CN220087278U - Transceiver with enhanced network signal structure - Google Patents

Abstract

The present utility model relates to the field of transceivers, and in particular, to a transceiver with an enhanced network signal structure. The technical proposal comprises: the transceiver comprises a transceiver host, wherein a host circuit board is arranged in the transceiver host, slots for plugging network cables and optical fiber cables are arranged at the front end of the transceiver host, radiating holes are formed in two sides of the transceiver host, a ventilation frame is fixed between the radiating holes in the transceiver host, a radiating channel penetrating through the ventilation frame is formed in the ventilation frame, two ends of the radiating channel are aligned with the radiating holes, connecting holes are formed in the bottom of the radiating channel and in positions corresponding to the host circuit board, and a group of jacks are formed in the middle position of the top of the radiating channel. According to the utility model, the radiating channel is arranged in the transceiver host, the detachable electrostatic rod is arranged in the channel, the electrostatic rod is utilized to adsorb the entering dust, and the situation of light attenuation caused by adhesion of the dust on the circuit board is avoided, so that the purpose of enhancing the network signal is realized.

Description

Transceiver with enhanced network signal structure

Technical Field

The present utility model relates to the field of transceivers, and in particular, to a transceiver with an enhanced network signal structure.

Background

The application of transceivers in networks belongs to an optical-to-electrical converter, which converts an optical signal connected to a transceiver into an electrical signal, or converts an electrical signal into an optical signal, and is generally applied in an actual network environment where an ethernet cable cannot cover and an optical fiber must be used to extend a transmission distance.

In actual conversion process, the optical fiber signal is receiving the condition such as extrusion buckling, temperature variation is great and dust is attached, all can appear the condition of light decay, if avoid, can lead to the network signal after the conversion to weaken setting and can't be connected to the network signal, to transceiver, the optical fiber tip is located the protection that has the shell in the transceiver shell, the condition of extrusion buckling can not appear, to temperature variation, can open inside radiator fan at the during operation, guarantee operating temperature's constancy, consequently, avoid the photoelectric conversion of transceiver to appear the condition of light decay, need carry out strict dustproof to its inside, avoid the light decay that the dust gets into and lead to, and then realize strengthening the mesh of network signal, especially, be directed against the dustproof of louvre department.

Disclosure of Invention

The present utility model aims to solve the problems in the background art and to provide a transceiver with an enhanced network signal structure.

The technical scheme of the utility model is as follows: the transceiver with the reinforced network signal structure comprises a transceiver host, a host circuit board is arranged in the transceiver host, slots for plugging network cables and optical fiber cables are arranged at the front end of the transceiver host, radiating holes are formed in two sides of the transceiver host, a ventilating frame is fixed between the radiating holes in the transceiver host, a radiating channel penetrating through the ventilating frame is formed in the ventilating frame, two ends of the radiating channel are aligned with the radiating holes, a connecting hole is formed in the bottom of the radiating channel and at a position corresponding to the host circuit board, a group of jacks are formed in the middle position of the top of the radiating channel, mounting holes are formed in the upper end of the transceiver host and at positions corresponding to the jacks, a sealing plate is arranged in the mounting holes, an electrostatic rod is arranged at the bottom of the sealing plate and at positions corresponding to the jacks, and the lower end of the electrostatic rod penetrates through the jacks and is positioned in the ventilating frame.

Preferably, both ends of the ventilation frame can be fixed with dustproof nets, so that the possibility that external dust enters the transceiver host is reduced.

Preferably, four corners of the sealing plate are fixed in the mounting holes through screws, sealing rings are fixed on the periphery of the sealing plate, the sealing plate can be detached for mounting by means of mounting of the screws, and tightness after mounting can be guaranteed by means of the sealing rings.

Preferably, a power supply box is fixed in the middle of the upper end of the sealing plate, a power supply device for supplying electric energy to the electrostatic rod is installed in the power supply box, and the electric energy can be supplied to the electrostatic rod by utilizing the power supply device in the power supply box, so that static electricity is generated and dust is adsorbed.

Preferably, a top plate is fixed at the center of the bottom of the sealing plate, the electrostatic rod is fixed at the bottom of the top plate, the bottom of the top plate is propped against the upper end of the ventilation frame, and the opening at the upper end of the jack can be sealed after the electrostatic rod is inserted into the ventilation frame.

Preferably, the bottom of the ventilation frame and the position corresponding to the connecting hole are provided with a heat dissipation fan, so that the air flow speed in the transceiver host can be increased, and the heat dissipation purpose is further realized.

Compared with the prior art, the utility model has the following beneficial technical effects: the heat dissipation channel is arranged in the transceiver host, the detachable electrostatic rod is arranged in the channel, the electrostatic rod is utilized to adsorb the entering dust, and the situation that the dust is attached to the circuit board to cause light attenuation is avoided, so that the purpose of enhancing network signals is realized.

Drawings

FIG. 1 is a schematic diagram of an assembly structure of a sealing plate and a transceiver host according to the present utility model;

FIG. 2 is a schematic view of the front cut-away structure of the present utility model;

FIG. 3 is a schematic view of the internal structure of the ventilating frame according to the present utility model;

FIG. 4 is a schematic view of the bottom structure of the sealing plate of the present utility model.

Reference numerals: 1. a transceiver host; 11. a host circuit board; 12. a heat radiation hole; 13. a mounting hole; 2. a ventilation frame; 21. a dust screen; 22. a connection hole; 23. a jack; 3. a sealing plate; 31. an electrostatic wand; 32. a seal ring; 33. a power supply box; 34. and a top plate.

