CN213072650U - Transceiver with good stability - Google Patents

Abstract

The utility model provides a transceiver with good stability, which belongs to the technical field of transceivers, and comprises a transceiver box body, an optical module structure, a dynamic monitoring component and a heat dissipation component, wherein a transceiver mainboard is fixed inside the transceiver box body, a power wire is fixed at one end of the transceiver box body, a network cable interface is arranged at one side of the power wire, the dynamic monitoring component and the dynamic monitoring component are fixed on the transceiver mainboard and are arranged close to the network cable interface end, the network cable interface is connected with a network cable connector fixed on the transceiver mainboard, the network cable connector is connected to the dynamic monitoring component, the optical module structure is fixed on the transceiver mainboard and is far away from the dynamic monitoring component, and the heat dissipation component is rotationally connected to two sides of the transceiver box body; this transceiver restarts the transceiver automatically, effectively ensures the stability of equipment, and the heating panel can be opened simultaneously, and the heat dissipation is exceeded, guarantees that the transceiver normally works.

Description

Transceiver with good stability

Technical Field

The utility model belongs to the technical field of the transceiver, concretely relates to good transceiver of stability.

Background

A transceiver is a device for signal conversion, and is generally referred to as a fiber optic transceiver. The optical fiber transceiver converts twisted pair electrical signals and optical signals to each other, ensures smooth transmission of data packets between two networks, and extends the transmission distance limit of the networks from 100 meters of copper wires to 100 kilometers.

The optical fiber transceiver is an ethernet transmission medium conversion unit that exchanges short-distance twisted pair electrical signals and long-distance optical signals, and is also called an optical-electrical converter, and is generally applied in a practical network environment where ethernet cables cannot cover and optical fibers must be used to extend transmission distance, and is generally located in an access layer application of a broadband metropolitan area network.

The optical transceiver in the prior art is easy to hang up because the optical transceiver is not restarted after long-time operation, and the transceiver cannot be stably operated.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a transceiver that stability is good aims at solving the problem among the prior art.

In order to achieve the above object, the utility model provides a following technical scheme: the optical module structure is fixed on the transceiver mainboard, the dynamic monitoring component and the heat dissipation component are connected to two sides of the transceiver box body in a rotating mode.

As an optimal solution of the present invention, the transceiver box is close to the optical module structure end is provided with a connector.

As an optimized scheme, the dynamic monitoring subassembly is including fixing the dynamic flow load sensor chip of transceiver mainboard upper end, dynamic flow load sensor chip both ends are fixed with connecting wire, and one end is connected to the net twine connector, and the other end is connected to optical module structure.

Adopt above-mentioned scheme: the transceiver is easy to hang up because of no restarting after long-time operation, a dynamic flow load sensor chip is arranged in the transceiver, and the transceiver is automatically restarted when a detection link detects that no flow passes through the transceiver, so that the stability of the equipment is guaranteed.

As a preferred scheme, radiator unit is including seting up the logical groove of transceiver box body both sides, the logical inslot portion rotates and is connected with the heating panel, has seted up a plurality of through-holes along heating panel length direction on the heating panel, and the heating panel both ends are passed through the containing part and are connected at logical inslot portion.

As an optimized scheme, the containing part is including rotating the head rod of connection at leading to groove both sides wall top, and the head rod is kept away from the turning point and is rotated and be connected with the second connecting rod, and the fastening is rotated between head rod and the second connecting rod and is connected, and the second connecting rod other end is rotated and is connected in leading to groove both sides wall bottom department, second connecting rod side fixed connection to the heating panel.

