CN219593669U - Self-cooked powder making device - Google Patents

Abstract

The utility model discloses a self-cooked powder making device which comprises a stirring module, a self-cooked module and a wire extrusion module, wherein the stirring module is used for mixing and stirring raw materials, conveying the mixed materials to the self-cooked module, and the self-cooked module is used for heating and cooking the materials, and the cooked materials are discharged in a fine strip shape after passing through the wire extrusion module to form rice flour. The feeding component of the device adopts the vertical structure, so that the space layout structure can be optimized, the occupied space of the whole body can be reduced, the possibility of raw material blockage can be reduced by the vertical structure, the stirring blades are composed of the vertical parts and the transverse parts, the raw materials can be stirred from different positions of the stirring barrel, and the whole stirring efficiency can be assisted to be improved.

Description

Self-cooked powder making device

Technical Field

The utility model relates to the technical field of fully-mechanized coal mining, in particular to a self-cooked pulverizing device.

Background

The self-cooking mode is a heating mode for processing rice flour, and is that after starch and rice pulp are mixed, the starch rice pulp mixture is extruded in equipment, heat is generated in the extrusion process, and the rice flour is heated and cooked. However, the existing devices have the following defects and shortcomings: the structure of the existing equipment for conveying rice flour raw materials is a horizontal structure, and the arrangement of the horizontal structure not only increases occupied space, but also easily causes the problem of blockage in the process of conveying the raw materials; and the existing stirring and feeding structure needs to manually check the residual amount of raw materials in the equipment in the production and processing process, and is limited in practical use.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the utility model and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description of the utility model and in the title of the utility model, which may not be used to limit the scope of the utility model.

The present utility model has been made in view of the above and/or problems occurring in the conventional self-cooked pulverizing apparatus.

Therefore, the problem to be solved by the present utility model is how to provide a self-cooked pulverizing device.

In order to solve the technical problems, the utility model provides the following technical scheme: the utility model provides a from ripe powder process unit, its includes, stirring module, including stirring subassembly and feeding subassembly, stirring subassembly includes the agitator, sets up the stirring piece in the agitator to and be used for bearing the box of agitator, feeding subassembly includes and carries auger and conveying pipe, the conveying pipe is in vertical state, carry auger to be located the inside of conveying pipe, the pay-off mouth of intercommunication has been seted up between conveying pipe and the agitator; the self-ripening module comprises a self-ripening assembly and a driving assembly, wherein the self-ripening assembly comprises a self-ripening barrel, a self-ripening auger movably arranged in the self-ripening barrel and self-ripening sheets detachably arranged at the tail end part of the self-ripening auger, and the driving assembly is used for driving the self-ripening auger to rotate; the wire extrusion module comprises a second driving assembly and a wire extrusion assembly, and the wire extrusion assembly is connected with the self-cooked barrel through a pipeline.

As a preferable scheme of the self-cooked pulverizing device of the utility model, the following is adopted: the wire extrusion assembly comprises a wire extrusion cylinder connected with the pipeline, a wire extrusion auger matched with the second driving assembly, and a wire extrusion sheet arranged at the end part of the wire extrusion cylinder, wherein a plurality of wire extrusion holes with the same specification and size are formed in the wire extrusion sheet.

As a preferable scheme of the self-cooked pulverizing device of the utility model, the following is adopted: the periphery of the self-cooked flake is provided with a plurality of uniformly distributed U-shaped notch grooves, the top end of the self-cooked barrel is provided with a feeding hole matched with the feeding pipe and a discharging hole matched with the pipeline, and the discharging hole is positioned above the self-cooked flake.

As a preferable scheme of the self-cooked pulverizing device of the utility model, the following is adopted: the feeding assembly further comprises a conveying motor, the conveying motor is located above the feeding pipe, and an output shaft of the conveying motor is fixedly connected with the top end of the conveying auger.

As a preferable scheme of the self-cooked pulverizing device of the utility model, the following is adopted: the feeding port is positioned on the side wall of the bottom of the stirring barrel, and two groups of symmetrically arranged feeding assemblies are mounted on the side surface of the stirring barrel.

