CN114602342A - High fat film, production method and device thereof - Google Patents

Abstract

The invention discloses a high fat membrane, a production method of the high fat membrane and a device thereof, relating to the technical field of production and processing of the high fat membrane. Mixing light raw materials of sodium dodecyl sulfate, silicon dioxide and potassium fulvate to form a film thickening raw material, stirring for 10-15 minutes, wherein the rotating speed per minute is not more than 180 revolutions; adding potassium dihydrogen phosphate and compound trace and medium elements, stirring for 10-15 min at a rotation speed of not more than 120 rpm; adding choline chloride, brassinolide, thickening film-forming additive, diethyl aminoethyl hexanoate and sodium salicylate, stirring for 10 minutes at a rotation speed of not more than 100 revolutions per minute; the stirring is accomplished and is stood for at least ten minutes, and in the process of stirring the production of the upper high-fat film, a three-layer stirring barrel is adopted, and a channel is formed by the upper-layer stirring and the lower-layer stirring layer, namely the upper layer and the lower layer of the stirring barrel form convection during stirring, and the stirring is carried out by arranging a fine stirring rod in the middle, so that the efficiency of the high-fat film in low-speed stirring is increased.

Description

High fat film, production method and device thereof

Technical Field

The invention belongs to the technical field of high-fat membrane production and processing, and particularly relates to a high-fat membrane, a production method of the high-fat membrane and a device thereof.

Background

The high-fat film is a white, fine and sticky water-soluble substance, the main dosage form is 27% high-fat film emulsion, a thin fatty acid film is arranged on the surface of a plant body after use, although germs can still invade the plant body, the germs cannot be expanded or rarely expands after invasion due to film control, and thus the purpose of preventing diseases is achieved. The high-lipid film has good prevention and treatment effects on most fungal diseases, the prevention of the fungal diseases is a physical effect, pathogenic bacteria cannot generate drug resistance, and the high-lipid film is non-toxic, harmless and non-toxic to people, plants and fishes, and is a pollution-free pesticide. After being sprayed on the surface of the plant, the plant can automatically diffuse to form a monomolecular film which can not be seen by naked eyes, and the plant is wrapped to protect the crops from being infected by external diseases and expanding of germs, and the growth, ventilation and light transmission of the crops are not influenced, so that the plant can play a role in preventing diseases; meanwhile, the plant can be protected against cold; is widely applicable to crops such as vegetables, melons, fruits, fruit trees and the like.

In the production process of the high-fat membrane, the compound needs to be stirred, and the high-fat membrane is often prepared by low-speed stirring and mixing in the stirring process, so that the production capacity of the high-fat membrane cannot be effectively improved.

Disclosure of Invention

The invention aims to provide a high-fat film, a production method of the high-fat film and a device thereof.

In order to solve the technical problems, the invention is realized by the following technical scheme:

the invention relates to a production device of a high-fat membrane, which comprises a stirring cylinder, wherein the stirring cylinder is provided with three layers of stirring areas, and an upper layer stirrer, a middle stirrer and a lower layer stirrer are arranged from a feeding port to a discharging port of the stirring cylinder;

a middle shaft is installed in the stirring cylinder, a flow distribution cover is arranged at the bottom of the middle shaft, a lower-layer stirrer is installed on the flow distribution cover, a blanking cavity is arranged in the middle shaft, a feeding hole and a discharging hole which correspond to the blanking cavity are formed in the upper end and the lower end of the middle shaft, the discharging hole is communicated with the flow distribution cover, a circle of discharging groove is formed in the flow distribution cover, the lower-layer stirrer is provided with a circle of second stirring bent plates, and the material facing surface of each second stirring bent plate is inclined to the middle stirrer;

the driver is installed to the axis, and the inner circle cover of middle part agitator is established on the driver, and middle part agitator is taken and is leaned on the upper end of reposition of redundant personnel cover.

The upper port of the shunting cover is provided with a sealing cover, the sealing cover comprises a sealing bearing and a ring cover, the height of an outer ring on the sealing bearing is greater than that of an inner ring, and the ring cover is arranged on the outer ring.

