CN111836129A - Antidetonation flood control 5G basic station - Google Patents

Antidetonation flood control 5G basic station Download PDF

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Publication number
CN111836129A
CN111836129A CN202010783536.0A CN202010783536A CN111836129A CN 111836129 A CN111836129 A CN 111836129A CN 202010783536 A CN202010783536 A CN 202010783536A CN 111836129 A CN111836129 A CN 111836129A
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CN
China
Prior art keywords
power generation
antenna
chuck
shell
ratchet wheel
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Granted
Application number
CN202010783536.0A
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Chinese (zh)
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CN111836129B (en
Inventor
郝宁宁
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QINGDAO KEHUA STEEL STRUCTURE CO.,LTD.
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郝宁宁
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Priority to CN202010783536.0A priority Critical patent/CN111836129B/en
Publication of CN111836129A publication Critical patent/CN111836129A/en
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Publication of CN111836129B publication Critical patent/CN111836129B/en
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04QSELECTING
    • H04Q1/00Details of selecting apparatus or arrangements
    • H04Q1/02Constructional details
    • H04Q1/11Protection against environment
    • H04Q1/112Protection against environment mechanical protection, e.g. resistance to earthquakes
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16FSPRINGS; SHOCK-ABSORBERS; MEANS FOR DAMPING VIBRATION
    • F16F15/00Suppression of vibrations in systems; Means or arrangements for avoiding or reducing out-of-balance forces, e.g. due to motion
    • F16F15/02Suppression of vibrations of non-rotating, e.g. reciprocating systems; Suppression of vibrations of rotating systems by use of members not moving with the rotating systems
    • F16F15/04Suppression of vibrations of non-rotating, e.g. reciprocating systems; Suppression of vibrations of rotating systems by use of members not moving with the rotating systems using elastic means
    • F16F15/06Suppression of vibrations of non-rotating, e.g. reciprocating systems; Suppression of vibrations of rotating systems by use of members not moving with the rotating systems using elastic means with metal springs
    • F16F15/067Suppression of vibrations of non-rotating, e.g. reciprocating systems; Suppression of vibrations of rotating systems by use of members not moving with the rotating systems using elastic means with metal springs using only wound springs
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02KDYNAMO-ELECTRIC MACHINES
    • H02K7/00Arrangements for handling mechanical energy structurally associated with dynamo-electric machines, e.g. structural association with mechanical driving motors or auxiliary dynamo-electric machines
    • H02K7/18Structural association of electric generators with mechanical driving motors, e.g. with turbines
    • H02K7/1807Rotary generators
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04QSELECTING
    • H04Q1/00Details of selecting apparatus or arrangements
    • H04Q1/02Constructional details
    • H04Q1/04Frames or mounting racks for selector switches; Accessories therefor, e.g. frame cover
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04QSELECTING
    • H04Q1/00Details of selecting apparatus or arrangements
    • H04Q1/02Constructional details
    • H04Q1/11Protection against environment
    • H04Q1/114Protection against environment flooding protection, e.g. using water proof provision
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W88/00Devices specially adapted for wireless communication networks, e.g. terminals, base stations or access point devices
    • H04W88/08Access point devices
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02DCLIMATE CHANGE MITIGATION TECHNOLOGIES IN INFORMATION AND COMMUNICATION TECHNOLOGIES [ICT], I.E. INFORMATION AND COMMUNICATION TECHNOLOGIES AIMING AT THE REDUCTION OF THEIR OWN ENERGY USE
    • Y02D30/00Reducing energy consumption in communication networks
    • Y02D30/70Reducing energy consumption in communication networks in wireless communication networks

Abstract

An anti-seismic and flood-control 5G base station comprises a machine room shell, a standby antenna mechanism, a base, an anti-seismic power generation module, an anti-seismic mechanism, a module moving mechanism, an anti-seismic mechanism chuck, a standby antenna, a roof, a power generation mechanism, a flood-control mechanism and a power generation mechanism shell; through buckle thorn ratchet buckle link shaft can let generating mechanism thorn ratchet card dead loose piece locating piece spring withstand thereby make generating mechanism bevel gear b die with generating mechanism thorn ratchet b card, inboard generating mechanism thorn ratchet b can not die with generating mechanism bevel gear b card and make generating mechanism thorn b anticlockwise rotation, drive the generator electricity generation, inside is equipped with hydraulic damping mechanism, effectively resists the earthquake, can not make the basic station impaired, can also use the interior of vibrations to generate electricity simultaneously.

Description

Antidetonation flood control 5G basic station
Technical Field
The invention belongs to the field of information communication and earthquake-proof and flood-proof, and particularly relates to an earthquake-proof and flood-proof 5G base station.
Background
At present, earthquake or flood disasters easily occur in mountain areas or south, and the communication of the areas is completely disconnected when the earthquake or flood disasters occur, so that information cannot be communicated, and the emergency rescue and disaster relief process is slow; therefore, a standby base station is needed, which plays a standby role when dangerous situations occur, so that the signal connection is smooth; meanwhile, the base station also needs to have the functions of shock resistance, self-power generation, flood resistance, standby antenna and the like, and the emergency rescue and disaster relief can be smoothly carried out.
