CN112399764B - Communication cabinet capable of preventing flood and water and automatically monitoring strength of signal source - Google Patents

Communication cabinet capable of preventing flood and water and automatically monitoring strength of signal source Download PDF

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Publication number
CN112399764B
CN112399764B CN202011497857.0A CN202011497857A CN112399764B CN 112399764 B CN112399764 B CN 112399764B CN 202011497857 A CN202011497857 A CN 202011497857A CN 112399764 B CN112399764 B CN 112399764B
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sliding
fixedly connected
buoyancy
wall
cavity
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CN112399764A (en
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夏婉
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Yancheng Langwei Software Co.,Ltd.
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Yancheng Hi Tech Pioneer Park Co ltd
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    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05KPRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
    • H05K7/00Constructional details common to different types of electric apparatus
    • H05K7/14Mounting supporting structure in casing or on frame or rack

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  • Engineering & Computer Science (AREA)
  • Microelectronics & Electronic Packaging (AREA)
  • Arrangements For Transmission Of Measured Signals (AREA)

Abstract

The invention discloses a communication cabinet capable of preventing flood and water and automatically monitoring the strength of a signal source, which comprises a waterproof base, wherein a buoyancy cavity with an upward opening is arranged in the waterproof base, the lower wall of the buoyancy cavity is in contact connection with three buoyancy balls, stabilizing springs are fixedly connected among the buoyancy balls, the upper ends of the buoyancy balls are fixedly connected with an equipment box, and an equipment cavity is arranged in the equipment box.

Description

Communication cabinet capable of preventing flood and water and automatically monitoring strength of signal source
Technical Field
The invention relates to the field related to communication cabinets, in particular to a flood-proof waterproof communication cabinet capable of automatically monitoring the strength of a signal source.
Background
The invention discloses a communication cabinet capable of automatically monitoring strength of a flood-proof waterproof signal source, which is characterized in that equipment and devices in the communication cabinet cannot be timely protected from water and flood in a common communication cabinet when flood disasters occur, the equipment and the devices cannot be damaged and cannot normally work, and a signal source cannot be monitored in real time in the communication cabinet, so that the communication equipment in the communication cabinet cannot always work smoothly and normally.
Disclosure of Invention
In order to solve the problems, the communication cabinet for automatically monitoring the strength of the flood control waterproof automatic monitoring signal source is designed in the embodiment, the communication cabinet for automatically monitoring the strength of the flood control waterproof automatic monitoring signal source comprises a waterproof base, a buoyancy cavity with an upward opening is arranged in the waterproof base, three buoyancy balls are in contact connection with the lower wall of the buoyancy cavity, stabilizing springs are fixedly connected between the buoyancy balls, an equipment box is fixedly connected to the upper end of each buoyancy ball, an equipment cavity is arranged in the equipment box, three partition plates are fixedly connected between the left side wall and the right side wall of the equipment cavity, a vertically through connecting port and two side through ports are arranged in the upper end surface and the lower end surface of each partition plate, the two side through ports are arranged in a bilateral symmetry mode by taking the central line of the equipment cavity as a symmetry center, eight communicators are fixedly connected between the front wall and the rear wall of the equipment cavity, and the eight communicators, four signal connecting blocks are fixedly connected to the outer peripheral surface of the communicator, the four signal connecting blocks are distributed and arranged in a vertical and bilateral symmetry mode by taking the central line of the communicator as a symmetry center, four built-in rotating shafts are rotatably connected between the front wall and the rear wall of the equipment cavity and are distributed and arranged in a vertical and bilateral symmetry mode by taking the central line of the equipment cavity as a symmetry center, built-in belt pulleys are fixedly connected to the outer peripheral surface of the built-in rotating shafts, vertical belts are rotatably connected between the built-in belt pulleys, eight fixing frames are fixedly connected to one end surface of the vertical belts which is close to the equipment cavity in the left and right direction, the eight fixing frames are distributed and arranged in a bilateral symmetry mode by taking the central line of the equipment cavity as a symmetry center, fixed wheels are fixedly connected to, the swing wheel is characterized in that a swing rod is rotatably connected on the outer peripheral surface of the swing wheel, one end of the swing rod, which is close to each other, is fixedly connected with a side fixing seat, one end of the side fixing seat, which is close to each other, is provided with a side monitor with opposite openings, one end of the isolating plate, which is close to each other, the upper wall of the buoyancy cavity, the lower wall of the buoyancy cavity, which is close to each other, is provided with four opening fixing blocks, the four opening fixing blocks are arranged in a bilateral symmetry mode by taking the central line of the equipment cavity as a symmetry center, sliding grooves with opposite openings are arranged in one end of the opening fixing blocks, two sliding shafts are rotatably connected between the front wall and the rear wall of the sliding grooves, the two sliding shafts are arranged, the peripheral surface of the pulley is connected to the inner wall of the sliding groove in a sliding manner, one end of the sliding shaft, which is close to each other up and down, is rotatably connected with a mutual repulsion magnetic rod, one end of the mutual repulsion magnetic rod, which is close to each other up and