CN114471817A - Processing technology of aldehyde-removing antibacterial nano spray - Google Patents

Abstract

The invention discloses a processing technology of an aldehyde-removing antibacterial nano-spray, which comprises the steps of producing the aldehyde-removing antibacterial nano-spray by using high-efficiency fine grinding equipment; the method comprises the following steps: A. putting raw materials to be ground into a discharging device; B. the feeding device feeds the raw materials into the crushing cover; C. starting a driving device to drive an upper grinding roller and a lower grinding roller to rotate, and grinding the raw materials through the upper grinding roller and the lower grinding roller; D. grinding the raw materials by a blowing grinding device; E. grinding the raw materials for multiple times through a repeated grinding assembly; F. collecting the ground crushed aggregates; G. uniformly mixing the collected crushed aggregates, filtering and subpackaging in a container with a sprayer; through having set up the grinder that blows can carry out multiple grinding to the raw materials, both can grind by circumferencial direction and can centripetal direction and centrifugal direction grinding to the fineness ground the raw materials has been improved.

Description

Processing technology of aldehyde-removing antibacterial nano spray

Technical Field

The invention belongs to the technical field of grinding preparation of sprays, and particularly relates to a processing technology of an aldehyde-removing antibacterial nano spray.

Background

The existing processing technology of the aldehyde-removing antibacterial nano spray needs to grind raw materials, and the grinding fineness can not be well guaranteed during grinding, namely the ground product can not be well guaranteed to meet the requirements, so that the final quality of the product is reduced.

Disclosure of Invention

The invention provides a processing technology of an aldehyde-removing antibacterial nano spray with better effect in order to overcome the defects of the prior art.

In order to achieve the purpose, the invention adopts the following technical scheme: a processing technology of aldehyde-removing antibacterial nano-spray comprises producing the aldehyde-removing antibacterial nano-spray by high-efficiency fine grinding equipment; the high-efficiency fine grinding equipment comprises a first supporting plate, a grinding cover arranged in the middle of the first supporting plate, two discharging devices arranged on the upper side and the lower side of the grinding cover, an upper grinding roller and a lower grinding roller which are arranged in the grinding cover, air-blowing grinding devices arranged on the upper grinding roller and the lower grinding roller, and a repeated grinding assembly arranged on the first supporting plate and connected to the grinding cover; the method comprises the following steps: A. putting raw materials to be ground into a discharging device; the feeding device comprises a feeding bin fixedly arranged on the upper side and the lower side of the crushing cover, a first electric door fixedly arranged on the feeding bin, a filter plate arranged in the feeding bin and used for filtering the crushing cover, an electric rod fixedly arranged on the crushing cover, a scraper fixedly connected to the electric rod and a second electric door arranged on the crushing cover; the filter plate and the second electric door are provided with driving pieces; the method comprises the following specific steps: when the materials need to be discharged, the first electric door at the upper position is opened, then the filter plate is driven by the driving piece and is also opened, then the second electric door is in a closed state, then the raw materials are put in along the first electric door and fall on the second electric door, then the first electric door is closed, then the second electric door is opened to discharge the materials, then the first electric door and the second electric door at the lower part are in an opened state, and the filter plate is in a closed state; B. the feeding device feeds the raw materials into the crushing cover; C. starting a driving device to drive an upper grinding roller and a lower grinding roller to rotate, and grinding the raw materials through the upper grinding roller and the lower grinding roller; D. grinding the raw materials by a blowing grinding device; the upper grinding roller comprises a conical feed opening arranged above the upper grinding roller, a straight barrel feed opening arranged below the conical feed opening, a third cavity arranged inside the upper grinding roller, and a gap grinding flow channel arranged between the upper grinding roller and the lower grinding roller and used for grinding raw materials; a first cavity is formed in the lower grinding roller; the air blowing grinding device comprises a second lifting block arranged in the first cavity in a sliding manner, a through hole arranged in the middle of the second lifting block, a first guide rod fixedly arranged in the first cavity and connected to the second lifting block in a sliding manner, a second tension spring arranged below the second lifting block, a second control assembly connected to the second tension spring, a second fixed rod fixedly arranged at the bottom of the first cavity and used for supporting the second lifting block, a second baffle plate arranged in the through hole in a sliding manner, a plurality of sliding chutes arranged on the first cavity, a plurality of angular air outlet channels arranged in the sliding chutes, a first grinding plate and a second grinding plate which are arranged in the sliding chutes in a sliding manner and used for blocking the angular air outlet channels, a telescopic block arranged in the sliding chutes and used for sealing the sliding chutes, and a grinding driving assembly connected to the second lifting block, the first grinding plate and the second grinding plate; the method comprises the following specific steps: the driving device blows air into the first cavity, so that the pressure inside the first cavity is increased, then the air blowing place is positioned below the second lifting block, so that the pressure below the second lifting block is increased, then the second lifting block is pushed to move upwards when the air is blown a lot, then the second baffle plate can slide in the through hole of the second lifting block, the second baffle plate seals the through hole at the beginning, then the through hole can not be sealed any more after the second lifting block moves upwards, so that the air can reach the upper part of the second lifting block, then the second lifting block moves downwards under the guidance of the first guide rod, then the second tension spring is stretched, then the angular air outlet channel is sealed by the first grinding plate and the second grinding plate, and then the second lifting block moves upwards, so that the second lifting block drives the first grinding plate and the second grinding plate to be away from each other through the grinding driving assembly, so that the angular outlet channels are no longer sealed, and then the air in the first cavity is blown out in the angular outlet channels and thus into the abrasive; E. grinding the raw materials for multiple times through a repeated grinding assembly; F. collecting the ground crushed aggregates; G. and uniformly mixing the collected crushed materials, filtering, and subpackaging in a container with a sprayer.

The invention mainly grinds the raw materials through the upper grinding roller and the lower grinding roller and simultaneously blows the raw materials, namely, the position of the grinding flow channel is blown, the blown gas can lead the raw materials to be turned over under the action of external force during grinding, thus leading the raw materials to be ground more uniformly, avoiding the raw materials from being adhered to the upper grinding roller or the lower grinding roller due to the extrusion force of the upper grinding roller and the lower grinding roller, simultaneously avoiding the problem that the grinding speed is too slow because only part of the raw materials can be contacted with the upper grinding roller and the lower grinding roller, blowing air into the raw materials later, leading more raw materials and the upper grinding roller to be contacted with the lower grinding roller while leading the raw materials to be turned over, increasing the grinding effect, simultaneously increasing the grinding and blanking speed, leading the ground raw materials to be blanked under the action of gravity and also under the action of the external force of wind, so that the grinding speed is further improved, then the first grinding plate and the second grinding plate are moved away from each other while air is blown, so that the raw materials are ground again while the first grinding plate and the second grinding plate are moved, so that the grinding effect on the raw materials is increased, then the raw materials are mainly ground in the circumferential direction while the raw materials are ground by the rotation of the upper grinding roller and the lower grinding roller, then the first grinding plate and the second grinding plate are moved in a centripetal motion and a centrifugal motion, so that the raw materials can be ground in the other direction while being ground in the circumferential direction, then the raw materials are ground in a bidirectional mode, the grinding effect is further increased, then the raw materials are blown by air, and the raw materials are turned over in a grinding flow channel, so that the raw material can be ground in the three-axis direction, the grinding speed and the grinding uniformity are further increased, the raw material can leave a grinding flow channel under the action of gravity and air blowing after being ground and fall on a filter plate below, the ground abrasive can be filtered by the filter plate below, so that the raw material meeting the requirements can fall down and be collected, the raw material not meeting the requirements is blocked by the filter plate, then the second electric door moves to seal the upper part of the filter plate, then the grinding assembly moves repeatedly to drive the grinding cover to rotate by an angle, the grinding cover rotates by a half circle, then the upper grinding roller, the lower grinding roller and the air blowing grinding device cannot move, then the feeding bin below can reach the upper position, so that the raw material not meeting the requirements reaches the upper part of the grinding cover, then the two electric rods drive the two scraping plates to move to the middle position from two sides, thereby also be exactly with the nonconforming raw materials gathering to the centre between filter and the second electrically operated gate, later the second electrically operated gate is opened once more, thereby can carry out the unloading, carry out the unloading from the position in the centre, messenger's raw materials that can be better fall to in the toper feed opening, later reachs grinding runner department once more through the toper feed opening and grinds, thereby carry out the grinding of repetitiveness many times, the convenient degree of operation has been increased, thereby the fineness of final product has still been increased, thereby can make more meticulous raw materials carry out more abundant stirring and mix, thereby can make the product quality of final production better.

