CN116690788B - Domestic ceramic pug stirring and homogenizing device and method thereof - Google Patents

Abstract

The invention discloses a stirring and homogenizing device and a stirring and homogenizing method for domestic ceramic pugs, and relates to the field of stirring and homogenizing of ceramic raw materials. According to the invention, the suction and connection liquid component, the flow collision piece and the liquid flow device are arranged, when the slurry is mixed, the slurry is injected into the mixing cavity through the feed inlet, then the motor is operated through the external controller, the position shielding tank drives the stirring rod to swing, the suction and connection liquid component can extract the slurry in the mixing cavity in the process, then the suction and connection liquid component is discharged into the position shielding tank through the flow collision piece, the mixing efficiency among the slurries is improved through sucking and spraying the slurry, and then part of the mixed slurry is discharged into the mixing cavity again through the liquid flow device, so that the mixing efficiency of the slurry can be improved repeatedly.

Description

Domestic ceramic pug stirring and homogenizing device and method thereof

Technical Field

The invention relates to the field of ceramic homogenization stirring, in particular to a stirring and homogenizing device and a stirring and homogenizing method for domestic ceramic pugs.

Background

Domestic ceramic is also referred to as tableware or home porcelain, and as the name implies, it is an essential domestic porcelain in the daily life of people. The domestic ceramic takes clay as a processing raw material, and is prepared into a finished product through processes such as stirring and homogenization; generally when stirring ceramic slurry, directly pour the thick liquids raw materials into equipment in, drive the rotation of puddler through the motor and carry out the mixing treatment to it afterwards, and the thick liquids raw materials stirs when pouring into equipment, leads to the thick liquids to be the layering distribution in equipment easily, and the puddler only can transversely stir when stirring the thick liquids simultaneously, so can lead to its mixing efficiency low to influence the stirring homogenization efficiency of device.

Disclosure of Invention

The invention aims at: in order to solve the problem of low mixing efficiency of slurry, a domestic ceramic pug stirring and homogenizing device and a method thereof are provided.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a domestic ceramics pug stirring homogenization device, includes the homogenization jar, the inside of homogenization jar is fixed with the compartment ring, the control chamber that is located the compartment ring top is offered to the inside of homogenization jar, the inside of homogenization jar is provided with the compounding chamber that is located the compartment ring below, the feed inlet is installed in the outside of homogenization jar, and the feed inlet extends to the inboard of compounding chamber, the bottom of homogenization jar is provided with the bin outlet, the motor is installed at the top of homogenization jar, the output of motor is connected with hides a jar, the bottom of hiding a jar is provided with the puddler, and the bottom of puddler extends to the inboard of compounding chamber, the outside of puddler is connected with the pipette through leading to inhale to link the liquid subassembly, it links to each other with hiding a jar through touching the stream spare to draw to link to each other, the outside of hiding a jar is provided with the liquid ware.

As still further aspects of the invention: the utility model provides a draw and inhale even liquid subassembly is including being fixed in the internal gear ring of operating cavity inner wall, the outside of puddler is fixed with two feed liquor storehouses, and two feed liquor storehouses are along the vertical axis symmetry setting of puddler, the one end in feed liquor storehouse is fixed with even dish frame, the bottom of even dish frame is connected with from changeing the straight-tooth wheel through the pivot rotation, from changeing the outside of straight-tooth wheel and the inboard of internal gear ring and meshing, the inboard in feed liquor storehouse is provided with the chock block, the one end of chock block is fixed with the pull rod, and the pull rod extends to the outside in feed liquor storehouse, the one end of pull rod is fixed with the straight-tooth cartridge, the bottom from changeing the straight-tooth wheel is fixed with the eccentric column, and the eccentric column is located the inboard of straight-tooth cartridge, the outside of puddler is fixed with even tooth fixed block, even tooth fixed block is located the below in feed liquor storehouse, the outside in feed liquor storehouse is provided with the unidirectional flow liquid pipe, the inboard of unidirectional flow liquid pipe is fixed with the link ring, the top of link ring is fixed with the flow deflector inboard, link-stop plate, link plate T is provided with the flow guide plate, the flow guide plate is connected with the hose, link bottom portion and the hose is connected with the bottom of liquid suction pipe, the side of the pump, the pump is connected with the hose.

