CN113182182A - Method and device for automatically screening and mixing ceramic powder - Google Patents

Abstract

The automatic ceramic powder screening and mixing device comprises a closed cavity, wherein the lower end of a screening device is provided with the closed cavity, one end of an ultrasonic oscillation mechanism is connected with the closed cavity, a vibration hammer is further arranged on the outer side of the screening device, the screening device further comprises a blanking pipe, and a material mixing device is arranged below the blanking pipe; the material mixing device comprises an adjusting bracket, a swinging blade, a servo motor and a sugar-coating machine, wherein the sugar-coating machine comprises a sugar-coating pot, the servo motor is arranged on the adjusting bracket and fixedly connected with one end of the swinging blade, and the other end of the swinging blade extends into the sugar-coating pot. When the ceramic powder is sieved, the ultrasonic generator is turned on to enable air in the closed cavity to generate and rise airflow through the screen, so that the ceramic powder in the sieving barrel is dispersed, and the ceramic powder uniformly falls into the containing barrel. And then the ceramic powder falls into the sugar coating pot from the material containing barrel, and is evenly stirred by repeatedly swinging the material containing barrel in the sugar coating pot, so that the labor intensity of workers is greatly reduced, and the labor cost is saved.

Description

Method and device for automatically screening and mixing ceramic powder

Technical Field

The invention relates to the field of powder processing, in particular to a device and a method for screening and mixing ceramic powder.

Background

When ceramic powders are sieved, continuous sieving is not usually performed in order to save electricity. But the ceramic powder is screened in batches, that is, quantitatively screened. The quantitative screening is an intermittent screening mode, so that the processing cost can be saved. In addition, in order to allow the ceramic powder to smoothly pass through the fine mesh of the screen, the sieving device needs to be vibrated finely and rapidly. However, such vibration tends to cause static electricity to the ceramic powder in the sieving device, so that the ceramic powder is accumulated and agglomerated, and the ceramic powder is prevented from passing through the sieve. And ceramic powder need stir ceramic powder after the ceramic powder screening, and the mode of manual stirring is generally adopted in the stirring of ceramic powder at present, and when the manual work was carried out even stirring, mainly lean on staff's experience and lean on eyes to stir while observing. The feeding mode needs continuous stirring by workers, and has the disadvantages of high labor intensity, low work cost and high labor cost.

The following patents are found to have similarities with the present invention through domestic search: the invention with the application number of 201410353801.6 and the name of YSZ ceramic powder for plasma spraying discloses a preparation method of YSZ ceramic powder for plasma spraying, which comprises the following steps: firstly, adding yttrium salt and zirconium salt into deionized water according to a certain proportion, and stirring until the yttrium salt and the zirconium salt are completely dissolved to obtain a mixed solution; secondly, carrying out coprecipitation treatment, and filtering and drying to obtain a solid mixture; thirdly, carrying out hydrothermal reaction on the solid mixture to obtain a hydrothermal reaction product; fourthly, filtering, washing and drying the hydrothermal reaction product, and uniformly mixing the hydrothermal reaction product with deionized water and a binder to obtain slurry; fifthly, carrying out spray drying treatment to obtain granules; and sixthly, sintering and screening the granules to obtain YSZ ceramic powder for plasma spraying. The YSZ ceramic powder prepared by the invention is of a full tetragonal structure, has the characteristics of uniform distribution of yttria, high solid solution alloying of yttria and zirconia and the like, and has simple equipment in the process, no high temperature and mechanical crushing in the whole production process and low production cost.

Although the above patent also discloses a process for sieving ceramic powder, the sieving is used for preparing ceramic powder, and the sieving is used for preparing ceramic powder for subsequent stirring, and the device and sieving function used in the sieving process are different.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: how to automatically and fully stir the screened ceramic powder to prepare spherical ceramic particles.