Detailed Description

The technical scheme of the utility model is further described below with reference to the attached drawings and specific embodiments.

Examples

As shown in fig. 1-4, the transceiver with the network signal strengthening structure provided by the utility model comprises a transceiver host 1, a host circuit board 11 is installed in the transceiver host 1, slots for plugging network wires and optical fiber wires are installed at the front end of the transceiver host 1, heat dissipation holes 12 are formed at both sides of the transceiver host 1, a ventilation frame 2 is fixed between the heat dissipation holes 12 in the transceiver host 1, a heat dissipation channel penetrating through the ventilation frame 2 is formed in the ventilation frame 2, both ends of the heat dissipation channel are aligned with the heat dissipation holes 12, a connecting hole 22 is formed at the bottom of the heat dissipation channel and at a position corresponding to the host circuit board 11, a group of jacks 23 are formed at the middle position of the top of the heat dissipation channel, a mounting hole 13 is formed at the upper end of the transceiver host 1 and at a position corresponding to the jacks 23, a sealing plate 3 is installed in the mounting hole 13, an electrostatic rod 31 is installed at the bottom of the sealing plate 3 and at a position corresponding to the jacks 23, the lower end of the electrostatic rod 31 penetrates through the jacks 23 and is located in the ventilation frame 2, and a heat dissipation fan is installed at the bottom of the ventilation frame 2 and at a position corresponding to the connecting hole 22.

The dust screen 21 can both be fixed with at ventilation frame 2 both ends, seal plate 3 four corners passes through the screw fixation in mounting hole 13 and the periphery is fixed with sealing washer 32, utilize the dismantlement to the screw on the seal plate 3, can demolish seal plate 3 from mounting hole 13 in, simultaneously can take out static stick 31 from ventilation frame 2, can concentrate the clearance to the dust on the static stick 31 this moment, guarantee the normal use of static stick 31, seal plate 3 upper end intermediate position is fixed with power box 33, install the power supply unit who provides electric energy for static stick 31 in the power box 33, seal plate 3 bottom central point puts and is fixed with roof 34, static stick 31 is fixed in roof 34 bottom, roof 34 bottom offsets with ventilation frame 2 upper end.

In this embodiment, firstly, the transceiver host 1 is connected to an external power supply, when in operation, the optical fiber wire and the network wire are only required to be respectively inserted into the corresponding slots, at this time, the heat dissipation fan is opened to operate, heat in the transceiver host 1 can be discharged, and then the purpose of keeping the working temperature constant in the transceiver host 1 is achieved, meanwhile, when the operation is stopped, some fine dust outside can pass through the heat dissipation holes 12 to enter the ventilation frame 2, at this time, the power supply equipment in the power supply box 33 can be utilized to supply electric energy to the electrostatic rod 31, so that static electricity is generated, further, fine dust can be adsorbed, the dust is prevented from adhering to the host circuit board 11 through the connecting holes 22, light attenuation caused by dust is avoided, the purpose of strengthening network signals is achieved, on the basis, the sealing plate 3 can be removed from the mounting holes 13 by disassembling screws on the sealing plate 3, meanwhile, the electrostatic rod 31 can be pumped out of the ventilation frame 2, the electrostatic rod 31 can be cleaned up in a concentrated manner, and normal use of the electrostatic rod 31 is ensured.

The above-described embodiments are merely a few preferred embodiments of the present utility model, and many alternative modifications and combinations of the above-described embodiments will be apparent to those skilled in the art based on the technical solutions of the present utility model and the related teachings of the above-described embodiments.

Claims (6)

1. Transceiver with strengthen network signal structure, including transceiver host computer (1), install host circuit board (11) in transceiver host computer (1), the slot that is used for net twine and optic fibre line grafting is installed to transceiver host computer (1) front end, its characterized in that: the transceiver host computer (1) both sides have all been seted up louvre (12), just be located in transceiver host computer (1) and be fixed with ventilation frame (2) between louvre (12), set up the heat dissipation passageway that runs through ventilation frame (2) in ventilation frame (2), heat dissipation passageway both ends and louvre (12) align, connecting hole (22) have been seted up in heat dissipation passageway bottom and with host circuit board (11) corresponding position, a set of jack (23) have been seted up to heat dissipation passageway top intermediate position, mounting hole (13) have been seted up in transceiver host computer (1) upper end and with jack (23) corresponding position, install closing plate (3) in mounting hole (13), electrostatic wand (31) are installed to closing plate (3) bottom and with jack (23) corresponding position, electrostatic wand (31) lower extreme passes jack (23) and is located ventilation frame (2).

2. Transceiver with enhanced network signalling structure according to claim 1, characterized in that the ventilation frame (2) can be fixed with dust screens (21) at both ends.

3. Transceiver with reinforced network signal structure according to claim 1, characterized in that the four corners of the sealing plate (3) are fixed in the mounting holes (13) by screws and the periphery is fixed with sealing rings (32).

4. Transceiver with reinforced network signal structure according to claim 1, characterized in that a power supply box (33) is fixed in the middle of the upper end of the sealing plate (3), and a power supply device for supplying electric energy to the electrostatic rod (31) is installed in the power supply box (33).

5. Transceiver with reinforced network signal structure according to claim 1, characterized in that the top plate (34) is fixed in the central position of the bottom of the sealing plate (3), the electrostatic rod (31) is fixed at the bottom of the top plate (34), and the bottom of the top plate (34) is abutted against the upper end of the ventilation frame (2).

6. Transceiver with reinforced network signal structure according to claim 1, characterized in that a heat sink is mounted at the bottom of the ventilation frame (2) in correspondence of the connection holes (22).