Further, the driver includes the lantern ring and drive wheel, the upper and lower both ends of the lantern ring all are provided with two rings of ring gears, the drive wheel is equipped with the round in the lantern ring, a drive wheel includes a second drive wheel and a first drive wheel, connect through the connecting axle between two drive wheels and the first drive wheel, the middle part agitator has a first well section of thick bamboo, a first well section of thick bamboo has interior flank of tooth, the second drive wheel respectively with the ring gear, the meshing of flank of tooth, first drive wheel respectively with the ring gear, the meshing of flank of tooth meshing.

Further, the middle part agitator still includes to fit with a contraceptive ring and lower ring, and it connects through the round support column to fit with a contraceptive ring and lower ring between, is provided with a puddler between each support column and the first well section of thick bamboo, and the puddler is flat pole, and a port of a first well section of thick bamboo has the orifice plate, and the orifice plate cover is established epaxially.

Furthermore, two pairs of bottom rings and circular rings are arranged on the lower-layer stirrer, the radius of each circular ring is larger than that of each bottom ring, and a circle of second stirring bent plate is arranged between the upper bottom ring and the lower bottom ring and between the circular rings.

Furthermore, the lower end of the mixing drum is provided with a ring seat, a bottom plate is arranged in the ring seat, the middle part of the bottom plate is provided with a through hole and a sliding groove, and the bottom ring and the circular ring are matched in the sliding groove.

Further, the upper agitator includes first stirring bent plate, first connecting ring and outer sliding ring set up in pairs and are equipped with two pairs, the setting of first stirring bent plate lopping is between first connecting ring and outer sliding ring, the spout has been seted up on the first stirring bent plate, be provided with the eyelidretractor between two first connecting rings, the eyelidretractor includes section of thick bamboo and backup pad in the second, the backup pad is equipped with two both ends that are located a section of thick bamboo in the second respectively, the cover is established epaxially in the second, set up the perpendicular groove that corresponds the feed inlet in the second on the section of thick bamboo.

Further, be provided with the apron in the agitator, have feed port on the apron, the bottom of agitator is provided with discharge port.

A high-fat membrane comprises the following substances in parts by weight: 2-3 parts of choline chloride, 0.3-0.4 part of sodium dodecyl sulfate, 3-4 parts of brassinolide, 2-3 parts of silicon dioxide, 7-8 parts of potassium fulvate, 60-64 parts of a thickening film-forming additive, 7-9 parts of monopotassium phosphate, 7-9 parts of composite trace and medium elements, 0.5-0.7 part of amine fresh fat and 4-6 parts of sodium salicylate.

A method for producing a high lipid film, comprising:

mixing the light raw materials of sodium dodecyl sulfate, silicon dioxide and potassium fulvate to form a film thickening raw material, stirring for 10-15 minutes at a rotating speed of not more than 180 revolutions per minute;

adding potassium dihydrogen phosphate and compound trace and medium elements, stirring for 10-15 min at a rotation speed of not more than 120 rpm;

adding choline chloride, brassinolide, thickening film-forming additive, diethyl aminoethyl hexanoate and sodium salicylate, stirring for 10 minutes at a rotation speed of not more than 100 revolutions per minute;

the stirring was completed and left to stand for at least ten minutes.

The invention has the following beneficial effects: the three-layer mixing drum is adopted to form a channel between the upper-layer mixing drum and the lower-layer mixing drum, namely, the upper layer and the lower layer of the mixing drum form convection during mixing, and are mixed by a fine mixing rod arranged in the middle part, so that the effect of low-speed mixing of the high-fat film is improved,

the invention adopts three layers of mixing drums, the upper layer of mixing drum and the lower layer of mixing drum form a channel, namely, the upper layer and the lower layer of the mixing drum form convection during mixing, and the high-fat membrane is mixed by a fine mixing rod arranged in the middle, so that the low-speed mixing efficiency of the high-fat membrane is improved, namely, the driving wheel and the ring gear are designed in a planet wheel type, the rotating speed of a mixer in the middle can be reduced, the ascending pressure of materials is reduced, and the overall flowing speed of the materials is increased.