In order to solve the problems, the technical scheme provided by the invention is as follows: the automatic ceramic powder screening and mixing device comprises a closed cavity, wherein the lower end of a screening device is provided with the closed cavity, one end of an ultrasonic oscillation mechanism is connected with the closed cavity, a vibration hammer is further arranged on the outer side of the screening device, the screening device further comprises a blanking pipe, and a material mixing device is arranged below the blanking pipe; the material mixing device comprises an adjusting bracket, a swinging blade, a servo motor and a sugar-coating machine, wherein the sugar-coating machine comprises a sugar-coating pot, the servo motor is arranged on the adjusting bracket and fixedly connected with one end of the swinging blade, and the other end of the swinging blade extends into the sugar-coating pot.

Preferably, the screening device comprises a screening bucket and a containing bucket, the containing bucket is arranged at the lower end of the screening bucket, a screen is arranged at the bottom of the screening bucket, the screen cover is closed at the upper end of the containing bucket, and a closed cavity is formed between the screen and the containing bucket.

Preferably, the ultrasonic oscillation mechanism comprises an ultrasonic sounder and an air duct, one end of the air duct extends into the closed cavity, and the other end of the air duct is connected with the ultrasonic sounder; both sides of the material containing barrel are connected with supports, each support is provided with a connecting rod, and each connecting rod is provided with a vibration hammer.

Preferably, a chassis is arranged below the material containing barrel, a spring is arranged between the material containing barrel and the chassis, the upper end of the spring is connected with the bottom of the material containing barrel, and the lower end of the spring is connected with the chassis.

Preferably, the adjusting support comprises a bottom plate, a supporting rod and a sleeve rod, the lower end of the supporting rod is fixedly connected to the bottom plate, the sleeve rod is sleeved on the supporting rod, more than two mounting holes are formed in the sleeve rod and the supporting rod, and the bolt penetrates through the mounting holes in the sleeve rod and the supporting rod and can limit the sleeve rod.

Preferably, the adjusting bracket further comprises a cross rod and a stabilizing rod, the cross rod is fixedly connected with the loop bar, the stabilizing rod is arranged on one side of the supporting rod, one end of the stabilizing rod is fixedly connected with the bottom plate, and the other end of the stabilizing rod is fixedly connected with the cross rod.

Preferably, the swinging device comprises a swinging rod and a claw, one end of the swinging rod is fixedly connected with a rotating shaft of the servo motor, and the other end of the swinging rod is fixedly connected with the claw; the sugar-coating machine comprises a machine base, a connector and a sugar-coating pan, wherein a motor is arranged in the machine base, one end of the connector is fixedly connected with a rotating shaft of the motor, and the other end of the connector is fixedly connected with the bottom of the sugar-coating pan.

A method for automatically screening and mixing ceramic powder comprises the steps of firstly starting an ultrasonic oscillation mechanism and a vibration hammer to screen the ceramic powder in a screening device, enabling the screened ceramic powder to fall into a sugar coating pot of a sugar coating machine, starting a servo motor to drive a swinging machine to stir the ceramic powder in the sugar coating pot, and adding glue into the sugar coating pot while stirring, so that the ceramic powder in the sugar coating pot is stirred into spherical ceramic particles.

Preferably, the screening device comprises a screening bucket and a containing bucket, the containing bucket is arranged at the lower end of the screening bucket, a screen is arranged at the bottom of the screening bucket, and the screen is covered at the upper end of the containing bucket, so that a closed cavity is formed between the screen and the containing bucket; the ultrasonic oscillation mechanism comprises an ultrasonic sounder and an air guide tube, the two ends of the air guide tube are respectively connected with the ultrasonic sounder and the air guide tube, the ultrasonic sounder is started to enable air in the material sieving barrel and the material containing barrel to oscillate, and the vibration hammer is started to enable the material sieving barrel and the material containing barrel to vibrate, so that ceramic powder in the material sieving barrel is sieved.

Preferably, the swinging handle is provided with a swinging rod and a claw, one end of the swinging rod is fixedly connected with a rotating shaft of the servo motor, and the other end of the swinging rod is fixedly connected with the claw; the sugar-coating machine also comprises a machine base and a joint, wherein a motor is arranged in the machine base, one end of the joint is fixedly connected with a rotating shaft of the motor, the other end of the joint is fixedly connected with the bottom of the sugar-coating pan, and the motor is started while stirring to drive the joint to drive the sugar-coating pan to rotate around the joint.

