CN219496743U - Optical fiber module switching device - Google Patents

Abstract

The utility model provides an optical fiber module switching device which comprises a switching device body, wherein the switching device body comprises a top plate, a partition plate, a bottom plate, a heat radiation module and a shielding assembly, interlayers are arranged between the top plate and the partition plate and between the partition plate and the bottom plate, the heat radiation module is arranged at the middle positions of the top plate and the bottom plate, through holes are formed in the surfaces of the partition plates, the shielding assembly is inserted into the through holes, the shielding assembly is provided with a plurality of uniformly distributed on the side edges of an inserting port, the whole optical fiber module switching device is in a columnar structure, two interlayer areas are formed on the outer side through the middle partition plate, the arrangement of wire parts is facilitated through the interlayer areas, the stability of connection is improved, the heat radiation module is arranged at the top and the bottom of a shell, the heat radiation module is connected through a middle spring and a screw rod, and the heat radiation module can be compressed into the inside when the optical fiber module switching device is not used, so that the occupied space is reduced.

Description

Optical fiber module switching device

Technical Field

The utility model relates to the technical field of communication equipment, in particular to an optical fiber module switching device.

Background

The optical fiber module consists of an optoelectronic device, a functional circuit, an optical interface and the like, wherein the optoelectronic device comprises a transmitting part and a receiving part, and after the electric signal plug is connected with the switching device, the electric signal plug can be connected with equipment such as a switch and a router at the rear end by means of wires, and the function of communication transmission is realized. According to the technical scheme disclosed in the prior art, according to the optical fiber module switching device described in the chinese patent document CN202221142927.5, on the basis of the original heat dissipation holes of the switching box, a graphene patch, a copper-aluminum alloy heat conduction plate and a copper-aluminum alloy heat dissipation plate are additionally arranged on the lower surface of the switching box, and the graphene patch conducts heat to the switching box, so that the heat dissipation performance and the use effect are improved.

According to the technical scheme disclosed by the utility model, after the optical fiber module is connected with the switching device in the prior art, other wires can be directly used for connecting the switching device for use, because the optical signal interface of the optical fiber module needs to be connected with the optical fiber wires, and the overlong optical fiber cable can only be stored in a manual bending mode, the optical fiber is easy to bend, the transmission of optical signals is affected, the conventional switching device cannot store the wires, and on the other hand, the existing switching device lacks an effective buffer protection function.

Disclosure of Invention

Aiming at the defects existing in the prior art, the utility model aims to provide the optical fiber module switching device which solves the problems in the background art, can roll up the optical fiber and the network cable, is convenient to arrange and store, has higher protection effect, can freely fold a heat dissipation structure, and reduces the whole volume.

In order to achieve the above object, the present utility model is realized by the following technical scheme: the utility model provides a fiber optic module switching device, includes the switching device body, the switching device body includes roof, baffle, bottom plate, heat dissipation module and shelters from the subassembly, all be provided with the intermediate layer between roof and the baffle and between baffle and the bottom plate, the grafting port has been seted up to the intermediate layer inboard, heat dissipation module has all been installed to the intermediate position department of roof and bottom plate, the through-hole has been seted up on the surface of baffle, the inside of through-hole alternates and has shelters from the subassembly, shelter from the subassembly and be provided with a plurality of and even distribution at the side of grafting port.

Further, the heat radiation module comprises an end cover and a coaming, wherein the coaming is fixedly arranged on the inner side of the end cover, heat radiation holes are formed in the surface of the coaming, and screws are inserted into the end cover.

Further, screw holes and hidden grooves are formed in the end portions of the coaming, the screw rod penetrates through the screw holes, and an adjusting knob is mounted on the top of the screw rod.

Further, the bounding wall is provided with two, and two bounding walls penetrate inside from the intermediate position of roof and bottom plate respectively, and two bounding walls are connected through the screw rod.

Furthermore, the inside of hiding the recess is inlayed and is equipped with the spring, the both ends of spring respectively with the innermost fixed connection of hiding the recess on two bounding walls, the spring is provided with a plurality ofly, and the spring is installed in the both sides of screw rod with the form of symmetry.