Of course, it is not necessary for any product in which the invention is practiced to achieve all of the above-described advantages at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic view of the construction of a stirrer;

FIG. 2 is a schematic view of the structure of the stirrer;

FIG. 3 is a schematic structural view of a flow dividing cover, a middle stirrer and a middle shaft;

FIG. 4 is a schematic view of the internal structure of the mixing drum;

FIG. 5 is a schematic view of the structure of the flow dividing hood, the middle agitator and the center shaft;

FIG. 6 is a schematic view of the internal structure of the flow dividing hood, the middle agitator and the center shaft;

FIG. 7 is a schematic view of the construction of the central agitator;

FIG. 8 is a schematic structural view of the flow dividing cover and the bottom bracket;

FIG. 9 is a schematic view of the construction of the central agitator;

in the drawings, the components represented by the respective reference numerals are listed below:

1. a mixing drum; 2. a base plate; 3. a flow dividing cover; 4. a middle agitator; 5. a cover plate; 6. an upper layer stirrer; 7. a lower layer stirrer; 8. a support; 9. a middle shaft; 10. a driver; 11. sealing the cover; 101. a ring seat; 201. a base plate; 202. a through hole; 301. a dispersion chamber; 302. a discharge chute; 401. a first middle cylinder; 402. a support column; 403. ring fitting; 404. a stirring rod; 405. a lower ring; 601. a first connecting ring; 602. an outer slip ring; 603. a first stirring bent plate; 701. a second stirring bent plate; 702. a bottom ring; 703. a circular ring; 802. a second middle cylinder; 803. a vertical slot; 901. a feed inlet; 902. a mesopore; 903. a blanking cavity; 904. a discharge port; 905. clamping the strip; 1001. a second drive wheel; 1002. a connecting shaft; 1003. a second drive wheel; 1004. a collar; 1005. a toothed ring; 1101. a cover plate; 1101. and a bearing.

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.

In the description of the present invention, it is to be understood that the terms "opening," "upper," "lower," "thickness," "top," "middle," "length," "inner," "peripheral," and the like are used in an orientation or positional relationship that is merely for convenience in describing and simplifying the description, and do not indicate or imply that the referenced component or element must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be considered as limiting the present invention.

Referring to fig. 1-9, the present invention is a mixing drum 1, the mixing drum 1 has three layers of mixing regions, from the inlet port to the outlet port of the mixing drum 1, an upper layer mixer 6, a middle layer mixer 4 and a lower layer mixer 7 are arranged; specifically, this agitating unit adopts the three-layer churn, forms the passageway with upper stirring and lower floor's stirring layer, and the upper and lower floor of agitator forms the convection current when the stirring promptly, sets up fine puddler through the middle part and stirs, increases the efficiency of high fat membrane at low-speed stirring.

A middle shaft 9 is installed in the mixing drum 1, an upper layer stirrer 6, a middle layer stirrer 4 and a lower layer stirrer 7 are sequentially installed from one end to the other end of the middle shaft 9, a driver 10 is arranged on the middle layer stirrer 4, so that the stirrer 4 respectively forms a rotation speed difference between the upper layer stirrer 6 and the upper layer stirrer 6, preferably, the rotation speeds of the upper layer stirrer 6, the upper layer stirrer 6 and the middle shaft 9 are the same, one end of the middle shaft 9 is connected with a speed reducer, a motor is used as a power source of the speed reducer, the rotation speed of the middle layer stirrer 4 is larger than that of the upper layer stirrer 6, and a corresponding middle hole 902 is formed in the corresponding middle shaft 9.

The middle stirrer 4 is used as a main stirring device of the materials.

The middle shaft 9 is provided with a driver 10, and the inner ring of the middle stirrer 4 is sleeved on the driver 10.

Specifically, the middle stirrer 4 further comprises an upper ring 403 and a lower ring 405, the upper ring 403 is connected with the lower ring 405 through a circle of support columns 402, a row of stirring rods 404 is arranged between each support column 402 and the first middle cylinder 401, the distance between each row of stirring rods 404 is preferably 10mm, each stirring rod 404 is a flat rod, the thickness of each stirring rod 404 is 5mm, a port of the first middle cylinder 401 is provided with a pore plate, and the pore plate is sleeved on the middle shaft 9.

The transmission device 10 includes a collar 1004 and a driving wheel, the driving wheel is provided with a circle on the collar 1004, two circles of toothed rings 1005 are provided at the upper and lower ends of the collar 1004, that is, the driving wheel and the ring toothed rings 1005 are designed in a planetary gear type.

