CN116923874B - Nano conductive paste storage device - Google Patents

Abstract

The invention relates to the technical field of conductive paste production, in particular to a nano conductive paste storage device which comprises a storage barrel body, a transduction stirrer, a wind vibration component and a flow guide column fixedly arranged in the storage barrel body, wherein the upper surface and the lower surface of the storage barrel body are respectively provided with a sealing screw cover and a counterweight base, the transduction stirrer is in a plurality of numbers and uniformly distributed on the periphery of the storage barrel body in the circumferential direction, and the wind vibration component is fixedly arranged on the top surface of the sealing screw cover; the transduction stirrer comprises a transmission box, stirring blades, a supporting leg rod movably arranged on the inner side of the transmission box, the stirring blades, a first speed reducing tooth and a second speed reducing tooth. According to the nano conductive paste storage device, the round bottom counterweight storage barrel structure is utilized to swing freely under wind power or other external acting forces, the storage barrel is prevented from toppling by the low gravity center structure, and the stirring blades are driven to rotate to continuously stir the inner conductive paste through contact deflection of the supporting leg rods on each side face and the bottom face, so that the stability of a dispersion system in the paste is ensured.

Description

Nano conductive paste storage device

Technical Field

The invention relates to the technical field of conductive paste production, in particular to a nano conductive paste storage device.

Background

The electronic paste is an electronic functional material integrating materials, metallurgy, chemical industry and electronic technology, and is a basic material of a hybrid integrated circuit, a sensitive element, a surface mounting technology, a resistor network, a display, various electronic discrete devices and the like. Poor stability of the conductive paste, uneven distribution of effective substances in the conductive paste, rough surface of a printed electronic circuit, poor adhesion among conductive particles and the like can all cause poor conductivity of the circuit; when solid matter precipitation remains in the transfer, conveying and storage processes of the conductive paste, the product quality is affected, various conveying pipelines can be blocked, and materials remaining on the pipelines not only pollute the product, but also affect the calculation of the content of the materials in the conductive paste.

Colloid stabilization theory colloid is a mixture of tiny particles suspended in a medium. These particles are typically in the nano-or micro-sized range and do not self-settle in the medium. Colloid stabilization theory has studied how to prevent these particles from settling or aggregating to maintain the stability of the colloid system, keep the conductive particles in the conductive paste dispersion stable, prevent them from settling or aggregating, which is a key factor in ensuring the performance and usability of the conductive paste. At present, physical methods are generally adopted for improving the stability of the conductive slurry, and comprise methods of simple mechanical stirring, electromagnetic stirring, ultrasonic stirring, heating and heat preservation and the like. The conductive paste obtained by the method has stability in a short time, and has no problem for small-scale on-site production and short-term storage; however, it is difficult to ensure the stability of the conductive paste during long-term storage of a large amount of nano conductive paste.

In view of the above, the present invention provides a nano conductive paste storage device to solve the existing problems, and aims to solve the problems and improve the practical value by the technology.

Disclosure of Invention

The present invention aims to solve one of the technical problems existing in the prior art or related technologies.

The technical scheme adopted by the invention is as follows: a nano-conductive paste storage device, comprising: the storage barrel body, the transduction stirrers, the wind vibration components and the flow guide columns are fixedly arranged in the storage barrel body, the sealing screw covers and the counterweight bases are respectively arranged on the upper surface and the lower surface of the storage barrel body, the transduction stirrers are distributed uniformly on the periphery of the storage barrel body in the circumferential direction, and the wind vibration components are fixedly arranged on the top surface of the sealing screw covers;

the energy conversion stirrer comprises a transmission box, a stirring blade, a supporting foot rod movably arranged at the inner side of the transmission box, the stirring blade, a first speed reducing tooth and a second speed reducing tooth, wherein a side cover is arranged on the surface of the transmission box and is in sliding sleeve joint with the end shaft surface of the second speed reducing tooth, one end of the supporting foot rod is provided with a swinging tooth meshed with the first speed reducing tooth, the other end of the supporting foot rod is provided with a sliding foot block, the shaft end of the stirring blade is provided with a transmission tooth connected with the second speed reducing tooth and positioned at the inner side of the transmission box, and a rotary pin connected with the inner side of the transmission box is arranged on the surface of the supporting foot rod and is in sleeve joint with a torsion spring for restoring and deflecting the supporting foot rod;