Disclosure of Invention
Aiming at the problems, the power generation mechanism bevel gear b and the power generation mechanism ratchet wheel b are clamped to be dead by a movable block positioning block spring through a clamping and buckling connecting shaft of the power generation mechanism ratchet wheel, the power generation mechanism ratchet wheel b on the inner side cannot be clamped to be dead with the power generation mechanism bevel gear b to enable the power generation mechanism ratchet wheel b to rotate anticlockwise and drive a power generator to generate power, a hydraulic damping mechanism is arranged in the power generation mechanism, the power generation mechanism ratchet wheel b effectively resists earthquake, cannot damage a base station, and can use a vibrating lining to generate power;
an anti-seismic and flood-control 5G base station comprises a machine room shell, a standby antenna mechanism, a base, an anti-seismic power generation module, an anti-seismic mechanism, a module moving mechanism, an anti-seismic mechanism chuck, a standby antenna, a roof, a power generation mechanism, a flood-control mechanism and a power generation mechanism shell; the backup antenna mechanism includes: the antenna joint a, the antenna joint b, the antenna joint c and the antenna joint d; the shockproof power generation module comprises: the vibration-proof power generation module a, the vibration-proof power generation module b, the vibration-proof power generation module c and the vibration-proof power generation module d; the shockproof mechanism comprises: the hydraulic cylinder body, the hydraulic rod and the damping spring; the module moving mechanism includes: the moving mechanism base, the moving mechanism motor, the moving mechanism lead screw nut and the lead screw nut are locked by the spring fastener; the shockproof mechanism chuck includes: the chuck shell, the positioning shaft, the chuck gear, the cam, the telescopic rod a, the chuck inner meshing gear, the chuck pinion, the chuck motor and the chuck pinion are positioned; the backup antenna includes: the antenna comprises an antenna motor, an antenna straight gear a, an antenna straight gear b, an antenna threaded rod, an antenna rod positioning mechanism and an antenna rod gear; the roof includes: the device comprises a roof shell, a movable door connecting rod, a movable door nut link, a roof motor, a roof nut and a roof screw rod; the power generation mechanism includes: the device comprises a power generation mechanism rack, a power generation mechanism gear a, a power generation mechanism bevel gear a, a power generation mechanism ratchet wheel a, a power generation mechanism 0 shockproof mechanism, a power generation mechanism ratchet wheel clamping loose piece positioning block spring, a power generation mechanism bevel gear c, a power generation mechanism bevel gear b, a power generation mechanism ratchet wheel b, a ratchet wheel clamping and buckling link shaft and a power generator; the flood protection mechanism comprises: a buoy of the flood control mechanism, a positioning shaft of the flood control mechanism, a buoy connecting rod, an actuating switch, an air bag, a sliding block for connecting the shell of the generating set and the wall surface, and a shell of the generating set,
furthermore, the machine room shell is fixed with the base under the condition of no danger, and the standby antenna mechanism is retracted into the machine room shell; when a dangerous situation occurs, the shockproof mechanism can jack the machine room shell to be separated from the base, the shockproof mechanism is fixed by using the shockproof mechanism chuck, and then the shockproof mechanism does not move and becomes movably connected; the shockproof power generation module a, the shockproof power generation module b, the shockproof power generation module c and the shockproof power generation module d are fixedly arranged on the upper end surface of the base, and the shockproof power generation module is used for generating power by using the shaking force; simultaneously, the standby antenna mechanism is extended and used as a standby antenna; when flood exists, the flood control mechanism can be triggered when the water level reaches a certain height, and the safety air bag is unfolded to serve as an air bag, so that the shell of the machine room cannot be flooded.
Furthermore, the moving mechanism base is fixedly arranged in the machine room shell and is used as a positioning shaft; the buoy of the flood control mechanism is fixedly arranged on the lower end surface of the buoy connecting rod, and the side surface of the buoy connecting rod is rotationally linked with the connecting shaft of the flood control mechanism positioning shaft; when flood control mechanism buoy met water, flood control mechanism buoy can make progress the buoy connecting rod and will touch the trigger switch with reserve antenna mechanism fixed connection, trigger switch start can with evenly distributed with the air bag in the reserve antenna mechanism outside, air bag explodes, can make reserve antenna mechanism not submerged, make reserve antenna mechanism come-up.
Furthermore, the module moving mechanism is a connecting mechanism of the power generation module and the wall surface, one side of the surface of the moving mechanism base is provided with a groove, two ends of the groove extend out of the support, the moving mechanism motor is fixedly connected with the moving mechanism base, and the moving mechanism lead screw is arranged on a motor shaft of the moving mechanism motor; the screw nut is clamped and the spring fastener is fixedly arranged on the rack of the power generation mechanism; when the motor works, the screw rod of the moving mechanism is driven to rotate; the moving mechanism screw nut and the moving mechanism screw are connected through a screw rod and a nut, when the moving mechanism screw rotates, the moving mechanism screw nut is driven to translate, and the screw rod nut is blocked, so that the spring fastener and the generating mechanism rack are bounced off.
Furthermore, an electromagnetic buckle device is arranged at the front end of the link sliding block of the shell of the generating device and the wall surface, is placed in a groove on one surface of the base of the moving mechanism, and can be blocked when moving to a specified position; the front end surface of the shell of the generator device is fixedly connected with the rear end surface of the shell of the generator device and the wall surface link sliding block; one end of a screw nut of the moving mechanism is provided with a bracket, the front end of the screw nut of the moving mechanism is provided with an electromagnetic spring buckle device which is usually clamped with a rack of the generating mechanism, and the rack of the generating mechanism and a shell of the generator device are also provided with electromagnetic buckles which are usually clamped; when a dangerous case occurs, the buckle of the screw nut of the moving mechanism and the buckle of the shell of the generator device are bounced, the motor of the moving mechanism works, and the screw nut of the moving mechanism drives the shell of the generator device to be connected with the sliding block on the wall surface, and the shell of the generator device and the rack of the generator device to move.
Furthermore, the upper end surface of the hydraulic cylinder body is fixedly connected with the top end surface in the machine room shell; the hydraulic rod is connected with the hydraulic cylinder body in a sliding manner; the middle of the hydraulic rod is provided with a rectangular groove, and the inner side of the rectangular groove is provided with an electromagnetic buckle; the damping spring is sleeved at the lower part of the hydraulic rod; when the rack of the power generation mechanism moves to a designated position, the buckle of the electromagnet is popped out and blocked, and the buoy of the flood control mechanism is separated from the shell of the power generator; the shell of the generator device is blocked with the base of the moving mechanism.
Furthermore, the chuck of the shockproof mechanism is usually blocked with the hydraulic rod, when a dangerous situation occurs, the hydraulic rod is matched with the hydraulic cylinder body, and after the standby antenna mechanism is jacked up, the chuck of the shockproof mechanism is separated from the hydraulic rod and is blocked with the machine room shell to become fixedly connected; the outer ring of the chuck shell is uniformly provided with circular grooves, and a small cylinder is arranged in the middle of the circular grooves; grooves are uniformly formed in the inner ring of the chuck shell; the positioning shaft is fixedly connected with a small cylinder on the chuck shell; the chuck gear is rotationally connected with the positioning shaft, and the cam is fixedly arranged on the chuck gear; the telescopic rod and the telescopic rod a are movably connected with the cam; the inside engaged gear of the chuck is engaged with the chuck gear. A groove at one end of the telescopic rod a penetrates through the outer ring, a small cylinder of the chuck shell penetrates through the groove, and the cylinder plays a positioning role; the telescopic rod penetrates through the groove of the inner ring; the chuck motor is fixedly connected with the chuck shell, the chuck pinion is linked to the chuck pinion positioning device, and the chuck pinion is positioned and installed on a motor shaft of the chuck motor; the chuck pinion is meshed with the chuck internal gear; when the chuck motor during operation, chuck pinion rotates, and the chuck internal gear who meshes with chuck pinion rotates, drives ten chuck gear rotations, and the cam rotates to can drive telescopic link and telescopic link a motion, realize that shockproof mechanism chuck and shockproof mechanism separation die with reserve antenna mechanism card.