One driving wheel comprises a second driving wheel 1003 and a first driving wheel 1001, the second driving wheel 1003 and the first driving wheel 1001 are connected through a connecting shaft 1002, preferably, the second driving wheel 1003 and the connecting shaft 1002 are designed in an integrated mode, a screw hole is formed in the middle of the first driving wheel 1001, the first driving wheel 1001 is installed at the other end of the connecting shaft 1002 through the screw hole, a collar 1004 is a stepped cylinder, the two ends are thin and the middle is thick, two rings of toothed rings 1005 are arranged on the thin ring, the tooth tips of the toothed rings 1005 do not leak out of the thick cylinder section of the stepped cylinder, namely, the installed second driving wheel 1003 and the first driving wheel 1001 can be clamped at the two ends of the stepped cylinder, the spacing is carried out through the stepped cylinder driving wheel on the collar 1004, correspondingly, the middle stirrer 4 is provided with a first middle cylinder 401, an inner tooth surface is arranged in the first middle cylinder 401, the second driving wheel 1003 is respectively meshed with the toothed rings 1005 and the inner tooth surfaces, the first driving wheel 1001 is respectively meshed with the toothed rings 1005 and the inner tooth surfaces, namely, the rotation of the middle shaft 9 drives the planet wheel formed by the driving wheel gear ring 1005 to drive the first middle cylinder 401, so that the middle stirrer 4 rotates.

In addition, the upper layer stirrer 4 and the lower layer stirrer 7 rotate along with the rotation of the middle shaft 9, the rotating speed of the middle stirrer 4 is less than that of the lower layer stirrer 7 and the upper layer stirrer 6, a rotating speed difference is formed, the ascending resistance of the material is reduced, meanwhile, the circulating material is vertically cut and stirred, and the material stirring efficiency is improved

Wherein:

the bottom of the middle shaft 9 is provided with a flow dividing cover 3, the bottom of the middle shaft 9 is provided with a barrel body, materials flowing downwards from the upper end of the middle rod 9 are firstly collected into the barrel body 1 and then flow out of a stirring range of a lower-layer stirrer 7 through a hole formed in the barrel body, specifically, the lower-layer stirrer 7 is installed on the flow dividing cover 3, a discharging cavity 903 is formed in the middle shaft 9, the upper end and the lower end of the middle shaft 9 are respectively provided with a feeding hole 901 and a discharging hole 904 corresponding to the discharging cavity 903, the discharging holes 904 are communicated with the flow dividing cover 3, the flow dividing cover 3 is provided with a circle of discharging grooves 302, a space between the inner part of the flow dividing cover 3 and the middle shaft 9 is a dispersing cavity 301, the lower-layer stirrer 7 is provided with a circle of second stirring bent plate 701, the material facing surface of the second stirring bent plate 701 is inclined towards the middle stirrer 4, and the materials are pushed upwards through the second stirring bent plate 701;

the closing cap 11 is installed to the last port of reposition of redundant personnel cover 3, and closing cap 11 includes sealed bearing 1101 and ring cover 1101, and the height that highly is greater than the inner ring of sealed bearing 1101 upper outer ring, and ring cover 1101 sets up on the outer ring, seals off the port of reposition of redundant personnel cover 3 through closing cap 11, and middle part agitator 4 takes on the upper end of reposition of redundant personnel cover 3, and is specific, and the low end of first well section of thick bamboo 401 is pressed on ring cover 1101.

Further, two pairs of bottom rings 702 and circular rings 703 are arranged on the lower stirrer 7, the radius of the circular ring 703 is larger than that of the bottom ring 702, a circle is arranged between the upper bottom ring 702 and the lower bottom ring 703 of the second stirring bent plate 701, and the bottom edge of the second stirring bent plate 701 is erected on the circular ring 703, namely, a gap is reserved between the second stirring bent plate 701 and the bottom plate 2, so that the material in the lower stirrer 4 is not completely pushed upwards, and the lower stirrer is prevented from being stuck.

Further, the mixing drum 1 comprises a lower end with a ring seat 101, a bottom plate 2 is installed in the ring seat 101, a through hole 202 and a sliding groove 201 are formed in the middle of the bottom plate 2, and a bottom ring 702 and a circular ring 703 are fitted in the sliding groove 201.