As a preferable scheme of the self-cooked pulverizing device of the utility model, the following is adopted: the stirring piece comprises a stirring motor, a first driving gear fixedly connected with an output shaft of the stirring motor, driven gears arranged at the bottom ends of the two stirring barrels, a chain connected to the peripheries of the first driving gear and the driven gears in a transmission mode, a connecting shaft fixedly connected with the driven gears, a connecting sleeve fixedly connected to the periphery of the connecting shaft and stirring blades fixedly connected to the periphery of the connecting sleeve, and the connecting sleeve and the stirring blades are located in the stirring barrels.

As a preferable scheme of the self-cooked pulverizing device of the utility model, the following is adopted: the stirring piece further comprises a leakage-proof plate, the leakage-proof plate is fixedly connected with the inner wall of the stirring barrel, the connecting shaft penetrates through the leakage-proof plate and is in rotary contact with the leakage-proof plate, and the connecting sleeve is rotationally connected to the top end of the leakage-proof plate.

As a preferable scheme of the self-cooked pulverizing device of the utility model, the following is adopted: the stirring blade comprises a transverse blade and a vertical blade which are vertically arranged, wherein the transverse blade is arranged into a triangular plate-shaped structure, and the vertical blade is arranged into a vertical plate-shaped structure.

As a preferable scheme of the self-cooked pulverizing device of the utility model, the following is adopted: still include detection module, it includes collection unit and detection unit, collection unit includes level sensor, alarm, transmission module and fixed connection at the connecting plate of level sensor one side, level sensor is located the top of agitator, detection unit includes pressure sensor and temperature sensor, pressure sensor and temperature sensor are used for detecting the inside pressure and the temperature of discharging pipe respectively.

As a preferable scheme of the self-cooked pulverizing device of the utility model, the following is adopted: the liquid level sensor is used for detecting the height of materials in the stirring barrel, the alarm and the transmission module are both connected with the liquid level sensor, and the alarm gives an alarm when the height of the materials is lower than a preset height.

The utility model has the beneficial effects that: the feeding assembly adopts a vertical structure, so that the space layout structure can be optimized, the occupied space of the whole body is reduced, the possibility of raw material blockage can be reduced by the vertical structure, the stirring blade consists of a vertical part and a transverse part, the raw materials can be stirred from different positions of the stirring barrel, and the whole stirring efficiency can be assisted to be improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art. Wherein:

fig. 1 is a general structural view of a self-cooked pulverizing apparatus.

Fig. 2 is a structural view of the stirring module of the self-cooked pulverizing apparatus with a part of the casing removed.

Fig. 3 is a view showing a structure of a part of stirring members of the self-cooked pulverizing apparatus.

Fig. 4 is a schematic view of a driven gear and a connecting shaft of the self-cooked pulverizing apparatus.

Fig. 5 is a view showing a structure of a stirring blade of the self-cooked pulverizing apparatus.

Fig. 6 is a schematic view showing the arrangement of the feeding assembly of the self-cooked pulverizing apparatus.

Fig. 7 is a structural view of a feeding assembly of the self-cooked pulverizing apparatus.

Fig. 8 is a schematic view of the position of the collecting unit of the self-cooked pulverizing apparatus.

Fig. 9 is a block diagram of a collecting unit of the self-cooked pulverizing apparatus.

Fig. 10 is a self-ripening module structure diagram of the self-ripening powder making apparatus.

Fig. 11 is a structural view of a driving assembly of the self-cooked pulverizing apparatus.

Fig. 12 is a construction diagram of a self-cooked assembly of the self-cooked pulverizing apparatus.

Fig. 13 is a schematic view of the position of the detecting unit of the self-cooked pulverizing device.

Fig. 14 is a schematic view showing the connection between the respective modules of the self-cooked pulverizing apparatus.

Fig. 15 is a cross-sectional view of a wire-extruding assembly of the self-cooked pulverizing apparatus.

Fig. 16 is a drawing showing a structure of a chip of the self-cooked pulverizing apparatus.

Detailed Description

In order that the above-recited objects, features and advantages of the present utility model will become more readily apparent, a more particular description of the utility model will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present utility model, but the present utility model may be practiced in other ways other than those described herein, and persons skilled in the art will readily appreciate that the present utility model is not limited to the specific embodiments disclosed below.

