CN111036356A

CN111036356A - Efficient preparation machine for ceramic glaze production

Info

Publication number: CN111036356A
Application number: CN201911241792.0A
Authority: CN
Inventors: 蔡立忠
Original assignee: Anhui Maiyuan Network Technology Co Ltd
Current assignee: Anhui Maiyuan Network Technology Co Ltd
Priority date: 2019-12-06
Filing date: 2019-12-06
Publication date: 2020-04-21

Abstract

The invention relates to the technical field of ceramic glaze production equipment, in particular to an efficient preparation machine for ceramic glaze production; the rotation of a servo motor is used as a motive power, and a first rotating shaft is driven to rotate through transmission, so that glaze raw materials put into a discharging pipe are firstly crushed by a crushing knife and then fall into a grinding channel; the grinding end is also driven by the first rotating shaft to grind the raw materials; the ground raw materials fall into a filter cavity and are filtered by a filter screen; the stirring box and the pumping and discharging assembly are also arranged, and the piston works by utilizing rotation to pump and discharge water into the stirring box, so that the raw materials falling into the stirring box from the material guide pipe are dissolved into glaze slurry; still set up the stirring subassembly, utilized the transmission to make the stirring rod mix the stirring in to the agitator tank equally, guaranteed the homogeneity of glaze slip.

Description

Efficient preparation machine for ceramic glaze production

Technical Field

The invention relates to the technical field of ceramic glaze production equipment, in particular to an efficient preparation machine for ceramic glaze production.

Background

Ceramic English ceramics (or China) is a variety of products made of materials which are prepared by using natural clay and various natural minerals as main raw materials through crushing, mixing, molding and calcining.

Articles made of pottery clay and fired at high temperature in special kilns have been called ceramics, which are a general term for pottery and porcelain. The traditional concept of ceramics refers to all artificial industrial products which take inorganic nonmetallic minerals such as clay and the like as raw materials. It includes various products made up by using clay or clay-containing mixture through the processes of mixing, forming and calcining. Ranging from the coarsest earthenware to the finest fine ceramics and porcelain. The main raw material of the ceramic is silicate mineral (such as clay, quartz and the like) in nature, so the ceramic and the ceramic belong to the category of silicate industry with industries such as glass, cement, enamel, refractory materials and the like.

The main production areas of the ceramics are Peng Ton, Jing De Town, Linling, Gao an, Fengcheng, Pingxiang, Li Chuan, Buddha mountain, Chaozhou, German, Zibo, Tangshan and Bei Liu. In addition, Jingdezhen is one of the porcelain cities in China.

The development history of the ceramic is an important component of the Chinese civilization history, China, as one of four civilization ancient countries, makes outstanding contributions to the progress and development of the human society, wherein the invention and the development of the ceramic have unique meanings, and the China has different artistic styles and different technical characteristics in each generation historically. "china" in english has the meaning of both china and ceramics, and clearly shows that china is the home country of ceramics. As early as one thousand years ago as the technology for manufacturing porcelain, Chinese has already manufactured very delicate ceramics. China is one of the earliest countries in the world to apply pottery, and Chinese porcelain is highly popular among people because of its high practicability and artistry.

In the manufacturing process of ceramics, glazing is an important process. The painted porcelain blank is rough and unsmooth, and is completely different, smooth and bright after being glazed: different glazing methods have different effects, and the common glazing methods include dipping, spraying, swinging, spraying, brushing and the like. Glaze here means a thin layer of colourless or coloured vitreous material covering the surface of the ceramic article.

The glaze material is prepared by mixing mineral raw materials (feldspar, quartz, talc, kaolin, etc.) with raw materials according to a certain proportion (part of raw materials can be made into frits first), grinding to prepare glaze slurry, applying the glaze slurry on the surface of a blank body, and calcining at a certain temperature. It can increase the mechanical strength, thermal stability and dielectric strength of the product, and also has the characteristics of beautifying the ware, being convenient for wiping and washing, being not eroded by the fishy smell of dust, etc.

