CN113690769A - Anticreep structure is used in distribution convenient to install fast - Google Patents
Anticreep structure is used in distribution convenient to install fast Download PDFInfo
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- CN113690769A CN113690769A CN202110950524.7A CN202110950524A CN113690769A CN 113690769 A CN113690769 A CN 113690769A CN 202110950524 A CN202110950524 A CN 202110950524A CN 113690769 A CN113690769 A CN 113690769A
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- 238000000926 separation method Methods 0.000 claims abstract description 9
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- 239000012528 membrane Substances 0.000 claims abstract description 7
- 238000007789 sealing Methods 0.000 claims description 48
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- 239000000110 cooling liquid Substances 0.000 claims description 13
- 238000004804 winding Methods 0.000 claims description 9
- 238000009434 installation Methods 0.000 claims description 8
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Classifications
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02B—BOARDS, SUBSTATIONS OR SWITCHING ARRANGEMENTS FOR THE SUPPLY OR DISTRIBUTION OF ELECTRIC POWER
- H02B1/00—Frameworks, boards, panels, desks, casings; Details of substations or switching arrangements
- H02B1/56—Cooling; Ventilation
- H02B1/565—Cooling; Ventilation for cabinets
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01D—SEPARATION
- B01D46/00—Filters or filtering processes specially modified for separating dispersed particles from gases or vapours
- B01D46/54—Particle separators, e.g. dust precipitators, using ultra-fine filter sheets or diaphragms
- B01D46/543—Particle separators, e.g. dust precipitators, using ultra-fine filter sheets or diaphragms using membranes
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02B—BOARDS, SUBSTATIONS OR SWITCHING ARRANGEMENTS FOR THE SUPPLY OR DISTRIBUTION OF ELECTRIC POWER
- H02B1/00—Frameworks, boards, panels, desks, casings; Details of substations or switching arrangements
- H02B1/26—Casings; Parts thereof or accessories therefor
- H02B1/28—Casings; Parts thereof or accessories therefor dustproof, splashproof, drip-proof, waterproof or flameproof
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02B—BOARDS, SUBSTATIONS OR SWITCHING ARRANGEMENTS FOR THE SUPPLY OR DISTRIBUTION OF ELECTRIC POWER
- H02B1/00—Frameworks, boards, panels, desks, casings; Details of substations or switching arrangements
- H02B1/26—Casings; Parts thereof or accessories therefor
- H02B1/30—Cabinet-type casings; Parts thereof or accessories therefor
Abstract
The invention discloses an anti-creeping structure for power distribution, which is convenient to install quickly and comprises an outer protection component, wherein the top of the inner side of the outer protection component is fixedly connected with an air flow circulation component, and the air flow circulation component is used for introducing low-temperature air into the outer protection component; in this scheme, highly from debugging the subassembly through the design, the air current circulation subassembly, the power conversion subassembly, high temperature air derives subassembly and low temperature air and introduces under the structure such as subassembly cooperates mutually, utilize remaining static charge in the air will be held back on the electrolyte filtering layer, supply the static charge, guarantee the purifying effect of follow-up electrolyte filtering layer to the air, and at the in-process that low temperature air introduced, utilize the gas-liquid separation membrane to realize the separation of water and gas, and then can avoid the high temperature air to take place the water congealing in the inside of inner seal box when contacting with low temperature air, and the leakproofness is high, realized the cooling of switch board, dispel the heat, it is waterproof, functions such as dustproof and prevent static.
Description
Technical Field
The invention relates to the technical field of power equipment, in particular to an anti-creeping structure for power distribution, which is convenient to install quickly.
Background
The existing outdoor power distribution cabinet is a common electrical product in life, the outdoor power distribution cabinet is arranged outdoors and used for placing various electrical devices, Chinese patent document CN110176724B discloses a constant-temperature high-waterproofness power distribution cabinet body and a working method thereof, but when the outdoor power distribution cabinet is actually used, certain defects still exist:
generally, after entering the interior of the power distribution cabinet and contacting with high-temperature air, low-temperature air is easy to condense, so that the moisture in the cabinet body is large, the power distribution cabinet and electronic components mounted in the power distribution cabinet are easy to corrode, the aging speed is accelerated, and further adverse phenomena such as electric leakage are caused;
then, rainwater easily enters the interior of the power distribution cabinet, so that short circuit or damage of power distribution elements is caused, and the service life of the power distribution cabinet is seriously influenced;
in addition, a large amount of static charges are easily accumulated in the wire, so that harmful substances such as dust and bacteria are accumulated on the surfaces of the wire and the electronic component and are not easy to remove, the stability of the wire and the electronic component in the operation process is influenced, and short circuit and electric leakage are further caused.
Disclosure of Invention
Aiming at the defects in the prior art, the invention aims to provide the anti-creeping structure for power distribution, which is convenient to install quickly and has the characteristics of static resistance, condensation resistance, rain resistance and electric creeping prevention.
In order to achieve the purpose, the invention provides the following technical scheme:
an anticreep structure for distribution convenient to quick installation includes:
the top of the inner side of the outer protection component is fixedly connected with an air flow circulation component, the air flow circulation component is used for introducing low-temperature air into the outer protection component, and the surface of the air flow circulation component is respectively communicated with a high-temperature air outlet component and a low-temperature air inlet component;
low temperature air introduces the subassembly, low temperature air introduces the subassembly and includes normal atmospheric temperature air introduction valve pipe, normal atmospheric temperature air introduction valve pipe joint is on the surface of shower nozzle, the port of normal atmospheric temperature air introduction valve pipe is located the coolant liquid circulation intracavity, the position department that corresponds low temperature air introduction piston seat on the piston sleeve box side end face communicates through low temperature air introduction valve pipe and coolant liquid circulation chamber, the port department of low temperature air introduction valve pipe and normal atmospheric temperature air introduction valve pipe all is provided with the gas-liquid separation membrane.
