CN107901217B - Efficient ceramic stone processing system - Google Patents

Abstract

The invention discloses an efficient ceramic stone processing system, which comprises a slurry inlet pipe, a magnetic suction pipe, a grinding box, an overflow box, a filter box and a feeding auger, wherein the slurry inlet pipe is connected with the magnetic suction pipe, an opening at one end of the magnetic suction pipe is hermetically connected with an end cover, a plurality of magnetic rods are arranged on the end cover, a slurry outlet pipe for discharging slurry is further arranged at the pipe body position of the magnetic suction pipe, the slurry outlet pipe is connected with the bottom of the grinding box, a plurality of grinding balls for grinding the slurry are placed in the grinding box, the top of the grinding box is provided with the overflow box communicated with the grinding box, a screen is further arranged between the overflow box and the grinding box, and the top of the overflow box is provided with a grinding motor, so that the efficient ceramic stone processing system has the beneficial effects that: the slurry can adsorb iron chips through the magnetic suction pipe before being ground, so that the product quality is improved, a continuous production mode of iron removal, grinding, filtering and screening and drying can be formed, the processing efficiency is greatly improved, the whole structure is simple, and the slurry has good market popularization.

Description

Efficient ceramic stone processing system

Technical Field

The invention relates to a stone processing device, in particular to a high-efficiency ceramic stone processing system.

Background

The crushed ceramic stone is also called porcelain clay, is the main raw material for making porcelain, and is a silicate rock mineral which is made of quartz, sericite and contains feldspar, aluminum oxide and the like. Is in a compact block shape, has white appearance, and is light green and lusterless with no obvious texture. The ceramic materials are mostly oxides, nitrides, borides, carbides, and the like. The existing porcelain clay processing equipment is many, but the structure is complex, and a whole set of ceramic stone processing system is not available at present.

Disclosure of Invention

The present invention is directed to a high efficiency ceramic stone processing system to solve the above problems of the background art.

In order to achieve the purpose, the invention provides the following technical scheme:

an efficient ceramic stone processing system comprises a slurry inlet pipe, a magnetic suction pipe, a grinding box, an overflow box, a filter box and a feeding auger, wherein the slurry inlet pipe is connected with the magnetic suction pipe, an opening at one end of the magnetic suction pipe is hermetically connected with an end cover, a plurality of magnetic rods are mounted on the end cover, a slurry outlet pipe for discharging slurry is further arranged at the pipe body position of the magnetic suction pipe, the slurry outlet pipe is connected with the bottom of the grinding box, a plurality of grinding balls for grinding the slurry are placed in the grinding box, the top of the grinding box is provided with the overflow box communicated with the grinding box, a screen is further mounted between the overflow box and the grinding box, the top of the overflow box is provided with a grinding motor, the output end of the grinding motor is connected with a rotating shaft, a spiral blade is fixed to the outside of the rotating shaft, and the spiral blade is placed in; the grinding box is connected with the filter box through an overflow pipe, an obliquely arranged filter screen is installed in the filter box, a slurry outlet is formed in the bottom of the filter box, a feed opening is formed in the side wall of the filter box at the position corresponding to the lowest end of the filter screen, and a feed pipe for guiding the movement of materials is installed at the feed opening; a feeding hopper for feeding and a blanking port for discharging are respectively arranged at two ends of the feeding auger, wherein the feeding hopper is positioned right below the discharging pipe, a plurality of high-frequency electromagnetic heating coils for heating are arranged on the inner wall of the feeding auger, and the feeding auger is driven by an auger motor to operate; the grinding motor, the high-frequency electromagnetic heating coil and the packing auger motor are electrically connected with an external power supply and a control switch.

As a further scheme of the invention: the feed hopper and the blanking pipe are connected by a cloth bag.

As a still further scheme of the invention: and one end of the feeding auger is also provided with a moisture discharge port, and the moisture discharge port is also provided with a filter screen for preventing the ceramic stone raw material from being blown down.

As a still further scheme of the invention: and a sealing door is arranged at one side of the grinding box.

As a still further scheme of the invention: the grinding ball is aligned to the polyhedral structure, and each surface of the grinding ball is provided with a plurality of friction stripes.

As a still further scheme of the invention: the vibrating motor convenient for blanking is installed at the bottom of the filter screen in the filter box.

As a still further scheme of the invention: the high-frequency electromagnetic heating coil is electrically connected with a temperature controller for controlling the heating temperature of the controller.

Compared with the prior art, the invention has the beneficial effects that: the slurry can adsorb iron chips through the magnetic suction pipe before being ground, so that the product quality is improved, a continuous production mode of iron removal, grinding, filtering and screening and drying can be formed, the processing efficiency is greatly improved, the whole structure is simple, and the slurry has good market popularization.

