CN113977886A - Individualized face guard production facility for clinical operation - Google Patents

Abstract

The invention discloses individualized mask production equipment for clinical operations, which belongs to the technical field of masks and comprises a shell, negative pressure suction mold mechanisms, an air suction mechanism and a vibration mechanism, wherein the negative pressure suction mold mechanisms are arranged on the left side and the right side of the upper surface of the shell, one part of the negative pressure suction mold mechanism is fixedly connected in the shell, the air suction mechanism is arranged in the shell and is positioned on the front side of the negative pressure suction mold mechanism, and the negative pressure suction mold mechanism is fixedly connected to the front side of the shell. According to the invention, the clamp sleeve can fix the hard pipe to avoid loosening by arranging the negative pressure die sucking mechanism, when the hard pipe is taken out from the clamp sleeve, the rubber sucker is attached to a finished product, then the pedal is stepped to control the hard pipe to drive the piston to move downwards through the slide rod, the piston draws air in the inflator, the air in the rubber sucker is drawn out, meanwhile, the rubber sucker can suck the finished product, and the hard pipe can be pulled to easily suck the finished product out of the die through the rubber sucker, so that the operation of people is greatly facilitated.

Description

Individualized face guard production facility for clinical operation

Technical Field

The invention belongs to the technical field of masks, and particularly relates to individualized mask production equipment for clinical operations.

Background

Masks are protectors for protecting a person's face and there may be large differences in the use of masks with different applications of breathing apparatus.

Chinese patent discloses a multifunctional warmer face shield injection molding mold (No. CN 201920934222.9), which comprises a first mold, a guide post, a second mold, a guide groove and a support spring, wherein the guide post is welded at two ends of one side surface of the first mold, the second mold is movably connected at the bottom of the first mold through the guide post, the guide groove is arranged at two ends of one side surface of the second mold and is matched with the guide post, the support spring is fixedly arranged in the inner cavity of the guide groove, the top of the support spring is connected with the bottom of the guide post, a movable mold is welded in the middle of one side surface of the first mold, a fixed mold is arranged in the middle of one side surface of the second mold and is matched with the movable mold, and a semiconductor refrigerating sheet is embedded in the inner cavity of the second mold, and the semiconductor refrigeration piece is positioned on one side of the fixed die, and a vibrator is embedded at the bottom of the fixed die. "but the material that is used for making the face guard all is the plastics material generally, people can't be effective quick after the completion of moulding plastics take out the finished product, and the higher comparatively hot hand of finished product temperature, bring certain inconvenience for people's operation, and when the mould was taken out and is stacked together simultaneously, probably because do not have the reason of complete cooling and lead to bonding together between the mould each other, the flaw of bonding state can appear on the mould surface when part mould like this, bring inconvenience for people's use.

Disclosure of Invention

The invention aims to: in order to solve the problem that people can not effectively and quickly take out finished products after injection molding is finished, the temperature of the finished products is high and hot, certain inconvenience is brought to the operation of people, the molds are taken out and stacked together, the molds can be bonded together due to the fact that the molds are not cooled completely, the defects of the bonding state can be caused on the surfaces of the molds when the molds are separated, inconvenience is brought to the use of people, and the individualized mask production equipment for clinical operation is provided.

In order to achieve the purpose, the invention adopts the following technical scheme:

the utility model provides a clinical operation is with individuation face guard production facility, includes shell, negative pressure suction mould mechanism, the mechanism and the vibrations mechanism of induced drafting, the left and right sides of shell upper surface all is provided with negative pressure suction mould mechanism, and some fixed connection of negative pressure suction mould mechanism is provided with the mechanism of induced drafting in the shell, and the mechanism of induced drafting is located the front side of negative pressure suction mould mechanism, and negative pressure suction mould mechanism fixed connection is in the front of shell, is provided with the vibrations mechanism in the negative pressure suction mould mechanism, and the one end of vibrations mechanism is connected with the one end of the mechanism of induced drafting.

