KR20160001743U - The improved structure of optical fiber network card having bypass ability - Google Patents

Abstract

The present invention relates to a network card substrate; A network processing chip installed on the network card substrate and making an electrical connection; A first slot disposed on the network card substrate and in electrical communication with the network processing chip; And a second slot disposed on the network card substrate and in electrical connection with the network processing chip. The present invention provides a common network card substrate to conveniently assemble an optical fiber network card configuration of a normal mode and a bypass mode and to modularly assemble according to different requirements on the user side so as to be assembled in commonality, The manufacturing assembly effect can be achieved.

Description

[0001] The present invention relates to an improved optical fiber network card having a bypass function,

The present invention relates to an optical fiber network card structure, and more particularly, to an optical fiber network card structure having a bypass function capable of simplifying a production assembly process and improving a production efficiency by facilitating selection and manufacture of a network card having a bypass function, Network card improvement structure.

Currently, a network card device for network transmission has a plurality of optical fiber modules installed on an optical transmission / reception device so as to be used for transmission of an optical fiber network. In order to solve the problem of network connection due to an abnormality of an inline device, The fiber-optic network card device is designed to have a bypass function. 1, and includes an optical transceiver 90. The optical transceiver 90 includes a first optical fiber network device 91, a second optical fiber network device 91, By connecting the optical fiber network facility 92 and the inline facility 93 to each other, an optical fiber network is constructed so that the inline facility 93 can perform data filtering and data filtering for the first optical fiber network facility 91 and the second optical fiber network facility 92, / RTI > and / or flow control functions. The optical transceiver assembly 90 mainly includes an optical transceiver assembly 94, a photoelectric transducer substrate 95, a light switch 96 and a switch control board 97. The optical transceiver assembly 94 includes A first optical transmission / reception port 941 and a second optical transmission / reception port 942 for connecting one optical fiber network facility 91 and a second optical fiber network facility 92, respectively. The photoelectric conversion substrate 95 includes an electric signal port 953 for electrically connecting the first photoelectric conversion unit 951 to the second photoelectric conversion unit 952 and the inline facility 93, The photoelectric conversion unit 951 and the second photoelectric conversion unit 952 convert the optical signals received from the first optical transmission / reception port 941 and the second optical transmission / reception port 942 into electric signals, And converts the electric signal received from the light receiving section 93 into an optical signal. The light switch 96 is connected to the first optical transmission / reception port 941, the second optical transmission / reception port 942 and the first photoelectric conversion unit 951 and the second photoelectric conversion unit 952, respectively. The switch control board 97 is electrically connected to the light switch 96 and has a control signal port 971. The control signal port 971 is electrically connected to the in- The inline facility 93 receives the control signal sent to the light changeover switch 6 through the control signal sending unit 931. [ The switch control board 97 changes the operation state of the light switch 96 according to the control signal received by the control signal port 971 and sets the light switch 96 to the normal mode Or activates the light switch 96 in the bypass mode. Receiving port 941 and the second optical transmission / reception port 942 in a situation where the in-line facility 93 does not pass through the in-line facility 93 when the in-line facility 93 is abnormally operated (shut down or powered off) So that the first optical fiber network facility 91 and the second optical fiber network facility 92 can still maintain normal network communication state.

The above-described bypass configuration of the conventional optical fiber card can achieve the bypass operation function of the network card, but is still defective. For example, the bypass configuration of the conventional optical fiber network card can operate in a normal mode and a bypass mode at the same time. However, when only the normal mode is required (that is, Pass mode is not necessary), the existing bypass mode configuration equipment is unnecessary and wastes, which is not economically advantageous. In other words, in view of economic benefits, it is generally necessary to have a fiber network card with these two modes so that it can be selected and used by an ordinary technician, but it can be applied in accordance with different choices of whether or not a bypass mode is required, It is impossible to design and manufacture a single network card substrate conveniently and flexibly so that it is a non-ideal design. Therefore, how to solve defects such as manufacturing and cost problems caused by different choices according to the necessity of the bypass mode of the conventional optical fiber network card device needs to be solved by an industry or a technician to be.