Further, the outer protection assembly comprises an outer sealing box and an inner sealing box, the inner sealing box is connected in an embedded mode inside the outer sealing box, and a sealed cooling liquid circulation cavity is formed between the outer sealing box and the inner sealing box.
Furthermore, a height self-adjusting assembly is arranged on the periphery of the outer sealing box and comprises a sunshade seat, the sunshade seat is positioned above the outer sealing box, a rainwater filter plate is embedded into a port of the sunshade seat, a pressing type conversion shaft is fixedly connected to four corners of the bottom of the sunshade seat, an upward-lifting type conversion shaft is connected to the surface of the pressing type conversion shaft in a sliding mode, and the same steel hoop clamped at the top of the outer sealing box is sleeved on the surfaces of the upward-lifting type conversion shaft and the pressing type conversion shaft.
Through adopting above-mentioned technical scheme, the sunshade seat still possesses the collection function of rainwater when playing thermal-insulated effect to external protection component, and the rainwater after rainwater filter filtration is gathered in the inside of sunshade seat.
Furthermore, the surface of the lifting type conversion shaft and the surface of the pressing type conversion shaft are sleeved with the same supporting type telescopic outer barrel, concave surface-shaped tooth surface grooves are formed in the positions, corresponding to the supporting type telescopic outer barrel, between the pressing type conversion shaft and the lifting type conversion shaft, concave surface-shaped tooth surface grooves are formed in the positions, corresponding to the supporting type telescopic outer barrel, between the two concave surface-shaped tooth surface grooves, the same conversion gear is linked, and the conversion gear is rotatably connected to the inner side wall of the supporting type telescopic outer barrel.
Through adopting above-mentioned technical scheme, utilize the conversion gear to turn into ascending thrust with decurrent thrust and promote outer protection component through the lift-up conversion axle and go upward, through promoting the height of outer protection component for ground.
Further, the air circulation subassembly includes the piston box cover, the inboard top of seal box including the top fixed connection of piston box cover, high temperature air derivation piston seat and low temperature air introduction piston seat have been cup jointed respectively to the inside of piston box cover, equal fixedly connected with threaded rod on the opposite face of low temperature air introduction piston seat and high temperature air derivation piston seat, the surperficial threaded connection of threaded rod has same screw-thread cylinder, screw-thread cylinder rotates to be connected on the inside wall of piston box cover, the surface of screw-thread cylinder still fixedly connected with driven bevel gear.
By adopting the technical scheme, when one of the fan blades is firstly subjected to the action of air flow and rotates, the generated torque can be transferred to the driving shaft through the linkage gear and the driven gear, and the driving bevel gear is driven by the driving shaft to rotate, so that the windward side of the rest of the fan blades can be automatically controlled.
Furthermore, the air flow circulation assembly further comprises a driven bevel gear, a driving bevel gear is meshed on the surface of the driven bevel gear and fixedly connected to the bottom end of the driving shaft, the driving bevel gear is respectively and rotatably connected to the tops of the inner sealing box and the outer sealing box, a power conversion assembly is further rotatably connected to the surface of the driving shaft and comprises a lower air disc and an upper air disc, the lower air disc and the upper air disc are both rotatably connected to the surface of the driving shaft, and the bottom of the lower air disc is fixedly connected to the top of the outer sealing box.
By adopting the technical scheme, in the process of driving the driving bevel gear to rotate by the driving shaft, the torque force is respectively acted on the two threaded cylinders by utilizing the linkage effect between the driving bevel gear and the two driven bevel gears.
Furthermore, the top of the upper layer wind plate is respectively connected with a driven gear, a linkage gear and a driving gear in a rotating mode, the driven gear is fixedly connected to the surface of the driving shaft, fan blades are further arranged between the lower layer wind plate and the lower layer wind plate, and the fan blades are fixedly connected to a rotating shaft connected with the driving gear.
By adopting the technical scheme, when the low-temperature air is introduced into the piston seat and moves towards one side close to the spray head, the negative pressure drainage effect is utilized, so that the low-temperature air which circularly flows in the cooling liquid circulating cavity can be introduced into the piston sleeve box through the low-temperature air introducing valve pipe.
Further, the high temperature air derivation subassembly includes bottom high temperature air derivation valve pipe, the one end that bottom high temperature air derivation valve pipe was located the inboard bottom of interior seal box, the other end joint of bottom high temperature air derivation valve pipe corresponds the position department of high temperature air derivation piston seat on piston sleeve box side end face, the position department that corresponds high temperature air derivation piston seat on the piston sleeve box side end face still the joint has the shower nozzle, the shower nozzle is the joint respectively on the side end face of interior seal box and outer seal box.
By adopting the technical scheme, when the low-temperature air is introduced into the piston seat and moves towards one side close to the spray head, the negative pressure drainage effect is utilized, so that the low-temperature air which circularly flows in the cooling liquid circulating cavity can be introduced into the piston sleeve box through the low-temperature air introducing valve pipe.
