CN114006779B - Be applied to edge calculation formula network converter - Google Patents

Abstract

The invention provides a network converter applied to edge computing, comprising: the converter comprises a converter shell, a sealing assembly, a driving assembly and a dust cover, wherein the dust cover is internally provided with a mounting station corresponding to the sealing assembly and the driving assembly; by arranging two extrusion sleeves which can be mutually extruded and attached in the dust cover, external dust and foreign matters are prevented from entering the interface, the safety of the network converter is effectively ensured, the service life of the network converter is prolonged, the movement of the extrusion sleeves can be indirectly controlled by manually rotating the driving wheel, and therefore, the network plug is convenient to insert into the interface, and trouble is avoided for users; the dust cover is clamped and arranged in the mounting sleeve, so that the dust cover can be independently replaced after the dust part is damaged, and the use of a user is further facilitated.

Description

Be applied to edge calculation formula network converter

Technical Field

The invention belongs to the technical field of network converters, and particularly relates to a network converter applied to edge computing.

Background

The network converter is a device applied between the wide area network and the internal local area network to realize the switching between the wide area network and the internal local area network, namely, the complete physical isolation of the internal and the external networks is realized by utilizing the separation of the servers and the lines of the internal and the external networks. The technology of the network converter mainly uses various firewalls, and the reason for this is mainly that networks are physically connected together, and the network converter is used in securities, tax, telecommunication, electric power, administrative units, public institutions and other departments except for confidential computer networks.

Edge computing refers to providing near-end services by adopting an open platform with integrated core capabilities such as network, computing, storage, application and the like on one side close to an object or data source. The application program is initiated at the edge side, and faster network service response is generated, so that the basic requirements of the industry in the aspects of real-time service, application intelligence, security, privacy protection and the like are met.

The existing network converter comprises a network converter shell and a plurality of interfaces positioned at the front end of the network converter shell, and when the network converter is used, a network cable plug is directly inserted into the interfaces, so that the network converter is very convenient. However, since the interface of the network converter is exposed, dust in the air easily enters the interface and causes pollution; in daily life, people sometimes sprinkle water on the network converter due to carelessness, and finally the water enters the network converter through the interface, so that the converter can be damaged.

Accordingly, there is a need to provide an improved solution to the above-mentioned deficiencies of the prior art.

Disclosure of Invention

The object of the present invention is to overcome the above-mentioned drawbacks of the prior art and to provide a network converter capable of interface sealing.

In order to achieve the above object, the present invention provides the following technical solutions:

a network converter for use in edge computing, the converter comprising:

the converter comprises a converter shell, a power supply and a power supply, wherein the converter shell is provided with an interface for plugging a network plug;

the two sealing assemblies are arranged on the outer sides of the interface and are oppositely arranged on two sides of the midline position of the interface;

the driving assembly is used for driving the sealing assembly to move;

the dustproof cover is detachably connected to the side wall of the converter shell, on one side of which the connector is formed, and a mounting station corresponding to the sealing assembly and the driving assembly is arranged in the dustproof cover;

the driving assembly drives the two sealing assemblies to press each other at the center line position of the interface so as to seal the interface, or drives the two sealing assemblies to be away from each other so as to enable a network plug to be inserted into the interface.

As described above for use in an edge-computing network converter, the seal assembly preferably comprises:

the extrusion sleeve is at least provided with a side wall which corresponds to the interface and has a certain width in the movement direction of the sealing assembly, and is used for sealing the interface;

one end of the guide rod is fixedly connected with the extrusion sleeve, and the other end of the guide rod is assembled on the dust cover in a sliding manner;

preferably, both sides of the inside of the dust cover are provided with sliding grooves, the sliding grooves extend along the axial direction of the guide rod, and both sides of the extrusion sleeve are provided with guide rails which are assembled in the sliding grooves in a sliding way;

preferably, there are two guide rods on the same extrusion sleeve.

As described above for the edge computing network converter, preferably, the guide rod is sleeved with a compression spring, so that the compression sleeve maintains a sealing state for the interface.