As still further aspects of the invention: the top and the bottom of feed liquor storehouse all are provided with one-way liquid pipe, the diameter of water conservancy diversion hole is greater than the diameter at T type movable support top, the diameter of spoiler is greater than the diameter of water conservancy diversion hole.

As still further aspects of the invention: the layer is inhaled the unit and is connected in the straight gear of putting of linking tooth fixed block one end including rotating through the pivot, and the one end of straight gear of putting links to each other with the pipette, the one end of linking tooth fixed block is rotated through the pivot and is connected with the gear of dialling, and the gear of dialling is located one side of straight gear of putting, the both sides bottom of straight slot card frame is fixed with the link, the one end of link is fixed with straight rack, and straight rack meshes with the gear of dialling mutually, be certain contained angle between the pipette of linking tooth fixed block both sides.

As still further aspects of the invention: the flow collision part comprises a spraying connecting pipe connected to the top of the unidirectional flow liquid pipe, the spraying connecting pipe is located above the liquid inlet bin, the top of the spraying connecting pipe penetrates through the inner side of the position shielding tank, the top of the spraying connecting pipe is connected with a reducer pipe, a conical flow guiding block is fixed on the inner wall of the position shielding tank, and the conical flow guiding block is located below the reducer pipe.

As still further aspects of the invention: the liquid flowing device comprises a communicating hole formed in one side of the conical flow guiding block, a liquid flowing connecting pipe is arranged at the bottom of the position shielding tank and located below the communicating hole, one end of the liquid flowing connecting pipe is connected with a corrugated hose, one end of the corrugated hose is connected with a liquid discharging pipe, and the bottom of the liquid discharging pipe extends to the inner side of the mixing cavity.

As still further aspects of the invention: the vibration flow connecting liquid piece is characterized by comprising guide connecting sliding rails arranged on two sides of the liquid inlet bin, wherein a sliding block is connected to the inner side of the guide connecting sliding rail in a sliding manner, a push rod is connected to one side of the sliding block in a rotating manner through a rotating shaft, a movable block is connected to one end of the push rod in a rotating manner, the movable block is arranged on the outer side of a liquid discharge pipe, a vibration knocking rod is fixed to one end of the movable block, which is far away from the liquid discharge pipe, a reset spring connected with the liquid inlet bin is arranged on one side of the sliding block, two sides of the push rod are positioned on the reset spring, a swing pin frame is connected to one end of the sliding block in a rotating manner through the rotating shaft, a torsion spring is connected to the outer side of the rotating shaft, which is connected with the sliding block, a stop pin is inserted into one end of the swing pin frame, a top pin spring connected with the swing pin frame is arranged on the outer side of the stop pin frame, triangular guide blocks are fixed on two sides of the straight groove clamping frame, and a connecting plate is fixed to the bottom of the swing pin frame.

As still further aspects of the invention: one end of the clamping pin is flush with one end of the connecting plate, and the transverse central axis of the clamping pin is in a superposition state with the transverse central axis of the connecting plate.

As still further aspects of the invention: one end of the shake knocking rod is attached to the stirring rod, and the width of the ejector rod is attached to the inner side of the guide and connection sliding rail.

As still further aspects of the invention: the distance from the eccentric column to the center of the secondary turning straight gear is equal to the length of the inner side of the liquid inlet bin, the outer side of the chock is attached to the inner wall of the liquid inlet bin, and the width of the straight slot clamping frame is equal to the diameter of the secondary turning straight gear.

A domestic ceramic pug stirring and homogenizing method, which uses the domestic ceramic pug stirring and homogenizing device, comprises the following steps: injecting the slurry into the mixing cavity through the feed inlet; then the motor is operated by an external controller, at the moment, the position shielding tank drives the stirring rod to swing, and the suction and liquid connection component can extract the slurry in the mixing cavity in the process; then the slurry is discharged into a shading tank through a collision piece, and the mixing efficiency between the slurries is improved through sucking and spraying the slurries; and then, part of the mixed slurry can be discharged into the mixing cavity again through the liquid flowing device, and the mixing efficiency of the slurry can be improved by repeating the steps for a plurality of times.