Further, the power generation mechanism is arranged inside the shell of the power generator device; the rack and the gear a of the power generation mechanism are arranged outside the shell of the power generator device, the bevel gear c of the power generation mechanism is movably and rotatably connected with the shell of the power generator device, and the shell of the power generator device plays a role of a bracket; the power generation mechanism gear a is fixedly connected with the power generation mechanism ratchet wheel a, and the power generation mechanism ratchet wheel a is fixedly connected with the ratchet wheel buckle link shaft; the power generation mechanism ratchet wheel b is also coaxially and rotatably connected with the inner side of the power generation mechanism bevel gear b; a power generation mechanism ratchet wheel clamping loose piece positioning block, a power generation mechanism ratchet wheel clamping loose piece positioning block spring, a ratchet wheel clamping buckle link shaft and a power generation mechanism ratchet wheel clamping loose piece a are also arranged on the inner side of a power generation mechanism bevel gear b; the ratchet wheel buckle connecting shaft is fixedly connected with a power generation mechanism ratchet wheel b on the inner side; the bevel gear a of the power generation mechanism is movably coaxially connected with the ratchet wheel a of the power generation mechanism; the bevel gear b of the power generation mechanism is movably and coaxially linked with the ratchet wheel b of the power generation mechanism; the generating mechanism bevel gear c is in bevel gear meshing connection with the generating mechanism bevel gear a and the generating mechanism bevel gear b; the power generation mechanism is characterized in that a power generation mechanism ratchet wheel clamping loose piece positioning block and a ratchet wheel clamping link shaft are fixedly connected with a power generation mechanism bevel gear b, and a power generation mechanism ratchet wheel clamping loose piece positioning block is fixedly connected with a power generation mechanism ratchet wheel clamping loose piece positioning block spring; the connecting shaft of the ratchet wheel buckle is movably connected with the dead-locking movable block a of the power generation mechanism, namely the ratchet wheel buckle; the inner side of a bevel gear a of the power generation mechanism is the same; a motor shaft of the generator is fixedly connected with a generator ratchet wheel b; the generator is fixed on the generator device shell; when the rack of the power generation mechanism moves upwards, the gear a of the power generation mechanism rotates clockwise to drive the ratchet wheel a of the power generation mechanism to rotate clockwise, the buckle on the bevel gear a of the power generation mechanism is blocked with the ratchet wheel a of the power generation mechanism, and the bevel gear a of the power generation mechanism rotates clockwise to drive the bevel gear c of the power generation mechanism to rotate anticlockwise and drive the bevel gear b of the power generation mechanism to rotate anticlockwise; the clamping connecting shaft of the clamping thorn wheel can enable the spring of the positioning block of the dead block of the clamping thorn wheel of the power generation mechanism to be propped against so as to enable the bevel gear b of the power generation mechanism and the thorn wheel b of the power generation mechanism to be clamped, and the thorn wheel b of the power generation mechanism on the inner side can not be clamped with the bevel gear b of the power generation mechanism so as to enable the thorn wheel b of the power generation mechanism to rotate anticlockwise and drive the power generator to generate power; when the rack of the power generation mechanism moves downwards, the gear a of the power generation mechanism rotates anticlockwise to drive the ratchet wheel a of the power generation mechanism to rotate anticlockwise, the bevel gear a of the power generation mechanism cannot be locked with the ratchet wheel a of the power generation mechanism, meanwhile, the ratchet wheel a of the power generation mechanism can drive the ratchet wheel b of the power generation mechanism, which is arranged inside the bevel gear b of the power generation mechanism, to be locked with the bevel gear b of the power generation mechanism, the bevel gear b of the power generation mechanism rotates anticlockwise, the bevel gear b of the power generation mechanism is locked with the ratchet wheel b of the power generation mechanism, and the ratchet wheel; meanwhile, the bevel gear b of the power generation mechanism can drive the bevel gear a of the power generation mechanism to rotate clockwise, but the bevel gear b of the power generation mechanism cannot be clamped with the ratchet wheel a of the power generation mechanism, and the rotation of the ratchet wheel a of the power generation mechanism is not influenced.
Furthermore, the roof is arranged on the upper end surface of the machine room shell, the roof motor is fixedly arranged on the roof shell, and the roof shell is provided with a circular door opening; the roof screw rod is arranged on a motor shaft of the roof motor, and the roof nut is arranged on the roof screw rod to be meshed with the roof screw rod; the movable door nut is fixedly connected with two sides of the roof nut, and circular holes are formed in two sides of the movable door nut and movably connected with one end of the movable door connecting rod; the movable door is movably connected to the other end of the movable door chain connecting rod, and meanwhile, a rectangular column of the movable door is movably connected to a small column on the roof shell; when the roof screw rod rotates, the roof nut drives the movable door nut to move left and right in a linked mode, and therefore the movable door is controlled to be opened and closed.
Furthermore, the lower end face of an antenna joint a of the standby antenna mechanism is fixedly arranged on the lower end face in the machine room shell, and the axis of the standby antenna mechanism is coaxial with the door hole of the roof shell; the antenna joint b is arranged on the upper end surface of the antenna joint a in a sliding manner; the antenna joint c is arranged on the upper end surface of the antenna joint b in a sliding manner; the antenna joint d is arranged on the upper end surface of the antenna joint c in a sliding manner; the antenna joint d is hollow, a rectangular groove is formed in the outer ring of the antenna joint d, and a thin shaft is arranged in the center of the antenna joint d and used for fixing a standby antenna; in the normal state, the antenna joint d, the antenna joint c and the antenna joint b are sequentially contracted in the antenna joint a, and the movable door on the roof is closed; when a dangerous situation occurs, the standby antenna mechanisms are sequentially extended, meanwhile, the movable door on the roof is opened, and the standby antenna on the antenna joint d is unfolded.
Furthermore, the spare antenna is fixedly arranged on a shaft in the middle of the antenna joint d; the antenna motor is fixedly arranged on the upper end surface inside the antenna joint d; the antenna straight gear a is arranged on a motor shaft of the antenna motor, and the antenna straight gear b is arranged on a shaft of the antenna joint d and is meshed with the antenna straight gear a; the antenna threaded rod is rotationally linked to the shaft of the antenna joint d and is fixedly connected with the antenna straight gear b; the antenna rod gear is rotatably arranged on a circular shaft of the antenna rod positioning mechanism and is meshed with the antenna threaded rod; one end of the antenna rod is fixedly arranged on the antenna rod gear; when the antenna is required, the antenna motor drives the antenna straight gear a and the antenna straight gear b to rotate, the antenna threaded rod is driven to rotate, the antenna threaded rod drives the antenna rod gear to rotate, and therefore the antenna rod can extend and retract on the antenna joint d.