Further, be provided with the fan leaf in the low temperature air inlet valve pipe, fan leaf fixed connection is on a switching section of thick bamboo surface, the surface of a switching section of thick bamboo still rotates to be connected on the net face seat, net face seat joint is on the inside wall of low temperature air inlet valve pipe, the surface winding of a switching section of thick bamboo is connected with the winding coil to the position department joint that corresponds the winding coil on the low temperature air inlet valve pipe inside wall has two permanent magnetism seats, and two opposite magnetic poles of permanent magnetism seat, the position department that piston box front side end face corresponds low temperature air inlet piston seat is through low temperature air derivation valve pipe and the front side end face intercommunication of reposition of redundant personnel, reposition of redundant personnel fixed connection is in the bottom of piston box.
Through adopting above-mentioned technical scheme, in the low temperature air after being ionized will be through the internal seal box of reposition of redundant personnel scattering, on the one hand, realize the cooling radiating effect to the inside electronic components of internal seal box, on the other hand, can utilize the air after the ionization to eliminate the static charge on the electronic components, when high temperature air piston seat removed to the one side of keeping away from the shower nozzle, in will leading into the piston box with high temperature air through bottom high temperature air extraction valve pipe, when high temperature air piston seat removed to the one side of being close to the shower nozzle, high temperature air will spray on the electrolyte filtering layer through the shower nozzle.
Furthermore, bottom high temperature air draws out valve pipe, high temperature air and derives valve pipe, normal atmospheric temperature air and introduces valve pipe, low temperature air and introduces valve pipe and low temperature air and derive valve pipe and all be by the combination of pipeline and check valve, the joint has the cutting ferrule on the side end face of outer seal box, the embedded electrolyte filter layer that is connected with in inside of cutting ferrule.
In conclusion, the invention has the following beneficial effects:
1. in the scheme, by the mutual matching of the designed structures such as the height self-debugging assembly, the air flow circulation assembly, the power conversion assembly, the high-temperature air leading-out assembly, the low-temperature air leading-in assembly and the like, when the height of the outer protection assembly relative to the ground is increased, the water accumulation on the ground can be further prevented, the high-risk coefficient accidents such as electric leakage and the like caused by the fact that the outer protection assembly is deeply inserted into the inner part of the outer protection assembly under the influence of water pressure and liquid flow force are avoided, the safety and normal operation of electric components in the inner sealing box are ensured, the inner sealing box can be started automatically, the inner sealing box can work with wind, the operation efficiency is higher, the power coefficient and the power generation efficiency of wind power driving are improved, the output of the total power can be automatically controlled, the leading-in work of the low-temperature air in the inner sealing box and the leading-out work of the high-temperature air can be automatically carried out, and residual static charges in the air can be intercepted on an electrolyte filtering layer, the static charge is supplemented, the air purification effect of a subsequent electrolyte filter layer is ensured, and in the process of introducing low-temperature air, the gas-liquid separation membrane is utilized to realize the separation of water and gas, so that the water condensation in the inner sealing box can be avoided when the high-temperature air is contacted with the low-temperature air, the sealing performance is high, and the functions of cooling, heat dissipation, water prevention, dust prevention, static electricity prevention and the like of the power distribution cabinet are realized;
2. by the designed height self-adjusting assembly, the sunshade seat has the heat insulation effect on the external protection assembly, also has the function of collecting rainwater, the rainwater filtered by the rainwater filter plate is gathered in the sunshade seat, the whole weight of the sunshade seat gradually rises and generates the trend of descending along with the gathering of the rainwater, when the sunshade seat moves downwards in the supporting type telescopic outer barrel to retract, the downward thrust is converted into the upward thrust by the conversion gear, the outer protection component is pushed to move upwards by the lifting type conversion shaft, the height of the outer protection component relative to the ground is lifted, when water is accumulated on the ground, the water can be prevented from penetrating into the outer protection assembly under the influence of water pressure and liquid flow force to cause high-risk-coefficient accidents such as electric leakage and the like, so that the safety and normal operation of the electric components in the inner sealing box are ensured;
3. by the designed airflow circulating assembly and the power conversion assembly, when one of the fan blades rotates under the action of the airflow firstly, the generated torsion can be transferred to the driving shaft through the linkage gear and the driven gear, the driving bevel gear is driven to rotate by the driving shaft, the windward side of the rest of the fan blades can be automatically controlled, the number of the fan blades is set to be a plurality, the initial stress angles of the plurality of fan blades are different, the special capability of automatically adjusting the stress angles of the fan blades is utilized, the requirement of the fan blades on wind power is reduced, low wind pressure starting is realized, the self-starting can be realized, but also can work with wind, the operation efficiency is higher, the power coefficient and the generating efficiency driven by wind power are improved, the output of the total power can be automatically controlled, so that the work of introducing low-temperature air and the work of leading out high-temperature air in the inner sealing box can be automatically carried out;