Compared with the prior art, the invention has the beneficial effects that:

1. through setting up and guiding and sucking the liquid component, touching the flow piece, liquid flowing device, when mixing the slurry, pour slurry into the compounding cavity through the feed inlet, then make the motor operate through the external controller, hide the position jar and will drive the puddler and swing at this moment, the slurry that the liquid component can be sucked in the compounding cavity in this process, then bump the flow piece and discharge into and hide the position jar, through sucking, spray to the slurry to increase the mixing efficiency between the slurries, can then discharge some slurries after mixing into the compounding cavity through the liquid flowing device again, so can improve the mixing homogeneity efficiency of slurry repeatedly;

2. through setting up shake and flow the liquid piece, when the triangle guide block is along with the removal of straight flute card frame and stopping the position round pin bottom contact, triangle guide block accessible its one side inclined plane extrudees stopping the position round pin, at this moment triangle guide block just can move to one side of stopping the position round pin, when straight flute card frame is recovered, triangle guide block accessible its one side plane drive pendulum round pin frame and remove, at this moment the sliding block moves along leading the even slide rail, reset spring contracts simultaneously, the sliding block makes movable block drive shake and knock the pole and keep away from the puddler, along with the removal that triangle guide block drove pendulum round pin frame can make the link plate contact with the position round pin, at this moment the link plate just can receive the hindrance of screens round pin, so alright make one end perk of pendulum round pin frame, stopping position round pin and triangle guide block separate, at this moment the sliding block just can recover under reset spring elastic restoring force effect, so alright make shake the pole beat the puddler, with the thick liquids of stirring pole bottom shake the puddler, prevent that the thick liquids on the puddler surface from causing the influence to the use of follow-up equipment, also increase simultaneously, the thick liquids in the position jar drive and mix the drain and mix the range of flow when moving relatively when the position of the slurry in the mixing pipe is moved to the mixing pipe has been improved and mixed material can take place in the mixing position and has been discharged the mixing position to the position of the mixing pipe;

3. through setting up the layer and inhale the unit, the straight rack is moved to the relative feed liquor storehouse of straight flute card frame accessible link drive straight rack, the link just can drive the shifting gear and rotate this moment, the shifting gear just makes the shifting straight gear of both sides carry out the syntropy rotation when rotating, be located the pipette one end perk that even teeth decided one side this moment, and be located the pipette that even teeth decided the piece opposite side and move down, so alright make the pipette absorb the thick liquids of different positions department, thereby improve the suction range of pipette, the cooperation bumps the thick liquids that the piece alright make different positions department and bumps and mix, thereby improve the whole mixing efficiency to the thick liquids of equipment.

Drawings

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

FIG. 2 is a partial cross-sectional view of the homogenization tank of the present invention;

FIG. 3 is a schematic diagram of the connection of the liquid inlet bin and the stirring rod;

FIG. 4 is a schematic view of the structure of the liquid inlet bin of the invention;

FIG. 5 is a partial cross-sectional view of a feed bin of the present invention;

FIG. 6 is a schematic view of the internal structure of the unidirectional fluid conduit of the present invention;

FIG. 7 is a schematic view of a seismological fluid coupling according to the present invention;

FIG. 8 is a schematic view of the internal structure of the shading tank of the present invention;

fig. 9 is a schematic diagram of the connection of the swing pin frame and the sliding block according to the present invention.

In the figure: 1. a homogenization tank; 2. a feed inlet; 3. a discharge port; 4. a motor; 501. a manipulation chamber; 502. a mixing cavity; 503. a compartment ring; 504. a position shielding tank; 505. a spray connecting pipe; 506. a slave spur gear; 507. a connecting hose; 508. a pipette; 509. a stirring rod; 510. a shifting gear; 511. positioning a spur gear; 512. a liquid discharge pipe; 513. a tray connecting frame; 514. a liquid inlet bin; 515. a connecting frame; 516. tooth-connected fixed blocks; 517. triangular guide blocks; 518. a knock pin spring; 519. a stop pin; 520. a swing pin frame; 521. a corrugated hose; 522. knocking a rod by vibration; 523. a guide connecting slide rail; 524. a return spring; 525. a clamping pin; 526. a push rod; 527. a straight slot clamping frame; 528. a unidirectional fluid pipe; 529. an eccentric column; 530. a pull rod; 531. a chock; 532. a straight rack; 533. a deflector aperture; 534. a movable plate spring; 535. a T-shaped movable frame; 536. a connecting ring; 537. a spoiler; 538. a connecting plate; 539. a movable block; 540. a sliding block; 541. a fluid connection pipe; 542. a conical flow guiding block; 543. communicating the communicating hole; 544. a reducer pipe; 545. a torsion spring; 546. an inner gear ring.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the description of the present invention, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "configured" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art. Hereinafter, an embodiment of the present invention will be described in accordance with its entire structure.

