CN116689401B - High-efficient wind shower - Google Patents

Abstract

The invention relates to the field of cleaning equipment, and particularly discloses a high-efficiency air shower, which comprises the following components: the air shower mechanism is arranged in the driving mechanism, the driving mechanism comprises a driving component arranged in the air shower mechanism, a separation component is connected to the driving component in a meshed manner, the separation component comprises a rotating disc rotatably connected in the air shower mechanism, and a plurality of separation plates are arranged at the top end of the rotating disc; according to the efficient air shower provided by the invention, a plurality of workers are separated through the separation plate, the two sliding assemblies slightly separate the feet of the workers, the driving assembly drives the separation assembly to rotate in the air shower mechanism, then the workers rotate and spin while being matched with the tooth missing piece through the rotating assembly, the rotating assembly drives the lifting assembly to gradually rise, the two sliding assemblies are driven to gradually separate the feet of the workers, and therefore, the workers can obtain more comprehensive air shower.

Description

High-efficient wind shower

Technical Field

The invention relates to the technical field of cleaning equipment, in particular to a high-efficiency air shower.

Background

The air shower is a local purifying device with strong universality, and the principle is that strong clean air is sprayed onto a human body through a nozzle, so that impurities such as dust, bacteria and the like attached to clothes or goods are effectively removed, and the pollution problem caused by the fact that workers enter and exit a clean room is reduced.

The air shower capable of storing filtered gas disclosed in the Chinese patent application publication No. CN108144921B solves the technical problems that a multistage filter reduces the flow rate when a nozzle sprays, and the service life of the filter is prolonged when the wind power is increased, but the structural design of the prior art is as follows:

in the use of air shower, although can drive the staff and carry out three hundred sixty degrees rotations, when many people use simultaneously, can lead to shielding each other between many staff, and general station is comparatively random when the staff drenches by the wind, can not guarantee the divided angle of both legs to also can lead to the both legs to shelter from each other, and then easily cause the wind of many places to drench the dead angle, make the staff drench thoroughly inadequately by the wind, thereby can lead to the dust to adhere to and be carried into clean room on staff's clothes.

We have therefore proposed a highly efficient air shower in order to solve the problems set out above.

Disclosure of Invention

The invention provides a high-efficiency air shower, which aims to solve the problems that the separation angle of two legs is smaller and air shower dead angles exist for multiple people to perform air shower simultaneously in the related technology.

The invention relates to a high-efficiency air shower, which comprises the following components:

the air shower mechanism is used for performing air shower on workers;

the driving mechanism is arranged in the air shower mechanism so as to drive workers to move, the driving mechanism comprises a driving component arranged in the air shower mechanism, a separation component is connected to the driving component in a meshed mode, the separation component comprises a rotating disc rotatably connected in the air shower mechanism, a toothed ring is arranged at the bottom end of the rotating disc, the toothed ring is connected with the driving component in a meshed mode, the driving component can drive the rotating disc to rotate through the toothed ring, and a plurality of separation plates are arranged at the top end of the rotating disc;

the supporting mechanism is arranged on the driving mechanism so as to support workers, the supporting mechanism comprises a plurality of supporting components which are rotationally connected to the separation component, a plurality of supporting components are arranged in the supporting components, the rotating components can drive the workers to rotate, a plurality of tooth missing pieces are arranged between the rotating components so as to enable the rotating components to rotate, two sliding components are slidingly connected to the rotating components, a space is reserved between the two sliding components so that the feet of the workers are separated, two elastic pieces are connected between the sliding components, two first wedge blocks are respectively arranged on the sliding components, lifting components are arranged at the bottoms of the sliding components, the lifting components are in threaded connection with the separation component, and the lifting components are driven to rotate through the supporting components when the rotating components rotate, so that the lifting components gradually rise and are mutually far away through the two first wedge blocks.

Preferably, the support assembly comprises a rotating cylinder rotatably connected to the separation assembly, two first elastic pieces are mounted on the rotating cylinder, the first elastic pieces are connected to the rotating assembly, a fixing ring is mounted on the outer side of the rotating cylinder, and two handrails are arranged on the fixing ring.

Preferably, the rotating assembly comprises a rotating plate which is connected in the supporting assembly in a sliding mode, two connecting pieces are arranged at the bottom end of the rotating plate, a third gear is arranged on the outer side of each connecting piece, two sliding grooves are formed in the rotating plate and used for enabling the sliding assembly to slide, two grooves are formed in the sliding grooves, and inclined planes are formed in two sides of the inner wall of each groove.

Preferably, the sliding assembly comprises a plurality of supporting bars arranged on the rotating assembly, two sliding bars are arranged at the bottoms of the supporting bars, the sliding bars are in sliding connection with the sliding grooves, sliding sleeves are in sliding connection with the outer sides of the sliding bars, and the sliding sleeves are mutually fixed.