4. through the designed air circulation assembly, the high-temperature air leading-out assembly and the low-temperature air leading-in assembly, in the process that the driving shaft drives the driving bevel gear to rotate, the torque force is respectively acted on the two thread cylinders by utilizing the linkage effect between the driving bevel gear and the two driven bevel gears, under the combined action effect of the torque force and the thread engagement force, the low-temperature air leading-in piston seat and the high-temperature air leading-out piston seat can respectively carry out corresponding piston motion by the same worker, when the low-temperature air leading-in piston seat moves to one side close to the spray head, the negative pressure drainage effect is utilized, so that the low-temperature air circularly flowing in the cooling liquid circulation cavity can be led into the piston sleeve box through the low-temperature air leading-in valve pipe, and the normal-temperature air filtered by the electrolyte filter layer can be led in through the normal-temperature air leading-in valve pipe and the probe along with the reduction of the air pressure intensity of the cooling liquid circulation cavity, in the process of introducing the low-temperature air into the piston sleeve box, the low-temperature air can directly act on the fan blades, the flowing force of the air can be converted into torsion and directly acts on the adapter cylinder by utilizing the particularity of the structure of the fan blades, the adapter cylinder drives the winding coil to cut magnetic induction lines generated between the permanent magnet bases and generate current, so that the low-temperature air flowing through the adapter cylinder can be ionized, when the low-temperature air is introduced into the piston base to move towards one side away from the spray head, the ionized low-temperature air can be scattered in the inner sealing box through the shunting body, on one hand, the cooling and heat dissipation effects on electronic components in the inner sealing box are realized, on the other hand, the static charges on the electronic components can be eliminated by utilizing the ionized air, when the high-temperature air piston base moves towards one side away from the spray head, the high-temperature air can be introduced into the piston sleeve box through the bottom-layer high-temperature air leading-out valve tube, when the high-temperature air piston seat moves to one side close to the spray head, high-temperature air is sprayed on the electrolyte filter layer through the spray head, on one hand, a backflushing effect is achieved, dust on the electrolyte filter layer can be removed, on the other hand, residual static charge in the air can be intercepted on the electrolyte filter layer to supplement the static charge, the air purifying effect of the follow-up electrolyte filter layer is guaranteed, in the process of introducing low-temperature air, water and air are separated through the gas-liquid separation membrane, water condensation in the inner sealing box when the high-temperature air is in contact with the low-temperature air can be avoided, the sealing performance is high, and the functions of cooling, heat dissipation, water prevention, dust prevention, static prevention and the like of the power distribution cabinet are achieved.
Drawings
FIG. 1 is a schematic perspective view of the present invention;
FIG. 2 is a schematic view of a disassembled structure of the height self-debugging assembly of the present invention;
FIG. 3 is a schematic cross-sectional view of a highly self-adjusting module according to the present invention;
FIG. 4 is a schematic view of the combined structure of the cryogenic air induction assembly and the power conversion assembly of the present invention;
FIG. 5 is a schematic perspective view of a power conversion module according to the present invention;
FIG. 6 is a perspective view of a low temperature air introduction assembly according to the present invention;
FIG. 7 is a schematic structural view of the low temperature air introduction assembly of the present invention after disassembly;
FIG. 8 is a schematic perspective view of a permanent magnet holder according to the present invention;
FIG. 9 is a schematic view of the air circulation assembly of the present invention;
FIG. 10 is a diagram illustrating a split structure of a highly self-debugging component according to the present invention.
In the figure:
1-an outer protective component; 101-outer sealed box; 102-an inner sealed box; 2-a height self-debugging component; 201-sunshade seat; 202-rain filter plate; 203-a push-down transfer shaft; 204-lifting type conversion shaft; 205-concave profile tooth surface groove; 206-a conversion gear; 207-supporting type telescopic outer cylinder; 208-a steel hoop; 3-an air flow circulation assembly; 301-a piston cartridge; 302-high temperature air outlet piston seat; 303-a threaded cylinder; 304-a threaded rod; 305-driven bevel gear; 306-a cryogenic air induction piston seat; 307-drive bevel gear; 308-a drive shaft; 4-a power conversion assembly; 401-lower layer wind plate; 402-upper wind plate; 403-driven gear; 404-linkage gear; 405-a drive gear; 406-a fan blade; 5-high temperature air leading-out component; 501-leading out valve pipe of bottom layer high temperature air; 502-high temperature air outlet valve tube; 503-spray head; 6-a low temperature air intake assembly; 601-introducing normal temperature air into a valve pipe; 602-cryogenic air intake valve tube; 603-low temperature air outlet valve pipe; 604-a shunt; 605-fan blades; 606-an adapter; 607-winding coil; 608-mesh surface seat; 609-permanent magnet seat; 7-cutting the ferrule; 8-electrolyte filter layer.
Detailed Description
Example (b):
the present invention is described in further detail below with reference to figures 1-10.
Referring to fig. 1-10, the present invention provides a technical solution: anticreep structure for distribution convenient to quick installation, including outer protective assembly 1
The top of the inner side of the outer protection component 1 is fixedly connected with an air flow circulation component 3, the air flow circulation component 3 is used for introducing low-temperature air into the outer protection component 1, and the surface of the air flow circulation component 3 is respectively communicated with a high-temperature air outlet component 5 and a low-temperature air inlet component 6;
low temperature air introduces subassembly 6 includes normal atmospheric temperature air introduction valve pipe 601, normal atmospheric temperature air introduction valve pipe 601 joint is on the surface of shower nozzle 503, normal atmospheric temperature air introduction valve pipe 601's port is located the coolant liquid circulation intracavity, position department that corresponds low temperature air introduction piston seat 306 on the end face of piston sleeve box 301 side is through low temperature air introduction valve pipe 602 and coolant liquid circulation chamber intercommunication, the port department of low temperature air introduction valve pipe 602 and normal atmospheric temperature air introduction valve pipe 601 all is provided with the gas-liquid separation membrane.