Referring to fig. 1 to 9, in the embodiment of the invention, a domestic ceramic pug stirring and homogenizing device comprises a homogenizing tank 1, wherein a compartment ring 503 is fixed in the homogenizing tank 1, a control cavity 501 positioned above the compartment ring 503 is arranged in the homogenizing tank 1, a mixing cavity 502 positioned below the compartment ring 503 is arranged in the homogenizing tank 1, a feed inlet 2 is arranged on the outer side of the homogenizing tank 1, the feed inlet 2 extends to the inner side of the mixing cavity 502, a discharge port 3 is arranged at the bottom of the homogenizing tank 1, a motor 4 is arranged at the top of the homogenizing tank 1, an output end of the motor 4 is connected with a position shielding tank 504, a stirring rod 509 is arranged at the bottom of the position shielding tank 504, the bottom of the stirring rod 509 extends to the inner side of the mixing cavity 502, a liquid suction and connection component is connected with a liquid suction pipe 508 through a liquid suction and connection component, the outer side of the position shielding tank 504 is provided with a liquid flow device through a flow collision part.

In this embodiment, when slurry is mixed, the slurry is injected into the mixing cavity 502 through the feed inlet 2, then the motor 4 is operated through the external controller, the position shielding tank 504 drives the stirring rod 509 to swing, the slurry in the mixing cavity 502 can be pumped by the suction and connection liquid component in the process, then the slurry is discharged into the position shielding tank 504 through the collision piece, the mixing efficiency between the slurries is increased by sucking and spraying the slurry, and then part of the mixed slurry can be discharged into the mixing cavity 502 again through the liquid flowing device, so that the mixing efficiency of the slurry can be improved and the homogenization stirring efficiency of the slurry is improved.

Referring to fig. 2, 3, 4, 5 and 6, the suction connecting liquid component includes an inner gear ring 546 fixed on the inner wall of the operating cavity 501, two liquid inlet cabins 514 are fixed on the outer side of the stirring rod 509, the two liquid inlet cabins 514 are symmetrically arranged along the vertical central axis of the stirring rod 509, one end of each liquid inlet cabin 514 is fixed with a connecting disc frame 513, the bottom of each connecting disc frame 513 is rotatably connected with a driven straight gear 506 through a rotating shaft, the outer side of the driven straight gear 506 is meshed with the inner side of the inner gear ring 546, a plug 531 is arranged on the inner side of each liquid inlet cabin 514, a pull rod 530 is fixed on one end of each plug 531, the pull rod 530 extends to the outer side of each liquid inlet cabin 514, a straight groove clamping frame 527 is fixed on one end of each pull rod 530, an eccentric column 529 is fixed on the bottom of the driven straight gear 506, and the eccentric column 529 is located on the inner side of the straight groove clamping frame 527, the outside of puddler 509 is fixed with even tooth fixed block 516, even tooth fixed block 516 is located the below of feed liquor storehouse 514, the outside of feed liquor storehouse 514 is provided with unidirectional current liquid pipe 528, unidirectional current liquid pipe 528's inboard is fixed with even bit ring 536, even bit ring 536's top is fixed with the baffle 537, even bit ring 536's inboard has seted up the water conservancy diversion hole 533, the bottom of baffle 537 is connected with T type and moves the frame 535, the bottom of T type moves the frame 535 passes water conservancy diversion hole 533 to even bit ring 536's bottom, the outside of T type moves the frame 535 is provided with the movable plate spring 534 that links to each other with even bit ring 536, unidirectional current liquid pipe 528's bottom is connected with coupling hose 507, coupling hose 507's bottom is provided with pipette 508, pipette 508 links to each other through the layer suction unit with even tooth fixed block 516, shake and the liquid piece that links to each other with the liquid ware is installed to shake in both sides of feed liquor storehouse 514.