the wind power vibration assembly comprises a main vertical frame, a wind roller sleeve and a permanent magnet sleeve seat movably mounted on the inner side of the main vertical frame, an inner supporting frame sleeved on the surface of the main vertical frame is fixedly mounted on the inner side of the wind roller sleeve, permanent magnet cores are fixedly mounted on the inner side of the inner supporting frame, rigid pull ropes fixed on the upper end and the lower end of the main vertical frame are arranged at two ends of each permanent magnet core, and the permanent magnet cores and the permanent magnet sleeve seat are in magnetic opposite arrangement and are mutually close to each other for lamination.

The present invention may be further configured in a preferred example to: the counterweight base is of a solid structure, the common gravity center of the counterweight base and the wind power vibration assembly is located on the joint surface of the storage barrel body and the counterweight base when the storage barrel body is filled with conductive slurry, and the bottom surface of the shoe block and the bottom surface of the counterweight base are located on the same horizontal plane.

The present invention may be further configured in a preferred example to: the storage barrel body is of a cone structure and is gradually reduced along the direction away from the counterweight base, the bottom surface of the storage barrel body is identical to the top surface of the counterweight base in surface connection, and the bottom surface of the counterweight base is of a spherical structure.

The present invention may be further configured in a preferred example to: the first reduction gear is of a double-gear structure and comprises an input gear meshed with the upper stage and an output gear meshed with the lower stage, and the diameter of the input gear is smaller than that of the output gear.

The present invention may be further configured in a preferred example to: the shoe is of a sphere structure, the outer surface of the shoe is of a smooth surface structure, the shoe and the swinging teeth are respectively positioned at two ends of the supporting leg rod, and the swinging teeth are close to the rotating shaft of the supporting leg rod.

The present invention may be further configured in a preferred example to: the flow guide column is positioned at the circle center of each transduction stirrer, a plurality of rotational flow blades are arranged on the surface of the flow guide column, the rotational flow blades are spiral, and the width of each blade is reduced along the bottom surface direction of the storage barrel body.

The present invention may be further configured in a preferred example to: the wind roller sleeve is of a conical sleeve structure and is sleeved on the periphery of the main vertical frame, and the wind roller sleeve is arranged on the surface of the main vertical frame in a floating mode through the inner supporting frame and the permanent magnet core which are pulled by the rigid pull rope inside the main vertical frame.

The present invention may be further configured in a preferred example to: the surface of the side cover is provided with a shaft guide groove which is obliquely arranged and is perpendicular to the connecting line of the center of the stirring blade and the center of the first speed reducing tooth, and the lowest end of the shaft guide groove is close to the connecting line of the center of the stirring blade and the center of the first speed reducing tooth.

The beneficial effects obtained by the invention are as follows:

1. according to the invention, the novel conductive paste storage barrel structure is arranged, the round bottom counterweight storage barrel structure is utilized to swing freely under wind power or other external acting forces, the storage barrel is prevented from toppling by the low gravity center structure, and the stirring blades are driven to rotate to continuously stir the internal conductive paste through contact deflection of the supporting leg rods on each side face and the bottom face, so that the stability of a dispersion system in the paste is ensured.

2. According to the invention, by arranging a novel gravity-driven transduction stirrer structure, self disordered swinging kinetic energy of the storage barrel is converted into rotational kinetic energy of stirring blades, under the action of external wind force through the wind power vibration component, the wind power sleeve starts vibrating (namely, a karman vortex street phenomenon is that when certain objects are bypassed by constant flow under certain conditions, two sides of the objects periodically fall off in opposite rotation directions and are arranged into regular double-line vortex), various swinging or vibration phenomena are generated, the whole wind power vibration component and the storage barrel body swing, and more swinging kinetic energy is input by mechanical transmission of the transduction stirrer.

