CN223110050U - An energy-saving green switch device - Google Patents

Abstract

The utility model belongs to the technical field of switches, and specifically relates to an energy-saving green switch device, including a shell, heat dissipation ports are respectively arranged on both sides of the shell, a switch body is arranged at one end of the shell, a plurality of communication interfaces are arranged on the switch body, a dust cleaning device is arranged above the other end of the shell, first filters are respectively arranged at both ends of the outer side of the shell, a fan is arranged in the first filter, and the fan is used to dissipate heat and cool the switch body. The utility model can quickly dissipate heat and cool the switch, and can also clean the dust generated during the cooling process through the first filter and the dust cleaning device to prevent dust from entering the interior and covering the chip, thereby requiring a longer time to control the fan to work to achieve heat dissipation, resulting in increased energy consumption.

Description

Energy-saving green switch device

Technical Field

The utility model belongs to the technical field of the switch, concretely relates to energy-saving green switch device.

Background

The switch is a network device for forwarding electric signals, and can provide an independent electric signal path for any two network nodes accessed to the switch, the most common switch is an Ethernet switch, and most of the switches use alternating current motors.

However, in actual use, when the fan dissipates heat in the exchanger, suction is generated behind the fan, so that dust is adsorbed by the suction through the through holes at the rear of the fan, and the dust can be accumulated and adhered by adding the filter screen, and part of the dust enters the inside and covers the chip, so that the fan needs to be controlled to work for a longer time to dissipate heat, and the energy consumption is increased.

Disclosure of utility model

The utility model aims to provide an energy-saving green exchanger device which can rapidly dissipate heat and cool the exchanger, and can clean dust generated in the cooling process through a first filter screen and an ash removing device, so that the dust is prevented from entering the inside and covering a chip, and a fan is controlled to work for a longer time to dissipate heat, so that energy consumption is increased.

The technical scheme adopted by the utility model is as follows:

An energy efficient green switch device comprising:

The heat exchanger comprises a shell, wherein heat dissipation ports are respectively arranged on two sides of the shell, one end of the shell is provided with an exchanger main body, a plurality of groups of communication interfaces are arranged on the exchanger main body, an ash removing device is arranged above the other end of the shell, first filter screens are respectively arranged at two ends of the outer side of the shell, a fan is arranged in each first filter screen, and the fan is used for dissipating heat and cooling the exchanger main body;

The ash removal device comprises a driving motor and a second filter screen, wherein the driving motor is used for controlling the second filter screen to move in the horizontal direction, and the second filter screen is used for filtering and cleaning dust in the shell.

As in one of the preferred embodiments of the utility model, ash removal device includes the fixed block, fixed block below and casing one end fixed connection, fixed block one side and driving motor fixed connection, driving motor output axle head fixedly connected with threaded rod, threaded connection has the movable block on the threaded rod, movable block below and second filter screen fixed connection.

In one preferred embodiment of the present invention, two ends of one side of the housing are respectively provided with an air inlet, a top end of the housing is provided with a moving through hole, a lower end of the housing is internally provided with a chute, and one side of the chute provided with the housing is provided with a rectangular through hole.

As in one of the preferred embodiments of the present invention, the first filter screen is disposed in the air inlet, and the first filter screen is fixedly connected with the housing, the lower end of the moving block is disposed in the moving through hole, the rectangular through hole is matched with one side of the second filter screen, the lower end of the second filter screen is disposed in the chute, and the second filter screen slides in the chute.

As one of the preferred embodiments of the utility model, the fixed block lower extreme is opened flutedly, the recess that the fixed block was opened and removal through-hole assorted, just threaded rod and movable block upper end set up respectively in the recess that the fixed block was opened, threaded rod both ends are connected with the fixed block rotation respectively.

In one preferred embodiment of the present invention, the heat dissipation opening is a louver.

The utility model has the technical effects that:

The energy-saving green switch device can be used for carrying out heat dissipation and temperature reduction treatment on the chips in the switch through the fan, so that the working efficiency of the switch can be greatly improved, and can be used for carrying out filtration treatment on air sucked by the fan through the first filter screen and the second filter screen, filtering part of dust in the air, preventing a large amount of dust from entering the switch and accumulating, covering the chips, and simultaneously enabling the second filter screen to be moved out of the switch through the ash removal device, and cleaning the dust on the second filter screen, so that the heat dissipation efficiency of the switch can be greatly improved, and the loss of energy consumption is reduced.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a rear elevational view of the present utility;

FIG. 3 is a schematic diagram of the present utility exploded construction;

FIG. 4 is a schematic diagram of the ash removal device;

Fig. 5 is a sectional view of the utility housing.

In the drawings, the list of components represented by the various numbers is as follows:

1. The device comprises a shell, 101, a movable through hole, 102, a rectangular through hole, 103, a sliding groove, 104, an air inlet, 2, a switch main body, 3, a communication interface, 4, a heat dissipation port, 5, an ash removing device, 501, a fixed block, 502, a driving motor, 503, a threaded rod, 504, a movable block, 505, a second filter screen, 6, a first filter screen, 7 and a fan.

