CN115108189A - Amino acid powder save set - Google Patents

Abstract

The invention discloses an amino acid powder storage device which comprises a support frame, a self-gravity spiral material taking, packaging and storing mechanism, an electromagnetic gas gun wall cleaning and storing material cylinder and a Venturi feeding mechanism. The invention belongs to the technical field of storage devices, and particularly relates to an amino acid powder storage device; the invention develops an electromagnetic air cannon wall-cleaning storage charging barrel, creatively adopts the form of an air cannon to remove the amino acid powder remained on the wall of an amino acid storage charging barrel, and when a rotating arm rotates, electromagnetic telescopic air cannons distributed on two sides of the rotating arm are started to remove the adhered amino acid powder; a self-gravity spiral material taking, packaging and storing mechanism is developed, Hooke's law and weighing are creatively combined, when the amino acid powder reaches a certain weight, an inverted spring assembly is compressed, a spring is shortened to push a slide rheostat, the current is increased, the magnetism of an electromagnetic coil is enhanced, a self-reset conductive electromagnetic sheet is attracted and close to the electromagnetic coil, a circuit is disconnected, a vertical electric push rod retracts, and quantitative supplement of the amino acid powder is achieved.

Description

Amino acid powder save set

Technical Field

The invention belongs to the technical field of storage devices, and particularly relates to an amino acid powder storage device.

Background

The amino acid powder is prepared by using leftovers of various sea fish processing factories and boiled slurry water as raw materials, performing microbial fermentation and acid-base hydrolysis treatment, and then performing spray drying.

The amino acid powder is easy to dissolve in water, has moisture absorption, the moisture absorption is enhanced along with the increase of the content of amino acid, the quality of the amino acid powder after moisture absorption is reduced, the traditional amino acid powder is placed in a barrel to be taken at any time, the environment for placing the amino acid powder is mostly an open industrial factory building, the amino acid powder is extremely easy to deliquesce, the amino acid powder after moisture absorption is extremely easy to adhere to a device, the barrel cover needs to be opened when the amino acid is taken, but water molecules enter the barrel when the cover is opened, the amino acid powder absorbs water and deliquesces along with the water, and the amino acid powder after deliquescence is adhered to the barrel wall; when needs quantitative ratio amino acid powder, the staving need be reopened to the weight of weighing amino acid powder at every turn, has increased the operating duration of taking amino acid powder undoubtedly for the amino acid deliquescence situation is more serious, synthesizes above factor and has researched and developed the dampproofing save set of amino acid powder, with the industrial production that is applicable to large batch.

Disclosure of Invention

Aiming at the situation and overcoming the defects of the prior art, the invention provides an amino acid powder storage device, which develops an electromagnetic air cannon wall cleaning storage charging barrel aiming at the problem that water molecules enter the barrel when the cover is opened and the amino acid powder absorbs water and deliquesces along with the water molecules, creatively adopts the form of an air cannon to clean the amino acid powder remained on the wall of the amino acid storage charging barrel, and when a rotating arm rotates, electromagnetic telescopic air cannons distributed on two sides of the rotating arm are started to clean the adhered amino acid powder; when the amino acid powder needs to be proportioned quantitatively, the barrel body needs to be opened again when the weight of the amino acid powder is weighed every time, the working time for taking the amino acid powder is prolonged undoubtedly, the weight increasing problem of the deliquescence condition of the amino acid is solved, a self-gravity spiral material taking, packaging and storing mechanism is developed, Hooke's law and weighing are combined creatively, when the amino acid powder reaches a certain weight, a compression inversion spring assembly is compressed, a compression spring rheostat is shortened, the current is increased, the magnetism of an electromagnetic coil is enhanced, a self-resetting conductive electromagnetic sheet is attracted, the self-resetting conductive electromagnetic sheet is close to the electromagnetic coil, the circuit is disconnected, a vertical electric push rod retracts, and therefore the amino acid powder is supplemented.

The technical scheme adopted by the invention is as follows: the invention provides an amino acid powder storage device which comprises a support frame, a self-gravity spiral material taking, packaging and storing mechanism, an electromagnetic gas gun wall cleaning storage material cylinder and a Venturi feeding mechanism, wherein the self-gravity spiral material taking, packaging and storing mechanism is arranged on the support frame, the electromagnetic gas gun wall cleaning storage material cylinder is arranged above the self-gravity spiral material taking, packaging and storing mechanism, the electromagnetic gas gun wall cleaning storage material cylinder is fixedly arranged on the support frame, and the Venturi feeding mechanism is fixedly arranged on the upper wall of the electromagnetic gas gun wall cleaning storage material cylinder.

In order to achieve the purpose, the support frame comprises a base, side frames and a controller, wherein the side frames are fixedly arranged on the base, and the controller is arranged in the middle of the side frames.

For reaching above-mentioned purpose, get material packing box and horizontal electric putter including protecting sheathing, self-gravity conveying screw, vertical electric putter, inversion spring assembly, standard and get material packing carton and horizontal electric putter from the gravity spiral, protecting sheathing is fixed to be located on the base, on self-gravity conveying screw is fixed to be located the base, and self-gravity conveying screw upper portion is equipped with puts the thing platform, vertical electric putter is fixed to be located and puts thing platform middle part, it locates vertical electric putter top to invert spring assembly, inverts and is equipped with the spring apron on the spring assembly, the material packing carton is located on the spring apron to the standard, horizontal electric putter is located and is put thing platform lateral wall, and horizontal electric putter is used for the propelling movement standard to get the material packing carton.