The inventor of the present invention has undertaken research on the solution of the problem in view of the defect in the selective use of the conventional optical fiber network card device and the non-ideal in the structural design, We have developed a fiber-optic network card enhancement structure that has been expanded to have a bypass function, and designed this idea for a long time in order to promote the society and the development of the industry.

The purpose of this invention is to provide a common network card substrate to conveniently assemble a fiber network network card configuration in Normal Mode or Bypass Mode and to assemble according to different demands on the user side To provide an improved fiber optic network card enhancement structure with a bypass function that is capable of achieving commonality, flexibility, and manufacturing and assembly benefits that are economically advantageous.

Another object of the present invention is to provide a modularized installation of a fiber-optic network card, facilitating the modular assembly of a common network card substrate, and optionally configuring a fiber-optic network card in a normal mode or a bypass mode The present invention provides an optical fiber network improvement structure that is expanded to have a bypass function capable of attaining a positive effect of reducing costs.

The optical fiber network improving structure extended to have the bypass function of the present invention for achieving the above object,

A network card substrate; A network processing chip installed on the network card substrate and making an electrical connection with the network card substrate; A first slot disposed on the network card substrate and in electrical communication with the network processing chip; And a second slot disposed on the network card substrate and in electrical connection with the network processing chip.

According to the above configuration, an external connection port is provided on the network card substrate, the external connection port is electrically connected to the network processing chip, and the external connection port electrically connects the inline facility.

According to the above configuration, the first transceiver module and the second transceiver module are installed on the network card substrate, the first transceiver module includes a first transceiver case and a first transceiver, A second transceiver case and a second transceiver, wherein the first transceiver and the second transceiver are in signal communication with the first slot and the second slot, respectively, i.e., the first slot and the second slot Each signal-connect the first transceiver module and the second transceiver module.

According to the above configuration, the network card substrate is further provided with a signal control connection port, an external connection port is provided on the network card substrate, the external connection port electrically connects the inline facility, The connection port electrically connects the network processing chip.

The bypass optical fiber module may further include a first optical adapter at a front end, a second optical adapter, a first photoelectric conversion chip inside, a second photoelectric conversion chip at a front end, And a first plug connector and a second plug connector at a rear end, wherein the first optical adapter is optically signal-connected to the first photoelectric conversion chip, 1 plug connector, the second optical adapter and the second photoelectric conversion chip are optically signal-connected, the second photoelectric conversion chip is electrically connected to the second plug connector, and the first The plug connector and the second plug connector are electrically connected to each other through the first slot and the second slot, respectively.

According to the above configuration, the rear end of the bypass optical fiber module is formed with a rib portion for installing the first plug connector and the second plug connector.

According to the above configuration, the signal control connector is installed on the bottom surface of the bypass optical fiber, and the bypass optical fiber module is assembled by being pushed along the network card substrate, so that the signal control connector and the signal control connection port are electrically connected .

According to the above configuration, the bypass optical fiber module further includes a light switch, wherein the light switch is optically connected between the first photo adapter and the first photoelectric conversion chip, Is optically signal-connected between the second optical adapter and the second photoelectric conversion chip.

According to the above configuration, the bypass optical fiber module further includes a microcontroller, and the microcontroller is electrically connected to the light switch.

According to the above configuration, the bypass optical fiber module further includes a signal controller electrically connected to the network processing chip, and the signal controller is electrically connected to the microcontroller.

According to the above configuration, the bypass optical fiber module is further provided with a battery, and the battery is independent of the optical fiber switch, the first photoelectric conversion chip, the second photoelectric conversion chip, the microcontroller and the signal controller in the bypass optical fiber module Supply power.

According to the configuration, the network card substrate is further provided with a microcontroller, and the microcontroller is electrically connected to the signal control connection port, the signal control connector, and the light changeover switch in order.