down, is fixedly connected with a moving seat, one end surface of the moving seat, which is close to each other up and down, is provided with a symmetrical annunciator with opposite openings, the lower wall of the equipment cavity is rotatably connected with a middle threaded shaft, the peripheral surface of the middle threaded shaft is in threaded connection with four magnetic threaded blocks, the front ends of the magnetic threaded blocks are fixedly connected with two front fixed shafts, the two front fixed shafts are distributed and arranged in a bilateral symmetry mode by taking the central line of the magnetic threaded blocks as a symmetry center, the peripheral surface of the front fixed shafts is rotatably connected with an extension rod, the, the lower end face of the middle symmetrical block is internally provided with a detector with a downward opening, the upper wall of the equipment cavity is provided with a sliding vertical port with an upward opening, the upper end of the equipment box is fixedly connected with an induction motor, the lower end of the induction motor is connected with the upper end of the middle threaded shaft in a power mode, the outer peripheral face of the middle threaded shaft is connected with the inner wall of the sliding vertical port in a sliding mode, the induction motor is electrically connected with the magnetic threaded blocks, the communicator, the middle symmetrical block, the side fixing seat and the moving seat, when a signal source in a communication cabinet is different due to natural disasters and the like, the induction motor is started at the moment to drive the middle threaded shaft to rotate, and further drive the four magnetic threaded blocks to move downwards integrally to drive the front fixing shaft to rotate, further drive the extension rod to swing, and further drive the extension wheel to rotate, and then the down-hanging rod is driven to swing, so as to drive the middle symmetrical block and the detector to move away from each other, at the moment, the detector is contacted with the signal connecting blocks at two sides, so that signal sources at two sides of the communicator can be monitored, and the signal sources at two sides of the communicator can be ensured to be strongest, and in the process that the magnetic thread block moves downwards, due to the magnetic force action between the magnetic thread block and the moving seat, the moving seat is further enabled to move close to and away from each other, at the moment, the moving seat drives the symmetrical annunciator and the mutually exclusive magnetic rod to move, so as to drive the pulley and the sliding shaft to move on the inner wall of the sliding groove, at the moment, the symmetrical annunciator is contacted with the signal connecting blocks at the upper side and the lower side, at the moment, the signal sources at the upper side and the lower side of the communicator can be monitored, so as to ensure that the signal sources Work, and at this moment perpendicular belt rotates, and then drives the mount reciprocates, and then drives the tight pulley the dead lever the swinging wheel the swinging arms side fixing base with the side monitor reciprocates, this moment the side monitor contact left and right is kept away from one side each other the signal connecting block, this moment the side monitor is right thereby the signal source that the communicator kept away from one side each other is monitored and is strengthened the signal source that the communicator kept away from one side each other guarantees work, and when taking place flood natural disasters, flood got into at this moment during the buoyancy intracavity, make the downside buoyancy ball upside, because the impact of rivers, the extrusion this moment stabilizing spring, the buoyancy ball makes the equipment damage in the communication rack is avoided in the equipment case come-up.
Preferably, two side sliding ports with upward openings are arranged in the upper wall of the equipment cavity, the two side sliding ports are symmetrically distributed in the left-right direction by taking the central line of the equipment cavity as a symmetric center, a sliding embedded shaft is slidably connected to the inner wall of the side sliding ports, a front bevel gear is fixedly connected to the lower end of the sliding embedded shaft, a driven bevel gear is fixedly connected to the upper end of the sliding embedded shaft, one end of the induction motor, which is far away from the left and right sides, is dynamically connected with a side driving shaft, one end of the side driving shaft, which is far away from the left and right sides, is fixedly connected with a driving bevel gear, one end of the driving bevel gear, which is close to the left and right sides, is engaged with the driven bevel gear, a rear bevel gear is fixedly connected to the front ends of the two built-in rotating shafts on the upper side, the upper end, at the moment, the induction motor is started, so that the side driving shaft is driven to rotate, the driving bevel gear and the driven bevel gear are driven to rotate, the sliding embedded shaft is driven to rotate, the front bevel gear is driven to rotate, the rear bevel gear is driven to rotate, the built-in rotating shaft and the built-in belt pulley are driven to rotate, the vertical belt is driven to rotate, and signal sources on two sides are monitored.
Preferably, stabilizer bars are symmetrically distributed in the buoyancy cavity in a bilateral manner by taking the center line of the buoyancy cavity as a symmetric center, sealing blocks are fixedly arranged at the upper end and the lower end of each stabilizer bar, the sealing blocks at the lower side are fixedly connected with the lower side wall of the buoyancy cavity, two sliding blocks are slidably connected on the outer peripheral surface of each stabilizer bar, the ends, close to each other, of the sliding blocks are fixedly connected to the ends, far away from each other, of the equipment box in a bilateral manner, buoyancy springs are fixedly connected at the lower ends of the sliding blocks, the lower ends of the buoyancy springs on the sliding blocks at the upper side are fixedly connected to the upper ends of the sliding blocks at the lower side, the lower ends of the buoyancy springs on the sliding blocks at the lower side are fixedly connected to the upper ends of the buoyancy balls in the vertical direction, when flood natural disast, the sliding block with buoyancy spring and both sides the come-up of buoyancy ball and then drive the whole come-up of equipment box is avoided being destroyed by the flood.
