CN112134731A - Automatic diagnosis device for multi-service transmission network equipment fault - Google Patents

Abstract

The invention provides an automatic diagnostic device for multi-service transmission network equipment failure, which belongs to the technical field of multi-service transmission network equipment and comprises: box, loading chamber and gas circulation cooling mechanism, loading chamber detachably installs on the outer wall of box, and gas circulation cooling mechanism includes: the gas input pipe, the gas output pipe, the air current produces device and heat sink, gas input pipe and gas output pipe all are connected with the heat sink, the gas input pipe sets up and discharges gas in the box to the heat sink is inside loading the indoor, the gas output pipe sets up and discharges gas in the heat sink to the box is inside loading the indoor, heat sink, the inside gas circulation passageway that is linked together with the box that makes up jointly of gas input pipe and gas output pipe, the heat sink sets up in loading the indoor. The invention solves the problems that the existing automatic diagnosis device for the multi-service transmission network equipment fault has an imperfect heat dissipation effect and can damage internal electronic components.

Description

Automatic diagnosis device for multi-service transmission network equipment fault

The technical field is as follows:

the invention belongs to the technical field of multi-service transmission network equipment, and particularly relates to an automatic fault diagnosis device for multi-service transmission network equipment.

Background art:

with the increasing demand for the transmission of multiple services such as IP data, voice, image, etc., in the communication field, the transport network needs to provide multiple service carrying capability. The multi-service transmission platform series equipment is transmission network node equipment, is a bridge area for fusing a data network and a voice network, is based on an SDH (synchronous digital hierarchy) platform, simultaneously supports and bears multiple services such as TDM (time division multiplexing), ATM (automatic Teller machine), Ethernet and the like, and can provide access, processing and transmission. When the multi-service transmission network equipment fails, the automatic diagnosis device for the multi-service transmission network equipment failure diagnoses the multi-service transmission network equipment failure, so that the diagnosis efficiency is improved.

Electronic information is received in the automatic diagnosis device of multiservice transmission network equipment trouble, various electronic components of processing and transmission can dispel the heat at the during operation, and multiservice transmission network equipment trouble automatic diagnosis device periphery comprises the box, the heat that electronic components gived off can gather in the box, lead to the temperature rise in the box, if not timely heat dissipation, high temperature environment can cause the damage to electronic components, the radiating mode of trompil on the lateral wall is generally taken to current box, but this radiating mode is unsatisfactory, not only the radiating efficiency is low, still can introduce external dust and get into the box, fall on electronic components, can cause contact failure to inside electronic components along with operating time's increase, even short circuit, these troubles can lead to electronic components unable normal work.

Therefore, there is a need to develop an automatic diagnostic device for the failure of the multi-service transmission network equipment, which facilitates heat dissipation and does not damage the internal electronic components.

The invention content is as follows:

the embodiment of the invention provides an automatic diagnosis device for equipment faults of a multi-service transmission network, which solves the problems that the existing automatic diagnosis device for equipment faults of the multi-service transmission network is not ideal in heat dissipation effect and can damage internal electronic components.

The embodiment of the invention provides an automatic diagnosis device for multi-service transmission network equipment faults, which comprises:

a case in which electronic components are built;

further comprising:

a loading chamber detachably mounted on an outer wall of the case and communicating with an inside of the case;

gas cycle cooling mechanism, it includes: gaseous input tube, gas output tube, air current produce device and heat sink, gaseous input tube with gaseous output tube all with the heat sink is connected, gaseous input tube sets up load indoor and will gaseous in the box to the inside emission of heat sink, gaseous output tube sets up load indoor and will gaseous in the heat sink to the inside emission of box, the heat sink gaseous input tube with the inside gas circulation passageway that makes up jointly of gas output tube with the box is inside to be linked together, gaseous produce device be in form in the gas circulation passageway by gaseous input tube to the air current that the gas output tube direction flows, the heat sink sets up load indoor.