According to the above configuration, the network card substrate is further provided with a signal controller electrically connected to the network processing chip, and the signal controller is electrically connected to the microcontroller.

According to the above configuration, the bypass optical fiber module further includes a battery, and the battery supplies independent power to the optical fiber switch, the first photoelectric conversion chip, and the second photoelectric conversion chip in the bypass optical fiber module.

According to the present invention, it is possible to achieve a positive effect of reducing costs by assembling the optical fiber network card configuration of the normal mode or the bypass mode.

1 is a schematic diagram showing a bypass mode configuration of a conventional optical fiber network card.
2 is a schematic structural view of a network card substrate of the present invention.
3 is a schematic structural view of a general mode optical fiber network card of the present invention.
4 is a schematic view showing a processing configuration of a network card substrate of the bypass mode according to the present invention.
5 is a schematic diagram showing a bypass mode configuration and a signal flow of the present invention.
6 is an exploded schematic view showing a bypass mode configuration of the present invention.
7 is an assembled schematic view showing a bypass mode configuration of the present invention.
8 is a schematic diagram showing a bypass mode configuration and signal flow according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 2, the optical fiber network improving structure extended to have the bypass function of the present invention includes a network card substrate 10, and the network card substrate 10 includes a network processing chip 12 The network processing chip 12 is electrically connected to the network card substrate 10 and a first slot 14 and a second slot 16 are provided on the network card substrate 10, The first slot 14 and the second slot 16 are electrically connected to the network processing chip 12, respectively. The external connection port 121 is electrically connected to the network processing chip 12 and the external connection port 121 is connected to the inline (30), and the in-line facility (30) is, for example, a desktop computer, a network host, and the like. The first slot 14, the second slot 16, and the external connection port 121 may all be configured as connectors.

Referring to FIG. 3, it is described that an optical fiber network card improving structure extended to have a bypass function of the present invention is used in a normal mode optical fiber network card configuration. That is, the optical fiber network card configuration does not have a bypass mode function. The first transceiver module 18 and the second transceiver module 20 are installed on the network card substrate 10 and the first slot 14 and the second slot 16 of the network card substrate 10 The first transceiver module 18 and the second transceiver module 20 signal and connect the first transceiver module 18 and the second transceiver module 20, respectively, and the first transceiver module 18 includes a first transceiver case 80 and a first transceiver 181 , And the second transceiver module 20 includes a second transceiver case 200 and a second transceiver 201. That is, the first slot 14 and the second slot 16 are installed behind the first transceiver case 180 and the second transceiver case 20, respectively. The first transceiver 181 and the second transceiver 201 are inserted into the first transceiver case 180 and the second transceiver case 200 so that the first transceiver 181 and the second transceiver 201 are inserted into the first transceiver case 180 and the second transceiver case 200, A first transceiver module 18 and a second transceiver 18 that are operatively connected to the network processing chip 12 by signaling connection of the first and second slots 201 and 201 to the first and second slots 14 and 16, Thereby forming the module 20. The first transceiver case 180 and the second transceiver case 200 may be made of metal and the action thereof fixes the first transceiver 181 and the second transceiver 201, Interference can be blocked and reduced.

When the transceiver case (for example, the first transceiver case 180 and the second transceiver case 200) is fabricated on the network card substrate 10 in the optical network network card configuration of the normal mode, Existing transceivers (e.g., the first transceiver 181 and the second transceiver 201) may be inserted into the transceiver case. The manufacturer or user can easily assemble the fiber optic network card at a relatively low cost and allow the inline facility 30 to easily connect to the network via the fiber optic network card.

