate portions.

Wherein the socket portion includes a plurality of socket inserting portions for retaining the connected state of the signal line portion; And a socket substrate portion having the socket inserting portion mounted thereon, the socket substrate portion being connected to the periodic plate portion and having a circuit for transmitting an electric signal of the signal line portion.

Wherein the socket base portion includes a socket hard portion on which the socket inserting portion is mounted; And a socket coupled portion connected to the socket hard portion and bent to be connected to the periodic plate portion.

The socket unit further includes a socket terminal unit mounted on the socket substrate unit and receiving external power.

In the multichannel transmission / reception module according to the present invention, welding between parts is eliminated, so that the assemblability can be improved and the productivity can be improved.

The multichannel transmitting / receiving module according to the present invention can be used by replacing only the parts that are faulty by assembling the parts.

In the multi-channel transmission / reception module according to the present invention, since the transmission part is mounted on the guide part and the reliability evaluation is performed before performing the optical alignment test, the assembling of the defective parts can be suppressed and a high yield can be ensured.

In the multichannel transmission / reception module according to the present invention, the flexible board is included in the transmitter board, so that the coupling with the periodic board can be smoothly performed.

In the multichannel transmission / reception module according to the present invention, each optical line unit is separately mounted on the guide unit, so that the optical line unit and the corresponding transmission unit can be replaced when an error occurs.

In the multi-channel Tx / Rx module according to the present invention, the respective signal line portions are individually mounted in the socket inserting portion, so that the socket inserting portion corresponding to each signal line portion can be replaced when an error occurs.

1 is a block diagram schematically illustrating a multi-channel transmission / reception module according to an embodiment of the present invention.
2 is a perspective view schematically showing an induction unit in a multi-channel transceiver module according to an embodiment of the present invention.
3 is a cross-sectional view schematically illustrating an induction unit in a multi-channel transceiver module according to an embodiment of the present invention.
4 is a diagram schematically illustrating a transmitting unit in a multi-channel transmitting / receiving module according to an embodiment of the present invention.
5 is a view schematically showing a state in which a transmission substrate section partitioned by a multi-channel transmission / reception module according to an embodiment of the present invention is disposed.
6 is a view schematically showing a state in which a single transmission substrate portion is arranged in a multi-channel transmission / reception module according to an embodiment of the present invention.
7 is a view schematically showing a socket unit in a multi-channel transmission / reception module according to an embodiment of the present invention.
8 is a diagram schematically showing a state in which a cable unit including a multi-channel transmission / reception module according to an embodiment of the present invention connects an input unit and an output unit.

Hereinafter, embodiments of a multi-channel transmission / reception module according to the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. Further, terms to be described below are terms defined in consideration of functions in the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

1 is a block diagram schematically illustrating a multi-channel transmission / reception module according to an embodiment of the present invention. Referring to FIG. 1, a multi-channel transceiver module 1 according to an embodiment of the present invention includes an induction unit 10, a transmission unit 20, and a periodic plate 30.

A plurality of optical line units 101 embedded in the cable unit 100 are individually inserted into the guide unit 10. The guide portion 10 changes the direction of the optical signal transmitted through the optical line portion 101. [ For example, the cable unit 100 may include four optical line units 101 for transmitting optical signals using optical fibers, and each of the optical line units 101 may be individually inserted into the guide unit 10, Can be maintained. Separate connecting means may be formed at the end of each optical line section 101 to be detachably attached to the guide section 10. At this time, each of the optical line units 101 may be separately partitioned or may be connected by a separate connector.

The transmitting unit 20 transmits or receives an optical signal transmitted through the guide unit 10. For example, the transmitting unit 20 may be mounted on the guiding unit 10 and may transmit the optical signal to the guiding unit 10. In addition, the transfer unit 20 is mounted on the guide unit 10 and can receive the optical signal transmitted from the guide unit 10.

The period plate portion 30 is connected to the transfer portion 20 by a connector, and has a circuit for transferring a video signal. For example, the periodic plate portion 30 and the transfer portion 20 may be coupled in a zip connector manner to eliminate the welding process.

