CN220527280U - Network interface - Google Patents

Abstract

The utility model relates to an electrical component's technical field discloses a network interface, which comprises a housin, set up the standing groove that supplies the embedding of quartzy plug on the terminal surface of casing, set up the holding tank of intercommunication standing groove on the casing, be equipped with the dead lever on the cell wall of holding tank, rotate on the dead lever and be connected with the rotatory board that shelters from the holding tank completely, be equipped with spacing subassembly on the casing, spacing subassembly is used for restricting the rotatory board and removes, and this application passes through the rotatory board and rotates around the dead lever, and when network interface is not using for a long time, the rotatory board can shelter from the opening of standing groove, lets the dust be difficult for entering into in the standing groove.

Description

Network interface

Technical Field

The present application relates to the technical field of electrical components, and in particular, to a network interface.

Background

The network interface is various interfaces of network equipment, the network interface is usually used for connecting end face crystal plugs of network cables, the crystal plugs are inserted into the network interface to realize signal transmission, and the network interface is firstly arranged on a wall, so that the crystal plugs can be inserted into the network interface.

The network interface in the related art comprises a shell, wherein a placing groove is formed in the end face of the shell, a crystal plug is inserted into the placing groove, a groove is formed in the groove wall of the placing groove, a bayonet lock of the crystal plug is embedded into the groove, and when the bayonet lock is embedded into the groove, the shell and the crystal plug are mutually fixed.

When some network interfaces are not connected into the crystal plug for a long time, dust can cover the inside of the placing groove, and the inside of the placing groove is difficult to clean because the network interfaces are smaller, so that when the crystal plug is required to be inserted into the placing groove, the dust can possibly cause the problem of poor contact.

Disclosure of Invention

In order to solve the problem that dust is easy to accumulate when a crystal plug is not connected for a long time, the application provides a network interface.

The network interface provided by the application adopts the following technical scheme:

the utility model provides a network interface, includes the casing, set up the standing groove that supplies the embedding of quartzy plug on the terminal surface of casing, set up the holding tank of intercommunication standing groove on the casing, be equipped with the dead lever on the cell wall of holding tank, rotate on the dead lever and be connected with the rotor plate that shelters from the holding tank completely, be equipped with spacing subassembly on the casing, spacing subassembly is used for restricting the rotor plate and removes.

Through adopting above-mentioned technical scheme, rotate around the dead lever through the pivoted panel, add limit assembly to the restriction of pivoted panel for the pivoted panel can shelter from the standing groove, shelter from the opening part of standing groove when not using the network interface for a long time, thereby lets the dust be difficult for getting into the standing groove, reduces the accumulation of dust in the standing groove; the rotating plate is not limited by the limiting component, the rotating plate can rotate around the fixed rod, the placing groove is not blocked by the rotating plate, the crystal plug can be smoothly embedded into the placing groove, and the shell and the crystal plug are connected with each other.

Optionally, the spacing subassembly includes the gag lever post, the gag lever post rotates to be connected on the casing, the rotation direction of gag lever post and the rotation direction mutually perpendicular of rotor plate, set up the spacing groove that supplies the gag lever post embedding on the terminal surface of rotor plate, works as in the gag lever post embedding spacing inslot, the rotor plate is difficult to rotate around the dead lever.

Through adopting above-mentioned technical scheme, through gag lever post embedding spacing inslot, in addition the rotation direction of gag lever post and the rotation direction mutually perpendicular of pivoted board for the pivoted board is difficult for driving the gag lever post and rotates, thereby lets the pivoted board be difficult for removing, makes the pivoted board can shelter from the opening part of standing groove completely.

Optionally, the draw-in groove has been seted up on the cell wall of spacing groove, be equipped with the fixture block that can imbed the draw-in groove on the surface of gag lever post, when the fixture block imbeds in the draw-in groove, the gag lever post is difficult for breaking away from the spacing groove.

Through adopting above-mentioned technical scheme, through in the fixture block embedding draw-in groove for the gag lever post is difficult for breaking away from the spacing groove, thereby lets the embedding spacing inslot that the gag lever post can be stable, makes the gag lever post restrict the pivoted plate, lets the pivoted plate can keep the shutoff to the standing groove.

Optionally, be equipped with the operation piece on the terminal surface of gag lever post, the operation piece is used for supplying the staff to drive the fixture block and breaks away from the draw-in groove.