As a further description of the above technical solution:

the negative pressure die sucking mechanism comprises a clamping sleeve fixedly connected to the upper surface of the shell, a hard pipe is arranged in the clamping sleeve, a suction nozzle is fixedly connected to one end of the hard pipe, a rubber suction cup is arranged on the front side of the suction nozzle, a plurality of first air holes are formed in the front side of the suction nozzle, and the first air holes are evenly distributed in the outer side of the rubber suction cup.

As a further description of the above technical solution:

one end of the back of the hard tube is communicated with a negative pressure suction tube, the other end of the negative pressure suction tube penetrates through the upper surface of the shell and extends into the shell, the other end of the negative pressure suction tube and the upper surface of the air cylinder are fixedly connected to the lower surface of the shell, and a piston is arranged in the air cylinder.

As a further description of the above technical solution:

the lower surface of the piston is fixedly connected with a pedal through a sliding rod, the sliding rod is located in a sliding sleeve clamped with the lower surface of the inflator, the lower surface of the pedal is fixedly connected with the lower surface of the inner wall of the shell through a first spring, and the pedal is located in a limiting hole formed in one side face of the shell.

As a further description of the above technical solution:

the mechanism of induced drafting includes the aspiration channel of fixed connection at shell inner wall upper surface, is provided with first pivot in the aspiration channel, and the surface joint of first pivot has a plurality of flabellums, and a plurality of flabellums are from last down align to grid setting, and the surface cover of first pivot is equipped with first bearing, and the left and right sides face of first bearing all is through the inner wall fixed connection of dead lever with the aspiration channel, and first pivot is located the wind hole that the set casing upper surface was seted up.

As a further description of the above technical solution:

the utility model discloses a motor, including first pivot, first bevel gear, second bevel gear joint, the surface of second pivot, the surface cover of second pivot is equipped with two second bearings, two second bearings joint respectively are at the left and right sides face of set casing, the equal joint in both ends of second pivot has the cam, the equal a plurality of aerofoil that gather of the equal fixedly connected with in left and right sides of second pivot surface, it is located the set casing to gather the aerofoil, the right-hand member of second pivot and the output shaft fixed connection of motor, the right flank fixed connection of lower surface through mount pad and shell of motor, the surface joint of motor output shaft has first drive wheel.

As a further description of the above technical solution:

the lower fixed surface of set casing is connected with the intercommunication shell, and the lower fixed surface intercommunication of intercommunication shell has a plurality of hoses, and the other end fixedly connected with cooling tube of hose, cooling tube fixed connection are in collecting the box, collect box fixed connection in the front of shell, and a plurality of second gas pockets have been seted up to the surface of cooling tube, and the front intercommunication of intercommunication shell has a plurality of tubules, and the other end of tubule runs through the inside and the intercommunication of negative pressure tubule and cooling tube in the suction nozzle.

As a further description of the above technical solution:

the mechanism of induced drafting still includes the cover shell of fixed connection in the shell, fixed connection is at the water pocket in the cover shell, the positive fixedly connected with ejector pad of water pocket, the positive fixedly connected with baffle of ejector pad, the left and right sides face of baffle all is through the back fixed connection of second spring with the cover shell inner wall, the back intercommunication of water pocket has the outlet pipe, the other end intercommunication of outlet pipe is in the one end of the spiral passageway that the set casing inner wall was seted up, the other end intercommunication of spiral passageway has the back flow, the other end of back flow runs through the inside of cover shell and communicates with the surface of water pocket.

As a further description of the above technical solution:

the utility model discloses a vibration mechanism, including the first drive wheel, the first drive wheel is connected with the first drive wheel transmission through the drive belt, the left surface of first drive wheel and the one end fixed connection of third pivot, the quantity of third pivot is two, fixedly connected with connecting axle between two third pivots, the equal fixedly connected with flange in upper and lower both sides of connecting axle surface, the outside cover of third pivot is equipped with the third bearing, two third bearings joint are in the left and right sides face of collecting the box inner wall respectively, the quantity of connecting axle is a plurality of, a plurality of connecting axles are in the past backward align to grid setting, the surface joint of third pivot has the gear, a plurality of gears are in the past backward align to grid setting and intermeshing.