The multi-channel transmission / reception module 1 according to an embodiment of the present invention may further include a socket unit 40. A plurality of signal line units 102 incorporated in the cable unit 100 are individually connected to the socket unit 40 and connected to the periodic plate unit 30 to transmit an electric signal of the signal line unit 102. For example, the cable unit 100 may include a plurality of optical line units 101 and a plurality of signal line units 102 for transmitting electrical signals. The plurality of signal line portions 102 are each made of an insulating layer covering the conductor and the conductor, and a part thereof is used for supplying power, and the rest can be used for transmitting a control signal or for grounding. The socket portion 40 and the periodic plate portion 30 may be coupled in a zip connector manner so that the welding process can be eliminated.

The multi-channel transceiver module 1 according to an embodiment of the present invention may further include a cover portion 50 and a terminal portion 60. [

The cover part 50 has a shape that can be assembled and the cover part 50 can include the guide part 10, the transfer part 20, the periodic plate part 30, and the socket part 40. The cable portion 100 may be inserted into one end of the cover portion 50.

For example, the guide portion 10, the transfer portion 20, the periodic plate portion 30, and the socket portion 40 may be mounted on the inner side of the cover portion 50 and maintained in a fixed state. The guide portion 10, the transfer portion 20, the periodic plate portion 30, and the socket portion 40 may be joined to the cover portion 50. In addition, the components can be kept fixed within the cover portion 50 in various ways.

The terminal portion 60 is connected to the periodic plate portion 30 and can be connected to the image means through the cover portion 50. [ For example, the video means may be a monitor, a television, a rooftop billboard, or the like.

The cover portion 50 may include a cover container portion 51 and a cover cover portion 52. The cover container portion (51) has a container shape with the upper side opened. The guide portion 10, the transfer portion 20, the periodic plate portion 30, and the socket portion 40 may be incorporated in the cover container portion 51. The cover lid portion 52 can be screwed to the cover container portion 51 to cover the open portion of the cover container portion 51. [

FIG. 2 is a perspective view schematically illustrating an induction unit in a multi-channel transceiver module according to an embodiment of the present invention, and FIG. 3 is a cross-sectional view schematically illustrating an induction unit in a multi-channel transceiver module according to an embodiment of the present invention. 1 to 3, an induction unit 10 includes an induction housing unit 11, a guide tube unit 12, an induction lens unit 13, and an induction filter unit 14.

The induction housing part 11 is made of plastic material. The induction housing part 11 includes a housing body part 111 and a housing coupling part 112 extending from the housing body part 111 to which the transfer part 20 or the induction filter part 14 is mounted can do.

The guiding tube portion 12 is formed in the guiding housing portion 11, and the optical line portions 101 are connected to each other to transmit optical signals. For example, the housing body portion 111 may be formed with a guide tube portion 12 corresponding to each optical line portion 101. Each optical line portion 101 is inserted into each guide tube portion 12 and each optical signal can be guided through the guide tube portion 12. [ In addition, the housing body portion 111 in which one guide tube portion 12 is formed may be connected to each other to guide the plurality of optical line portions 101.

The guide lens section 13 is formed in the guide housing section 11 and aligns the optical signal transmitted through the guide tube section 12. [ For example, the guide lens unit 13 may be disposed in a straight line with the guide tube 12, and may protrude to the inside of the housing coupling part 112 to form a spherical surface.

The guide lens unit 13 may be integrally formed with the guide housing unit 11. [ That is, the guide portion 10 can be integrally injection-molded. In addition, the guide lens unit 13 can be manufactured as a separate component and mounted on the guide housing unit 11. [

The induction filter section 14 is mounted inside the induction housing section 11 and changes the optical signal direction. For example, the image signal transmitted from the transmission unit 20 can be reflected by the inductive filter unit 14 and reach the optical line unit 101 inserted into the flow path housing unit 11. The image signal transmitted from the optical line unit 101 can be reflected by the inductive filter unit 14 and reach the transfer unit 20.

4 is a diagram schematically illustrating a transmitting unit in a multi-channel transmitting / receiving module according to an embodiment of the present invention. 1 to 4, a transmitter 20 according to an embodiment of the present invention includes a transmitter plate 21, a transmission element 22, and a transmission heat dissipation unit 23.

The transmitter plate portion 21 is mounted on the guide portion 10 and is connected to the periodic plate portion 30. In one example, the transmitter plate portion 21 may be formed with a circuit for transmitting an optical signal.