Referring to FIGS. 4, 5, 6, and 7, an optical fiber network improving structure extended to have a bypass function of the present invention is applied to a configuration of a fiber network card having a bypass mode. A signal control connection port 22 is further provided on the network card substrate 10 and the signal control connection port 22 is electrically connected to the network processing chip 12. [ The present invention also includes a bypass optical fiber module 24 wherein the bypass optical fiber module 24 includes a first optical adapter 241 with a front end protruding therefrom, a second optical adapter 242, A second photoelectric conversion chip 262, a first plug connector 244 at the rear end, and a second plug connector 245. The photoelectric conversion chip 261, the second photoelectric conversion chip 262,

The first optical adapter 241 is optically connected to the first photoelectric conversion chip 261 and the first photoelectric conversion chip 261 is electrically connected to the first plug connector 244, The second optical adapter 242 is optically connected to the second photoelectric conversion chip 262 and the second photoelectric conversion chip 262 is electrically connected to the second plug connector 245. The first optical adapter 241 and the second optical adapter 242 are optically connected to the first optical fiber network equipment and the second optical fiber network equipment (not shown), respectively, to form a network connection. A recessed portion 246 for providing the first plug connector 244 and the second plug connector 245 is formed at the rear end of the bypass optical fiber module 24, The second plug connector 244 and the second plug connector 245 are composed of a circuit board and a connector and the circuit board can connect an electrical signal and the connector is connected to the first slot 14 and the second slot 16, . A signal control connector 243 is provided on the bottom surface of the bypass optical fiber module 24.

The first plug connector 244 and the second plug connector 245 are pushed along the network card substrate 10 when the bypass optical fiber module 24 is assembled and connected to the first plug connector 244, And the second plug connector 245 are connected to the first slot 14 and the second slot 16 to complete the electrical connection and at the same time the signal control connector 243 is connected to the signal control connection port 22, the optical network card configuration with the Bypass Mode is assembled.

The first photoelectric conversion chip 261 converts the optical signal transmitted by the first optical adapter 241 into an electrical signal and supplies the electrical signal to the first plug connector 244, To the inline facility (30) via the network processing chip (12). The first photoelectric conversion chip 261 also converts an electrical signal transmitted by the inline facility 30 through the network processing chip 12, the first slot 14 and the first plug connector 244 into an optical signal And transmits the optical signal to the first optical adapter 241. The second photoelectric conversion chip 262 converts the optical signal transmitted by the second optical adapter 242 into an electrical signal and transmits the electrical signal to the second plug connector 245, To the inline facility (30) via the network processing chip (12). The second photoelectric conversion chip 262 also converts the electrical signals transmitted by the inline facility 30 through the network processing chip 12, the second slot 16 and the second plug connector 245, And transmits the optical signal to the second optical adapter 242. [

Referring to FIG. 5, the specific configuration and signal flow of the bypass optical fiber module 24 of the present invention will be described. The bypass optical fiber module 24 further includes a light switch 26, a microcontroller 27 and the signal controller 28. The light switch 26 is connected to the first optical adapter The light switch 26 is also optically connected between the first photoelectric conversion unit 241 and the first photoelectric conversion unit 261 and similarly the light conversion switch 26 is also optically connected between the second photoelectric conversion unit 242 and the second photoelectric conversion chip 262. [ As shown in FIG. The microcontroller 27 is electrically connected to the light switch 26 and the signal controller 28 is electrically connected to the microcontroller 27 and the signal controller 28 also controls the signal control And is electrically connected to the connection port 22 to cause the signal controller 28 to be electrically connected to the network processing chip 12. [

The signal controller 28 may be a counter device and detects whether the network processing chip 12 has an electrical signal through a counter system to determine whether the inline facility 30 is normally connected to the network . Additionally, in a situation where the signal controller 28 continues to detect whether the network processing chip 12 has an electrical signal, if the network is in a steady state, the network processing chip 12 has an electrical signal , The signal controller 28 receives an electrical signal response, so that the signal controller 28 can recognize that the in-line facility 30 is normally connected to the network. However, since the network processing chip 12 loses power and loses the electrical signal if the network is in an abnormal state, i.e., the in-line facility 30 is shut down or powered off, the signal controller 28 Since the electric signal response is not received, the signal controller 28 can recognize that the in-line facility 30 is in the network cutoff state.