Further, protective housing includes shell body, packing carton entry, packing carton export, clean wall start-stop switch, links up interface and barrier plate, shell body is fixed to be located on the base, shell body upper portion lateral wall is located to the packing carton entry, shell body lower part lateral wall is located in the packing carton export, and packing carton entry offside is located to the packing carton export, clean wall start-stop switch locates the shell body lateral wall, and clean wall start-stop switch locates packing carton entry homonymy, the shell body upper wall is located to the interface that links up, the barrier plate is fixed to be located packing carton export below, and the barrier plate is used for blockking to get the packing carton from the standard of eminence cunning down.

Further, from gravity conveying screw including conveying screw support body, speed reduction axle, put thing platform and slope, conveying screw support body is fixed to be located on the base, the speed reduction axle is located on the conveying screw support body, put the thing platform and locate screw support body top, put and be equipped with the recess on the thing platform, the slope is located and is put one side of keeping away from horizontal electric putter on the thing platform, and the slope is used for getting the material packing carton steady slip to the speed reduction epaxially with the standard.

Further, the inverted spring assembly comprises a compression spring rheostat, a spring cover plate, a self-resetting conductive electromagnetic sheet, a power supply, an electromagnetic coil and a transverse push switch, the compression spring rheostat is fixedly arranged on the upper wall of the vertical electric push rod, the spring cover plate is arranged above the compression spring rheostat, the self-resetting conductive electromagnetic sheet is rotatably arranged on the spring cover plate, the power supply is fixedly arranged on the side wall of the groove of the object placing table, the electromagnetic coil is fixedly arranged on the bottom wall of the spring cover plate, the transverse push switch is arranged on the upper wall of the vertical electric push rod, the transverse push switch is arranged below the spring cover plate, when the amino acid powder reaches a certain weight, the inverted spring assembly is compressed, the compression spring rheostat is shortened, the resistance is reduced, the current is increased, the magnetism of the electromagnetic coil is enhanced, the self-resetting conductive electromagnetic sheet is attracted, the self-resetting conductive electromagnetic sheet is close to the electromagnetic coil, the main circuit is disconnected, and the vertical electric push rod retracts to the original position, the supplement of amino acid powder is completed, the spring cover plate presses the transverse pushing switch downwards, the transverse electric push rod is opened, when the vertical electric push rod returns to the original position, the transverse electric push rod pushes the standard material taking packaging box to the slope, and the standard material taking packaging box slides downwards under the action of gravity.

The compression spring rheostat comprises a conductive rod and a resistance spring, the conductive rod is fixedly arranged on the lower wall of the spring cover plate, the resistance spring is arranged on the lower wall of the spring cover plate, the conductive rod penetrates through the resistance spring, and when the resistance spring is compressed, the conductive rod slides downwards, so that the resistance value of a circuit is reduced.

Further, the standard material taking packaging box comprises a material taking box, a buffer spring piece, a material taking interface and a material taking groove, the material taking box is arranged on the spring cover plate, the buffer spring piece is fixedly arranged on one side, away from the slope, of the material taking box, the material taking interface is arranged on the upper wall of the material taking box, the material taking groove is communicated with one side of the material taking box, and the material taking groove is arranged on the opposite side of the buffer spring piece.

Further, the speed reduction axle includes from gravity roller, seal box and speed reduction turbine, from the rotation of gravity roller locate on the transport screw frame body, the seal box is fixed to be located transport screw frame body lateral wall, from the rotation of gravity roller locate the seal box lateral wall, speed reduction turbine locates dead weight roller tip, and in speed reduction turbine located the seal box, be full of non-Newton fluid in the seal box, drive speed reduction turbine when rotating from the gravity roller and rotate, speed reduction turbine stirs non-Newton cow body, reaches and prevents that the standard from getting the purpose that the material packing carton is too fast gliding.

In order to achieve the purpose, the electromagnetic gas cannon wall cleaning storage charging barrel comprises an amino acid powder storage charging barrel, a rotary gas cannon wall cleaning mechanism, a reducing diameter charging barrel and a discharging mechanism, wherein the amino acid powder storage charging barrel is fixedly arranged on a supporting frame, the rotary gas cannon wall cleaning mechanism is arranged on the amino acid powder storage charging barrel, the reducing diameter charging barrel is fixedly arranged at the bottom of the amino acid powder storage charging barrel, and the discharging mechanism is arranged at the bottom of the reducing diameter charging barrel.

Further, rotatory gas big gun clean wall mechanism includes rotary driving motor, rotation axis, swinging boom and the flexible gas big gun of electromagnetism, rotary driving motor locates amino acid powder and deposits the feed cylinder upper wall, the rotation axis is located on rotary driving motor's the output shaft, the swinging boom is fixed to be located on the rotation axis, swinging boom branch house rotation axis both sides, the flexible gas big gun of electromagnetism is located the one end of keeping away from the rotation axis on the swinging boom, and the flexible gas big gun of electromagnetism is used for producing the gas shock of transient state, and the gas shock is deposited the feed cylinder inner wall at amino acid powder, clears away the amino acid powder of adhesion on amino acid powder deposits the feed cylinder inner wall.

Wherein, the flexible air cannon of electromagnetism includes air cannon shell, reducing air cock and electromagnetism telescopic link, the air cannon shell is located in the swinging boom, the reducing air cock is located one side that air cannon shell tip is close to amino acid powder and deposits the feed cylinder inner wall, inside the air cannon shell is placed in to the electromagnetism telescopic link in, the reciprocal flexible compressed air of telescopic link when the electromagnetism telescopic link moves, the high-speed efflux air of blowout in the reducing air cock, high-speed efflux air impact is on amino acid powder, and amino acid powder is driven from amino acid powder and is deposited the feed cylinder inner wall and clear away, and the amino acid powder after clearing away falls back convergent diameter feed cylinder.