As a further description of the above technical solution:

the upside of connecting axle is provided with the backup pad, the equal fixedly connected with slider in the left and right sides of backup pad, and slider sliding connection is in collecting the spout that the box inner wall was seted up, and the upper surface of slider passes through the upper surface fixed connection of third spring and spout inner wall, and the equal fixed connection of a plurality of backup pads is at the lower surface of cushion, and cushion fixed connection just is located the downside of cooling tube in collecting the box.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

1. according to the invention, the clamp sleeve can fix the hard pipe to avoid loosening by arranging the negative pressure die sucking mechanism, when the hard pipe is taken out from the clamp sleeve, the rubber sucker is attached to a finished product, then the pedal is stepped to control the hard pipe to drive the piston to move downwards through the slide rod, the piston draws air in the inflator, the air in the rubber sucker is drawn out, meanwhile, the rubber sucker can suck the finished product, and the hard pipe can be pulled to easily suck the finished product out of the die through the rubber sucker, so that the operation of people is greatly facilitated.

2. According to the invention, by arranging the air suction mechanism, the motor can drive the second rotating shaft to rotate when working, the second rotating shaft drives the first bevel gear to rotate through the second bevel gear, the first bevel gear drives the plurality of fan blades to rotate through the first rotating shaft, the fan blades can suck external air into the air suction pipe, finally, the air enters the inside of the fixed shell through the air suction pipe, the air inside the fixed shell enters the communicating shell, finally, the air is discharged through the plurality of thin pipes and the plurality of hoses, the air entering the inside of the radiating pipe is sprayed out through the plurality of second air holes, the purpose of cooling a finished product is achieved, the air in the thin pipes enters the plurality of first air holes, in the process of taking out the mold, the cooling air volume cannot affect the adsorption effect of the rubber sucker, the finished product can be cooled, the good cooling effect on the finished product is achieved, and the finished product is prevented from being bonded together. Simultaneously the second pivot can drive the cam rotatory when rotatory, the cam can extrude the baffle, the baffle can drive the ejector pad and remove backward, the ejector pad removes backward and can extrude the water pocket, comdenstion water in the water pocket can discharge and get into to the helical passage in through the outlet pipe, the helical passage water-logging can cool off the air in the set casing, effective cooling air reaches the better cooling effect to the mould, through setting up the second spring, when the cam is no longer to the baffle extrusion, the second spring can push up the baffle through self elasticity extension, the baffle drives the water pocket through the ejector pad and resumes to initial position, comdenstion water in the helical passage flows back to the water pocket once more this moment, effective neutralization temperature, keep the cooling effect to finished product.

3. In the invention, by arranging the vibration mechanism, when the motor works, the first driving wheel drives the second driving wheel to rotate through the driving belt, the second driving wheel drives the gears to rotate through the third rotating shaft, a plurality of gears can simultaneously rotate under the meshing action, the gears drive the convex plate to rotate through the connecting shaft, the convex plate can form an extrusion effect on the supporting plate when rotating, the supporting plate can push the elastic cushion, and the elastic cushion can effectively vibrate a large number of finished products to generate vibration, avoid the bonding condition among finished products, ensure the effective circulation of air among a large number of finished products, improve the heat dissipation effect of the finished products, the supporting plate can stably move up and down along the track by arranging the sliding block, the sliding groove and the third spring, meanwhile, the third spring can push the sliding block after the supporting plate moves upwards, and the sliding block drives the supporting plate to move downwards to the initial position.

Drawings

Fig. 1 is a schematic perspective view of an individualized mask production device for clinical operation according to the present invention;

FIG. 2 is a schematic three-dimensional structure diagram of an air cylinder and a slide bar in the individualized mask production equipment for clinical operation according to the present invention;

FIG. 3 is a schematic cross-sectional view of an air suction mechanism in the production equipment of the individualized mask for clinical operation;

FIG. 4 is a schematic structural diagram of a rubber pad and a slider in the production equipment of the individualized mask for clinical operation according to the present invention;

FIG. 5 is a schematic structural diagram of a connecting shaft and a third rotating shaft in the production equipment of the individualized mask for clinical operation according to the present invention;

fig. 6 is a schematic perspective view of a baffle and a cover in the individualized mask production equipment for clinical operation according to the present invention.