Preferably, the lifting assembly comprises a lifting plate arranged in the rotating cylinder, two second wedges are arranged on the lifting plate, the first wedges are arranged above the second wedges, one end of the lifting plate is provided with a threaded portion, and the threaded portion is in threaded connection with the separation assembly.

Preferably, the driving assembly comprises a driving source, a first gear is arranged on the driving source, one side of the first gear is connected with a second gear in a meshed mode, and the second gear is connected with the toothed ring in a meshed mode.

Preferably, the air shower mechanism comprises a protection component arranged on the outer side of the partition plate, a supporting seat is arranged at the bottom of the protection component, a cover plate is arranged at the top of the protection component, and a dust collection component which is communicated with the bottom of the cover plate is arranged at the bottom of the cover plate.

Preferably, enclose between protective component, apron, dust absorption subassembly, rolling disc and a plurality of the division board and be had a plurality of wind to drench the chamber, protective component's inner wall one side is provided with the wind and drenches the subassembly, the wind drenches the subassembly and including installing a plurality of air supply board in protective component inner wall, a plurality of all install a plurality of wind on the air supply board and drenches the mouth, protective component's opposite side is provided with a plurality of disinfection lamp.

Preferably, the outside of connecting piece is equipped with the extrusion subassembly, the extrusion subassembly is including rotating the swivel becket of connecting on the connecting piece, install the connecting plate on the swivel becket, the briquetting is installed at one side top of connecting plate, lower layering is installed to one side bottom of connecting plate.

Preferably, a plurality of control assemblies are arranged below the inner wall of the protection assembly, and the plurality of control assemblies respectively control the opening or closing of the plurality of air supply plates.

By adopting the technical scheme, the invention has the beneficial effects that: the staff gets into behind the wind and drenches the mechanism stand on separating the subassembly, separate many staff through a plurality of division board this moment, avoid sheltering from each other, then the staff stands and makes both feet slightly separate on two slip subassemblies, this moment under the effect of gravity, the rotating assembly moves down and lacks tooth meshing, drive assembly drives the subassembly simultaneously and drenches the mechanism in the wind and rotate, the cooperation of rethread rotating assembly and lacks tooth makes the subassembly that slides in separating the subassembly autorotation, thereby make the staff rotate and the rotation, the rotatory in-process of rotating assembly drives lifting unit and rises gradually in separating the subassembly, two first voussoirs drive two respectively and slide the subassembly and keep away from gradually this moment, make the both legs of staff separate gradually, thereby make the staff can obtain more comprehensive wind to drench the dead angle, avoid producing wind and drenche the dead angle, the wind to the staff drenches the effect has been improved.

Drawings

Fig. 1 is a schematic overall structure of a first embodiment of the present invention.

Fig. 2 is a schematic structural view of a driving mechanism according to a first embodiment of the present invention.

Fig. 3 is a schematic structural diagram of a driving assembly according to a first embodiment of the present invention.

Fig. 4 is a schematic structural view of a supporting mechanism according to a first embodiment of the present invention.

Fig. 5 is a schematic structural diagram of a sliding assembly according to a first embodiment of the present invention.

Fig. 6 is an exploded view of a support assembly according to a first embodiment of the present invention.

Fig. 7 is an exploded view of a rotary assembly according to a first embodiment of the present invention.

Fig. 8 is a schematic structural view of a rotating plate according to a first embodiment of the present invention.

Fig. 9 is a schematic structural diagram of a lifting assembly according to a first embodiment of the present invention.

Fig. 10 is a schematic structural view of a partition assembly according to a first embodiment of the present invention.

Fig. 11 is a schematic structural view of a rotary disk according to a first embodiment of the present invention.

Fig. 12 is a schematic structural view of a driving source according to a first embodiment of the present invention.

Fig. 13 is a schematic structural view of a protection component according to a first embodiment of the present invention.

Fig. 14 is a schematic structural view of an air shower chamber according to a first embodiment of the present invention.

Fig. 15 is a schematic structural view of a shower assembly according to a first embodiment of the present invention.

Fig. 16 is a schematic structural view of a sterilizing lamp according to a first embodiment of the present invention.

Fig. 17 is a schematic view showing the structure of an air supply plate according to the first embodiment of the present invention.

Fig. 18 is a schematic view showing a partial sectional structure of a mounting barrel according to a first embodiment of the present invention.

Fig. 19 is a schematic structural view of a pressing assembly according to a second embodiment of the present invention.

Fig. 20 is a schematic structural view of a connection board according to a second embodiment of the present invention.

Fig. 21 is a schematic structural view of a control assembly according to a second embodiment of the present invention.