Further, drop feed mechanism includes that amino acid powder keeps apart a section of thick bamboo, amino acid powder discharge gate, sealed cap, slider and ejection of compact funnel of keeping apart, amino acid powder keeps apart a fixed tapered diameter feed cylinder below of locating, tapered diameter feed cylinder bottom lateral wall is located to amino acid powder discharge gate, sealed cap fixed locating of keeping apart of amino acid powder top, sealed cap and amino acid powder of keeping apart coaxial setting of a section of thick bamboo, inside the sealed cap that keeps apart was located in slider slip, the slider cross-section set up for T shape, ejection of compact funnel is fixed to be located amino acid powder and keeps apart a diapire.

The sliding part comprises a sliding body and a jacking rod, the sliding body is arranged inside the sealed isolation cap in a sliding mode, the jacking rod is arranged on the side wall of the amino acid powder isolation cylinder in a sliding mode, and the jacking rod penetrates through the amino acid powder isolation cylinder and is fixedly arranged on the flange of the sliding body.

In order to achieve the purpose, the Venturi feeding mechanism comprises a supporting seat, a supporting plate, a driving motor, a fan, a reducing pipe, an expanding pipe, a pressure-reducing powder sucking opening, a powder sucking pipe, an amino acid feeding pipe and a side wall hole, wherein the supporting seat is fixedly arranged on the upper wall of the amino acid powder storage cylinder, the supporting seat is divided at two sides of the rotary driving motor, the supporting plate is fixedly arranged on the supporting seat, the driving motor is arranged on the supporting plate, the fan is arranged on an output shaft of the driving motor, the reducing pipe is fixedly arranged on one side of the fan, the reducing pipe is fixedly arranged on the supporting plate, the expanding pipe is fixedly arranged on one side of the reducing pipe far away from the fan, the pressure-reducing powder sucking opening is fixedly arranged on the outer wall of the reducing pipe and the expanding pipe far away from the supporting plate, the pressure-reducing powder sucking opening is communicated with the reducing pipe and the expanding pipe, the powder sucking pipe is arranged on the pressure-reducing powder sucking opening, the amino acid feeding pipe is communicated with the upper wall of the amino acid powder storage cylinder, the side wall hole is arranged on the side wall of the driving motor, the fan is driven to rotate when the driving motor is started, airflow stirred by the fan flows to the expanding pipe from the reducing pipe, the flow speed of the airflow is increased in the process that the reducing pipe flows to the expanding pipe, an air pressure difference is formed at the pressure reduction powder suction opening, the air pressure difference is enough to suck amino acid powder, and the sucked amino acid powder flows to the amino acid feeding pipe along with the airflow so as to be conveyed into the amino acid powder storage barrel.

The invention with the structure has the following beneficial effects:

(1) the scheme provides an amino acid powder storage device, a Venturi feeding mechanism realizes automatic feeding and storage of amino acid powder, a driving motor drives a fan to rotate when being started, airflow stirred by the fan flows to an expanding pipe from a reducing pipe, the flow speed of the airflow is increased in the process that the reducing pipe flows to the expanding pipe, an air pressure difference is formed at a pressure reduction powder suction port and is enough to suck the amino acid powder, and the sucked amino acid powder flows to an amino acid feeding pipe along with the airflow so as to be conveyed into an amino acid powder storage barrel, so that automatic feeding, sealing and storage of the amino acid powder are realized;

(2) the scheme provides an amino acid powder storage device, the cleaning wall storage material cylinder of an electromagnetic air gun realizes the removal of amino acid powder on the inner wall of the amino acid powder storage material cylinder, when an electromagnetic telescopic rod acts, the telescopic rod stretches and compresses air in a reciprocating manner, high-speed jet air is sprayed out of a reducing air nozzle and impacts on the amino acid powder, the amino acid powder is removed from the inner wall of the amino acid powder storage material cylinder, and the removed amino acid powder falls back to the material cylinder with the reduced diameter, so that the aim of removing the amino acid powder on the inner wall of the amino acid powder storage material cylinder is fulfilled;

(3) the scheme provides an amino acid powder storage device, a self-gravity spiral material taking, packaging and storing mechanism realizes the standardized packaging and taking of amino acid powder, the Hooke's law and weighing are creatively combined, when the amino acid powder reaches a certain weight, a spring assembly is compressed and inverted, when a spring is shortened to a designed length, a vertical electric push rod switch is extruded, the vertical electric push rod retracts, so that the quantitative supplement of the amino acid powder is completed, a non-Newtonian fluid and a speed reducing function are combined through the arrangement of a speed reducing shaft, and the stable falling of a standard material taking and packaging box is realized;

(4) compared with the traditional amino acid powder storage device, the amino acid powder storage device provided by the invention is in accordance with the mode of mostly adopting quantitative proportion for taking amino acid powder in the modern processing industry, the amino acid powder is stored in a closed container to prevent deliquescence by adopting a quantitative packaging method, then the amino acid powder is stored in a standard material taking packaging box, and the standard material taking packaging box is taken out when being taken, so that the problem that the amino acid powder is deliquesced because a barrel cover is frequently opened when the amino acid powder is taken for multiple times is solved.

