CN219875796U - Temperature self-adaptive network switching equipment - Google Patents

Abstract

The utility model relates to the technical field of temperature self-adaptive network switching equipment, and provides temperature self-adaptive network switching equipment which comprises a plurality of switches, wherein the switch comprises an equipment shell, a plurality of first radiating mechanisms and a plurality of second radiating mechanisms, the first radiating mechanisms, the second radiating mechanisms and the switches are all positioned in the equipment shell, the equipment shell comprises a top exhaust port, a plurality of fixing frames, a plurality of clamping grooves for embedding the first radiating mechanisms and a plurality of back exhaust ports, connecting plates and connecting grooves are arranged on two sides of the equipment shell, the switches are fixedly connected with the fixing frames, the fixing frames are sequentially arranged along the linear direction, the first radiating mechanisms are positioned above the switches, the second radiating mechanisms are positioned between adjacent switches and above the first radiating mechanisms, the back exhaust ports are parallel to the second radiating mechanisms, and the second radiating mechanisms face the back exhaust ports. Through the technical scheme, the problem of temperature rise in the running process of the exchange equipment in the prior art is solved.

Description

Temperature self-adaptive network switching equipment

Technical Field

The utility model relates to the technical field of temperature self-adaptive network switching equipment, in particular to temperature self-adaptive network switching equipment.

Background

The network switching device is a network hardware device composed of a plurality of switches, and can connect different devices on a computer network by exchanging messages to receive and forward data to a target device.

The switch can gradually generate heat in the operation process, and when the temperature reaches a certain degree, the operation of the switch can be influenced. And along with the increase of workload, more switches need to be added, a plurality of switches run simultaneously, the temperature rise can be faster, the running of the network switch is not smooth enough, the switch can be burnt down even, short circuit is caused, and the network switch equipment is damaged smoothly.

Disclosure of Invention

The utility model provides a temperature self-adaptive network switching device, which solves the problem of temperature rise in the operation process of the switching device and ensures the running stability of the device.

The technical scheme of the utility model is as follows:

the utility model provides a temperature self-adaptation formula network switching equipment, including a plurality of switches, including the equipment casing, a plurality of first cooling mechanism and a plurality of second cooling mechanism, first cooling mechanism, the second cooling mechanism, the switch all is located inside the equipment casing, the equipment casing includes top gas vent and a plurality of mount, a plurality of draw-in grooves that supply first cooling mechanism to imbed, a plurality of back gas vent, and equipment casing both sides all are equipped with connecting plate and spread groove, switch and mount fixed connection, mount are arranged in proper order along the linear direction, first cooling mechanism is located the switch top, second cooling mechanism is located between the adjacent switch, and be located first cooling mechanism top, back gas vent is on a parallel with second cooling mechanism, and second cooling mechanism is towards back gas vent.

Further, the first heat dissipation mechanism comprises a first heat dissipation plate and a plurality of heat dissipation units, the second heat dissipation mechanism comprises a second heat dissipation plate and a plurality of heat dissipation units, and the first heat dissipation mechanism and the second heat dissipation mechanism are fixedly connected with the equipment shell.

Further, be equipped with the spacing groove that supplies the radiating element embedding on the first heating panel, a plurality of radiating element one-to-one electricity connect the spacing groove, and spacing groove both sides all are equipped with the stopper, spacing groove and stopper integrated into one piece, and the spacing groove is arranged in proper order along the linear direction.

Further, be equipped with the spacing groove that supplies the heat dissipation unit embedding on the second heating panel, a plurality of heat dissipation units one-to-one electricity connect the spacing groove, and the spacing groove both sides all are equipped with the stopper, spacing groove and stopper integrated into one piece to arrange in proper order along the linear direction, second heating panel both ends are equipped with baffle and fixed orifices respectively, and the width of second heating panel is less than or equal to the width of first heating panel.

Further, the heat dissipation unit comprises a unit shell and a heat dissipation fan, wherein a plurality of air holes are formed in the surface of the unit shell, and the air holes are sequentially arranged along the linear direction.