As shown in fig. 10, the outer shield assembly 1 includes an outer sealed box 101 and an inner sealed box 102, the inner sealed box 102 is embedded inside the outer sealed box 101, and a sealed cooling liquid circulation chamber is formed between the outer sealed box 101 and the inner sealed box 102.
In this embodiment: sunshade seat 201 still possesses the collection function of rainwater when having thermal-insulated effect to external protection component 1, and the rainwater after rainwater filter 202 filtration is handled is gathered in sunshade seat 201's inside, and along with the gathering of rainwater, sunshade seat 201's whole weight risees gradually and produces the trend of descending, and sunshade seat 201 is down when taking place to retract the action in the inside of the flexible urceolus 207 of supporting formula.
As shown in fig. 2, a height self-adjusting assembly 2 is arranged on the periphery of the outer sealing box 101, the height self-adjusting assembly 2 includes a sunshade seat 201, the sunshade seat 201 is located above the outer sealing box 101, a rainwater filtering plate 202 is embedded into a port of the sunshade seat 201, a downward-pressing type converting shaft 203 is fixedly connected to four corners of the bottom of the sunshade seat 201, an upward-lifting type converting shaft 204 is slidably connected to the surface of the downward-pressing type converting shaft 203, and a steel hoop 208 clamped at the top of the outer sealing box 101 is sleeved on the surfaces of the upward-lifting type converting shaft 204 and the downward-pressing type converting shaft 203.
As shown in fig. 2, the same supporting telescopic outer cylinder 207 is sleeved on the surfaces of the lifting type conversion shaft 204 and the pressing type conversion shaft 203, concave-shaped tooth grooves 205 are formed between the pressing type conversion shaft 203 and the lifting type conversion shaft 204 at positions corresponding to the supporting telescopic outer cylinder 207, the same conversion gear 206 is linked between the two concave-shaped tooth grooves 205, and the conversion gear 206 is rotatably connected to the inner side wall of the supporting telescopic outer cylinder 207.
In this embodiment: utilize conversion gear 206 to turn into ascending thrust with decurrent thrust and promote outer protection component 1 through last formula conversion shaft 204 and go upward, through promoting the height of outer protection component 1 for ground, and then when can prevent that ground from taking place ponding, receive the influence of water pressure and liquid flow power and deepen the inside of outer protection component 1 and initiate high risk coefficient accident such as electric leakage.
As shown in fig. 4, the air flow circulation assembly 3 includes a piston sleeve 301, the top of the piston sleeve 301 is fixedly connected to the top of the inner side of the inner sealed box 102, a high temperature air outlet piston seat 302 and a low temperature air inlet piston seat 306 are respectively sleeved inside the piston sleeve 301, a threaded rod 304 is fixedly connected to each of the opposite surfaces of the low temperature air inlet piston seat 306 and the high temperature air outlet piston seat 302, the same threaded cylinder 303 is threadedly connected to the surface of the threaded rod 304, the threaded cylinder 303 is rotatably connected to the inner side wall of the piston sleeve 301, and a driven bevel gear 305 is fixedly connected to the surface of the threaded cylinder 303.
In this embodiment: when one of the fan blades 406 is firstly subjected to the action of air flow and rotates, the generated torque can be transferred to the driving shaft 308 through the linkage gear 404 and the driven gear 403, and the driving bevel gear 307 is driven to rotate through the driving shaft 308, so that the windward side of the rest of the fan blades 406 can be automatically controlled, the number of the fan blades 406 is set to be a plurality, the initial stress angles of the fan blades 406 are different, the special capability of the fan blades 406 for automatically adjusting the stress angles is utilized, the requirement of the fan blades 406 on wind power is reduced, low wind pressure starting is realized, automatic starting can be realized, the fan blades 406 can work with wind, and the operation efficiency is higher.
As shown in fig. 4, the air circulation assembly 3 further includes a driven bevel gear 305, a driving bevel gear 307 is engaged with a surface of the driven bevel gear 305, the driving bevel gear 307 is fixedly connected to a bottom end of the driving shaft 308, the driving bevel gear 307 is respectively rotatably connected to tops of the inner seal box 102 and the outer seal box 101, a power conversion assembly 4 is further rotatably connected to a surface of the driving shaft 308, the power conversion assembly 4 includes a lower wind plate 401 and an upper wind plate 402, the lower wind plate 401 and the upper wind plate 402 are both rotatably connected to a surface of the driving shaft 308, and a bottom of the lower wind plate 401 is fixedly connected to a top of the outer seal box 101.
In this embodiment: in the process of driving the driving bevel gear 307 to rotate, the driving shaft 308 utilizes the linkage effect between the driving bevel gear 307 and the two driven bevel gears 305 to apply torque forces to the two threaded cylinders 303, so that the low-temperature air introducing piston seat 306 and the high-temperature air discharging piston seat 302 can perform corresponding piston motions under the combined effect of the torque forces and the thread engagement forces.
As shown in fig. 4, the top of the upper layer wind disk 402 is rotatably connected with a driven gear 403, a linkage gear 404 and a driving gear 405 respectively, the driven gear 403 is fixedly connected to the surface of the driving shaft 308, a fan blade 406 is further arranged between the lower layer wind disk 401 and the lower layer wind disk 401, and the fan blade 406 is fixedly connected to a rotating shaft connected with the driving gear 405.