Drawings

FIG. 1 is a schematic diagram of the general structure of an amino acid powder storage device provided by the present invention;

FIG. 2 is a front view of an amino acid powder storage device provided by the present invention;

FIG. 3 is a left side view of an amino acid powder storage device according to the present invention;

FIG. 4 is a perspective view of a protective housing of an amino acid powder storage device according to the present invention;

FIG. 5 is a diagram of the installation position of the self-gravity conveying screw of the amino acid powder storage device relative to a standard material taking and packaging box according to the present invention;

FIG. 6 is an enlarged view of portion A of FIG. 5;

FIG. 7 is a schematic view of the installation position of the lateral push switch of the amino acid powder storage device relative to the compression spring varistor according to the present invention;

FIG. 8 is a schematic view of the installation position of a lateral push switch of the amino acid powder storage device relative to a self-gravity conveying screw according to the present invention;

FIG. 9 is a sectional view of a deceleration shaft structure of an amino acid powder storage device according to the present invention;

FIG. 10 is a sectional view of an electromagnetic telescopic air cannon structure of an amino acid powder storage device provided by the invention;

fig. 11 is a top view of a standard material-taking packaging box of the amino acid powder storage device provided by the invention;

FIG. 12 is a cross-sectional view of a standard dispensing package for an amino acid powder holding device according to the present invention;

FIG. 13 is a schematic diagram of the general structure of a standard dispensing packaging box of an amino acid powder storage device according to the present invention;

FIG. 14 is a schematic view of the installation position of the rotary air gun wall cleaning mechanism of the amino acid powder storage device provided by the invention;

FIG. 15 is a schematic view of the mounting position of a discharging mechanism of an amino acid powder storage device according to the present invention;

FIG. 16 is an enlarged view of portion B of FIG. 15;

FIG. 17 is a schematic structural view of a sliding member of the amino acid powder storage device according to the present invention;

FIG. 18 is a schematic view of the installation position of a venturi feeding mechanism of an amino acid powder storage device provided by the invention;

FIG. 19 is a detailed view of the structure of a Venturi feeding mechanism of the amino acid powder storage device provided by the invention;

fig. 20 is a circuit diagram of a start-stop control circuit of a vertical electric push rod of the amino acid powder storage device provided by the invention.

The device comprises a support frame 1, a support frame 2, a self-gravity spiral material taking, packaging and storing mechanism 3, an electromagnetic gas blasting wall cleaning and storing material barrel 4, a Venturi feeding mechanism 11, a base 12, a side frame 13, a controller 21, a protective shell 22, a self-gravity conveying spiral 23, a vertical electric push rod 24, an inverted spring assembly 25, a standard material taking and packaging box 26, a transverse electric push rod 211, a shell body 212, a packaging box inlet 213, a packaging box outlet 214, a wall cleaning start-stop switch 215, an upper connecting port 216, a blocking plate 221, a conveying spiral frame body 222, a speed reducing shaft 223, a placing platform 224, a slope 241, a compression spring rheostat 242, a spring cover plate, a spring 243, a self-resetting conductive electromagnetic sheet 244, a power supply, a 245, an electromagnetic coil 246, a transverse push switch 2411, a conductive rod 2412, a resistance spring 251, a material taking box 252, a self-gravity spiral material taking switch, a self-gravity spiral material taking and a self-resetting conductive electromagnetic sheet, a power supply switch, a self-positioning conductive electromagnetic coil switch, a self-positioning conductive electromagnetic sheet, a power supply switch, a power supply, a power supply, a power supply power, The device comprises a buffer spring leaf, 253, a material taking interface, 254, a material taking buckle groove, 2221, a self-gravity roller shaft, 2222, a sealing box, 2223, a speed reducing turbine, 31, an amino acid powder storage cylinder, 32, a rotary air gun wall cleaning mechanism, 33, a tapered diameter cylinder, 34, a discharging mechanism, 321, a rotary driving motor, 322, a rotating shaft, 323, a rotating arm, 324, an electromagnetic telescopic air gun, 3241, an air gun shell, 3242, a reducing air nozzle, 3243, an electromagnetic telescopic rod, 341, an amino acid powder isolating cylinder, 342, an amino acid powder discharging port, 343, a sealing isolating cap, 344, a sliding piece, 345, a discharging funnel, 3441, a sliding body, 3442, a jacking rod, 41, a supporting seat, 42, a supporting plate, 43, a driving motor, 44, a fan, 45, a reducing diameter pipe, 46, an expanding pipe, 47, a pressure reducing powder sucking port, 48, a powder sucking pipe, 49, an amino acid pipe, 410 and a side wall hole.

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

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 "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus should not be construed as limiting the present invention.

As shown in fig. 1-2, the invention provides an amino acid powder storage device, which comprises a support frame 1, a self-gravity spiral material taking, packaging and storing mechanism 2, an electromagnetic gas gun wall cleaning and storing material cylinder 3 and a venturi feeding mechanism 4, wherein the self-gravity spiral material taking, packaging and storing mechanism 2 is arranged on the support frame 1, the electromagnetic gas gun wall cleaning and storing material cylinder 3 is arranged above the self-gravity spiral material taking, packaging and storing mechanism 2, the electromagnetic gas gun wall cleaning and storing material cylinder 3 is fixedly arranged on the support frame 1, and the venturi feeding mechanism 4 is fixedly arranged on the upper wall of the electromagnetic gas gun wall cleaning and storing material cylinder 3.

As shown in fig. 1-3, the supporting frame 1 includes a base 11, a side frame 12 and a controller 13, the side frame 12 is fixed on the base 11, and the controller 13 is disposed in the middle of the side frame 12.

As shown in fig. 4-8, the material-taking, packaging and storing mechanism 2 includes a protective casing 21, a self-gravity conveying screw 22, a vertical electric pushing rod 23, an inverted spring assembly 24, a standard material-taking packaging box 25 and a horizontal electric pushing rod 26, the protective casing 21 is fixedly arranged on the base 11, the self-gravity conveying screw 22 is fixedly arranged on the base 11, a material-placing table 223 is arranged on the upper portion of the self-gravity conveying screw 22, the vertical electric pushing rod 23 is fixedly arranged in the middle of the material-placing table 223, the inverted spring assembly 24 is arranged above the vertical electric pushing rod 23, a spring cover plate 242 is arranged on the inverted spring assembly 24, the standard material-taking packaging box 25 is arranged on the spring cover plate 242, the horizontal electric pushing rod 26 is arranged on the side wall of the material-placing table 223, and the horizontal electric pushing rod 26 is used for pushing the standard material-taking packaging box 25.