Preferably, the upper end of the waterproof base is fixedly connected with two magnetic blocks, the two magnetic blocks are arranged in a bilateral symmetry manner by taking the central line of the buoyancy cavity as a symmetry center, the magnetic blocks are electrically connected with the induction motor, the upper ends of the magnetic blocks are magnetically connected with magnetic rods, opposite openings are arranged in the left end face and the right end face of each magnetic rod, which are close to one end face, the upper walls of the opposite openings are fixedly connected with loosening springs, the lower ends of the loosening springs are fixedly connected with U-shaped rods, the ends of the U-shaped rods, which are far away from each other, are slidably connected onto the inner walls of the opposite openings, when a flood natural disaster occurs, the induction motor is started at the moment, so that the magnetic blocks and the magnetic rods are magnetically attracted to avoid flood from entering the side openings, and if the flood natural disaster is too violent, the magnetic blocks and the magnetic rods lose the magnetic attraction and, at the moment, the magnetic rod swings to drive the U-shaped rod to move downwards, the loosening spring is stretched, and the U-shaped rod drives the isolating device in the next step.
Preferably, the front end of the U-shaped rod is fixedly connected with a wheel shaft, the outer peripheral surface of the wheel shaft is connected with a sealing rod in a sliding manner, the lower end of the sealing rod is provided with a downward moving cavity with a downward opening, the inner wall of the downward moving cavity is connected with a sliding rod in a sliding manner, the lower end of the sliding rod is fixedly connected with a sealing magnetic block, the lower wall of the buoyancy cavity is internally and fixedly connected with two attraction blocks, the two attraction blocks are distributed and arranged in a bilateral symmetry manner by taking the central line of the buoyancy cavity as a symmetry center, the attraction blocks are magnetically connected with the sealing magnetic block, when the U-shaped rod moves downward, the wheel shaft is driven to rotate, the sealing rod is driven to swing close to each other, the sliding rod is driven to move downward and move close to each other, the sealing magnetic block is driven to move downward to the upper side of the attraction blocks, and the sealing, at the moment, the closing rod and the sliding rod play a role in isolating flood and prevent flood from entering the buoyancy cavity.
Preferably, a closed wheel is rotatably connected to the rear end face of the magnetic rod, an inclined rod is rotatably connected to the outer peripheral face of the closed wheel, a symmetrical wheel is rotatably connected to the rear end face of the inclined rod, a connecting rod is rotatably connected to the outer peripheral face of the symmetrical wheel, an intermediate wheel is rotatably connected between the connecting rods, a vertical rod is rotatably connected to the outer peripheral face of the intermediate wheel, a cavity with a downward opening is formed in the lower end of the vertical rod, a T-shaped rod is slidably connected to the inner wall of the cavity, the lower end of the T-shaped rod is fixedly connected to the upper end of the induction motor, when the communication cabinet moves due to natural disasters such as flood and the like, the upward movement of the induction motor further drives the T-shaped rod to move upward to drive the vertical rod to swing to further drive the intermediate wheel to rotate to further drive the connecting rod to swing to further, and then drive the down tube swing, and then drive the closing wheel rotates, and then drive the magnetic pole swing, the magnetic pole swing makes the equipment in the communication rack isolated.
The invention has the beneficial effects that: the communication cabinet can timely prevent water and flood for various devices and devices in the communication cabinet in severe weather environment and flood disasters, prevent the communication cabinet from being damaged due to natural disasters, and can monitor the strength of a signal source in real time and change the flexible connection mode of the devices and the devices in the communication cabinet at any time in normal use.
Drawings
In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.
The invention is further illustrated with reference to the following figures and examples.
Fig. 1 is a schematic view of the overall structure of a flood-proof and waterproof communication cabinet capable of automatically monitoring the strength of a signal source according to the present invention.
Fig. 2 is an enlarged schematic view of a in fig. 1.
Fig. 3 is an enlarged schematic view of B in fig. 1.
Fig. 4 is an enlarged schematic view of C in fig. 1.
Fig. 5 is an enlarged schematic view of D in fig. 1.
Fig. 6 is an enlarged schematic view of E in fig. 1.
Detailed Description
The invention will now be described in detail with reference to fig. 1-6, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.