Fig. 22 is an enlarged schematic view of the structure at a in fig. 21 according to the second embodiment of the present invention.

Reference numerals:

10. a wind shower mechanism; 11. a protective assembly; 111. a protective shell; 112. an access opening; 113. a step; 12. a support base; 13. a cover plate; 14. a dust collection assembly; 141. a mounting cylinder; 142. an air suction hole; 15. an air shower assembly; 151. a wind supply plate; 152. a wind shower nozzle; 16. a sterilizing lamp; 17. a control assembly; 171. starting a switch; 172. closing the switch; 18. a wind shower cavity;

20. a driving mechanism; 21. a drive assembly; 211. a driving source; 212. a first gear; 213. a second gear; 214. a rotating shaft; 22. a partition assembly; 221. a rotating disc; 222. a toothed ring; 223. a partition plate; 224. a mounting hole; 225. a thread groove; 226. a communication groove; 227. a limit groove;

30. a support mechanism; 31. a support assembly; 311. a rotating cylinder; 312. a first elastic member; 313. a fixing ring; 314. an armrest; 32. a rotating assembly; 321. a rotating plate; 322. a connecting piece; 323. a third gear; 324. a chute; 325. a groove; 326. a lifting groove; 327. a first vent hole; 33. a slip assembly; 331. a support bar; 332. a second vent hole; 333. a slide bar; 334. a sliding sleeve; 34. a second elastic member; 35. a first wedge; 36. a lifting assembly; 361. a lifting plate; 362. a second wedge; 363. a threaded portion; 37. tooth-missing pieces; 38. an extrusion assembly; 381. a rotating ring; 382. a connecting plate; 383. pressing into blocks; 384. and (5) a lower pressing bar.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings. The embodiments described below by referring to the drawings are illustrative and intended to explain the present invention and should not be construed as limiting the invention.

As shown in fig. 1 to 18, the efficient air shower of the invention comprises an air shower mechanism 10 for performing air shower on a worker, wherein a driving mechanism 20 is arranged in the air shower mechanism 10 for driving the worker to move, a supporting mechanism 30 is arranged on the driving mechanism 20 for supporting the worker, the worker stands on the driving mechanism 20 after entering the air shower mechanism 10 and then stands on the supporting mechanism 30, the driving mechanism 20 drives the supporting mechanism 30 to rotate for driving the worker to move, and the air shower mechanism 10 performs air shower on the worker in the moving process.

As shown in fig. 1 to 3, the driving mechanism 20 includes a driving component 21 disposed in the air shower mechanism 10, and a separation component 22 is engaged and connected to the driving component 21, so that a plurality of workers can be separated independently, and the workers can be prevented from standing together to shield each other in the air shower process, so that the air shower effect on the bodies of the workers is improved, and the driving component 21 drives the separation component 22 to rotate, and can drive the workers separated by the separation component 22 to rotate.

As shown in fig. 2 to 5, the supporting mechanism 30 includes a plurality of supporting components 31 rotatably connected to the partition component 22, rotating components 32 are disposed in the plurality of supporting components 31, the rotating components 32 can drive a worker to rotate, a tooth missing piece 37 is disposed between the plurality of rotating components 32, in this embodiment, the tooth missing piece 37 is a tooth missing gear, two sliding components 33 are slidably connected to the rotating components 32, a space is reserved between the two sliding components 33, the two feet of the worker can be positioned through the two sliding components 33, and the two legs of the worker can be slightly separated when the worker stands at first due to the space between the two sliding components 33.

As shown in fig. 2 to 5, a second elastic member 34 is connected between the two sliding components 33 to drive the two sliding components 33 to reset, in this embodiment, the second elastic member 34 is a spring, in other embodiments, the second elastic member 34 is a tension spring, the initial state of the second elastic member 34 is a tensile state, the two sliding components 33 are provided with a first wedge 35, the initial states of the two first wedges 35 are respectively contacted with the two sliding components 33, the bottoms of the two sliding components 33 are provided with a lifting component 36, the lifting component 36 is in threaded connection with the separating component 22, and when a worker stands on the rotating component 32, the rotating component 32 slides downwards in the supporting component 31, so that the lifting component 36 is contacted with the first wedge 35.

The partition assembly 22 drives the rotating assembly 32 to synchronously rotate when rotating, after the rotating assembly 32 contacts with the tooth missing piece 37, the rotating assembly 32 rotates through the tooth missing piece 37, the rotating assembly 32 can also drive the supporting assembly 31 to rotate in the partition assembly 22 in the rotating process, so that a worker can rotate by three hundred sixty degrees, the lifting assembly 36 is driven to rotate in the rotating process of the supporting assembly 31, the lifting assembly 36 is in threaded connection with the partition assembly 22, the lifting assembly 36 is gradually lifted and pushes the two first wedges 35 to be mutually far away, the second elastic piece 34 is stretched again, feet of the worker can be gradually separated, the legs of the worker are driven to be gradually diverged, and the situation that wind cannot blow the crotch due to too close of the legs of the worker when the worker stands is avoided.