As shown in fig. 4, the protective housing 21 includes a housing body 211, a packing box inlet 212, a packing box outlet 213, a clean wall start/stop switch 214, a top interface 215 and a blocking plate 216, the housing body 211 is fixed on the base 11, the packing box inlet 212 is arranged on the upper side wall of the housing body 211, the packing box outlet 213 is arranged on the lower side wall of the housing body 211, the packing box outlet 213 is arranged on the opposite side wall of the packing box inlet 212, the clean wall start/stop switch 214 is arranged on the side wall of the housing body 211, the clean wall start/stop switch 214 is arranged on the same side as the packing box inlet 212, the top interface 215 is arranged on the upper wall of the housing body 211, the blocking plate 216 is fixed below the packing box outlet 213, and the blocking plate 216 is used for blocking the standard material-taking packing box 25 sliding from a high place.

As shown in fig. 5-6, the self-gravity conveying screw 22 includes a conveying screw frame body 221, a decelerating shaft 222, a placing table 223 and a slope 224, the conveying screw frame body 221 is fixedly disposed on the base 11, the decelerating shaft 222 is disposed on the conveying screw frame body 221, the placing table 223 is disposed above the conveying screw frame body, the slope 224 is disposed on one side of the placing table 223 far away from the transverse electric push rod 26, and the slope 224 is used for smoothly sliding the standard packing box taking material 25 onto the decelerating shaft 222.

As shown in fig. 6-8 and 20, the inverted spring assembly 24 includes a compression spring varistor 241, a spring cover plate 242, a self-resetting conductive electromagnetic plate 243, a power supply 244, an electromagnetic coil 245 and a lateral push switch 246, the compression spring varistor 241 is fixedly disposed on the upper wall of the vertical electric push rod 23, the spring cover plate 242 is disposed above the compression spring varistor 241, the self-resetting conductive electromagnetic plate 243 is rotatably disposed on the spring cover plate 242, the power supply 244 is fixedly disposed on the side wall of the groove of the object placing table, the electromagnetic coil 245 is fixedly disposed on the bottom wall of the spring cover plate 242, the lateral push switch 246 is disposed on the upper wall of the vertical electric push rod 23, the lateral push switch 246 is disposed below the spring cover plate 242, when the amino acid powder reaches a certain weight, the inverted spring assembly 24 is compressed, the compression spring varistor 241 shortens, the resistance decreases, the current increases, the electromagnetic coil 245 magnetically increases, and attracts the self-resetting conductive electromagnetic plate 243, the self-resetting conductive electromagnetic sheet 243 is close to the electromagnetic coil 245, the main circuit is disconnected, the vertical electric push rod 23 retracts to the original position, amino acid powder is supplemented, the spring cover plate 242 presses the transverse push switch 246 downwards, the transverse electric push rod 26 is opened, when the vertical electric push rod 23 returns to the original position, the transverse electric push rod 26 pushes the standard material taking packaging box 25 to the slope 224, and the standard material taking packaging box 25 slides downwards under the action of gravity.

As shown in fig. 20, the compression spring varistor 241 includes a conductive rod 2411 and a resistance spring 2412, the conductive rod 2411 is fixedly disposed on the lower wall of the spring cover 242, the resistance spring 2412 is disposed on the lower wall of the spring cover 242, the conductive rod 2411 passes through the resistance spring 2412, when the resistance spring 2412 is compressed, the conductive rod 2411 slides down, and the circuit resistance value is reduced.

As shown in fig. 11-13, the standard material taking package box 25 includes a material taking box 251, a buffer spring plate 252, a material taking interface 253 and a material taking groove 254, wherein the material taking box 251 is disposed on the spring cover 242, the buffer spring plate 252 is fixedly disposed on one side of the material taking box 251 away from the slope 224, the material taking interface 253 is disposed on the upper wall of the material taking box 251, the material taking groove 254 is disposed on one side of the material taking box 251, and the material taking groove 254 is disposed on the opposite side of the buffer spring plate 252.

As shown in fig. 9, the speed reducing shaft 222 includes a self-gravity roller 2221, a sealing box 2222 and a speed reducing turbine 2223, the self-gravity roller 2221 is rotatably disposed on the conveying spiral frame body 221, the sealing box 2222 is fixedly disposed on the side wall of the conveying spiral frame body 221, the self-gravity roller 2221 is rotatably disposed on the side wall of the sealing box 2222, the speed reducing turbine 2223 is disposed at the end of the self-gravity roller 2221, the speed reducing turbine 2223 is disposed in the sealing box 2222, the sealing box 2222 is filled with non-newton fluid, the speed reducing turbine 2223 is driven to rotate when the self-gravity roller 2221 rotates, the speed reducing turbine 2223 stirs the non-newton cows, and the purpose of preventing the standard material taking packaging box 25 from sliding too fast is achieved.

As shown in fig. 14 and 16, the electromagnetic gas cannon wall cleaning storage cylinder 3 includes an amino acid powder storage cylinder 31, a rotary gas cannon wall cleaning mechanism 32, a tapered diameter cylinder 33 and a discharging mechanism 34, wherein the amino acid powder storage cylinder 31 is fixedly arranged on the support frame 1, the rotary gas cannon wall cleaning mechanism 32 is arranged on the amino acid powder storage cylinder 31, the tapered diameter cylinder 33 is fixedly arranged at the bottom of the amino acid powder storage cylinder 31, and the discharging mechanism 34 is arranged at the bottom of the tapered diameter cylinder 33.