Drawings

Fig. 1 is a schematic structural diagram of an efficient ceramic stone processing system.

Fig. 2 is a schematic diagram of a grinding box in an efficient ceramic stone processing system.

FIG. 3 is a schematic diagram of a feeding auger in a high-efficiency ceramic stone processing system.

In the figure: 1-slurry inlet pipe, 2-magnetic suction pipe, 3-grinding box, 4-overflow box, 5-filter box, 6-feeding auger, 7-end cover, 8-magnetic bar, 9-slurry outlet pipe, 10-helical blade, 11-screen, 12-grinding motor, 13-rotating shaft, 14-overflow pipe, 15-filter screen, 16-slurry outlet, 17-blanking port, 18-blanking pipe, 19-cloth bag, 20-feed hopper, 21-high-frequency electromagnetic heating coil, 22-blanking port and 23-auger motor.

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.

Referring to fig. 1 to 3, in the embodiment of the present invention, an efficient ceramic stone processing system includes a slurry inlet pipe 1, a magnetic suction pipe 2, a grinding box 3, an overflow box 4, a filter box 5, and a feeding auger 6, wherein the slurry inlet pipe 1 is connected to the magnetic suction pipe 2, an opening at one end of the magnetic suction pipe 2 is hermetically connected to an end cover 7, the end cover 7 is provided with a plurality of magnetic rods 8, a slurry outlet pipe 9 for discharging slurry is further disposed at a pipe body position of the magnetic suction pipe 2, the slurry outlet pipe 9 is connected to a bottom of the grinding box 3, a plurality of grinding balls for grinding slurry are disposed in the grinding box 3, the top of the grinding box 3 is provided with the overflow box 4 communicated with the grinding box 3, a screen 11 is further disposed between the overflow box 4 and the grinding box 3 for preventing the grinding balls and ceramic stone raw materials with a large particle size from escaping, the top of the overflow box 4 is provided with a grinding motor 12, an output end of the grinding motor 12 is connected to a rotating shaft, a helical blade 10 is fixed outside the rotating shaft 13, and the helical blade 10 is arranged in the grinding box 3; the grinding box 3 is connected with the filter box 5 through an overflow pipe 14, a filter screen 15 which is obliquely arranged is installed in the filter box 5, a slurry outlet 16 is formed in the bottom of the filter box 5, a feed opening 17 is formed in the side wall of the filter box 5 at the position corresponding to the lowest end of the filter screen 15, and a feed pipe 18 for guiding the movement of materials is installed at the feed opening 17; the both ends of pay-off auger 6 are equipped with the feeder hopper 20 that is used for the feeding respectively and are used for the blanking mouth 22 of the ejection of compact, wherein the position of feeder hopper 20 is under blanking pipe 18, be used for catching the ceramic stone raw materials that filters out, install a plurality of high frequency electromagnetic heating coil 21 that are used for heating on the inner wall of pay-off auger 6, pay-off auger 6 is by auger motor 23 drive operation, when pay-off auger 6 drive ceramic stone raw materials moves to blanking mouth 22 from feeder hopper 20, can carry out abundant stoving to ceramic stone raw materials, in operation, thick liquids enter into magnetism from admission pipe 1 and inhale inside pipe 2, iron fillings in the thick liquids are adsorbed by magnetic rod 8 of end cover 7 installation, thick liquids after the deironing enter into grinding box 3 from the bottom, start grinding motor 12, helical blade 10 drive thick liquids and grinding ball motion, the extrusion of grinding ball each other is ground the large granule ceramic stone in the thick liquids, the ceramic stone with the particle size meeting the requirement after grinding can penetrate through the screen 11, the ceramic stone with the particle size not meeting the requirement is continuously ground in the grinding box 3, the slurry can be driven to move upwards to the overflow box 4 when the helical blade 10 moves, the slurry flows into the filtering box 5, moisture falls into the bottom of the filtering box 5 and flows out from the slurry outlet 16 after being filtered by the filter screen 15, then the ceramic stone raw material at the filtering part enters the material conveying auger 6, and the ceramic stone raw material can be fully dried when the material conveying auger 6 drives the ceramic stone raw material to move from the feed hopper 20 to the blanking port 22; the grinding motor 12, the high-frequency electromagnetic heating coil 21 and the packing auger motor 23 are electrically connected with an external power supply and a control switch.

The feed hopper 20 and the blanking pipe 18 are connected by the cloth bag 19, so that the ceramic stone raw material can be reduced from spilling, and resources are saved.

One end of the feeding auger 6 is also provided with a moisture discharge port (not shown), and the moisture discharge port is also provided with a filter screen 15 for preventing the ceramic stone raw material from being blown down.