The transmission element section 22 is surface mounted on the transmitter plate section 21 and transmits or receives an optical signal. For example, the light emitting element and the light receiving element may be separately mounted to the transfer element portion 22. The light emitting element generates an optical signal, and the light receiving element can receive the optical signal. If the light emitting element and the light receiving element are mounted at the same time, transmission and reception of the optical signal can be mixed. The epoxy layer can be cured in the transfer portion 22. The epoxy layer may cover the transfer element portion 22 to protect the transfer element portion 22.

The transmission heat-radiating portion 23 is coupled to the transmitter plate portion 21 to emit heat. The transmission heat dissipating part 23 may be coupled to the transmitter plate part 21 after the transmitter plate part 21 on which the transmission element part 22 is surface mounted is mounted on the induction housing part 11. [ The transmission heat-radiating portion 23 may include a metal material capable of conducting heat.

The transmitter plate portion 21 according to an embodiment of the present invention includes a rigid substrate portion 211 and a flexible substrate portion 212. The hard substrate portion 211 may include a hard material having a limited shape deformation, and the soft substrate portion 212 may include a soft material free from shape deformation.

The hard substrate portion 211 is mounted on the guide portion 10. For example, the hard substrate portion 211 may be bonded to the inside of the housing coupling portion 112. In addition, the hard substrate portion 211 can be kept mounted on the housing coupling portion 112 in various coupling schemes.

The flexible substrate portion 212 is connected to the hard substrate portion 211 and is connected to the periodic plate portion 30. For example, the flexible substrate portion 212 may be connected to the hard substrate portion 211 to transmit and receive electrical signals, and may be connected to the periodic plate portion 30 by forming a collector connector at the end portion.

The flexible substrate portion 212 is connected to the upper side of the hard substrate portion 211 and the transmission element portion 22 can be mounted on the flexible substrate portion 212. In addition, the flexible substrate portion 212 is connected to the lower side or the side surface of the hard substrate portion 211, and the transfer element portion 22 can be mounted on the hard substrate portion 211.

5 is a view schematically showing a state in which a transmission substrate section partitioned by a multi-channel transmission / reception module according to an embodiment of the present invention is disposed. 1 to 5, a plurality of the transmitter plate portions 21 are spaced apart from each other so as to correspond to the guide tube portions 12 that are partitioned. Then, the transmitter element portion 22 is mounted on each of the transmitter plate portions 21.

For example, four induction tube portions 12 may be formed in the induction housing portion 11, four transmitter plate portions 21 may be disposed in line with the respective guide tube portions 12, (23) can be coupled to the four transmitter plates (21). At this time, an epoxy layer may be formed on each of the transmitter plate portions 21.

6 is a view schematically showing a state in which a single transmission substrate portion is arranged in a multi-channel transmission / reception module according to an embodiment of the present invention. Referring to FIGS. 1 to 4 and 6, one transmitter plate 21 is equipped with a plurality of transmission elements 22 corresponding to the guide tubes 12, respectively.

For example, four induction tube portions 12 are formed in the induction housing portion 11, four transfer element portions 22 are surface-mounted on one transmitter plate portion 21, Lt; / RTI > One transmission heat radiating part 23 may be coupled to one transmitter plate part 21. [ At this time, the epoxy layer may cover the whole of the transfer element part 22 mounted on one transmitter plate part 21.

7 is a view schematically showing a socket unit in a multi-channel transmission / reception module according to an embodiment of the present invention. Referring to FIGS. 1 and 7, a socket unit 40 according to an embodiment of the present invention includes a socket inserting unit 41 and a socket substrate unit 42.

The socket inserting portion 41 retains the connected state of the signal line portion 102 inserted therein. For example, seven signal line units 102 embedded in the cable unit 100 may be individually inserted into the seven socket inserting units 41 and maintained in a coupled state. At this time, the number of the socket inserting portions 41 may be changed according to the number of the signal line portions 102. Separate connecting means may be formed at the end of each signal line portion 102 and may be detachably attached to the socket inserting portion 41. Meanwhile, the socket inserting portions 41 can be disposed individually or integrally, and the plurality of signal line portions 102 can be inserted into the socket inserting portion 41 separately or integrally connected.

A socket inserting portion 41 is mounted on the socket base portion 42. The socket substrate unit 42 includes a circuit for transmitting an electric signal of the signal line unit 102 and is connected to the periodic plate unit 30 to transmit an electric signal.

The socket substrate portion 42 according to an embodiment of the present invention may include a socket hard portion 421 and a socket soft portion 422. The socket hardened part 421 may include a hard material having a limited shape deformation, and the socket softened part 422 may include a soft material that is deformable.

