CN112600766B - Switch with distributed hybrid structure for network engineering - Google Patents

Abstract

The invention relates to a switch with a distributed mixed structure for network engineering, which comprises a switch main body and a fixed plate, wherein one side of the outer wall of the switch main body is provided with a charging hole, one side of the outer wall of the switch main body is provided with a radiating strip hole, one side of the outer wall of the switch main body is provided with a connecting port, the bottom of the lower end of the switch main body is provided with a groove, and the periphery of the outer wall of the groove is provided with a cover plate. According to the invention, through the arrangement of the airflow control mechanism, the rack, the movable plate and the transmission gear shaft, the fixed transmission gear shaft is arranged at the inner side of the outer wall of the fixed plate, so that the gear on the transmission gear shaft and the rack on the movable plate are mutually embedded, and the movable plate can horizontally move by rotating the transmission gear shaft, so that the airflow groove covered by the movable plate is exposed, a user can adjust the opening size of the airflow groove according to the requirement, and better use experience is provided.

Description

Switch with distributed hybrid structure for network engineering

Technical Field

The invention relates to the technical field of switches in network engineering, in particular to a switch with a distributed mixed structure for network engineering.

Background

A switch is a device for expanding a network, and can provide more connection ports for a sub-network so as to connect more computers. With the development of the communication industry and the promotion of informatization of national economy, the network switch market is in a steady rising situation. The switch has the characteristics of high cost performance, high flexibility, relative simplicity, easy realization and the like, and the switch can simultaneously transmit the information packets without mutual influence, prevent transmission conflict and improve the actual throughput of the network. Therefore, ethernet technology has become the most important lan networking technology today, and network switches have become the most popular switches.

Most of the existing switches adopt a traditional distributed model, but with the explosive increase of internet bandwidth and connection, the traditional distributed architecture is less and less obvious, in the process of data transmission, the data can be distributed in sequence under the heavy weight of the data, port devices at the edge can not mutually transmit, the data also need to be transmitted to a main terminal first and then transmitted, the fluctuation delay and the lower service quality can be caused, the receiving efficiency of the data can be influenced, in the process of exchange, heat can be generated, the heat needs to be discharged from the switches, but in the process of air exchange, the air flow can not be adjusted according to the requirement, so that the switches are at normal temperature.

Disclosure of Invention

It is an object of the present invention to provide a switch with a distributed hybrid architecture for network engineering, to solve the above-mentioned problems, most of the existing switches proposed in the background art adopt the conventional distributed model, with the explosive growth of internet bandwidth and connectivity, however, traditional distributed architectures are less and less obvious, in the process of data transmission, under the condition of repeated and sequential distribution of data, port devices at the same edge can not mutually transmit, and the data also need to be transmitted to the main terminal first and then transmitted, which can cause the fluctuation delay and lower service quality, thus affecting the receiving efficiency of the data, and in the process of exchange, heat can be generated, and the heat needs to be exhausted from the exchanger, however, the air flow rate cannot be adjusted as required during the air exchange process, and the exchanger is at a normal temperature.

In order to achieve the purpose, the invention provides the following technical scheme: a switch with a distributed mixed structure for network engineering comprises a switch main body and a fixing plate, wherein one side of the outer wall of the switch main body is provided with a charging hole, one side of the outer wall of the switch main body is provided with a heat dissipation strip hole, one side of the outer wall of the switch main body is provided with a connecting port, the bottom of the lower end of the switch main body is provided with a groove, a cover plate is arranged around the outer wall of the groove, the fixing plate is arranged at two sides of the inner part of the switch main body, two sides of the inner part of the fixing plate are provided with a heat conversion mechanism, an airflow groove is arranged in the inner part of the fixing plate, two sides of the outer wall of the fixing plate are provided with a limiting rail plate, the middle end of the inner side of the limiting rail plate is provided with an airflow control mechanism, the middle end of the inner part of the switch main body is provided with a data machine body, one side of the outer wall of the data machine body is provided with a fixing block, and the joint of the outer wall of the fixing block and the inner wall of the switch main body is provided with a fixing bolt, and a wire group is arranged at the joint of the inner side of the charging hole and the outer wall of the airflow control mechanism.

Preferably, the switch main body passes through to constitute detachable construction between recess and the apron, and is the horizontal form between switch main body and the apron and distributes.

Preferably, the switch main body forms a bolt structure through a fixing bolt and a fixing block, and the fixing block is distributed in an L shape.