Further, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic can be included in at least one implementation of the utility model. 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 16, in a first embodiment of the present utility model, a self-cooked powder making apparatus is provided, where the self-cooked powder making apparatus includes a stirring module a, a self-cooked module B and a wire extrusion module C, the stirring module a is used for mixing and stirring raw materials, and delivering the mixed materials to the self-cooked module B, the self-cooked module B is used for heating and cooking the materials, and the cooked materials are discharged in a fine strip shape after passing through the wire extrusion module C to form rice flour.

Specifically, stirring module a includes stirring subassembly 100 and feeding subassembly 200, and stirring subassembly 100 includes agitator 101, sets up at the inside stirring piece 102 of agitator 101 to and be used for bearing the box 103 of agitator 101, feeding subassembly 200 includes carries auger 201 and conveying pipe 202, conveying pipe 202 is in vertical state, carry auger 201 to be located the inside of conveying pipe 202, the pay-off mouth 202a of intercommunication has been seted up between conveying pipe 202 and the agitator 101. The vertical arrangement of the feeding pipe 202 can enable the whole structure to be more compact, and the occupied space of the whole body is reduced.

The self-ripening module B comprises a self-ripening assembly 300 and a driving assembly 400, wherein the self-ripening assembly 300 comprises a self-ripening barrel 301, a self-ripening auger 302 movably arranged in the self-ripening barrel 301 and a self-ripening sheet 303 detachably arranged at the tail end of the self-ripening auger 302, and the driving assembly 400 is used for driving the self-ripening auger 302 to rotate.

In this embodiment, the driving assembly 400 includes a driving motor 401, a supporting seat 402, a casing 403 installed at the top end of the supporting seat 402, and a driving member 404 disposed inside the supporting seat 402 and the casing 403, where the driving motor 401 is cooperatively connected with the two sets of self-cooked assemblies 300 through the driving member 404, the driving motor 401 is set as a gear motor, and the driving motor 401 is fixedly connected to the side surface of the supporting seat 402, where the casing 403 is detachably installed at the top end of the supporting seat 402, and a specific installation manner may be, but is not limited to, bolting.

The driving piece 404 comprises a second driving gear 404a fixedly connected with the output shaft of the driving motor 401, transmission gears 404b arranged on two sides of the second driving gear 404a, a thrust bearing 404c arranged on one side of the transmission gears 404b and a driving shaft 404d fixedly connected with the second driving gear 404a, the second driving gear 404a is meshed with the transmission gears 404b, the inner ring wall of the thrust bearing 404c is fixedly connected with the corresponding driving shaft 404d, the outer ring wall of the thrust bearing 404c is fixedly connected with the supporting seat 402, and the arrangement of the thrust bearing 404c can improve the axial load capacity of the output shaft and assist in improving the stability of the driving piece 404 during operation.

One end of the driving shaft 404d, which is far from the thrust bearing 404c, extends into the self-cooked drum 301 and is fixedly connected with one end of the self-cooked auger 302, and the self-cooked drum 301 is fixedly connected to one side of the supporting seat 402.

The driving piece 404 further comprises a limit bearing 404e, an outer ring wall and an inner ring wall of the limit bearing 404e are respectively and fixedly connected with the supporting seat 402 and the driving shaft 404d, the limit bearing 404e and the thrust bearing 404c respectively abut against two sides of the driving gear 404b, and the setting of the limit bearing 404e can assist in improving the stability of the driving shaft 404d and the driving gear 404b during rotation. The driving motor 401 drives the second driving gear 404a to rotate, the second driving gear 404a and the transmission gear 404b rotate, so that the two transmission gears 404b rotate, the transmission gear 404b drives the driving shaft 404d to synchronously rotate, and finally the driving shaft 404d drives the self-cooked auger 302 to rotate.

The extruding module C includes a second driving assembly 500 and an extruding assembly 600, the extruding assembly 600 is connected with the self-cooked barrel 301 through a pipe 601, in this embodiment, the second driving assembly 500 is a combination of a motor and a reduction gearbox, the extruding assembly 600 includes an extruding barrel 602 connected with the pipe 601, an extruding auger 603 matched with the second driving assembly 500, and an extruding sheet 604 disposed at an end of the extruding barrel 602, and a plurality of extruding holes 604a with the same specification and size are disposed on the extruding sheet 604, and the second driving assembly 500 can drive the extruding auger 603 to rotate.