Through adopting above-mentioned technical scheme, the staff of being convenient for rotates the gag lever post through the drive operation piece, realizes that the fixture block breaks away from the draw-in groove to the gag lever post of being convenient for breaks away from the draw-in groove, makes the gag lever post remove the restriction to the pivoted plate.

Optionally, the spout has been seted up on the terminal surface of casing, sliding connection has the slider in the spout, the gag lever post rotates to be connected on the terminal surface that the slider kept away from the spout diapire, when slider butt spout diapire terminal surface, the gag lever post is located the spout completely.

Through adopting above-mentioned technical scheme, slide in the spout through the slider, let the gag lever post can be located the spout for the gag lever post is not located outside the casing, is difficult for taking too big space when making the gag lever post not restricting the pivoted plate, reduces the space that the gag lever post occupy, makes the occupation space that the gag lever post is difficult for influencing the network interface.

Optionally, the holding groove has been seted up on the terminal surface of gag lever post, the holding groove runs through to the terminal surface of gag lever post below, sliding connection has the anticreep piece in the holding groove, set up the anticreep groove that supplies the embedding of anticreep piece on the cell wall of spout below, works as when the anticreep piece embedding anticreep inslot, the gag lever post is difficult for breaking away from the spout.

Through adopting above-mentioned technical scheme, slide in the storage tank through the anticreep piece for the anticreep piece can slide downwards, and when the gag lever post was located the spout, anticreep piece butt spout's cell wall was until the anticreep piece embedding anticreep inslot, let the gag lever post be restricted by the anticreep piece, make the gag lever post be difficult for breaking away from the spout, thereby let the gag lever post be difficult for taking too much space.

Optionally, an ejecting spring is arranged on the bottom wall of the chute, the ejecting spring is arranged on the end face of the sliding block, which faces the bottom wall of the chute, and when the limiting rod is completely positioned in the chute, the ejecting spring is in a compressed state.

Through adopting above-mentioned technical scheme, be in compression state through popping up the spring for pop up the spring and exert effort to the slider, in addition drive anticreep piece breaks away from the anticreep groove, make pop up the spring and drive the slider and remove to the direction of keeping away from the spout diapire, thereby let the slider can remove smoothly from the spout in, be convenient for take out the gag lever post from the spout in.

Optionally, an elastic block is provided on the groove wall of the placement groove, and an embedding groove into which the elastic block is embedded is provided on the side surface of the rotating plate, and when the elastic block is embedded into the embedding groove, the rotating plate completely shields the placement groove.

Through adopting above-mentioned technical scheme, through in the elastic block embedding caulking groove for the pivoted board can be fixed in the standing groove in advance, reduces simultaneously and rotates the board and carry out pivoted possibility around the dead lever because of the vibration, makes the pivoted board shelter from the standing groove that can be more stable.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the rotating plate is limited by the limiting component, so that the rotating plate is not easy to rotate around the fixed rod, the placing groove can be shielded by the rotating plate, dust is not easy to enter the placing groove, and the dust is not easy to influence the placing groove; the rotating plate rotates around the fixed rod, so that the rotating plate can not shade the placing groove, and the crystal plug can be smoothly inserted into the placing groove.

2. Through the anti-drop block sliding in the accommodation groove for the anti-drop block can remove to the direction of penetration of accommodation groove, makes the anti-drop block can imbed anti-drop inslot smoothly, lets the limiting lever of anti-drop block break away from the spout, makes the limiting lever can be stable be located the spout.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present application;

FIG. 2 is an exploded view highlighting a rotating plate;

FIG. 3 is a cross-sectional view highlighting a moving mass;

fig. 4 is an exploded view showing the anti-slip block.

Reference numerals: 1. a housing; 11. a placement groove; 12. a receiving groove; 121. an elastic block; 13. a fixed rod; 14. a chute; 141. a moving groove; 142. an anti-drop groove; 143. a spring is ejected; 2. a rotating plate; 21. perforating; 22. a caulking groove; 23. a limit groove; 231. a clamping groove; 3. a slide block; 31. a moving block; 32. a rotating groove; 321. a support rod; 4. a limit component; 41. a limit rod; 411. a through hole; 42. a receiving groove; 421. an anti-falling block; 43. a clamping block; 44. an operation block.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-4.