Due to the adoption of the technical scheme, the invention has the following advantages:
(1) the clamping connecting shaft of the power generation mechanism ratchet wheel can enable the power generation mechanism ratchet wheel clamping loose block positioning block to be propped by a spring so as to enable the power generation mechanism bevel gear b and the power generation mechanism ratchet wheel b to be clamped, the power generation mechanism ratchet wheel b on the inner side cannot be clamped with the power generation mechanism bevel gear b so as to enable the power generation mechanism ratchet wheel b to rotate anticlockwise and drive a power generator to generate power, a hydraulic damping mechanism is arranged inside the power generation mechanism ratchet wheel b, the power generation mechanism ratchet wheel b can effectively resist earthquakes, cannot damage a base station, and can use the vibrating inner part to generate power;
(2) when flood exists, the flood control mechanism is triggered when the water level reaches a certain height, the safety air bag is unfolded to serve as an air bag, so that the shell of the machine room cannot be flooded, and the safety air bag is arranged on the outer side of the machine room and can be bounced off to prevent the base station from being flooded when the water situation occurs;
(3) when needs, antenna motor drives antenna straight-toothed gear a, antenna straight-toothed gear b and rotates, drives the antenna threaded rod and rotates, and the antenna threaded rod drives the antenna mast gear rotatory to make the extension and the shrink of antenna realization on antenna joint d, inside still is equipped with reserve antenna, and ordinary shrink pops up when having the dangerous case earlier and ensures that the disaster area can not the communication interrupt.
Drawings
Fig. 1 is a schematic view of the overall structure of the present invention.
FIG. 2 is a schematic view of the internal structure of the present invention.
Fig. 3 and fig. 4 are schematic structural views of the anti-seismic power generation module according to the present invention.
FIG. 5 is a schematic view of the chuck structure of the anti-vibration mechanism of the present invention.
Fig. 6 is a partially enlarged view of the chuck a of the present invention.
Fig. 7 is a schematic view of the internal structure of the power generation mechanism of the present invention.
FIG. 8 is a schematic view of the structure of the door of the invention.
Fig. 9 is a schematic diagram of the overall structure of the stand-by antenna of the present invention.
Fig. 10 is a schematic diagram of the structure of the internal antenna of the spare antenna head according to the present invention.
Reference numerals: 1-machine room shell; 2-a standby antenna mechanism; 3-a base; 4-a shockproof power generation module; 5-a shock-proof mechanism; 6-module moving mechanism; 7-anti-vibration mechanism chuck; 8-a standby antenna; 9-roof; 10-a power generation mechanism; 11-flood control agencies; 12-a power generation mechanism housing; 201-antenna joint a; 202-antenna joint b; 203-antenna joint c; 204-antenna joint d; 401-shockproof power generation module a; 402-shockproof power generation module b; 403-shockproof power generation module c; 404-shockproof power generation module d; 501-a hydraulic cylinder body; 502-hydraulic lever; 503-damping spring; 601-a moving mechanism base; 603-moving mechanism motor; 604-moving mechanism screw; 605-moving mechanism lead screw nut; 606-the screw nut locks the spring buckle; 701-chuck housing; 702-a positioning shaft; 703-chuck gear; 704-a cam; 705-telescoping rod; 706-telescoping rod a; 708-chuck pinion; 709-chuck motor; 710-chuck pinion positioning; 707-chuck ring gear; 801-antenna motor; 802-antenna spur gear a; 803-antenna spur gear b; 804-antenna threaded rod; 805-an antenna mast; 806-an antenna mast positioning mechanism; 807-mast gear; 901-roof shell; 902-a movable door; 903-a movable door link rod; 904-moving door nut link; 905-roof motor; 906-roof nut; 907-roof screw; 1001-generating mechanism rack; 1002-generating mechanism gear a; 1003-power generation mechanism bevel gear a; 1004-a ratchet wheel of a power generation mechanism; 1006-a dead block positioning block of a ratchet wheel of the power generation mechanism; 1007-a movable block positioning block spring is locked by a ratchet wheel of a power generation mechanism; 1013-the power generation mechanism is provided with a dead-locked loose block a by a ratchet wheel; 1009-generating mechanism bevel gear b; 1010-a power generation mechanism ratchet wheel b; 1011-thorn ratchet buckle link shaft; 1012-a generator; 1008-power generation mechanism bevel gear c; 1101-flood control mechanism buoy; 1102-a flood protection mechanism positioning shaft; 1103-buoy link; 1104-trigger switch; 1105-an airbag; 1201-the power generation device housing links the slider with the wall; 1202-Generator device housing.
DETAILED DESCRIPTION OF EMBODIMENT (S) OF INVENTION
The technical scheme of the invention is further specifically described by the following embodiments and the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in many ways other than those described herein, and it will be apparent to those skilled in the art that similar modifications can be made without departing from the spirit of the invention, and therefore the invention is not limited to the specific embodiments disclosed below.
In the description of the present invention, it should be noted that the terms "upper", "lower", "front", "back", "left", "right", and the like indicate orientations or positional relationships based on orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention are conventionally placed in use, and are only used for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.
In the embodiment, as shown in fig. 1 to 10, a seismic and flood control 5G base station includes a machine room housing 1, a spare antenna mechanism 2, a base 3, a seismic power generation module 4, a seismic mechanism 5, a module moving mechanism 6, a seismic mechanism chuck 7, a spare antenna 8, a roof 9, a power generation mechanism 10, a flood control mechanism 11, and a power generation mechanism housing 12; the standby antenna mechanism 2 includes: an antenna joint a201, an antenna joint b202, an antenna joint c203, and an antenna joint d 204; the shockproof power generation module 4 comprises: the shockproof power generation module a401, the shockproof power generation module b402, the shockproof power generation module c403 and the shockproof power generation module d 404; the shockproof mechanism 5 includes: a hydraulic cylinder 501, a hydraulic rod 502 and a damping spring 503; the module moving mechanism 6 includes: the device comprises a moving mechanism base 601, a moving mechanism motor 603, a moving mechanism lead screw 604, a moving mechanism lead screw nut 605 and a lead screw nut clamping spring fastener 606; the shockproof mechanism chuck 7 includes: a chuck housing 701, a positioning shaft 702, a chuck gear 703, a cam 704, an expansion rod 705, an expansion rod a706, a chuck ring gear 707, a chuck pinion 708, a chuck motor 709, and a chuck pinion positioning 710; the backup antenna 8 includes: an antenna motor 801, an antenna straight gear a802, an antenna straight gear b803, an antenna threaded rod 804, an antenna rod 805, an antenna rod positioning mechanism 806 and an antenna rod gear 807; the roof 9 includes: a roof shell 901, a movable door 902, a movable door link rod 903, a movable door nut link 904, a roof motor 905, a roof nut 906 and a roof screw 907; the power generation mechanism 10 includes: a generating mechanism rack 1001, a generating mechanism gear a 1002, a generating mechanism bevel gear a1003, a generating mechanism ratchet wheel a1004, a generating mechanism ratchet wheel clamping loose piece positioning block 1006, a generating mechanism ratchet wheel clamping loose piece positioning block spring 1007, a generating mechanism bevel gear c1008, a generating mechanism bevel gear b1009, a generating mechanism ratchet wheel b1010, a ratchet wheel clamping and linking shaft 1011 and a generator 1012; the flood protection structure 11 comprises: flood protection mechanism buoy 1101, flood protection mechanism positioning shaft 1102, buoy connecting rod 1103, trigger switch 1104, airbag 1105, power generation device shell and wall surface link sliding block 1201 and power generation device shell 1202.