When the wire extruder is used, starch and rice pulp mixture is firstly put into the stirring barrel 101 from a material tray, after the materials are stirred and mixed by the stirring piece 102, the conveying motor 203 is started, the conveying auger 201 is driven to rotate, the conveying auger 201 rotates to enable the materials in the stirring barrel 101 to enter the inside of the material conveying pipe 202 from the material feeding port 202a, the conveying auger 201 rotates to convey the materials, the materials are discharged from the bottom end of the material conveying pipe 202, the rice flour raw materials are conveyed into the self-cooked barrel 301, the driving assembly 400 drives the self-cooked auger 302 to rotate to convey the rice flour materials, the self-cooked auger 302 rubs the rice flour materials to generate heat in the process, the rice flour materials are heated, the self-cooked barrel 303 can increase the resistance (pressure) in the self-cooked barrel, the temperature is continuously increased, the integral self-cooked efficiency is improved, the self-cooked barrel 303 and the self-cooked auger 302 keep synchronous rotation, the self-cooked materials are extruded from the U-shaped notch groove of the self-cooked barrel, finally the self-cooked rice flour materials are conveyed from the pipeline 601 to the wire extruder 602, the self-cooked rice flour materials are conveyed to the wire extruder barrel 602, the self-cooked rice flour materials are driven by the second driving assembly 603 to drive the wire extruder assembly 500 to rotate, the wire extruder die 604, and the wire extruder die is cooled by the wire extruder die. It should be noted that during the process of conveying the rice flour material in the extruding tube 602, the pressure in the extruding tube 602 increases, so that the temperature in the tube increases and the rice flour material is further heated and cooked.

Example 2

Referring to fig. 1 to 16, a second embodiment of the present utility model is based on the previous embodiment.

Further, a plurality of uniformly distributed U-shaped grooves are formed in the periphery of the self-cooked sheet 303, the set of the U-shaped grooves facilitates the extrusion of the rice flour material from the self-cooked barrel 301 from the U-shaped grooves, a feeding port 301a matched with the feeding pipe 202 and a discharging port 301b matched with the pipeline 601 are formed in the top end of the self-cooked barrel 301, and the discharging port 301b is located above the self-cooked sheet 303.

The feeding assembly 200 further comprises a conveying motor 203, the conveying motor 203 is located above the feeding pipe 202, an output shaft of the conveying motor 203 is fixedly connected with the top end of the conveying auger 201, the conveying motor 203 is arranged to be a gear motor, the conveying motor 203 is directly connected with the conveying auger 201, and compared with other transmission modes, transmission efficiency between the conveying motor 203 and the conveying auger 201 can be improved.

Preferably, the feeding port 202a is located on the bottom side wall of the stirring barrel 101, two groups of symmetrically arranged feeding assemblies 200 are mounted on the side surface of the stirring barrel 101, and the two groups of feeding assemblies 200 simultaneously convey materials in the stirring barrel 101, so that the efficiency of integrally conveying the materials can be improved.

The stirring piece 102 comprises a stirring motor 102a, a first driving gear 102b fixedly connected with an output shaft of the stirring motor 102a, a driven gear 102c arranged at the bottom ends of the two stirring barrels 101, a chain 102d in transmission connection with the peripheries of the first driving gear 102b and the driven gear 102c, a connecting shaft 102e fixedly connected with the driven gear 102c, a connecting sleeve 102f fixedly connected with the periphery of the connecting shaft 102e and stirring blades 102g fixedly connected with the periphery of the connecting sleeve 102f, wherein the connecting sleeve 102f and the stirring blades 102g are both positioned in the stirring barrels 101.

The stirring piece 102 further comprises a leakage-proof plate 102h, the leakage-proof plate 102h is fixedly connected with the inner wall of the stirring barrel 101, the connecting shaft 102e penetrates through the leakage-proof plate 102h and is in rotary contact with the leakage-proof plate, and the connecting sleeve 102f is rotatably connected to the top end of the leakage-proof plate 102 h. The leakage preventing plate 102h is provided to prevent leakage of materials.

Preferably, the stirring blade 102g includes a transverse blade 102g-1 and a vertical blade 102g-2 that are vertically arranged, the transverse blade 102g-1 is configured as a triangular plate structure, and the vertical blade 102g-2 is configured as a vertical plate structure.