In certain embodiments, the cooling device comprises:

the upper end and the lower end of the cylinder are respectively provided with an air inlet and an air outlet;

the partition plate is arranged on the inner side wall of the cylinder and divides the cylinder into an upper space and a lower space, wherein the upper space is used for storing cooling liquid and is positioned above the lower space;

the pipe of bending, it is made by the heat conduction material and is including the pipe section of bending, the pipe section of admitting air and the pipe section of giving vent to anger, the pipe section of bending is become by the first pipe section of bending and the second pipe section of bending intertwine, the upper end of the pipe section of admitting air the lower extreme of the pipe section of giving vent to anger with the lower extreme of the pipe section of bending, the pipe section of bending with the pipe section of giving vent to anger and the pipe section of admitting air all sets up in the top space, the lower extreme of the pipe section of admitting air alternates in the baffle, the one end of gas input tube by the air inlet of barrel extends in the below space and with the pipe section of admitting air is inside to be passed through the below space is linked together, the one end.

In certain embodiments, the cooling device further comprises:

the mounting frame is provided with a gas transmission channel and is mounted in the space below the cylinder, and the gas transmission channel is communicated with the gas input pipe and the gas inlet pipe section; and

and the water absorption cotton is installed in the gas transmission channel of the mounting rack and covers the gas circulation area of the gas transmission channel.

In certain embodiments, the cooling device further comprises:

the lower end of the extrusion frame falls on the top surface of the absorbent cotton, the upper end of the extrusion frame is provided with a pressing section which extends horizontally outwards, and the upper end of the mounting frame is provided with an L-shaped pressure-bearing section which extends outwards; a movable mounting gap is formed between the pressing section of the extrusion frame and the pressure-bearing section of the mounting frame;

a first spring disposed in the movable mounting gap and extending and retracting in a vertical direction; and

and the pressing mechanism is used for pressing the extrusion frame so that the extrusion frame moves up and down.

In certain embodiments, the pressing mechanism comprises:

the mounting cylinder is internally provided with a cylinder hole;

the second spring is arranged in the cylinder hole of the mounting cylinder;

a collar disposed in a bore of the mounting barrel for stopping the second spring;

the upper end of the movable shaft penetrates through the partition plate and the shaft collar and is fixedly connected with the lower end of the second spring positioned in the cylinder hole of the mounting cylinder, and the lower end of the movable shaft extends to the pressing section of the extrusion frame;

the lower end of the pressure lever is fixedly connected with the upper end of the second spring; and

and the pressing plate is horizontally and fixedly connected to the upper end of the pressing rod.

In some embodiments, the mounting frame includes a sleeve and a mounting plate transversely disposed in the sleeve, the sleeve is disposed in the lower space, two ends of the sleeve are respectively provided with an upper vent port and a lower vent port, the upper vent port of the sleeve is aligned with the lower port of the air inlet pipe section, the lower vent port of the sleeve is aligned with one end of the air inlet pipe, the inner space of the sleeve is communicated with the air inlet pipe and the air inlet pipe section, the mounting plate is provided with vent holes, and the absorbent cotton is fixed on the top surface of the mounting plate.

In some embodiments, the mounting bracket further includes a first arc-shaped plate and a second arc-shaped plate, the first arc-shaped plate and the second arc-shaped plate are obliquely arranged on the inner side wall of the sleeve in a staggered manner, the first arc-shaped plate is located above the second arc-shaped plate and below the mounting plate, the cooling device further includes a water collecting pipe and a water storage tank, the water storage tank is located on the outer side wall of the barrel, the water collecting pipe is arranged in a downward inclined manner, one end of the water collecting pipe is jointed to the water falling end of the second arc-shaped plate, and the other end of the water collecting pipe extends to the water storage tank.

In some embodiments, the loading chamber is clamped on an opening door of the box body, an L-shaped stop shaft is rotatably connected to the opening door of the box body, and the stop shaft abuts against the front face of the loading chamber.

In some embodiments, the airflow generating device employs a fan.