In the prior art, the traditional manual grinding and water adding stirring modes are adopted for glaze processing, so that the efficiency is low, the automation degree is low, the requirements of industrial production cannot be obviously met, and the improvement is needed.

Disclosure of Invention

Technical problem to be solved

The invention aims to overcome the defects in the prior art and provides an efficient preparation machine for producing ceramic glaze.

(II) technical scheme

An efficient preparation machine for ceramic glaze production comprises a feeding pipe;

the upper section of the blanking pipe is a hopper with a large upper part and a small lower part; a top cover is arranged at the top of the hopper, and a charging opening is arranged at the left end of the top cover; a first rotating shaft is arranged in the hopper, and the first rotating shaft and the hopper are correspondingly provided with staggered crushing cutters;

the bottom end of the first rotating shaft extends into the middle section of the blanking pipe and is provided with a grinding end, the inner wall of the middle section of the blanking pipe is provided with a material guide bulge corresponding to the grinding end, and a grinding channel is formed between the grinding end and the material guide bulge; the grinding end head and the material guide bulge are correspondingly provided with a grinding bulge;

the lower section of the blanking pipe is provided with a filter cavity, and the bottom end of the blanking pipe is provided with a filter screen.

Preferably, the grinding end head comprises an upper part and a lower part, wherein the upper part is a necking structure with a large upper part and a small lower part, and the lower part is a flaring structure with a small upper part and a large lower part; the material guiding bulges are designed to be correspondingly waisted.

Preferably, the device also comprises a support, the support comprises a base, a vertical plate, a first support plate, a second support plate and a slide rod, the base is arranged below the blanking pipe, the vertical plate is fixedly connected to the right end of the base, and the first support plate, the second support plate and the slide rod are fixedly connected to the left side of the vertical plate from bottom to top in sequence; the slide bar is horizontally arranged, and the left end of the slide bar is connected with the right side wall of the blanking pipe.

Preferably, the device comprises a driving assembly, wherein the driving assembly comprises a servo motor, a first gear, a second gear, a first rod, a first sliding block, a first sliding rail, a sliding sleeve, a second rod and a rack; the servo motor is fixedly arranged on the second support plate through a motor base, the output end of the servo motor extends forwards and is connected with a first gear, the left side of the first gear is matched with the second gear, and the second gear is arranged on the second support plate through a mounting frame; the right end of the first rod is hinged with the disc surface of the first gear, and the left end of the first rod is provided with a first sliding block; the second gear is provided with a disk surface sliding block, and the disk surface sliding block is rotationally connected with the disk surface of the second gear; the first rod is provided with a slide way, and the disk surface slide block is matched with the slide way and can move along the slide way; the first sliding block is connected to a vertical first sliding rail in a sliding mode, a sliding sleeve is arranged at the top end of the first sliding rail, and the sliding sleeve is sleeved on the sliding rod and can move along the sliding rod; the top of the sliding sleeve is connected with a second rod, and the top end of the second rod is connected with a rack leftwards; the top end of the first rotating shaft extends out of the top cover and is provided with a driven gear, and the driven gear is matched with the rack.

Preferably, the cleaning device further comprises a filtering assembly, the filtering assembly comprises a third rod, a spring and a cleaning brush, and the right end of the third rod is connected with a first sliding rail; the third rod is also sleeved with a spring, the left end of the spring is propped against the outer wall of the blanking pipe, and the right end of the spring is propped against the left side of the first sliding rail; the left end of the third rod extends into the discharging pipe and is provided with a cleaning brush, and the brush hair of the cleaning brush is arranged facing the filter screen.

Preferably, the left side of the bottom end of the discharging pipe is also provided with a movable door, the top end of the movable door is hinged with the discharging pipe, and the bottom end of the movable door is connected with the discharging pipe through a detachable fixing bolt.