Furthermore, the second control assembly comprises a first sliding plate, a first rope, a fourth gear shaft, a reel and a fifth gear box, wherein the first sliding plate is arranged on the first guide rod in a sliding mode and fixedly connected to the second tension spring; the fourth gear shaft is connected to the repeated grinding assembly; the first rope is wound on the reel; a plurality of first guide rods are arranged; so that the second tension spring is also provided in plurality; the first sliding plate and the first rope are as many as the second tension spring; each of the first ropes is wound around the reel at a different height; the method comprises the following specific steps: the repeated grinding assembly drives the crushing cover to rotate for half a circle to drive the fourth gear shaft to rotate, so that the reel is driven to rotate, the reel can drive the first rope to wind on the reel, or the first rope is loosened outwards, the first rope is enabled not to wind on the reel any more, the winding and loosening length at each time enables half of the circumference of the first rope, namely the length is short, so that the first sliding plate can be pulled to move downwards for a certain distance through the first rope, or the first sliding plate is loosened, and the first sliding plate moves upwards for a certain distance under the tension of the second tension spring; the height of the first sliding plate is gradually reduced along with the grinding time, namely the longer the grinding time is, the farther the first sliding plate is away from the second lifting block;

the stretched length of the second tension spring is changed mainly by adjusting the position of the first sliding plate, so that the elastic force of the second tension spring is changed, then the downward force on the second lifting block is changed, then the height of the first sliding plate is gradually reduced along with the grinding time, namely the grinding time is longer, the first sliding plate is farther away from the second lifting block, so that the grinding time is longer, the downward pulling force on the second lifting block is larger, so that the second lifting block can move upwards after the pressure below the second lifting block reaches X, the distance of a grinding flow channel between the upper grinding roller and the lower grinding roller is smaller and smaller along with the increase of the grinding time, so that the raw materials to be ground each time become finer, and then the downward force on the second lifting block is increased, therefore, the second lifting block can move upwards only when the pressure intensity reaches X originally, the second lifting block can move upwards only when the pressure intensity is larger than X, so that the amount of blown air is larger, the wind speed is higher, the speed of turning raw materials is increased, the blanking speed is increased, the raw materials become fine, the upper grinding roller and the lower grinding roller are more difficult to completely grind all the raw materials, the raw materials can be better ground by increasing the amount and the speed of blown air, the raw materials can be prevented from falling into the first cavity along the angular air outlet channel by larger wind power, the running stability of the equipment is further improved, the blanking speed is increased, the raw materials can meet the requirements only by grinding once after becoming fine, when the raw materials are not refined, the raw materials can be ground for more time to meet the requirements, so that useless work is avoided, the utilization efficiency of energy is improved, the raw materials are better guaranteed to be ground to be qualified, and energy is saved.

Further, the air-blowing grinding device also comprises a first telescopic rod and a first spring which are fixedly arranged above the first cavity and between the first cavity and the second baffle, a first control assembly connected with the second lifting block and the second baffle, and an arc-shaped push block; the first control assembly comprises a first rack fixedly connected to the second lifting block, a third support plate fixedly arranged on the first cavity, a third rotating shaft rotatably connected to the third support plate, a straight gear fixedly connected to the third rotating shaft and meshed with the first rack, a second rack meshed with the straight gear and fixedly connected to the second baffle, a fifth support plate fixedly arranged above the second baffle, a third telescopic rod fixedly connected between the fifth support plate and the second rack, a third spring arranged between the fifth support plate and the second rack and used for resetting the second rack, a fourth telescopic rod fixedly connected to the second rack, and a second sliding plate fixedly connected to the fourth telescopic rod and slidably arranged above the second baffle; the arc-shaped push block comprises a fourth support plate fixedly arranged below the second lifting block, a second telescopic rod fixedly arranged between the fourth support plate and the arc-shaped push block, and a second spring arranged between the fourth support plate and the arc-shaped push block and used for pushing the arc-shaped push block; the arc-shaped push block and the second baffle are provided with arc-shaped matching angles which are matched with each other; the method comprises the following specific steps: the second lifting block moves upwards to drive the first rack to move upwards, then the first rack drives the straight gear to rotate, then the straight gear drives the second rack to move downwards, then the first telescopic rod can stretch and retract, the first spring drives the second baffle to reset, then the second rack drives the second baffle to move downwards, so that the second baffle is disengaged from the through hole on the second lifting block, then the second sliding plate is engaged with the arc-shaped push block, then the arc-shaped push block pushes the second sliding plate to move in the centripetal direction under the action of the second spring, then the second sliding plate drives the second rack to move in the centripetal direction through the fourth telescopic rod, then the second rack is disengaged from the straight gear, the second lifting block resets after the pressure is reduced, and then the second lifting block moves in the direction of the second baffle, the arc ejector pad can contact with the second baffle afterwards to make the arc ejector pad reset under the effect of arc cooperation angle, thereby make the second rack reset again.

The second lifting block can move downwards only by moving upwards to enable the second baffle to move downwards, so that the through hole in the second lifting block can be opened quickly, then the air pressure below the second lifting block can be blown out quickly and outwards after being large enough, then the second rack and the straight gear are disengaged, namely when the pressure below the second lifting block is reduced, the through hole in the second lifting block is not sealed, so that the second lifting block can reset downwards quickly under the action of the second tension spring, then the second lifting block can reset completely, the second baffle cannot move along with the resetting of the second lifting block, originally, the second lifting block needs to move downwards for a certain distance to enable the through hole in the second lifting block to be disengaged from the second baffle, and then the through hole in the second lifting block can be closed quickly if the second baffle moves upwards as soon as the second lifting block starts to move downwards, thereby lead to first lapping plate and second lapping plate not to reset completely just make the pressure of second lift piece top step-down, the outside air that blows off of unable high speed and high amount of wind to also the phenomenon that the abrasive entered into first cavity inside appears easily, thereby also better improvement the steady operation of equipment, thereby the meticulous degree that better assurance raw materials ground, the quality of better improvement product.

Furthermore, the air-blowing grinding device also comprises a first pressure increasing plate arranged in the third cavity in a sliding manner, a plurality of first vent holes arranged on the first pressure increasing plate, a first fixing rod fixedly arranged on the third cavity, a first baffle plate fixedly arranged below the upper grinding roller driving device and connected to the first vent holes in a sliding manner for sealing the first baffle plate, a second support plate fixedly arranged below the third cavity, and a first tension spring fixedly connected to the second support plate and the first pressure increasing plate; the upper grinding roller is provided with an angular air outlet channel, a chute and a grinding driving assembly which have the same structure with the lower grinding roller at the same position; the method comprises the following specific steps: air can blow in above first pressure boost board, and later first pressure boost board is held by first extension spring, can make first pressure boost board downstream after first pressure boost board top pressure increases to have the air to outwards blow out, later can make first lapping plate and the second lapping plate of upper grinding roller below open through grinding drive assembly, thereby make the air outwards blow out, can make first pressure boost board reset again after the pressure reduction, seal first air vent once more, thereby also better messenger's air outwards blows out in upper grinding roller below.

Further, the grinding driving assembly comprises a second rope and a third rope which are fixedly connected to the second lifting block, a sealing tube and a third tension spring, wherein the sealing tube and the third tension spring are arranged in the first grinding plate and the second grinding plate; the first grinding plate is fixedly connected to the third rope and is connected to the second rope in a sliding mode; the second grinding plate is fixedly connected to the second rope and is connected to the third rope in a sliding mode; the telescopic block is connected with the second rope and the third rope in a sliding mode; the method comprises the following specific steps of; second elevator upward movement, pulling second rope and third rope move, later the second rope drives the motion of second grinding board, the third rope drives the repeated grinding subassembly of grinding drive assembly and moves, the direction that second rope and third rope drive first grinding board and second grinding board carry out the motion is opposite, thereby make both open, thereby can make angular form air outlet channel expose and blow, later first grinding board and second grinding board can reset under the effect of sealing tube and third extension spring and make angular form air outlet channel closed.

