CN113635440B - Agitating unit is smashed to mud for pottery - Google Patents

Abstract

The invention discloses a ceramic mud material crushing and stirring device which comprises a blanking assembly, a feeding barrel, a filtering pipeline and a discharging channel, wherein two ends of the filtering pipeline are communicated with the inside of a shell; the drying assembly comprises a separating disc, a heating disc and a scraping shovel, the separating disc is arranged below the feeding barrel, the heating disc is connected with the separating disc, the heating disc is arranged below the separating disc, and the side wall of the heating disc is fixedly connected with the shell; crushing unit, including eccentric crushing piece and crushing wall, crushing wall set up in the casing, crushing wall set up in the heating plate below, eccentric crushing piece set up in the crushing wall, eccentric crushing piece bottom with the casing is connected. The invention has the beneficial effects that: the stones are separated from the pug, the device for processing the pug is reduced to shake, the efficiency of the device for processing the pug is high, and the residue of the pug in the device for processing the pug is small.

Description

Agitating unit is smashed to mud for pottery

Technical Field

The invention relates to the technical field of pug crushing and stirring devices, in particular to a pug crushing and stirring device for ceramics.

Background

Ceramics, which are various products made of materials obtained by crushing, mixing, molding and firing natural clay and various natural minerals as main raw materials, have been called ceramics by people in the past, which are made of pottery clay and fired at high temperature in special kilns, and the traditional concept of ceramics refers to all artificial industrial products made of inorganic nonmetallic minerals such as clay and the like as raw materials, and includes various products made of clay or mixtures containing clay through mixing, molding and firing.

At present, the stirring needs to be smashed to multiple pug before the pottery is fired, and traditional agitating unit stirs for a long time and makes the pug be stained with the inner wall of attaching at puddler and agitator tank easily, seriously influences the stirring of later stage pug to there is the persistence of the great granule of stone etc. in the pug, be unfavorable for later stage pottery to fire, and the stirring is wasted time and energy, and work efficiency is low.

Disclosure of Invention

This section is for the purpose of summarizing some aspects of embodiments of the invention and to briefly introduce some preferred embodiments, and in this section as well as in the abstract and the title of the invention of this application some simplifications or omissions may be made to avoid obscuring the purpose of this section, the abstract and the title of the invention, and such simplifications or omissions are not intended to limit the scope of the invention.

The present invention has been made keeping in mind the above problems and/or problems occurring in the prior art.

Therefore, the technical problems to be solved by the invention are that stones in the mud are inconvenient to process, a device for processing the mud shakes violently, the efficiency of the device for processing the mud is low, and much mud remains in the device for processing the mud.

In order to solve the technical problems, the invention provides the following technical scheme: the mud material crushing and stirring device for ceramics comprises a blanking assembly, a feeding barrel, a filtering pipeline and a discharging channel, wherein the feeding barrel is arranged in the shell, two ends of the filtering pipeline are communicated with the inside of the shell, and the discharging channel is arranged at the bottom of the shell;

the drying assembly comprises a separating disc, a heating disc and a spatula, the separating disc is arranged below the feeding barrel, the heating disc is connected with the separating disc, the heating disc is arranged below the separating disc, the side wall of the heating disc is fixedly connected with the shell, and the spatula is arranged between the separating disc and the heating disc;

crushing unit, including eccentric crushing piece and crushing wall, crushing wall set up in the casing, crushing wall set up in the heating plate below, eccentric crushing piece set up in the crushing wall, eccentric crushing piece bottom with the casing is connected.

As a preferable scheme of the ceramic pug crushing and stirring device of the invention, wherein: the casing upper end is provided with the feed inlet, be provided with the lewis hole under the feed inlet, the feedwell is provided with a plurality of steel cables, the feedwell with the lewis hole is through a plurality of steel cable connection.

As a preferable scheme of the ceramic pug crushing and stirring device of the invention, wherein: separation gaps are arranged between the side walls of the separation discs and the shell.

As a preferable scheme of the ceramic pug crushing and stirring device of the invention, wherein: be provided with first motor on the heating plate, be provided with the connecting rod on the heating plate, connecting rod one end embedding in the first motor, the separation disc passes through the connecting rod with the heating plate is connected.