In this embodiment: when the low-temperature air introducing piston seat 306 moves to the side close to the spray nozzle 503, the negative pressure drainage effect is utilized, so that the low-temperature air circularly flowing in the cooling liquid circulating cavity can be introduced into the piston sleeve 301 through the low-temperature air introducing valve pipe 602, as the air pressure intensity of the cooling liquid circulating cavity is reduced, the normal-temperature air filtered by the electrolyte filter layer 8 can be introduced through the normal-temperature air introducing valve pipe 601 and the probe, and the low-temperature air can directly act on the fan blade 605 in the process of being introduced into the piston sleeve 301.
As shown in fig. 6, the high-temperature air guiding assembly 5 includes a bottom-layer high-temperature air guiding valve tube 501, one end of the bottom-layer high-temperature air guiding valve tube 501 is located at the bottom of the inner side of the inner seal box 102, the other end of the bottom-layer high-temperature air guiding valve tube 501 is clamped at a position on the side end surface of the piston sleeve 301 corresponding to the high-temperature air guiding piston seat 302, a nozzle 503 is further clamped at a position on the side end surface of the piston sleeve 301 corresponding to the high-temperature air guiding piston seat 302, and the nozzle 503 is clamped at the side end surfaces of the inner seal box 102 and the outer seal box 101, respectively.
In this embodiment: when the low-temperature air introducing piston seat 306 moves to the side close to the spray nozzle 503, the negative pressure drainage effect is utilized, so that the low-temperature air circularly flowing in the cooling liquid circulating cavity can be introduced into the piston sleeve 301 through the low-temperature air introducing valve pipe 602, the normal-temperature air filtered by the electrolyte filter layer 8 can be introduced through the normal-temperature air introducing valve pipe 601 and the probe along with the reduction of the air pressure intensity of the cooling liquid circulating cavity, and the low-temperature air can directly act on the fan blade 605 in the process of being introduced into the piston sleeve 301, and the flowing force of the air can be converted into the torsion and directly acts on the adapter 606 by utilizing the structural particularity of the fan blade 605.
As shown in fig. 6, a fan blade 605 is arranged in the low-temperature air inlet valve pipe 602, the fan blade 605 is fixedly connected to the surface of the adapter cylinder 606, the surface of the adapter cylinder 606 is further rotatably connected to a mesh surface seat 608, the mesh surface seat 608 is clamped on the inner side wall of the low-temperature air inlet valve pipe 602, the surface of the adapter cylinder 606 is wound and connected with a winding coil 607, two permanent magnet seats 609 are clamped at positions on the inner side wall of the low-temperature air inlet valve pipe 602 corresponding to the winding coil 607, the magnetic poles of the opposite surfaces of the two permanent magnet seats 609 are opposite, the front end surface of the piston sleeve 301 corresponding to the position of the low-temperature air inlet piston seat 306 is communicated with the front end surface of the flow divider 604 through the low-temperature air outlet valve pipe 603, and the flow divider 604 is fixedly connected to the bottom of the piston sleeve 301.
As shown in fig. 6, the bottom layer high temperature air outlet valve pipe 501, the high temperature air outlet valve pipe 502, the normal temperature air inlet valve pipe 601, the low temperature air inlet valve pipe 602, and the low temperature air outlet valve pipe 603 are all a combination of a pipeline and a check valve, the side end surface of the outer seal box 101 is clamped with a clamping sleeve 7, and the inside of the clamping sleeve 7 is connected with the electrolyte filter layer 8 in an embedded manner.
In this embodiment: the ionized low-temperature air is scattered in the inner sealing box 102 through the flow dividing body 604, on one hand, the cooling and heat dissipation effects of electronic components inside the inner sealing box 102 are achieved, on the other hand, the ionized air can be used for eliminating static charges on the electronic components, when the high-temperature air piston seat moves towards one side far away from the spray head 503, the high-temperature air is led into the piston box 301 through the bottom high-temperature air leading-out valve pipe 501, and when the high-temperature air piston seat moves towards one side close to the spray head 503, the high-temperature air is sprayed onto the electrolyte filter layer 8 through the spray head 503, on the one hand, the backflushing effect is achieved, dust on the electrolyte filter layer 8 can be removed, on the other hand, residual static charges in the air can be intercepted on the electrolyte filter layer 8 to supplement the static charges, and the air purification effect of the subsequent electrolyte filter layer 8 is guaranteed.