As described above for use in edge-computing network converters, preferably, adjacent sides of the extrusion jackets in both of the seal assemblies are provided with seal gaskets;

preferably, an arc-shaped groove is arranged in the middle of the sealing cushion layer so as to correspondingly clamp the network cable connected with the network plug after the network plug is inserted.

As described above, for application to an edge computing network converter, preferably, there are two driving assemblies, and the two driving assemblies respectively drive the two sealing assemblies, including:

the rolling shaft is arranged at one side of the extrusion sleeve far away from the interface, and two ends of the rolling shaft are rotatably connected to the inner walls of the left side and the right side of the dust cover;

the gear ring is coaxially assembled on the rolling shaft;

the rack is arranged on the outer wall of the extrusion sleeve and extends along the movement direction of the driving assembly;

the gear ring is correspondingly meshed with the rack, and the rolling shaft is rotated to drive the extrusion sleeve to move.

The driving assembly further comprises a driving wheel, wherein the driving wheel is fixedly connected to the rolling shaft and is coaxially arranged with the rolling shaft; the side part of the driving wheel extends out of the dust cover, and the driving wheel is stirred to drive the rolling shaft.

As described above, in the edge computing network converter, preferably, the two ends on the rolling shaft are sleeved with protective sleeves to clamp the gear ring, so as to limit the gear ring;

preferably, the outer peripheral surface of the driving wheel is provided with poking teeth.

As described above, in the edge computing network converter, preferably, openings corresponding to the interfaces are provided on opposite sides of the dust cover, and the sealing component is close to the inner wall of the dust cover corresponding to the opening on one side of the interface; the side wall of the extrusion sleeve is provided with a sealing sheet, and the sealing sheet is in sliding friction with the inner wall of the dust cover in the movement process of the extrusion sleeve.

The above-mentioned application to edge computing type network converter, preferably, the said dust cover has externally sleeved the installation sleeve, the said installation sleeve is square frame, the said installation sleeve is connected to said converter shell through the removable way;

preferably, at least two opposite side outer walls of the dust cover are provided with bulges, and the inner wall of the mounting sleeve is provided with limit grooves corresponding to the bulges.

As described above for the edge computing network converter, preferably, the converter housing has a plurality of interfaces arranged in a linear manner, each of the interfaces is provided with one of the dust covers, and is equipped with one of the sealing assemblies and the driving assembly.

The beneficial effects are that: the two sealing components which can move relatively in front of the interface are arranged, and the interface is sealed by the two sealing components, so that dust and water pollution is avoided; the two driving assemblies are arranged to drive the two sealing assemblies respectively, and when the network connector is required to be plugged, the two sealing assemblies are driven to be separated from each other, and the network connector penetrates through a gap between the two sealing assemblies to be plugged with the interface.

Drawings

The accompanying drawings, which 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. Wherein:

FIG. 1 is a schematic diagram of a converter according to an embodiment of the present invention;

FIG. 2 is a schematic cross-sectional view of A-A of FIG. 1;

FIG. 3 is a schematic view illustrating an inner structure of a dust cap according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of the connection between the rolling shaft and the extrusion sleeve according to an embodiment of the present invention.

In the figure: 1. a converter housing; 2. an interface; 3. a mounting sleeve; 4. a dust cover; 5. a rear opening; 6. a front opening; 7. extruding the sleeve; 8. extruding a spring; 9. a rack; 10. a rolling shaft; 11. a gear ring; 12. a driving wheel; 13. a guide rod; 14. a sliding port; 15. a sealing cushion layer; 16. a protective sleeve; 17. a sealing sheet; 18. a bulge; 19. and a guide rail.

Detailed Description

The following description of the technical solutions in the embodiments of the present invention will be clear and complete, and it is obvious that the described embodiments are only some embodiments of the present invention, but not all embodiments. All other embodiments, which are derived by a person skilled in the art based on the embodiments of the invention, fall within the scope of protection of the invention.

In the description of the present invention, the terms "longitudinal", "transverse", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", etc. refer to the orientation or positional relationship based on that shown in the drawings, merely for convenience of description of the present invention and do not require that the present invention must be constructed and operated in a specific orientation, and thus should not be construed as limiting the present invention. The terms "coupled" and "connected" as used herein are to be construed broadly and may be, for example, fixedly coupled or detachably coupled; either directly or indirectly through intermediate components, the specific meaning of the terms being understood by those of ordinary skill in the art as the case may be.