In this embodiment, when the motor 4 drives the position shielding tank 504 and the stirring rod 509 to rotate, the straight gear 506 rotates along the internal gear ring 546, the plug 531 is pulled by the eccentric column 529 and the pull rod 530 from the straight gear 506, the cavity in the liquid inlet 514 is increased, negative pressure is formed in the liquid inlet 514 during this process, the one-way flow plate 537 in the one-way flow tube 528 at the bottom of the liquid inlet 514 is moved upwards, so that the slurry in the mixing cavity 502 flows into the liquid inlet 514 through the liquid suction tube 508, the connecting hose 507, the one-way flow tube 528 and the flow guiding hole 533 under the action of pressure, the pull rod 530 is pushed by the continuous rotation of the straight gear 506, so that the plug 531 extrudes the slurry in the liquid inlet 514, the one-way flow tube 528 at the bottom of the liquid inlet 514 is blocked by the baffle 537, the one-way flow tube 528 above the liquid inlet 514 is opened, so that the slurry in the liquid inlet 514 is pushed to the position shielding unit through the collision piece 504 to mix the slurry in the different positions, and the raw materials are adsorbed by the different positions.

Referring to fig. 5 and 6, the top and bottom of the liquid inlet bin 514 are provided with unidirectional liquid flow pipes 528, the diameter of the flow guiding hole 533 is larger than the diameter of the top of the T-shaped movable frame 535, and the diameter of the flow blocking plate 537 is larger than the diameter of the flow guiding hole 533.

In this embodiment, the structure is provided to make the baffle 537 block the diversion hole 533, so that when the baffle 537 is far away from the vicinal ring 536 under the pressure, the slurry at the bottom of the vicinal ring 536 passes through the unidirectional flow tube 528 through the diversion hole 533, thereby making the slurry sucked by the pipette 508 flow unidirectionally.

Referring to fig. 2, 3 and 4, the layer suction unit includes a positioning spur gear 511 rotatably connected to one end of a tooth fixing block 516 through a rotation shaft, one end of the positioning spur gear 511 is connected to a liquid suction pipe 508, one end of the tooth fixing block 516 is rotatably connected to a shifting gear 510 through the rotation shaft, the shifting gear 510 is located at one side of the positioning spur gear 511, connecting frames 515 are fixed to bottoms of two sides of the straight slot clamping frames 527, a spur rack 532 is fixed to one end of each connecting frame 515, the spur rack 532 is meshed with the corresponding shifting gear 510, and a certain included angle is formed between the liquid suction pipes 508 on two sides of the tooth fixing block 516.

In this embodiment, when the straight slot clamping frame 527 moves relative to the liquid inlet bin 514, the connecting frame 515 drives the straight rack 532 to move, at this time, the connecting frame 515 drives the shifting gear 510 to rotate, when the shifting gear 510 rotates, the shifting straight gears 511 on two sides can rotate in the same direction, at this time, one end of the liquid suction pipe 508 located on one side of the continuous tooth fixing block 516 is tilted, and the liquid suction pipe 508 located on the other side of the continuous tooth fixing block 516 moves down, so that the liquid suction pipe 508 can suck the slurry at different positions, thereby improving the sucking range of the liquid suction pipe 508, and the slurry at different positions can be collided and mixed by matching with the collision piece, thereby improving the mixing efficiency of the whole device for the slurry.

Referring to fig. 3 and 8, the collision member includes a spraying connection pipe 505 connected to the top of the unidirectional flow pipe 528, the spraying connection pipe 505 is located above the liquid inlet bin 514, the top of the spraying connection pipe 505 penetrates to the inner side of the shielding tank 504, the top of the spraying connection pipe 505 is connected with a reducer 544, a conical flow guiding block 542 is fixed on the inner wall of the shielding tank 504, and the conical flow guiding block 542 is located below the reducer 544.

In this embodiment, when the slurry in the liquid inlet bin 514 is extruded into the spraying connecting pipe 505 through the unidirectional liquid flowing pipe 528, the slurry can be discharged through the reducing pipe 544, in this process, since one end diameter of the reducing pipe 544 is smaller than that of the spraying connecting pipe 505, a certain impact force can be generated when the slurry is extruded out of the reducing pipe 544, the slurry sprayed out of the reducing pipe 544 can collide in the shielding tank 504, so that the slurries at different positions sucked by the liquid suction pipe 508 can collide, the sprayed slurry can be sprayed, and the slurry can be mixed under the action of gravity, so that the mixing efficiency between the slurries can be improved.