Further, the width of the second heat dissipation mechanism is smaller than the gap between the adjacent fixing frames.

Further, the central axis of the first heat dissipation mechanism is perpendicular to the central axis of the second heat dissipation mechanism.

Furthermore, the heat-sensitive sensors are arranged in the fixing frames, and each heat-sensitive sensor is respectively and electrically connected with the first heat dissipation mechanism and the second heat dissipation mechanism.

The working principle and the beneficial effects of the utility model are as follows:

1. in the utility model, the heat dissipation is carried out through the first heat dissipation mechanism and the second heat dissipation mechanism, and the heat dissipation fans are arranged in the first heat dissipation mechanism and the second heat dissipation mechanism. And after the first heat dissipation mechanism discharges the hot air of the exchanger, the second heat dissipation mechanism discharges the hot air from the air outlet. And because there may be a plurality of switches in the equipment, just be equipped with an gas vent that supplies second heat dissipation mechanism to discharge the steam between the adjacent switch, the switch that is located the top can directly be through first heat dissipation mechanism with the steam can directly follow the gas vent that the top was seted up and discharge.

2. The air flow is driven by the cooling fan to dissipate heat, and the cooling fan has the obvious advantages of wide speed regulation range, controllability, reliability, light weight, environmental protection, energy conservation, environmental tolerance, economy and the like.

Drawings

The utility model will be described in further detail with reference to the drawings and the detailed description.

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a front view of the present utility model;

FIG. 3 is a schematic view of the device housing of the present utility model;

fig. 4 is a front view of the device housing of the present utility model;

FIG. 5 is a schematic structural diagram of a first heat dissipating mechanism according to the present utility model;

FIG. 6 is a cross-sectional view of a first heat dissipating plate according to the present utility model;

FIG. 7 is a cross-sectional view of a heat dissipating unit in the present utility model;

FIG. 8 is a schematic diagram of a second heat dissipation mechanism according to the present utility model;

fig. 9 is a schematic structural diagram of a second heat dissipating plate according to the present utility model.

Reference numerals:

1. an equipment housing; 11. a fixing frame; 12. a clamping groove; 13. a connecting plate; 14. a back exhaust port; 15. a top vent; 16. a connecting groove; 2. a first heat dissipation mechanism; 21. a first heat dissipation plate; 211. a limit groove; 212. a limiting block; 22. a heat radiation unit; 221. a unit housing; 222. a heat radiation fan; 223. air holes; 3. a switch; 4. a second heat dissipation mechanism; 41. a second heat dissipation plate; 411. a baffle; 412. a fixing hole; 5. a heat sensitive sensor.

Detailed Description

The technical solutions of the embodiments of the present utility model will be clearly and completely described below in conjunction with the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1 to 4, a temperature-adaptive network switching device includes a device housing 1, a plurality of switches 3, a plurality of first heat dissipation mechanisms 2 and a plurality of second heat dissipation mechanisms 4, wherein the first heat dissipation mechanisms 2, the second heat dissipation mechanisms 4 and the switches 3 are all located inside the device housing 1, the device housing 1 includes a top air outlet 15 and a plurality of fixing frames 11, a plurality of clamping slots 12 for embedding the first heat dissipation mechanisms 2, and a plurality of back air outlets 14, and both sides of the device housing 1 are respectively provided with a connecting plate 13 and a connecting slot 16, the switches 3 are fixedly connected with the fixing frames 11, the fixing frames 11 are sequentially arranged along a linear direction, the first heat dissipation mechanisms 2 are located above the switches, the second heat dissipation mechanisms 4 are located between the adjacent switches 3 and are located above the first heat dissipation mechanisms 2, the back air outlets 14 are parallel to the second heat dissipation mechanisms 4, and the second heat dissipation mechanisms 4 face the back air outlets 14.

As shown in fig. 5 and 8, the first heat dissipation mechanism 2 in the present embodiment includes a first heat dissipation plate 21 and if the heat dissipation units 22 are included, the second heat dissipation mechanism 4 includes a second heat dissipation plate 41 and a plurality of heat dissipation units 22, the first heat dissipation mechanism 2 and the second heat dissipation mechanism 4 are fixedly connected with the device housing 1, and the temperature adaptivity of the present embodiment is achieved through the two heat dissipation mechanisms.

