CN211505967U - Multi-slot photoelectric converter - Google Patents

Abstract

The utility model relates to the field of photoelectric conversion, and particularly provides a multi-slot photoelectric converter, which comprises a main control end, a slot connecting end and a state monitor; the main control end is arranged behind the notch connecting end and is electrically connected with the notch connecting end, the state monitor is arranged above the notch connecting end and is connected with the main control end, and the notch connecting end and the state monitor are also wirelessly connected with the background controller; the utility model discloses an above-mentioned structure, through setting up the notch link and set up setting up when a plurality of notches and signal conversion in the mode of setting up paired line interface, fiber interface module and conversion module on the notch link, solved among the prior art photoelectric converter owing to receive converter self volume restriction, lead to often less of trench setting, the problem of the extensive conversion of being not convenient for.

Description

Multi-slot photoelectric converter

Technical Field

The utility model belongs to the technical field of photoelectric conversion and specifically relates to a multislot position photoelectric converter.

Background

Ethernet is a networking technology with the widest application, and has been widely used in various social fields such as enterprises, schools, residential areas and the like due to its advantages of high reliability, large media information amount, easy expansion and update, and the like. And the photoelectric converter is used as the main equipment for the broadband access of the Ethernet, so that the market demand is large. The photoelectric converter capable of remotely monitoring the working environment has wider requirement prospect, and can provide an intelligent optical communication product with domestic leading level and independent intellectual property rights for the construction of the national optical fiber communication network. Telecommunication operators can conveniently maintain equipment, reduce labor cost, improve working efficiency and save energy and reduce emission by remotely monitoring the photoelectric converter of the working environment;

however, the existing photoelectric converter is limited by the size of the converter, so that the slot position arrangement is often less, large-scale conversion is inconvenient, and meanwhile, when the photoelectric converter fails and is powered off, the background system cannot know the position and fault information of the failed photoelectric converter at the first time, so that the maintenance is delayed.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a simple structure, can realize multislot position photoelectric converter that multislot position is connected.

The technical scheme adopted for realizing the type is as follows:

a multi-slot photoelectric converter comprises a main control end, a slot connecting end and a state monitor;

the main control end is arranged behind the notch connecting end and is electrically connected with the notch connecting end, the state monitor is arranged above the notch connecting end and is connected with the main control end, and the notch connecting end and the state monitor are also wirelessly connected with the background controller;

the notch connecting end comprises a fixed shell, at least one twisted pair interface, an optical fiber interface module and a conversion module;

the conversion module is arranged in the fixed shell and connected with the main control end, and the twisted pair interface and the optical fiber interface module are arranged on the side edge of the fixed shell and connected with the conversion module.

Furthermore, the optical fiber interface module comprises a status indicator light and an optical fiber interface;

and the status indicator lamp is connected with each output pin of the optical fiber interface.

Furthermore, the main control end and the notch connecting end are detachably fixed together.

Further, the main control end comprises a main control shell, a control module, at least one radio frequency antenna, a power supply interface and an equipment switch;

the control module set up in the main control shell, the radio frequency antenna sets up main control shell top and with the control module group links to each other, the power supply interface and the equipment switch sets up one side of main control shell and with the control module group links to each other.

Further, the state monitor comprises a monitor shell, a radio frequency antenna, a storage battery module, a state acquisition module, a key input module and a display module;

the state acquisition module sets up in the watch-dog shell and with the control module links to each other, the battery module sets up in the watch-dog shell and with the state acquisition module links to each other, radio frequency antenna the key input module and the display module all sets up on the watch-dog shell and with the state acquisition module links to each other.

Furthermore, the notch connecting end also comprises a working state display module;

the working state display module is arranged on the fixed shell and connected with the conversion module.

Further, the main control end also comprises a heat dissipation opening;

the heat dissipation opening is arranged on one side of the main control shell.