As shown in fig. 14, the wall cleaning mechanism 32 of the rotary air cannon comprises a rotary driving motor 321, a rotary shaft 322, a rotary arm 323 and an electromagnetic telescopic air cannon 324, wherein the rotary driving motor 321 is arranged on the upper wall of the amino acid powder storage cylinder 31, the rotary shaft 322 is arranged on the output shaft of the rotary driving motor 321, the rotary arm 323 is fixedly arranged on the rotary shaft 322, the rotary arm 323 is arranged at two sides of the rotary shaft 322, the electromagnetic telescopic air cannon 324 is arranged at one end of the rotary arm 323 far away from the rotary shaft 322, the electromagnetic telescopic air cannon 324 is used for generating transient gas impact, and when the gas impacts on the amino acid powder storage cylinder 31, the amino acid powder adhered on the inner wall of the amino acid powder storage cylinder 31 is cleaned.

As shown in fig. 16, electromagnetism flexible air cannon 324 includes air cannon shell 3241, reducing air cock 3242 and electromagnetism telescopic link 3243, air cannon shell 3241 is located in the swinging boom 323, one side that the end of reducing air cock 3242 is close to amino acid powder storage cylinder 31 inner wall is located to air cannon shell 3241, place inside air cannon shell 3241 in electromagnetism telescopic link 3243, be equipped with the telescopic link on the electromagnetism telescopic link 3243, the reciprocal flexible compressed air of telescopic link when electromagnetism telescopic link 3243 acts, high-speed efflux air of blowout in the reducing air cock 3242, high-speed efflux air strikes on amino acid powder, and amino acid powder is clear away from amino acid powder storage cylinder 31 inner wall, and amino acid powder after the clearance falls back to reducing diameter feed cylinder 33.

As shown in fig. 15-16, the discharging mechanism 34 includes an amino acid powder isolating cylinder 341, an amino acid powder discharging port 342, a sealing isolating cap 343, a sliding member 344 and a discharging funnel 345, the amino acid powder isolating cylinder 341 is fixedly disposed below the tapered diameter cylinder 33, the amino acid powder discharging port 342 is disposed on the bottom side wall of the tapered diameter cylinder 33, the sealing isolating cap 343 is fixedly disposed above the amino acid powder isolating cylinder 341, the sealing isolating cap 343 and the amino acid powder isolating cylinder 341 are coaxially disposed, the sliding member 344 is slidably disposed inside the sealing isolating cap 343, the cross section of the sliding member 344 is in a T-shaped configuration, and the discharging funnel 345 is fixedly disposed on the bottom wall of the amino acid powder isolating cylinder 341.

As shown in fig. 17, the sliding member 344 includes a sliding body 3441 and a jacking rod 3442, the sliding body 3441 is slidably disposed inside the sealing isolation cap 343, the jacking rod 3442 is slidably disposed on the side wall of the amino acid powder isolation cylinder 341, and the jacking rod 3442 is fixedly disposed on the flange of the sliding body 3441 through the amino acid powder isolation cylinder 341.

As shown in fig. 18-19, the venturi feeding mechanism 4 includes a supporting base 41, a supporting plate 42, a driving motor 43, a fan 44, a reducing pipe 45, an expanding pipe 46, a pressure-reducing powder-sucking port 47, a powder-sucking pipe 48, an amino acid feeding pipe 49 and a side wall hole 410, the supporting base 41 is fixed on the upper wall of the amino acid powder storage barrel, the supporting base 41 is disposed on both sides of the rotating driving motor 43, the supporting plate 42 is fixed on the supporting base 41, the driving motor 43 is disposed on the supporting plate 42, the driving motor 43 is electrically connected to the wall-cleaning start-stop switch 214, the fan 44 is disposed on the output shaft of the driving motor 43, the reducing pipe 45 is fixed on one side of the fan 44, the reducing pipe 45 is fixed on the supporting plate 42, the expanding pipe 46 is fixed on the side of the reducing pipe 45 far away from the fan 44, the pressure-reducing powder-sucking port 47 is fixed on the outer walls of the expanding pipe 45 and the expanding pipe 46 far away from the supporting plate 42, the pressure-reducing powder-sucking port 47 is arranged on the reducing pipe 45 and the expanding pipe 46 in a penetrating manner, the powder-sucking pipe 48 is arranged on the pressure-reducing powder-sucking port 47, the amino acid feeding pipe 49 is fixedly arranged on the upper wall of the amino acid powder storage cylinder 31 in a penetrating manner, the side wall hole 410 is arranged on the side wall of the driving motor 43, the driving motor 43 is started to drive the fan 44 to rotate, the airflow stirred by the fan 44 flows from the reducing pipe 45 to the expanding pipe 46, the flow speed of the airflow is increased in the process that the reducing pipe 45 flows to the expanding pipe 46, an air pressure difference is formed at the pressure-reducing powder-sucking port 47 and is enough to suck the amino acid powder, and the sucked amino acid powder flows to the amino acid feeding pipe 49 along with the airflow so as to be conveyed to the amino acid powder storage cylinder 31.

