Anti-adhesion mixing equipment for pigment for printing and packaging through acoustic wave resonance heating
Technical Field
The invention relates to the field of mixing equipment, in particular to mixing equipment for printing and packaging pigment with acoustic resonance heating and anti-adhesion functions.
Background
Printing is a technique of transferring ink to the surface of a material such as paper, fabric, plastic, or leather by performing processes such as plate making, inking, and pressing on an original such as characters, pictures, photographs, or forgery prevention, and thereby mass-transferring the content of the original. Pigment is long-time places, can appear deposiing, the solidification phenomenon, and then need stir it before the use and mix, need wash mixing apparatus after the pigment stirring mixes and appear impurity when preventing to stir mixed pigment next time, because pigment has stronger adhesion, leads to wasing comparatively difficultly, needs staff's manual washing, and the current technical consideration is not comprehensive, has following drawback:
need wash mixing apparatus after pigment stirring and mix and appear impurity when preventing to stir mixed pigment next time, because pigment has stronger adhesion, the pigment easily adheres on the puddler, generally lets in clear water and stirs, nevertheless can't all stir at every turn at the washing mixing apparatus and mix the back and just wash at once, take place pigment drying easily and make the adhesion stronger, lead to the clear water to wash comparatively difficult, need staff's manual washing.
Disclosure of Invention
Aiming at the defects in the prior art, the invention aims to provide a pigment mixing device for printing and packaging with acoustic resonance heating and anti-adhesion functions, so that the problems that in the prior art, the mixing device needs to be cleaned after the pigment is stirred and mixed to prevent impurities from appearing when the pigment is stirred and mixed next time, the pigment is easy to adhere to a stirring rod due to strong adhesion of the pigment, clear water is generally introduced for stirring, the mixing device cannot be cleaned immediately after stirring and mixing every time, the pigment is easy to dry, the adhesion is stronger, the clear water is difficult to clean, and the pigment is required to be manually cleaned by workers are solved.
In order to achieve the purpose, the invention is realized by the following technical scheme:
the utility model provides a sound wave resonance heating antiseized for printing package pigment mixing apparatus, its structure includes base, controller, motor, connector, dwang, agitating unit, the upper right side of base is equipped with the controller, the motor is installed in the connector afterbody, agitating unit is equipped with four and is equidistance annular distribution around the dwang, the upper end embedding of dwang is installed in the connector and swing joint, agitating unit includes housing, electro-magnet, first sliding block, fixed partition, second sliding block, current generation device, wire, heating wire, sound wave resonance device, the electro-magnet is installed in the inside right-hand member of housing, first sliding block is located the left side of electro-magnet and its left side surface and fixed partition laminate mutually, the right side surface and the fixed partition of second laminate mutually, current generation device passes through the wire and is connected with the heating wire electricity, the sound wave resonance device is arranged at the left end inside the outer housing.
The first sliding block comprises an armature, a fixed groove, a first spring and a first sliding block main body, wherein the armature is embedded in the fixed groove and connected with the fixed groove in an electric welding mode, the fixed groove and the sliding block main body are of an integrated structure, and the first spring is embedded in the left inner part of the sliding block main body.
As a further aspect of the present invention, the second slider includes a second spring, a second slider body, and a vibrating tuning fork, the second spring is embedded inside the right side of the second slider body, and the vibrating tuning fork is installed on the left side of the second slider body and connected by electric welding.
As a further aspect of the present invention, the current generating device includes an arc-shaped moving block, an elastic element, and a dielectric, the elastic element is disposed on the upper surface of the arc-shaped moving block and connected to the arc-shaped moving block by electric welding, and the dielectric is mounted above the arc-shaped moving block and electrically connected to the heating wire through a wire.
As a further aspect of the present invention, the acoustic wave resonance device includes a soundboard, a vibrating diaphragm, a resonant tuning fork, and a resonating plate, wherein the vibrating diaphragm is embedded in the soundboard, and the resonant tuning fork is disposed opposite to the vibrating tuning fork and welded to the resonating plate.
As a further aspect of the present invention, the outer casing is heated by the heating wire, thereby increasing the solubility of the outer part of the outer casing contacting water and increasing the molecular movement of the pigment adhered to the outer casing, so that the pigment can be better washed away.