As a preferable scheme of the ceramic pug crushing and stirring device of the invention, wherein: the plane of the upper end face of the heating plate and the plane of the lower end face of the heating plate are horizontal planes, the plane of the upper end face of the separation disc is parallel to the plane of the lower end face of the separation disc, and the plane of the upper end face of the separation disc and the plane of the lower end face of the separation disc are not coplanar with the plane of the upper end face of the heating plate.

As a preferable scheme of the ceramic pug crushing and stirring device of the invention, wherein: the upper port of the filtering pipeline is arranged between the horizontal plane where the highest point on the upper end surface of the separating disc is located and the horizontal plane where the lowest point on the upper end surface of the separating disc is located, the lower port of the filtering pipeline is arranged between the horizontal plane where the lowest point on the lower end surface of the separating disc is located and the plane where the upper end surface of the heating disc is located, and a filtering net is arranged in the filtering pipeline.

As a preferable scheme of the ceramic pug crushing and stirring device of the invention, wherein: the scraping shovel is arranged above the heating disc and connected with the first motor, and the lower end face of the scraping shovel is parallel to the upper end face of the heating disc;

be provided with a plurality of heating chambeies in the heating plate, be provided with a plurality of flexible arms in the spatula, the heating plate below is provided with the baffle, the spatula set up in separating disc perk end below.

As a preferable scheme of the ceramic pug crushing and stirring device of the invention, wherein: the eccentric smashing device is characterized in that an eccentric smashing piece, a first fixing rod, a second fixing rod, a third fixing rod, a fourth fixing rod and a second motor are arranged on the eccentric smashing piece, one end of each of the first fixing rod, the second fixing rod, the third fixing rod and the fourth fixing rod is connected with the eccentric smashing piece, and the other end of each of the first fixing rod, the second fixing rod, the third fixing rod and the fourth fixing rod is not connected with the eccentric smashing piece and is connected with the second motor.

As a preferable scheme of the ceramic pug crushing and stirring device of the invention, wherein: the first fixation bar length is equal to the second fixation bar length, the third fixation bar length is equal to the fourth fixation bar length, and the first fixation bar length is greater than the third fixation bar length;

the eccentric crushing piece is a cone-shaped structural object block, and the axis of the eccentric crushing piece is not collinear with the axis of the second motor.

As a preferable scheme of the ceramic pug crushing and stirring device of the invention, wherein: an extrusion cavity is arranged between the side wall of the tilting end of the eccentric crushing piece and the crushing wall, and a feeding cavity is arranged between the side wall of the sinking end of the eccentric crushing piece and the crushing wall.

The invention has the beneficial effects that: the stones are separated from the pug, the device for processing the pug is reduced to shake, the efficiency of the device for processing the pug is high, and the residue of the pug in the device for processing the pug is small.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the description below are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without inventive labor. Wherein:

fig. 1 is a schematic partial structure view of a ceramic pug crushing and stirring device according to an embodiment of the invention.

Fig. 2 is a schematic view of the overall structure of the ceramic slurry pulverizing and stirring apparatus according to an embodiment of the present invention.

Fig. 3 is a schematic structural diagram of a feed barrel in the ceramic slurry pulverizing and stirring apparatus according to an embodiment of the present invention.

Fig. 4 is a schematic structural diagram of a spatula in the ceramic slurry crushing and stirring device according to an embodiment of the invention.

Fig. 5 is a schematic structural view of a heating plate in the ceramic pug crushing and stirring device according to an embodiment of the invention.

Fig. 6 is a schematic structural view of an eccentric crushing member in the ceramic slurry crushing and stirring device according to an embodiment of the present invention.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways than those specifically described and will be readily apparent to those of ordinary skill in the art without departing from the spirit of the present invention, and therefore the present invention is not limited to the specific embodiments disclosed below.

Next, the present invention is described in detail with reference to the drawings, and in the detailed description of the embodiments of the present invention, the cross-sectional views illustrating the device structures are not enlarged partially according to the general scale for convenience of illustration, and the drawings are only exemplary, which should not limit the scope of the present invention. In addition, the three-dimensional dimensions of length, width and depth should be included in the actual fabrication.