The communication cabinet comprises a waterproof base 11, a buoyancy cavity 12 with an upward opening is arranged in the waterproof base 11, three buoyancy balls 39 are connected to the lower wall of the buoyancy cavity 12 in a contact manner, stabilizing springs 40 are fixedly connected between the buoyancy balls 39, an equipment box 13 is fixedly connected to the upper end of each buoyancy ball 39, an equipment cavity 14 is arranged in the equipment box 13, three partition plates 31 are fixedly connected between the left side wall and the right side wall of the equipment cavity 14, a vertically through connecting port 15 and two side through ports 16 are arranged on the upper end surface and the lower end surface of each partition plate 31, the two side through ports 16 are symmetrically distributed and arranged in a left-right manner by taking the center line of the equipment cavity 14 as a symmetric center, eight communicators 41 are fixedly connected between the front wall and the rear wall of the equipment cavity 14, and the eight communicators 41 are symmetrically distributed and arranged in a left-right manner by taking the center line of the equipment cavity 14, four signal connecting blocks 56 are fixedly connected to the outer peripheral surface of the communicator 41, the four signal connecting blocks 56 are distributed and arranged in a vertically and horizontally symmetrical manner with the central line of the communicator 41 as a symmetrical center, four built-in rotating shafts 75 are rotatably connected between the front and rear walls of the equipment cavity 14, the four built-in rotating shafts 75 are distributed and arranged in a vertically and horizontally symmetrical manner with the central line of the equipment cavity 14 as a symmetrical center, built-in belt pulleys 76 are fixedly connected to the outer peripheral surface of the built-in rotating shafts 75, vertical belts 17 are rotatably connected between the built-in belt pulleys 76, eight fixing frames 78 are fixedly connected to one end surface of the vertical belts 17 close to each other left and right, the eight fixing frames 78 are distributed and arranged in a horizontally symmetrical manner with the central line of the equipment cavity 14 as a symmetrical center, a fixing wheel 79 is fixedly, the rear end of the fixing rod 45 is fixedly connected with a swinging wheel 77, the peripheral surface of the swinging wheel 77 is rotatably connected with a swinging rod 46, the swinging rod 46 is mutually close to one end of a fixedly connected side fixing seat 47, the side fixing seat 47 is mutually close to one end surface and is provided with a side monitor 44 with opposite openings, the upper wall of the separation plate 31 and the upper wall of the buoyancy chamber 12 are mutually close to one end, the separation plate 31 and the lower wall of the buoyancy chamber 12 are mutually close to one side and are respectively fixedly connected with four opening fixing blocks 48, the four opening fixing blocks 48 are arranged in a bilateral symmetry mode by taking the central line of the equipment chamber 14 as a symmetry center, the opening fixing blocks 48 are mutually close to one end surface and are provided with sliding grooves 49 with opposite openings, the front wall and the rear wall of the sliding grooves 49 are rotatably connected with two sliding shafts 42, and the two sliding shafts 42 are arranged in a bilateral symmetry mode by taking the central line, the outer peripheral surface of the sliding shaft 42 is rotatably connected with a pulley 58, the outer peripheral surface of the pulley 58 is slidably connected with the inner wall of the sliding groove 49, one end of the sliding shaft 42, which is close to each other up and down, is rotatably connected with a mutual-exclusion magnetic force rod 59, one end of the mutual-exclusion magnetic force rod 59, which is close to each other up and down, is fixedly connected with a moving seat 43, one end surface of the moving seat 43, which is close to each other up and down, is provided with a symmetrical annunciator 57 with opposite openings, the lower wall of the equipment cavity 14 is rotatably connected with a middle threaded shaft 38, the outer peripheral surface of the middle threaded shaft 38 is in threaded connection with four magnetic threaded blocks 62, the front ends of the magnetic threaded blocks 62 are fixedly connected with two front fixing shafts 63, the two front fixing shafts 63 are arranged in bilateral symmetry with the center line of the magnetic threaded blocks 62, the outer peripheral surface of the extension wheel 52 is rotatably connected with a drop rod 54, the lower end of the drop rod 54 is fixedly connected with a middle symmetrical block 50, the lower end surface of the middle symmetrical block 50 is provided with a detector 55 with a downward opening, the upper wall of the equipment cavity 14 is provided with a sliding vertical port 61 with an upward opening, the upper end of the equipment box 13 is fixedly connected with an induction motor 60, the lower end of the induction motor 60 is in power connection with the upper end of the middle threaded shaft 38, the outer peripheral surface of the middle threaded shaft 38 is in sliding connection with the inner wall of the sliding vertical port 61, the induction motor 60 is electrically connected with the magnetic threaded block 62, the communicator 41, the middle symmetrical block 50, the side fixed seat 47 and the movable seat 43, when a signal source in the communication cabinet is different due to natural disasters and the like, the induction motor 60 is started at the moment to further drive the middle threaded shaft 38 to rotate, then the four magnetic thread blocks 62 are driven to move downwards integrally, and further the preposed fixed shaft 63 is driven to rotate, and further the extension rod 51 is driven to swing, and further the extension wheel 52 is driven to rotate, and further the down-hanging rod 54 is driven to swing, and further the middle symmetrical block 50 and the detector 55 are driven to move away from each other, at this time, the detector 55 contacts the signal connecting blocks 56 at both sides so that the signal sources at both sides of the communicator 41 can be monitored, and thus the signal sources at both sides of the communicator 41 can reach the strongest signal source, and during the downward movement of the magnetic thread blocks 62, due to the magnetic force action between the magnetic thread blocks 62 and the moving seat 43, the moving seats 43 are further moved towards and away from each other, at this time, the moving seat 43 drives the symmetrical annunciator 57 and the repulsive magnetic rod 59 to move, the pulley 58 and the sliding shaft 42 are further driven to move on the inner wall of the sliding groove 49, at this time, the symmetrical annunciators 57 contact the signal connecting blocks 56 on the upper and lower sides, at this time, the signal sources on the upper and lower sides of the communicator 41 can be monitored to ensure that the signal sources on the upper and lower sides of the communicator 41 can be strengthened to ensure that the communicator 41 can normally operate, at this time, the vertical belt 17 rotates to drive the fixing frame 78 to move up and down, further, the fixing wheel 79, the fixing rod 45, the swinging wheel 77, the swinging rod 46, the side fixing seat 47 and the side monitor 44 to move up and down, at this time, the side monitor 44 contacts the signal connecting blocks 56 on the left and right sides which are far away from each other, at this time, the side monitor 44 monitors the signal sources on the side where the communicator 41 is far away from each other to strengthen the signal sources on the side where, and when the natural disaster of flood takes place, flood got into this moment in the buoyancy chamber 12 for the downside the buoyancy ball 39 upside because the impact of rivers, the extrusion this moment stabilized spring 40, buoyancy ball 39 makes equipment box 13 come up avoids the equipment in the communication rack to damage.