When the wire extruder is used, starch and rice pulp mixture is firstly put into the stirring barrel 101 from a material tray, after the materials are stirred and mixed by the stirring piece 102, the conveying motor 203 is started, the conveying auger 201 is driven to rotate, the conveying auger 201 rotates to enable the materials in the stirring barrel 101 to enter the inside of the material conveying pipe 202 from the material feeding port 202a, the conveying auger 201 rotates to convey the materials, the materials are discharged from the bottom end of the material conveying pipe 202, the rice flour raw materials are conveyed into the self-cooked barrel 301, the driving assembly 400 drives the self-cooked auger 302 to rotate to convey the rice flour materials, the self-cooked auger 302 rubs the rice flour materials to generate heat in the process, the rice flour materials are heated, the self-cooked barrel 303 can increase the resistance (pressure) in the self-cooked barrel, the temperature is continuously increased, the integral self-cooked efficiency is improved, the self-cooked barrel 303 and the self-cooked auger 302 keep synchronous rotation, the self-cooked materials are extruded from the U-shaped notch groove of the self-cooked barrel, finally the self-cooked rice flour materials are conveyed from the pipeline 601 to the wire extruder 602, the self-cooked rice flour materials are conveyed to the wire extruder barrel 602, the self-cooked rice flour materials are driven by the second driving assembly 603 to drive the wire extruder assembly 500 to rotate, the wire extruder die 604, and the wire extruder die is cooled by the wire extruder die.

Example 3

Referring to fig. 1 to 16, a third embodiment of the present utility model is based on the first two embodiments, and is different from the first two embodiments in that: also comprises a detection module D.

Specifically, the detection module D includes a collection unit 700 and a detection unit 800, the collection unit 700 includes a liquid level sensor 701, an alarm 702, a transmission module 703, and a connection board 704 fixedly connected to one side of the liquid level sensor 701, where the liquid level sensor 701 is located above the stirring tank 101, the liquid level sensor 701 is set as a radar liquid level sensor, the alarm 702 and the transmission module 703 are also installed on the connection board 704, and the transmission module 703 may be set as bluetooth transmission, but is not limited to bluetooth transmission.

The liquid level sensor 701 is used for detecting the height of the material in the stirring barrel 101, the alarm 702 and the transmission module 703 are both connected with the liquid level sensor 701, and the alarm 702 gives an alarm when the height of the material is lower than a preset height. In actual use, the transmission module 703 can be connected with control equipment of a control room of the rice noodle production processing factory, and data monitored by the liquid level sensor 701 can be transmitted to the control room.

The detection unit 800 comprises a pressure sensor 801 and a temperature sensor 802, wherein the pressure sensor 801 and the temperature sensor 802 are respectively used for detecting the pressure and the temperature inside the discharging pipe 804. Preferably, the pressure sensor 801 and the temperature sensor 802 are both located at the bottom of the end face of the discharging pipe 804, that is, the pressure sensor 801 and the temperature sensor 802 are located at the end of the discharging pipe 804, so that the pressure and the temperature inside the discharging pipe 804 before the rice flour material is discharged can be conveniently monitored.

It should be noted that the above embodiments are only for illustrating the technical solution of the present utility model and not for limiting the same, and although the present utility model has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present utility model may be modified or substituted without departing from the spirit and scope of the technical solution of the present utility model, which is intended to be covered in the scope of the claims of the present utility model.

Claims (10)

1. A self-cooked powder making device is characterized in that: comprising the steps of (a) a step of,

the stirring module (A) comprises a stirring assembly (100) and a feeding assembly (200), the stirring assembly (100) comprises a stirring barrel (101), a stirring piece (102) arranged inside the stirring barrel (101) and a box body (103) used for bearing the stirring barrel (101), the feeding assembly (200) comprises a conveying auger (201) and a feeding pipe (202), the feeding pipe (202) is in a vertical state, the conveying auger (201) is positioned inside the feeding pipe (202), and a feeding port (202 a) communicated with the stirring barrel (101) is formed between the feeding pipe (202);

the self-ripening module (B) comprises a self-ripening assembly (300) and a driving assembly (400), wherein the self-ripening assembly (300) comprises a self-ripening barrel (301), a self-ripening auger (302) movably arranged in the self-ripening barrel (301) and a self-ripening sheet (303) detachably arranged at the tail end part of the self-ripening auger (302), and the driving assembly (400) is used for driving the self-ripening auger (302) to rotate;

the wire extrusion module (C) comprises a second driving assembly (500) and a wire extrusion assembly (600), and the wire extrusion assembly (600) is connected with the self-cooked barrel (301) through a pipeline (601).