Further, shelter from the subassembly and include telescopic link and telescopic sleeve, first magnet board is installed to telescopic sleeve's bottom, telescopic sleeve's inside is inserted to telescopic link's bottom.

Further, the second magnet board is installed at the top of telescopic link, the inboard of roof and bottom plate all inlays and is equipped with the third magnet board, and every third magnet board all is in same perpendicular line with corresponding shielding assembly.

Further, the length of the telescopic sleeve is larger than the width of the interlayer, the telescopic sleeve passes through the inside of the through hole, and the inner diameter of the through hole is the same as the surface diameter of the telescopic sleeve.

The utility model has the beneficial effects that: the utility model relates to an optical fiber module switching device which comprises a switching device body, wherein the switching device body comprises a top plate, a partition plate, a bottom plate, an interlayer, an inserting port, a shielding assembly, a heat dissipation module, an end cover, a coaming, a heat dissipation hole, a screw, an adjusting knob, a spring, a threaded hole, a telescopic sleeve, a first magnet plate, a telescopic rod, a second magnet plate, a third magnet plate, a through hole and a hidden groove.

The optical fiber module switching device is integrally in a columnar structure, two interlayer areas are formed on the outer side through the middle partition board, and the optical fiber cable connected with the other end of the optical fiber module and the network cable connected with the switching device can be wound and stored through the interlayer areas, so that the wire parts are conveniently tidied, and the connection stability is improved.

This fiber module switching device all installs heat dissipation module at the top and the bottom of shell, and two sets of heat dissipation module are connected through middle spring and screw rod, can control the connected state between two heat dissipation module through rotating the screw rod, and then expand when using and realize the radiating effect, and then compress heat dissipation module to the inside of shell when not using and reduce occupation space.

This fiber module switching device installs a plurality of shielding components in the outside, and every shielding component homoenergetic is controlled its flexible length and is located the position, can establish in the outside after coiling different wire rods through this structure, shelters from the wire rod of coiling completion, avoids the wire rod to take place the condition of pine to take place to take off, and the accommodation process is nimble more convenient.

Drawings

FIG. 1 is a schematic view of the configuration of a fiber optic module adapter according to the present utility model;

FIG. 2 is a schematic diagram of a heat dissipating module portion of an optical fiber module adapter according to the present utility model;

FIG. 3 is a schematic view of a shielding assembly of a fiber optic module adapter according to the present utility model;

FIG. 4 is a cross-sectional view of a threaded rod and spring portion of a fiber optic module adapter of the present utility model;

in the figure: 1. a top plate; 2. a partition plate; 3. a bottom plate; 4. an interlayer; 5. a plug port; 6. a shielding assembly; 7. a heat dissipation module; 8. an end cap; 9. coaming plate; 10. a heat radiation hole; 11. a screw; 12. an adjustment knob; 13. a spring; 14. a threaded hole; 15. a telescoping sleeve; 16. a first magnet plate; 17. a telescopic rod; 18. a second magnet plate; 19. a third magnet plate; 20. a through hole; 21. the recess is hidden.

Detailed Description

The utility model is further described in connection with the following detailed description, in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the utility model easy to understand.

Referring to fig. 1 to 4, the present utility model provides a technical solution: the utility model provides an optical fiber module switching device, includes the switching device body, the switching device body includes roof 1, baffle 2, bottom plate 3, heat dissipation module 7 and shelters from subassembly 6, all be provided with intermediate layer 4 between roof 1 and the baffle 2 and between baffle 2 and the bottom plate 3, grafting port 5 has been seted up to the inboard of intermediate layer 4, heat dissipation module 7 is all installed to the intermediate position department of roof 1 and bottom plate 3, through-hole 20 has been seted up on the surface of baffle 2, the inside of through-hole 20 alternates and has shelters from subassembly 6, shelter from subassembly 6 and be provided with a plurality of and even distribution at the side of grafting port 5, wholly be columnar structure to form two intermediate layer 4 regions with the outside through baffle 2 in the centre, can be with the optical fiber cable that the optical fiber module other end is connected and the network cable that switching device connects all wind accomodate through this intermediate layer 4 region, be convenient for arrange wire part, improved the stability of connection, when this optical fiber module switching device uses, directly connect the grafting port 5 part with the baffle 2 bottom to use the net wire to correspond the baffle 2 top port 5 and connect the external connection equipment that need the top plate 3 to carry out the heat dissipation effect to the intermediate layer 3, can realize the heat dissipation device when the both sides and the top plate 1 is connected, and the heat dissipation device is realized to the intermediate layer 3 promptly.