Preferably, the fixed plate is distributed along the axis of the switch main body in a symmetrical shape, and a welding integrated structure is formed between the fixed plate and the switch main body.

Preferably, the airflow control mechanism comprises a rack, a movable plate and a transmission gear shaft, wherein the rack is arranged on one side of the outer wall of the movable plate, and the transmission gear shaft is arranged on one side of the outer wall of the rack.

Preferably, the movable plate forms a gear transmission structure between the rack and the transmission gear shaft, and the movable plate is symmetrically distributed along the central axis of the transmission gear shaft.

Preferably, the heat conversion mechanism comprises a cooling chamber and air nozzles, and the air nozzles are arranged on two sides of the outer wall of the cooling chamber.

Preferably, the cooling chamber is symmetrically distributed along the central axis of the fixing plate, and the cooling chamber is communicated with the air injection port.

Preferably, a sliding structure is formed between the limiting rail plate and the movable plate, and the inner wall of the limiting rail plate is distributed in a rectangular shape.

Compared with the prior art, the invention has the following beneficial effects:

1. the invention adopts the arrangement of the exchanger main body, the fixing plates and the airflow grooves, the fixing plates are symmetrically distributed along the central axis of the exchanger main body, the fixing plates are vertically positioned at two sides in the exchanger main body, the welding mode is adopted to ensure the connection strength of the connection positions, the structure is stable, the rectangular airflow groove is arranged on the inner side of the fixing plates, so that air can flow through the inner wall of the airflow groove to ensure the circulation of the air in the exchanger main body, and the invention is a main mode for discharging the heat in the exchanger main body.

2. According to the invention, through the arrangement of the airflow control mechanism, the rack, the movable plate and the transmission gear shaft, the airflow control mechanism comprises the rack, the movable plate and the transmission gear shaft, the fixed transmission gear shaft is arranged at the inner side of the outer wall of the fixed plate, so that the gear on the transmission gear shaft and the rack on the movable plate are mutually embedded, the movable plate can horizontally move by rotating the transmission gear shaft, and the airflow groove covered by the movable plate is exposed, so that a user can adjust the opening size of the airflow groove according to the requirement, and better use experience is provided.

3. The heat conversion mechanism comprises a cooling chamber and air nozzles, the air nozzles are arranged on two sides of the outer wall of the cooling chamber, the cooling chamber is symmetrically distributed along the central axis of the fixing plate, the cooling chamber is communicated with the air nozzles, the symmetrical heat conversion mechanism is arranged on two sides of the inner part of the movable plate, and the heat conversion mechanism enables the cooling chamber to generate cold air through an external control module to be sprayed out from the air nozzles on the inner side, so that the cold air can be uniformly transmitted through the inner part of the exchanger main body under the circulation of air to cool and remove heat of an internal data machine body.

Drawings

Fig. 1 is a schematic perspective view of a switch with a distributed hybrid structure for network engineering according to the present invention;

FIG. 2 is a schematic diagram of the internal structure of a flushing head of a switch with a distributed hybrid structure for network engineering according to the present invention;

FIG. 3 is a schematic bottom view of a switch with a distributed hybrid architecture for network engineering according to the present invention;

fig. 4 is a schematic side view of a fixed board of a switch with a distributed hybrid structure for network engineering according to the present invention;

fig. 5 is a schematic diagram of a control system of a switch with a distributed hybrid structure for network engineering according to the present invention.

In the figure: 1. a switch main body; 2. a fixing plate; 3. an airflow control mechanism; 301. a rack; 302. a movable plate; 303. a drive gear shaft; 4. an air flow groove; 5. a heat transfer mechanism; 501. a cooling chamber; 502. an air jet port; 6. a groove; 7. a cover plate; 8. a charging hole; 9. a wire set; 10. a connection port; 11. a fixed block; 12. a data body; 13. a limiting rail plate; 14. heat dissipation bar holes; 15. and fixing the bolt.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: a switch with a distributed mixed structure for network engineering comprises a switch main body 1, a fixing plate 2, an airflow control mechanism 3, an airflow groove 4, a heat conversion mechanism 5, a groove 6, a cover plate 7, a charging hole 8, a wire group 9, a connecting port 10, a fixing block 11, a data machine body 12, a limiting rail plate 13, a radiating strip hole 14 and a fixing bolt 15, wherein the charging hole 8 is arranged on one side of the outer wall of the switch main body 1, the radiating strip hole 14 is arranged on one side of the outer wall of the switch main body 1, the connecting port 10 is arranged on one side of the outer wall of the switch main body 1, the groove 6 is arranged at the bottom of the lower end of the switch main body 1, the cover plate 7 is arranged on the periphery of the outer wall of the groove 6, the fixing plate 2 is arranged on two sides of the interior of the switch main body 1, the heat conversion mechanism 5 is arranged on two sides of the interior of the fixing plate 2, and the airflow groove 4 is arranged in the interior of the fixing plate 2, the outer wall both sides of fixed plate 2 are provided with spacing rail plate 13, and the inboard middle-end of spacing rail plate 13 is provided with airflow control mechanism 3, and the inside middle-end of switch main part 1 is provided with data organism 12, and outer wall one side of data organism 12 is provided with fixed block 11, and the outer wall of fixed block 11 and the inner wall junction of switch main part 1 are provided with fixing bolt 15, and the inboard of hole 8 that charges and airflow control mechanism 3's outer wall junction are provided with group 9.