As shown in fig. 3 and 6, the supporting component 31 includes a rotating cylinder 311 rotatably connected to the separating component 22, in this embodiment, the rotating cylinder 311 is T-shaped, the first elastic members 312 are installed on two sides of the inner bottom wall of the rotating cylinder 311, in this embodiment, the first elastic members 312 are springs, in other embodiments, the first elastic members 312 are elastic plates, the top ends of the first elastic members 312 are connected to the rotating component 32, a fixing ring 313 is installed on the outer side of the top end of the rotating cylinder 311, and two symmetrically arranged armrests 314 are installed on the top end of the fixing ring 313, so that a worker holds the armrests 314 when showering with wind, stability of the worker when rotating is ensured, and movable grooves for the lifting component 36 to pass through are formed on two sides of the rotating cylinder 311.

As shown in fig. 4 and 7, the rotating assembly 32 includes a rotating plate 321 slidably connected in a rotating cylinder 311, a bottom end of the rotating plate 321 is mounted on a top end of a first elastic member 312, the rotating cylinder 311 and the rotating plate 321 are located on the same axis, when a worker stands on the rotating plate 321, the rotating plate 321 is pressed to move downward under the action of gravity and compress the first elastic member 312, connecting members 322 are mounted on two sides of the bottom end of the rotating plate 321, the first elastic member 312 is sleeved on the outer side of the connecting members 322, in this embodiment, the connecting members 322 are arc-shaped plates, in other embodiments, the connecting members 322 are connecting rods, two grooves for sliding the connecting members 322 are formed at the bottom ends of the rotating cylinder 311, and a third gear 323 is mounted on the outer sides of the bottom ends of the two connecting members 322.

When the rotating plate 321 moves downwards, the connecting piece 322 moves downwards along with the rotating plate 321 to enable the tooth missing piece 37 to be meshed with the third gear 323, and when the third gear 323 is meshed with teeth on the tooth missing piece 37, the third gear 323 can be driven to rotate through the tooth missing piece 37, so that the rotating cylinder 311 and the rotating plate 321 are driven to rotate synchronously.

As shown in fig. 5 and 8, the two sides of the top end of the rotating plate 321 are provided with sliding grooves 324 for the sliding assembly 33 to slide, two symmetrically arranged grooves 325 are provided on the inner bottom wall of the sliding grooves 324, two sides of the inner wall of the grooves 325 are provided with inclined planes, one side of the top end of the rotating plate 321, which is close to the sliding grooves 324, is provided with a lifting groove 326, the top of the rotating plate 321 is provided with a plurality of uniformly distributed first ventilation holes 327, and a plurality of first ventilation holes 327 are arranged between the two sliding grooves 324 to enable wind to circulate through the first ventilation holes 327.

As shown in fig. 4 and 5, the sliding component 33 includes a plurality of support bars 331 disposed at the top end of the rotating plate 321, and a space is provided between the support bars 331 and the top end of the rotating plate 321, so as to avoid the support bars 331 covering the first ventilation holes 327 on the rotating plate 321, the plurality of support bars 331 are in contact with each other, the top of the support bars 331 is provided with a plurality of second ventilation holes 332, and the plurality of second ventilation holes 332 are uniformly distributed along the length direction of the support bars 331, so that wind can circulate on the soles of the staff.

As shown in fig. 5 and 8, the bottom two sides of the plurality of support bars 331 are respectively provided with a slide bar 333, the bottom of the slide bar 333 is slidably connected with the inner bottom wall of the chute 324, the outer side of the slide bar 333 is slidably connected with a slide sleeve 334, the slide sleeve 334 is slidably connected with the chute 324, the plurality of slide sleeves 334 are mutually fixed, the plurality of support bars 331 can slide transversely simultaneously, and meanwhile, when the slide bar 333 enters the groove 325, one support bar 331 can slide longitudinally independently, so that the plurality of support bars 331 can fall alternately, wind can pass through between the two support bars 331, the sole is prevented from being shielded by the support bars 331, and more comprehensive wind showering is facilitated to the sole.