In this embodiment, the heat dissipation module 7 includes end cover 8 and bounding wall 9, bounding wall 9 fixed mounting is in the inboard of end cover 8, the louvre 10 has been seted up to the surface of bounding wall 9, threaded hole 14 and hidden recess 21 have been seted up to the inside interlude of end cover 8, threaded hole 14 and hidden recess 21 have been seted up to the tip of bounding wall 9, threaded hole 14's inside is followed to threaded rod 11, adjust knob 12 is installed at the top of threaded rod 11, and specifically, when dispelling the heat, through the adjust knob 12 at the rotation top, utilize the rotation of threaded rod 11, take out threaded rod 11 from being in the bounding wall 9 of bottom, lose the connection effect of threaded rod 11 between two bounding walls 9 at this moment, can separate two bounding walls 9 under the effect of intermediate spring 13, until ejecting every bounding wall 9 to the outside of roof 1 and bottom plate 3, utilize a plurality of louvres 10 on bounding wall 9 can outwards derive the heat that the inside electronic component produced, realize the radiating effect, and when not using through rotating threaded rod 11 with two bounding walls 9 carry out butt joint combination, until accomodate the inside of groove 21 with spring 13, can press down every bottom plate 1 or 3 at the whole space, realize the reduction in the storage effect.

According to the embodiment, the coaming 9 is provided with two coamings, and the two coamings 9 penetrate into the inside from the intermediate position of the top plate 1 and the bottom plate 3 respectively, the two coamings 9 are connected through the screw 11, the spring 13 is embedded in the hidden groove 21, two ends of the spring 13 are fixedly connected with the innermost sides of the hidden grooves 21 on the two coamings 9 respectively, the spring 13 is provided with a plurality of springs, the springs 13 are installed on two sides of the screw 11 in a symmetrical mode, the heat dissipation modules 7 are all installed at the top and the bottom of the shell, the two groups of heat dissipation modules 7 are connected through the middle spring 13 and the screw 11, the connecting state between the two heat dissipation modules 7 can be controlled through rotating the screw 11, then the heat dissipation effect is achieved through unfolding when the screw 11 is used, and then the heat dissipation modules 7 are compressed to the inside of the shell, and the occupied space is reduced specifically when the heat dissipation modules 7 are unfolded when the heat dissipation device is used in a switching mode, the coamings 9 on two sides are ejected outwards at the moment, the spring 13 is always in an extending state, therefore after the outside is impacted, the impact point acts on the cover plate, the whole device can be directly connected with the top plate through the compression device, namely the whole wire material can be prevented from falling down through the compression device, and the whole buffer device can be connected with the top plate 1, and the whole buffer device can be directly connected with the top plate 2 through the buffer device, and the buffer device can be prevented from being connected through the side impact device.