In the invention:

switch main part 1 passes through recess 6 and apron and constitutes detachable construction between 7, and be the level form between switch main part 1 and the apron 7 and distribute, recess 6 of rectangle is seted up to the lower extreme in switch main part 1, the user can come to maintain its switch main part 1's structure through recess 6, reach the purpose of switch main part 1 long-term use, can laminate on recess 6's outer wall and place apron 7, and fix its department with the screw, come to seal its switch main part 1's inside, make switch main part 1's lower surface and apron 7 locate on same horizontal plane, guarantee this switch main part 1's long-term stability.

The switch main part 1 passes through and constitutes the bolt construction between fixing bolt 15 and the fixed block 11, and the fixed block 11 is L form and distributes, and the outer wall of this fixed block 11 is L form, adopts welded mode with its one end, fixes the outer wall side at data organism 12, and the card hole on the rethread fixed block 11 fixes it on the inner wall of switch main part 1, fixes its inside data organism 12, guarantees the stability of its during use.

Fixed plate 2 is the symmetry form along the axis department of switch main part 1 and distributes, and constitute integrative structure of welding between fixed plate 2 and the switch main part 1, fixed plate 2 is the inside both sides that vertical form is in switch main part 1, adopt the welded mode, guarantee the joint strength of its junction, stable in structure, air current groove 4 of rectangle begins to have on the inboard of fixed plate 2, make the air can follow the interior wall flow of air current groove 4 and pass through, guarantee the circulation of the inside air of switch main part 1, be the main mode with heat outgoing in switch main part 1.

The airflow control mechanism 3 comprises a rack 301, a movable plate 302 and a transmission gear shaft 303, wherein the rack 301 is arranged on one side of the outer wall of the movable plate 302, a transmission gear shaft 303 is arranged on one side of the outer wall of the rack 301, the movable plate 302 forms a gear transmission structure through the rack 301 and the transmission gear shaft 303, the movable plate 302 is symmetrically distributed along the central axis of the transmission gear shaft 303, the fixed transmission gear shaft 303 is arranged on the inner side of the outer wall of the fixed plate 2, so that a gear on the transmission gear shaft 303 and the rack 301 on the movable plate 302 are mutually embedded, the movable plate 302 can horizontally move by rotating the transmission gear shaft 303, and the airflow groove 4 covered by the movable plate 302 is exposed, so that a user can adjust the opening size of the airflow groove 4 according to requirements, and better use experience is provided.

The heat conversion mechanism 5 comprises a cooling chamber 501 and an air jet 502, the air jet 502 is arranged on two sides of the outer wall of the cooling chamber 501, the cooling chamber 501 is symmetrically distributed along the central axis of the fixing plate 2, the cooling chamber 501 is communicated with the air jet 502, the heat conversion mechanism 5 is symmetrically arranged on two sides of the inner part of the movable plate 302, and the heat conversion mechanism 5 enables the cooling chamber 501 to generate cold air through an external control module to be sprayed out of the air jet 502 on the inner side, so that the cold air can be uniformly transmitted through the inner part of the exchanger main body 1 under the circulation of air to cool and remove heat of the data body 12 inside.

A sliding structure is formed between the limiting rail plate 13 and the movable plate 302, the inner wall of the limiting rail plate 13 is distributed in a rectangular shape, the upper side and the lower side of the movable plate 302 are provided with the horizontal limiting rail plate 13, the rectangular inner wall of the limiting rail plate 13 is embedded with the movable plate 302, and when the movable plate 302 is moved horizontally, the limiting rail plate 13 can play a good auxiliary limiting role to ensure the stability of the movable plate 302 in the sliding process.