Detailed Description

In order that the objects and advantages of the utility model will become more apparent, a more particular description of the utility model will be rendered by reference to specific embodiments thereof. It should be understood that the following text is used to describe only one or more specific embodiments of the present utility model and does not strictly limit the scope of protection of the specific claims.

As shown in fig. 1 and fig. 2, an energy-saving green switch device comprises a shell 1, wherein heat dissipation ports 4 are respectively arranged on two sides of the shell 1, one end of the shell 1 is provided with a switch main body 2, a plurality of groups of communication interfaces 3 are arranged on the switch main body 2, an ash removing device 5 is arranged above the other end of the shell 1, two ends of the outer side of the shell 1 are respectively provided with a first filter screen 6, a fan 7 is arranged in the first filter screen 6, and the fan 7 is used for dissipating heat and cooling the switch main body 2;

The ash cleaning device 5 includes a driving motor 502 and a second filter screen 505, the driving motor 502 is used for controlling the second filter screen 505 to move horizontally, and the second filter screen 505 is used for filtering and cleaning dust in the casing 1.

In this embodiment, when the temperature rises after the switch body 2 inside the casing 1 is operated, the fan 7 is started at this time, so that the external cold air enters the switch body 2 inside the casing 1 through the first filter screen 6 and the fan 7, and radiates heat to cool the switch body 2, while a part of dust in the cold air is filtered off while passing through the first filter screen 6, and simultaneously, when the cold air enters the casing 1 through the fan 7, the cold air directly passes through the second filter screen 505 in the ash removing device 5, so that another part of dust in the cold air can be filtered on the second filter screen 505, and at this time, the cold air passes through the second filter screen 505, radiates heat to cool the switch body 2, and is discharged through the heat radiation ports 4 on both sides of the casing 1, when the dust on the first filter screen 6 is accumulated to influence heat dissipation, the dust on the first filter screen 6 can be directly cleaned, meanwhile, the ash removal device 5 is started, the driving motor 502 starts to work, the threaded rod 503 at the output shaft end of the driving motor 502 is driven to rotate, the upper end of the moving block 504 on the threaded rod 503 moves along the groove formed by the fixed block 501, the lower end of the moving block 504 moves along the moving through hole 101, the second filter screen 505 below the moving block 504 moves outwards along the sliding groove 103 and moves to the outside of the shell 1 through the rectangular through hole 102, at the moment, the dust on the second filter screen 505 can be cleaned, and after the cleaning is finished, the ash removal device 5 is started to be controlled to reverse and recover to an initial state, so that a series of work is completed.

As shown in fig. 2 and 4, the ash removing device 5 includes a fixed block 501, the lower part of the fixed block 501 is fixedly connected with one end of the casing 1, one side of the fixed block 501 is fixedly connected with a driving motor 502, the output shaft end of the driving motor 502 is fixedly connected with a threaded rod 503, a moving block 504 is screwed on the threaded rod 503, and the lower part of the moving block 504 is fixedly connected with a second filter screen 505.

In the above manner, the ash removing device 5 is started, so that the driving motor 502 starts to work, and the threaded rod 503 at the output shaft end of the driving motor 502 is driven to rotate, so that the moving block 504 on the threaded rod 503 moves, and the second filter screen 505 below the moving block 504 moves together, and moves to the outside of the casing 1 through the rectangular through hole 102, at this time, dust on the second filter screen 505 can be cleaned, and thus loss of energy consumption can be reduced.

As shown in fig. 5, two ends of one side of the casing 1 are respectively provided with an air inlet 104, the top end of the casing 1 is provided with a moving through hole 101, the lower end of the casing 1 is internally provided with a sliding groove 103, and one side of the sliding groove 103 of the casing 1 is provided with a rectangular through hole 102.

As shown in fig. 3 to 5, the first filter screen 6 is disposed in the air inlet 104, and the first filter screen 6 is fixedly connected with the housing 1, the lower end of the moving block 504 is disposed in the moving through hole 101, the rectangular through hole 102 is matched with one side of the second filter screen 505, the lower end of the second filter screen 505 is disposed in the chute 103, and the second filter screen 505 slides in the chute 103.

As shown in fig. 4, the lower end of the fixed block 501 is provided with a groove, the groove provided by the fixed block 501 is matched with the moving through hole 101, the upper ends of the threaded rod 503 and the moving block 504 are respectively arranged in the groove provided by the fixed block 501, and two ends of the threaded rod 503 are respectively connected with the fixed block 501 in a rotating way.

In the above manner, when dust in the second filter screen 505 is accumulated to affect heat dissipation, the ash removal device 5 is started at this time, so that the driving motor 502 starts to work, thereby driving the threaded rod 503 at the output shaft end of the driving motor 502 to rotate, so that the upper end of the moving block 504 on the threaded rod 503 moves along the groove opened by the fixed block 501, the lower end of the moving block 504 moves along the moving through hole 101, so that the second filter screen 505 below the moving block 504 moves outwards along the sliding groove 103 and moves to the outside of the shell 1 through the rectangular through hole 102, at this time, dust on the second filter screen 505 can be cleaned, after cleaning is finished, the ash removal device 5 is started to be controlled to reverse and restore to the initial state, thereby effectively preventing the dust from entering the inside and covering the chip, and a longer time is required for controlling the fan 7 to work to achieve heat dissipation, and the energy consumption is increased.