Furthermore, a plurality of chutes are formed on the outer surfaces of the first grinding plate and the second grinding plate; the directions of the first grinding plate and the second grinding plate on the upper grinding roller and the first grinding plate and the second grinding plate chute on the lower grinding roller are opposite, namely, the first grinding plate and the second grinding plate chute are crossed; first abrasive sheet and second abrasive sheet can keep away from each other and move, thereby grind a plurality of first abrasive sheets and the second abrasive sheet of two places about the runner and all can the interactive movement, and a plurality of chutes on first abrasive sheet and the second abrasive sheet can present the form of crossing and extrude the raw materials, and promote, thereby also be exactly at first abrasive sheet and second abrasive sheet carry out centripetal direction and centrifugal direction to the raw materials and still can pass through the setting of chute when grinding, drive the quick circular motion that carries on of raw materials, thereby also can make the speed of grinding further improve, thereby better grind it meticulously, thereby further increased the quality of product.

Furthermore, the driving device comprises a first supporting rod fixedly connected to the first supporting rod, a second supporting rod fixedly connected to the first supporting rod, a supporting ring fixedly connected to the second supporting rod and respectively connected to the upper grinding roller and the lower grinding roller, an air pump fixedly arranged on the first supporting plate and used for ventilating the first supporting rod, the second supporting rod and the inside of the supporting ring, a first motor fixedly connected to the first supporting plate, a second rotating shaft fixedly connected to the first motor, a second transmission belt wound on the second rotating shaft, a third gear pipe connected to the second transmission belt and rotatably arranged on the first supporting rod, a second gear pipe meshed with the third gear pipe and rotatably arranged on the second supporting rod, a fourth gear box rotatably connected to the third gear pipe and the second gear pipe and used for protecting the third gear pipe and the second gear pipe, a first gear pipe meshed with the second gear pipe and rotatably arranged on the second supporting rod, a first gear pipe connected to the first gear pipe, a second gear pipe connected to the second gear pipe and rotatably arranged on the second supporting rod, a second gear pipe connected to the second gear pipe, a third gear pipe connected to the third gear pipe, a second gear pipe connected to the third gear pipe, a third gear, The upper grinding roller is rotationally connected with the second gear pipe and the first gear pipe and used for protecting the upper grinding roller and the first gear pipe, the second bevel gear is fixedly connected with the first gear pipe, the two third bevel gears are meshed with the second bevel gear and fixedly connected with the upper grinding roller and the lower grinding roller, the two annular protective covers are rotationally connected with the first gear pipe, the upper grinding roller and the lower grinding roller and used for protecting the second bevel gear and the third bevel gear, circular grooves are formed in the upper grinding roller and the lower grinding roller and are in sliding connection with a supporting ring and used for guiding the upper grinding roller and the lower grinding roller, a first air outlet channel is formed in the supporting ring, and a second air outlet channel is formed in the upper grinding roller and the lower grinding roller and used for being matched with the first air outlet channel; the method comprises the following specific steps: the first supporting rod, the second supporting rod and the supporting ring are used for supporting the positions of the upper grinding roller and the lower grinding roller to enable the upper grinding roller and the lower grinding roller to be positioned inside the crushing cover, then the first motor drives the second rotating shaft to rotate, the second rotating shaft is communicated with the second driving belt to drive the third gear pipe to rotate around the first supporting rod, then the third gear pipe drives the second gear pipe to rotate, the second gear pipe drives the first gear pipe to rotate, then the first gear pipe is communicated with the second helical gear to drive the third helical gear to rotate, the third helical gear rotates to drive the upper grinding roller and the lower grinding roller to rotate, then the upper grinding roller and the lower grinding roller can slide relative to the annular protective cover, then the upper and lower two portions of the third gear pipe are meshed with the second gear pipe, so that the rotating directions of the upper and lower two gear pipes are opposite, and further that the rotating directions of the upper grinding roller and the lower grinding roller are opposite, the air pump is communicated with the first supporting rod, the second supporting rod and the first air outlet channel to blow air into the first cavity;

the cooperation of the first air outlet channel and the second air outlet channel of clearance can make the air blow to in the first cavity, and the first air outlet channel is annular groove of blowing, and the second air outlet channel is circular shape hole, thereby it blows into air in the last upward grinding roller that grinds the roller under and that is inside also being first cavity and the third cavity of the last nature of second air outlet channel to be exactly that first air outlet channel can clearance, thereby can make the relative motion of first grinding plate and second grinding plate continuously go on, thereby has also increased both relative motion and has ground the number of times, further improves the grinding effect.

Furthermore, the repeated grinding assembly comprises a second motor fixedly connected with the first supporting plate, a first rotating shaft fixedly connected with the second motor, a first transmission belt wound on the first rotating shaft, a belt wheel fixedly connected with the grinding cover and rotatably arranged on the third gear pipe and wound together with the first transmission belt, a fixed helical gear fixedly connected with the grinding cover and rotatably connected with the fourth gear box, and a first gear shaft meshed with the fixed helical gear and rotatably arranged on the fourth gear box, the gear box comprises a first gear box, a second gear shaft, a second gear box, a threaded rod, a first helical gear and a threaded pipe, wherein the first gear box is rotatably arranged on a first gear shaft, the second gear shaft is rotatably arranged on the first gear box and is meshed with the first gear shaft; the method comprises the following specific steps: after the grinding of the raw materials in the feeding bin above is finished, some raw materials which are not ground to meet the requirements can be arranged on the filter plate below, then the second motor drives the first rotating shaft to rotate, the first rotating shaft is communicated with the first transmission belt to drive the belt pulley to rotate, then the belt pulley drives the crushing cover to rotate, then the crushing cover can be rotated by half a circle, so that the raw materials in the feeding bin below can reach the upper part, then the raw materials are discharged again and ground, then the crushing cover can rotate and simultaneously drive the fixed bevel gear to rotate, then the fixed bevel gear drives the first gear shaft to rotate, then the first gear shaft can drive the second gear box to rotate, then the second gear shaft can drive the threaded rod to rotate through the first bevel gear, so that the threaded rod can rotate by half a circle, and then the threaded rod can drive the threaded pipe to move downwards, the annular protective cover is connected with the second supporting rod, the second supporting rod above the annular protective cover can stretch and retract, and the length of the second supporting rod is fixed and unchanged when the annular protective cover does not stretch, so that the annular protective cover can drive the upper grinding roller to move downwards for a certain distance, and the distance between the upper grinding roller and the lower grinding roller is shortened;

the distance between the upper grinding roller and the lower grinding roller is close to grind in different degrees by rotating the crushing cover every time, the particle size of raw materials can be finer than that before the raw materials are not ground every time the raw materials are ground, so that the crushing cover rotates every time, the distance between the upper grinding roller and the lower grinding roller is close to grind the fine raw materials before the raw materials are ground, the raw materials can be finer when the raw materials are ground for multiple times, the raw materials can be finer, the fine grinding can be guaranteed after the raw materials are ground, the fine grinding is carried out after coarse grinding, the raw materials meeting the requirements are generated during coarse grinding, the raw materials needing to be ground every time are reduced, and the upper grinding roller and the lower grinding roller can be protected after coarse grinding and fine grinding, the damage to the upper grinding roller and the lower grinding roller caused by excessive size change during one-time grinding is avoided, so that the grinding speed and the grinding effect are better guaranteed while the service life is prolonged, the ground raw materials are further more refined, and the product quality is further improved.

Furthermore, two first gear shafts are arranged and are respectively positioned at the upper end and the lower end of the fixed bevel gear; the repeated grinding assembly also comprises a third gear box which is rotationally connected with the first gear shaft below and a third gear shaft which is meshed with the first gear shaft and is rotationally connected with the third gear box; the third gear shaft is rotationally connected to the fifth gear box; the third gear shaft is meshed with the fourth gear shaft; the fourth gear shaft rotates to drive the reel and the first rope to move;

the third gear axle that drives the below through first gear axle rotates to drive second control assembly moves, thereby exactly makes first sliding plate control the tensile length of second extension spring, thereby also when grinding at every turn, the average fineness of raw materials can change, thereby will make the intensity of the outside air that blows out of angular form air outlet channel change, thereby better blow and grind it.