Referring to fig. 2, 3 and 8, the liquid flowing device includes a communicating hole 543 formed on one side of a conical flow guiding block 542, a liquid flowing connecting pipe 541 is mounted at the bottom of the position shielding tank 504, the liquid flowing connecting pipe 541 is located below the communicating hole 543, one end of the liquid flowing connecting pipe 541 is connected with a corrugated hose 521, one end of the corrugated hose 521 is connected with a liquid draining pipe 512, and the bottom of the liquid draining pipe 512 extends to the inner side of the mixing cavity 502.

In this embodiment, by arranging this structure, the slurry ejected from the reducer 544 can fall along the inclined plane of the tapered guide block 542 to the inner side of the through hole 543 under the action of gravity, and then can flow into the mixing cavity 502 through the fluid connecting pipe 541, the bellows 521 and the liquid discharge pipe 512, so as to increase the stability of the slurry discharged after mixing in the mask tank 504.

Referring to fig. 2, 3, 4, 7 and 9, the shake-flow connecting member includes a guide slide rail 523 mounted on two sides of the liquid inlet bin 514, a sliding block 540 is slidably connected on the inner side of the guide slide rail 523, one side of the sliding block 540 is rotatably connected with a push rod 526 through a rotating shaft, one end of the push rod 526 is rotatably connected with a movable block 539 through the rotating shaft, the movable block 539 is mounted on the outer side of the liquid outlet tube 512, one end of the movable block 539 far away from the liquid outlet tube 512 is fixed with a shake knocking rod 522, one side of the sliding block 540 is provided with a return spring 524 connected with the liquid inlet bin 514, the return spring 524 is located on two sides of the push rod 526, one end of the sliding block 540 is rotatably connected with a swinging pin frame 520 through the rotating shaft, the outer side of the rotating shaft connected with the sliding block 540 is clamped with a torsion spring 545, one end of the swinging pin frame 520 is spliced with a stop pin 519, the outer side of the stop pin 519 is provided with a top pin 518 connected with the swinging pin frame 520, two sides of the straight slot clamping frame 527 are fixed with triangular guide blocks 517, the bottom of the swinging pin 520 is fixed with a connecting plate 538, and one end of the guide pin frame 520 is fixed with a torsion pin 525.

In this embodiment, when the triangular guide 517 moves along with the straight slot clamping frame 527 and contacts with the bottom of the stop pin 519, the triangular guide 517 can squeeze the stop pin 519 through the inclined plane at one side of the triangular guide 517, at this time, the triangular guide 517 can move to one side of the stop pin 519, when the straight slot clamping frame 527 recovers, the triangular guide 517 can drive the swing pin frame 520 through the plane at one side of the triangular guide 517 to move, at this time, the sliding block 540 moves along the guide and connection sliding rail 523, and at the same time, the reset spring 524 contracts, the sliding block 540 enables the movable block 539 to drive the vibration striking rod 522 to be far away from the stirring rod 509, and along with the movement of the triangular guide 517 to drive the swing pin frame 520, the connecting plate 538 can be contacted with the stop pin 525, at this time, the connecting plate 538 can be hindered by the stop pin 525, so that one end of the swing pin frame 520 can lift up, the stop pin 519 can recover quickly under the elastic recovery force of the reset spring 524, at this time, the vibration striking rod 522 can strike the stirring rod 509, and the bottom of the stirring rod 509 is also separated from the stirring rod 509, and the stirring rod 509 is also prevented from moving along with the movement of the triangular guide 517, and the stirring rod 517 can move to the surface of the mixing tank 512, and the mixing tank is prevented from being moved relatively to the mixing tank 512.

Referring to fig. 7, one end of the retaining pin 525 is flush with one end of the connecting plate 538, and the transverse central axis of the retaining pin 525 is coincident with the transverse central axis of the connecting plate 538.

In the present embodiment, the structure is provided such that the locking pin 525 and the link plate 538 are positioned at the same level, so that the locking pin 525 blocks the movement of the link plate 538.

Referring to fig. 7, one end of the knock rod 522 is attached to the stirring rod 509, and the width of the push rod 526 is attached to the inner side of the guide rail 523.

In the present embodiment, by providing this structure, the stability of the movement of the sliding block 540 relative to the guide rail 523 is increased, and at the same time, the accuracy of the collision of the knock rod 522 against the stirring rod 509 is also improved.