Beneficially, two side sliding ports 69 with upward openings are arranged in the upper wall of the device cavity 14, the two side sliding ports 69 are symmetrically distributed left and right with the center line of the device cavity 14 as the symmetric center, a sliding embedded shaft 72 is slidably connected to the inner wall of the side sliding port 69, a front bevel gear 73 is fixedly connected to the lower end of the sliding embedded shaft 72, a driven bevel gear 71 is fixedly connected to the upper end of the sliding embedded shaft 72, a side driving shaft 24 is dynamically connected to the end of the induction motor 60 which is far away from the left and right, a driving bevel gear 70 is fixedly connected to the end of the side driving shaft 24 which is far away from the left and right, the lower end of the driving bevel gear 70 is engaged with the end of the driven bevel gear 71 which is near to the left and right, a rear bevel gear 74 is fixedly connected to the front ends of the two upper built-in rotating shafts, when the intensity of signal sources on two sides of equipment in a communication cabinet needs to be automatically monitored, the induction motor 60 is started at the moment, so that the side driving shaft 24 is driven to rotate, the driving bevel gear 70 and the driven bevel gear 71 are driven to rotate, the sliding embedded shaft 72 is driven to rotate, the front bevel gear 73 is driven to rotate, the rear bevel gear 74 is driven to rotate, the built-in rotating shaft 75 and the built-in belt pulley 76 are driven to rotate, the vertical belt 17 is driven to rotate, and the signal sources on two sides are monitored.
Beneficially, stabilizer bars 30 are symmetrically distributed in the buoyancy chamber 12 with the center line of the buoyancy chamber 12 as the symmetric center, sealing blocks 22 are fixedly arranged at the upper and lower ends of the stabilizer bars 30, the sealing block 22 at the lower side is fixedly connected with the lower side wall of the buoyancy chamber 12, two sliding blocks 20 are slidably connected to the outer circumferential surface of the stabilizer bar 30, the ends of the sliding blocks 20 close to each other are fixedly connected to the ends of the equipment box 13 far away from each other, a buoyancy spring 35 is fixedly connected to the lower end of the sliding block 20, the lower end of the buoyancy spring 35 on the upper sliding block 20 is fixedly connected to the upper end of the sliding block 20 at the lower side, the lower end of the buoyancy spring 35 on the lower sliding block 20 is fixedly connected to the upper end of the buoyancy ball 39 in the vertical direction, when a natural flood disaster occurs and flood enters the buoyancy chamber 12, the two buoyancy balls 39 on both, and then drive the sliding block 20 to slide on the outer peripheral surface of the stabilizer bar 30, the sliding block 20, the buoyancy spring 35 and the buoyancy balls 39 on both sides float upwards to drive the whole equipment box 13 to float upwards to avoid being damaged by flood.
Beneficially, the upper end of the waterproof base 11 is fixedly connected with two magnetic blocks 36, the two magnetic blocks 36 are symmetrically distributed with the central line of the buoyancy chamber 12 as the symmetric center, the magnetic blocks 36 are electrically connected with the induction motor 60, the upper end of the magnetic block 36 is magnetically connected with the magnetic rod 19, opposite openings 34 with opposite openings are arranged in the left side and the right side of the magnetic rod 19, which are close to one end face, respectively, the upper wall of the opposite opening 34 is fixedly connected with a loosening spring 33, the lower end of the loosening spring 33 is fixedly connected with a U-shaped rod 18, one end of the U-shaped rod 18, which is far away from each other, is slidably connected to the inner wall of the opposite opening 34, when a flood natural disaster occurs, the induction motor 60 is started at the moment, so that the magnetic blocks 36 and the magnetic rod 19 are magnetically attracted to avoid flood from entering the side opening 16, and at the moment, if the flood, the magnetic block 36 and the magnetic rod 19 lose magnetic attraction and are separated, at this time, the magnetic rod 19 swings to drive the U-shaped rod 18 to move downwards, so that the loosening spring 33 is stretched, and the U-shaped rod 18 drives the next isolating device.
Beneficially, an axle 66 is fixedly connected to the front end of the U-shaped rod 18, a closing rod 67 is slidably connected to the outer peripheral surface of the axle 66, a downward moving cavity 65 with a downward opening is formed at the lower end of the closing rod 67, a sliding rod 68 is slidably connected to the inner wall of the downward moving cavity 65, a closed magnetic block 64 is fixedly connected to the lower end of the sliding rod 68, two attraction blocks 37 are fixedly connected to the lower wall of the buoyancy cavity 12, the two attraction blocks 37 are symmetrically distributed and arranged with the center line of the buoyancy cavity 12 as the symmetry center, the attraction blocks 37 are magnetically connected with the closed magnetic block 64, when the U-shaped rod 18 moves downward, the axle 66 is driven to rotate, the closing rod 67 is driven to swing close to each other, the sliding rod 68 is driven to move downward and close to each other, and the closed magnetic block 64 is driven to move downward to the upper side of the attraction block 37, at this time, the sealing magnetic block 64 and the attraction block 37 are magnetically attracted, and at this time, the sealing rod 67 and the sliding rod 68 isolate flood water from entering the buoyancy chamber 12.