The invention will be described in detail below with reference to the drawings in connection with embodiments. It should be noted that, without conflict, the embodiments of the present invention and features of the embodiments may be combined with each other.

As shown in fig. 1-4, a network converter for edge computing applications, the converter comprising: a converter housing 1, the converter housing 1 being provided with an interface 2 for plugging in a network plug; the two sealing assemblies are arranged on the outer side of the interface 2 and are oppositely arranged on two sides of the center line position of the interface 2; the driving assembly is used for driving the sealing assembly to perform relative movement; the dustproof cover is detachably connected to the side wall of the converter shell 1 on one side where the connector 2 is arranged, and a mounting station corresponding to the sealing component and the driving component is arranged in the dustproof cover; the driving assembly drives the two sealing assemblies to press each other at the center line position of the interface 2 so as to seal the interface 2, or drives the two sealing assemblies to be away from each other so as to allow the network plug to be inserted into the interface 2. Two sealing components capable of relatively moving in front of the interface 2 are arranged, and the interface 2 is sealed through the two sealing components, so that dust and water pollution is avoided; two driving assemblies are arranged to drive the two sealing assemblies respectively, and when the network connector is required to be plugged, the two sealing assemblies are driven to be separated from each other, and the network connector penetrates through a gap between the two sealing assemblies to be plugged with the interface 2.

In another alternative embodiment of the present application, a seal assembly includes: the extrusion sleeve 7 is a square sleeve body, the extrusion sleeve 7 is at least provided with side walls which correspond to the interface 2 and have a certain width in the movement direction of the sealing assembly, and one side of the two extrusion sleeves opposite to each other is a flat end surface so as to form shielding and sealing for the interface 2 through the extrusion sleeve 7 when the two extrusion sleeves 7 are mutually extruded at the center line position of the interface 2; the guide rod 13, one end of the guide rod 13 is fixedly connected with the extrusion sleeve 7, and the other end is assembled on the dust cover in a sliding way; the extrusion sleeves 7 are guided by the guide rods 13, so that the two extrusion sleeves 7 can reciprocate along a fixed path.

In this embodiment, there are two guide rods 13 on the same pressing sleeve 7, see fig. 4, and the pressing sleeve 7 is limited by the two guide rods 13 not to rotate relative to the side wall of the corresponding interface 2 of the converter housing 1.

In another alternative embodiment of the present application, the guide rod 13 is sleeved with the extrusion spring 8, one end of the extrusion spring 8 abuts against the inner wall of the dust cover 4, the other end abuts against the extrusion sleeve 7, and the extrusion spring 8 makes the two extrusion sleeves 7 have a tendency to extrude relatively, so that the extrusion sleeve 7 maintains a sealing state on the interface 2, and maintains sealing under the condition of no external force.

In an alternative embodiment of the present application, the adjacent sides of the squeeze jacket 7 in both seal assemblies are provided with a sealing cushion layer 15; the sealing cushion layer 15 is a rubber pad, and is sealed by extrusion deformation, so that water infiltration is avoided. Or the sealing cushion layer 15 is a sponge cushion. Wherein, the rubber pad is connected with detachable mode, is convenient for maintain according to the net twine diameter, perhaps changes after damaging.

In this embodiment, the middle part of the sealing cushion layer 15 is provided with an arc groove, and the arc groove extends along the insertion direction of the network plug and is matched with the outer diameter of the network cable, so that after the network plug is inserted, the network cable connected with the network plug is correspondingly clamped along with the extrusion sleeve 7, and the interface 2 after the network plug is connected is sealed through the arc groove corresponding to the network cable, thereby ensuring the sealing effect.

In another alternative embodiment of the present application, there are two drive assemblies, the two drive assemblies driving the two seal assemblies respectively, comprising: the rolling shaft 10 is arranged at one side of the extrusion sleeve 7 far away from the connector 2, and two ends of the rolling shaft 10 are rotatably connected to the inner walls of the left side and the right side of the dust cover; a ring gear 11, the ring gear 11 being coaxially fitted on the rolling shaft 10; the rack 9 is arranged on the outer wall of the extrusion sleeve 7 and extends along the movement direction of the driving assembly; the gear ring 11 correspondingly engages the gear rack 9, and rotates the rolling shaft 10 to drive the extrusion sleeve 7 to move.