3. According to the invention, the conductive paste is stirred through the rotary motion of the stirring blades and conveyed to the guide column, so that the conductive paste is guided to perform spiral circulation on the surface of the smoke cyclone blade after contacting the surface of the cyclone blade, and the conductive paste forming upper and lower regional layers in the storage barrel body is mutually dispersed, thereby further avoiding segregation and precipitation phenomena generated by long-term storage of the conductive paste in the storage barrel body.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an embodiment of the present invention;

FIG. 2 is a schematic cross-sectional view of a bucket according to an embodiment of the present invention;

FIG. 3 is an exploded view of a transducer stirrer according to an embodiment of the present invention;

FIG. 4 is a schematic view showing the internal structure of a transmission case according to an embodiment of the present invention;

FIG. 5 is a schematic cross-sectional view of a wind vibration assembly according to an embodiment of the present invention;

FIG. 6 is a schematic view of the inner cross-sectional structure of a wind-roller housing according to an embodiment of the present invention;

fig. 7 is a schematic view of a flow guiding column according to an embodiment of the invention.

Reference numerals:

100. a storage barrel; 110. sealing the screw cap; 120. a counterweight base;

200. a transduction mixer; 210. a transmission box; 220. a support leg; 230. stirring the leaves; 240. a first reduction gear; 250. a second reduction gear; 211. a side cover; 212. a shaft guide groove; 221. a shoe block; 222. swinging teeth; 223. a torsion spring;

300. a wind vibration assembly; 310. a main stand; 320. a wind roller sleeve; 330. a permanent magnet sleeve seat; 321. an inner bracket; 322. a permanent magnet core;

400. a flow guiding column; 410. swirl vanes.

Detailed Description

The objects, technical solutions and advantages of the present invention will become more apparent by the following detailed description of the present invention with reference to the accompanying drawings. It should be noted that, without conflict, the embodiments of the present invention and features in the embodiments may be combined with each other.

Some embodiments of the present invention provide a nano-conductive paste storage device with reference to the accompanying drawings.

Referring to fig. 1 to 7, the nano conductive paste storage device provided by the present invention includes: the wind power vibration device comprises a storage barrel 100, a transduction stirrer 200, a wind power vibration component 300 and a flow guide column 400 fixedly arranged in the storage barrel 100, wherein the upper surface and the lower surface of the storage barrel 100 are respectively provided with a sealing screw cover 110 and a counterweight base 120, the transduction stirrer 200 is a plurality of and uniformly distributed on the periphery of the storage barrel 100 in the circumferential direction, and the wind power vibration component 300 is fixedly arranged on the top surface of the sealing screw cover 110;

the transduction mixer 200 comprises a transmission box 210, a stirring blade 230, a supporting foot rod 220 movably mounted on the inner side of the transmission box 210, the stirring blade 230, a first decelerating tooth 240 and a second decelerating tooth 250, wherein a side cover 211 is arranged on the surface of the transmission box 210, the side cover 211 is in sliding sleeve joint with the end shaft surface of the second decelerating tooth 250, one end of the supporting foot rod 220 is provided with a swinging tooth 222 meshed with the first decelerating tooth 240, the other end of the supporting foot rod 220 is provided with a sliding foot block 221, the shaft end of the stirring blade 230 is provided with a transmission tooth connected with the second decelerating tooth 250 and positioned on the inner side of the transmission box 210, and a rotary pin connected with the inner side of the transmission box 210 is arranged on the surface of the supporting foot rod 220 and sleeved with a torsion spring 223 for restoring and deflecting the supporting foot rod 220;

the wind vibration assembly 300 comprises a main vertical frame 310, a wind roller sleeve 320 and a permanent magnet sleeve seat 330 movably mounted on the inner side of the main vertical frame 310, an inner supporting frame 321 sleeved on the surface of the main vertical frame 310 is fixedly mounted on the inner side of the wind roller sleeve 320, a permanent magnet core 322 is fixedly mounted on the inner side of the inner supporting frame 321, rigid pull ropes fixed on the upper end and the lower end of the main vertical frame 310 are arranged at two ends of the permanent magnet core 322, and the permanent magnet core 322 and the permanent magnet sleeve seat 330 are in magnetic opposite arrangement and are close to each other for lamination.