As a further scheme of the invention, the length of the arched moving block is equal to that of the moving groove in the current generating device, so that the height of two ends of the arched moving block is prevented from being uneven when the arched moving block moves.
As a further scheme of the invention, the damage caused by the fact that the arched moving block excessively presses the dielectric is avoided through the elastic element.
As a further aspect of the present invention, when the dielectric is deformed by an external force, a polarization phenomenon occurs, and bound charges of different signs are formed on opposite surfaces to form a current.
As a further scheme of the invention, the sound returning plate is of an arc-shaped structure, and sound waves can be better reflected and collected through the arc-shaped smooth curved surface.
As a further aspect of the present invention, the vibrating tuning fork, the resonant tuning fork and the resonant plate are made of the same material, and have the same resonant frequency.
Advantageous effects of the invention
Compared with the traditional mixing equipment for the pigment, the invention extrudes the dielectric substance by the upward movement of the arched moving block under the action of the current generating device and the electric heating wire, so that the dielectric substance forms current when deformed by external force, and the current is led into the electric heating wire through the conducting wire to heat the outer housing, thereby improving the solubility of water contacting the outside of the outer housing, improving the molecular motion of the pigment adhered on the outer housing and better cleaning the pigment.
Under the action of the sound wave resonance device, the sound returning plate reflects and collects sound waves of the outer housing, which are impacted by water flow, so that the vibration diaphragm vibrates to impact the vibration tuning fork, the vibration tuning fork generates the sound waves to enable the resonance tuning fork to resonate, meanwhile, the resonance plate also resonates to drive the outer housing to vibrate, the surface pressure of the outer housing is reduced sharply and finally is reduced to be lower than the saturated vapor pressure of the temperature, tiny bubbles are generated firstly, then the bubbles absorb and remove gas to gradually increase to form vacuoles, the temperature of external water is heated through the heating wire, the formation of the vacuoles is improved, impact waves are generated when the vacuoles are closed, thousands of atmospheric pressures are generated around the bubbles, insoluble dirt is damaged to be dispersed in the water, and the purpose of cleaning the outer housing is achieved.
Drawings
Other features, objects and advantages of the invention will become more apparent from a reading of the detailed description of non-limiting embodiments with reference to the attached drawings.
In the drawings:
FIG. 1 is a schematic structural diagram of a mixing device for heating and anti-sticking pigment for printing and packaging by acoustic resonance.
FIG. 2 is a plan view of a stirring device according to the present invention.
FIG. 3 is a schematic structural diagram of a first slider according to the present invention.
FIG. 4 is a schematic structural diagram of a second slider according to the present invention.
Fig. 5 is a schematic structural diagram of a current generation device according to the present invention.
Fig. 6 is a schematic structural diagram of an acoustic wave resonator device according to the present invention.
In the figure: a base-1, a controller-2, a motor-3, a connector-4, a rotating rod-5, a stirring device-6, an outer casing-61, an electromagnet-62, a first sliding block-63, a fixed clapboard-64, a second sliding block-65, a current generating device-66, a lead-67, a heating wire-68 and a sound wave resonance device-69, armature-6301, fixed groove-6302, first spring-6303, first slider body-6304, second spring-6501, second slider body-6502, vibrating tuning fork-6503, arched moving block-6601, elastic element-6602, dielectric substance-6603, echo plate-6901, vibrating diaphragm-6902, resonant tuning fork-6903, and resonant plate-6904.
Detailed Description
In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.