The working principle is as follows: firstly, the sunshade seat 201 has a heat insulation effect on the external protection component 1 and also has a rainwater collection function, rainwater filtered by the rainwater filter plate 202 is collected inside the sunshade seat 201, the whole weight of the sunshade seat 201 gradually increases and a descending trend is generated along with the collection of the rainwater, when the sunshade seat 201 descends inside the supporting telescopic outer barrel 207 to retract, downward thrust is converted into upward thrust by the conversion gear 206 and the external protection component 1 is pushed to ascend by the lifting conversion shaft 204, and by lifting the height of the external protection component 1 relative to the ground, when water accumulation occurs on the ground, high risk coefficient accidents such as electric leakage and the like caused by the influence of water pressure and liquid flow force deepening inside the external protection component 1 can be prevented, so that the safe and normal operation of electrical components in the inner sealing box 102 can be ensured, when one of the blades 406 is subjected to the action of air flow and rotates, the generated torque can be transferred to the driving shaft 308 through the linkage gear 404 and the driven gear 403, and the driving bevel gear 307 is driven to rotate through the driving shaft 308, so that the windward side of the rest blades 406 can be automatically controlled, the number of the blades 406 is set to be a plurality, the initial stress angles of the blades 406 are not equal, the special capability of the blades 406 for automatically adjusting the stress angles is utilized, the requirement of the blades 406 on wind power is reduced, low wind pressure starting is realized, the self-starting can be realized, the operation efficiency is higher, the power coefficient and the power generation efficiency of wind power driving are improved, the output of the total power can be automatically controlled, and the work of introducing low-temperature air and the work of leading out high-temperature air in the inner sealing box 102 can be automatically performed, in the process that the driving shaft 308 drives the driving bevel gear 307 to rotate, the torque force is respectively applied to the two threaded cylinders 303 by using the linkage effect between the driving bevel gear 307 and the two driven bevel gears 305, under the combined effect of the torque force and the thread engagement force, the low-temperature air introducing piston seat 306 and the high-temperature air leading-out piston seat 302 can respectively perform corresponding piston motions by using the same, when the low-temperature air introducing piston seat 306 moves to one side close to the spray head 503, the low-temperature air circularly flowing in the cooling liquid circulating cavity can be introduced into the piston sleeve 301 through the low-temperature air introducing valve pipe 602 by using the negative pressure drainage effect, and as the air pressure intensity of the cooling liquid circulating cavity is reduced, the normal-temperature air filtered by the electrolyte filter layer 8 can be introduced through the normal-temperature air introducing valve pipe 601 and the probe, and the low-temperature air is introduced into the piston sleeve 301, the low-temperature air flows through the adapter tube 606 and is ionized, when the low-temperature air is introduced into the piston seat 306 to move towards the side away from the nozzle 503, the ionized low-temperature air is scattered in the inner sealing box 102 through the flow dividing body 604, on one hand, the cooling and heat dissipation effects on the electronic components inside the inner sealing box 102 are realized, on the other hand, the ionized air can be used for eliminating static charges on the electronic components, when the high-temperature air piston seat moves towards the side away from the nozzle 503, the high-temperature air is introduced into the piston sleeve box 301 through the bottom-layer high-temperature air outlet valve pipe 501, when the high-temperature air piston seat moves towards one side close to the spray head 503, high-temperature air is sprayed on the electrolyte filter layer 8 through the spray head 503, on one hand, a backflushing effect is achieved, dust on the electrolyte filter layer 8 can be removed, on the other hand, residual static charges in the air can be intercepted on the electrolyte filter layer 8 to supplement the static charges, the subsequent air purification effect of the electrolyte filter layer 8 is guaranteed, in the process of introducing low-temperature air, water and gas are separated through the gas-liquid separation membrane, further, water condensation in the inner sealing box 102 when the high-temperature air is in contact with the low-temperature air can be avoided, the sealing performance is high, and the functions of cooling, heat dissipation, water prevention, dust prevention, static electricity prevention and the like of the power distribution cabinet are achieved.
The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications of the present embodiment without inventive contribution as needed after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present invention.
Claims (10)
1. The utility model provides an anticreep structure is used in distribution convenient to quick installation which characterized in that includes:
the air flow circulating assembly (3) is used for introducing low-temperature air into the outer protection assembly (1), and the surface of the air flow circulating assembly (3) is respectively communicated with a high-temperature air leading-out assembly (5) and a low-temperature air leading-in assembly (6);
low temperature air introduces subassembly (6), low temperature air introduces subassembly (6) includes normal atmospheric temperature air introduction valve pipe (601), normal atmospheric temperature air introduction valve pipe (601) joint is on the surface of shower nozzle (503), the port of normal atmospheric temperature air introduction valve pipe (601) is located coolant liquid circulation intracavity, piston sleeve box (301) side end face is gone up the position department that corresponds low temperature air introduction piston seat (306) and is passed through low temperature air introduction valve pipe (602) and coolant liquid circulation chamber intercommunication, the port department of low temperature air introduction valve pipe (602) and normal atmospheric temperature air introduction valve pipe (601) all is provided with the gas-liquid separation membrane.
2. The anti-creeping structure for power distribution convenient to install quickly as claimed in claim 1, wherein the outer protective assembly (1) comprises an outer sealing box (101) and an inner sealing box (102), the inner sealing box (102) is embedded and connected inside the outer sealing box (101), and a sealed cooling liquid circulation cavity is formed between the outer sealing box (101) and the inner sealing box (102).
3. The anti-creeping structure convenient for quick installation for power distribution according to claim 2, wherein a height self-debugging assembly (2) is disposed at the periphery of the outer sealing box (101), the height self-debugging assembly (2) comprises a sunshade seat (201), the sunshade seat (201) is located above the outer sealing box (101), a rainwater filtering plate (202) is embedded into a port of the sunshade seat (201), four corners of the bottom of the sunshade seat (201) are fixedly connected with a downward pressing type converting shaft (203), a surface of the downward pressing type converting shaft (203) is slidably connected with an upward lifting type converting shaft (204), and the surfaces of the upward lifting type converting shaft (204) and the downward pressing type converting shaft (203) are sleeved with a same steel hoop (208) clamped at the top of the outer sealing box (101).