The embodiment discloses a network interface. Referring to fig. 1, a network interface includes a housing 1.

Referring to fig. 1 and 2, a placement groove 11 into which a crystal plug is inserted is formed in an end surface of the case 1. An accommodating groove 12 communicated with the accommodating groove 11 is formed in the end face of the shell 1, and the accommodating groove 12 extends along the length direction of the accommodating groove 11. A fixed rod 13 is fixedly connected to the groove wall of the accommodating groove 12, and two opposite ends of the fixed rod 13 are respectively abutted against the groove wall of the accommodating groove 12.

Referring to fig. 2, a rotating plate 2 is provided in the accommodating groove 12, and a through hole 21 through which the fixing rod 13 passes is provided in an end surface of the rotating plate 2. The rotating plate 2 can rotate around the fixed rod 13, and the rotating plate 2 can completely block the opening of the placing groove 11. When the rotating plate 2 shields the placing groove 11, the end face of the rotating plate 2 facing the bottom wall of the placing groove 11 is provided with a caulking groove 22. An elastic block 121 is fixedly connected to the groove wall of the placing groove 11, and the elastic block 121 can be embedded into the caulking groove 22. When the elastic block 121 is embedded in the caulking groove 22, the rotating plate 2 can completely block the placement groove 11.

Referring to fig. 3, a chute 14 is provided on an end surface of the housing 1, and the chute 14 extends in the extending direction of the placement groove 11. The two opposite side walls of the chute 14 are provided with a moving groove 141, and the moving groove 141 extends along the length direction of the chute 14.

Referring to fig. 3 and 4, the chute 14 is provided with a drop-preventing groove 142 on a vertically downward chute wall, and the drop-preventing groove 142 extends in a vertical direction.

Referring to fig. 3, an ejector spring 143 is fixedly connected to the bottom wall of the chute 14, and a slider 3 is fixedly connected to the end surface of the ejector spring 143, wherein the slider 3 is capable of sliding in the chute 14. The moving block 31 is integrally formed on the opposite end surfaces of the slider 3, the moving block 31 can slide in the moving groove 141, and the moving block 31 is not easily separated from the moving groove 141.

Referring to fig. 2 and 3, a housing 1 is provided with a limiting assembly 4 for limiting the rotation of the rotation plate 2. The limit assembly 4 includes a limit lever 41. The end surface of the slider 3 far from the ejection spring 143 is provided with a rotation groove 32, and the rotation groove 32 penetrates the slider 3 toward the direction of the placement groove 11. The groove wall of the rotating groove 32 is fixedly connected with a supporting rod 321, and the end surfaces of the two opposite sides of the supporting rod 321 are respectively and fixedly connected with the groove walls of the two opposite sides of the rotating groove 32. The length direction of the support rod 321 is perpendicular to the length direction of the fixing rod 13. The outer surface of the limit rod 41 is provided with a through hole 411 for the support rod 321 to pass through, that is, the limit rod 41 can rotate around the support rod 321, and the rotation direction of the limit rod 41 is mutually perpendicular to the rotation direction of the rotating plate 2. The stopper rod 41 is slidable in the chute 14. When the stop lever 41 is fully seated within the chute 14, the pop-up spring 143 is in a compressed state.

Referring to fig. 3 and 4, when the limit lever 41 is located in the chute 14, a receiving groove 42 is formed in an end surface of the limit lever 41 away from the slider 3, and the receiving groove 42 penetrates the limit lever 41 in a vertically downward direction. The holding groove 42 is slidably connected with a drop-off preventing block 421, and the drop-off preventing block 421 can be inserted into the drop-off preventing groove 142. When the anti-drop block 421 is inserted into the anti-drop groove 142, the stopper rod 41 is not easily separated from the slide groove 14.

Referring to fig. 2 and 3, two clamping blocks 43 are fixedly connected to the outer surface of the limit lever 41, and the two clamping blocks 43 are respectively located at two opposite sides of the limit lever 41. An operation block 44 is fixedly connected to the outer surface of the limit rod 41, and the operation block 44 is used for driving the limit rod 41 to rotate around the support rod 321.