Illustration of the drawings:

1. a housing; 2. a negative pressure suction mold mechanism; 21. a negative pressure suction pipe; 22. a hard tube; 23. a jacket; 24. a suction nozzle; 25. a rubber suction cup; 26. a first air hole; 27. an air cylinder; 28. a piston; 29. a slide bar; 210. a first spring; 211. a pedal; 3. an air suction mechanism; 31. an air suction pipe; 32. a fan blade; 33. a first rotating shaft; 34. fixing the rod; 35. a wind hole; 36. a first bevel gear; 37. a second bevel gear; 38. a wind-collecting plate; 39. a second rotating shaft; 310. a cam; 311. a spiral channel; 312. a stationary case; 313. a communicating shell; 314. a hose; 315. a thin tube; 316. a radiating pipe; 317. a collection box; 318. a baffle plate; 319. a second spring; 320. a push block; 321. a water bladder; 322. a return pipe; 323. a housing; 324. a water outlet pipe; 325. a motor; 326. a first drive pulley; 4. a vibration mechanism; 41. a transmission belt; 42. a second transmission wheel; 43. a third rotating shaft; 44. a gear; 45. a connecting shaft; 46. a convex plate; 47. a support plate; 48. a slider; 49. a third spring; 410. an elastic pad; 5. and a limiting hole.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-6, the present invention provides a technical solution: an individualized mask production device for clinical operation comprises a shell 1, a negative pressure suction mold mechanism 2, an air suction mechanism 3 and a vibration mechanism 4, wherein the negative pressure suction mold mechanism 2 is arranged on the left side and the right side of the upper surface of the shell 1, a part of the negative pressure suction mold mechanism 2 is fixedly connected in the shell 1, the negative pressure suction mold mechanism 2 comprises a jacket 23 fixedly connected on the upper surface of the shell 1, a hard tube 22 is arranged in the jacket 23, one end of the hard tube 22 is fixedly connected with a suction nozzle 24, the front side of the suction nozzle 24 is provided with a rubber suction cup 25, the front side of the suction nozzle 24 is provided with a plurality of first air holes 26, the plurality of first air holes 26 are uniformly distributed on the outer side of the rubber suction cup 25, one end of the back side of the hard tube 22 is communicated with the negative pressure suction tube 21, the other end of the negative pressure suction tube 21 penetrates through the upper surface of the shell 1 and extends into the shell 1, the other end of the negative pressure suction tube 21 and the upper surface of an air cylinder 27, the air cylinder 27 is fixedly connected to the lower surface of the shell 1, a piston 28 is arranged in the air cylinder 27, the lower surface of the piston 28 is fixedly connected with a pedal 211 through a sliding rod 29, the sliding rod 29 is positioned in a sliding sleeve clamped on the lower surface of the air cylinder 27, the lower surface of the pedal 211 is fixedly connected with the lower surface of the inner wall of the shell 1 through a first spring 210, and the pedal 211 is positioned in a limiting hole 5 formed in one side surface of the shell 1;

the specific implementation mode is as follows: through setting up negative pressure suction mould mechanism 2, jacket 23 can fix hard tube 22 and avoid becoming flexible, when taking out hard tube 22 from jacket 23, adhere to rubber suction cup 25 on the finished product, then step on footboard 211 and control it and drive piston 28 downstream through slide bar 29, piston 28 is through the inside air of extraction inflator 27, the inside air of rubber suction cup 25 is taken out this moment, rubber suction cup 25 can adsorb the finished product simultaneously, pulling hard tube 22 can easily follow the suction of finished product from the mould through rubber suction cup 25 this moment, greatly make things convenient for people's operation, through setting up first spring 210, when footboard 211 is no longer stepped on, first spring 210 can push footboard 211 to the initial position through self elastic extension.