In this embodiment, the weight base 120 is a solid structure, and the common center of gravity of the weight base 120 and the wind power vibration assembly 300 is located on the joint surface of the weight base 120 and the storage tub 100 in a state where the storage tub 100 is filled with conductive paste, and the bottom surface of the shoe 221 and the bottom surface of the weight base 120 are located on the same horizontal plane.

Further, the storage barrel 100 has a cone structure and is tapered along a direction away from the counterweight base 120, the bottom surface of the storage barrel 100 is identical to the top surface of the counterweight base 120, and the bottom surface of the counterweight base 120 has a spherical structure.

Specifically, the entire tub 100 is supported by the weight mount 120, and may swing in any direction, converting external pushing or wind force into a swing motion of the tub 100.

In this embodiment, the first reduction teeth 240 are of a double gear construction, including input teeth that mesh with the previous stage and output teeth that mesh with the next stage, the input teeth being smaller in diameter than the output teeth.

Specifically, the first reduction gear 240 is used for reducing and driving to increase the swinging action of the swinging gear 222, so that the swinging gear 222 can realize multiple rotations of the first reduction gear 240 and the second reduction gear 250 under the small swing amplitude.

In this embodiment, the shoe 221 has a spherical structure, the outer surface of the shoe 221 has a smooth surface structure, the shoe 221 and the oscillating tooth 222 are respectively located at two ends of the supporting leg 220, and the oscillating tooth 222 is close to the rotating shaft of the supporting leg 220.

Specifically, supporting of temple bar 220 with low friction slider 221 allows for deflection of temple bar 220 by contact and sliding on the ground while bucket body 100 is tilted.

In this embodiment, the flow guide posts 400 are located at the arrangement center of the respective transduction stirrers 200, and the surface of the flow guide posts 400 is provided with a plurality of swirl vanes 410, the swirl vanes 410 being helical and the vane width being reduced along the bottom surface direction of the storage tub 100.

Specifically, the plurality of stirring blades 230 perform a rotation motion to stir the conductive paste, and the conductive paste is guided to perform a spiral circulation on the surface of the cyclone blade 410 after contacting the surface of the cyclone blade 410, and the conductive paste forming upper and lower zone layers inside the storage tub 100 is dispersed with each other.

In this embodiment, the wind roller sleeve 320 is in a conical sleeve structure and is sleeved on the outer periphery of the main stand 310, and the wind roller sleeve 320 is floatingly arranged on the surface of the main stand 310 by pulling the inner support 321 and the permanent magnet core 322 through the rigid pull rope inside the main stand 310.

In this embodiment, the surface of the side cover 211 is provided with a shaft guide groove 212, the shaft guide groove 212 is arranged obliquely and perpendicular to the line connecting the stirring blade 230 and the center of the first reduction gear 240, and the lowest end of the shaft guide groove 212 is close to the line connecting the stirring blade 230 and the center of the first reduction gear 240.

Specifically, the second reduction gear 250 moves to the lowest position of the side cover 211 in the counterclockwise rotation of the first reduction gear 240 to be engaged with the stirring blade 230 and the first reduction gear 240, and the second reduction gear 250 is forced to be pushed upward along the side cover 211 to be disengaged from the first reduction gear 240 and the stirring blade 230 in the clockwise rotation of the first reduction gear 240.

The working principle and the using flow of the invention are as follows:

when the nano conductive paste storage device is used, the sealing screw cover 110 is opened to fill nano conductive paste and store the nano conductive paste in a sealing way, the storage barrel body 100 can be placed at a shade position of a ventilation position to ensure the constant temperature of the whole storage barrel body 100, workers can periodically patrol and push the storage barrel body 100 to shake, the storage barrel body 100 can shake in any direction under the support of the counterweight base 120, when the storage barrel body 100 inclines to shake at one side, the sliding foot block 221 contacts with the ground to enable the supporting foot rod 220 to deflect, the stirring blade 230 is driven to rotate by the meshing transmission of the swinging teeth 222, the first decelerating teeth 240, the second decelerating teeth 250 and the stirring blade 230, the storage barrel body 100 is supported by the counterweight base 120 to reversely swing in a restoration way, the torsion spring 223 is elastically released to drive the supporting foot rod 220 to reversely deflect, the first decelerating teeth 240 reversely rotate in the restoration deflection, because the second decelerating tooth 250 is pin-sleeved inside the side cover 211 and can slide, the second decelerating tooth 250 moves to the lowest position of the side cover 211 and can be meshed with the stirring blade 230 and the first decelerating tooth 240 in the anticlockwise rotation of the first decelerating tooth 240, the second decelerating tooth 250 is forced to be pushed upwards along the side cover 211 and separated from the first decelerating tooth 240 and the stirring blade 230 in the clockwise rotation of the first decelerating tooth 240, namely, the first decelerating tooth 240 can rotate freely, the surface of the stirring blade 230 which cannot be acted by the elastic restoring force of the torsion spring 223 can be quickly eliminated, the internal transduction stirrer 200 is repeatedly rocked for a plurality of times to ensure that the internal transduction stirrer 200 converts more external thrust kinetic energy into rotational stirring kinetic energy of the stirring blade 230, the stirring blades 230 perform stirring of the conductive paste, and convey the conductive paste to the guide post 400, so that the conductive paste is guided to perform spiral circulation on the surface of the smoke cyclone blade 410 after contacting the surface of the cyclone blade 410, and the conductive paste forming upper and lower zone layers inside the storage barrel body 100 is mutually dispersed, so that segregation and precipitation phenomena generated by long-term storage of the conductive paste inside the storage barrel body 100 are further avoided;

in addition, under the action of external wind force, when wind force collides with the surface of the wind roller sleeve 320, the wind roller sleeve 320 starts vibrating, namely, a karman vortex street phenomenon, which means that when certain objects are bypassed by constant incoming flow under certain conditions, two sides of the objects periodically fall off and rotate in opposite directions and are arranged into regular double-line vortex, various swinging or vibration phenomena are generated, the wind roller sleeve 320 is supported by the inner support frame 321, the main support frame 310 is suspended under the limit of the pull rope in the main support frame 310, the center of the wind roller sleeve 320 deviates from the center of the main support frame 310 under the magnetic repulsive force of the permanent magnet core 322 and the permanent magnet sleeve seat 330 to keep the tension state of the pull rope, and the inner support frame 321 moves out of order under the action of wind force to strike the main support frame 310 at high frequency, so that the whole wind vibration assembly 300 and the storage barrel 100 swing, and more swinging kinetic energy are mechanically conducted through the energy conversion stirrer 200 to stir kinetic energy input.

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

Claims (9)

1. A nano-conductive paste storage device, comprising: the storage barrel comprises a storage barrel body (100), a plurality of transduction stirrers (200) and wind vibration components (300) and guide posts (400) fixedly arranged in the storage barrel body (100), wherein sealing screw covers (110) and counterweight bases (120) are respectively arranged on the upper surface and the lower surface of the storage barrel body (100), the transduction stirrers (200) are uniformly distributed on the periphery of the storage barrel body (100) in the circumferential direction, the wind vibration components (300) are fixedly arranged on the top surface of the sealing screw covers (110), the counterweight bases (120) are of solid structures, and the common gravity centers of the counterweight bases (120) and the wind vibration components (300) are positioned on the joint surfaces of the storage barrel body (100) and the counterweight bases (120) when the storage barrel body (100) is filled with conductive paste;

the energy conversion stirrer (200) comprises a transmission box (210), stirring blades (230) and a supporting foot rod (220), the stirring blades (230), a first speed reduction tooth (240) and a second speed reduction tooth (250) which are movably arranged on the inner side of the transmission box (210), a side cover (211) is arranged on the surface of the transmission box (210), the side cover (211) is in sliding sleeve connection with the end shaft surface of the second speed reduction tooth (250), one end of the supporting foot rod (220) is provided with a swing tooth (222) meshed with the first speed reduction tooth (240), the other end of the supporting foot rod (220) is provided with a sliding foot block (221), the shaft end of the stirring blades (230) is provided with a transmission tooth which is positioned on the inner side of the transmission box (210) and is connected with the second speed reduction tooth (250), and the surface of the supporting foot rod (220) is provided with a rotary pin connected with a torsion spring (223) for restoring and deflecting the supporting foot rod (220) in a sleeved mode;