The loading chamber is detachably arranged on the side wall of the box body of the automatic diagnosis device for the equipment fault of the multi-service transmission network, the gas circulation cooling mechanism in the loading chamber is used for cooling hot gas in the box body by introducing the hot gas into the cooling device and discharging the cooled gas into the box body again, in the process, holes do not need to be formed in the box body for heat dissipation, external dust is prevented from entering the box body, and the problems that the heat dissipation effect of the existing automatic diagnosis device for the equipment fault of the multi-service transmission network is not ideal and internal electronic components are damaged are solved.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

Description of the 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 principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a schematic view of the connection between the gas circulation cooling mechanism and the loading chamber;

FIG. 2 is a schematic structural view of the present invention;

reference numerals: 10. a box body; 20. a loading chamber; 30. a gas circulation cooling mechanism; 301. a gas input pipe; 302. a gas output pipe; 303. an air flow generating device; 304. a cooling device; 3041. a barrel; 30411. an upper space; 30412. a lower space; 3042. a partition plate; 3043. bending the pipe; 30431. bending the pipe section; 304311, a first bend section; 304312, a second folded tube section; 30432. an air intake pipe section; 30433. an air outlet pipe section; 3044. a mounting frame; 30441. a gas transmission channel; 30442. a pressure-bearing section; 30443. a sleeve; 304431, an upper vent; 304432, lower vent; 30444. mounting a plate; 304441, air holes; 30445. a first arc-shaped plate; 30446. a second arc-shaped plate; 3045. absorbent cotton; 3046. an extrusion frame; 30461. a pressing section; 3047. a first spring; 3048. a pressing mechanism; 30481. mounting the cylinder; 30482. a second spring; 30483. a collar; 30484. a movable shaft; 30485. a pressure lever; 30486. a pressing plate; 3049. a water collection pipe; 30410. a water storage tank; 40. a gas circulation channel; 50. a gear shaft.

The specific implementation mode is as follows:

in order to make the objects, technical solutions and advantages of the technical solutions of the present invention clearer, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the drawings of the specific embodiments of the present invention. Like reference symbols in the various drawings indicate like elements. It should be noted that the described embodiments are only some embodiments of the invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the described embodiments of the invention without any inventive step, are within the scope of protection of the invention.

As shown in fig. 1-2, an embodiment of the present invention provides an apparatus for automatically diagnosing a failure of a multi-service transmission network device, including: the box body 10, the loading chamber 20 and the gas circulation cooling mechanism 30.

Electronic components are built in the case 10, and the electronic components generate heat in the case 10 when operating.

The gas circulation cooling mechanism 30 includes: gas input pipe 301, gas output pipe 302, gas flow generator 303 and heat sink 304, gas input pipe 301 and gas output pipe 302 all are connected with heat sink 304, gas input pipe 301 sets up in loading room 20 and discharges the interior gas of box 10 to the inside of heat sink 304, gas output pipe 302 sets up in loading room 20 and discharges the interior gas of heat sink 304 to the inside of box 10, heat sink 304, gas input pipe 301 and the inside gas output pipe 302 group together become the gas circulation passageway 40 that is linked together with the box 10 inside, gas generator forms the gas flow that flows by gas input pipe 301 to gas output pipe 302 direction in gas circulation passageway 40, heat sink 304 sets up in loading room 20 and is used for reducing the hot gas temperature.

The loading chamber 20 is detachably installed on an outer wall of the casing 10 and communicates with the inside of the casing 10

When the gas circulation cooling mechanism 30 needs to be disassembled and maintained, the loading chamber 20 can be disassembled and assembled for convenient operation. Wherein, the loading chamber 20 may be a box-shaped structure.

During operation, the gas with heat in the box 10 can firstly enter the cooling device 304 through the gas input pipe 301 under the action of the gas flow generating device 303, and after the cooling device 304 performs cooling treatment, the gas is discharged into the box 10 again through the gas output pipe 302, and the whole process does not perform gas exchange with the outside, so that dust is not introduced into the box 10.

As shown in FIG. 1, in one embodiment, the cooling device 304 includes: a cylinder 3041, a baffle 3042 and a bending pipe 3043.