As shown in fig. 4, 5, 8 and 9, the lifting assembly 36 includes a lifting plate 361 disposed inside the rotating cylinder 311, the second wedges 362 are mounted at the middle parts of two sides of the lifting plate 361, the first wedges 35 are disposed above the second wedges 362, the lifting groove 326 is matched with the second wedges 362, so that the second wedges 362 can slide up and down in the lifting groove 326, a threaded portion 363 is disposed at one end of the lifting plate 361, the threaded portion 363 on the lifting plate 361 is in threaded connection with the partition assembly 22, and two ends of the lifting plate 361 slide in two movable grooves on two sides of the rotating cylinder 311 respectively, so that the lifting plate 361 can move up and down.

The threaded portion 363 on the lifting plate 361 is in threaded connection with the separation assembly 22, and can drive the lifting plate 361 to gradually rise in the process of rotating the rotating cylinder 311, at this time, the lifting plate 361 drives the two second wedges 362 to gradually rise and respectively prop against the two first wedges 35, so that the two first wedges 35 are far away from each other, and simultaneously the two first wedges 35 respectively push the plurality of support bars 331 in the two sliding assemblies 33 to be far away from each other, so that the feet of a worker are gradually separated.

As shown in fig. 3 and 10, the separation assembly 22 includes a rotating disc 221 rotatably connected in the shower mechanism 10, a toothed ring 222 is installed at the bottom end of the rotating disc 221, the toothed ring 222 is engaged with the driving assembly 21, the driving assembly 21 can drive the rotating disc 221 to rotate through the toothed ring 222, the top end of the rotating disc 221 is provided with a plurality of separation plates 223, in this embodiment, the number of the separation plates 223 can be two, three, four or more, the plurality of separation plates 223 are installed at the top end of the rotating disc 221 in an annular array, and a plurality of staff can be separated through the plurality of separation plates 223, so as to avoid mutual shielding.

As shown in fig. 5, 6 and 9 to 11, a plurality of mounting holes 224 distributed in an annular array are formed at the top end of the rotating plate 221, one mounting hole 224 is located between every two adjacent partition plates 223, a threaded groove 225 is formed on the inner wall of the mounting hole 224, a threaded portion 363 on the lifting plate 361 is in threaded connection with the threaded groove 225, a longitudinal communicating groove 226 is formed between the starting end of the threaded groove 225 and the tail end of the threaded groove 225, so that when the threaded portion 363 on the lifting plate 361 moves to the tail end of the threaded groove 225, the lifting plate 361 can be enabled to fall along the communicating groove 226 on the threaded groove 225, the lifting plate 361 is reset, the rotating cylinder 311 is rotationally connected in the mounting hole 224, and the top end of the rotating cylinder 311 and the top end of the rotating plate 221 are located on the same plane.

When the rotating cylinder 311 rotates in the mounting hole 224, the rotating cylinder 311 drives the lifting plate 361 to rotate in the threaded groove 225, so that the lifting plate 361 is driven to ascend, when the rotating cylinder 311 stops rotating, the worker finishes air shower, and at the moment, the second elastic piece 34 resets and pulls the two first wedges 35 to approach each other, so that the supporting bar 331 is driven to reset, and meanwhile, the lifting plate 361 falls along the communicating groove 226 on the threaded groove 225.

As shown in fig. 3, 10 and 12, the driving assembly 21 includes a driving source 211, in this embodiment, the driving source 211 is a servo motor with a brake, a first gear 212 is installed at the bottom end of the driving source 211 through an output shaft, a second gear 213 is connected to one side of the first gear 212 in a meshed manner, in this embodiment, the diameter of the second gear 213 is larger than that of the first gear 212, the second gear 213 is connected to a toothed ring 222 in a meshed manner, the second gear 213 is disposed below the tooth missing piece 37, the second gear 213 is disposed inside the toothed ring 222, a rotating shaft 214 is installed in the middle of the second gear 213, the driving source 211 drives the first gear 212 to rotate through the output shaft thereon, at this time, the first gear 212 drives a rotating disc 221 on the toothed ring 222 to rotate through the second gear 213, and the rotating disc 221 drives a plurality of separating plates 223 to rotate.

As shown in fig. 12 to 16, the air shower mechanism 10 includes a protection component 11 disposed outside a partition plate 223, a supporting seat 12 is installed at the bottom of the protection component 11, in this embodiment, a cavity is formed at the top of the supporting seat 12, the bottom end of a rotating shaft 214 in a second gear 213 is rotatably connected to the inner bottom wall of the supporting seat 12, a cover plate 13 is installed at the top of the protection component 11, a dust collection component 14 which is communicated with the bottom of the cover plate 13 is installed, a plurality of air shower cavities 18 are enclosed between the protection component 11, the cover plate 13, the dust collection component 14, a rotating disc 221 and a plurality of partition plates 223, an air shower component 15 is disposed at one side of the inner wall of the protection component 11, a plurality of sterilizing lamps 16 are disposed at the other side of the protection component 11 to sterilize the used air shower cavities 18, in this embodiment, the sterilizing lamps 16 are ultraviolet sterilizing lamps, and the rotating disc 221 are rotatably connected to the inside of the protection component 11.