Adopt above-mentioned scheme: when the transceiver box body dispels the heat, can open the heating panel and dispel the heat, through rotating head rod and second connecting rod, rotate the heating panel along leading to the groove to being certain angle with leading to the groove, dispel the heat from through-hole and two directions that lead to the groove, the radiating effect is good, and head rod and second connecting rod can be accomodate simultaneously, and when the transceiver box body was carried, the heating panel can be accomodate, does not occupy unnecessary space.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the transceiver with good stability is provided with a dynamic monitoring component which comprises a dynamic flow load sensor chip fixed at the upper end of a transceiver mainboard, wherein connecting wires are fixed at two ends of the dynamic flow load sensor chip, one end of the dynamic flow load sensor chip is connected to a network cable connector, and the other end of the dynamic flow load sensor chip is connected to an optical module structure; the transceiver is easy to hang up because of no restarting after long-time operation, a dynamic flow load sensor chip is arranged in the transceiver, and the transceiver is automatically restarted when a detection link detects that no flow passes through the transceiver, so that the stability of the equipment is guaranteed.

2. The transceiver with good stability is provided with a heat dissipation assembly which comprises through grooves formed in two sides of a transceiver box body, a heat dissipation plate is rotatably connected inside each through groove, a plurality of through holes are formed in the heat dissipation plate along the length direction of the heat dissipation plate, two ends of the heat dissipation plate are connected inside each through groove through a containing part, each containing part comprises a first connecting rod rotatably connected to the tops of two side walls of each through groove, each first connecting rod is rotatably connected with a second connecting rod far away from a rotating point, each first connecting rod and each second connecting rod are fixedly and rotatably connected, the other end of each second connecting rod is rotatably connected to the bottom of the two side walls of each through groove, the side faces of each second connecting rod are fixedly connected to the heat dissipation plate, when the transceiver box body dissipates heat, the heat dissipation plate can be opened to dissipate heat, the heat can be rotated to, the radiating effect is good, and simultaneously head rod and second connecting rod can be accomodate, and when the transceiver box body carried, the heating panel can be accomodate, does not occupy unnecessary space.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 is a schematic structural view of the present invention;

fig. 2 is a schematic diagram of a power supply lead side structure of the present invention;

fig. 3 is a schematic view of the internal structure of the transceiver box of the present invention;

in the figure: 1. a transceiver box; 2. an optical module structure; 3. a dynamic monitoring component; 4. a heat dissipating component; 5. a transceiver motherboard; 6. a power supply lead; 7. a network cable interface; 8. a network cable connector; 9. a connecting port; 10. a dynamic flow load sensor chip; 11. connecting a lead; 12. a through groove; 13. a heat dissipation plate; 14. a through hole; 15. a first connecting rod; 16. a second connecting rod.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Examples

Referring to fig. 1-3, the present invention provides the following technical solutions: including transceiver box body 1, optical module structure 2, dynamic monitoring subassembly 3, radiator unit 4, 1 inside transceiver mainboard 5 that is fixed with of transceiver box body, 1 one end of transceiver box body is fixed with power wire 6, and 6 one sides of power wire are equipped with net twine interface 7, fixes on the transceiver mainboard 5 dynamic monitoring subassembly 3, dynamic monitoring subassembly 3 are close to net twine interface 7 end setting, and net twine interface 7 is connected with the net twine connector 8 of fixing on transceiver mainboard 5, and net twine connector 8 is connected to dynamic monitoring subassembly 3, optical module structure 2 are fixed keep away from dynamic monitoring subassembly 3 setting on the transceiver mainboard 5, and radiator unit 4 rotates to be connected in 1 both sides of transceiver box body.

Specifically, a connector 9 is disposed at the end of the transceiver box 1 close to the optical module structure 2.

Specifically, the dynamic monitoring component 3 includes a dynamic flow load sensor chip 10 fixed on the upper end of the transceiver motherboard 5, two ends of the dynamic flow load sensor chip 10 are fixed with connecting wires 11, one end is connected to the network cable connector 8, and the other end is connected to the optical module structure 2.

Specifically, radiator unit 4 is including seting up logical groove 12 of 1 both sides of transceiver box body, and the internal rotation of logical groove 12 is connected with heating panel 13, has seted up a plurality of through-holes 14 along heating panel 13 length direction on heating panel 13, and heating panel 13 both ends are passed through the receiving part and are connected inside logical groove 12.