When the amino acid powder storage barrel is used, firstly, amino acid powder is filled into the amino acid powder storage barrel 31, specifically, the powder suction pipe 48 is inserted into powder to be absorbed, the wall cleaning start-stop switch 214 is turned on, the driving motor 43 drives the fan 44 to rotate when turned on, airflow stirred by the fan 44 flows to the expanding pipe 46 from the reducing pipe 45, the flow speed of the airflow is increased in the process that the reducing pipe 45 flows to the expanding pipe 46, an air pressure difference is formed at the pressure reduction powder suction port 47 and is enough to suck the amino acid powder, and the sucked amino acid powder flows to the amino acid feeding pipe 49 along with the airflow so as to be conveyed into the amino acid powder storage barrel 31; if the amino acid powder is to be taken, firstly, the standard material taking packaging box 25 is scratched into the object placing table 223 from the packaging box inlet 212, the vertical electric push rod 23 is electrified and lifted due to the fact that the standard material taking packaging box 25 compresses the inverted spring assembly 24, specifically, the self-reset conductive electromagnetic sheet 243 is shortened, the circuit resistance is reduced, the current is increased, when the circuit voltage reaches the threshold voltage of the conduction of the diode, the circuit is connected, the electric push rod 23 is lifted to the discharging hopper 345, the spring cover plate 242 lifts the jacking rod 3442, the sliding piece slides and lifts in the sealed isolation cap 343, the amino acid powder leaks from the amino acid powder discharging port 342 and then enters the discharging hopper 345, the amino acid powder enters the standard material taking packaging box 25 from the discharging hopper 345, when the amino acid powder in the standard material taking packaging box 25 is filled to a certain weight, the compression spring rheostat 241 is compressed to a set value, the circuit current is increased, the magnetism of the electromagnetic coil 245 is enhanced, the electromagnetic coil 245 adsorbs the self-resetting conductive electromagnetic sheet 243, the self-resetting conductive electromagnetic sheet 243 slides in the direction of approaching the electromagnetic coil 245, the main circuit is powered off, the vertical electric push rod 23 retracts to the original position, when the vertical electric push rod 23 returns to the original position, the horizontal electric push rod 26 pushes the standard material taking packaging box 25 to the slope 224, the standard material taking packaging box 25 slides downwards under the action of gravity, and when the standard material taking packaging box 25 slides downwards to the packaging box outlet 213, a manufacturer takes away the standard material taking packaging box 25.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

The present invention and its embodiments have been described above, and the description is not intended to be limiting, and the drawings are only one embodiment of the present invention, and the actual structure is not limited thereto. In summary, those skilled in the art should appreciate that they can readily use the disclosed conception and specific embodiments as a basis for designing or modifying other structures for carrying out the same purposes of the present invention without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. The utility model provides an amino acid powder save set which characterized in that: comprises a support frame (1), a self-gravity spiral material taking, packaging and storing mechanism (2), an electromagnetic gas gun wall cleaning and storing material cylinder (3) and a Venturi feeding mechanism (4), wherein the self-gravity spiral material taking, packaging and storing mechanism (2) is arranged on the support frame (1), the electromagnetic gas gun wall cleaning and storing material cylinder (3) is arranged above the self-gravity spiral material taking, packaging and storing mechanism (2), the electromagnetic gas gun wall cleaning and storing material cylinder (3) is fixedly arranged on the support frame (1), the Venturi feeding mechanism (4) is fixedly arranged on the upper wall of the electromagnetic gas gun wall cleaning and storing material cylinder (3), the Venturi feeding mechanism (4) comprises a support seat (41), a support plate (42), a driving motor (43), a fan (44), a reducing pipe (45), an expanding pipe (46), a pressure reducing powder sucking port (47), a powder sucking pipe (48), an amino acid feeding pipe (49) and a side wall hole (410), the supporting seat (41) is fixedly arranged on the upper wall of the electromagnetic air cannon wall cleaning storage charging barrel (3), the supporting plate (42) is fixedly arranged on the supporting seat (41), the driving motor (43) is arranged on the supporting plate (42), the driving motor (43) is electrically connected with the wall cleaning start-stop switch (214), the fan (44) is arranged on the output shaft of the driving motor (43), the reducing pipe (45) is fixedly arranged on one side of the fan (44), the reducing pipe (45) is fixedly arranged on the supporting plate (42), the expanding pipe (46) is fixedly arranged on one side of the reducing pipe (45) far away from the fan (44), the pressure reducing powder suction port (47) is fixedly arranged on the outer wall of the reducing pipe (45) far away from the supporting plate (42) and the expanding pipe (46), the pressure reducing powder suction port (47) is communicated on the reducing pipe (45) and the expanding pipe (46), and the powder suction pipe (48) is arranged on the pressure reducing powder suction port (47), the amino acid feeding pipe (49) is fixedly arranged on the upper wall of the amino acid powder storage barrel (31) in a penetrating manner, and the side wall hole (410) is arranged on the side wall of the driving motor (43).

2. The amino acid powder preservation device according to claim 1, wherein: the support frame (1) comprises a base (11), side frames (12) and a controller (13), wherein the side frames (12) are fixedly arranged on the base (11), and the controller (13) is arranged in the middle of the side frames (12).

3. The amino acid powder preservation device according to claim 2, wherein: the self-gravity spiral material taking, packaging and storing mechanism (2) comprises a protective shell (21), a self-gravity conveying spiral (22), a vertical electric push rod (23), an inverted spring assembly (24), a standard material taking and packaging box (25) and a transverse electric push rod (26), the protective shell (21) is fixedly arranged on the base (11), the self-gravity conveying screw (22) is fixedly arranged on the base (11), the upper part of the self-gravity conveying screw (22) is provided with an object placing table (223), the vertical electric push rod (23) is fixedly arranged in the middle of the object placing table (223), the inverted spring assembly (24) is arranged above the vertical electric push rod (23), the inverted spring assembly (24) is provided with a spring cover plate (242), the standard material taking packaging box (25) is arranged on the spring cover plate (242), and the transverse electric push rod (26) is arranged on the side wall of the object placing table (223).

4. The amino acid powder preservation device according to claim 3, wherein: protective housing (21) includes shell body (211), packing carton entry (212), packing carton export (213), clean wall opens stop switch (214), goes up interface (215) and barrier plate (216), shell body (211) is fixed to be located on base (11), shell body (211) upper portion lateral wall is located in packing carton entry (212), shell body (211) lower part lateral wall is located in packing carton export (213), packing carton entry (212) offside is located in packing carton export (213), clean wall opens stop switch (214) and locates shell body (211) lateral wall, clean wall opens stop switch (214) and locates packing carton entry (212) homonymy, go up interface (215) and locate shell body (211) upper wall, barrier plate (216) are fixed to be located packing carton export (213) below.