And a sealing door is arranged at one side of the grinding box 3.

The grinding ball is regular polyhedron structure, can increase the area of contact with ceramic stone raw materials, and all is equipped with multichannel friction stripe on every face of grinding ball.

The vibrating motor convenient for blanking is installed at the bottom of the filter screen 15 in the filter box 5.

The high-frequency electromagnetic heating coil 21 is electrically connected with a temperature controller for controlling the heating temperature.

The working principle of the invention is as follows: when the grinding device works, slurry enters the magnetic suction pipe 2 from the slurry inlet pipe 1, scrap iron in the slurry is adsorbed by a magnetic rod 8 arranged on an end cover 7, the slurry without iron enters the grinding box 3 from the bottom, the grinding motor 12 is started, the spiral blade 10 drives the slurry and grinding balls to move, the grinding balls extrude each other to grind large-particle ceramic stones in the slurry, the ceramic stones with the particle sizes meeting the requirements after grinding can penetrate through the screen 11, the ceramic stones with the particle sizes not meeting the requirements can continue grinding in the grinding box 3, the spiral blade 10 can drive the slurry to move upwards to the overflow box 4 and flow into the filter box 5, after being filtered by the filter screen 15, moisture falls into the bottom of the filter box 5 and flows out from the slurry outlet 16, then the ceramic stone raw material at the filtering position enters the material conveying auger 6, and when the ceramic stone raw material is driven by the feeding auger 6 to move from the feed hopper 20 to the discharge port 22, can fully dry the ceramic stone raw material.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (7)

1. An efficient ceramic stone processing system comprises a slurry inlet pipe (1), a magnetic suction pipe (2), a grinding box (3), an overflow box (4), a filter box (5) and a feeding auger (6), and is characterized in that the slurry inlet pipe (1) is connected with the magnetic suction pipe (2), an end cover (7) is hermetically connected with an opening at one end of the magnetic suction pipe (2), a plurality of magnetic rods (8) are installed on the end cover (7), a slurry outlet pipe (9) for slurry outlet is further arranged at the pipe body position of the magnetic suction pipe (2), the slurry outlet pipe (9) is connected with the bottom of the grinding box (3), a plurality of grinding balls for grinding slurry are placed in the grinding box (3), the overflow box (4) communicated with the grinding box is arranged at the top of the grinding box (3), a screen (11) is further installed between the overflow box (4) and the grinding box (3), a grinding motor (12) is installed at the top of the overflow box (4), the output end of the grinding motor (12) is connected with a rotating shaft (13), a helical blade (10) is fixed outside the rotating shaft (13), and the helical blade (10) is arranged in the grinding box (3); the grinding box (3) is connected with the filter box (5) through an overflow pipe (14), a filter screen (15) which is obliquely arranged is installed in the filter box (5), a slurry outlet (16) is formed in the bottom of the filter box (5), a feed opening (17) is formed in the side wall of the filter box (5) at the position corresponding to the lowest end of the filter screen (15), and a feed pipe (18) for guiding the movement of materials is installed at the feed opening (17); a feed hopper (20) for feeding and a blanking port (22) for discharging are respectively arranged at two ends of the feeding auger (6), wherein the feed hopper (20) is positioned right below the discharging pipe (18), a plurality of high-frequency electromagnetic heating coils (21) for heating are arranged on the inner wall of the feeding auger (6), and the feeding auger (6) is driven by an auger motor (23) to operate; the grinding motor (12), the high-frequency electromagnetic heating coil (21) and the packing auger motor (23) are electrically connected with an external power supply and the control switch.

2. The efficient ceramic stone processing system as claimed in claim 1, wherein the feed hopper (20) and the blanking pipe (18) are connected by a cloth bag (19).

3. The efficient ceramic stone processing system as claimed in claim 1, wherein a moisture discharge port is further formed at one end of the feeding auger (6), and a filter screen (15) for preventing the ceramic stone raw material from being blown off is also mounted on the moisture discharge port.

4. The efficient ceramic stone processing system as claimed in claim 1, wherein a sealing door is opened at one side position of the grinding box (3).

5. The efficient ceramic stone processing system as claimed in claim 1, wherein the grinding ball has a regular polyhedron structure, and a plurality of friction stripes are provided on each surface of the grinding ball.

6. The high-efficiency ceramic stone processing system as claimed in claim 1, wherein the bottom of the filter screen (15) in the filter box (5) is provided with a vibration motor for facilitating blanking.

7. The high efficiency ceramic stone processing system as claimed in claim 1, wherein the high frequency electromagnetic heating coil (21) is electrically connected to a temperature controller for controlling a heating temperature.

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