As shown in fig. 3, the heat dissipation port 4 is in a louver design.

In the above-mentioned mode, the cooling port 4 is the tripe fan design, can be faster with the hot-blast discharge casing 1 in the switch main part 2 to can also prevent that the dust from getting into inside the casing 1 through the cooling port 4, and cover on the chip, thereby need the control fan 7 work of longer time in order to reach the heat dissipation, lead to the energy consumption increase.

The working principle of the utility model is as follows: when the temperature of the exchanger main body 2 inside the shell 1 is raised after the operation, the fan 7 is started at this time, so that external cold air enters the exchanger main body 2 inside the shell 1 through the first filter screen 6 and the fan 7, and radiates heat and cools the exchanger main body 2, meanwhile, part of dust in the cold air can be filtered when passing through the first filter screen 6, simultaneously, when the cold air enters the inside of the shell 1 through the fan 7, the cold air directly passes through the second filter screen 505 in the ash removal device 5, so that the other part of dust in the cold air can be filtered on the second filter screen 505, and at this time, the cold air passes through the second filter screen 505, radiates heat and cools the exchanger main body 2, and is discharged through the radiating openings 4 at two sides of the shell 1, when the dust on the first filter screen 6 is accumulated to influence the radiation, can directly clear up the dust on the first filter screen 6, simultaneously, start ash removal device 5, make driving motor 502 start working, thereby drive the threaded rod 503 of driving motor 502 output axle head and rotate, make the movable block 504 upper end on the threaded rod 503 remove along the recess that fixed block 501 opened, the movable block 504 lower extreme removes along the removal through-hole 101, thereby make the second filter screen 505 of movable block 504 below remove outside along spout 103, and move outside casing 1 through rectangular through-hole 102, can clear up the dust on the second filter screen 505 this moment, after the clearance, start control ash removal device 5, make it reverse and resume initial state, thereby accomplish a series of works.

The foregoing is merely a preferred embodiment of the present utility model and it should be noted that modifications and adaptations to those skilled in the art may be made without departing from the principles of the present utility model, which are intended to be comprehended within the scope of the present utility model. Structures, devices and methods of operation not specifically described and illustrated in the present application are all implemented by conventional means in the art unless specifically indicated and limited.

Claims (6)

1. An energy-saving green switch device, characterized in that it includes: A shell (1), heat dissipation ports (4) are respectively arranged on both sides of the shell (1), a switch body (2) is arranged at one end of the shell (1), a plurality of communication interfaces (3) are arranged on the switch body (2), a dust cleaning device (5) is arranged above the other end of the shell (1), first filter screens (6) are respectively arranged at both ends of the outer side of the shell (1), a fan (7) is arranged inside the first filter screen (6), and the fan (7) is used to dissipate heat and cool the switch body (2); The dust cleaning device (5) comprises a driving motor (502) and a second filter (505), wherein the driving motor (502) is used to control the second filter (505) to move horizontally, and the second filter (505) is used to filter and clean dust inside the housing (1). 2. An energy-saving green exchanger device according to claim 1, characterized in that: the cleaning device (5) includes a fixed block (501), the bottom of the fixed block (501) is fixedly connected to one end of the shell (1), one side of the fixed block (501) is fixedly connected to the driving motor (502), the output shaft end of the driving motor (502) is fixedly connected with a threaded rod (503), the threaded rod (503) is threadedly connected with a moving block (504), and the bottom of the moving block (504) is fixedly connected to the second filter (505). 3. An energy-saving green switch device according to claim 2, characterized in that: air inlets (104) are respectively opened at both ends of one side of the shell (1), a movable through hole (101) is opened at the top of the shell (1), a slide groove (103) is opened inside the lower end of the shell (1), and a rectangular through hole (102) is opened on one side of the slide groove (103) opened in the shell (1). 4. An energy-saving green switch device according to claim 3, characterized in that: the first filter (6) is arranged in the air inlet (104), and the first filter (6) is fixedly connected to the shell (1), the lower end of the moving block (504) is arranged in the moving through hole (101), the rectangular through hole (102) matches one side of the second filter (505), the lower end of the second filter (505) is arranged in the slide groove (103), and the second filter (505) slides in the slide groove (103). 5. An energy-saving green switch device according to claim 3, characterized in that: a groove is opened at the lower end of the fixed block (501), the groove opened by the fixed block (501) matches the movable through hole (101), and the upper ends of the threaded rod (503) and the movable block (504) are respectively arranged in the grooves opened by the fixed block (501), and the two ends of the threaded rod (503) are respectively rotatably connected to the fixed block (501). 6. An energy-saving green switch device according to claim 1, characterized in that: the heat dissipation port (4) is designed as a louver fan.