The beneficial technical effects of the invention are as follows: when the ceramic powder is sieved, the ultrasonic generator is turned on to enable air in the closed cavity to generate and rise airflow through the screen, so that the ceramic powder in the sieving barrel is dispersed, and the ceramic powder uniformly falls into the containing barrel. And then the ceramic powder falls into the sugar coating pot from the material containing barrel, and is evenly stirred by repeatedly swinging the material containing barrel in the sugar coating pot, so that the labor intensity of workers is greatly reduced, and the labor cost is saved.

Drawings

FIG. 1 is a schematic overall structure diagram according to a first embodiment;

FIG. 2 is a schematic view of the overall structure of a screening device according to an embodiment;

FIG. 3 is a perspective view of the mounting structure of the vibratory hammer;

FIG. 4 is a schematic view of the overall structure of the stirring device;

FIG. 5 is a schematic structural view of an adjusting bracket and a swinging blade in the first embodiment;

FIG. 6 is a schematic view of a sugar coating machine according to an embodiment;

in the figure: the device comprises a screening barrel 11, a screen 12, a containing barrel 13, an air duct 14, a blanking pipe 15, a vibration hammer 21, a connecting rod 22, a support 23, a spring 31, a base plate 32, a table plate 41, a support column 42, a bottom plate 51, a supporting rod 52, a loop bar 53, a cross bar 54, a stabilizing rod 55, a servo motor 61, a swinging rod 62, a claw 63, a base 71, a joint 72 and a sugar coating pan 73.

Detailed Description

The invention is further described with reference to the following examples and figures:

example one

As shown in fig. 1, 2 and 3, the screening device includes two screening buckets 11 and a holding bucket 13, in this embodiment, the two screening buckets 11 are arranged up and down to form a two-layer screening structure. The bottom of the material sieving barrel 11 is provided with a screen 12, the screen 12 is provided with through meshes, and the aperture of the meshes is slightly larger than the diameter of the ceramic powder. The material containing barrel 13 is arranged at the lower end of the material sieving barrel 11, and the screen 12 covers the upper end of the material containing barrel 13, so that a closed cavity is formed between the screen 12 and the material containing barrel 13.

The ultrasonic oscillation mechanism comprises an ultrasonic sound generator and an air duct 14, one end of the air duct 14 penetrates through the barrel wall of the material containing barrel 13 and extends into the closed cavity, and the other end of the air duct 14 is connected with the ultrasonic sound generator (the ultrasonic sound generator is not shown in the figure). When the ultrasonic sounder is started, the air in the closed cavity in the material containing barrel 13 generates rapid vibration, and the vibration of the air in the closed cavity can be sequentially transmitted to the two material sieving barrels 11 above, so that the ceramic powder in the two material sieving barrels 11 is dispersed without piling and balling.

Supports 23 are connected to both sides of the bucket 13, each support 23 is provided with a connecting rod 22, and each connecting rod 22 is provided with a vibration hammer 21. The support 23 in this embodiment is composed of two arc plates and a circular plate, one ends of the two arc plates are fixedly connected to the barrel wall outside the material containing barrel 13, and the other ends of the two arc plates are fixedly connected to the circular plate. Two connecting rods 22 are arranged on each side of the charging bucket 13, each connecting rod 22 is T-shaped, the upper end of each T-shaped connecting rod 22 is fixedly connected with a circular plate, and the lower end of each T-shaped connecting rod 22 is fixedly connected with the vibration hammer 21.

A base plate 32 is arranged below the material containing barrel 13, the upper end of the blanking pipe 15 extends into the closed cavity of the screening device, and the lower end of the blanking pipe 15 penetrates through the base plate 32. A spring 31 is arranged between the charging bucket 13 and the chassis 32, the upper end of the spring 31 is connected with the bottom of the charging bucket 13, and the lower end of the spring 31 is connected with the chassis 32. The springs 31 are uniformly wound around the outer side of the blanking pipe 15, and the number of the springs 31 is eight in the embodiment in order to better buffer the vibration of the vibration hammers 21 on the containing barrel 13 and the screening barrel 11 in all directions.