For example, the socket hard portion 421 may be mounted on the cover container portion 51. [ The socket-hardened portion 421 may be assembled to the cover container portion 51 so as to be replaceable. The socket flexible portion 422 is connected to the socket-hardened portion 421 so as to transmit and receive an electric signal, and the housing connector can be formed at the end of the socket flexible portion 422 to be connected to the baseplate portion 30. On the other hand, the socket base portion 42 may be made of a soft material only.

The socket portion 40 according to an embodiment of the present invention may further include a socket terminal portion 43. The socket terminal portion 43 is mounted on the socket base portion 42 and receives external power. For example, the socket terminal portion 43 may be exposed to the outside through the cover container portion 51 and connected to the power supply means.

8 is a diagram schematically showing a state in which a cable unit including a multi-channel transmission / reception module according to an embodiment of the present invention connects an input unit and an output unit. Referring to FIGS. 1 and 8, a multi-channel transmission / reception module 1 may be mounted on both ends of a cable unit 100 and connected to a video unit. That is, one of the multi-channel transmission / reception modules 1 is connected to the input unit 200, and the other of the multi-channel transmission / reception modules 1 is connected to the output unit 300. For example, the input unit 200 may be a computer or a set-top box for inputting a video signal. The output unit 300 may be a display device for outputting a video signal. One of the multichannel transmission / reception modules 1 is connected to the input unit 200 to transmit an optical signal, and the other of the multichannel transmission / reception modules 1 receives an optical signal transmitted through the optical line unit 101 And transmit it to the output unit 300.

The assembly and operation of the multi-channel transceiver module according to an embodiment of the present invention will now be described.

The induction housing part 11 in which a plurality of induction tube parts 12 are formed is manufactured and the transfer part 20 is mounted in the induction housing part 11. [ The transmission unit 20 includes a transmitter plate unit 21 mounted on the induction housing unit 11 and a transmission element unit 21 mounted on the transmitter plate unit 21 and including various elements capable of transmitting and receiving optical signals, (22).

When the transmitter plate portion 21 is mounted on the guiding housing portion 11, the optical alignment inspection can be performed to determine whether the transmitter plate portion 21 is defective or not. When the optical alignment inspection is completed, the transmission heat dissipating unit 23 may be additionally mounted on the transmitter plate unit 21 to emit heat generated in the transmitter plate unit 21. [

On the other hand, the cover container portion 51 is attached to both ends of the cable portion 100 and the guide portion 10, the transfer portion 20, the period plate portion 30, (40). For example, the guide housing part 11 with the transmitter plate part 21 mounted thereon is assembled to the cover container part 51 and the base plate part 30 is fixed to the terminal part 60 formed at the end of the cover container part 51 You can connect. Then, the socket base portion 42 can be assembled to the cover container portion 51. At this time, the transmitter plate portion 21 and the socket substrate portion 42 can be connected to the periodic plate portion 30.

When the installation of the guide portion 10, the transfer portion 20, the periodic plate portion 30 and the socket portion 40 is completed, the plurality of optical line portions 101 are guided from the cable housing portion 100 to the guide housing portion 11 and connects the plurality of signal line parts 102 to the socket inserting part 41. [

When the optical line unit 101 and the signal line unit 102 are assembled together, the cover lid unit 52 is assembled to the cover container unit 51, and the guide unit 10, the transfer unit 20, The plate portion 30, and the socket portion 40, respectively.

When the assembly of the multichannel transmission / reception module 1 is completed as described above, one end of the cable unit 100 is connected to the input unit 200, and the other end of the cable unit 100 is connected to the output unit 300. Accordingly, the video signal generated in the input unit 200 is transmitted to the output unit 300 through the cable unit 100, and a video signal can be implemented in the output unit 300.

The multichannel transmission / reception module 1 according to the embodiment of the present invention eliminates the welding between parts, thereby improving the assemblability and the productivity.

The multichannel transmission / reception module 1 according to the embodiment of the present invention can be used by replacing only a component in which an error occurs, by assembling the components.

The multichannel transmission / reception module 1 according to the embodiment of the present invention performs the reliability evaluation before the transmission unit 20 is mounted on the guide unit 10 and performs the optical alignment test, The yield can be guaranteed.

In the multi-channel transmission / reception module 1 according to the embodiment of the present invention, the flexible board part 211 is included in the transmitter board part 21 so that the connection with the periodic board 30 can be smoothly performed.