The upper end and the lower end of the cylinder 3041 are respectively provided with an air inlet and an air outlet.

The partition 3042 is disposed on an inner sidewall of the barrel 3041, and specifically, the partition 3042 may be mounted on the inner sidewall of the barrel 3041 by a clamping manner.

The partition 3042 divides the cylinder 3041 into an upper space 30411 and a lower space 30412, wherein the upper space 30411 is used for storing a cooling liquid such as low-temperature water and is located above the lower space 30412.

The bent pipe 3043 is made of a heat conductive material such as copper and includes a bent pipe segment 30431, an air inlet pipe segment 30432 and an air outlet pipe segment 30433, the bent pipe segment 30431 is formed by winding a first bent pipe segment 304311 and a second bent pipe segment 304312, the upper end of the air inlet pipe segment 30432 and the lower end of the air outlet pipe segment 30433 are connected to the lower end and the upper end of the bent pipe segment 30431, the air outlet pipe segment 30433 and the air inlet pipe segment 30432 are both disposed in the upper space 30411, the lower end of the air inlet pipe segment 30432 is inserted into the partition 3042, the connection between the air inlet pipe segment 30432 and the partition 3042 can be sealed by waterproof treatment, for example, a sealing ring is disposed, one end of the gas input pipe segment 301 extends from the gas inlet of the cylinder 3041 into the lower space 30412 and communicates with the interior of the air inlet pipe segment 30432 through the lower space 304. The bent pipe section 30431 of the bent pipe 3043 is configured to extend the heat dissipation path of the gas, so that the heat dissipation time of the gas in the bent pipe 3043 in the pipe is prolonged, and the heat dissipation effect is good. The gas in the box 10 enters the lower space 30412 through the gas input pipe 301, enters the gas inlet pipe 30432 through the lower space 30412, and then sequentially enters the bent pipe 30431, the gas outlet pipe 30433, and the gas outlet pipe 302.

As shown in FIG. 1, in one embodiment, the cooling device 304 further comprises: a mounting bracket 3044 and absorbent cotton 3045.

The mounting bracket 3044 has a gas transmission channel 30441 and is installed in the lower space 30412 of the cylinder 3041, the gas transmission channel 30441 communicates the gas input pipe 301 and the gas input pipe 30432,

the absorbent cotton 3045 is installed in the gas transmission passage 30441 of the mounting bracket 3044 and covers the gas flow area of the gas transmission passage 30441. Considering that in seasons or regions with much moisture in the air, the gas in the box body 10 is liquefied into water drops when meeting cold in the bent pipe 3043 and is discharged from the gas inlet pipe 30432 along the bent pipe 3043, which easily causes water accumulation in the box body 10, in order to discharge the adverse factor, the absorbent cotton 3045 is provided, and the absorbent cotton 3045 can absorb the water drops flowing down from the gas inlet pipe 30432, and not only does the absorbent cotton 3045 perform moisture absorption on the absorbent cotton 3045 in advance when the gas does not enter the bent pipe 3043. The absorbent cotton 3045 is positioned right below the lower port of the intake pipe section 30432.

As shown in FIG. 1, in one embodiment, the cooling device 304 further comprises: a pressing frame 3046 and a first spring 3047.

The lower end of the extrusion frame 3046 falls on the top surface of the absorbent cotton 3045, the upper end of the extrusion frame 3046 has a pressing section 30461 extending horizontally outwards, and the upper end of the mounting frame 3044 has an L-shaped pressure-bearing section 30442 extending outwards; a movable mounting gap is formed between the pressing section 30461 of the extruding frame 3046 and the bearing section 30442 of the mounting frame 3044.

The first spring 3047 is disposed in the movable mounting gap and extends and contracts in the vertical direction; and

the pressing mechanism 3048 serves to press the pressing frame 3046 so that the pressing frame 3046 moves up and down.