As shown in fig. 1 to fig. 6, the invention provides a technical scheme of a mixing device for heating and sticking-preventing pigment for printing and packaging by acoustic resonance:
as shown in fig. 1-2, a mixing apparatus for printing and packaging pigment is heated and adhered in an anti-sticking manner by sound wave resonance, the structure of the mixing apparatus comprises a base 1, a controller 2, a motor 3, a connector 4, a rotating rod 5 and a stirring device 6, the controller 2 is arranged at the upper right of the base 1, the motor 3 is arranged at the tail of the connector 4, the stirring device 6 is provided with four stirring devices and is distributed around the rotating rod 5 in an equidistant annular manner, the upper end of the rotating rod 5 is embedded in the connector 4 and is movably connected with the connector, the stirring device 6 comprises an outer casing 61, an electromagnet 62, a first sliding block 63, a fixed partition plate 64, a second sliding block 65, a current generating device 66, a conducting wire 67, an electric heating wire 68 and a sound wave resonance device 69, the electromagnet 62 is arranged at the inner right end of the outer casing 61, the first sliding block 63 is arranged at the left side of the, the right side surface of the second sliding block 65 is attached to the fixed partition 64, the current generating device 66 is electrically connected to the heating wire 68 through the wire 67, the acoustic wave resonance device 69 is installed at the left end inside the outer casing 61, and the outer casing 61 is heated by the heating wire 68, so that the solubility of water contacting the outside of the outer casing 61 is improved, the molecular motion of the pigment adhered to the outer casing 61 is improved, and the pigment can be better washed away.
As shown in fig. 3, the first slider 63 includes an armature 6301, a fixing groove 6302, a first spring 6303, and a first main slider body 6304, wherein the armature 6301 is embedded in the fixing groove 6302 and connected thereto by electric welding, the fixing groove 6302 and the main slider body 6304 are integrated, the first spring 6303 is embedded in the left inner portion of the main slider body 6304, the armature 6301 is attracted by the electromagnet 62, the first main slider body 6304 is driven to move to push the arched moving block 6601 to move upward, and the first spring 6303 and the centrifugal force limit the moving distance of the first main slider body 6304.
As shown in fig. 4, the second slider 65 includes a second spring 6501, a second slider body 6502, and a vibrating tuning fork 6503, the second spring 6501 is embedded inside the right side of the second slider body 6502, the vibrating tuning fork 6503 is installed on the left side of the second slider body 6502 and is electrically welded to the second slider body 6502, the second slider body 6502 is moved by centrifugal force to push the arched moving block 6601 to move upward, the moving distance of the second slider body 6502 is limited by the second spring 6501, and the vibrating tuning fork 6503 is moved by the movement of the second slider body 6502 to contact the vibrating diaphragm 6902.
As shown in fig. 5, the current generating device 66 includes an arc-shaped moving block 6601, an elastic element 6602, and a dielectric 6603, wherein the elastic element 6602 is disposed on the upper surface of the arc-shaped moving block 6601 and electrically connected to the electric heating wire 68 through a conductive wire 67, the dielectric 6603 is pressed by the upward movement of the arc-shaped moving block 6601, so that when the dielectric 6603 is deformed by an external force, a polarization phenomenon occurs, different bound charges are formed on the two opposite surfaces to form a current, and the damage caused by the excessive pressing of the dielectric 6603 by the arc-shaped moving block 6601 is avoided by the elastic element 6602.
As shown in fig. 6, the acoustic wave resonance device 69 includes an echo plate 6901, a vibration diaphragm 6902, a resonance tuning fork 6903 and a resonance plate 6904, the vibration diaphragm 6902 is embedded in the middle of the echo plate 6901, the resonance tuning fork 6903 is disposed opposite to the vibration tuning fork 6503 and welded to the resonance plate 6904, and the sound waves can be better reflected and collected by the arc smooth curved surface of the echo plate 6901, so that the vibration diaphragm 6902 vibrates and impacts the vibration tuning fork 6503, so that the vibration tuning fork 6503 emits sound waves to resonate the resonance tuning fork 6903, and meanwhile, since the resonance tuning fork 6903 and the resonance plate 6904 are made of the same material and have the same resonance frequency, the resonance plate 6904 also resonates to drive the outer casing 61 to vibrate, the surface pressure of the outer casing 61 drops sharply and finally drops below the saturation vapor pressure of the temperature, tiny bubbles are generated at this time, and then the bubbles absorb gas to gradually increase and form the bubbles, the temperature of the external water is heated by the heating wire 68 to increase the formation of the cavitation bubbles, thereby generating shock waves when the cavitation bubbles are closed, generating thousands of atmospheric pressures around the shock waves, destroying insoluble contaminants and dispersing them in the water, thereby achieving the purpose of cleaning the outer casing 61.