As shown in fig. 14 to 16, the protection component 11 includes a protection shell 111 installed at the top of the support base 12, the protection shell 111 is communicated with a cavity on the support base 12, the top of the protection shell 111 is installed at the bottom of the cover plate 13, the two sides of the protection shell 111 are both provided with an access port 112 for the entrance and exit of a worker, the two sides of the protection shell 111 are both provided with steps 113 near the bottom of the access port 112, the bottom of the steps 113 and the bottom of the support base 12 are located on the same plane, so that the worker steps on the steps 113 to enter the access port 112, the two sides of the inner wall of the protection shell 111 are respectively provided with grooves for installing the air shower component 15 and a plurality of disinfection lamps 16, and a plurality of separation plates 223 are both slidingly connected on the inner wall of the protection shell 111 and are hermetically arranged through sealing gaskets.

As shown in fig. 14, 15 and 17, the air shower assembly 15 includes a plurality of air supply plates 151 installed in an inner wall of the protective housing 111, the plurality of air supply plates 151 are in an arc array around an axis of the rotating disc 221, a plurality of air shower nozzles 152 are installed on the plurality of air supply plates 151, the plurality of air shower nozzles 152 are arranged at equal intervals along a length direction of the air supply plates 151, the air shower nozzles 152 are embedded and installed on the inner wall of the protective housing 111 and do not extend out of the inner wall of the protective housing 111, damage to the air shower nozzles 152 caused by rotation of the partition plates 223 is avoided, and an included angle range of every two adjacent partition plates 223 can cover the plurality of air shower nozzles 152, so that workers can be subjected to air shower of all the air shower nozzles 152 simultaneously.

As shown in fig. 3, 13 and 18, the dust collection assembly 14 includes a mounting cylinder 141 mounted at the bottom of the cover plate 13, a dust exhaust hole communicated with the mounting cylinder 141 is provided at the top end of the cover plate 13, the dust exhaust hole on the cover plate 13 is connected with an external exhaust fan, the driving source 211 is mounted on the inner wall of the mounting cylinder 141, an output shaft on the driving source 211 penetrates through the bottom end of the mounting cylinder 141 and extends into the supporting seat 12, the tooth-missing piece 37 is mounted at the outer side of the bottom end of the mounting cylinder 141, a plurality of air exhaust holes 142 are provided on the outer circumferential surface of the mounting cylinder 141, the plurality of air exhaust holes 142 are distributed in an arc shape along the axis of the mounting cylinder 141, the plurality of air exhaust holes 142 are arranged near the top end of the rotating disc 221, the plurality of air exhaust holes 142 correspond to the plurality of air exhaust nozzles 152, the external exhaust fan is used for exhausting air into the mounting cylinder 141 at this time, and the mounting cylinder 141 is used for exhausting air into the air exhaust cavity 18, and the air nozzles 152 are used for blowing air towards the air exhaust holes 142, thereby accelerating the flow speed in the air cavity 18, and simultaneously taking away dust in the air cavity 18, and facilitating dust handling.

When the hand-held air shower device is used, the driving source 211 is started, at the moment, the driving source 211 drives the first gear 212 to rotate through the driving shaft on the hand-held air shower device, meanwhile, the first gear 212 drives the second gear 213 to rotate, so that the rotating disc 221 on the toothed ring 222 is driven to rotate, at the moment, the rotating cylinder 311 and the rotating plate 321 rotate along with the rotating disc 221, when a worker needs to shower air, the worker passes through the inlet and outlet 112 to enter the air shower cavity 18, stands feet on the supporting bars 331, and then holds the hands on the handrails 314.

When a worker stands on the supporting bar 331, the rotating plate 321 moves downwards in the rotating cylinder 311 under the action of gravity, the first elastic piece 312 is compressed, meanwhile, the first wedge 35 on the supporting bar 331 is contacted with the second wedge 362 on the lifting plate 361, the rotating plate 321 drives the third gear 323 to move downwards through the connecting piece 322, when the third gear 323 is meshed with teeth on the tooth lack piece 37, the air shower cavity 18 enters the air shower range of the air shower nozzle 152, meanwhile, under the action of the rotating disc 221, the third gear 323 can rotate on the tooth lack piece 37 for one circle, and in the rotating process of the third gear 323, the third gear 323 drives the rotating cylinder 311 and the rotating plate 321 to rotate through the connecting piece 322, so that the worker is driven to rotate, and the worker can perform three hundred sixty degrees of air shower.