5. The amino acid powder preservation device according to claim 4, wherein: from gravity conveying screw (22) including conveying screw support body (221), speed reduction axle (222), put thing platform (223) and slope (224), conveying screw support body (221) are fixed to be located on base (11), speed reduction axle (222) are located on conveying screw support body (221), put thing platform (223) and locate the screw support body top, slope (224) are located and are kept away from one side of horizontal electric putter (26) on putting thing platform (223).

6. The amino acid powder preservation device according to claim 5, wherein: the inverted spring assembly (24) comprises a compression spring rheostat (241), a spring cover plate (242), a self-reset conductive electromagnetic sheet (243), a power supply (244), an electromagnetic coil (245) and a transverse push switch (246), the compression spring rheostat (241) is fixedly arranged on the upper wall of the vertical electric push rod (23), the spring cover plate (242) is arranged above the compression spring rheostat (241), the self-reset conductive electromagnetic sheet (243) is rotatably arranged on the spring cover plate (242), the power supply (244) is fixedly arranged on the side wall of a groove of the object placing table (223), the electromagnetic coil (245) is fixedly arranged on the bottom wall of the spring cover plate (242), the transverse push switch (246) is arranged on the upper wall of the vertical electric push rod (23), and the transverse push switch (246) is arranged below the spring cover plate (242).

7. The amino acid powder preservation device according to claim 6, wherein: the standard material taking packaging box (25) comprises a material taking box (251), a buffer spring piece (252), a material taking interface (253) and a material taking buckle groove (254), wherein the material taking box (251) is arranged on a spring cover plate (242), the buffer spring piece (252) is fixedly arranged on one side, away from a slope (224), of the material taking box (251), the material taking interface (253) is arranged on the upper wall of the material taking box (251), the material taking buckle groove (254) is arranged on one side of the material taking box (251) in a penetrating mode, and the material taking buckle groove (254) is arranged on the opposite side of the buffer spring piece (252).

8. The amino acid powder preservation device according to claim 7, wherein: the speed reducing shaft (222) comprises a self-gravity roll shaft (2221), a sealing box (2222) and a speed reducing turbine (2223), the self-gravity roll shaft (2221) is rotatably arranged on the conveying spiral frame body (221), the sealing box (2222) is fixedly arranged on the side wall of the conveying spiral frame body (221), the self-gravity roll shaft (2221) is rotatably arranged on the side wall of the sealing box (2222), the speed reducing turbine (2223) is arranged at the end part of the self-gravity roll shaft (2221), the speed reducing turbine (2223) is arranged in the sealing box (2222), and the sealing box (2222) is filled with non-Newtonian fluid.

9. The amino acid powder preservation device according to claim 8, wherein: the electromagnetic gas cannon wall cleaning storage charging barrel (3) comprises an amino acid powder storage charging barrel (31), a rotary gas cannon wall cleaning mechanism (32), a reducing diameter charging barrel (33) and a discharging mechanism (34), wherein the amino acid powder storage charging barrel (31) is fixedly arranged on a supporting frame (1), the rotary gas cannon wall cleaning mechanism (32) is arranged on the amino acid powder storage charging barrel (31), the reducing diameter charging barrel (33) is fixedly arranged at the bottom of the amino acid powder storage charging barrel (31), and the discharging mechanism (34) is arranged at the bottom of the reducing diameter charging barrel (33); the wall cleaning mechanism of the rotary air cannon (32) comprises a rotary driving motor (321), a rotary shaft (322), a rotary arm (323) and an electromagnetic telescopic air cannon (324), wherein the rotary driving motor (321) is arranged on the upper wall of the amino acid powder storage barrel (31), the rotary shaft (322) is arranged on an output shaft of the rotary driving motor (321), the rotary arm (323) is fixedly arranged on the rotary shaft (322), the rotary arm (323) is arranged on two sides of the rotary shaft (322), and the electromagnetic telescopic air cannon (324) is arranged at one end, far away from the rotary shaft (322), of the rotary arm (323; the electromagnetic telescopic air gun (324) comprises an air gun shell (3241), a variable diameter air nozzle (3242) and an electromagnetic telescopic rod (3243), the air gun shell (3241) is arranged in the rotating arm (323), the variable diameter air nozzle (3242) is arranged on one side, close to the inner wall of the amino acid powder storage barrel (31), of the end portion of the air gun shell (3241), the electromagnetic telescopic rod (3243) is arranged in the air gun shell (3241), and the electromagnetic telescopic rod (3243) is provided with a telescopic rod.

10. The amino acid powder preservation device according to claim 9, wherein: the discharging mechanism (34) comprises an amino acid powder isolating cylinder (341), an amino acid powder discharging port (342), a sealing isolating cap (343), a sliding part (344) and a discharging funnel (345), the amino acid powder isolating cylinder (341) is fixedly arranged below the tapered diameter charging cylinder (33), the amino acid powder discharging port (342) is arranged on the side wall of the bottom of the tapered diameter charging cylinder (33), the sealing isolating cap (343) is fixedly arranged above the amino acid powder isolating cylinder (341), the sealing isolating cap (343) and the amino acid powder isolating cylinder (341) are coaxially arranged, the sliding part (344) is slidably arranged inside the sealing isolating cap (343), the section of the sliding part (344) is in a T-shaped arrangement, and the discharging funnel (345) is fixedly arranged on the bottom wall of the amino acid powder isolating cylinder (341); the sliding part (344) comprises a sliding body (3441) and a jacking rod (3442), the sliding body (3441) is arranged inside the sealed isolation cap (343) in a sliding mode, the jacking rod (3442) is arranged on the side wall of the amino acid powder isolation cylinder (341) in a sliding mode, and the jacking rod (3442) penetrates through the amino acid powder isolation cylinder (341) and is fixedly arranged on the flange of the sliding body (3441).

Images