An air suction mechanism 3 is arranged in the shell 1, the air suction mechanism 3 is positioned at the front side of the negative pressure die sucking mechanism 2, the air suction mechanism 3 comprises an air suction pipe 31 fixedly connected with the upper surface of the inner wall of the shell 1, a first rotating shaft 33 is arranged in the air suction pipe 31, a plurality of fan blades 32 are clamped on the outer surface of the first rotating shaft 33, the fan blades 32 are uniformly arranged from top to bottom, a first bearing is sleeved on the outer surface of the first rotating shaft 33, the left side surface and the right side surface of the first bearing are fixedly connected with the inner wall of the air suction pipe 31 through a fixing rod 34, the first rotating shaft 33 is positioned in an air hole 35 formed in the upper surface of the fixed shell 312, a first bevel gear 36 is fixedly connected at the bottom end of the first rotating shaft 33, the first bevel gear 36 is meshed with a second bevel gear 37, the second bevel gear 37 is clamped on the outer surface of a second rotating shaft 39, two second bearings are sleeved on the outer surface of the second rotating shaft 39, and are respectively clamped on the left side surface and the right side surface of the fixed shell 312, the cam 310 is clamped at both ends of the second rotating shaft 39, the multiple air collecting plates 38 are fixedly connected to both left and right sides of the outer surface of the second rotating shaft 39, the air collecting plates 38 are located in the fixing shell 312, the right end of the second rotating shaft 39 is fixedly connected with the output shaft of the motor 325, the lower surface of the motor 325 is fixedly connected with the right side surface of the housing 1 through the mounting seat, the first driving wheel 326 is clamped on the outer surface of the output shaft of the motor 325, the lower surface of the fixing shell 312 is fixedly connected with the communicating shell 313, the lower surface of the communicating shell 313 is fixedly communicated with the multiple hoses 314, the other end of the hose 314 is fixedly connected with the radiating pipe 316, the radiating pipe 316 is fixedly connected in the collecting box 317, the collecting box 317 is fixedly connected on the front surface of the housing 1, the outer surface of the radiating pipe 316 is provided with multiple second air holes, the front surface of the communicating shell 313 is communicated with the multiple thin pipes 315, and the other ends of the thin pipes 315 penetrate through the insides of the negative pressure thin pipes 315 and the radiating pipe 316 and are communicated in the suction nozzle 24, the air suction mechanism 3 further comprises a casing 323 fixedly connected in the shell 1, the casing 323 is fixedly connected in the water bag 321, the front surface of the water bag 321 is fixedly connected with a push block 320, the front surface of the push block 320 is fixedly connected with a baffle 318, the left side surface and the right side surface of the baffle 318 are fixedly connected with the back surface of the inner wall of the casing 323 through a second spring 319, the back surface of the water bag 321 is communicated with a water outlet pipe 324, the other end of the water outlet pipe 324 is communicated with one end of a spiral channel 311 arranged on the inner wall of the fixed casing 312, the other end of the spiral channel 311 is communicated with a return pipe 322, and the other end of the return pipe 322 penetrates through the inside of the casing 323 and is communicated with the outer surface of the water bag 321;