In the process of rotating the rotating cylinder 311, the rotating cylinder 311 drives the threaded portion 363 on the lifting plate 361 to rotate in the threaded groove 225, at this time, the lifting plate 361 gradually rises and pushes the two first wedges 35 to move away from each other through the second wedges 362, so that the plurality of support bars 331 in the two sliding assemblies 33 are driven to move away from each other, in the process of moving the plurality of support bars 331, the sliding bar 333 on the support bars 331 slides in the interior of the sliding groove 324, when the sliding bar 333 enters the groove 325 of the sliding groove 324, one of the support bars 331 moves down, so that the sole of a worker can blow the sole through the slit, when the plurality of support bars 331 continue to move, the sliding bar 333 entering the groove 325 is pushed out along the inclined plane in the groove 325, at this time, the next sliding bar 333 enters the groove 325, so that the plurality of support bars 331 can alternately drop down, so that the sole of the foot can be fully winded, when the rotating cylinder 311 rotates once, at this time, the lifting plate 311 rotates once, the sliding bar 333 moves down, and the threaded portion on the lifting plate 361 enters the lifting plate 226 on the threaded groove 225, and the lifting plate 361 is communicated with the groove 361, so that the lifting plate 363 is reset.

In the process that the worker drenches with wind, external air exhauster is to the inside convulsions of mounting cylinder 141, mounting cylinder 141 is through inhaling wind hole 142 to the interior convulsions of wind drenching the chamber 18 this moment, the dust that produces in the wind drenches this moment in the process gets into mounting cylinder 141 through inhaling wind hole 142 and outwards discharges through the dust exhaust hole on the apron 13, after the wind drenches, the staff leaves the wind from another access & exit 112 and drenches chamber 18, first spring resets and promotes the rotor plate 321 and reset this moment, simultaneously rotor plate 321 drives the third gear 323 on the connecting piece 322 and moves up, make rotor plate 321 at initial state, the third gear 323 can't rotate under the effect of lacking tooth piece 37, then rotor plate 221 continues to rotate and drive the wind drenches chamber 18 after the use and remove to sterilamp 16 department, sterilamp 16 disinfects the wind drenches chamber 18 after the use this moment, the convenience is continued to use next time.

To avoid wasting energy by continuing to blow air while the air shower 152 is unmanned, a second embodiment of the present invention is provided to overcome the above-mentioned drawbacks.

As shown in fig. 19 to 22, a second embodiment of the present invention is different from the first embodiment in that: an extrusion component 38 is additionally arranged on the outer side of the connecting piece 322, a limiting groove 227 for the extrusion component 38 to slide up and down is formed in the toothed ring 222, a plurality of control components 17 are arranged below the inner wall of the protective shell 111, the plurality of control components 17 respectively control the opening or closing of the plurality of air supply plates 151, and when the extrusion component 38 moves along with the connecting piece 322, the control components 17 can be extruded, and at the moment, the control components 17 control the air shower nozzle 152 to be opened or closed.

As shown in fig. 19 to 20, the pressing assembly 38 includes a rotary ring 381 rotatably connected to the connection member 322, a connection plate 382 is installed at an outer side of the connection ring, one side of the connection plate 382 extends out of the toothed ring 222 through the limit groove 227, an upper pressing block 383 is installed at a top of one side of the connection plate 382, and a lower pressing bar 384 is installed at a bottom of one side of the connection plate 382, and in this embodiment, a length of the upper pressing block 383 is smaller than a length of the lower pressing bar 384.

When the rotating plate 321 moves downwards, the connecting plate 382 can be driven by the connecting piece 322 to move downwards, so that an upper pressing block 383 and a lower pressing block 384 on the connecting plate 382 can contact the control assembly 17, when the connecting piece 322 rotates around the axis of the rotating plate 221, the connecting piece 322 drives the upper pressing block 383 to contact and extrude the control assembly 17 through the connecting plate 382 on the rotating ring 381, at the moment, the control assembly 17 opens the air supply plate 151 to blow air, then the connecting plate 382 moves continuously to enable the lower pressing block 384 to contact the control assembly 17, and when the lower pressing block 384 breaks away from the control assembly 17, the control assembly 17 controls the air supply plate 151 to be closed, so that the air supply plate 151 can be opened when a worker passes through, and the air supply plate 151 is closed when no worker passes through, so that the waste of energy is avoided.

As shown in fig. 21 to 22, the control assembly 17 includes a start switch 171 mounted on an inner wall of the protective housing 111 to control the air supply plate 151 to be opened, the start switch 171 is disposed below the shower nozzle 152, a close switch 172 is mounted on the inner wall of the protective housing 111 near the lower side of the start switch 171 to control the air supply plate 151 to be closed, when the connecting plate 382 moves, the upper pressing block 383 first contacts with the start switch 171, the start switch 171 controls the air supply plate 151 to be opened, and as the connecting plate 382 continues to move, the lower pressing bar 384 contacts with the close switch 172, and when the lower pressing bar 384 is separated from the close switch 172, the close switch 172 controls the air supply plate 151 to be closed.