The specific realization principle is as follows: when the mixing device needs to be cleaned after the pigments are stirred and mixed, clean water is introduced, the mixing device is started through the controller 2, so that the rotating rod 5 drives the stirring device 6 to start rotating, the electromagnet 62 is electrified to adsorb the armature 6301 to approach, the first sliding block main body 6304 is driven to move to push the arched moving block 6601 to move upwards, the moving distance of the first sliding block main body 6304 is limited by the first spring 6303 and centrifugal force, the rotating rod 5 drives the stirring device 6 to rotate to generate centrifugal force, the second sliding block main body 6502 is driven to move by centrifugal force to push the arched moving block 6601 to move upwards, the moving distance of the second sliding block main body 6502 is limited by the second spring 6501, the vibrating tuning fork 6503 is driven to move by the second sliding block main body 6502 to contact with the vibrating diaphragm 6902, and the arched moving block 6601 moves upwards to squeeze the dielectric 6603, therefore, when the dielectric 6603 is deformed by an external force, a polarization phenomenon occurs, different bound charges are formed on the two opposite surfaces to form a current, meanwhile, the elastic element 6602 is used for avoiding the damage caused by the fact that the arched moving block 6601 extrudes the dielectric 6603 excessively, the current is led into the heating wire 68 through the lead 67, the heating wire 68 heats the outer housing 61 to improve the solubility and the temperature of water contacting with the outside of the outer housing 61 and improve the molecular motion of pigment adhered on the outer housing 61, so that the pigment can be better cleaned, sound waves impacted by the outer housing 61 and water flow can be better reflected and collected through the arc smooth curved surface of the echo plate 6901, so that the vibration diaphragm 6902 vibrates to impact the vibration tuning fork 6503, so that the vibration tuning fork 6503 emits the sound waves to enable the resonance tuning fork 6903 to resonate, and meanwhile, because the resonance tuning fork 6903 and the resonance plate 6904 are made of the same, the resonance frequency is the same, so that the resonance plate 6904 will also resonate to drive the outer casing 61 to vibrate, the surface pressure of the outer casing 61 will decrease sharply and finally decrease below the saturated vapor pressure of the temperature, at this time, tiny bubbles will be generated first, then the bubbles will absorb the gas and gradually increase to form vacuoles, the temperature of the outside water is heated by the heating wire 68 to increase the vacuoles formation, thereby shock waves will be generated when the vacuoles are closed, thousands of atmospheric pressure will be generated around the vacuoles, and the insoluble dirt will be destroyed and dispersed in the water, thereby achieving the purpose of cleaning the outer casing 61.
The invention solves the problems that in the prior art, when the mixing device is required to be cleaned after the pigments are stirred and mixed to prevent impurities from appearing when the pigments are stirred and mixed next time, the pigments are easy to adhere to a stirring rod because the pigments have strong adhesion, and are generally stirred by introducing clean water, but the mixing device cannot be cleaned immediately after being stirred and mixed each time, the pigments are easy to dry to cause stronger adhesion, so that the clean water is difficult to clean, and the pigments are required to be manually cleaned by workers, through the mutual combination of the components, the invention extrudes a dielectric substance through the upward movement of an arched movable block under the action of a current generating device and an electric heating wire, so that the dielectric substance forms current when being deformed by external force, and the current is introduced into the electric heating wire through a lead to heat the outer housing, thereby improving the solubility of water contacting the outer portion of the outer housing and improving the molecular motion of the pigments adhered to the, so that the pigment can be better washed away.
Under the action of the sound wave resonance device, the sound returning plate reflects and collects sound waves of the outer housing, which are impacted by water flow, so that the vibration diaphragm vibrates to impact the vibration tuning fork, the vibration tuning fork generates the sound waves to enable the resonance tuning fork to resonate, meanwhile, the resonance plate also resonates to drive the outer housing to vibrate, the surface pressure of the outer housing is reduced sharply and finally is reduced to be lower than the saturated vapor pressure of the temperature, tiny bubbles are generated firstly, then the bubbles absorb and remove gas to gradually increase to form vacuoles, the temperature of external water is heated through the heating wire, the formation of the vacuoles is improved, impact waves are generated when the vacuoles are closed, thousands of atmospheric pressures are generated around the bubbles, insoluble dirt is damaged to be dispersed in the water, and the purpose of cleaning the outer housing is achieved.
While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.
Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.