Specifically, the containing part is including rotating the head rod 15 of connecting at leading to 12 both sides wall tops of groove, head rod 15 is kept away from the pivot point and is rotated and be connected with second connecting rod 16, the fastening is rotated and is connected between head rod 15 and the second connecting rod 16, the 16 other ends of second connecting rod are rotated and are connected in leading to 12 both sides wall bottoms department, 16 side fixed connection of second connecting rod to heating panel 13, head rod 15 and second connecting rod 16 can rotate, simultaneously can rotate heating panel 13 along leading to the groove to be certain angle with leading to groove 12, the rotation between head rod 15 and the second connecting rod 16 is the fastening formula and rotates, heating panel 13 is under the no exogenic action of open mode, can not accomodate automatically.

The utility model discloses a theory of operation and use flow: when the optical fiber load sensor is used, the optical fiber is connected to a network cable interface 7, the power supply is communicated through a power supply lead 6, an output network cable is connected to a connector 9, and when the transceiver works, if the transceiver does not restart for a long time, the dynamic flow load sensor chip 10 of a colleague restarts when no flow is detected to pass through a detection link; when the transceiver box body 1 dissipates heat, the heat dissipation plate 13 can be opened to dissipate heat, and the heat dissipation plate 13 is rotated to a certain angle with the through groove 12 along the through groove by rotating the first connecting rod 15 and the second connecting rod 16, so that heat dissipation is performed from two directions of the through hole 14 and the through groove 12.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (5)

1. A transceiver with good stability is characterized by comprising a transceiver box body (1), a light module structure (2), a dynamic monitoring component (3) and a heat dissipation component (4), wherein a transceiver mainboard (5) is fixed in the transceiver box body (1), a power supply lead (6) is fixed at one end of the transceiver box body (1), a network cable interface (7) is arranged at one side of the power supply lead (6), the dynamic monitoring component (3) is fixed on the transceiver mainboard (5), the dynamic monitoring component (3) is arranged close to the network cable interface (7), the network cable interface (7) is connected with a network cable connector (8) fixed on the transceiver mainboard (5), the network cable connector (8) is connected to the dynamic monitoring component (3), the light module structure (2) is fixed on the transceiver mainboard (5) and is arranged far away from the dynamic monitoring component (3), the heat dissipation assembly (4) is rotatably connected to two sides of the transceiver box body (1).

2. The transceiver with good stability according to claim 1, wherein the transceiver box (1) is provided with a connection port (9) near the optical module structure (2).

3. The transceiver with good stability according to claim 1, wherein the dynamic monitoring component (3) comprises a dynamic flow load sensor chip (10) fixed on the upper end of the transceiver motherboard (5), and the dynamic flow load sensor chip (10) has two ends fixed with a connecting wire (11), one end connected to the network cable connector (8) and the other end connected to the optical module structure (2).

4. The transceiver with good stability according to claim 1, wherein the heat dissipation assembly (4) comprises through grooves (12) formed in two sides of the transceiver box body (1), a heat dissipation plate (13) is rotatably connected inside the through grooves (12), a plurality of through holes (14) are formed in the heat dissipation plate (13) along the length direction of the heat dissipation plate (13), and two ends of the heat dissipation plate (13) are connected inside the through grooves (12) through accommodating parts.

5. The transceiver with good stability according to claim 4, wherein the receiving member comprises a first connecting rod (15) rotatably connected to the top of the two side walls of the through slot (12), a second connecting rod (16) rotatably connected to the first connecting rod (15) away from the rotation point, the first connecting rod (15) and the second connecting rod (16) are fastened and rotatably connected, the other end of the second connecting rod (16) is rotatably connected to the bottom of the two side walls of the through slot (12), and the side of the second connecting rod (16) is fixedly connected to the heat dissipation plate (13).

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