Furthermore, the air blowing direction of the angular air outlet channel is vertical and horizontal, so that raw materials are prevented from falling into the first cavity, the discharging speed can be increased through horizontal blowing, and the grinding speed is increased.

In conclusion, the air-blowing grinding device can be used for grinding the raw materials in multiple ways, and can be used for grinding in the circumferential direction and in the centripetal direction and the centrifugal direction, so that the grinding fineness of the raw materials is improved; set up repeated grinding subassembly, can also adjust the degree of grinding when carrying out a lot of grinding to the raw materials to better assurance the fineness after the raw materials grinds.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the structure of the support ring of the present invention;

FIG. 3 is a schematic view of the structure of the chute of the present invention;

FIG. 4 is a schematic top view of the present invention;

FIG. 5 is a first schematic sectional view of M-M of the present invention;

FIG. 6 is an enlarged view of A of FIG. 5 according to the present invention;

FIG. 7 is an enlarged view of B of FIG. 6 in accordance with the present invention;

FIG. 8 is an enlarged view of C of FIG. 6 in accordance with the present invention;

FIG. 9 is an enlarged view of D of FIG. 6 in accordance with the present invention;

FIG. 10 is an enlarged view of E of FIG. 6 in accordance with the present invention;

FIG. 11 is an enlarged view of F of FIG. 6 according to the present invention;

FIG. 12 is a schematic sectional view of M-M of the present invention;

FIG. 13 is an enlarged view of G of FIG. 12 in accordance with the present invention;

FIG. 14 is an enlarged view of H of FIG. 13 in accordance with the present invention;

FIG. 15 is an enlarged view of J of FIG. 13 in accordance with the invention;

FIG. 16 is an enlarged view of K of FIG. 15 in accordance with the invention;

FIG. 17 is an enlarged view of L of FIG. 13 in accordance with the present invention;

FIG. 18 is a schematic view of the N-N position structure in the present invention;

FIG. 19 is a schematic cross-sectional view of N-N in the present invention;

FIG. 20 is an enlarged view of R of FIG. 19 in accordance with the present invention;

FIG. 21 is an enlarged view of S of FIG. 19 in accordance with the present invention;

FIG. 22 is an enlarged view of T of FIG. 21 in accordance with the present invention;

Detailed Description

In order to make the technical solutions of the present invention better understood, 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.

As shown in fig. 1-22, a process for preparing an aldehyde-removing antibacterial nano-spray, which comprises the steps of producing the aldehyde-removing antibacterial nano-spray by using high-efficiency fine grinding equipment; the high-efficiency fine grinding equipment comprises a first supporting plate 1, a grinding cover 2 arranged in the middle of the first supporting plate 1, two discharging devices arranged on the upper side and the lower side of the grinding cover 2, an upper grinding roller 5 and a lower grinding roller 6 arranged in the grinding cover 2, an air blowing grinding device 7 arranged on the upper grinding roller 5 and the lower grinding roller 6, and a repeated grinding assembly 8 arranged on the first supporting plate 1 and connected with the grinding cover 2; the method comprises the following steps: A. putting raw materials to be ground into a discharging device; the feeding device comprises a feeding bin 3 fixedly arranged on the upper side and the lower side of the crushing cover 2, a first electric door 31 fixedly arranged on the feeding bin 3, a filter plate 32 arranged in the feeding bin 3 and used for filtering the crushing cover 2, an electric rod 33 fixedly arranged on the crushing cover 2, a scraper 34 fixedly connected with the electric rod 33 and a second electric door 35 arranged on the crushing cover 2; driving pieces are arranged on the filter plate 32 and the second electric door 35; the method comprises the following specific steps: when the materials need to be discharged, the first electric door 31 at the upper position is opened, then the filter plate 32 is driven by the driving piece and is also opened, then the second electric door 35 is in a closed state, then the raw materials are put in along the first electric door 31 and fall on the second electric door 35, then the first electric door 31 is closed, then the second electric door 35 is opened to discharge the materials, then the first electric door 31 and the second electric door 35 at the lower part are in an opened state, and the filter plate 32 is in a closed state; B. the feeding device feeds the raw materials into the crushing cover 2; C. starting a driving device 4 to drive an upper grinding roller 5 and a lower grinding roller 6 to rotate, and grinding the raw materials through the upper grinding roller 5 and the lower grinding roller 6; d. Grinding the raw materials by a blowing grinding device 7; the upper grinding roller 5 comprises a conical feed opening 51 arranged above the upper grinding roller 5, a straight barrel feed opening 52 arranged below the conical feed opening 51, a third cavity 54 arranged inside the upper grinding roller 5, and a gap grinding flow channel 53 arranged between the upper grinding roller 5 and the lower grinding roller 6 and used for grinding raw materials; a first cavity 61 is arranged inside the lower grinding roller 6; the air-blowing grinding device 7 comprises a second lifting block 71 arranged in the first cavity 61 in a sliding manner, a through hole arranged in the middle of the second lifting block 71, a first guide rod 72 fixedly arranged in the first cavity 61 and connected to the second lifting block 71 in a sliding manner, a second tension spring 711 arranged below the second lifting block 71, a second control assembly 73 connected to the second tension spring 711, and a second fixing rod 74 fixedly arranged at the bottom of the first cavity 61 and used for supporting the second lifting block 71, a second baffle 75 slidably disposed in the through hole, a plurality of sliding grooves 63 disposed on the first cavity 61, a plurality of angular air outlet passages 62 disposed in the sliding grooves 63, a first grinding plate 78 and a second grinding plate 781 slidably disposed in the sliding grooves 63 for blocking the angular air outlet passages 62, a telescopic block 79 disposed in the sliding grooves 63 for sealing the sliding grooves 63, and a grinding driving assembly 9 connected to the second lifting block 71, the first grinding plate 78 and the second grinding plate 781; the method comprises the following specific steps: the driving device 4 blows air into the first cavity 61, so that the pressure inside the first cavity 61 is increased, then the air is blown to a place below the second lifting block 71, so that the pressure below the second lifting block 71 is increased, then when the air is blown much, the second lifting block 71 is pushed to move upwards, then the second baffle plate 75 is slid in the through hole of the second lifting block 71, the second baffle plate 75 seals the through hole at the beginning, then the through hole is not sealed again after the second lifting block 71 moves upwards, so that the air reaches above the second lifting block 71, then the second lifting block 71 moves downwards under the guidance of the first guide rod 72, then the second tension spring is stretched, then the angular air outlet channel 62 is sealed by the first grinding plate 78 and the second grinding plate 781, and then the second lifting block 71 moves upwards, so that the second lifting block 71 drives the first grinding plate 711 by the grinding driving assembly 9 The plate 78 and the second abrasive plate 781 are moved away from each other so that the angled air outlet channel 62 is no longer sealed, after which the air in the first cavity 61 is blown out in the angled air outlet channel 62 and thus in the abrasive; E. grinding the raw material for multiple times by the repeated grinding assembly 8; F. collecting the ground crushed aggregates; G. and uniformly mixing the collected crushed materials, filtering, and subpackaging in a container with a sprayer.

Specifically, as shown in fig. 13-14 and 17, the second control assembly 73 includes a first sliding plate 731 slidably disposed on the first guide bar 72 and fixedly connected to the second tension spring 711, a first rope 732 fixedly connected to the first sliding plate 731, a fourth gear shaft 734 rotatably disposed below the first cavity 61, a reel 733 fixedly connected to the fourth gear shaft 734 and connected to the first rope 732, and a fifth gear box 735 fixedly disposed below the lower grinding roller 6 and rotatably connected to the fourth gear shaft 734 for protecting the fourth gear shaft 734; the fourth gear shaft 734 is connected to the regrinding assembly 8; the first rope 732 is wound around the reel 733; a plurality of first guide rods 72 are provided; the second extension spring 711 is also provided in plurality; the first sliding plate 731 and the first rope 732 are also as many as the second tension spring 711; each of the first ropes 732 is wound around the reel 733 at different heights; the method comprises the following specific steps: the fourth gear shaft 734 is driven to rotate by the repeated grinding assembly 8 for half a rotation of the crushing cover 2, so as to drive the reel 733 to rotate, and then the reel 733 drives the first rope 732 to wind on the reel 733, or the first rope 732 is loosened outwards, so that the first rope 732 is not wound on the reel 733, and the wound and loosened length makes a half of the circumference of the first rope 732, that is, a short length, so that the first sliding plate 731 is pulled to move downwards by the first rope 732 for a certain distance, or the first sliding plate 731 is loosened, and the first sliding plate 731 is moved upwards for a certain distance by the tension of the second tension spring 711; thereafter, the height of the first sliding plate 731 is gradually decreased as the grinding time is increased, that is, the longer the grinding time is, the farther the first sliding plate 731 is away from the second lifting block 71.