the specific implementation mode is as follows: through setting up the mechanism 3 that induced drafts, wherein the motor 325 during operation can drive the rotation of second pivot 39, second pivot 39 drives first bevel gear 36 through second bevel gear 37 and rotates, first bevel gear 36 drives a plurality of flabellum 32 rotatoryly through first pivot 33, flabellum 32 can be with outside air suction in to aspiration channel 31, last air passes through aspiration channel 31 and gets into to the set casing 312 inside, the inside air of set casing 312 gets into to the intercommunication shell 313 in, discharge through a plurality of tubules 315 and a plurality of hose 314 at last, the air that gets into to the inside of cooling tube 316 passes through a plurality of second gas pocket blowout, reach the purpose of cooling off-the-shelf, and the air in the tubule 315 gets into to a plurality of first gas ports 26 in, also can cool down the finished product taking out the in-process of mould, reach the cooling effect fine to the finished product, avoid the finished product to bond together. Through the structural design, the cooling air volume formed by the first air holes 26 does not influence the adsorption effect of the rubber suction cups 25. Meanwhile, the cam 310 can be driven to rotate when the second rotating shaft 39 rotates, the cam 310 can extrude the baffle 318, the baffle 318 can drive the push block 320 to move backwards, the push block 320 moves backwards to extrude the water bag 321, condensed water in the water bag 321 can be discharged through the water outlet pipe 324 and enter the spiral channel 311, water in the spiral channel 311 can cool air in the fixed shell 312, the effective cooling air achieves a better cooling effect on the mold, through the arrangement of the second spring 319, when the cam 310 does not extrude the baffle 318 any more, the second spring 319 can push the baffle 318 through elastic extension of the second spring 319, the baffle 318 drives the water bag 321 to restore to an initial position through the push block 320, at the moment, the condensed water in the spiral channel 311 flows back to the water bag 321 again, the water temperature is effectively neutralized, and the cooling effect on a finished product is kept.

The negative pressure die sucking mechanism 2 is fixedly connected to the front of the shell 1, a vibration mechanism 4 is arranged in the negative pressure die sucking mechanism 2, one end of the vibration mechanism 4 is connected with one end of the air suction mechanism 3, the vibration mechanism 4 comprises a second driving wheel 42, the second driving wheel 42 is in transmission connection with a first driving wheel 326 through a transmission belt 41, the left side surface of the second driving wheel 42 is fixedly connected with one end of a third rotating shaft 43, the number of the third rotating shafts 43 is two, a connecting shaft 45 is fixedly connected between the two third rotating shafts 43, the upper side and the lower side of the outer surface of the connecting shaft 45 are both fixedly connected with convex plates 46, a third bearing is sleeved on the outer side of the third rotating shaft 43, the two third bearings are respectively clamped on the left side surface and the right side surface of the inner wall of the collecting box 317, the number of the connecting shafts 45 is multiple, the multiple connecting shafts 45 are uniformly arranged from front to back, and a gear 44 is clamped on the outer surface of the third rotating shaft 43, the gears 44 are uniformly arranged from front to back and are meshed with each other, a supporting plate 47 is arranged on the upper side of the connecting shaft 45, sliders 48 are fixedly connected to the left side and the right side of each supporting plate 47, the sliders 48 are slidably connected in sliding grooves formed in the inner wall of the collecting box 317, the upper surfaces of the sliders 48 are fixedly connected with the upper surfaces of the inner walls of the sliding grooves through third springs 49, the supporting plates 47 are fixedly connected to the lower surfaces of the elastic cushions 410, and the elastic cushions 410 are fixedly connected in the collecting box 317 and located on the lower sides of the radiating pipes 316;

the specific implementation mode is as follows: by arranging the vibration mechanism 4, wherein the first driving wheel 326 drives the second driving wheel 42 to rotate through the driving belt 41 when the motor 325 works, the second driving wheel 42 drives the gear 44 to rotate through the third rotating shaft 43, the plurality of gears 44 can rotate simultaneously under the meshing action, the gear 44 drives the convex plate 46 to rotate through the connecting shaft 45, the convex plate 46 can form an extrusion effect on the supporting plate 47 when rotating, the supporting plate 47 can push the elastic pad 410, and the elastic pad 410 can effectively vibrate to enable a large amount of finished products to generate vibration, avoid the bonding condition among finished products, ensure the effective circulation of air among a large number of finished products, improve the heat dissipation effect of the finished products, by providing the slider 48, the slide groove, and the third spring 49, the support plate 47 can be stably moved up and down along the trajectory, meanwhile, after the supporting plate 47 moves upwards, the third spring 49 can push the sliding block 48, and the sliding block 48 drives the supporting plate 47 to move downwards to the initial position.