The machine room shell 1 is fixed with the base 3 under the condition of no danger, and the standby antenna mechanism 2 is retracted in the machine room shell 1; when a dangerous situation occurs, the shockproof mechanism 5 can jack the machine room shell 1 up to be separated from the base 3, the shockproof mechanism is fixed by using the shockproof mechanism chuck 7, and then the shockproof mechanism 5 does not move and becomes movably connected; the shockproof power generation module a401, the shockproof power generation module b402, the shockproof power generation module c403 and the shockproof power generation module d404 on the shockproof power generation module 4 are fixedly arranged on the upper end surface of the base 3, and the shockproof power generation module 4 is used for generating power by using the shaking force; while the standby antenna mechanism 2 is extended for serving as the standby antenna 8; when flood exists and the water level reaches a certain height, the flood control mechanism 11 can be triggered, the safety airbag 1105 is unfolded to serve as an airbag, so that the machine room shell 1 cannot be flooded.
In an alternative implementation manner of the embodiment of the present invention, as shown in fig. 2, a moving mechanism base 601 is fixedly installed inside a machine room housing 1, and serves as a positioning shaft 702; the flood control mechanism buoy 1101 is fixedly arranged on the lower end surface of the buoy connecting rod 1103, and the side surface of the buoy connecting rod 1103 is rotationally linked with the connecting shaft of the flood control mechanism positioning shaft 1102; when flood control mechanism buoy 1101 meets water, flood control mechanism buoy 1101 can float upward buoy connecting rod 1103 and can touch trigger switch 1104 fixedly connected with standby antenna mechanism 2, trigger switch 1104 is started and can be uniformly distributed on airbag 1105 on the outer side of standby antenna mechanism 2, and airbag 1105 explodes to enable standby antenna mechanism 2 not to be submerged, so that standby antenna mechanism 2 floats upward.
In an optional implementation manner of the embodiment of the present invention, as shown in fig. 3 and 4, the module moving mechanism 6 is a connecting mechanism between the power generation module and the wall surface, one side of the plate surface of the moving mechanism base 601 is provided with a groove, two ends of the groove extend out of the bracket, the moving mechanism motor 603 is fixedly connected with the moving mechanism base 601, and the moving mechanism lead screw 604 is installed on a motor shaft of the moving mechanism motor 603; the screw nut locking spring fastener 606 is fixedly arranged on the generating mechanism rack 1001; when the motor works, the moving mechanism screw 604 is driven to rotate; the moving mechanism screw nut 605 and the moving mechanism screw 604 are connected by a screw rod and a nut, when the moving mechanism screw 604 rotates, the moving mechanism screw nut 605 is driven to translate, and the screw nut is locked to the spring fastener 606 and the generating mechanism rack 1001 is bounced off. An electromagnetic buckle device is arranged at the front end of a link sliding block 1201 between the power generation device shell and the wall surface, is placed in a groove on one surface of a moving mechanism base 601, and can be clamped when moving to a specified position; the front end face of the generator device shell 1202 is fixedly connected with the rear end face of the generator device shell and the wall surface link sliding block 1201; one end of a screw nut 605 of the moving mechanism is provided with a bracket, the front end of the screw nut is provided with an electromagnetic spring clamping device which is usually clamped with a rack 1001 of the generating mechanism, and the rack 1001 of the generating mechanism and a shell 1202 of the generating device are also provided with electromagnetic clamping devices which are usually clamped; when a dangerous case occurs, the buckle of the screw nut 605 of the moving mechanism and the buckle of the shell 1202 of the generator device are bounced off, the motor 603 of the moving mechanism works, and the screw nut 605 of the moving mechanism drives the shell of the generator device to move along with the wall surface link sliding block 1201, the shell 1202 of the generator device and the rack 1001 of the generator device;
in an optional implementation manner of the embodiment of the present invention, as shown in fig. 3 and 4, the upper end surface of the hydraulic cylinder 501 is fixedly connected with the top end surface inside the machine room housing 1; the hydraulic rod 502 is connected with the hydraulic cylinder 501 in a sliding manner; a rectangular groove is arranged in the middle of the hydraulic rod 502, and an electromagnetic buckle is arranged on the inner side of the rectangular groove; a damping spring 503 is sleeved on the lower part of the hydraulic rod 502; when the power generation mechanism rack 1001 moves to a designated position, the electromagnet buckles pop up and are clamped, and the flood control mechanism buoy 1101 is separated from the power generator device shell 1202; the generator housing 1202 is locked to the moving mechanism base 601.
In an optional implementation manner of the embodiment of the present invention, as shown in fig. 5 and 6, the chuck 7 of the anti-vibration mechanism is normally locked with the hydraulic rod 502, when a dangerous situation occurs, the hydraulic rod 502 and the hydraulic cylinder 501 are mutually matched, and after the standby antenna mechanism 2 is lifted, the chuck 7 of the anti-vibration mechanism is separated from the hydraulic rod 502 and is locked with the machine room housing 1 to become a fixed connection; the outer ring of the chuck shell 701 is uniformly provided with circular grooves, and a small cylinder is arranged in the middle of the circular grooves; grooves are uniformly formed in the inner ring of the chuck shell 701; the positioning shaft 702 is fixedly connected with a small cylinder on the chuck shell 701; the chuck gear 703 is rotationally connected with the positioning shaft 702, and the cam 704 is fixedly arranged on the chuck gear 703; the telescopic rod 705 and the telescopic rod a706 are movably connected with the cam 704; the chuck ring gear 707 meshes with the chuck gear 703. A groove at one end of the telescopic rod a706 penetrates through the outer ring, a small cylinder of the chuck shell 701 penetrates through the groove, and the cylinder plays a positioning role; the telescoping rod 705 passes through the inner race groove; the chuck motor 709 is fixedly connected with the chuck shell 701, the chuck pinion 708 is connected with the chuck pinion positioning 710, and the chuck pinion positioning 710 is installed on a motor shaft of the chuck motor 709; chuck pinion 708 meshes with chuck ring gear 707; when the chuck motor 709 works, the chuck pinion 708 rotates, the chuck inner gear 707 meshed with the chuck pinion 708 rotates to drive the ten chuck gears 703 to rotate, the cam 704 rotates, and therefore the telescopic rod 705 and the telescopic rod a706 can be driven to move, and the chuck 7 of the anti-vibration mechanism is separated from the anti-vibration mechanism 5 and is clamped with the standby antenna mechanism 2.