Specifically, as shown in fig. 13 to 16, the air-blowing grinding device 7 further includes a first telescopic rod 751 and a first spring 752 fixedly disposed between the first cavity 61 and the second baffle 75, a first control assembly 76 connected to the second lifting block 71 and the second baffle 75, and an arc-shaped pushing block 77; the first control assembly 76 comprises a first rack 761 fixedly connected to the second lifting block 71, a third support plate 762 fixedly arranged on the first cavity 61, a third rotating shaft 765 rotatably connected to the third support plate 762, a spur gear 763 fixedly connected to the third rotating shaft 765 and meshed with the first rack 761, a second rack 764 meshed with the spur gear 763 and fixedly connected to the second baffle 75, a fifth support plate 767 fixedly arranged above the second baffle 75, a third telescopic rod 766 fixedly connected between the fifth support plate 767 and the second rack 764, a third spring 768 arranged between the fifth support plate 767 and the second rack 764 for resetting the second rack 764, a fourth telescopic rod 760 fixedly connected to the second rack 764, and a second sliding plate 769 fixedly connected to the fourth telescopic rod 760 and slidably arranged above the second baffle 75; the arc-shaped pushing block 77 comprises a fourth supporting plate 772 fixedly arranged below the second lifting block 71, a second expansion link 771 fixedly arranged between the fourth supporting plate 772 and the arc-shaped pushing block 77, and a second spring 773 arranged between the fourth supporting plate 772 and the arc-shaped pushing block 77 and used for pushing the arc-shaped pushing block 77; the arc-shaped push block 77 and the second baffle 75 are provided with arc-shaped matching angles which are matched with each other; the method comprises the following specific steps: the second lifting block 71 moves upward to drive the first rack 761 to move upward, then the first rack 761 drives the spur gear 763 to rotate, then the spur gear 763 drives the second rack 764 to move downward, then the first telescopic rod 751 can extend and retract, the first spring 752 drives the second baffle 75 to reset, then the second rack 764 drives the second baffle 75 to move downward, so that the through holes on the second baffle 75 and the second lifting block 71 are disengaged, then the second sliding plate 769 is engaged with the arc-shaped pushing block 77, then the arc-shaped pushing block 77 drives the second sliding plate 769 to move in a centripetal direction under the action of the second spring 773, then the second sliding plate 769 drives the second rack 764 to move in the centripetal direction through the fourth telescopic rod 760, then the second rack 764 is disengaged from the spur gear 763, and after the pressure intensity is reduced, the second lifting block 71 resets, the second lifter 71 is then moved toward the second stop 75, the arc pushing block 77 contacts the second stop 75, and the arc pushing block 77 is reset by the arc engaging angle, so that the second rack 764 is reset again.

Specifically, as shown in fig. 3, 13 and 20, the air-blowing grinding device 7 further includes a first pressure increasing plate 70 slidably disposed inside the third cavity 54, a plurality of first vent holes 701 disposed on the first pressure increasing plate 70, a first fixing rod 704 fixedly disposed on the third cavity 54, a first baffle 705 fixedly disposed below the driving device 4 of the upper grinding roller 50 and slidably connected to the first vent holes 701 for sealing the first vent hole 701, a second support plate 702 fixedly disposed below the third cavity 54, and a first tension spring 703 fixedly connected to the second support plate 702 and the first pressure increasing plate 70; the upper grinding roller 5 is provided with an angular air outlet channel 62, a chute 63 and a grinding driving assembly 9 which have the same structure with the lower grinding roller 6 in the same position; the method comprises the following specific steps: air is blown in above the first pressure increasing plate 70, then the first pressure increasing plate 70 is pulled by the first tension spring 703, pressure above the first pressure increasing plate 70 increases to move the first pressure increasing plate 70 downward, so that air is blown out, then the first grinding plate 78 and the second grinding plate 781 below the upper grinding roller 5 are opened by the grinding driving assembly 9, so that air is blown out, and pressure decreases to reset the first pressure increasing plate 70, so that the first air vent 701 is sealed again, so that air is blown out below the upper grinding roller 5 better.

Specifically, as shown in fig. 20 to 22, the grinding driving assembly 9 includes a second rope 91 and a third rope 92 fixedly connected to the second lifting block 71, a sealing tube 93 and a third tension spring 94 disposed inside the first grinding plate 78 and the second grinding plate 781; the first grinding plate 78 is fixedly connected to the third rope 92 and slidably connected to the second rope 91; the second grinding plate 781 is fixedly connected to the second rope 91 and slidably connected to the third rope 92; the telescopic block 79 is slidably connected to a second rope 91 and a third rope 92; the method comprises the following specific steps of; the second lifting block 71 moves upwards to pull the second rope 91 and the third rope 92 to move, then the second rope 91 drives the second grinding plate 781 to move, the third rope 92 drives the grinding driving assembly 9 to repeat the grinding assembly 8 to move, the directions of the first grinding plate 78 and the second grinding plate 781 driven by the second rope 91 and the third rope 92 are opposite, so that the first grinding plate and the second grinding plate 781 can be opened, the angle air outlet channel 62 can be exposed for blowing air, and then the first grinding plate 78 and the second grinding plate 781 can be reset under the action of the sealing pipe 93 and the third tension spring 94 to close the angle air outlet channel 62.

Specifically, as shown in fig. 6 and 13, a plurality of inclined grooves are formed on the outer surfaces of the first grinding plate 78 and the second grinding plate 781; the directions of the inclined grooves of the first grinding plate 78 and the second grinding plate 781 on the upper grinding roller 5 and the first grinding plate 78 and the second grinding plate 781 on the lower grinding roller 6 are opposite, namely, the inclined grooves intersect with each other; first abrasive sheet 78 and second abrasive sheet 781 can keep away from each other and move, thereby grind a plurality of first abrasive sheet 78 and second abrasive sheet 781 of two places about runner 53 and all can the reciprocal motion, and a plurality of chutes on first abrasive sheet 78 and the second abrasive sheet 781 can present the form of crossing and extrude the raw materials, and promote, thereby also be exactly at first abrasive sheet 78 and second abrasive sheet 781 and carry out centripetal direction and centrifugal direction to the raw materials and grind the setting that still can pass through the chute, drive the quick circular motion that carries on of raw materials, thereby the speed that also can make the grinding further improves, thereby better grind it meticulously, thereby further increased the quality of product.