In the description of the present invention, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In the description of the present invention, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

While embodiments of the present invention have been shown and described above, it will be understood that the above embodiments are illustrative and not to be construed as limiting the invention, and that variations, modifications, alternatives and variations may be made to the above embodiments by one of ordinary skill in the art within the scope of the invention.

Claims (4)

1. A high efficiency air shower, comprising:

the air shower mechanism is used for performing air shower on workers;

the driving mechanism is arranged in the air shower mechanism so as to drive workers to move, the driving mechanism comprises a driving component arranged in the air shower mechanism, a separation component is connected to the driving component in a meshed mode, the separation component comprises a rotating disc rotatably connected in the air shower mechanism, a toothed ring is arranged at the bottom end of the rotating disc, the toothed ring is connected with the driving component in a meshed mode, the driving component can drive the rotating disc to rotate through the toothed ring, and a plurality of separation plates are arranged at the top end of the rotating disc;

the supporting mechanism is arranged on the driving mechanism to support workers, the supporting mechanism comprises a plurality of supporting components which are rotationally connected to the separation component, a plurality of rotating components are arranged in the supporting components, the rotating components can drive the workers to rotate, tooth missing pieces are arranged between the rotating components so as to enable the rotating components to rotate, two sliding components are connected to the rotating components in a sliding manner, a space is reserved between the two sliding components so that feet of the workers are separated, a second elastic piece is connected between the two sliding components, first wedge blocks are arranged on the two sliding components, lifting components are arranged at the bottoms of the two sliding components and are in threaded connection with the separation component, and the lifting components are driven to rotate through the supporting components when the rotating components rotate, so that the lifting components gradually rise and push the two sliding components to be mutually far away through the two first wedge blocks;

the support assembly comprises a rotating cylinder which is rotatably connected to the separation assembly, two first elastic pieces are arranged on the rotating cylinder, the first elastic pieces are connected to the rotating assembly, a fixed ring is arranged on the outer side of the rotating cylinder, and two handrails are arranged on the fixed ring;

the rotating assembly comprises a rotating plate which is connected in the supporting assembly in a sliding way, two connecting pieces are arranged at the bottom end of the rotating plate, a third gear is arranged on the outer sides of the two connecting pieces, two sliding grooves are formed in the rotating plate for the sliding assembly to slide, two grooves are formed in the sliding grooves, and inclined planes are formed in two sides of the inner wall of each groove;

the sliding assembly comprises a plurality of supporting bars arranged on the rotating assembly, two sliding bars are arranged at the bottoms of the supporting bars, the sliding bars are in sliding connection with the sliding grooves, sliding sleeves are in sliding connection with the outer sides of the sliding bars, and the sliding sleeves are mutually fixed;

the lifting assembly comprises a lifting plate arranged in the rotating cylinder, two second wedges are arranged on the lifting plate, the first wedges are arranged above the second wedges, one end of the lifting plate is provided with a threaded part, and the threaded part is in threaded connection with the separation assembly;

the air shower mechanism comprises a protection assembly arranged on the outer side of the partition plate, a supporting seat is arranged at the bottom of the protection assembly, a cover plate is arranged at the top of the protection assembly, and a dust collection assembly which is communicated is arranged at the bottom of the cover plate;

the utility model discloses a dust collection device, including protection subassembly, apron, dust absorption subassembly, rolling disc and a plurality of enclose into between the division board and have a plurality of wind to drench the chamber, protection subassembly's inner wall one side is provided with the wind and drenches the subassembly, the wind drenches the subassembly and including installing a plurality of air supply board in protection subassembly inner wall, a plurality of all install a plurality of wind on the air supply board and drenches the mouth, protection subassembly's opposite side is provided with a plurality of sterilamp.

2. The efficient air shower of claim 1, wherein the driving assembly comprises a driving source, a first gear is mounted on the driving source, a second gear is connected to one side of the first gear in a meshed manner, and the second gear is connected to the toothed ring in a meshed manner.

3. The efficient air shower according to claim 1, wherein an extrusion assembly is arranged on the outer side of the connecting piece, the extrusion assembly comprises a rotating ring rotatably connected to the connecting piece, a connecting plate is mounted on the rotating ring, an upper pressing block is mounted on the top of one side of the connecting plate, and a lower pressing bar is mounted on the bottom of one side of the connecting plate.

4. The efficient air shower according to claim 1, wherein a plurality of control assemblies are installed below the inner wall of the protection assembly, and the plurality of control assemblies control the opening or closing of the plurality of air supply plates respectively.