In order to mount and fix the screening device, in the present embodiment, a table 41 is provided on a pillar 42, and the chassis 32 of the screening device is fixedly connected to the table 41. The blanking pipe 15 penetrates through the table plate 41, the sugar coating machine is arranged below the blanking pipe 15, and after the two layers of screening buckets 11 of the screening device are screened, ceramic powder with small diameter enters the containing bucket 13 and falls into the sugar coating machine along the blanking pipe 15 to be stirred.

As shown in fig. 1, 4, 5 and 6, the ceramic powder stirring device comprises a sugar coating machine, an adjusting bracket and a swinging machine. The adjusting bracket comprises a bottom plate 51, a supporting rod 52, a sleeve rod 53, a cross rod 54 and a stabilizing rod 55, the swinging device comprises a swinging rod 62 and a claw 63, and the sugar-coating machine comprises a base 71, a joint 72 and a sugar-coating pan 73. The lower end of the support rod 52 is fixedly connected to the bottom plate 51, the loop rod 53 is sleeved on the support rod 52, and the cross rod 54 and the loop rod 53 are perpendicular to each other and fixedly connected. The stabilizing rod 55 is disposed on one side of the supporting rod 52, one end of the stabilizing rod 55 is fixedly connected to the bottom plate 51, and the other end of the stabilizing rod 55 is fixedly connected to the cross rod 54. The supporting rod 52 and the loop bar 53 are provided with mounting holes with equal intervals, and when bolts pass through different mounting holes on the supporting rod 52 and the loop bar 53, the position of the loop bar 53 can be limited, and the heights of the loop bar 53 and each part connected with the loop bar 53 can also be adjusted.

One end of the swing rod 62 is fixedly connected with a rotating shaft of the servo motor 61, and the other end of the swing rod 62 is fixedly connected with the claw 63. The raking claw 63 in this embodiment is a double-row structured raking claw 63, and the nail teeth of the double-row structured raking claw 63 are distributed in a staggered manner, so that the raking claw 63 can stir the ceramic powder in the pan of the sugar machine more fully and uniformly. The rotating shaft of the servo motor 61 rotates a certain angle and then rotates reversely, so that the swinging claw 63 swings in the pan of the sugar machine in a reciprocating manner, and ceramic powder is automatically and continuously stirred.

In this embodiment, the base 71 of the sugar-coating machine is a hollow rectangular parallelepiped, but the front end of the base 71 is protruded forward, so that the front end of the base 71 forms two inclined surfaces, and the inclined surface at the upper end of the two inclined surfaces is provided with an opening. A motor is arranged in the hollow base 71, one end of a joint 72 of the sugar-coating machine is fixedly connected with a rotating shaft of the motor, and the other end of the joint 72 is fixedly connected with the bottom of the sugar-coating pan 73. The sugar coating pan 73 is in the shape of a hollow ellipsoid with an open top, one end of the joint 72 connected with the rotating shaft of the motor is in a cylinder shape, and one end of the joint 72 connected with the bottom of the sugar coating pan 73 is in a circular truncated cone shape. The motor is started to drive the joint 72 and the sugar coating pan 73 to rotate together by the rotating shaft of the motor, and the sugar coating pan 73 rotates in one direction slowly in the process of stirring the ceramic powder.

Obviously, several modifications and variations are possible without departing from the principles of the invention as described.

Claims (10)

1. The automatic ceramic powder screening and mixing device is characterized in that a closed cavity is formed in the lower end of a screening device, one end of an ultrasonic oscillation mechanism is connected with the closed cavity, a vibration hammer is further arranged on the outer side of the screening device, the screening device further comprises a blanking pipe, and a mixing device is arranged below the blanking pipe; the material mixing device comprises an adjusting bracket, a swinging blade, a servo motor and a sugar-coating machine, wherein the sugar-coating machine comprises a sugar-coating pot, the servo motor is arranged on the adjusting bracket and fixedly connected with one end of the swinging blade, and the other end of the swinging blade extends into the sugar-coating pot.