Specifically, as shown in fig. 1-2 and 5-11, the driving device 4 includes a first supporting rod 41 fixedly connected to the first supporting plate 1, a second supporting rod 42 fixedly connected to the first supporting rod 41, a supporting ring 47 fixedly connected to the second supporting rod 42 and respectively connected to the upper grinding roller 5 and the lower grinding roller 6, an air pump 40 fixedly disposed on the first supporting plate 1 for ventilating the interiors of the first supporting rod 41, the second supporting rod 42 and the supporting ring 47, a first motor 44 fixedly connected to the first supporting plate 1, a second rotating shaft 441 fixedly connected to the first motor 44, a second driving belt 442 wound on the second rotating shaft 441, a third gear tube 443 connected to the second driving belt 442 and rotatably disposed on the first supporting rod 41, a second gear tube 444 engaged with the third gear tube and rotatably disposed on the second supporting rod 42, a third gear tube 443, a third gear tube, A fourth gear case 43 rotatably connected to the third gear tube 443 and the second gear tube 444 for protecting the third gear tube 443 and the second gear tube 444, a first gear tube 445 engaged with the second gear tube 444 and rotatably provided on the second support rod 42, an upper grinding roller 5 of the driving device 4 rotatably connected to the second gear tube 444 and the first gear tube 445 for protecting them, a second helical gear 446 fixedly connected to the first gear tube 445, two third helical gears engaged with the second helical gear 446 and fixedly connected to the upper grinding roller 5 and the lower grinding roller 6, two annular protective covers 46 rotatably connected to the first gear tube 445 and the upper grinding roller 5 and the lower grinding roller 6 for protecting the second helical gear 446 and the third helical gear 447, circular grooves 447 provided on the upper grinding roller 5 and the lower grinding roller 6 and slidably connected to the support ring 47 for guiding the upper grinding roller 5 and the lower grinding roller 6, circular grooves 447 provided on the upper grinding roller 5 and the lower grinding roller 6, A first air outlet channel 471 arranged on the support ring 47, and a second air outlet channel 472 arranged on the upper grinding roller 5 and the lower grinding roller 6 and used for matching with the first air outlet channel 471; the method comprises the following specific steps: the first and second support rods 41, 42 and the support ring 47 are used to support the positions of the upper and lower grinding rollers 5, 6 inside the grinding hood 2, then the first motor 44 drives the second rotation shaft 441 to rotate, the second rotation shaft 441 drives the second transmission belt 442 to drive the third gear tube 443 to rotate around the first support rod 41, then the third gear tube 443 drives the second gear tube 444 to rotate, the second gear tube 444 drives the first gear tube 445 to rotate, then the first gear tube 445 drives the second bevel gear 446 to rotate, the third bevel gear 447 rotates to drive the upper and lower grinding rollers 5, 6 to slide relative to the annular protective cover 46, then two second gear tubes 444 are arranged at the upper and lower positions of the third gear tube 443 to mesh with the third bevel gear tube 443, so that the rotation directions of the upper and lower second gear tubes 444 are opposite, and thus the rotation directions of the upper and lower grinding rolls 5 and 6 are opposite, so that the raw material is ground by turning off the relative rotation of the upper and lower grinding rolls 5 and 6, and the air pump 40 blows air into the first cavity 61 by turning off the first and second support rods 41 and 42 and the first air outlet passage 471.

Specifically, as shown in fig. 1, 5-7, 9-11, and 13, the repetitive grinding assembly 8 includes a second motor 81 fixedly connected to the first support plate 1, a first rotating shaft 82 fixedly connected to the second motor 81, a first driving belt 83 wound around the first rotating shaft 82, a pulley 84 fixedly connected to the pulverization housing 2 and rotatably disposed on the third gear pipe 443 and wound around the first driving belt 83, a fixed helical gear 85 fixedly connected to the pulverization housing 2 and rotatably coupled to the fourth gear box 43, a first gear shaft 86 engaged with the fixed helical gear 85 and rotatably disposed on the fourth gear box 43, a first gear box 861 rotatably disposed on the first gear shaft 86, a second gear shaft 87 rotatably disposed on the first gear box 861 and engaged with the first gear shaft 86, a second gear box 871 rotatably coupled to the second gear shaft 87, a threaded rod 873 rotatably disposed on the second gear box 871, A first helical gear 872 fixedly connected to the threaded rod 873 and engaged with the second gear shaft 87, and a threaded pipe 874 fixedly provided on the annular protection cover 46 and threadedly connected with the threaded rod 873; the method comprises the following specific steps: after the grinding of the raw material in the upper feeding bin 3 is completed, some raw material which is not ground to meet the requirement exists on the lower filter plate 32, then the second motor 81 drives the first rotating shaft 82 to rotate, the first rotating shaft 82 drives the belt pulley 84 to rotate through the first driving belt 83, then the belt pulley 84 drives the crushing cover 2 to rotate, then the crushing cover 2 can rotate for half a circle, so that the raw material in the lower feeding bin 3 can reach the upper part, then the raw material is discharged again and ground, then the crushing cover 2 rotates and simultaneously drives the fixed bevel gear 85 to rotate, then the fixed bevel gear 85 drives the first gear shaft 86 to rotate, then the first gear shaft 86 rotates to drive the second gear box 871 to rotate, then the second gear shaft 87 drives the threaded rod 873 to rotate through the first bevel gear 872, so that the threaded rod 873 can rotate for half a circle, then, the rotation of the threaded rod 873 will drive the threaded pipe 874 to move downwards, then the threaded pipe 874 will drive the annular protection cover 46 to move downwards, then the annular protection cover 46 is connected with the second support rod 42, then the upper second support rod 42 can be extended and retracted, and the length is fixed when not extended and retracted, so that the annular protection cover 46 will drive the upper grinding roller 5 to move downwards for a certain distance, and the distance between the upper grinding roller 5 and the lower grinding roller 6 will be shortened.

Specifically, as shown in fig. 7 to 9 and 13 to 14, two first gear shafts 86 are provided, and are respectively located at the upper and lower ends of the fixed helical gear 85; the regrinding assembly 8 further includes a third gear housing 881 rotatably coupled to the lower first gear shaft 86, and a third gear shaft 88 meshed with the first gear shaft 86 and rotatably coupled to the third gear housing 881; the third gear shaft 88 is rotatably connected to the fifth gear box 735; the third gear shaft 88 is meshed with a fourth gear shaft 734; the rotation of the fourth gear shaft 734 causes the reel 733 and the first rope 732 to move.

Specifically, as shown in fig. 13, the air blowing direction of the angular air outlet channel 62 is vertical and horizontal, so as to prevent the raw material from falling into the first cavity 61, and to increase the discharging speed by horizontal blowing, thereby increasing the grinding speed.

It is to be understood that the described embodiments are merely a few embodiments of the invention, and not all 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.

Claims (9)

1. A processing technology of an aldehyde-removing antibacterial nano-spray is characterized in that the aldehyde-removing antibacterial nano-spray is produced by high-efficiency fine grinding equipment; the high-efficiency fine grinding equipment comprises a first supporting plate (1), a grinding cover (2) arranged in the middle of the first supporting plate (1), two discharging devices arranged on the upper side and the lower side of the grinding cover (2), an upper grinding roller (5) and a lower grinding roller (6) arranged in the grinding cover (2), air-blowing grinding devices (7) arranged on the upper grinding roller (5) and the lower grinding roller (6), and a repeated grinding assembly (8) arranged on the first supporting plate (1) and connected to the grinding cover (2); the method comprises the following steps: A. putting raw materials to be ground into a discharging device; the feeding device comprises a feeding bin (3) fixedly arranged on the upper side and the lower side of the crushing cover (2), a first electric door (31) fixedly arranged on the feeding bin (3), a filter plate (32) arranged in the feeding bin (3) and used for filtering the crushing cover (2), an electric rod (33) fixedly arranged on the crushing cover (2), a scraper (34) fixedly connected to the electric rod (33), and a second electric door (35) arranged on the crushing cover (2); driving pieces are arranged on the filter plate (32) and the second electric door (35); the method comprises the following specific steps: when the materials need to be discharged, the first electric door (31) at the upper position can be opened, then the filter plate (32) can be driven by the driving piece and also can be opened, then the second electric door (35) is in a closed state, then the raw materials are put into the filter plate along the first electric door (31) and fall onto the second electric door (35), then the first electric door (31) is closed, then the second electric door (35) is opened to discharge the materials, then the first electric door (31) and the second electric door (35) at the lower part are in an opened state, and the filter plate (32) is in a closed state; B. the feeding device feeds the raw materials into the crushing cover (2); C. starting a driving device (4) to drive an upper grinding roller (5) and a lower grinding roller (6) to rotate, and grinding the raw materials through the upper grinding roller (5) and the lower grinding roller (6); D. grinding the raw materials by a blowing grinding device (7); the upper grinding roller (5) comprises a conical feed opening (51) arranged above the upper grinding roller (5), a straight-tube feed opening (52) arranged below the conical feed opening (51), a third cavity (54) arranged inside the upper grinding roller (5), and a gap grinding flow channel (53) arranged between the upper grinding roller (5) and the lower grinding roller (6) and used for grinding raw materials; a first cavity (61) is arranged in the lower grinding roller (6); the air blowing grinding device (7) comprises a second lifting block (71) arranged in a first cavity (61) in a sliding mode, a through hole arranged in the middle of the second lifting block (71), a first guide rod (72) fixedly arranged in the first cavity (61) and connected to the second lifting block (71) in a sliding mode, a second tension spring (711) arranged below the second lifting block (71), a second control assembly (73) connected to the second tension spring (711), a second fixing rod (74) fixedly arranged at the bottom of the first cavity (61) and used for supporting the second lifting block (71), a second baffle (75) arranged in the through hole in a sliding mode, a plurality of sliding grooves (63) arranged on the first cavity (61), a plurality of angular air outlet channels (62) arranged in the sliding grooves (63), a first grinding plate (78) and a second grinding plate (781) which are arranged in the sliding grooves (63) in a sliding mode and used for blocking the angular air outlet channels (62), A telescopic block (79) arranged in the sliding chute (63) and used for sealing the sliding chute (63), and a grinding driving assembly (9) connected with the second lifting block (71), the first grinding plate (78) and the second grinding plate (781); the method comprises the following specific steps: the driving device (4) blows air into the first cavity (61) to increase the pressure inside the first cavity (61), then blows air at a place below the second lifting block (71) to increase the pressure below the second lifting block (71), then pushes the second lifting block (71) to move upwards when the air blows much, then slides the second baffle plate (75) in the through hole of the second lifting block (71), the second baffle plate (75) seals the through hole at the beginning, then the through hole is not sealed again when the second lifting block (71) moves upwards, so that the air reaches above the second lifting block (71), then the second lifting block (71) moves downwards under the guidance of the first guide rod (72), then the second tension spring (711) is stretched, and then the angular air outlet channel (62) is sealed by the first grinding plate (78) and the second grinding plate (781), then the second lifting block (71) moves upwards to enable the second lifting block (71) to drive the first grinding plate (78) and the second grinding plate (781) to move away from each other through the grinding driving assembly (9), so that the angle air outlet channel (62) is not sealed any more, and then air in the first cavity (61) is blown outwards in the angle air outlet channel (62) to be blown into the grinding materials; E. grinding the raw material for a plurality of times by a repeated grinding assembly (8); F. collecting the ground crushed aggregates; G. and uniformly mixing the collected crushed materials, filtering and subpackaging in a container with a sprayer.