Referring to fig. 2 and 5, the distance from the eccentric column 529 to the center of the turning gear 506 is equal to the length of the inner side of the liquid inlet chamber 514, the outer side of the plug 531 is attached to the inner wall of the liquid inlet chamber 514, and the width of the straight slot clamping frame 527 is equal to the diameter of the turning gear 506.

In this embodiment, by setting this structure, when the slave rotation spur gear 506 rotates relative to the disc frame 513, the eccentric column 529 drives the spur slot clamping frame 527 to perform stable movement, so as to increase the stability of the slurry discharging and sucking liquid inlet bin 514.

The foregoing description is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical solution of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims (9)

1. The utility model provides a domestic ceramic pug stirring homogenization device, includes homogenization jar (1), its characterized in that, the inside of homogenization jar (1) is fixed with compartment ring (503), the control chamber (501) that is located compartment ring (503) top is seted up to the inside of homogenization jar (1), the inside of homogenization jar (1) is provided with compounding chamber (502) that are located compartment ring (503) below, feed inlet (2) are installed in the outside of homogenization jar (1), and feed inlet (2) extend to the inboard of compounding chamber (502), the bottom of homogenization jar (1) is provided with bin outlet (3), motor (4) are installed at the top of homogenization jar (1), the output of motor (4) is connected with and hides a jar (504), the bottom of hiding a jar (504) is provided with puddler (509), the bottom of puddler (509) extends to the inboard of compounding chamber (502), the outside of puddler (509) is connected with pipe (508) through the drainage component, the drainage component is connected with the outside of hiding jar (504) through the drainage component, and the drainage component is provided with the outside of hiding jar (504);

the suction connection liquid component comprises an inner gear ring (546) fixed on the inner wall of the operating cavity (501), two liquid inlet cabins (514) are fixed on the outer side of the stirring rod (509), the two liquid inlet cabins (514) are symmetrically arranged along the vertical central axis of the stirring rod (509), a disc connecting frame (513) is fixed on one end of the liquid inlet cabins (514), the bottom of the disc connecting frame (513) is rotationally connected with a driven straight gear (506) through a rotating shaft, the outer side of the driven straight gear (506) is meshed with the inner side of the inner gear ring (546), a plug block (531) is arranged on the inner side of the liquid inlet cabins (514), a pull rod (530) is fixed on one end of the plug block (531), the pull rod (530) extends to the outer side of the liquid inlet cabins (514), a straight groove clamping frame (527) is fixed on one end of the pull rod (530), an eccentric column (529) is fixed on the inner side of the straight groove clamping frame (527), the stirring rod (509) is meshed with the inner side of the inner gear ring (546), the plug block (528) is fixed on the outer side of the stirring rod (509), the liquid inlet pipe (528) is fixed on the inner side of the fixed pipe (536), the liquid inlet pipe (528) is fixed on the inner side of the fixed pipe (528), the utility model discloses a liquid sucking device, including baffle (537), connecting ring (536), connecting hose (507)'s bottom is provided with water conservancy diversion hole (533), and the bottom of baffle (537) is connected with T type and moves frame (535), and the bottom that water conservancy diversion hole (533) was passed to connecting ring (536) is moved to the bottom of T type, the outside that moves frame (535) is provided with movable plate spring (534) that link to each other with connecting ring (536), the bottom of uniflow hose (528) is connected with coupling hose (507), the bottom of coupling hose (507) is provided with pipette (508), and pipette (508) link to each other through the layer suction unit with linking tooth fixed block (516), shake and even liquid piece is installed to the both sides of feed liquor storehouse (514), shake even liquid piece and liquid flowing device link to each other.

2. The domestic ceramic pug stirring and homogenizing device according to claim 1, wherein the top and the bottom of the liquid inlet bin (514) are respectively provided with a unidirectional liquid flow pipe (528), the diameter of the flow guide hole (533) is larger than that of the top of the T-shaped movable frame (535), and the diameter of the flow blocking plate (537) is larger than that of the flow guide hole (533).