The utility model adopts the structure, realizes the simultaneous setting and signal conversion of a plurality of notches by arranging the notch connecting end and arranging the twisted pair interface, the optical fiber interface module and the conversion module on the notch connecting end, solves the problems that the photoelectric converter in the prior art is limited by the volume of the converter, so that the arrangement of the slots is often less and the large-scale conversion is inconvenient, and the design of the notch connecting end and the main control end in a separated way can lead a user to select the notch connecting end with the corresponding number of notches for use according to the self requirement, improves the flexibility of the user to use, and realizes that the state monitor can normally run and sends the working state of the main control end to the background control terminal when the main control end and the notch connecting end stop running by arranging the state monitor to independently acquire the working state of the main control end, the problem of among the prior art simultaneously when the photoelectric converter breaks down the outage, backstage system often can't learn trouble photoelectric converter's position and trouble information the very first time, has caused the delay to the maintenance is solved.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of a multi-slot photoelectric converter according to the present invention;

fig. 2 is a side view of a slot connection end in an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a main control end in an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a state monitor according to an embodiment of the present invention;

fig. 5 is a schematic circuit diagram of a conversion module according to an embodiment of the present invention;

fig. 6 is a schematic circuit diagram of a control module according to an embodiment of the present invention;

fig. 7 is a schematic structural diagram of a state acquisition module according to an embodiment of the present invention;

the number designations in the figures are: 10-a main control end, 20-a notch connecting end, 30-a state monitor, 21-a fixed shell, 22-a twisted pair interface, 23-an optical fiber interface module, 24-a conversion module, 231-a state indicator lamp, 232-an optical fiber interface, 11-a main control shell, 12-a control module, 13-a first radio frequency antenna, 14-a power supply interface, 15-an equipment switch, 31-a monitor shell, 32-a second radio frequency antenna, 33-a storage battery module, 34-a state acquisition module, 35-a key input module, 36-a display module, 25-a working state display module and 16-a heat dissipation opening.

Detailed Description

The following describes the present invention with reference to the accompanying drawings. It should be noted that the description of the embodiments is provided to help understanding of the present invention, but the present invention is not limited thereto. In addition, the technical features related to the embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other.

A multi-slot photoelectric converter is shown in FIG. 1, and includes a main control end 10, a slot connection end 20 and a status monitor 30;

the main control end 10 is arranged behind the notch connecting end 20 and is electrically connected with the notch connecting end, the state monitor 30 is arranged above the notch connecting end 20 and is connected with the main control end 10, and the notch connecting end 20 and the state monitor 30 are also wirelessly connected with the background controller;

the notch connection end 20 is used for connecting an external optical fiber line and a twisted pair and performing signal conversion;

the main control end 10 is used for acquiring a control signal sent by the background controller and controlling the notch connection end 20 to perform signal conversion according to the control signal;

the state monitor 30 is used for acquiring the running state information of the state monitor 30 and sending the running state information to the background controller;

as shown in fig. 1, 2 and 5, the slot connection end 20 includes a fixed housing 21, at least one twisted pair interface 22, an optical fiber interface module 23 and a conversion module 24;

the conversion module 24 is arranged in the fixed shell 21 and connected with the main control end 10, and the twisted pair interface 22 and the optical fiber interface module 23 are arranged on the side edge of the fixed shell 21 and connected with the conversion module 24;

the twisted-pair interface 22 is used for fixedly connecting twisted-pairs;

the optical fiber interface module 23 is used for fixing the connected optical fiber data line;

the conversion module 24 is used for converting signals.

Further, as shown in fig. 2, the optical fiber interface module 23 includes a status indicator light 231 and an optical fiber interface 232;

the status indicator light 231 is connected with each output pin of the optical fiber interface 232;

the status indicator light 231 is used for displaying the connection status of the optical fiber data line inserted on the optical fiber interface 232.

Further, the main control end 10 and the notch connecting end 20 are detachably fixed together.

Further, as shown in fig. 3 and fig. 6, the main control terminal 10 includes a main control housing 11, a control module 12, at least one first radio frequency antenna 13, a power supply interface 14, and an equipment switch 15;

the control module 12 is arranged in the main control shell 11, the first radio frequency antenna 13 is arranged above the main control shell 11 and connected with the control module 12, and the power supply interface 14 and the equipment switch 15 are arranged on one side of the main control shell 11 and connected with the control module 12;

the control module 12 is configured to obtain a control signal sent by the background controller through the first rf antenna 13, and control the conversion module 24 to perform data conversion according to the control signal.