2. The processing technology of the aldehyde-removing antibacterial nano spray according to claim 1, characterized in that: the second control assembly (73) comprises a first sliding plate (731) which is arranged on the first guide rod (72) in a sliding mode and fixedly connected to the second tension spring (711), a first rope (732) fixedly connected to the first sliding plate (731), a fourth gear shaft (734) rotatably arranged below the first cavity (61), a reel (733) fixedly connected to the fourth gear shaft (734) and connected to the first rope (732), and a fifth gear box (735) fixedly arranged below the lower grinding roller (6) and rotatably connected to the fourth gear shaft (734) and used for protecting the fourth gear shaft (734); the fourth gear shaft (734) is connected to the regrind assembly (8); the method comprises the following specific steps: the fourth gear shaft (734) is driven to rotate by the repeated grinding assembly (8) driving the crushing cover (2) to rotate for half a turn, so as to drive the winding wheel (733) to rotate, then the winding wheel (733) drives the first rope (732) to wind on the winding wheel (733), or the first rope (732) is loosened outwards so that the first rope (732) is not wound on the winding wheel (733), and the wound and loosened length enables half of the circumference of the first rope (732), namely the short length, so that the first sliding plate (731) is pulled to move downwards for a certain distance through the first rope (732), or the first sliding plate (731) is loosened, and the first sliding plate (731) is pulled upwards for a certain distance by the tension of the second tension spring (711).

3. The processing technology of the aldehyde-removing antibacterial nano spray as claimed in claim 2, wherein the processing technology comprises the following steps: the air-blowing grinding device (7) further comprises a first telescopic rod (751) and a first spring (752) which are fixedly arranged above the first cavity (61) and between the second baffle plate (75), a first control assembly (76) connected to the second lifting block (71) and the second baffle plate (75) and an arc-shaped push block (77); the first control assembly (76) comprises a first rack (761) fixedly connected to the second lifting block (71), a third supporting plate (762) fixedly arranged on the first cavity (61), a third rotating shaft (765) rotatably connected to the third supporting plate (762), a straight gear (763) fixedly connected to the third rotating shaft (765) and meshed with the first rack (761), a second rack (764) meshed with the straight gear (763) and fixedly connected to the second baffle (75), a fifth supporting plate (767) fixedly arranged above the second baffle (75), a third telescopic rod (766) fixedly connected between the fifth supporting plate (767) and the second rack (764), a third spring (768) arranged between the fifth supporting plate (767) and the second rack (764) and used for resetting the second rack (764), and a fourth telescopic rod (760) fixedly connected to the second rack (764), A second sliding plate (769) fixedly connected to the fourth telescopic rod (760) and arranged above the second baffle plate (75) in a sliding manner; the arc-shaped push block (77) comprises a fourth supporting plate (772) fixedly arranged below the second lifting block (71), a second expansion rod (771) fixedly arranged between the fourth supporting plate (772) and the arc-shaped push block (77), and a second spring (773) arranged between the fourth supporting plate (772) and the arc-shaped push block (77) and used for pushing the arc-shaped push block (77); the method comprises the following specific steps: the second lifting block (71) moves upwards to drive the first rack (761) to move upwards, then the first rack (761) drives the spur gear (763) to rotate, then the spur gear (763) drives the second rack (764) to move downwards, then the first telescopic rod (751) can stretch and retract, the first spring (752) drives the second baffle (75) to reset, then the second rack (764) drives the second baffle (75) to move downwards, so that the second baffle (75) and the through hole in the second lifting block (71) are disengaged, then the second sliding plate (769) and the arc-shaped pushing block (77) are engaged, then the arc-shaped pushing block (77) can push the second sliding plate (769) to move in the centripetal direction under the action of the second spring (773), and then the second sliding plate (769) can drive the second rack (764) to move in the centripetal direction through the fourth telescopic rod (760), then the second rack (764) and the straight gear (763) are disengaged, the second lifting block (71) is reset after the pressure intensity is reduced, then the second lifting block (71) moves towards the second baffle plate (75), then the arc-shaped push block (77) is contacted with the second baffle plate (75), and the arc-shaped push block (77) is reset under the action of the arc-shaped matching angle, so that the second rack (764) is reset again.

4. The processing technology of the aldehyde-removing antibacterial nano spray according to claim 3, characterized in that: the air-blowing grinding device (7) further comprises a first pressure increasing plate (70) arranged in the third cavity (54) in a sliding manner, a plurality of first vent holes (701) formed in the first pressure increasing plate (70), a first fixing rod (704) fixedly arranged on the third cavity (54), a first baffle plate (705) fixedly arranged below the driving device (4) of the upper grinding roller (50) and connected to the first vent holes (701) in a sliding manner for sealing the first vent holes, a second support plate (702) fixedly arranged below the third cavity (54), and a first tension spring (703) fixedly connected to the second support plate (702) and the first pressure increasing plate (70); the upper grinding roller (5) is provided with an angular air outlet channel (62), a chute (63) and a grinding driving assembly (9), wherein the angular air outlet channel and the chute have the same structure as the lower grinding roller (6) in the same position; the method comprises the following specific steps: air is blown in above the first pressure increasing plate (70), then the first pressure increasing plate (70) is pulled by the first tension spring (703), the pressure intensity above the first pressure increasing plate (70) is increased, then the first pressure increasing plate (70) moves downwards, so that air is blown out outwards, and then the first grinding plate (78) and the second grinding plate (781) below the upper grinding roller (5) are opened through the grinding driving assembly (9).

5. The processing technology of the aldehyde-removing antibacterial nano spray according to claim 1, characterized in that: the grinding driving assembly (9) comprises a second rope (91) and a third rope (92) which are fixedly connected to the second lifting block (71), and a sealing pipe (93) and a third tension spring (94) which are arranged inside the first grinding plate (78) and the second grinding plate (781); the first grinding plate (78) is fixedly connected to a third rope (92) and is slidably connected to a second rope (91); the second grinding plate (781) is fixedly connected to the second rope (91) and slidably connected to the third rope (92); the telescopic block (79) is connected with a second rope (91) and a third rope (92) in a sliding mode; the method comprises the following specific steps of; the second lifting block (71) moves upwards, the second rope (91) and the third rope (92) are pulled to move, then the second rope (91) drives the second grinding plate (781) to move, the third rope (92) drives the grinding driving assembly (9) to repeat the grinding assembly (8) to move, the directions of the second rope (91) and the third rope (92) driving the first grinding plate (78) and the second grinding plate (781) to move are opposite, so that the first grinding plate (78) and the second grinding plate (781) can be opened, the angle air outlet channel (62) can be exposed for air blowing, and then the first grinding plate (78) and the second grinding plate (781) can be reset under the action of the sealing pipe (93) and the third tension spring (94) to enable the angle air outlet channel (62) to be closed.