4. The anti-creeping structure convenient for quick installation for power distribution as claimed in claim 1, wherein the same supporting telescopic outer cylinder (207) is sleeved on the surfaces of the lifting type converting shaft (204) and the pressing type converting shaft (203), concave face grooves (205) are formed between the pressing type converting shaft (203) and the lifting type converting shaft (204) at positions corresponding to the supporting telescopic outer cylinder (207), the same converting gear (206) is linked between the two concave face grooves (205), and the converting gear (206) is rotatably connected to the inner side wall of the supporting telescopic outer cylinder (207).
5. The anti-creeping structure for power distribution convenient to install rapidly as claimed in claim 4, wherein the air circulation assembly (3) comprises a piston sleeve (301), the top of the piston sleeve (301) is fixedly connected to the top of the inner side of the inner sealed box (102), the piston sleeve (301) is sleeved with a high temperature air leading-out piston seat (302) and a low temperature air leading-in piston seat (306), the opposite surfaces of the low temperature air leading-out piston seat (306) and the high temperature air leading-out piston seat (302) are fixedly connected with a threaded rod (304), the surface of the threaded rod (304) is screwed with the same threaded cylinder (303), the threaded cylinder (303) is rotatably connected to the inner side wall of the piston sleeve (301), and the surface of the threaded cylinder (303) is further fixedly connected with a driven bevel gear (305).
6. The anti-creeping structure for power distribution, which is convenient to install quickly as claimed in claim 1, the air circulation assembly (3) further comprises a driven bevel gear (305), wherein a driving bevel gear (307) is meshed with the surface of the driven bevel gear (305), the driving bevel gear (307) is fixedly connected to the bottom end of the driving shaft (308), the driving bevel gear (307) is respectively and rotatably connected to the tops of the inner sealing box (102) and the outer sealing box (101), the surface of the driving shaft (308) is also rotationally connected with a power conversion component (4), the power conversion assembly (4) comprises a lower layer wind disk (401) and an upper layer wind disk (402), the lower layer wind plate (401) and the upper layer wind plate (402) are both rotationally connected to the surface of the driving shaft (308), the bottom of the lower layer wind plate (401) is fixedly connected with the top of the outer sealing box (101).
7. The anti-creeping structure for power distribution convenient to mount quickly as claimed in claim 1, wherein the top of the upper wind plate (402) is rotatably connected with a driven gear (403), a linkage gear (404) and a driving gear (405), respectively, the driven gear (403) is fixedly connected to the surface of the driving shaft (308), a wind blade (406) is further disposed between the lower wind plate (401) and the lower wind plate (401), and the wind blade (406) is fixedly connected to a rotating shaft connected with the driving gear (405).
8. The anti-creeping structure for power distribution convenient for quick installation according to claim 1, wherein the high-temperature air leading-out assembly (5) comprises a bottom-layer high-temperature air leading-out valve tube (501), one end of the bottom-layer high-temperature air leading-out valve tube (501) is located at the bottom of the inner side of the inner sealed box (102), the other end of the bottom-layer high-temperature air leading-out valve tube (501) is clamped at a position corresponding to the high-temperature air leading-out piston seat (302) on the side end surface of the piston sleeve box (301), a nozzle (503) is clamped at a position corresponding to the high-temperature air leading-out piston seat (302) on the side end surface of the piston sleeve box (301), and the nozzle (503) is clamped on the side end surfaces of the inner sealed box (102) and the outer sealed box (101), respectively.
9. The anti-creeping structure for power distribution convenient for quick installation according to claim 8, wherein a fan blade (605) is disposed in the low temperature air introducing valve pipe (602), the fan blade (605) is fixedly connected to the surface of the adapter cylinder (606), the surface of the adapter cylinder (606) is further rotatably connected to a mesh surface base (608), the mesh surface base (608) is clamped on the inner side wall of the low temperature air introducing valve pipe (602), the surface of the adapter cylinder (606) is wound and connected with a winding coil (607), and two permanent magnet bases (609) are clamped on the inner side wall of the low temperature air introducing valve pipe (602) at positions corresponding to the winding coil (607), and the magnetic poles of the opposite surfaces of the two permanent magnet bases (609) are opposite, the position of the front side end surface of the piston sleeve box (301) corresponding to the low temperature air introducing piston base (306) is communicated with the front side end of the diverter body (604) through the low temperature air guiding valve pipe (603), the shunt body (604) is fixedly connected to the bottom of the piston sleeve box (301).
10. The anti-creeping structure convenient for quick installation for power distribution of claim 1, wherein the bottom high temperature air outlet valve pipe (501), the high temperature air outlet valve pipe (502), the normal temperature air inlet valve pipe (601), the low temperature air inlet valve pipe (602) and the low temperature air outlet valve pipe (603) are all a combination of a pipeline and a one-way valve, the side end surface of the outer sealing box (101) is clamped with a clamping sleeve (7), and the clamping sleeve (7) is embedded and connected with the electrolyte filter layer (8).
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| Application Number | Priority Date | Filing Date | Title |
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| CN202110950524.7A CN113690769B (en) | 2021-08-18 | 2021-08-18 | Anti-creeping structure for power distribution convenient to install fast |
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202110950524.7A CN113690769B (en) | 2021-08-18 | 2021-08-18 | Anti-creeping structure for power distribution convenient to install fast |
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| CN113690769B CN113690769B (en) | 2023-11-28 |
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| CN114526526A (en) * | 2022-04-22 | 2022-05-24 | 山东中泰医疗器械有限公司 | Multifunctional medical air purification equipment |
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| CN113690769B (en) | 2023-11-28 |
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