In an alternative implementation of the embodiment of the present invention, as shown in fig. 7, the power generation mechanism 10 is inside the generator device housing 1202; the generating mechanism rack 1001 and the generating mechanism gear a 1002 are arranged outside the generator device shell 1202, the generating mechanism bevel gear c1008 is movably connected with the generator device shell 1202 in a rotating mode, and the generator device shell 1202 plays a role of a bracket; the power generation mechanism gear a 1002 is fixedly connected with a power generation mechanism ratchet wheel a1004, and the power generation mechanism ratchet wheel a1004 is fixedly connected with a ratchet wheel buckle link shaft 1011; the power generation mechanism ratchet wheel b1010 is also coaxially and rotatably connected with the inner side of the power generation mechanism bevel gear b 1009; a power generation mechanism ratchet wheel clamping loose piece positioning block 1006, a power generation mechanism ratchet wheel clamping loose piece positioning block spring 1007, a ratchet wheel clamping buckle link shaft 1011 and a power generation mechanism ratchet wheel clamping loose piece a1013 are also arranged on the inner side of a power generation mechanism bevel gear b 1009; the ratchet wheel buckle connecting shaft 1011 is fixedly connected with a power generation mechanism ratchet wheel b1010 on the inner side; the bevel gear a1003 of the power generation mechanism is movably coaxially connected with a ratchet wheel a1004 of the power generation mechanism; the bevel gear b1009 of the power generation mechanism is movably and coaxially linked with the ratchet wheel b1010 of the power generation mechanism; the generating mechanism bevel gear c1008 is in bevel gear meshing connection with the generating mechanism bevel gear a1003 and the generating mechanism bevel gear b 1009; the power generation mechanism ratchet wheel clamping loose piece positioning block 1006 and the ratchet wheel clamping link shaft 1011 are fixedly connected with a power generation mechanism bevel gear b1009, and the power generation mechanism ratchet wheel clamping loose piece positioning block 1006 is fixedly connected with a power generation mechanism ratchet wheel clamping loose piece positioning block spring 1007; the connecting shaft 1011 of the ratchet wheel fastener is movably connected with the dead-locking movable block a1013 of the ratchet wheel of the power generation mechanism, and the dead-locking movable block is a ratchet wheel fastener; the same principle is applied to the inner side of a bevel gear a1003 of the power generation mechanism; a motor shaft of the generator 1012 is fixedly connected with a generator ratchet wheel b 1010; the generator 1012 is secured to the generator device housing 1202; when the rack 1001 of the power generation mechanism moves upwards, the gear a 1002 of the power generation mechanism rotates clockwise to drive the ratchet wheel a1004 of the power generation mechanism to rotate clockwise, the buckle on the bevel gear a1003 of the power generation mechanism is blocked with the ratchet wheel a1004 of the power generation mechanism, and the bevel gear a1003 of the power generation mechanism rotates clockwise to drive the bevel gear c1008 of the power generation mechanism to rotate anticlockwise and drive the bevel gear b1009 of the power generation mechanism to rotate anticlockwise; the snap-fit ratchet snap-fit link shaft 1011 enables the dead-locking movable block positioning block spring 1007 of the power generation mechanism ratchet to be propped against so as to enable the bevel gear b1009 of the power generation mechanism to be dead-locked with the ratchet wheel b1010 of the power generation mechanism, and the ratchet wheel b1010 of the power generation mechanism on the inner side cannot be dead-locked with the bevel gear b1009 of the power generation mechanism so as to enable the ratchet wheel b1010 of the power generation mechanism to rotate anticlockwise and drive the power generator 1012 to generate power; when the generating mechanism rack 1001 moves downwards, the generating mechanism gear a 1002 rotates anticlockwise to drive the generating mechanism ratchet wheel a1004 to rotate anticlockwise, the generating mechanism bevel gear a1003 cannot be clamped with the generating mechanism ratchet wheel a1004, meanwhile, the generating mechanism ratchet wheel a1004 can drive the generating mechanism ratchet wheel b1010 and the generating mechanism bevel gear b1009 which are arranged in the generating mechanism bevel gear b1009 to be clamped, the generating mechanism bevel gear b1009 rotates anticlockwise, the generating mechanism bevel gear b1009 and the generating mechanism ratchet wheel b1010 are clamped, and the generating mechanism ratchet wheel b1010 rotates anticlockwise; meanwhile, the bevel gear b1009 of the generating mechanism can drive the bevel gear a1003 of the generating mechanism to rotate clockwise, but cannot be locked with the ratchet wheel a1004 of the generating mechanism, and the rotation of the ratchet wheel a1004 of the generating mechanism is not influenced.
In an optional implementation manner of the embodiment of the present invention, as shown in fig. 8, a roof 9 is installed on an upper end surface of a machine room housing 1, a roof motor 905 is fixedly installed on a roof housing 901, and the roof housing 901 is provided with a circular door opening; a roof screw 907 is mounted on a motor shaft of the roof motor 905, and a roof nut 906 is mounted on the roof screw 907 to be meshed therewith; the movable door nut link 904 is fixedly arranged on two sides of the roof nut 906, and circular holes are formed in the two sides of the movable door nut link 904 and are movably connected with one end of the movable door link rod 903; the movable door 902 is movably connected to the other end of the movable door link rod 903, and meanwhile, a rectangular column of the movable door 902 is movably connected to a small column on the roof shell 901; when the roof screw 907 rotates, the roof nut 906 drives the movable door nut link 904 to move left and right, thereby controlling the opening and closing of the movable door 902.
In an optional implementation manner of the embodiment of the present invention, as shown in fig. 9, a low end surface of an antenna joint a201 of a standby antenna mechanism 2 is fixedly installed on a lower end surface inside a machine room housing 1, and an axis of the standby antenna mechanism 2 is coaxial with a door opening of a roof housing 901; the antenna joint b202 is slidably mounted on the upper end surface of the antenna joint a 201; the antenna joint c203 is slidably mounted on the upper end surface of the antenna joint b 202; the antenna joint d204 is slidably mounted on the upper end surface of the antenna joint c 203; the antenna joint d204 is hollow, a rectangular groove is formed in the outer ring of the antenna joint d204, and a thin shaft is arranged in the center of the antenna joint d and used for fixing the standby antenna 8; in a normal state, the antenna joint d204, the antenna joint c203 and the antenna joint b202 are sequentially contracted in the antenna joint a201, and the movable door 902 on the roof 9 is closed; in case of danger, the standby antenna mechanism 2 is sequentially extended, and at the same time the movable door 902 on the roof 9 is opened and the standby antenna 8 on the antenna joint d204 is deployed.