Beneficially, a closing wheel 32 is rotatably connected to the rear end face of the magnetic rod 19, an inclined rod 21 is rotatably connected to the outer peripheral face of the closing wheel 32, a symmetrical wheel 23 is rotatably connected to the rear end face of the inclined rod 21, a connecting rod 28 is rotatably connected to the outer peripheral face of the symmetrical wheel 23, an intermediate wheel 26 is rotatably connected between the connecting rods 28, a vertical rod 27 is rotatably connected to the outer peripheral face of the intermediate wheel 26, a cavity 25 with a downward opening is formed at the lower end of the vertical rod 27, a T-shaped rod 29 is slidably connected to the inner wall of the cavity 25, the lower end of the T-shaped rod 29 is fixedly connected to the upper end of the induction motor 60, when the communication cabinet moves due to a natural disaster such as flood, the induction motor 60 moves upwards to drive the T-shaped rod 29 to move upwards to drive the vertical rod 27 to swing to drive the intermediate wheel 26 to rotate to drive the connecting rod 28 to, and then the symmetrical wheel 23 is driven to rotate, the inclined rod 21 is driven to swing, the sealing wheel 32 is driven to rotate, the magnetic rod 19 is driven to swing, and the magnetic rod 19 swings to isolate equipment in the communication cabinet.
The following describes in detail the use steps of a flood-proof and waterproof communication cabinet with an automatic signal source strength monitoring function according to the present disclosure with reference to fig. 1 to 6:
initially, the induction motor 60, the communicator 41, the side monitor 44, the symmetrical annunciator 57 and the detector 55 are in a closed state, the side monitor 44, the symmetrical annunciator 57, the signal connection block 56 and the detector 55 are in a contact-free state, the magnetic thread block 62 is in any position in the equipment chamber 14, the closed magnetic block 64 is out of contact with the attraction block 37, the magnetic block 36 is magnetically connected with the lower end of the magnetic rod 19, and the fixing frame 78 is in any position in the equipment chamber 14.
When the signal source in the communication cabinet is different due to natural disasters and the like, the induction motor 60 is started at the moment, the middle threaded shaft 38 is driven to rotate, the four magnetic threaded blocks 62 are driven to integrally move downwards, the front fixing shaft 63 is driven to rotate, the extension rod 51 is driven to swing, the extension wheel 52 is driven to rotate, the down hanging rod 54 is driven to swing, the middle symmetrical block 50 and the detector 55 are driven to move away from each other, the detector 55 is contacted with the signal connecting blocks 56 at the two sides at the moment, so that the signal sources at the two sides of the communicator 41 can be monitored, the signal sources at the two sides of the communicator 41 can be ensured to be strongest, and in the process that the magnetic threaded blocks 62 move downwards, the movable seats 43 approach and move away from each other due to the magnetic action between the magnetic threaded blocks 62 and the movable seats 43, and the movable seats 43 drive the symmetrical signal devices 57 at the moment, The mutually exclusive magnetic rod 59 moves to drive the pulley 58 and the sliding shaft 42 to move on the inner wall of the sliding groove 49, at the moment, the symmetrical annunciator 57 contacts the signal connecting blocks 56 at the upper side and the lower side, at the moment, the signal sources at the upper side and the lower side of the communicator 41 can be monitored to ensure that the signal sources at the upper side and the lower side of the communicator 41 can be strengthened to ensure that the communicator 41 can normally work, at the moment, the vertical belt 17 rotates to drive the fixing frame 78 to move up and down, further, the fixing wheel 79, the fixing rod 45, the swinging wheel 77, the swinging rod 46, the side fixing seat 47 and the side monitor 44 move up and down, at the moment, the side monitor 44 contacts the signal connecting blocks 56 at the left side and the right side, at the moment, the side monitor 44 monitors the signal sources at the side, far away from each other side, of, when flood enters the buoyancy chamber 12 at this time, the buoyancy ball 39 on the lower side pushes the stabilizing spring 40 due to the impact of water flow, and the buoyancy ball 39 enables the equipment box 13 to float upwards to avoid the damage of equipment in the communication cabinet.
When the intensity of signal sources on two sides of the equipment in the communication cabinet needs to be automatically monitored, the induction motor 60 is started, the side driving shaft 24 is driven to rotate, the driving bevel gear 70 and the driven bevel gear 71 are driven to rotate, the sliding embedded shaft 72 is driven to rotate, the front bevel gear 73 is driven to rotate, the rear bevel gear 74 is driven to rotate, the built-in rotating shaft 75 and the built-in belt pulley 76 are driven to rotate, the vertical belt 17 is driven to rotate, the signal sources on two sides are monitored, when a natural flood disaster occurs and flood enters the buoyancy cavity 12, the two buoyancy balls 39 on two sides float upwards, the buoyancy springs 35 are compressed, the sliding block 20 is driven to slide on the outer peripheral surface of the stabilizer bar 30, the sliding block 20, the buoyancy springs 35 and the buoyancy balls 39 on two sides float upwards, and the equipment box 13 is driven to integrally float upwards to avoid being damaged by the flood, when taking place flood natural disasters, start induction motor 60 this moment for magnetic block 36 and 19 magnetism of magnetic force pole are inhaled, avoid the flood to get into side opening 16, if the flood natural disasters is too violent this moment, magnetic block 36 and magnetic force pole 19 lose magnetism and inhale and break away from, and the swing of magnetic force pole 19 this moment and then drive U-shaped pole 18 downstream, and then tensile not hard up spring 33, U-shaped pole 18 drives isolating device on next step.