Further, the upper stirrer 6 includes a first stirring curved plate 603, a first connecting ring 601 and an outer sliding ring 602, the first connecting ring 601 and the outer sliding ring 602 are arranged in pairs and are provided with two pairs, the first stirring curved plate 603 is arranged between the first connecting ring 601 and the outer sliding ring 602 in a loop, a sliding groove is formed in the first stirring curved plate 603, a support 8 is arranged between the two first connecting rings 601, the support 8 includes a second middle cylinder 802 and a support plate 801, the support plate 801 is provided with two ends respectively located at the second middle cylinder 802, the second middle cylinder 802 is sleeved on the middle shaft 9, a vertical groove 803 corresponding to the feed port 901 is formed in the second middle cylinder 802, preferably, a clamping strip 905 is arranged on the middle shaft 9, and a clamping groove corresponding to the clamping strip 905 is formed in the inner surface of the second middle cylinder 802, so that the upper stirrer 6 and the middle shaft do not rotate relatively.

A cover plate 5 is arranged in the stirring barrel 1, a feeding port 501 is formed in the cover plate 5, a discharging port is formed in the bottom of the stirring barrel 1, the cover plate 5 is used for plugging rising materials, the materials are made to enter a vertical groove 803 formed in the second middle barrel 802, and therefore the materials enter a feeding hole 901 formed in the middle shaft 9.

A high-fat membrane comprises the following substances in parts by weight: 2-3 parts of choline chloride, 0.3-0.4 part of sodium dodecyl sulfate, 3-4 parts of brassinolide, 2-3 parts of silicon dioxide, 7-8 parts of potassium fulvate, 60-64 parts of a thickening film-forming additive, 7-9 parts of monopotassium phosphate, 7-9 parts of composite trace and medium elements, 0.5-0.7 part of amine fresh fat and 4-6 parts of sodium salicylate.

Preferably, 2.5 parts of choline chloride, 0.35 part of sodium dodecyl sulfate, 3.5 parts of brassinolide, 2.5 parts of silicon dioxide, 7.55 parts of potassium fulvate, 62 parts of thickening film-forming additive, 8 parts of monopotassium phosphate, 8 parts of compound trace and medium elements, 0.6 part of diethyl aminoethyl hexanoate and 5 parts of sodium salicylate, wherein the content of effective substances of the brassinolide is about 0.10%.

A method for producing a high lipid film, comprising:

wherein the required raw materials need cold water for instant dissolution or wettable powder with the mesh number not less than 80 meshes,

mixing the light raw materials of sodium dodecyl sulfate, silicon dioxide and potassium fulvate to obtain the film thickening raw material, and stirring for 10-15 minutes. The stirring is selected to be at a constant speed and a low speed, and the rotating speed per minute is not more than 180 revolutions.

And (3) adding monopotassium phosphate and compound trace and medium elements into the mixed raw materials in the step (2), and stirring for 10-15 minutes. The stirring is selected to be at a constant speed and a low speed, and the rotating speed per minute is not more than 120 revolutions.

The remaining raw materials were added and stirred for 10 minutes. The stirring is selected to be at a constant speed and a low speed, and the rotating speed per minute is not more than 100 revolutions.

The mixture was allowed to stand for at least ten minutes after stirring was completed. And entering a packaging link.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (10)

1. An apparatus for producing a high-fat film, comprising:

the stirring device comprises a stirring drum (1), wherein the stirring drum (1) is provided with three layers of stirring areas, and an upper layer stirrer (6), a middle stirrer (4) and a lower layer stirrer (7) are arranged from a feeding port to a discharging port of the stirring drum (1);

a middle shaft (9) is installed in the mixing drum (1), a shunting cover (3) is arranged at the bottom of the middle shaft (9), a lower-layer stirrer (7) is installed on the shunting cover (3), a blanking cavity (903) is arranged in the middle shaft (9), a feeding hole (901) and a discharging hole (904) corresponding to the blanking cavity (903) are formed in the upper end and the lower end of the middle shaft (9), the discharging hole (904) is communicated with the shunting cover (3), a circle of discharging groove (302) is formed in the shunting cover (3), a circle of second mixing bent plate (701) is arranged on the lower-layer stirrer (7), and the material facing surface of the second mixing bent plate (701) inclines towards the middle stirrer (4);

the driver (10) is installed on the middle shaft (9), the inner ring of the middle stirrer (4) is sleeved on the driver (10), and the middle stirrer (4) is abutted against the upper end of the shunt cover (3).