Preferably, the stirring device further comprises a stirring box, wherein the stirring box is arranged below the blanking pipe, and the top of the stirring box is provided with an opening and aligned with the outlet of the blanking pipe; the stirring box is fixedly connected on the base through a supporting rod.

Preferably, the piston type air conditioner further comprises a pumping and exhausting assembly, wherein the pumping and exhausting assembly comprises a piston cylinder, a second sliding rail and a second sliding block; the first rod is downwards connected with a second sliding rail through a connecting rod; the second sliding rail is horizontally arranged, and the bottom of the second sliding rail is connected with a second sliding block in a sliding manner; the piston cylinder is arranged on the first support plate, a piston plate is arranged in the piston cylinder, the top of the piston plate is connected with a piston rod, and the piston rod extends upwards out of the piston cylinder and is connected with the second slide block; one side of the bottom of the piston cylinder is connected with a liquid suction pipe, and a first check valve for controlling liquid to flow into the piston cylinder is arranged on the liquid suction pipe; the other side of the bottom end of the piston cylinder is connected with a liquid guide pipe, the liquid guide pipe extends to the top of the stirring box, and a second one-way valve for controlling liquid to flow out of the piston cylinder is arranged on the liquid guide pipe.

Preferably, the first slide rail and the second slide rail are i-shaped slide rails, and the first slide block and the second slide block are corresponding C-shaped slide blocks.

Preferably, the stirring device also comprises a stirring component, wherein the stirring component comprises a third gear, a first bevel gear, a second rotating shaft, a third rotating shaft and a stirring rod; the third gear is arranged on the right side of the first gear and is meshed with the first gear; the third gear is also arranged on the second support plate through the mounting frame; the third gear is coaxially connected with a first bevel gear, the first bevel gear is vertically meshed with a second bevel gear, the second bevel gear is connected with a second rotating shaft, and the second rotating shaft downwards penetrates through a second support plate and a first support plate and is rotatably connected with the base; a vertical third rotating shaft is arranged in the stirring box, and stirring rods are uniformly arranged on the third rotating shaft; the third rotating shaft downwards penetrates through the stirring box and is provided with a second driving wheel; a first driving wheel is correspondingly arranged on the second rotating shaft, and the first driving wheel is in transmission connection with the second driving wheel through a transmission belt; the bottom end of the third rotating shaft is rotatably connected with the base; the bottom of the stirring box is also connected with a liquid discharge pipe, and a valve is arranged on the liquid discharge pipe.

(III) advantageous effects

The invention provides an efficient preparation machine for ceramic glaze production, which has the following advantages:

1, a servo motor is adopted to drive a first gear to rotate, a second gear also rotates along with the first gear, and a first rod starts to do up-and-down reciprocating motion and left-and-right reciprocating motion; the first sliding block is connected with the first sliding rail in a sliding mode, the first sliding rail is guided by the sliding rod through the sliding sleeve, the first sliding rail reciprocates left and right and drives the rack to move left and right through the second rod, so that the rack drives the first rotating shaft to rotate through the driven gear, and glaze raw materials put into the feeding and discharging pipe are firstly crushed by the crushing cutter and then fall into the grinding channel; the grinding end is also driven by the first rotating shaft to grind the raw materials; the ground material falls into the filter chamber and is filtered by the filter screen.

2, when still utilizing a slide rail to remove about, drive the cleaning brush through No. three poles and clear up the mediation to the filter screen, prevent to block up, guarantee the filter effect.

3, still set up agitator tank and pump drainage subassembly, utilize a pole to drive No. two slide rails and do up-and-down reciprocating motion and left-and-right reciprocating motion, nevertheless because No. two sliders and No. two slide rail sliding connection to still receive the restriction of piston rod, make No. two sliders pass through the piston rod and drive the piston plate up-and-down motion, the cooperation feed liquor pipe, the check valve of catheter, the realization is pumped drainage with water and is advanced into the agitator tank, makes the raw materials that fall into the agitator tank from the passage dissolve into the glaze slip.