The multichannel transmission / reception module 1 according to the embodiment of the present invention is configured such that each optical line portion 101 is individually mounted on the guiding portion 10, The portion 22 can be replaced.

Channel transmission and reception module 1 according to an embodiment of the present invention is configured such that each signal line portion 102 is individually mounted on the socket inserting portion 41 so that the signal line portions 102 corresponding to the respective signal line portions 102 The socket base portion 42 connected to the socket inserting portion 41 or the socket inserting portion 41 can be replaced.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand. Accordingly, the true scope of protection of the present invention should be defined by the following claims.

10: guide part 11: guiding housing part
12: guide tube part 13: guide lens part
20: Transmission unit 21: Transmitter plate
22: transfer element part 23:
30: a periodic plate portion 40: a socket portion
41: socket inserting portion 42: socket substrate portion
43: socket terminal part 50: cover part
60: terminal portion 100: cable portion
101: optical line section 102: signal line section
200: input unit 300: output unit

Claims (13)

delete An inducing unit into which a plurality of optical line units embedded in the cable unit are individually inserted and which change the optical signal direction;
A transmitter for transmitting or receiving an optical signal transmitted through the guide;
A periodic plate connected to the transmission unit by a connector and having a circuit for transmitting an image signal; And
And a socket unit connected to the plurality of signal line units individually incorporated in the cable unit and connected to the periodic plate unit to transmit an electric signal of the signal line unit,
The socket portion
A plurality of socket inserters for inserting and retaining the connected signal line portions; And
And a socket substrate portion in which the socket inserting portion is mounted, the socket substrate portion is connected to the periodic plate portion, and a circuit for transmitting an electric signal of the signal line portion is embedded.
An inducing unit into which a plurality of optical line units embedded in the cable unit are individually inserted and which change the optical signal direction;
A transmitter for transmitting or receiving an optical signal transmitted through the guide;
A periodic plate connected to the transmission unit by a connector and having a circuit for transmitting an image signal;
A socket unit connected to the plurality of signal line units built in the cable unit individually and connected to the period plate unit to transmit an electric signal of the signal line unit;
A cover portion in which the guide portion, the transfer portion, the period plate portion, the socket portion, and the cable portion are inserted; And
And a terminal portion connected to the periodic plate portion and connected to the image means through the cover portion,
The socket portion
A plurality of socket inserters for inserting and retaining the connected signal line portions; And
And a socket substrate portion in which the socket inserting portion is mounted, the socket substrate portion is connected to the periodic plate portion, and a circuit for transmitting an electric signal of the signal line portion is embedded.
4. The apparatus according to claim 2 or 3, wherein the guide portion
An induction housing part;
A guide tube portion formed in the guide housing portion and connected to the optical line portions to transmit an optical signal;
An induction lens unit formed on the induction housing unit and arranged to align an optical signal transmitted through the induction tube unit; And
And an induction filter unit formed in the induction housing unit and adapted to change an optical signal direction.
5. The method of claim 4,
Wherein the guide lens unit is integrally formed with the guide housing unit.
5. The method of claim 4,
And the guide lens unit is mounted on the guide housing part.
5. The apparatus of claim 4, wherein the transmitting unit
A transmitter plate mounted on the guide and connected to the periodic plate;
A transmission element part that is surface mounted on the transmitter plate part and transmits or receives an optical signal; And
And a transmission heat dissipating unit coupled to the transmitter plate to radiate heat.
8. The apparatus of claim 7, wherein the transfer substrate portion
A hard substrate portion mounted on the guide portion; And
And a flexible substrate portion connected to the rigid substrate portion and bent to be connected to the periodic plate portion.
8. The method of claim 7,
Wherein the transfer substrate portion comprises a plurality of guide portions corresponding to the partitioned guide portions,
And the transmission element unit is mounted on each of the transmitter plate units.
8. The method of claim 7,
Wherein the plurality of transmission element parts corresponding to the guide tube part partitioned are mounted on one transmitter plate part.
delete The connector according to claim 2 or 3, wherein the socket substrate portion
A socket hard portion to which the socket inserting portion is mounted; And
And a socket flexible portion connected to the socket hard portion and bent to be connected to the periodic plate portion.
The connector according to claim 2 or 3, wherein the socket portion
And a socket terminal unit mounted on the socket substrate unit and receiving an external power source.

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