As shown in fig. 6 and 9, a first heat dissipation plate 21 in the embodiment is provided with a limit groove 211 in which a heat dissipation unit 22 is embedded, the heat dissipation units 22 are electrically connected with the limit groove 211 in a one-to-one correspondence manner, and both sides of the limit groove 211 are provided with limit blocks 212, and the limit groove 211 and the limit blocks 212 are integrally formed and sequentially arranged along a linear direction; the second heat dissipation plate 41 is provided with a limit groove 211 in which the heat dissipation units 22 are embedded, the heat dissipation units 22 are electrically connected with the limit grooves 211 in a one-to-one correspondence manner, two sides of each limit groove 211 are respectively provided with a limit block 212, the limit grooves 211 and the limit blocks 212 are integrally formed, and the limit grooves 211 are sequentially arranged along the linear direction, so that the heat dissipation units 22 are uniformly distributed, the heat dissipation can be uniformly performed, and the phenomenon that temperature differences exist in each part is avoided.

A back exhaust port 14 for exhausting the hot air from the second heat dissipating mechanism 4 is provided between the adjacent switches 3, and the top-most switch 3 can directly exhaust the hot air from the top exhaust port 15 through the first heat dissipating mechanism 2.

Meanwhile, the central axis of the first heat dissipation mechanism 2 and the central axis of the second heat dissipation mechanism 4 are perpendicular to each other, and the width of the second heat dissipation plate 41 is smaller than or equal to the width of the first heat dissipation plate 21. Both ends of the second heat dissipation plate 41 are respectively provided with a baffle 411 and a fixing hole 412, namely the second heat dissipation plate 41 is penetrated in a connecting groove 16 formed on the equipment shell 1 and fixedly connected with the connecting plate 13 through the fixing hole 412, and the fixed connection is realized preferably through bolts, so that the installation and the disassembly are convenient; and after the second heat dissipation plate 41 is connected with the device housing 1, a gap exists at the connection part of the second heat dissipation plate 41, and the baffle 411 is used for shielding the gap, so that dust is prevented from entering the device from the gap, and the function of the device is affected.

In this embodiment, there are two switches 3, and a first heat dissipation mechanism 2 is disposed above each switch 3, so that one first heat dissipation mechanism 2 is located between two adjacent switches 3, and because the switches 3 are fixedly connected with the fixing frames 11, the first heat dissipation mechanism 2 is located in the gap between two adjacent fixing frames 11. Meanwhile, since the second heat dissipation mechanism 4 is further arranged, the central axis of the second heat dissipation mechanism 4 is perpendicular to the central axis of the first heat dissipation mechanism 2, and in such a positional relationship, the width of the second heat dissipation mechanism 4 needs to be smaller than the gap between the adjacent fixing frames 11, so that the second heat dissipation mechanism 4 is prevented from interfering with the fixing frames 11 and the first heat dissipation mechanism 2, and therefore the embodiment is not practical.

Namely, in the present embodiment, the distribution points of the heat dissipation mechanisms are in units of the switches 3, and the switches 3 positioned at the top of the device are removed to dissipate heat through the first heat dissipation mechanism 2 and the top air outlet 15; the first heat dissipation mechanism 2, the second heat dissipation mechanism 4 and the back air outlet 14 are arranged above the other switches and cooperate with each other to conduct heat dissipation.

As shown in fig. 7, the heat dissipation unit 22 of the present embodiment achieves heat dissipation through the heat dissipation unit 22, the heat dissipation unit 22 includes a unit housing 221 and a heat dissipation fan 222, when the heat dissipation fan 222 works, air is driven to flow, so that heat dissipated by the device is promoted to neutralize with ambient air, the temperature of the device is stabilized in a section, a plurality of air holes 223 are formed in the surface of the unit housing 221, and the air holes 223 are sequentially arranged along the linear direction, so that uniform flow of air can be ensured.