4, still set up the stirring subassembly, utilized a gear to drive No. three gear revolve to drive No. two pivot rotations through the bevel gear transmission, drive No. three pivot rotations through the drive wheel transmission again, thereby make the stirring rod mix the stirring in to the agitator tank, guarantee the homogeneity of glaze slip.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only for the present invention and protect some embodiments, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a block diagram of the present invention;

FIG. 2 is a block diagram of a drive assembly;

FIG. 3 is a view showing the structure of the blanking pipe;

FIG. 4 is a cross-sectional view of the polishing head;

FIG. 5 is a block diagram of the pumping assembly;

FIG. 6 is a view showing the structure of the slide rail and the slide block;

fig. 7 is a structural view of the stirring assembly.

In the drawings, the components represented by the respective reference numerals are listed below:

101-a base, 102-a vertical plate, 103-a first support plate, 104-a second support plate and 105-a sliding rod;

2-a blanking pipe, 201-a charging opening, 202-a hopper, 203-a material guiding bulge, 204-a filter cavity, 205-a movable door and 206-a fixing bolt;

3-driving component, 301-motor base, 302-first gear, 303-second gear, 304-first rod, 305-slideway, 306-disk surface slider, 307-first slider, 308-first slide rail, 309-slide sleeve, 310-second rod, 311-rack, 312-driven gear, 313-first rotating shaft, 314-crushing cutter, 315-grinding end head, 316-grinding projection;

4-stirring component, 401-third gear, 402-first bevel gear, 403-second bevel gear, 404-second rotating shaft, 405-first driving wheel, 406-driving belt, 407-second driving wheel, 408-third rotating shaft and 409-stirring rod;

5-piston cylinder, 501-piston plate, 502-catheter, 503-check valve II, 504-piston rod, 505-pipette, 506-check valve I;

6-stirring box, 601-liquid discharge pipe, 602-supporting rod;

701-rod III, 702-spring, 703-cleaning brush, 704-filter screen;

801-connecting rod, 802-sliding rail II and 803-sliding block II.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

An efficient preparation machine for ceramic glaze production comprises a feeding pipe 2;

the upper section of the blanking pipe 2 is provided with a hopper 201 with a large upper part and a small lower part; a top cover is arranged at the top of the hopper 201, and a feed inlet 201 is formed at the left end of the top cover; a first rotating shaft 313 is arranged in the hopper 201, and the first rotating shaft 313 and the hopper 201 are correspondingly provided with staggered crushing blades 314;

the bottom end of the first rotating shaft 313 extends into the middle section of the blanking pipe 2 and is connected with a grinding end head 315, a material guide bulge 203 is processed on the inner wall of the middle section of the blanking pipe 2 corresponding to the grinding end head 315, and a grinding channel is formed between the grinding end head 315 and the material guide bulge 203; the grinding end 315 and the material guide bulge 203 are also correspondingly provided with a grinding bulge 316;

the lower section of the feeding pipe 2 is provided with a filter cavity 204, and the bottom end of the feeding pipe 2 is provided with a filter screen 704.

The grinding end 315 includes an upper portion and a lower portion, the upper portion is a necking structure with a large upper portion and a small lower portion, and the lower portion is a flaring structure with a small upper portion and a large lower portion; the material guiding bulge 203 is designed to be correspondingly waisted.