Furthermore, the reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic may be included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Example 1

Referring to fig. 1 to 3, the embodiment provides a ceramic pug crushing and stirring device, which comprises a blanking assembly 100, a feeding barrel 102, a filtering pipeline 103 and a discharging channel 104, wherein the feeding barrel 102 is arranged in the shell 101, two ends of the filtering pipeline 103 are both communicated with the inside of the shell 101, the discharging channel 104 is arranged at the bottom of the shell 101, and the discharging channel 104 is connected with a pumping device such as a pressure pump and the like to pump out crushed pugs;

the drying assembly 200 comprises a separating disc 201, a heating disc 202 and a spatula 203, wherein the separating disc 201 is arranged below the feed barrel 102, the heating disc 202 is connected with the separating disc 201, the heating disc 202 is arranged below the separating disc 201, the side wall of the heating disc 202 is fixedly connected with the shell 101, and the spatula 203 is arranged between the separating disc 201 and the heating disc 202;

the crushing assembly 300 comprises an eccentric crushing piece 301 and a crushing wall 302, wherein the crushing wall 302 is arranged in the shell 101, the crushing wall 302 is arranged below the heating plate 202, the eccentric crushing piece 301 is arranged in the crushing wall 302, and the bottom of the eccentric crushing piece 301 is connected with the shell 101.

The upper end of the shell 101 is provided with a feeding hole 101a, a lifting hole 101b is arranged below the feeding hole 101a, the charging barrel 102 is provided with a plurality of steel ropes 102a, the charging barrel 102 and the lifting hole 101b are connected through the plurality of steel ropes 102a, the charging barrel 102 has enough weight, the charging barrel 102 can play a role of a damper when the device integrally shakes, and therefore the device is effectively prevented from being damaged due to resonance.

Separation gaps 201a are arranged between the side walls of the separation discs 201 and the casing 101, and the separation gaps 201a are proper in size, so that stones cannot fall from the separation gaps 201a to the heating plate 202 in the rotation process of the separation discs 201.

The heating plate 202 is provided with a first motor 202a, the heating plate 202 is provided with a connecting rod 202b, one end of the connecting rod 202b is embedded into the first motor 202a, the separating disc 201 is connected with the heating plate 202 through the connecting rod 202b, and the separating disc 201 is fixedly connected with the shell 101 to ensure that the device is stable in the rotating process.

Example 2

Referring to fig. 1 to 5, the difference between this embodiment and the previous embodiment is that the upper end plane and the lower end plane of the heating plate 202 are both horizontal planes, the upper end plane and the lower end plane of the separation plate 201 are parallel, the upper end plane and the lower end plane of the separation plate 201 are not coplanar with the upper end plane of the heating plate 202, and the heating plate 202 has a certain inclination angle, so that the stone can be forced in the vertical direction during the rotation process, and can fall into the filtering pipe 103 quickly.

Filter pipe 103 upper end mouth sets up between the minimum point department horizontal plane on the most significant point department horizontal plane on the separating disc 201 up end and the separating disc 201 up end, it can be effectual get rid of the stone and filter pipe 103 to change the structure, the port sets up under the separating disc 201 between minimum point department horizontal plane and heating plate 202 up end department plane on the terminal surface, be provided with filter screen 103a in the filter pipe 103, it remains to have the pug on the stone that falls into on the filter screen 103a, there is the pug on the stone after the one end time that stews can flow in on heating plate 202 along filter pipe 103, the position on the filter screen 103a in the filter pipe 103 is provided with the openable door, can open the openable door after the stone is accumulated to certain degree and take out the stone.

The spatula 203 is arranged above the heating plate 202, the spatula 203 is connected with the first motor 202a, the lower end surface of the spatula 203 is parallel to the upper end surface of the heating plate 202, and the sharp end of the spatula 203 is arranged according to the rotating direction of the first motor 202a, so that the sharp end of the spatula 203 can scrape mud on the heating plate 202 into the heating cavity 202c along the rotating direction of the first motor 202 a;

a plurality of heating cavities 202c are arranged in the heating plate 202, a plurality of telescopic arms 203a are arranged in the spatula 203, the bottom surface of the spatula 203 is tightly attached to the heating plate 202, chamfers are arranged at the end parts of the telescopic arms 203a, and the telescopic arms 203a cannot be popped up when being squeezed by the heating plate 202 in the rotating process of the spatula 203;