2. The automatic ceramic powder screening and mixing device as claimed in claim 1, wherein the screening device comprises a screening barrel and a holding barrel, the holding barrel is arranged at the lower end of the screening barrel, a screen is arranged at the bottom of the screening barrel, the screen covers the upper end of the holding barrel, and a closed cavity is formed between the screen and the holding barrel.

3. The automatic ceramic powder screening and mixing device according to claim 2, wherein the ultrasonic oscillation mechanism comprises an ultrasonic sound generator and an air guide tube, one end of the air guide tube extends into the closed cavity, and the other end of the air guide tube is connected with the ultrasonic sound generator; both sides of the material containing barrel are connected with supports, each support is provided with a connecting rod, and each connecting rod is provided with a vibration hammer.

4. The automatic ceramic powder screening and mixing device as claimed in claim 3, wherein a base plate is arranged below the material containing barrel, a spring is arranged between the material containing barrel and the base plate, the upper end of the spring is connected with the bottom of the material containing barrel, and the lower end of the spring is connected with the base plate.

5. The automatic ceramic powder screening and mixing device as claimed in claim 1, wherein the adjusting bracket comprises a bottom plate, a support rod and a sleeve rod, the lower end of the support rod is fixedly connected to the bottom plate, the sleeve rod is sleeved on the support rod, more than two mounting holes are formed in the sleeve rod and the support rod, and a bolt penetrates through the mounting holes in the sleeve rod and the support rod to limit the sleeve rod.

6. The automatic ceramic powder screening and mixing device as claimed in claim 1 or 5, wherein the adjusting bracket further comprises a cross bar and a stabilizing bar, the cross bar is fixedly connected with the loop bar, the stabilizing bar is arranged on one side of the supporting bar, one end of the stabilizing bar is fixedly connected with the bottom plate, and the other end of the stabilizing bar is fixedly connected with the cross bar.

7. The automatic ceramic powder screening and mixing device according to claim 6, wherein the swinging mechanism comprises a swinging rod and a claw, one end of the swinging rod is fixedly connected with a rotating shaft of a servo motor, and the other end of the swinging rod is fixedly connected with the claw; the sugar-coating machine comprises a machine base, a connector and a sugar-coating pan, wherein a motor is arranged in the machine base, one end of the connector is fixedly connected with a rotating shaft of the motor, and the other end of the connector is fixedly connected with the bottom of the sugar-coating pan.

8. The automatic ceramic powder sieving and mixing method is characterized in that an ultrasonic oscillation mechanism and a vibration hammer are started to sieve ceramic powder in a sieving device, the sieved ceramic powder falls into a sugar coating pot of a sugar coating machine, a servo motor is started to drive a swinging device to stir the ceramic powder in the sugar coating pot, and glue is added into the sugar coating pot while stirring, so that the ceramic powder in the sugar coating pot is stirred into spherical ceramic particles.

9. The method for automatically sieving and mixing ceramic powder as claimed in claim 8, wherein the sieving device comprises a sieving barrel and a holding barrel, the holding barrel is arranged at the lower end of the sieving barrel, a sieve mesh is arranged at the bottom of the sieving barrel, the sieve mesh is covered at the upper end of the holding barrel, and a closed cavity is formed between the sieve mesh and the holding barrel; the ultrasonic oscillation mechanism comprises an ultrasonic sounder and an air guide tube, the two ends of the air guide tube are respectively connected with the ultrasonic sounder and the air guide tube, the ultrasonic sounder is started to enable air in the material sieving barrel and the material containing barrel to oscillate, and the vibration hammer is started to enable the material sieving barrel and the material containing barrel to vibrate, so that ceramic powder in the material sieving barrel is sieved.

10. The method for automatically screening and mixing ceramic powder as claimed in claim 8, wherein a swing rod and a claw are arranged on the swing pan, one end of the swing rod is fixedly connected with a rotating shaft of a servo motor, and the other end of the swing rod is fixedly connected with the claw; the sugar-coating machine also comprises a machine base and a joint, wherein a motor is arranged in the machine base, one end of the joint is fixedly connected with a rotating shaft of the motor, the other end of the joint is fixedly connected with the bottom of the sugar-coating pan, and the motor is started while stirring to drive the joint to drive the sugar-coating pan to rotate around the joint.

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