As shown in fig. 2, a heat-sensitive sensor 5 is disposed in a fixing frame 11 in this embodiment, each heat-sensitive sensor 5 is electrically connected to a first heat dissipation mechanism 2 and a second heat dissipation mechanism 4, respectively, the temperature of the switch 3 will continuously rise in the working process, when the temperature reaches a certain value, the heat-sensitive sensor 5 will be triggered, the heat-sensitive sensor 5 sends a signal, the device will supply power to the heat dissipation mechanism, that is, the operation of the heat dissipation mechanism is controlled by the heat-sensitive sensor 5, so as to ensure the temperature self-adaptability of this embodiment.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (8)

1. The utility model provides a temperature self-adaptation formula network switching equipment, includes a plurality of switch (3), a serial communication port, including equipment casing (1), a plurality of first cooling mechanism (2) and a plurality of second cooling mechanism (4), first cooling mechanism (2), second cooling mechanism (4), switch (3) all are located inside equipment casing (1), equipment casing (1) are including top gas vent (15), a plurality of mount (11), a plurality of draw-in grooves (12) that supply first cooling mechanism (2) to imbed, a plurality of back gas vent (14), and equipment casing (1) both sides all are equipped with connecting plate (13) and spread groove (16), switch (3) and mount (11) fixed connection mount (11) arrange in proper order along the linear direction, first cooling mechanism (2) are located switch top, second cooling mechanism (4) are located between adjacent switch (3) and are located first cooling mechanism (2) top, back gas vent (14) are on a parallel with second cooling mechanism (4), and second cooling mechanism (4) orientation back gas vent (14).

2. The temperature-adaptive network switching device according to claim 1, wherein the first heat dissipation mechanism (2) comprises a first heat dissipation plate (21) and a plurality of heat dissipation units (22), the second heat dissipation mechanism (4) comprises a second heat dissipation plate (41) and a plurality of heat dissipation units (22), and the first heat dissipation mechanism (2) and the second heat dissipation mechanism (4) are fixedly connected with the device housing (1).

3. The temperature-adaptive network switching device according to claim 2, wherein the first heat dissipation plate (21) is provided with a limiting groove (211) in which the heat dissipation units (22) are embedded, the plurality of heat dissipation units (22) are electrically connected with the limiting groove (211) in a one-to-one correspondence manner, limiting blocks (212) are respectively arranged on two sides of the limiting groove (211), the limiting groove (211) and the limiting blocks (212) are integrally formed, and the limiting grooves (211) are sequentially arranged along the linear direction.

4. The temperature-adaptive network switching device according to claim 2, wherein the second heat dissipation plate (41) is provided with a limiting groove (211) in which the heat dissipation units (22) are embedded, a plurality of the heat dissipation units (22) are electrically connected with the limiting groove (211) in a one-to-one correspondence manner, limiting blocks (212) are arranged on two sides of the limiting groove (211), the limiting groove (211) and the limiting blocks (212) are integrally formed and sequentially arranged in a linear direction, two ends of the second heat dissipation plate (41) are respectively provided with a baffle plate (411) and a fixing hole (412), and the width of the second heat dissipation plate (41) is smaller than or equal to that of the first heat dissipation plate (21).

5. The temperature-adaptive network switching device according to claim 2, wherein the heat dissipation unit (22) comprises a unit housing (221) and a heat dissipation fan (222), and a plurality of air holes (223) are formed in the surface of the unit housing (221), and the air holes (223) are sequentially arranged along the linear direction.

6. A temperature-adaptive network switching device according to claim 1, characterized in that the width of the second heat dissipation means (4) is smaller than the gap between adjacent holders (11).

7. A temperature-adaptive network switching device according to claim 1, characterized in that the central axis of the first heat dissipation means (2) and the central axis of the second heat dissipation means (4) are perpendicular to each other.

8. The temperature-adaptive network switching device according to claim 1, wherein a plurality of heat-sensitive sensors (5) are respectively arranged in the fixing frames (11), and each heat-sensitive sensor (5) is respectively and electrically connected with the first heat dissipation mechanism (2) and the second heat dissipation mechanism (4).