when the storage barrel body (100) is inclined to one side and sways, the sliding foot block (221) is contacted with the ground, so that the supporting foot rod (220) deflects, the stirring blade (230) is driven to rotate by utilizing the meshing transmission of the swinging teeth (222) and the first decelerating teeth (240), the second decelerating teeth (250) and the stirring blade (230), the storage barrel body (100) is supported by the counterweight base (120) to reversely swing, the torsion spring (223) elastically releases to drive the supporting foot rod (220) to reversely deflect, the first decelerating teeth (240) reversely rotate in the return deflection, the second decelerating teeth (250) are sleeved in the side cover (211) in a pin shaft manner, the second decelerating teeth (250) move to the lowest position of the side cover (211) in the anticlockwise rotation of the first decelerating teeth (240) and can be meshed with the stirring blade (230) and the first decelerating teeth (240), the second decelerating teeth (250) are forced to upwards push the first decelerating teeth (240) and the stirring blade (230) to be separated from the first decelerating teeth (230) in the clockwise rotation of the side cover (211), and the torsion spring (223) can not elastically release the elastic restoring force to the torsion spring (223) so that the elastic restoring force can not be released, repeatedly shaking the storage barrel body (100) for a plurality of times ensures that the internal transduction stirrer (200) converts more external thrust kinetic energy into rotary stirring kinetic energy of the stirring blades (230), and the stirring blades (230) perform rotary motion to stir the conductive paste.

2. The nano-conductive paste storage device according to claim 1, wherein the bottom surface of the shoe block (221) is located at the same level as the bottom surface of the counterweight base (120).

3. The nano conductive paste storage device according to claim 1, wherein the storage barrel body (100) is in a cone structure and is tapered in diameter along a direction away from the counterweight base (120), the bottom surface of the storage barrel body (100) is identical to the top surface of the counterweight base (120), and the bottom surface of the counterweight base (120) is in a spherical structure.

4. The nano-conductive paste storage device according to claim 1, wherein the first reduction teeth (240) are of a double gear structure including input teeth engaged with a previous stage and output teeth engaged with a next stage, the input teeth having a smaller diameter than the output teeth.

5. The nano conductive paste storage device according to claim 1, wherein the shoe block (221) has a spherical structure, the outer surface of the shoe block (221) has a smooth surface structure, the shoe block (221) and the swing teeth (222) are respectively positioned at two ends of the supporting leg rod (220), and the swing teeth (222) are close to the rotating shaft of the supporting leg rod (220).

6. The nano conductive paste storage device according to claim 1, wherein the wind power vibration component (300) comprises a main stand (310), a wind roller sleeve (320) and a permanent magnet sleeve seat (330) movably mounted on the inner side of the main stand (310), an inner support (321) sleeved on the surface of the main stand (310) is fixedly mounted on the inner side of the wind roller sleeve (320), a permanent magnet core (322) is fixedly mounted on the inner side of the inner support (321), rigid pull ropes fixed on the upper end and the lower end of the main stand (310) are arranged at two ends of the permanent magnet core (322), and the permanent magnet core (322) and the permanent magnet sleeve seat (330) are in magnetic opposite arrangement and are close to each other for lamination.

7. The nano conductive paste storage device according to claim 6, wherein the wind roller sleeve (320) is in a conical sleeve structure and is sleeved on the periphery of the main stand (310), and the wind roller sleeve (320) is floatingly arranged on the surface of the main stand (310) by pulling the inner support (321) and the permanent magnet core (322) through a rigid pull rope inside the main stand (310).

8. The nano conductive paste storage device according to claim 1, wherein the flow guiding columns (400) are located at the arrangement center of each transduction mixer (200), a plurality of swirl blades (410) are arranged on the surface of the flow guiding columns (400), the swirl blades (410) are spiral, and the blade widths are reduced along the bottom surface direction of the storage barrel body (100).

9. The nano-conductive paste storage device according to claim 1, wherein the surface of the side cover (211) is provided with a shaft guide groove (212), the shaft guide groove (212) is obliquely arranged and is perpendicular to the connecting line of the center of the stirring blade (230) and the center of the first speed reducing tooth (240), and the lowest end of the shaft guide groove (212) is close to the connecting line of the center of the stirring blade (230) and the center of the first speed reducing tooth (240).