2. The self-cooked pulverizing apparatus as defined in claim 1, wherein: the wire extrusion assembly (600) comprises a wire extrusion cylinder (602) connected with the pipeline (601), a wire extrusion auger (603) matched with the second driving assembly (500), and wire extrusion sheets (604) arranged at the end parts of the wire extrusion cylinder (602), wherein a plurality of wire extrusion holes (604 a) with the same specification and size are formed in the wire extrusion sheets (604).

3. The self-cooked pulverizing apparatus as defined in claim 2, wherein: the periphery of the self-cooked sheet (303) is provided with a plurality of uniformly distributed U-shaped grooves, the top end of the self-cooked barrel (301) is provided with a feeding hole (301 a) matched with the feeding pipe (202), and a discharging hole (301 b) matched with the pipeline (601), and the discharging hole (301 b) is positioned above the self-cooked sheet (303).

4. A self-cooked pulverizing apparatus as defined in claim 3, wherein: the feeding assembly (200) further comprises a conveying motor (203), the conveying motor (203) is located above the feeding pipe (202), and an output shaft of the conveying motor (203) is fixedly connected with the top end of the conveying auger (201).

5. A self-cooked pulverizing apparatus according to any one of claims 1, 2 and 4, wherein: the feeding port (202 a) is positioned on the side wall of the bottom of the stirring barrel (101), and two groups of symmetrically arranged feeding assemblies (200) are mounted on the side surface of the stirring barrel (101).

6. The self-cooked pulverizing apparatus as defined in claim 5, wherein: the stirring piece (102) comprises a stirring motor (102 a), a first driving gear (102 b) fixedly connected with an output shaft of the stirring motor (102 a), a driven gear (102 c) arranged at the bottom ends of two stirring barrels (101) and a chain (102 d) in transmission connection with the peripheries of the first driving gear (102 b) and the driven gear (102 c), a connecting shaft (102 e) fixedly connected with the driven gear (102 c), a connecting sleeve (102 f) fixedly connected with the periphery of the connecting shaft (102 e) and stirring blades (102 g) fixedly connected with the periphery of the connecting sleeve (102 f), wherein the connecting sleeve (102 f) and the stirring blades (102 g) are both positioned inside the stirring barrels (101).

7. The self-cooked pulverizing apparatus as defined in claim 6, wherein: the stirring piece (102) further comprises a leakage-proof plate (102 h), the leakage-proof plate (102 h) is fixedly connected with the inner wall of the stirring barrel (101), the connecting shaft (102 e) penetrates through the leakage-proof plate (102 h) and is in rotary contact with the leakage-proof plate, and the connecting sleeve (102 f) is rotationally connected to the top end of the leakage-proof plate (102 h).

8. A self-cooked pulverizing apparatus as defined in claim 6 or 7, wherein: the stirring blade (102 g) comprises a transverse blade (102 g-1) and a vertical blade (102 g-2) which are vertically arranged, wherein the transverse blade (102 g-1) is of a triangular plate-shaped structure, and the vertical blade (102 g-2) is of a vertical plate-shaped structure.

9. A self-cooked pulverizing apparatus according to any one of claims 4, 6 and 7, wherein: still include detection module (D), it includes collection unit (700) and detection unit (800), collection unit (700) are including level sensor (701), alarm (702), transmission module (703) and fixed connection connecting plate (704) in level sensor (701) one side, level sensor (701) are located the top of agitator (101), detection unit (800) are including pressure sensor (801) and temperature sensor (802), pressure sensor (801) and temperature sensor (802) are used for detecting the inside pressure and the temperature of discharging pipe (804) respectively.

10. The self-cooked pulverizing apparatus as defined in claim 9, wherein: the liquid level sensor (701) is used for detecting the height of materials in the stirring barrel (101), the alarm (702) and the transmission module (703) are both connected with the liquid level sensor (701), and the alarm (702) gives an alarm when the height of the materials is lower than a preset height.