Further, as shown in fig. 4 and 7, the status monitor 30 includes a monitor housing 31, a second rf antenna 32, a storage battery module 33, a status acquiring module 34, a key input module 35, and a display module 36;

the state acquisition module 34 is arranged in the monitor shell 31 and connected with the control module 12, the storage battery module 33 is arranged in the monitor shell 31 and connected with the state acquisition module 34, and the second radio frequency antenna 32, the key input module 35 and the display module 36 are all arranged on the monitor shell 31 and connected with the state acquisition module 34;

the state acquiring module 34 is configured to acquire the working state information of the control module 12 and not send the working state information to the background controller through the second rf antenna 32;

the state acquiring module 34 is further configured to determine that when the control module 12 stops working, the state acquiring module sends position information and an alarm signal to the background controller;

the battery module 33 is used to supply power to the state monitor 30, so as to prevent the state monitor 30 from being terminated when the operation is terminated due to the operational failure of the main control terminal 10 and the slot connection terminal 20.

Further, as shown in fig. 1, the notch connection end 20 further includes an operating state display module 25;

the working state display module 25 is arranged on the fixed shell 21 and connected with the conversion module 24;

the working state display module 25 is used for acquiring the working state of the conversion module 24 and displaying the working state accordingly.

Further, as shown in fig. 3, the main control terminal 10 further includes a heat dissipation opening 16;

the heat dissipation opening 16 is arranged on one side of the main control shell 11;

the heat dissipation opening 16 is used to dissipate heat from the main control housing 11.

In a specific application scenario of the present invention, before the user uses the present invention, the user first selects the notch connection end 20 with the appropriate number of notches to install on the main control end 10, then connects the optical fiber connection line and the twisted pair line to the notch connection end 20 and presses the device switch 15, at which point the present invention starts to operate, the control module 12 acquires the control signal sent by the background controller through the first rf antenna 13, and controls the conversion module 24 to perform data conversion according to the control signal, meanwhile, the working state display module 25 obtains the working state of the conversion module 24 and displays the working state accordingly, the state monitor 30 obtains the working state information of the control module 12 and transmits the working state information to the background controller through the second rf antenna 32 instead of the first rf antenna, thereby it is right to realize the user in background controller department the utility model discloses a signal conversion and operating condition information's control.

The utility model discloses in another applied scene, the operational failure appears in main control end 10 and notch link 20 and leads to the operation to terminate, and state monitor 30 judges control module 12 stop work this moment, then to the backstage controller sends positional information and alarm signal to the messenger reminds the user in time to maintain.

The embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to the described embodiments. It will be apparent to those skilled in the art that various changes, modifications, substitutions and alterations can be made in the embodiments without departing from the principles and spirit of the invention, and the scope of the invention is to be accorded the full scope of the claims.

Claims (7)

1. A multi-slot photoelectric converter is characterized by comprising a main control end, a slot connecting end and a state monitor;

the main control end is arranged behind the notch connecting end and is electrically connected with the notch connecting end, the state monitor is arranged above the notch connecting end and is connected with the main control end, and the notch connecting end and the state monitor are also wirelessly connected with the background controller;

the notch connecting end comprises a fixed shell, at least one twisted pair interface, an optical fiber interface module and a conversion module;

the conversion module is arranged in the fixed shell and connected with the main control end, and the twisted pair interface and the optical fiber interface module are arranged on the side edge of the fixed shell and connected with the conversion module.

2. The multiple slot optoelectronic converter of claim 1, wherein the optical fiber interface module comprises a status indicator light and an optical fiber interface;

and the status indicator lamp is connected with each output pin of the optical fiber interface.

3. The multiple slot optoelectronic transducer of claim 1, wherein said master terminal and said slot connection terminal are removably secured together.

4. The multi-slot photoelectric converter according to claim 1, wherein the master control end comprises a master control housing, a control module, at least one radio frequency antenna, a power supply interface, and an equipment switch;

the control module set up in the main control shell, the radio frequency antenna sets up main control shell top and with the control module group links to each other, the power supply interface and the equipment switch sets up one side of main control shell and with the control module group links to each other.

5. The multi-slot photoelectric converter according to claim 4, wherein the status monitor comprises a monitor housing, a radio frequency antenna, a storage battery module, a status acquisition module, a key input module and a display module;

the state acquisition module sets up in the watch-dog shell and with the control module links to each other, the battery module sets up in the watch-dog shell and with the state acquisition module links to each other, radio frequency antenna the key input module and the display module all sets up on the watch-dog shell and with the state acquisition module links to each other.

6. The multiple slot photoelectric converter of claim 1, wherein the slot connection end further comprises an operating state display module;

the working state display module is arranged on the fixed shell and connected with the conversion module.

7. The multiple slot optoelectronic converter of claim 4, wherein said master control end further comprises a heat dissipation opening;

the heat dissipation opening is arranged on one side of the main control shell.

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