Considering that the water in the absorbent cotton 3045 is accumulated too much as time goes on, and the water is not used normally, the whole loading chamber 20 is removed before the treatment, so that the water is prevented from falling into the box 10 during the treatment of the water in the absorbent cotton 3045, specifically, the absorbent cotton 3045 is treated in a process that the pressing mechanism 3048 presses the pressing frame 3046, the pressing frame 3046 moves downward and forms a pressing force on the absorbent cotton 3045 together with the mounting frame 3044, so that the water in the absorbent cotton 3045 is pressed out, the absorbent cotton 3045 can be used again, the whole process is simple, the first spring 3047 is compressed in the vertical direction during the pressing process, and the first spring 3047 returns to the initial position after the pressing process is finished, and the height of the pressing frame 3046 can be set according to the height of the first spring 3047.

As shown in fig. 1, in an embodiment, the pressing mechanism 3048 includes: a mounting cylinder 30481, a second spring 30482, a collar 30483, a movable shaft 30484, a pressure lever 30485, and a pressing plate 30486.

The mounting barrel 30481 is internally provided with a barrel hole, the second spring 30482 is arranged in the barrel hole of the mounting barrel 30481, the collar 30483 is arranged in the barrel hole of the mounting barrel 30481 and is used for stopping the second spring 30482, the upper end of the movable shaft 30484 penetrates through the partition 3042 and the collar 30483 and is fixedly connected with the lower end of the second spring 30482 in the barrel hole of the mounting barrel 30481, the movable shaft 30484 moves up and down in the hole of the partition 3042 and is correspondingly waterproof, a small amount of water leakage can flow into the absorbent cotton 3045 in time, the lower end of the movable shaft 30484 extends to the pressing section 30461 of the extrusion frame 3046, the lower end of the compression bar 30485 is fixedly connected with the upper end of the second spring 30482, and the pressing plate 30486 is horizontally and fixedly connected with the upper end of the compression bar 30485. When the pressing mechanism 3048 works, a worker presses the pressing plate 30486, the pressing rod 30485 moves downward and pushes the second spring 30482 to compress to drive the movable shaft 30484 to move vertically downward, the movable shaft 30484 contacts with the extrusion frame 3046 to drive the extrusion frame 3046 to move downward, and the second spring 30482 can also play a role in buffering in the pressing process to prevent the water absorbent cotton 3045 from being damaged due to too strong force.

As shown in fig. 1, in an embodiment, the mounting bracket 3044 includes a sleeve 30443 and a mounting plate 30444 transversely disposed in the sleeve 30443, the mounting plate 30444 and the sleeve 30443 may be welded together, the sleeve 30443 is disposed in the lower space 30412, two ends of the sleeve 30443 respectively have an upper vent opening 304431 and a lower vent opening 304432, the upper vent opening 304431 of the sleeve 30443 is aligned with the lower opening of the air inlet pipe 30432, the lower vent opening 304432 of the sleeve 30443 is abutted to one end of the air inlet pipe 301, the inner space of the sleeve 30443 is communicated with the air inlet pipe 301 and the air inlet pipe 30432, the mounting plate 30444 has air holes 304441, the water-absorbing cotton 3045 is fixed on the top surface of the mounting plate 30444 by gluing, and the mounting bracket 3044 is simple and practical in structure.

As shown in fig. 1, in an embodiment, the mounting bracket 3044 further includes a first arc-shaped plate 30445 and a second arc-shaped plate 30446, the first arc-shaped plate 30445 and the second arc-shaped plate 30446 are obliquely arranged on the inner sidewall of the sleeve 30443 in a staggered manner, the first arc-shaped plate 30445 is located above the second arc-shaped plate 30446 and below the mounting plate 30444, the cooling device 304 further includes a water collecting pipe 3049 and a water storage tank 30410, the water storage tank 30410 is located on the outer sidewall of the cylinder 3041, the water collecting pipe 3049 is arranged in a downward inclination manner, one end of the water collecting pipe 3049 is joined to the water falling end of the second arc-shaped plate 30446, the other end of the water collecting pipe 3049 extends to the water storage tank 30410, and the water squeezed from the water absorption cotton 3045 flows into the water storage tank 30410 through the first arc-shaped plate 30445, the second.