The device also comprises a support, wherein the support comprises a base 101, a vertical plate 102, a first support plate 103, a second support plate 104 and a sliding rod 105, the base 101 is arranged below the discharging pipe 2, the vertical plate 102 is fixedly connected to the right end of the base 101, and the first support plate 103, the second support plate 104 and the sliding rod 105 are fixedly connected to the left side of the vertical plate 102 from bottom to top in sequence; the sliding rod 105 is horizontally arranged, and the left end of the sliding rod is connected with the right side wall of the blanking pipe 2;

the device also comprises a driving component 3, wherein the driving component 3 comprises a servo motor, a first gear 302, a second gear 303, a first rod 304, a first sliding block 307, a first sliding rail 308, a sliding sleeve 209, a second rod 310 and a rack 311; the servo motor is fixedly arranged on the second support plate 104 through a motor base 301, the output end of the servo motor extends forwards and is connected with a first gear 302, a second gear 303 is matched on the left side of the first gear 302, and the second gear 303 is arranged on the second support plate 104 through a mounting frame; the right end of the first rod 304 is hinged with the disk surface of the first gear 302, and the left end is fixedly connected with a first sliding block 307; the second gear 303 is provided with a disk surface sliding block 306, and the disk surface sliding block 306 is rotatably connected with the disk surface 303 of the second gear; the first rod 304 is provided with a slide way 305, and a disk surface slide block 306 is matched with the slide way 305 and can move along the slide way 305; the first sliding block 307 is connected to a vertical first sliding rail 308 in a sliding manner, the top end of the first sliding rail 308 is connected with a sliding sleeve 309, and the sliding sleeve 309 is sleeved on the sliding rod 105 and can move along the sliding rod 105; the top of the sliding sleeve 309 is connected with a second rod 310, and the top end of the second rod 310 is connected with a rack 311 leftwards; the top end of the first rotating shaft 313 extends out of the top cover and is connected with a driven gear 312, and the driven gear 312 is matched with the rack 311.

Specifically, the servo motor is started to drive the first gear 302 to rotate, the second gear 303 also rotates, and the first rod 301 starts to reciprocate up and down and left and right; since the first sliding block 307 is slidably connected with the first sliding rail 308, and the first sliding rail 308 is guided by the sliding rod 105 through the sliding sleeve 309, the first sliding rail 308 reciprocates left and right and drives the rack 311 to move left and right through the second rod 310, so that the rack 311 drives the first rotating shaft 313 to rotate through the driven gear 312; in consideration of the stability of connection, the first slide rail 308 is an i-shaped slide rail, and the first slide block 307 is a corresponding C-shaped slide block, so as to avoid falling off during movement.

The glaze raw materials are thrown in from a feed inlet 201, and are firstly crushed by a crushing knife 314 and then fall into a grinding channel; the grinding end 315 is also driven by the first rotating shaft 313 to grind the raw materials; the ground material falls into the filter cavity 204 and passes through the screen 704 to complete the filtration.

Due to the design of the grinding end head 315 and the waist-closing material guide bulge 203, the grinding channel is bent, so that the retention time of raw materials can be prolonged, and the grinding effect is improved.

Example 2

The cleaning device further comprises a filtering component, the filtering component comprises a third rod 701, a spring 702 and a cleaning brush 703, and the right end of the third rod 701 is connected with a first sliding rail 308; the third rod 701 is also sleeved with a spring 702, the left end of the spring 702 abuts against the outer wall of the blanking pipe 2, and the right end of the spring 702 abuts against the left side of the first sliding rail 308; the left end of the third rod 701 extends into the blanking pipe 2 and is connected with a cleaning brush 703, and the bristles of the cleaning brush 703 face the filter screen 704.

Wherein, unloading pipe 2 bottom left side still is equipped with dodge gate 205, and dodge gate 205 top hinges unloading pipe 2, the bottom is passed through detachable fixing bolt 206 and is connected with unloading pipe 2.

Specifically, when the first sliding rail 308 moves left and right, the cleaning brush 703 is driven by the third rod 701 to clean and dredge the filter screen 704, so that blockage is prevented, and the filtering effect is ensured. When slag discharge or recovery is required, the movable door 205 is opened to collect the slag.