6. The processing technology of the aldehyde-removing antibacterial nano spray according to claim 1, characterized in that: a plurality of inclined grooves are formed in the outer surfaces of the first grinding plate (78) and the second grinding plate (781); the directions of the chutes of the first grinding plate (78) and the second grinding plate (781) on the upper grinding roller (5) and the chutes of the first grinding plate (78) and the second grinding plate (781) on the lower grinding roller (6) are opposite, namely, the chutes are intersected with each other; the first grinding plate (78) and the second grinding plate (781) are moved away from each other, so that the plurality of first grinding plates (78) and the second grinding plate (781) at the upper and lower positions of the grinding flow passage (53) are moved relative to each other, and the plurality of inclined grooves on the first grinding plate (78) and the second grinding plate (781) are in a crossed manner to extrude the raw materials.

7. The processing technology of the aldehyde-removing antibacterial nano spray as claimed in claim 2, wherein the processing technology comprises the following steps: the driving device (4) comprises a first supporting rod (41) fixedly connected to the first supporting plate (1), a second supporting rod (42) fixedly connected to the first supporting rod (41), an air pump (40) fixedly connected to the second supporting rod (42) and respectively connected to the upper grinding roller (5) and the lower grinding roller (6), a supporting ring (47) fixedly arranged on the first supporting plate (1) and used for ventilating the first supporting rod (41), the second supporting rod (42) and the inside of the supporting ring (47), a first motor (44) fixedly connected to the first supporting plate (1), a second rotating shaft (441) fixedly connected to the first motor (44), a second driving belt (442) wound on the second rotating shaft (441), a third gear pipe (443) connected to the second driving belt (442) and rotatably arranged on the first supporting rod (41), a second gear pipe (444) meshed to the third gear pipe (443) and rotatably arranged on the second supporting rod (42), and a second gear pipe (444), A fourth gear box (43) rotatably connected to the third gear pipe (443) and the second gear pipe (444) for protecting the third gear pipe (443) and the second gear pipe (444), a first gear pipe (445) engaged with the second gear pipe (444) and rotatably disposed on the second support rod (42), an upper grinding roller (5) rotatably connected to the drive unit (4) of the second gear pipe (444) and the first gear pipe (445) for protecting both, a second helical gear (446) fixedly connected to the first gear pipe (445), two third helical gears (447) engaged with the second helical gear (446) and fixedly connected to the upper grinding roller (5) and the lower grinding roller (6), two annular protective covers (46) rotatably connected to the first gear pipe (445), the upper grinding roller (5) and the lower grinding roller (6) for protecting the second helical gear (446) and the third helical gears (447), The air outlet device comprises circular grooves, a first air outlet channel (471) and a second air outlet channel (472), wherein the circular grooves are arranged on an upper grinding roller (5) and a lower grinding roller (6) and are in sliding connection with a supporting ring (47) and used for guiding the upper grinding roller (5) and the lower grinding roller (6), the first air outlet channel (471) is arranged on the supporting ring (47), and the second air outlet channel (472) is arranged on the upper grinding roller (5) and the lower grinding roller (6) and used for being matched with the first air outlet channel (471); the method comprises the following specific steps: the first supporting rod (41), the second supporting rod (42) and the supporting ring (47) are used for supporting the positions of the upper grinding roller (5) and the lower grinding roller (6) to enable the upper grinding roller and the lower grinding roller to be positioned inside the crushing cover (2), then the first motor (44) drives the second rotating shaft (441) to rotate, the second rotating shaft (441) is communicated with the second driving belt (442) to drive the third gear pipe (443) to rotate around the first supporting rod (41), then the third gear pipe (443) drives the second gear pipe (444) to rotate, the second gear pipe (444) drives the first gear pipe (445) to rotate, then the first gear pipe (445) is communicated with the second helical gear (446) to drive the third helical gear (447) to rotate, the third helical gear (447) can drive the upper grinding roller (5) and the lower grinding roller (6) to rotate, and then the upper grinding roller (5) and the lower grinding roller (6) and the annular protective cover (46) can slide relatively, then, two second gear pipes (444) are arranged at the upper and lower positions of the third gear pipe (443) to be meshed with the third gear pipe, so that the rotating directions of the upper and lower second gear pipes (444) are opposite, and the rotating directions of the upper grinding roller (5) and the lower grinding roller (6) are opposite, so that the raw materials are ground by closing the relative rotation of the upper grinding roller (5) and the lower grinding roller (6), and the air pump (40) blows air into the first cavity (61) by closing the first supporting rod (41) and the second supporting rod (42) and the first air outlet channel (471).

8. The processing technology of the aldehyde-removing antibacterial nano spray according to claim 7, characterized in that: the repeated grinding assembly (8) comprises a second motor (81) fixedly connected to the first supporting plate (1), a first rotating shaft (82) fixedly connected to the second motor (81), a first transmission belt (83) wound on the first rotating shaft (82), a belt wheel (84) fixedly connected to the crushing cover (2) and rotatably arranged on the third gear pipe (443) and wound together with the first transmission belt (83), a fixed bevel gear (85) fixedly connected to the crushing cover (2) and rotatably connected to the fourth gear box (43), a first gear shaft (86) meshed with the fixed bevel gear (85) and rotatably arranged on the fourth gear box (43), a first gear box (861) rotatably arranged on the first gear shaft (86), a second gear shaft (87) rotatably arranged on the first gear box (861) and meshed with the first gear shaft (86), a second gear box (871) rotatably connected to the second gear shaft (87), a second gear box (871), A threaded rod (873) rotatably arranged in the second gear box (871), a first bevel gear (872) fixedly connected to the threaded rod (873) and meshed with the second gear shaft (87), and a threaded pipe (874) fixedly arranged on the annular protective cover (46) and in threaded connection with the threaded rod (873); the method comprises the following specific steps: after grinding the raw material in the feeding bin (3) at the upper part, the raw material which does not meet the requirement can be obtained on the filtering plate (32) at the lower part, then the second motor (81) drives the first rotating shaft (82) to rotate, the first rotating shaft (82) is communicated with the first transmission belt (83) to drive the belt wheel (84) to rotate, then the belt wheel (84) drives the crushing cover (2) to rotate, then the crushing cover (2) can rotate for a half circle, so that the raw material in the feeding bin (3) at the lower part can reach the upper part, then the raw material is discharged again and ground, then the fixed bevel gear (85) can be driven to rotate while the crushing cover (2) rotates, then the fixed bevel gear (85) drives the first gear shaft (86) to rotate, then the first gear shaft (86) can drive the second gear box (bevel gear) to rotate, then the second gear shaft (87) can drive the threaded rod (873) to rotate through the first bevel gear (872), and then the second gear shaft (87) can drive the threaded rod (873) to rotate through the first bevel gear (bevel gear) to perform grinding It is rotatory, thereby also can make threaded rod (873) rotatory half a turn, threaded rod (873) rotatory can drive screwed pipe (874) downstream afterwards, screwed pipe (874) can drive annular safety cover (46) downstream afterwards, annular safety cover (46) are connected with second bracing piece (42) afterwards, second bracing piece (42) of top can stretch out and draw back afterwards, and length is fixed unchangeable when not stretching out and drawing back, thereby also annular safety cover (46) can drive grinding roller (5) a section distance of downstream.

9. The processing technology of the aldehyde-removing antibacterial nano spray according to claim 8, characterized in that: two first gear shafts (86) are respectively positioned at the upper end and the lower end of the fixed bevel gear (85); the regrinding assembly (8) further comprises a third gear case (881) rotatably connected to the first gear shaft (86) therebelow, and a third gear shaft (88) meshed with the first gear shaft (86) and rotatably connected to the third gear case (881); the third gear shaft (88) is rotatably connected to a fifth gear box (735); the third gear shaft (88) is meshed with a fourth gear shaft (734); the rotation of the fourth gear shaft (734) drives the reel (733) and the first rope (732) to move.

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