When the U-shaped bar 18 is moved downwards, the axle 66 is caused to rotate, and the closing bars 67 are caused to swing towards each other, thereby driving the sliding rod 68 to move downwards and approach each other, further driving the sealing magnetic block 64 to move downwards to the upper side of the attraction block 37, at this time, the sealing magnetic block 64 and the attraction block 37 are magnetically attracted, at this time, the sealing rod 67 and the sliding rod 68 play a role in isolating flood and preventing flood from entering the buoyancy chamber 12, when the communication cabinet moves due to natural disasters such as flood, the induction motor 60 moves upwards to drive the T-shaped rod 29 to move upwards and further drive the vertical rod 27 to swing, thereby driving the intermediate wheel 26 to rotate and further driving the connecting rod 28 to swing, and further driving the symmetrical wheel 23 to rotate, and then the diagonal rod 21 is driven to swing, and further the sealing wheel 32 is driven to rotate, and further the magnetic rod 19 is driven to swing, and the magnetic rod 19 swings to enable the equipment in the communication cabinet to be isolated.
The invention has the beneficial effects that: the invention can timely carry out water and flood prevention on various devices and devices in the communication cabinet in severe weather environment and when flood disasters occur, prevent the communication cabinet from being damaged due to natural disasters, and can monitor the strength of a signal source in real time and change the flexible connection mode of the devices and the devices in the communication cabinet at any time in normal use.
The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (6)

1. The utility model provides a communication rack of waterproof automatic monitoring signal source power of flood control, includes waterproof base, its characterized in that: a buoyancy cavity with an upward opening is arranged in the waterproof base, three buoyancy balls are connected to the lower wall of the buoyancy cavity in a contact manner, a stabilizing spring is fixedly connected between the buoyancy balls, an equipment box is fixedly connected to the upper ends of the buoyancy balls, an equipment cavity is arranged in the equipment box, three partition plates are fixedly connected between the left side wall and the right side wall of the equipment cavity, a vertically through connector and two side through holes are arranged in the upper end surface and the lower end surface of each partition plate, the two side through holes are arranged in a bilateral symmetry manner by taking the central line of the equipment cavity as a symmetry center, eight communicators are fixedly connected between the front wall and the rear wall of the equipment cavity, the eight communicators are arranged in a bilateral symmetry manner by taking the central line of the equipment cavity as a symmetry center, four signal connecting blocks are fixedly connected to the outer peripheral surface of each communicator, and, four built-in rotating shafts are rotatably connected between the front wall and the rear wall of the equipment cavity, the four built-in rotating shafts are vertically and bilaterally symmetrically distributed by taking the central line of the equipment cavity as a symmetric center, built-in belt pulleys are fixedly connected on the outer peripheral surfaces of the built-in rotating shafts, vertical belts are rotatably connected between the built-in belt pulleys, eight fixing frames are fixedly connected on one end surface of the vertical belts which are close to each other left and right, the eight fixing frames are arranged symmetrically with the central line of the equipment cavity as the symmetric center, fixed wheels are fixedly connected at the front ends of the fixing frames, fixed rods are rotatably connected on the outer peripheral surfaces of the fixed wheels, swinging wheels are fixedly connected at the rear ends of the fixed rods, swinging rods are rotatably connected on the outer peripheral surfaces of the swinging wheels, one ends of the swinging rods, the partition board and the upper wall of the buoyancy cavity are close to one side of each other, the partition board is close to one end of each other from top to bottom, the partition board and the lower wall of the buoyancy cavity are close to one side of each other, four opening fixing blocks are fixedly connected with each other, the four opening fixing blocks are distributed and arranged in a bilateral symmetry mode by taking the central line of the equipment cavity as the symmetry center, sliding grooves with opposite openings are arranged in the upper end face and the lower end face of each opening fixing block, two sliding shafts are rotationally connected between the front wall and the rear wall of each sliding groove, the two sliding shafts are distributed and arranged in a bilateral symmetry mode by taking the central line of the sliding groove as the symmetry center, pulleys are rotationally connected on the outer peripheral surfaces of the sliding shafts, the outer peripheral surfaces of the pulleys are slidably connected on the inner wall of the sliding grooves, one ends of the, the upper end face and the lower end face of the movable seat, which are close to each other, are provided with symmetrical annunciators with opposite openings, the lower wall of the equipment cavity is rotationally connected with a middle threaded shaft, the outer peripheral surface of the middle threaded shaft is in threaded connection with four magnetic thread blocks, the front end of each magnetic thread block is fixedly connected with two preposed fixed shafts, the two preposed fixed shafts are symmetrically distributed and arranged with the central line of the magnetic thread block as the symmetrical center, the outer peripheral surface of the preposed fixed shaft is rotationally connected with an extension rod, the front end of the extension rod is fixedly connected with an extension wheel, the outer peripheral surface of the extension wheel is rotationally connected with a down-hanging rod, the lower end of the down-hanging rod is fixedly connected with a middle symmetrical block, the lower end face of the middle symmetrical block is internally provided with a detector with a downward opening, the, the lower end of the induction motor is in power connection with the upper end of the middle threaded shaft, the outer peripheral surface of the middle threaded shaft is in sliding connection with the inner wall of the sliding vertical port, and the induction motor is electrically connected with the magnetic threaded block, the communicator, the middle symmetrical block, the side fixing seat and the moving seat.