Example 3

The stirring box 6 is arranged below the discharging pipe 2, and an opening is formed in the top of the stirring box 6 and aligned with an outlet of the discharging pipe 2; the stirring box 6 is fixedly connected to the base 101 through a support rod 602.

The piston cylinder is characterized by further comprising a pumping and exhausting assembly, wherein the pumping and exhausting assembly comprises a piston cylinder 5, a second sliding rail 802 and a second sliding block 803; the first rod 304 is downwards connected with a second sliding rail 802 through a connecting rod 801; the second sliding rail 802 is horizontally arranged, and the bottom of the second sliding rail is connected with a second sliding block 803 in a sliding manner; the piston cylinder 5 is arranged on the first support plate 103, a piston plate 501 is arranged in the piston cylinder 5, the top of the piston plate 501 is connected with a piston rod 504, and the piston rod 504 extends upwards out of the piston cylinder 5 and is connected with a second sliding block 803; one side of the bottom of the piston cylinder 5 is connected with a pipette 505, and the pipette 505 is provided with a first check valve 506 for controlling liquid to flow into the piston cylinder 5; the other side of the bottom end of the piston cylinder 5 is connected with a liquid guide pipe 502, the liquid guide pipe 502 extends to the top of the stirring box 6, and the liquid guide pipe 502 is provided with a second one-way valve 503 for controlling liquid to flow out of the piston cylinder 5.

The stirring box 6 is used for receiving the raw materials falling from the blanking pipe 2. The pipette 505 is connected to a water source to automatically add water to the stirring tank 6 from the piston cylinder 5. Specifically, the first rod 304 drives the second sliding rail 802 to reciprocate up and down and to reciprocate left and right, but the second sliding block 803 is connected with the second sliding rail 802 in a sliding manner and is limited by the piston rod 504, so that the second sliding block 803 drives the piston plate 501 to move up and down through the piston rod 504, and the liquid inlet pipe 505 and the one-way valve of the liquid guide pipe 502 are matched to realize water pumping and drainage, so that the raw materials in the stirring box 6 are dissolved into glaze slurry. In consideration of the connection stability, the second sliding rail 802 is an i-shaped sliding rail, and the second sliding block 803 is a corresponding C-shaped sliding block, so as to avoid falling off when moving up and down.

Example 4

The stirring device further comprises a stirring component 4, wherein the stirring component 4 comprises a third gear 401, a first bevel gear 402, a second bevel gear 403, a second rotating shaft 404, a third rotating shaft 408 and a stirring rod 409; the third gear 401 is arranged on the right side of the first gear 302 and meshed with the first gear 302; the third gear 401 is also mounted on the second support plate 104 through a mounting frame; the third gear 401 is coaxially connected with a first bevel gear 402, the first bevel gear 402 is vertically meshed with a second bevel gear 403, the second bevel gear 403 is connected with a second rotating shaft 404, and the second rotating shaft 404 downwards penetrates through the second support plate 104 and the first support plate 103 and is rotatably connected with the base 101; a vertical third rotating shaft 408 is arranged in the stirring box 6, and stirring rods 409 are uniformly connected to the third rotating shaft 408; a third rotating shaft 408 downwards penetrates through the stirring box 6 and is provided with a second driving wheel 407; a first driving wheel 405 is correspondingly arranged on the second rotating shaft 404, and the first driving wheel 405 is in driving connection with a second driving wheel 407 through a driving belt 406; the bottom end of the third rotating shaft 408 is rotatably connected with the base 101; the bottom of the stirring box 6 is also connected with a liquid discharge pipe 601, and a valve is arranged on the liquid discharge pipe 601.

Specifically, a gear 302 rotates, and No. three gear 401 also follows the rotation to drive No. two pivot 404 rotations through the bevel gear transmission, drive No. three pivot 408 rotations through the drive wheel transmission again, thereby make the stirring rod 409 mix the stirring in to agitator tank 6, guarantee the homogeneity of glaze slip.