3. The domestic ceramic pug stirring and homogenizing device according to claim 1, wherein the layering suction unit comprises a positioning straight gear (511) rotatably connected to one end of a continuous tooth positioning block (516) through a rotating shaft, one end of the positioning straight gear (511) is connected with a liquid suction pipe (508), one end of the continuous tooth positioning block (516) is rotatably connected with a shifting gear (510) through the rotating shaft, the shifting gear (510) is located at one side of the positioning straight gear (511), connecting frames (515) are fixed at the bottoms of two sides of the straight groove clamping frames (527), one end of each connecting frame (515) is fixedly provided with a straight rack (532), the straight rack (532) is meshed with the corresponding liquid suction pipe (508) on two sides of the continuous tooth positioning block (516), and a certain included angle is formed between the liquid suction pipes (508).

4. The stirring and homogenizing device for ceramic pugs for daily use according to claim 3, wherein the flow collision piece comprises a spraying connecting pipe (505) connected to the top of a unidirectional flow pipe (528), the spraying connecting pipe (505) is located above the liquid inlet bin (514), the top of the spraying connecting pipe (505) penetrates through the inner side of the position shielding tank (504), the top end of the spraying connecting pipe (505) is connected with a reducer pipe (544), a conical flow guide block (542) is fixed on the inner wall of the position shielding tank (504), and the conical flow guide block (542) is located below the reducer pipe (544).

5. The stirring and homogenizing device for domestic ceramic pugs according to claim 4, wherein the liquid flowing device comprises a communicating hole (543) formed in one side of a conical guide block (542), a liquid flowing connecting pipe (541) is mounted at the bottom of the position shielding tank (504), the liquid flowing connecting pipe (541) is located below the communicating hole (543), one end of the liquid flowing connecting pipe (541) is connected with a corrugated hose (521), one end of the corrugated hose (521) is connected with a liquid draining pipe (512), and the bottom of the liquid draining pipe (512) extends to the inner side of the mixing cavity (502).

6. The stirring and homogenizing device for ceramic pugs for daily use according to claim 5, wherein the vibration flow connecting piece comprises guide connecting sliding rails (523) arranged on two sides of the liquid inlet bin (514), sliding blocks (540) are slidably connected on the inner sides of the guide connecting sliding rails (523), one sides of the sliding blocks (540) are rotatably connected with ejector rods (526) through rotating shafts, one ends of the ejector rods (526) are rotatably connected with movable blocks (539) through rotating shafts, the movable blocks (539) are arranged on the outer sides of the liquid outlet tubes (512), vibration knocking rods (522) are fixedly arranged on one ends of the movable blocks (539) far away from the liquid outlet tubes (512), return springs (524) connected with the liquid inlet bin (514) are arranged on one sides of the sliding blocks (540), swing pin frames (520) are rotatably connected with rotating shafts 519), torsion springs (545) are clamped on the outer sides of the connection sides of the sliding blocks (540), one ends of the swing pin frames (520) are fixedly connected with triangular pin frames (538) of the guide blocks (538), the two sides of the swing frames (538) are fixedly connected with triangular pin frames (518), one end of the guide connection sliding rail (523) is fixed with a clamping pin (525).

7. The domestic ceramic pug stirring and homogenizing device according to claim 6, wherein one end of the clamping pin (525) is flush with one end of the connecting plate (538), and a transverse central axis of the clamping pin (525) is in a superposition state with a transverse central axis of the connecting plate (538);

one end of the shake knocking rod (522) is attached to the stirring rod (509), and the width of the ejector rod (526) is attached to the inner side of the guide and connection sliding rail (523).

8. The domestic ceramic pug stirring and homogenizing device according to claim 1, wherein the distance from the eccentric column (529) to the center of the turning straight gear (506) is equal to the length of the inner side of the liquid inlet bin (514), the outer side of the plug block (531) is attached to the inner wall of the liquid inlet bin (514), and the width of the straight groove clamping frame (527) is equal to the diameter of the turning straight gear (506).

9. A domestic ceramic pug stirring and homogenizing method using the domestic ceramic pug stirring and homogenizing device according to any one of claims 1 to 8, characterized by comprising: injecting the slurry into the mixing cavity (502) through the feed inlet (2); then the motor (4) is operated by an external controller, at the moment, the position shielding tank (504) drives the stirring rod (509) to swing, and in the process, the suction connecting liquid component can extract the slurry in the mixing cavity (502); then the slurry is discharged into a shading tank (504) through a collision piece, and the mixing efficiency between the slurries is increased through sucking and spraying the slurries; and then discharging part of the mixed slurry into the mixing cavity (502) again through the liquid flowing device, and repeating the steps for a plurality of times.