In another alternative embodiment of the present application, the driving assembly further includes a driving wheel 12, where the driving wheel 12 is fixedly connected to the rolling shaft 10 and is coaxially disposed with the rolling shaft 10; the side part of the driving wheel 12 extends out of the dust cover, and the side part of the specific driving wheel 12 extends out of the front end of the dust cover, and the driving wheel 12 is shifted to drive the rolling shaft 10.

In another alternative embodiment of the present application, two ends on the rolling shaft 10 are sleeved with protective sleeves 16 to clamp the gear ring 11, and limit the gear ring 11; the protecting sleeve 16 is a rubber sleeve or a metal sleeve, and is in interference fit with the rolling shaft 10, so that the gear ring 11 is clamped in the middle, and the gear ring 11 is meshed with the rack 9.

The outer peripheral surface of the driving wheel 12 is provided with poking teeth, so that friction force is reduced, and poking is facilitated.

In some embodiments, the driving wheels 12 are gears, and the driving wheels corresponding to the two extrusion sleeves in the same dust cover are meshed with each other, so that one of the driving wheels is shifted to drive the two extrusion sleeves to perform relative movement simultaneously.

In another alternative embodiment of the present application, openings corresponding to the interfaces 2 are provided on two opposite sides of the dust cover, specifically, a rear opening 5 corresponding to the interface 2 and a front opening 6 provided at the front end of the sealing cover, and the sealing assembly is close to the inner wall of the dust cover corresponding to one side of the rear opening 5; the side wall of the extrusion sleeve 7 is provided with a sealing piece 17, and the sealing piece 17 is in sliding friction with the inner wall of the dust cover in the movement process of the extrusion sleeve 7. The sealing piece 17 is made of rubber, so that the extrusion sleeve 7 and the side wall of the dust cover are sealed, and the sealing effect is improved.

In another alternative embodiment of the present application, the two sides of the inside of the dust cover are provided with sliding grooves, the two sides of the extrusion sleeve 7 are provided with guide rails 19 slidably fitted in the sliding grooves, and the sliding grooves extend along the movement direction (or the axial direction of the guide rod 13) of the sealing assembly thereof for slidably limiting the extrusion sleeve 7.

In another alternative embodiment of the application, the outer part of the dust cover is sleeved with the mounting sleeve 3, the mounting sleeve 3 is a square frame body, and the square frame body is detachably connected to the converter shell 1; and the disassembly and the overhaul are convenient. The dust cap may be glued or screwed to the converter housing 1.

At least the outer walls of the two opposite sides of the dust cover are provided with bulges 18, namely solid hemispherical bulges, and the inner wall of the mounting sleeve 3 is provided with limit grooves corresponding to the bulges 18.

The dust cover and the mounting sleeve 3 are respectively provided with a sliding opening 14 corresponding to the guide rod 13, and the sliding opening 14 is matched with the guide rod 13.

In another alternative embodiment of the present application, the converter housing 1 has a plurality of interfaces 2 arranged in a linear manner, each interface 2 corresponds to a dust cover, and is equipped with a sealing assembly and a driving assembly, so as to perform sealing of any one interface 2 and plugging of network connectors according to the requirement.

In summary, the two extrusion sleeves 7 which can be mutually extruded and attached are arranged in the dustproof cover, so that external dust and foreign matters are prevented from entering the interface 2, the safety of the network converter is effectively ensured, the service life of the network converter is prolonged, the extrusion sleeve 7 can be indirectly controlled to move by manually rotating the driving wheel 12, and therefore, the network plug is conveniently inserted into the interface 2, and the trouble to a user is avoided; the dust cover is clamped in the mounting sleeve 3, so that the dust cover can be independently replaced after the dust part is damaged, and the use of a user is further facilitated. It is to be understood that the above description is exemplary only and that the embodiments of the present application are not limited thereto.