It should be noted that the electrical components are all provided with power supplies, and the control method is the prior art, and is generally described herein for avoiding the redundancy of the description.

In the description herein, references to the description of "one embodiment," "an example," "a specific example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims

1. The efficient preparation machine for producing the ceramic glaze is characterized by comprising a feeding pipe (2);

the upper section of the blanking pipe (2) is provided with a hopper (202) with a large upper part and a small lower part; a top cover is arranged at the top of the hopper (202), and a feeding port (201) is arranged at the left end of the top cover; a first rotating shaft (313) is arranged in the hopper (202), and the first rotating shaft (313) and the hopper (202) are correspondingly provided with staggered crushing knives (314);

the bottom end of the first rotating shaft (313) extends into the middle section of the blanking pipe (2) and is provided with a grinding end (315), the inner wall of the middle section of the blanking pipe (2) is provided with a material guide bulge (203) corresponding to the grinding end (315), and a grinding channel is formed between the grinding end (315) and the material guide bulge (203); the grinding end head (315) and the material guide bulge (203) are also correspondingly provided with a grinding bulge (316);

the lower section of the blanking pipe (2) is provided with a filter cavity (204), and the bottom end of the blanking pipe (2) is provided with a filter screen (704).

2. The efficient preparation machine for ceramic glaze production according to claim 1, wherein the grinding head (315) comprises an upper part and a lower part, wherein the upper part is a necking structure with a large upper part and a small lower part, and the lower part is a flaring structure with a small upper part and a large lower part; the material guiding bulges (203) are designed to be correspondingly waisted.

3. The efficient preparation machine for producing the ceramic glaze according to claim 2, further comprising a support, wherein the support comprises a base (101), a vertical plate (102), a first support plate (103), a second support plate (104) and a sliding rod (105), the base (101) is arranged below the discharging pipe (2), the vertical plate (102) is fixedly connected to the right end of the base (101), and the first support plate (103), the second support plate (104) and the sliding rod (105) are fixedly connected to the left side of the vertical plate (102) from bottom to top; the slide bar (105) is horizontally arranged, and the left end of the slide bar is connected with the right side wall of the blanking pipe (2).

4. The efficient preparation machine for ceramic glaze production according to claim 3, further comprising a driving assembly (3), wherein the driving assembly (3) comprises a servo motor, a first gear (302), a second gear (303), a first rod (304), a first sliding block (307), a first sliding rail (308), a sliding sleeve (309), a second rod (310) and a rack (311); the servo motor is fixedly arranged on the second support plate (104) through a motor base (301), the output end of the servo motor extends forwards and is connected with a first gear (302), the left side of the first gear (302) is matched with a second gear (303), and the second gear (303) is arranged on the second support plate (104) through a mounting frame; the right end of the first rod (304) is hinged with the disk surface of the first gear (302), and the left end of the first rod is provided with a first sliding block (307); the second gear (303) is provided with a disk surface sliding block (306), and the disk surface sliding block (306) is rotatably connected with the disk surface of the second gear (303); the first rod (304) is provided with a slide way (305), and the disk surface slide block (306) is matched with the slide way (305) and can move along the slide way (305); the first sliding block (307) is connected to a vertical first sliding rail (308) in a sliding mode, a sliding sleeve (309) is arranged at the top end of the first sliding rail (308), and the sliding sleeve (309) is sleeved on the sliding rod (105) and can move along the sliding rod (105); the top of the sliding sleeve (309) is connected with a second rod (310), and the top end of the second rod (310) is connected with a rack (311) leftwards; the top end of the first rotating shaft (313) extends out of the top cover and is provided with a driven gear (312), and the driven gear (312) is matched with the rack (311).