a baffle plate 202d is arranged below the heating plate 202, the upper end surface of the baffle plate 202d is tightly attached to the lower end surface of the heating plate 202, when the baffle plate 202d rotates to the position below the heating cavity 202c, the scraper 203 rotates to the position above the heating cavity 202c, the telescopic arm 203a ejects mud in the stirring heating cavity 202c, when the baffle plate 202d does not rotate to the position below the heating cavity 202c, moisture in the fully heated mud in the heating cavity 202c is fully evaporated, the mud is possibly adhered to the inner wall of the heating cavity 202c due to agglomeration, the mud falls down from the heating cavity 202c under the thrust of the telescopic arm 203a, and the edge of the heating cavity 202c is provided with a fillet so that the telescopic arm 203a can conveniently stretch;

the spatula 203 is arranged below the tilting end of the separating disc 201, so that the center of gravity of the whole drying assembly 200 is on the rotating axis in the rotating process, and the side wall of the spatula 203 close to one side of the shell 101 has a radian, so that the spatula 203 is prevented from contacting with the shell 101 in the rotating process.

Example 3

Referring to fig. 2 and 6, the present embodiment is different from the previous embodiment in that an eccentric crushing block 301a, a first fixing rod 301b, a second fixing rod 301c, a third fixing rod 301d, a fourth fixing rod 301e and a second motor 301f are disposed on the eccentric crushing member 301, the first fixing rod 301b, the second fixing rod 301c, the third fixing rod 301d and the fourth fixing rod 301e are connected to the eccentric crushing block 301a at one end, and the first fixing rod 301b, the second fixing rod 301c, the third fixing rod 301d and the fourth fixing rod 301e are not connected to the eccentric crushing block 301a and connected to the second motor 301f at the other end.

The length of the first fixing lever 301b is equal to that of the second fixing lever 301c, the length of the third fixing lever 301d is equal to that of the fourth fixing lever 301e, and the length of the first fixing lever 301b is greater than that of the third fixing lever 301 d;

the eccentric crushing block 301a is a cone-shaped structural body, the axis of the eccentric crushing block 301a is not collinear with the axis of the second motor 301f, and the lengths of the first fixing rod 301b, the second fixing rod 301c, the third fixing rod 301d and the fourth fixing rod 301e determine the center of gravity offset of the eccentric crushing block 301 a.

An extrusion cavity 302a is arranged between the side wall of the tilting end of the eccentric crushing block 301a and the crushing wall 302, and a feeding cavity 302b is arranged between the side wall of the sinking end of the eccentric crushing block 301a and the crushing wall 302.

Because the crushing wall 302 is fixed, the eccentric crushing block 301a rotates ceaselessly, the extrusion cavity 302a and the feeding cavity 302b are dynamic spaces, the friction coefficient of the material between the side wall of the eccentric crushing block 301a and the inner wall of the crushing wall 302 is low, the material is dry, the rotating speed of the material is far lower than that of the eccentric crushing block 301a, the opening at the upper end of the feeding cavity 302b is enough for the material to enter, the material enters the extrusion cavity 302a along with the rotation of the eccentric crushing block 301a, the material is crushed by extrusion, the rotating speed of the eccentric crushing block 301a is fast enough, and the material is ensured to be sufficiently extruded before leaving the extrusion cavity 302 a;

the gap between the lower end of the extrusion cavity 302a and the upper end of the feeding cavity 302b is smaller than the gap between the upper end of the extrusion cavity 302a and the upper end of the feeding cavity 302b, and the eccentric crushing block 301a does not contact with the crushing wall 302 during the rotation.