2. A high fat membrane production apparatus as claimed in claim 2, wherein the upper port of the diversion cover (3) is provided with a cover (11), the cover (11) comprises a sealed bearing (1101) and a ring cover (1101), the height of the outer ring of the sealed bearing (1101) is greater than that of the inner ring, and the ring cover (1101) is arranged on the outer ring.

3. The production device of high fat films as claimed in claim 1 or 2, wherein the driver (10) comprises a collar (1004) and a driving wheel, two rings of toothed rings (1005) are arranged at the upper end and the lower end of the collar (1004), one ring of driving wheel is arranged on the collar (1004), one driving wheel comprises a second driving wheel (1003) and a first driving wheel (1001), the second driving wheel (1003) and the first driving wheel (1001) are connected through a connecting shaft (1002), the middle stirrer (4) comprises a first middle cylinder (401), an inner tooth surface is arranged in the first middle cylinder (401), the second driving wheel (1003) is respectively meshed with the toothed rings (1005) and the inner tooth surface, and the first driving wheel (1001) is respectively meshed with the toothed rings (1005) and the inner tooth surface.

4. The apparatus for producing high-fat membranes according to claim 3, wherein the middle agitator (4) further comprises an upper ring (403) and a lower ring (405), the upper ring (403) and the lower ring (405) are connected by a circle of support pillars (402), a row of agitation rods (404) is arranged between each support pillar (402) and the first middle cylinder (401), the agitation rods (404) are flat rods, and a port of the first middle cylinder (401) is provided with a pore plate which is sleeved on the middle shaft (9).

5. The apparatus for producing high-fat films according to claim 1, wherein the lower stirrer (7) has two pairs of bottom rings (702) and circular rings (703), the radius of the circular rings (703) is larger than that of the bottom rings (702), and the second stirring bent plate (701) is provided with one turn between the upper bottom ring (702) and the lower bottom ring (703).

6. The apparatus for producing high fat film according to claim 1, wherein the lower end of the mixing drum (1) has a ring seat (101), the ring seat (101) is provided with a bottom plate (2), the middle part of the bottom plate (2) has a through hole (202) and a chute (201), and the bottom ring (702) and the circular ring (703) are fitted in the chute (201).

7. The production device of high-fat membranes according to claim 1, wherein the upper layer stirrer (6) comprises a first stirring bent plate (603), a first connecting ring (601) and an outer sliding ring (602), the first connecting ring (601) and the outer sliding ring (602) are arranged in pairs and are provided with two pairs, the first stirring bent plate (603) is arranged between the first connecting ring (601) and the outer sliding ring (602) in a circle, a sliding groove is formed in the first stirring bent plate (603), a support (8) is arranged between the two first connecting rings (601), the support (8) comprises a second middle cylinder (802) and a support plate (801), the support plate (801) is provided with two vertical grooves (803) which are respectively located at two ends of the second middle cylinder (802), the second middle cylinder (802) is sleeved on the middle shaft (9), and the second middle cylinder (802) is provided with a vertical groove (803) corresponding to the feed inlet (901).

8. The apparatus for producing high-fat films according to claim 1, wherein a cover plate (5) is arranged in the mixing drum (1), the cover plate (5) is provided with a feeding port (501), and the bottom of the mixing drum (1) is provided with a discharging port.

9. The high lipid membrane according to claim 1, wherein the weight parts of each substance are as follows: 2-3 parts of choline chloride, 0.3-0.4 part of sodium dodecyl sulfate, 3-4 parts of brassinolide, 2-3 parts of silicon dioxide, 7-8 parts of potassium fulvate, 60-64 parts of a thickening film-forming additive, 7-9 parts of monopotassium phosphate, 7-9 parts of composite trace and medium elements, 0.5-0.7 part of amine fresh fat and 4-6 parts of sodium salicylate.

10. A method for producing a high-fat film, comprising:

mixing the light raw materials of sodium dodecyl sulfate, silicon dioxide and potassium fulvate to form a film thickening raw material, stirring for 10-15 minutes at a rotating speed of not more than 180 revolutions per minute;

adding potassium dihydrogen phosphate and compound trace and medium elements, stirring for 10-15 min at a rotation speed of not more than 120 rpm;

adding choline chloride, brassinolide, thickening film-forming additive, diethyl aminoethyl hexanoate and sodium salicylate, stirring for 10 minutes at a rotation speed of not more than 100 revolutions per minute;

the stirring was completed and left to stand for at least ten minutes.

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