5. The efficient preparation machine for ceramic glaze production as claimed in claim 4, further comprising a filter assembly, wherein the filter assembly comprises a third rod (701), a spring (702) and a cleaning brush (703), and the right end of the third rod (701) is connected with a first sliding rail (308); the third rod (701) is also sleeved with a spring (702), the left end of the spring (702) abuts against the outer wall of the blanking pipe (2), and the right end of the spring (702) abuts against the left side of the first sliding rail (308); the left end of the third rod (701) extends into the discharging pipe (2) and is provided with a cleaning brush (703), and the brush hair of the cleaning brush (703) faces the filter screen (704).

6. The efficient preparation machine for ceramic glaze production according to claim 5, wherein a movable door (205) is further arranged on the left side of the bottom end of the feeding pipe (2), the top end of the movable door (205) is hinged to the feeding pipe (2), and the bottom end of the movable door is connected with the feeding pipe (2) through a detachable fixing bolt (206).

7. The efficient preparation machine for ceramic glaze production according to claim 6, further comprising a stirring box (6), wherein the stirring box (6) is arranged below the feeding pipe (2), and the top of the stirring box is provided with an opening and aligned with the outlet of the feeding pipe (2); the stirring box (6) is fixedly connected to the base (101) through a support rod (602).

8. The efficient preparation machine for ceramic glaze production according to claim 7, further comprising a pumping assembly, wherein the pumping assembly comprises a piston cylinder (5), a second sliding rail (802) and a second sliding block (803); the first rod (304) is connected with a second sliding rail (802) downwards through a connecting rod (801); the second sliding rail (802) is horizontally arranged, and the bottom of the second sliding rail is connected with a second sliding block (803) in a sliding manner; the piston cylinder (5) is arranged on the first support plate (103), a piston plate (501) is arranged in the piston cylinder (5), the top of the piston plate (501) is connected with a piston rod (504), and the piston rod (504) extends upwards out of the piston cylinder (5) and is connected with the second sliding block (803); one side of the bottom of the piston cylinder (5) is connected with a liquid suction pipe (505), and the liquid suction pipe (505) is provided with a one-way valve (506) for controlling liquid to flow into the piston cylinder (5); the other side of the bottom end of the piston cylinder (5) is connected with a liquid guide pipe (502), the liquid guide pipe (502) extends to the top of the stirring box (6), and a second one-way valve (503) for controlling liquid to flow out of the piston cylinder (5) is arranged on the liquid guide pipe (502).

9. The efficient preparation machine for ceramic glaze production according to claim 8, wherein the first sliding rail (308) and the second sliding rail (802) are I-shaped sliding rails, and the first sliding block (307) and the second sliding block (803) are corresponding C-shaped sliding blocks.

10. The efficient preparation machine for ceramic glaze production according to claim 9, further comprising a stirring assembly (4), wherein the stirring assembly (4) comprises a third gear (401), a first bevel gear (402), a second bevel gear (403), a second rotating shaft (404), a third rotating shaft (408) and a stirring rod (409); the third gear (401) is arranged on the right side of the first gear (302) and is meshed with the first gear (302); the third gear (401) is also mounted on the second support plate (104) through a mounting frame; the third gear (401) is coaxially connected with a first bevel gear (402), the first bevel gear (402) is vertically meshed with a second bevel gear (403), the second bevel gear (403) is connected with a second rotating shaft (404), and the second rotating shaft (404) downwards penetrates through the second support plate (104) and the first support plate (103) and is rotatably connected with the base (101); a vertical third rotating shaft (408) is arranged in the stirring box (6), and stirring rods (409) are uniformly arranged on the third rotating shaft (408); the third rotating shaft (408) downwards penetrates through the stirring box (6) and is provided with a second driving wheel (407); a first driving wheel (405) is correspondingly arranged on the second rotating shaft (404), and the first driving wheel (405) is in transmission connection with a second driving wheel (407) through a transmission belt (406); the bottom end of the third rotating shaft (408) is rotatably connected with the base (101); the bottom of the stirring box (6) is also connected with a liquid discharge pipe (601), and a valve is arranged on the liquid discharge pipe (601).