2. The communication cabinet of claim 1, wherein the flood control and water proof automatic signal source strength monitoring system comprises: the device comprises an equipment cavity and is characterized in that two side sliding ports with upward openings are arranged in the upper wall of the equipment cavity, the side sliding ports are arranged in a manner that the central line of the equipment cavity is in bilateral symmetry distribution as a symmetry center, a sliding embedded shaft is connected to the inner wall of the side sliding port in a sliding mode, a front bevel gear is fixedly connected to the lower end of the sliding embedded shaft, a driven bevel gear is fixedly connected to the upper end of the sliding embedded shaft, one end of an induction motor is connected with a side driving shaft in a power-driven mode, one end of the side driving shaft is connected with a driving bevel gear in a driving mode, the lower end of the driving bevel gear is connected with one end of the driven bevel gear in a meshing mode, the front end of the built-in rotating shaft is fixedly connected.
3. The communication cabinet of claim 1, wherein the flood control and water proof automatic signal source strength monitoring system comprises: buoyancy intracavity with buoyancy chamber central line distributes for symmetry center bilateral symmetry and is provided with the stabilizer bar, and both ends have set firmly closed piece about the stabilizer bar, and the closed piece fixed connection of downside in lateral wall under the buoyancy chamber, sliding connection has two sliding blocks on the stabilizer bar outer peripheral face, be close to one end fixed connection each other about the sliding block in keep away from one end each other about the equipment box, sliding block lower extreme fixedly connected with buoyancy spring, buoyancy spring lower extreme fixed connection on the sliding block of upside are in the sliding block upper end of downside, and buoyancy spring lower extreme fixed connection on the sliding block of downside is in vertical direction the buoyancy ball upper end.
4. The communication cabinet of claim 1, wherein the flood control and water proof automatic signal source strength monitoring system comprises: two magnetic force pieces of waterproof base upper end fixedly connected with, two the magnetic force piece with buoyancy chamber central line distributes the setting for symmetry center bilateral symmetry, the magnetic force piece with induction motor electric connection, magnetic force piece upper end magnetism is connected with the magnetic pole, be equipped with the subtend mouth that the opening is relative in being close to one end face each other about the magnetic pole, subtend mouthful upper wall fixedly connected with not hard up spring, not hard up spring lower extreme fixedly connected with U-shaped pole, the U-shaped pole keep away from one end sliding connection each other in on the subtend mouthful inner wall.
5. The communication cabinet of claim 4, wherein the flood control and water proof automatic signal source strength monitoring system comprises: the front end of the U-shaped rod is fixedly connected with a wheel shaft, the outer peripheral surface of the wheel shaft is connected with a sealing rod in a sliding mode, the lower end of the sealing rod is provided with a downward moving cavity with a downward opening, the inner wall of the downward moving cavity is connected with a sliding rod in a sliding mode, the lower end of the sliding rod is fixedly connected with a sealing magnetic block, two attraction blocks are fixedly connected in the lower wall of the buoyancy cavity, the two attraction blocks are distributed and arranged in a bilateral symmetry mode by taking the center line of the buoyancy cavity as the symmetry center, and the attraction blocks are magnetically connected with the sealing magnetic block.
6. The communication cabinet of claim 4, wherein the flood control and water proof automatic signal source strength monitoring system comprises: the magnetic pole rear end face internal rotation is connected with the closing wheel, it is connected with the down tube to rotate on the closing wheel outer peripheral face, the down tube rear end face internal rotation is connected with the symmetrical wheel, it is connected with the connecting rod to rotate on the symmetrical wheel outer peripheral face, it is connected with the intermediate wheel to rotate between the connecting rod, it is connected with the vertical pole to rotate on the intermediate wheel outer peripheral face, the vertical pole lower extreme is equipped with the decurrent cavity of opening, sliding connection has T shape pole on the cavity inner wall, T shape pole lower extreme fixed connection in induction motor upper end.
CN202011497857.0A 2020-12-17 2020-12-17 Communication cabinet capable of preventing flood and water and automatically monitoring strength of signal source Active CN112399764B (en)

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN109378721A (en) * 2018-10-12 2019-02-22 南宁安普电力设备有限公司 A kind of gas all insulation fully enclosed looped network cabinet
CN112051651A (en) * 2020-09-29 2020-12-08 义乌市婉聚电子有限公司 Full-automatic processing banding device of optical cable coating
CN112081341A (en) * 2020-10-26 2020-12-15 郑州噢澳电子科技有限公司 Floor device for preventing electric shock in transformer substation

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN112074145A (en) * 2020-09-22 2020-12-11 温州漂逸科技有限公司 Be used for impaired quick protection device of communication machine prevention

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN109378721A (en) * 2018-10-12 2019-02-22 南宁安普电力设备有限公司 A kind of gas all insulation fully enclosed looped network cabinet
CN112051651A (en) * 2020-09-29 2020-12-08 义乌市婉聚电子有限公司 Full-automatic processing banding device of optical cable coating
CN112081341A (en) * 2020-10-26 2020-12-15 郑州噢澳电子科技有限公司 Floor device for preventing electric shock in transformer substation

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