The working principle is as follows: when in use, when the hard tube 22 is taken out from the jacket 23, the rubber suction cup 25 is attached to the finished product, then the pedal 211 is stepped to control the rubber suction cup to drive the piston 28 to move downwards through the slide rod 29, the piston 28 draws air in the air cylinder 27, at the same time, the air in the rubber suction cup 25 is drawn out, the rubber suction cup 25 can absorb the finished product, at the same time, the hard tube 22 is pulled to easily suck the finished product out of the mold through the rubber suction cup 25, the sucked finished product is put into the collection box 317, the motor 325 can drive the second rotating shaft 39 to rotate when working, the second rotating shaft 39 drives the first bevel gear 36 to rotate through the second bevel gear 37, the first bevel gear 36 drives the plurality of fan blades 32 to rotate through the first rotating shaft 33, the fan blades 32 can suck external air into the air suction pipe 31, finally, the air enters the fixed shell 312 through the air suction pipe 31, the air in the fixed shell 312 enters the communicating shell 313, finally, the air entering the radiating pipe 316 is discharged through the thin pipes 315 and the hoses 314, and is ejected through the second air holes to achieve the purpose of cooling the finished product, the air in the thin pipes 315 enters the first air holes 26, the finished product can be cooled in the process of taking out the mold, so as to achieve a good cooling effect on the finished product, the cam 310 can be driven to rotate when the second rotating shaft 39 rotates, the cam 310 can press the baffle 318, the baffle 318 can drive the push block 320 to move backwards, the push block 320 can move backwards to press the water sac 321, the condensed water in the water sac 321 can be discharged through the water outlet pipe 324 and enter the spiral channel 311, the water in the spiral channel 311 can cool the air in the fixed shell 312, the effective cooling air achieves a better cooling effect on the mold, the first driving wheel 326 drives the second driving wheel 42 to rotate through the driving belt 41 when the motor 325 works, second drive wheel 42 drives gear 44 rotatoryly through third pivot 43, a plurality of gears 44 can rotate simultaneously under the meshing effect, gear 44 passes through connecting axle 45 and drives the flange 46 rotatoryly, can form the extrusion effect to backup pad 47 when flange 46 is rotatory, backup pad 47 can push up cushion 410, cushion 410 can effectively shake and let the condition that a large amount of finished products produced vibrations, avoid the condition that bonds to appear between the finished product, also can guarantee that the air effectively circulates between a large amount of finished products, improve off-the-shelf radiating effect.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (10)

1. The utility model provides a clinical operation is with individuation face guard production facility, includes shell (1), negative pressure suction die mechanism (2), induced drafts mechanism (3) and vibrations mechanism (4), its characterized in that, the left and right sides of shell (1) upper surface all is provided with negative pressure suction die mechanism (2), and the partly fixed connection of negative pressure suction die mechanism (2) is provided with in shell (1) induced drafts mechanism (3) in shell (1), and induced drafts mechanism (3) and is located the front side of negative pressure suction die mechanism (2), and negative pressure suction die mechanism (2) fixed connection is in the front of shell (1), is provided with vibrations mechanism (4) in negative pressure suction die mechanism (2), and the one end of vibrations mechanism (4) is connected with the one end of the mechanism (3) of induced drafting.

2. The production equipment of the individualized mask for clinical operation according to claim 1, wherein the negative pressure die-sucking mechanism (2) comprises a jacket (23) fixedly connected to the upper surface of the shell (1), a hard tube (22) is arranged in the jacket (23), one end of the hard tube (22) is fixedly connected with a suction nozzle (24), a rubber suction cup (25) is arranged on the front surface of the suction nozzle (24), a plurality of first air holes (26) are formed in the front surface of the suction nozzle (24), and the plurality of first air holes (26) are uniformly distributed on the outer side of the rubber suction cup (25).

3. The clinical individualized mask production equipment for surgery as recited in claim 2, wherein one end of the back surface of the rigid tube (22) is communicated with a negative pressure suction tube (21), the other end of the negative pressure suction tube (21) penetrates through the upper surface of the housing (1) and extends into the housing (1), the other end of the negative pressure suction tube (21) is connected with the upper surface of an air cylinder (27), the air cylinder (27) is fixedly connected with the lower surface of the housing (1), and a piston (28) is arranged in the air cylinder (27).