The foregoing description of the preferred embodiments of the invention is not intended to limit the invention to the particular embodiments disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

Claims (11)

1. A network switch for edge computing applications, said switch comprising:

the converter comprises a converter shell, a power supply and a power supply, wherein the converter shell is provided with an interface for plugging a network plug;

the two sealing assemblies are arranged on the outer side of the interface and are oppositely arranged on two sides of the center line of the interface, each sealing assembly comprises an extrusion sleeve and a guide rod, one end of each guide rod is fixedly connected with each extrusion sleeve, the other end of each guide rod is slidably assembled on the dust cover, the extrusion sleeves are guided by the guide rods, the two extrusion sleeves are guaranteed to reciprocate along a fixed path, and two guide rods on the same extrusion sleeve are arranged;

the drive assembly, drive assembly is used for driving seal assembly moves, drive assembly has two, two drive assembly drives respectively two seal assembly includes: the rolling shaft is arranged at one side of the extrusion sleeve far away from the interface, and two ends of the rolling shaft are rotatably connected to the inner walls of the left side and the right side of the dust cover; the gear ring is coaxially assembled on the rolling shaft; the rack is arranged on the outer wall of the extrusion sleeve and extends along the movement direction of the driving assembly; the gear ring is correspondingly meshed with the rack, the rolling shaft is rotated to drive the extrusion sleeve to move, and two ends of the rolling shaft are sleeved with protective sleeves to clamp the gear ring and limit the gear ring;

the dustproof cover is detachably connected to the side wall of the converter shell, which is provided with the connector, the dustproof cover is internally provided with a mounting station corresponding to the sealing component and the driving component, both sides of the inside of the dustproof cover are provided with sliding grooves which axially extend along the guide rod, both sides of the extrusion sleeve are provided with guide rails which are assembled in the sliding grooves in a sliding manner, the outside of the dustproof cover is sleeved with a mounting sleeve, the protective cover and the mounting sleeve are respectively provided with a sliding opening corresponding to the guide rod, and the sliding openings are matched with the guide rod;

the driving assembly drives the two sealing assemblies to press each other at the center line position of the interface so as to seal the interface, or drives the two sealing assemblies to be away from each other so as to enable a network plug to be inserted into the interface.

2. The network switch as recited in claim 1, wherein,

the extrusion sleeve is a square sleeve body and is provided with at least one side wall which corresponds to the interface and has a certain width in the movement direction of the sealing assembly, and one side of the two extrusion sleeves, which is opposite, is a flat end surface so as to seal the interface.

3. The network switch as claimed in claim 2, wherein said guide rods are sleeved with compression springs to maintain a seal against said interface at said compression sleeve.

4. The network converter of claim 2, wherein adjacent sides of the compression sleeve in both of the seal assemblies are provided with a sealing cushion.

5. The network converter according to claim 4, wherein the sealing cushion layer is provided with an arc-shaped groove in the middle to clamp the network cable connected with the network plug after the network plug is inserted.

6. The network converter according to claim 1, wherein the driving assembly further comprises a driving wheel, and the driving wheel is fixedly connected to the rolling shaft and coaxially arranged with the rolling shaft; the side part of the driving wheel extends out of the dust cover, and the driving wheel is stirred to drive the rolling shaft.

7. The network converter according to claim 6, wherein the driving wheel is provided with teeth on its outer peripheral surface.

8. The edge computing network converter of claim 2, wherein openings corresponding to the interfaces are formed in two opposite sides of the dust cover, and the sealing assembly is arranged on an inner wall, close to the dust cover, corresponding to the opening on one side of the interfaces; the side wall of the extrusion sleeve is provided with a sealing sheet, and the sealing sheet is in sliding friction with the inner wall of the dust cover in the movement process of the extrusion sleeve.

9. The network converter of claim 1, wherein the mounting sleeve is a square frame and is detachably connected to the converter housing.

10. The network converter according to claim 9, wherein at least two opposite outer walls of the dust cover are provided with bulges, and the inner wall of the mounting sleeve is provided with limit grooves corresponding to the bulges.

11. The network converter according to claim 1, wherein the converter housing has a plurality of said interfaces arranged in a linear manner, each of said interfaces having a corresponding one of said dust caps and being equipped with a set of said sealing assembly and said driving assembly.