In an alternative implementation of the embodiment of the present invention, as shown in fig. 10, the standby antenna 8 is fixedly mounted on the shaft in the middle of the antenna joint d 204; the antenna motor 801 is fixedly arranged on the upper end face inside the antenna joint d 204; an antenna spur gear a802 is installed on a motor shaft of an antenna motor 801, and an antenna spur gear b803 is installed on a shaft of an antenna joint d204 and meshed with the antenna spur gear a 802; the antenna threaded rod 804 is rotationally linked to the shaft of the antenna joint d204 and is fixedly connected with the antenna straight gear b 803; an antenna rod gear 807 is rotatably mounted on the circular shaft of the antenna rod positioning mechanism 806 and is meshed with the antenna threaded rod 804; one end of the antenna rod 805 is fixedly mounted on the antenna rod gear 807; when needed, the antenna motor 801 drives the antenna spur gear a802 and the antenna spur gear b803 to rotate, and drives the antenna threaded rod 804 to rotate, and the antenna threaded rod 804 drives the antenna rod gear 807 to rotate, so that the antenna rod 805 extends and retracts on the antenna joint d 204.

Claims (8)

1. An anti-seismic flood control 5G base station comprises a machine room shell (1), a standby antenna mechanism (2), a base (3), an anti-seismic power generation module (4), an anti-seismic mechanism (5), a module moving mechanism (6), an anti-seismic mechanism chuck (7), a standby antenna (8), a roof (9), a power generation mechanism (10), a flood control mechanism (11) and a power generation mechanism shell (12); the backup antenna mechanism (2) comprises: an antenna joint a (201), an antenna joint b (202), an antenna joint c (203), and an antenna joint d (204); the shockproof power generation module (4) comprises: the system comprises an anti-vibration power generation module a (401), an anti-vibration power generation module b (402), an anti-vibration power generation module c (403) and an anti-vibration power generation module d (404); the shockproof mechanism (5) comprises: the hydraulic cylinder body (501), the hydraulic rod (502) and the damping spring (503); the module moving mechanism (6) includes: the device comprises a moving mechanism base (601), a moving mechanism motor (603), a moving mechanism lead screw (604), a moving mechanism lead screw nut (605) and a lead screw nut clamping spring fastener (606); the shockproof mechanism chuck (7) comprises: the automatic chuck device comprises a chuck shell (701), a positioning shaft (702), a chuck gear (703), a cam (704), an expansion rod (705), an expansion rod a (706), a chuck inner gear (707), a chuck pinion (708), a chuck motor (709) and a chuck pinion positioning (710); the backup antenna (8) comprises: an antenna motor (801), an antenna straight gear a (802), an antenna straight gear b (803), an antenna threaded rod (804), an antenna rod (805), an antenna rod positioning mechanism (806) and an antenna rod gear (807); the roof (9) comprises: the device comprises a roof shell (901), a movable door (902), a movable door link rod (903), a movable door nut link (904), a roof motor (905), a roof nut (906) and a roof screw rod (907); the power generation mechanism (10) includes: the device comprises a power generation mechanism rack (1001), a power generation mechanism gear a (1002), a power generation mechanism bevel gear a (1003), a power generation mechanism ratchet wheel a (1004), a power generation mechanism ratchet wheel clamping loose piece positioning block (1006), a power generation mechanism ratchet wheel clamping loose piece positioning block spring (1007), a power generation mechanism bevel gear c (1008), a power generation mechanism bevel gear b (1009), a power generation mechanism ratchet wheel b (1010), a ratchet wheel clamping and linking shaft (1011) and a power generator (1012); the flood protection mechanism (11) comprises: flood protection mechanism buoy (1101), flood protection mechanism location axle (1102), buoy connecting rod (1103), trigger switch (1104), air bag (1105), power generation facility shell and wall link sliding block (1201), power generation facility shell (1202), its characterized in that: the machine room shell (1) is fixed with the base (3) under the condition of no danger, and the standby antenna mechanism (2) is retracted in the machine room shell (1); when a dangerous situation occurs, the shockproof mechanism (5) can jack the machine room shell (1) to be separated from the base (3), the shockproof mechanism is fixed by using the shockproof mechanism chuck (7), and then the shockproof mechanism (5) does not move and becomes movably connected; the shockproof power generation module a (401), the shockproof power generation module b (402), the shockproof power generation module c (403) and the shockproof power generation module d (404) on the shockproof power generation module (4) are fixedly arranged on the upper end surface of the base (3), and the shockproof power generation module (4) is used for generating power by using the shaking force; while the backup antenna mechanism (2) is extended for acting as a backup antenna (8); when flood exists, when the water level reaches a certain height, the flood control mechanism (11) can be triggered, the safety airbag (1105) is unfolded to serve as an airbag, and the machine room shell (1) cannot be flooded.
2. An earthquake-resistant and flood-proof 5G base station according to claim 1, wherein the moving mechanism base (601) is fixedly arranged inside the machine room shell (1) and is used as a positioning shaft (702); the flood control mechanism buoy (1101) is fixedly arranged on the lower end face of the buoy connecting rod (1103), and the side face of the buoy connecting rod (1103) is rotatably connected with a connecting shaft of the flood control mechanism positioning shaft (1102).
3. An earthquake-resistant flood-control 5G base station according to claim 2, wherein the module moving mechanism (6) is a connecting mechanism of a power generation module and a wall surface, one side of the surface of the moving mechanism base (601) is provided with a groove, two ends of the groove extend out of the bracket, the moving mechanism motor (603) is fixedly connected with the moving mechanism base (601), and the moving mechanism lead screw (604) is arranged on a motor shaft of the moving mechanism motor (603); a screw nut blocking spring fastener (606) is fixedly arranged on a rack (1001) of the power generation mechanism; an electromagnetic buckle device is arranged at the front end of a link sliding block (1201) between the power generation device shell and the wall surface and is placed in a groove on one surface of a moving mechanism base (601); the lock can be locked when the lock moves to a specified position; the front end face of the generator device shell (1202) is fixedly connected with the rear end face of the generator device shell and the wall surface link sliding block (1201); one end of a screw nut (605) of the moving mechanism is provided with a support, the front end of the screw nut is provided with an electromagnetic spring clamping device which is usually clamped with a rack (1001) of the generating mechanism, and the rack (1001) of the generating mechanism and a shell (1202) of the generator device are also provided with electromagnetic clamping buckles which are usually clamped.