As shown in fig. 1, in an embodiment, the loading chamber 20 is clamped on the opening door of the box 10, and an L-shaped stop shaft 50 is rotatably connected to the opening door of the box 10, and the stop shaft 50 abuts against the front surface of the loading chamber 20 to prevent the loading chamber 20 from falling.

Preferably, the airflow generating device 303 employs a fan.

The loading chamber 20 is detachably mounted on the side wall of the box body 10 of the automatic diagnosis device for the equipment fault of the multi-service transmission network, the gas circulation cooling mechanism 30 in the loading chamber 20 is used for cooling hot gas in the box body 10 by introducing the hot gas into the cooling device 304 and discharging the cooled gas into the box body 10 again, in the process, holes are not needed to be formed in the box body 10 for heat dissipation, external dust is prevented from entering the box body 10, and the problems that the heat dissipation effect of the existing automatic diagnosis device for the equipment fault of the multi-service transmission network is not ideal and internal electronic components are damaged are solved.

The technical means disclosed by the scheme of the invention are not limited to the technical means disclosed by the technical means, and also comprise the technical scheme formed by equivalent replacement of the technical features. The present invention is not limited to the details given herein, but is within the ordinary knowledge of those skilled in the art.

Claims (9)

1. An automatic diagnostic device for multi-service transmission network equipment failure, comprising:

a case (10) in which electronic components are housed;

it is characterized by also comprising:

a loading chamber (20) detachably mounted on an outer wall of the case (10) and communicating with the inside of the case (10);

gas circulation cooling mechanism (30), it includes: gas input tube (301), gas output tube (302), gas flow generating device (303) and heat sink (304), gas input tube (301) with gas output tube (302) all with heat sink (304) are connected, gas input tube (301) set up in loading room (20) and with gaseous in box (10) to the inside emission of heat sink (304), gas output tube (302) set up in loading room (20) and with gaseous in heat sink (304) to the inside emission of box (10), heat sink (304), gas input tube (301) and inside the assembling of gas output tube (302) together with gas circulation passageway (40) that is linked together in box (10), gas generating device in gas circulation passageway (40) form by gas input tube (301) to the gas flow of gas output tube (302) direction flow, the cooling device (304) is disposed within the loading chamber (20).

2. The apparatus for automatic diagnosis of equipment failure in a multi-service transport network according to claim 1, characterized in that: the cooling device (304) comprises:

a cylinder (3041) having an air inlet and an air outlet at the upper and lower ends thereof, respectively;

a partition plate (3042) disposed on an inner sidewall of the cylinder (3041), the partition plate (3042) dividing the cylinder (3041) into an upper space (30411) and a lower space (30412), wherein the upper space (30411) is used for storing a cooling liquid and is located above the lower space (30412);

a bent pipe (3043) made of a heat conductive material and including a bent pipe section (30431), an air inlet pipe section (30432) and an air outlet pipe section (30433), wherein the bent pipe section (30431) is formed by mutually winding a first bent pipe section (304311) and a second bent pipe section (304312), the upper end of the air inlet pipe section (30432) and the lower end of the air outlet pipe section (30433) are connected with the lower end and the upper end of the bent pipe section (30431), the air outlet pipe section (30433) and the air inlet pipe section (30432) are both arranged in the upper space (30411), the lower end of the air inlet pipe section (30432) is inserted into the partition plate (3042), one end of the air inlet pipe (301) extends from the air inlet of the cylinder (3041) to the lower space (30412) and is communicated with the interior of the air inlet pipe section (30432) through the lower space (12), one end of the gas output pipe (302) extends to the gas outlet of the cylinder (3041).

3. The apparatus for automatic diagnosis of equipment failure in a multi-service transport network according to claim 2, characterized in that: the cooling device (304) further comprises:

a mounting rack (3044) which is provided with a gas transmission channel (30441) and is mounted in a lower space (30412) of the cylinder body (3041), wherein the gas transmission channel (30441) is communicated with the gas input pipe (301) and the gas inlet pipe section (30432); and

absorbent cotton (3045) installed in the gas transmission passage (30441) of the mounting rack (3044) and covering a gas circulation area of the gas transmission passage (30441).