Claims (4)

1. The utility model provides a agitating unit is smashed to mud for pottery which characterized in that: comprises the steps of (a) preparing a substrate,

the blanking assembly (100) comprises a shell (101), a feeding barrel (102), a filtering pipeline (103) and a discharging channel (104), wherein the feeding barrel (102) is arranged in the shell (101), two ends of the filtering pipeline (103) are communicated with the inside of the shell (101), and the discharging channel (104) is arranged at the bottom of the shell (101);

a drying assembly (200) comprising a separating disc (201), a heating disc (202) and a spatula (203), wherein the separating disc (201) is arranged below the feed barrel (102), the heating disc (202) is connected with the separating disc (201), the heating disc (202) is arranged below the separating disc (201), the side wall of the heating disc (202) is fixedly connected with the shell (101), the spatula (203) is arranged between the separating disc (201) and the heating disc (202), and the separating disc (201) is obliquely arranged in the shell (101);

a comminution assembly (300) comprising an eccentric comminution member (301) and a comminution wall (302), the comminution wall (302) being disposed within the housing (101), the comminution wall (302) being disposed below the heating disk (202), the eccentric comminution member (301) being disposed within the comminution wall (302), the bottom of the eccentric comminution member (301) being connected to the housing (101);

a feed inlet (101 a) is formed in the upper end of the shell (101), a lifting hole (101 b) is formed below the feed inlet (101 a), the feed barrel (102) is provided with a plurality of steel ropes (102 a), and the feed barrel (102) is connected with the lifting hole (101 b) through the plurality of steel ropes (102 a);

a separation gap (201 a) is arranged between the side wall of the separation disc (201) and the shell (101);

a first motor (202 a) is arranged on the heating plate (202), a connecting rod (202 b) is arranged on the heating plate (202), one end of the connecting rod (202 b) is embedded into the first motor (202 a), and the separating plate (201) is connected with the heating plate (202) through the connecting rod (202 b);

the plane of the upper end face and the plane of the lower end face of the heating plate (202) are horizontal planes, the plane of the upper end face and the plane of the lower end face of the separating plate (201) are parallel, and the planes of the upper end face and the lower end face of the separating plate (201) are not coplanar with the plane of the upper end face of the heating plate (202);

the upper port of the filtering pipeline (103) is arranged between the horizontal plane where the highest point on the upper end surface of the separating disc (201) is located and the horizontal plane where the lowest point on the upper end surface of the separating disc (201) is located, the lower port of the filtering pipeline (103) is arranged between the horizontal plane where the lowest point on the lower end surface of the separating disc (201) is located and the plane where the upper end surface of the heating disc (202) is located, and a filter screen (103 a) is arranged in the filtering pipeline (103);

the spatula (203) is arranged above the heating plate (202), the spatula (203) is connected with the first motor (202 a), and the lower end face of the spatula (203) is parallel to the upper end face of the heating plate (202);

be provided with a plurality of heating chambers (202 c) in heating plate (202), be provided with a plurality of flexible arms (203 a) in spatula (203), heating plate (202) below is provided with baffle (202 d), spatula (203) set up in separating disc (201) perk end below.

2. The ceramic sludge pulverizing and stirring apparatus as set forth in claim 1, wherein: be provided with eccentric crushing piece (301 a), first dead lever (301 b), second dead lever (301 c), third dead lever (301 d), fourth dead lever (301 e) and second motor (301 f) on eccentric crushing piece (301), first dead lever (301 b), second dead lever (301 c), third dead lever (301 d) and fourth dead lever (301 e) all have one end with eccentric crushing piece (301 a) is connected, first dead lever (301 b), second dead lever (301 c), third dead lever (301 d) and fourth dead lever (301 e) do not with eccentric crushing piece (301 a) is connected the other end all with second motor (301 f) is connected.

3. The ceramic sludge pulverizing and stirring apparatus as set forth in claim 2, wherein: the length of the first fixing rod (301 b) is equal to that of the second fixing rod (301 c), the length of the third fixing rod (301 d) is equal to that of the fourth fixing rod (301 e), and the length of the first fixing rod (301 b) is greater than that of the third fixing rod (301 d);

the eccentric crushing block (301 a) is a cone structure block, and the axis of the eccentric crushing block (301 a) is not collinear with the axis of the second motor (301 f).

4. The ceramic sludge pulverizing and stirring apparatus as set forth in claim 3, wherein: the eccentric crushing block is characterized in that an extrusion cavity (302 a) is formed between the side wall of the tilting end of the eccentric crushing block (301 a) and the crushing wall (302), and a feeding cavity (302 b) is formed between the side wall of the sinking end of the eccentric crushing block (301 a) and the crushing wall (302).

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