4. An earthquake-resistant and flood-proof 5G base station according to claim 1, wherein the upper end surface of the hydraulic cylinder body (501) is fixedly connected with the top end surface inside the machine room shell (1); the hydraulic rod (502) is connected with the hydraulic cylinder body (501) in a sliding manner; a rectangular groove is arranged in the middle of the hydraulic rod (502), and an electromagnetic buckle is arranged on the inner side of the rectangular groove; the damping spring (503) is sleeved on the lower part of the hydraulic rod (502).
5. An earthquake-resistant and flood-proof 5G base station according to claim 1, wherein the chuck (7) of the earthquake-resistant mechanism is normally locked by a hydraulic rod (502); the outer ring of the chuck shell (701) is uniformly provided with circular grooves, and a small cylinder is arranged in the middle of the circular grooves; grooves are uniformly formed in the inner ring of the chuck shell (701); the positioning shaft (702) is fixedly connected with a small cylinder on the chuck shell (701); the chuck gear (703) is rotationally connected with the positioning shaft (702), and the cam (704) is fixedly arranged on the chuck gear (703); the telescopic rod (705) and the telescopic rod a (706) are movably connected with the cam (704); a chuck ring gear (707) meshing with the chuck gear (703); a groove at one end of the telescopic rod a (706) penetrates through the outer ring, a small cylinder of the chuck shell (701) penetrates through the groove, and the cylinder plays a positioning role; the telescopic rod (705) penetrates through the groove of the inner ring; the chuck motor (709) is fixedly connected with the chuck shell (701), the chuck pinion (708) is linked on a chuck pinion positioning (710), and the chuck pinion positioning (710) is installed on a motor shaft of the chuck motor (709); the chuck pinion (708) meshes with a chuck ring gear (707).
6. An earthquake-resistant flood-protection 5G base station according to claim 1, characterized in that said power generation means (10) is inside the generator device housing (1202); the generating mechanism rack (1001) and the generating mechanism gear a (1002) are arranged outside the generator device shell (1202), the generating mechanism bevel gear c (1008) is movably connected with the generator device shell (1202) in a rotating way, and the generator device shell (1202) plays a role of a bracket; the power generation mechanism gear a (1002) is fixedly connected with a power generation mechanism ratchet wheel a (1004), and the power generation mechanism ratchet wheel a (1004) is fixedly connected with a ratchet wheel buckle link shaft (1011); the power generation mechanism ratchet wheel b (1010) is also coaxially and rotationally connected with the inner side of the power generation mechanism bevel gear b (1009); a power generation mechanism ratchet wheel clamping loose piece positioning block (1006), a power generation mechanism ratchet wheel clamping loose piece positioning block spring (1007), a ratchet wheel clamping buckle connecting shaft (1011) and a power generation mechanism ratchet wheel clamping loose piece a (1013) are also arranged on the inner side of a power generation mechanism bevel gear b (1009); the ratchet wheel buckle connecting shaft (1011) is fixedly connected with the power generation mechanism ratchet wheel b (1010) on the inner side; the bevel gear a (1003) of the power generation mechanism is movably coaxially connected with a ratchet wheel a (1004) of the power generation mechanism; the bevel gear b (1009) of the power generation mechanism is movably and coaxially linked with the ratchet wheel b (1010) of the power generation mechanism; the generating mechanism bevel gear c (1008) is in bevel gear meshing connection with the generating mechanism bevel gear a (1003) and the generating mechanism bevel gear b (1009); the power generation mechanism dead-locking movable block positioning block (1006) is fixedly connected with a power generation mechanism bevel gear b (1009) through a power generation mechanism dead-locking movable block clamping and connecting shaft (1011), and the power generation mechanism dead-locking movable block positioning block (1006) is fixedly connected with a power generation mechanism dead-locking movable block positioning block spring (1007); the connecting shaft (1011) of the ratchet wheel buckle is movably connected with the dead-locking movable block a (1013) of the ratchet wheel of the power generation mechanism, and the dead-locking movable block a is a ratchet wheel buckle; the same principle is applied to the inner side of a bevel gear a (1003) of the power generation mechanism; a motor shaft of the generator (1012) is fixedly connected with a generator mechanism ratchet wheel b (1010); the generator (1012) is secured to the generator device housing (1202).
7. An earthquake-resistant and flood-proof 5G base station according to claim 1, wherein the roof (9) is installed on the upper end surface of the machine room housing (1), the roof motor (905) is fixedly installed on the roof housing (901), and the roof housing (901) is provided with a circular door opening; the roof screw (907) is installed on a motor shaft of the roof motor (905), and the roof nut (906) is installed on the roof screw (907) to be meshed with the roof screw; the movable door nut link (904) is fixedly arranged on two sides of the roof nut (906), and circular holes are formed in the two sides of the movable door nut link and movably connected with one end of the movable door link rod (903); the movable door (902) is movably connected to the other end of the movable door chain connecting rod (903), and meanwhile, the rectangular column of the movable door (902) is movably connected to the small column on the roof shell (901).
8. An earthquake-resistant and flood-proof 5G base station according to claim 1, wherein the lower end face of the antenna joint a (201) of the standby antenna mechanism (2) is fixedly arranged on the lower end face of the interior of the machine room shell (1), and the axis of the standby antenna mechanism (2) is coaxial with the door opening of the roof shell (901); the antenna joint b (202) is slidably mounted on the upper end face of the antenna joint a (201); the antenna joint c (203) is slidably mounted on the upper end face of the antenna joint b (202); the antenna joint d (204) is slidably mounted on the upper end face of the antenna joint c (203); the antenna joint d (204) is hollow, a rectangular groove is formed in the outer ring of the antenna joint d, and a thin shaft is arranged in the center of the antenna joint d and used for fixing the standby antenna (8); the spare antenna (8) is fixedly arranged on the shaft in the middle of the antenna joint d (204); the antenna motor (801) is fixedly arranged on the upper end face inside the antenna joint d (204); an antenna straight gear a (802) is installed on a motor shaft of an antenna motor (801), and an antenna straight gear b (803) is installed on a shaft of an antenna joint d (204) and meshed with the antenna straight gear a (802); the antenna threaded rod (804) is rotationally linked to the shaft of the antenna joint d (204) and is fixedly connected with the antenna straight gear b (803); an antenna rod gear (807) is rotatably arranged on a circular shaft of the antenna rod positioning mechanism (806) and is meshed with the antenna threaded rod (804); one end of the antenna rod (805) is fixedly mounted on the antenna rod gear (807).
CN202010783536.0A 2020-08-06 2020-08-06 Antidetonation flood control 5G basic station Active CN111836129B (en)

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CN112886432A (en) * 2021-04-12 2021-06-01 胡雪梅 Movable power distribution cabinet

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CN112886432A (en) * 2021-04-12 2021-06-01 胡雪梅 Movable power distribution cabinet

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