The working principle of the embodiment is as follows: when the switch with the distributed mixed structure is used, a user respectively fixes a plurality of switch main bodies 1 at proper positions to respectively connect the switch main bodies 1 through transmission lines, so that each switch main body 1 can play the role of a main switch main body 1 to provide storage and distribution data to other switch main bodies 1, and each switch main body 1 also can play the role of a marginal switch main body 1 to reduce the frequent times of data distribution and ensure the faster data transmission speed, when the switch main body 1 generates heat in the switching process, a power supply group can be driven through a control module group to drive a gear shaft 303 to rotate, so that a movable plate 302 can horizontally move through gear engagement, and an airflow groove 4 covered by the movable plate 302 is exposed, the opening size of airflow groove 4 can be adjusted according to the requirement of the user, better use experience is provided, and meanwhile, the cooling chamber 501 in heat conversion mechanism 5 can generate cold air through the external control module to be sprayed out from the inner side air jet 502, so that the cold air can uniformly spread inside exchanger body 1 under the circulation of air to cool and remove heat of the data machine body 12 inside.

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 various changes in the embodiments and/or modifications of the invention can be made, and equivalents and modifications of some features of the invention can be made without departing from the spirit and scope of the invention.

Claims (6)

1. A switch with a distributed hybrid structure for network engineering, comprising a switch main body (1) and a fixed plate (2), characterized in that: the switch is characterized in that a charging hole (8) is formed in one side of the outer wall of the switch main body (1), a radiating strip hole (14) is formed in one side of the outer wall of the switch main body (1), a connecting port (10) is formed in one side of the outer wall of the switch main body (1), a groove (6) is formed in the bottom of the lower end of the switch main body (1), cover plates (7) are arranged on the periphery of the outer wall of the groove (6), fixing plates (2) are arranged on two sides of the interior of the switch main body (1), a heat conversion mechanism (5) is arranged on two sides of the interior of each fixing plate (2), an airflow groove (4) is formed in the interior of each fixing plate (2), limiting rail plates (13) are arranged on two sides of the outer wall of each fixing plate (2), an airflow control mechanism (3) is arranged at the middle ends of the inner sides of the limiting rail plates (13), and a data machine body (12) is arranged at the middle end of the interior of the switch main body (1), and one side of the outer wall of the data machine body (12) is provided with a fixed block (11), a connecting part of the outer wall of the fixed block (11) and the inner wall of the switch main body (1) is provided with a fixing bolt (15), a connecting part of the inner side of the charging hole (8) and the outer wall of the air flow control mechanism (3) is provided with a wire group (9), the air flow control mechanism (3) comprises a rack (301), a movable plate (302) and a transmission gear shaft (303), one side of the outer wall of the movable plate (302) is provided with the rack (301), one side of the outer wall of the rack (301) is provided with the transmission gear shaft (303), the movable plate (302) forms a gear transmission structure through the rack (301) and the transmission gear shaft (303), the movable plate (302) is symmetrically distributed along the central axis of the transmission gear shaft (303), the heat conversion mechanism (5) comprises a cooling chamber (501) and an air jet (502), and air nozzles (502) are arranged on two sides of the outer wall of the cooling chamber (501).

2. A switch with a distributed hybrid architecture for network engineering according to claim 1, characterized in that: the switch main body (1) forms a detachable structure through the groove (6) and the cover plate (7), and the switch main body (1) and the cover plate (7) are distributed horizontally.

3. A switch with a distributed hybrid architecture for network engineering according to claim 1, characterized in that: the switch main body (1) forms a bolt structure through the fixing bolt (15) and the fixing block (11), and the fixing block (11) is distributed in an L shape.

4. A switch with distributed hybrid architecture for network engineering according to claim 1, characterized in that: the fixed plate (2) is symmetrically distributed along the central axis of the switch main body (1), and a welding integrated structure is formed between the fixed plate (2) and the switch main body (1).

5. A switch with a distributed hybrid architecture for network engineering according to claim 1, characterized in that: the cooling chamber (501) is symmetrically distributed along the central axis of the fixing plate (2), and the cooling chamber (501) is communicated with the air injection port (502).

6. A switch with a distributed hybrid architecture for network engineering according to claim 1, characterized in that: a sliding structure is formed between the limiting rail plate (13) and the movable plate (302), and the inner wall of the limiting rail plate (13) is distributed in a rectangular shape.

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