In the present invention, when the bypass optical fiber module 24 is installed to have a function of bypass mode, if the signal controller 28 does not receive the electric signal of the network processing chip 12 , The inline facility 30 is in a network shutdown state and the signal controller 28 causes the microcontroller 27 to operate the light changeover switch 26 in the bypass mode. That is, the first optical adapter 241 and the second optical adapter 242 are disconnected from the in-line facility 30, and the first optical adapter 241 and the second optical adapter 242 are connected to the light- So that the communication between the first optical fiber network equipment and the second optical fiber network equipment is not blocked so as to maintain smooth connection of the network continuously.

When the signal controller 28 receives the electrical signal of the network processing chip 12, the inline facility 30 indicates that the network connection is smooth and the signal controller 28 is connected to the microcontroller 27, Causes the light switch 26 to operate in the normal mode to allow the first optical adapter 241 and the second optical adapter 242 to connect the inline facility 30. That is, when the bypass optical fiber module 24 is installed on the network card substrate 10 of the present invention, it can be expanded to have a bypass mode function and also has a function of a normal mode .

5) may be installed in the bypass optical fiber module 24 and the battery 29 may be connected to each element in the bypass optical fiber module 24, 26, the first photoelectric conversion chip 261, the second photoelectric conversion chip 262, the microcontroller 27, the signal controller 28 and the like, so that the inline facility 30 loses power , It is possible to cause each element in the bypass optical fiber module 24 to be switched to the function of the bypass mode by the power supplied from the battery 29.

Referring to FIG. 8, the specific configuration and signal flow of another embodiment of the bypass optical fiber module according to the present invention will be described, which is converted and designed on the basis of the structure of the embodiment of FIG. 5, with the following differences. The microcontroller 27 and the signal controller 28 are installed on the network card substrate 10 and the microcontroller 27 sequentially connects the signal control connection port 22, And the signal controller 28 is electrically connected to the network processing chip 12. The microprocessor 27 is electrically connected to the signal controller 28, Lt; / RTI > 8) may be installed in the bypass optical fiber module 24 and the battery 29 may be connected to each element in the bypass optical fiber module 24, The second photoelectric conversion chip 26, the first photoelectric conversion chip 261, the second photoelectric conversion chip 262, and the like. 5, when the bypass optical fiber module 24 is installed on the network card substrate 10 of the present invention, the bypass optical fiber module 24 can be expanded to have a bypass mode function At the same time, it also has the function of Normal Mode.

The optical fiber network card upgrading structure extended to have the bypass function of the present invention provides the common network card substrate through the above configuration to make the optical network card configuration of the normal mode or the bypass mode more convenient And assembling is performed according to different requirements of the user side, so that manufacturing and assembling effects that are compatible with commonality, flexibility, and economical benefit can be achieved. The present invention also provides a modularized installation of the optical fiber network card, facilitating the modular assembly of the common network card substrate, and selectively assembling the optical fiber network card configuration in the normal mode or the bypass mode, .

The above description is only a preferred embodiment of the present invention, and does not limit the scope of the present invention. The equivalent changes and modifications in accordance with the shape, structure, characteristic and spirit described in the scope of claim for utility model registration of this invention are all within the scope of utility model registration claim of this invention.

10: Network card substrate
12: Network processing chip
121: External connection port
14: 1st slot
16: second slot
18: first transceiver module
180: first transceiver case
181: first transceiver
20: second transceiver module
200: second transceiver case
201: second transceiver
22: Signal control connection port
24: Bypass optical fiber module
241: First optical adapter
242: Second optical adapter
243: Signal control connector
244: first plug connector
245: second plug connector
246:
26: Light switch
261: First photoelectric conversion chip
262: second photoelectric conversion chip
27: Microcontroller
28: Signal controller
29: Battery
30: In-line facilities

Claims (14)