This embodiment, shelter from subassembly 6 includes telescopic link 17 and telescopic sleeve 15, first magnet board 16 is installed to telescopic sleeve 15's bottom, telescopic link 17's bottom inserts telescopic sleeve 15's inside, second magnet board 18 is installed at telescopic link 17's top, the inboard of roof 1 and bottom plate 3 all inlays and is equipped with third magnet board 19, and every third magnet board 19 all is in same perpendicular with corresponding shielding subassembly 6, telescopic sleeve 15's length is greater than interlayer 4's width, telescopic sleeve 15 passes from through hole 20's inside, and through-hole 20's inboard diameter is the same with telescopic sleeve 15's surface diameter, installs a plurality of shielding subassembly 6 in the outside, and every shielding subassembly 6 all can control its telescopic length and the position of being located, erects in the outside after coiling different wires, shelter from the condition that the wire rod takes place to the wire rod that the coiling was accomplished, and adjust the process more nimble, and convenient if fiber module connects the back, or wire rod part is greater than interlayer 4 with the length, can shelter from the wire rod that the inside diameter is the wire rod that the second magnet board is fully coiled by the wire rod is fully to the wire rod is fully, and the wire rod is fully coiled up to the wire rod is fully through the second magnet board 16, and the wire rod is then the wire rod is fully can be adsorbed by the wire rod is 16 in the corresponding to the outside of the telescopic sleeve 16, the situation is avoided the outside to the wire rod to the outside to the wire rod is fully to the outside after the wire rod is fully coiled in the length 16.

While the fundamental and principal features of the utility model and advantages of the utility model have been shown and described, it will be apparent to those skilled in the art that the utility model is not limited to the details of the foregoing exemplary embodiments, but may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (8)

1. The utility model provides a fiber optic module switching device, includes switching device body, its characterized in that: the switching device body includes roof (1), baffle (2), bottom plate (3), heat dissipation module (7) and shelters from subassembly (6), all be provided with intermediate layer (4) between roof (1) and baffle (2) and between baffle (2) and bottom plate (3), grafting port (5) have been seted up to the inboard of intermediate layer (4), heat dissipation module (7) have all been installed in intermediate position department of roof (1) and bottom plate (3), through-hole (20) have been seted up on the surface of baffle (2), the inside of through-hole (20) alternates and has shelters from subassembly (6), shelter from subassembly (6) are provided with a plurality of and even distribution in the side of grafting port (5).

2. The fiber optic module switching device according to claim 1, wherein: the heat dissipation module (7) comprises an end cover (8) and a surrounding plate (9), wherein the surrounding plate (9) is fixedly installed on the inner side of the end cover (8), heat dissipation holes (10) are formed in the surface of the surrounding plate (9), and screws (11) are inserted into the end cover (8).

3. The fiber optic module switching device according to claim 2, wherein: screw holes (14) and hidden grooves (21) are formed in the end portions of the coaming plates (9), the screw rods (11) penetrate through the screw holes (14), and the top portions of the screw rods (11) are provided with adjusting knobs (12).

4. A fiber optic module switching device according to claim 3, wherein: the coaming (9) is provided with two, and two coamings (9) penetrate into the inside from the intermediate position of roof (1) and bottom plate (3) respectively, and two coamings (9) are connected through screw rod (11).

5. A fiber optic module switching device according to claim 3, wherein: the spring (13) is embedded in the hidden groove (21), two ends of the spring (13) are fixedly connected with the innermost sides of the hidden grooves (21) on the two coamings (9) respectively, the springs (13) are arranged in a plurality, and the springs (13) are symmetrically arranged on two sides of the screw (11).

6. The fiber optic module switching device according to claim 1, wherein: the shielding assembly (6) comprises a telescopic rod (17) and a telescopic sleeve (15), a first magnet plate (16) is arranged at the bottom end of the telescopic sleeve (15), and the bottom of the telescopic rod (17) is inserted into the telescopic sleeve (15).

7. The fiber optic module switching device according to claim 6, wherein: the top of telescopic link (17) is installed second magnet board (18), the inboard of roof (1) and bottom plate (3) all inlays and is equipped with third magnet board (19), and every third magnet board (19) all are in same perpendicular line with corresponding shielding assembly (6).

8. The fiber optic module switching device according to claim 7, wherein: the length of the telescopic sleeve (15) is larger than the width of the interlayer (4), the telescopic sleeve (15) passes through the inside of the through hole (20), and the inner diameter of the through hole (20) is the same as the surface diameter of the telescopic sleeve (15).