4. The clinical individualized mask production equipment for surgery as claimed in claim 3, wherein the lower surface of the piston (28) is fixedly connected with a pedal (211) through a slide rod (29), the slide rod (29) is located in a slide sleeve clamped on the lower surface of the air cylinder (27), the lower surface of the pedal (211) is fixedly connected with the lower surface of the inner wall of the housing (1) through a first spring (210), and the pedal (211) is located in a limit hole (5) formed in one side surface of the housing (1).

5. The individualized mask production equipment for clinical operation according to claim 1, wherein the air suction mechanism (3) comprises an air suction pipe (31) fixedly connected to the upper surface of the inner wall of the housing (1), a first rotating shaft (33) is arranged in the air suction pipe (31), a plurality of fan blades (32) are connected to the outer surface of the first rotating shaft (33) in a clamping manner, the fan blades (32) are uniformly arranged from top to bottom, a first bearing is sleeved on the outer surface of the first rotating shaft (33), the left side surface and the right side surface of the first bearing are fixedly connected to the inner wall of the air suction pipe (31) through fixing rods (34), and the first rotating shaft (33) is located in an air hole (35) formed in the upper surface of the fixing housing (312).

6. The clinical operation individualized mask production equipment according to claim 5, wherein a first bevel gear (36) is fixedly connected to the bottom end of the first rotating shaft (33), the first bevel gear (36) is engaged with a second bevel gear (37), the second bevel gear (37) is clamped on the outer surface of the second rotating shaft (39), two second bearings are sleeved on the outer surface of the second rotating shaft (39), the two second bearings are respectively clamped on the left side surface and the right side surface of the fixed shell (312), cams (310) are clamped at both ends of the second rotating shaft (39), a plurality of air collecting plates (38) are fixedly connected to both the left side and the right side surfaces of the outer surface of the second rotating shaft (39), the air collecting plates (38) are located in the fixed shell (312), the right end of the second rotating shaft (39) is fixedly connected with the output shaft of the motor (325), and the lower surface of the motor (325) is fixedly connected with the right side surface of the outer shell (1) through a mounting seat, the outer surface of the output shaft of the motor (325) is clamped with a first transmission wheel (326).

7. The clinical operation individualized mask production equipment according to claim 6, wherein the lower surface of the fixed shell (312) is fixedly connected with a communicating shell (313), the lower surface of the communicating shell (313) is fixedly communicated with a plurality of hoses (314), the other end of each hose (314) is fixedly connected with a radiating pipe (316), each radiating pipe (316) is fixedly connected in a collecting box (317), each collecting box (317) is fixedly connected to the front surface of the shell (1), a plurality of second air holes are formed in the outer surface of each radiating pipe (316), the front surface of the communicating shell (313) is communicated with a plurality of thin pipes (315), and the other ends of the thin pipes (315) penetrate through the insides of the negative pressure thin pipes (315) and the radiating pipes (316) and are communicated in the suction nozzle (24).

8. A clinical individualized mask production device for surgical use according to claim 7, wherein the air suction mechanism (3) further comprises a casing (323) fixedly connected inside the casing (1), the casing (323) being fixedly connected inside the water bladder (321).

9. The clinical individualized mask production equipment for surgical operation as claimed in claim 8, wherein the pushing block (320) is fixedly connected to the front surface of the water bag (321), the baffle plate (318) is fixedly connected to the front surface of the pushing block (320), and the left and right side surfaces of the baffle plate (318) are fixedly connected to the back surface of the inner wall of the casing (323) through the second spring (319).

10. The production equipment of the individualized mask for clinical operation according to claim 9, wherein the back surface of the water bag (321) is communicated with a water outlet pipe (324), the other end of the water outlet pipe (324) is communicated with one end of a spiral channel (311) formed in the inner wall of the fixed shell (312), the other end of the spiral channel (311) is communicated with a return pipe (322), and the other end of the return pipe (322) penetrates through the inside of the casing (323) and is communicated with the outer surface of the water bag (321).

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