4. The apparatus for automatic diagnosis of equipment failure in a multi-service transport network according to claim 3, characterized in that: the cooling device (304) further comprises:

the lower end of the extrusion frame (3046) falls on the top surface of the absorbent cotton (3045), the upper end of the extrusion frame (3046) is provided with a pressing section (30461) which extends horizontally outwards, and the upper end of the mounting frame (3044) is provided with an L-shaped pressure-bearing section (30442) which extends outwards; a movable mounting gap is arranged between the pressing section (30461) of the extrusion frame (3046) and the pressure-bearing section (30442) of the mounting frame (3044);

a first spring (3047) provided in the movable mounting gap and expanding and contracting in a vertical direction; and

a pressing mechanism (3048) for pressing the pressing frame (3046) so that the pressing frame (3046) moves up and down.

5. The apparatus for automatic diagnosis of equipment failure in a multi-service transport network according to claim 4, characterized in that: the pressing mechanism (3048) includes:

a mounting cylinder (30481) having a cylinder bore therein;

a second spring (30482) disposed within a barrel bore of the mounting barrel (30481);

a collar (30483) disposed within a bore of the mounting barrel (30481) for stopping the second spring (30482);

the upper end of the movable shaft (30484) penetrates through the partition plate (3042) and the collar (30483) and is fixedly connected with the lower end of the second spring (30482) positioned in the barrel hole of the mounting barrel (30481), and the lower end of the movable shaft (30484) extends to the pressing section (30461) of the extrusion frame (3046);

the lower end of the pressure rod (30485) is fixedly connected with the upper end of the second spring (30482); and

and the pressing plate (30486) is horizontally and fixedly connected to the upper end of the pressure rod (30485).

6. The apparatus for automatic diagnosis of equipment failure in a multi-service transport network according to claim 3, characterized in that: the mounting frame (3044) comprises a sleeve (30443) and a mounting plate (30444) transversely arranged in the sleeve (30443), the sleeve (30443) is arranged in the lower space (30412), two ends of the sleeve (30443) are respectively provided with an upper vent port (304431) and a lower vent port (304432), an upper vent port (304431) of the sleeve (30443) is aligned with a lower port of the air inlet pipe section (30432), a lower vent port (304432) of the sleeve (30443) is aligned with one end of the air inlet pipe (301), the inner space of the sleeve (30443) is communicated with the air inlet pipe section (301) and the air inlet pipe section (30432), the mounting plate (30444) is provided with a vent hole (304441), and the water absorption cotton (3045) is fixed on the top surface of the mounting plate (30444).

7. The apparatus for automatic diagnosis of equipment failure in a multi-service transport network according to claim 6, characterized in that: the mounting rack (3044) further comprises a first arc-shaped plate (30445) and a second arc-shaped plate (30446), wherein the first arc-shaped plate (30445) and the second arc-shaped plate (30446) are obliquely arranged on the inner side wall of the sleeve (30443) in a staggered manner, the first arc-shaped plate (30445) is positioned above the second arc-shaped plate (30446) and below the mounting plate (30444), the cooling device (304) further comprises a water collecting pipe (3049) and a water storage tank (30410), the water storage tank (30410) is positioned on the outer side wall of the cylinder (3041), the water collecting pipe (3049) is arranged in a downward inclined manner, one end of the water collecting pipe (3049) is jointed with the water falling end of the second arc-shaped plate (30446), and the other end of the water collecting pipe (3049) extends to the water storage tank (30410).

8. The apparatus for automatic diagnosis of equipment failure in a multi-service transport network according to claim 7, wherein: the loading chamber (20) is clamped on an opening door of the box body (10), an L-shaped stop shaft (50) is rotatably connected to the opening door of the box body (10), and the stop shaft (50) abuts against the front face of the loading chamber (20).

9. The apparatus for automatic diagnosis of equipment failure in a multi-service transport network according to claim 1, characterized in that: the airflow generating device (303) adopts a fan.

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