A network card substrate;
A network processing chip installed on the network card substrate and making an electrical connection with the network card substrate;
A first slot disposed on the network card substrate and in electrical communication with the network processing chip; And
A second slot disposed on the network card substrate and in electrical communication with the network processing chip;
The optical fiber network card improving structure being expanded to have a bypass function including a power saving function. The method according to claim 1,
An external connection port is provided on the network card substrate, the external connection port is electrically connected to the network processing chip, and the external connection port electrically connects an inline facility, Network card improvement structure. 3. The method of claim 2,
Wherein a first transceiver module and a second transceiver module are installed on the network card substrate, the first transceiver module includes a first transceiver case and a first transceiver, and the second transceiver module includes a second transceiver case and a second transceiver module, Wherein the first transceiver and the second transceiver are communicatively coupled to the first slot and the second slot, respectively, wherein the first slot and the second slot are respectively connected to the first transceiver module And a second transceiver module, said second transceiver module signaling said second transceiver module. 3. The method of claim 2,
A signal control connection port is further provided on the network card substrate, an external connection port is provided on the network card substrate, the external connection port electrically connects the inline facility, A fiber optic network card enhancement structure that is electrically extended with a bypass function to electrically connect the processing chip. 5. The method of claim 4,
Further comprising a bypass optical fiber module,
The bypass optical fiber module includes a first optical adapter at a front end, a second optical adapter, a first photoelectric conversion chip inside, a second photoelectric conversion chip, a first plug connector at a rear end, Wherein the first optical adapter is optically connected to the first photoelectric conversion chip and the first photoelectric conversion chip is electrically connected to the first plug connector, The second photoelectric conversion chip is optically connected to the second photoelectric conversion chip, and the second photoelectric conversion chip is electrically connected to the second plug connector, and the first plug connector and the second plug connector are respectively connected to the first slot and the second slot, And an optical fiber network card enhancement structure expanded to have a bypass function, wherein the optical fiber network card enhancement structure is electrically connected to the second slot. 6. The method of claim 5,
And a rib portion for providing the first plug connector and the second plug connector is formed at a rear end of the bypass optical fiber module. 6. The method of claim 5,
A signal control connector is installed on a bottom surface of the bypass optical fiber module and the bypass optical fiber module is assembled by being pushed along the network card substrate so that the signal control connector and the signal control connection port are electrically connected A fiber optic network card enhancement structure that is extended to have a bypass function. 8. The method of claim 7,
Wherein the bypass optical fiber module further comprises a light switch, wherein the light switch is optically signal-connected between the first photo adapter and the first photoelectric conversion chip, An optical fiber network card improved structure extended optically between the optical adapter and the second photoelectric conversion chip and having a bypass function. 9. The method of claim 8,
Wherein the bypass optical fiber module further includes a microcontroller, and the microcontroller is electrically connected to the light switch, wherein the microcontroller is extended to have a bypass function. 10. The method of claim 9,
Wherein the bypass optical fiber module further comprises a signal controller electrically connected to the network processing chip, the signal controller being electrically connected to the microcontroller, the bypass optical fiber module being expanded to have a bypass function. 11. The method of claim 10,
The bypass optical fiber module is further provided with a battery, and the battery supplies independent power to the light switch, the first photoelectric conversion chip, the second photoelectric conversion chip, the microcontroller, and the signal controller in the bypass optical fiber module , A fiber optic network card enhancement architecture that is extended to have bypass functionality. 9. The method of claim 8,
The microcontroller is further provided with a microcontroller on the network card substrate. The microcontroller is connected to the signal control connection port, the signal control connector, and the optical switch in order. The microcontroller includes an optical fiber network card improvement structure . 13. The method of claim 12,
Wherein the network card substrate is further provided with a signal controller electrically connected to the network processing chip and the signal controller is electrically connected to the microcontroller. 14. The method of claim 13,
The bypass optical fiber module is further provided with a battery, and the battery is provided with a bypass function for supplying independent power to the photoelectric conversion switch, the first photoelectric conversion chip, and the second photoelectric conversion chip in the bypass optical fiber module Expanded fiber optic network card improvement structure.

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