Referring to fig. 2, when the rotating plate 2 shields the placement groove 11, a limit groove 23 is formed on the end surface of the rotating plate 2 away from the bottom wall of the placement groove 11, and the limit groove 23 penetrates the rotating plate 2 toward the direction of the chute 14. The limit groove 23 is used for embedding the limit rod 41. The groove walls on two opposite sides of the limit groove 23 are respectively provided with a clamping groove 231 for embedding the clamping block 43. When the clamping block 43 is embedded in the clamping groove 231, the limiting rod 41 can be embedded in the limiting groove 23, and the operating block 44 is located on one side, away from the bottom wall of the limiting groove 23, of the limiting rod 41.

The implementation principle of the network interface in the embodiment of the application is as follows: the operator drives the operation block 44 to separate the limit rod 41 from the limit groove 23, then moves the limit rod 41 towards the bottom wall of the chute 14, inserts the anti-drop block 421 into the anti-drop groove 142, and then takes the rotating plate 2 out of the placing groove 11, so that the crystal plug can be inserted into the placing groove 11.

The foregoing description of the preferred embodiments of the present application is not intended to limit the utility model, but is intended to cover any modifications, equivalents, improvements, etc. that fall within the spirit and scope of the present application.

Claims (8)

1. The utility model provides a network interface, includes casing (1), offer standing groove (11) that supply quartzy plug to imbed on the terminal surface of casing (1), its characterized in that: the novel rotary table is characterized in that a containing groove (12) communicated with the containing groove (11) is formed in the shell (1), a fixing rod (13) is arranged on the groove wall of the containing groove (12), a rotary plate (2) which completely shields the containing groove (12) is connected to the fixing rod (13) in a rotary mode, a limiting assembly (4) is arranged on the shell (1), and the limiting assembly (4) is used for limiting the rotary plate (2) to move.

2. A network interface as claimed in claim 1, wherein: the limiting component (4) comprises a limiting rod (41), the limiting rod (41) is rotationally connected to the shell (1), the rotation direction of the limiting rod (41) is mutually perpendicular to the rotation direction of the rotating plate (2), a limiting groove (23) for embedding the limiting rod (41) is formed in the end face of the rotating plate (2), and the rotating plate (2) is not easy to rotate around the fixing rod (13) when the limiting rod (41) is embedded into the limiting groove (23).

3. A network interface as claimed in claim 2, wherein: the clamping groove (231) is formed in the groove wall of the limiting groove (23), the clamping block (43) capable of being embedded into the clamping groove (231) is arranged on the outer surface of the limiting rod (41), and when the clamping block (43) is embedded into the clamping groove (231), the limiting rod (41) is not easy to separate from the limiting groove (23).

4. A network interface as claimed in claim 3, wherein: an operation block (44) is arranged on the end face of the limiting rod (41), and the operation block (44) is used for enabling a worker to drive the clamping block (43) to be separated from the clamping groove (231).

5. A network interface as claimed in claim 2, wherein: the sliding chute (14) is formed in the end face of the shell (1), the sliding chute (14) is connected with the sliding block (3) in a sliding mode, the limiting rod (41) is connected to the end face, far away from the bottom wall of the sliding chute (14), of the sliding block (3), and when the sliding block (3) abuts against the end face, far away from the bottom wall of the sliding chute (14), the limiting rod (41) is completely located in the sliding chute (14).

6. A network interface as claimed in claim 5, wherein: the utility model discloses a limiting rod, including locating lever (41), locating lever (41) and limiting rod, set up accommodation groove (42) on the terminal surface of locating lever (41), accommodation groove (42) run through to the terminal surface of locating lever (41) below, sliding connection has anticreep piece (421) in accommodation groove (42), set up on the cell wall of spout (14) below and supply anticreep piece (421) embedded anticreep groove (142), works as when anticreep piece (421) are embedded in anticreep groove (142), locating lever (41) is difficult for breaking away from spout (14).

7. A network interface as claimed in claim 6, wherein: the bottom wall of the sliding groove (14) is provided with an ejecting spring (143), the ejecting spring (143) is arranged on the end face of the sliding block (3) facing the bottom wall of the sliding groove (14), and when the limiting rod (41) is completely positioned in the sliding groove (14), the ejecting spring (143) is in a compressed state.

8. A network interface as claimed in claim 1, wherein: an elastic block (121) is arranged on the groove wall of the placing groove (11), an embedding groove (22) for embedding the elastic block (121) is arranged on the side face of the rotating plate (2), and when the elastic block (121) is embedded into the embedding groove (22), the rotating plate (2) completely shields the placing groove (11).