CN214974656U - Vertical ball mill is used in processing of pottery tableware - Google Patents

Abstract

The utility model discloses a vertical ball mill is used in processing of pottery tableware, including screening room, vertical ball mill main part, heat dissipation cover and welt, the inside of screening room loops through spring support frame and is provided with third sieve, second sieve and first sieve, and the top of screening room is fixed with the support body, and one side of support body is provided with control panel, and the inside of support body is provided with the vertical ball mill main part, evenly is fixed with the welt through the fastener on the inner wall of vertical ball mill main part. The utility model discloses an install the vertical ball mill main part, the outside cover of vertical ball mill main part is equipped with the heat dissipation cover, and the outside of vertical ball mill main part is concentric circles structural distribution and has the heat dissipation wing, and the heat dissipation wing is the copper alloy material that coefficient of heat conductivity is high, does benefit to and adsorbs into the heat dissipation cover with the heat transfer that produces in the grinding process in, and the outside evenly distributed of heat dissipation cover has the fan, and the fan operation produces suction, derives the heat outside, does benefit to the effect that plays the ventilation cooling.

Description

Vertical ball mill is used in processing of pottery tableware

Technical Field

The utility model relates to a vertical ball mill technical field specifically is a vertical ball mill is used in processing of pottery tableware.

Background

The ball mill is a key device for crushing and then crushing materials, and is widely applied to the production industries of ceramic tableware processing and the like, the ball mill is divided into a vertical ball mill and a horizontal ball mill, for example, when a rotating shaft rotates, the combined action of centrifugal force, gravity and friction force enables the grinding medium and the materials to generate ordered motion circulation and the macroscopic stress to be basically balanced, the grinding medium spirally rises on the surface of a spiral blade, and the grinding medium spirally falls between the inner liner of a cylinder body and the outer edge of the spiral blade, so that the materials are strongly extruded and ground, and the materials are subjected to comprehensive actions of stress fracture, micro-shearing, splitting and the like, thereby realizing high-efficiency grinding.

The existing vertical ball mill has partial deficiency, the internal grinding medium generates large heat easily due to friction when grinding materials, the internal grinding medium is not easy to diffuse out in time, and the lining plate inside the vertical ball mill is simple in structure, not enough in structural strength and compressive property, easy to damage due to collision of the materials and the grinding medium, and needs to be replaced frequently.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a vertical ball mill is used in processing of pottery tableware to solve the heat dissipation that proposes in the above-mentioned background art inconvenient, the welt damages easily and does not possess the problem of screening function.

In order to achieve the above object, the utility model provides a following technical scheme: a vertical ball mill for processing ceramic tableware comprises a screening chamber, a vertical ball mill main body, a heat dissipation cover and a lining plate, the interior of the screening chamber is provided with a third sieve plate, a second sieve plate and a first sieve plate sequentially through a spring support frame, the top end of the screening chamber is fixed with a frame body, and one side of the frame body is provided with a control panel, the interior of the frame body is provided with a vertical ball mill main body, the bottom end of the interior of the vertical ball mill main body is uniformly filled with grinding media, the bottom end of the vertical ball mill main body is communicated with the screening chamber through a material guide pipe, a servo motor is fixed at the central position of the top of the frame body, and the output end of the servo motor is provided with a rotating shaft which extends to the interior of the vertical ball mill main body, and helical blades are uniformly distributed on the rotating shaft, and lining plates are uniformly fixed on the inner wall of the vertical ball mill main body through fasteners.

Preferably, the central point department of third sieve, second sieve and first sieve bottom all is provided with vibrating motor, and the sieve mesh size on third sieve, second sieve and the first sieve diminishes in proper order.

Preferably, third sieve, second sieve and first sieve are the slope form, and all are provided with the discharge gate on the screening room of third sieve, second sieve and first sieve one side.

Preferably, the radiating fins are distributed on the outer side of the vertical ball mill main body in a concentric circle structure, and the radiating fins are made of copper alloy materials with high heat conductivity coefficients.

Preferably, the outer side of the vertical ball mill main body is provided with a heat dissipation cover, and fans are uniformly distributed on the outer side of the heat dissipation cover.

Preferably, the lining plates are all arc-shaped structures, and the lining plates are distributed around the vertical ball mill main body in a concentric circle structure.

Preferably, the reinforcing layers are arranged inside the side walls of the lining plate, and reinforcing ribs are uniformly distributed inside the reinforcing layers.

Preferably, the lining plates on two sides of the reinforcing layer are internally provided with compression-resistant layers which are composed of rigid spring sleeves which are uniformly arranged.

Compared with the prior art, the beneficial effects of the utility model are that:

(1) this vertical ball mill for ceramic tableware processing is through installing the vertical ball mill main part, and the outside cover of vertical ball mill main part is equipped with the heat dissipation cover, and the outside of vertical ball mill main part is concentric circles structure distribution and has the heat dissipation wing, and the heat dissipation wing is the copper alloy material that coefficient of heat conductivity is high, does benefit to and adsorbs into the heat dissipation cover with the heat transfer that produces among the grinding process in, and the outside evenly distributed of heat dissipation cover has the fan, and the fan operation produces suction, exports the heat outside, does benefit to the effect that plays the ventilation cooling.

(2) This vertical ball mill for ceramic tableware processing is fixed with the welt through the fastener evenly through the inner wall at the vertical ball mill main part, the welt all is the arc structure, do benefit to the inner wall that protects the vertical ball mill main part and avoid grinding medium and material direct impact and friction, all be provided with enhancement layer and resistance to compression layer in the welt lateral wall, it has the strengthening rib to strengthen intraformational evenly distributed, the resistance to compression layer comprises equidistant distribution's rigidity spring housing, do benefit to the structural strength and the compressive property that improve the welt, be difficult to damage when receiving extrusion collision, do benefit to and reduce the change frequency.

(3) This vertical ball mill for ceramic tableware processing is through installing the screening room, first sieve, the second sieve, third sieve and vibrating motor, the third sieve, sieve mesh size on second sieve and the first sieve steadilys decrease in proper order, the material after the grinding enters into the screening room through the passage, at first fall on the third sieve, vibrating motor drives the shake of third sieve, the material that accords with the third sieve mesh falls down on the second sieve, the material that does not accord with is derived by the discharge gate of one side, so on, do benefit to and classify according to the careful degree that the material ground and derive.

Drawings

Fig. 1 is a schematic front view of a cross-sectional structure of the present invention;

fig. 2 is a schematic top view of the cross-sectional structure of the heat dissipation cover of the present invention;

FIG. 3 is a schematic view of the top-view cross-sectional structure of the vertical ball mill main body of the present invention;

fig. 4 is an enlarged cross-sectional view of the utility model at a in fig. 3;

fig. 5 is a schematic view of a first sieve plate structure of the present invention.

In the figure: 1. a screening chamber; 2. a first screen deck; 3. a second screen deck; 4. a third screen deck; 5. a material guide pipe; 6. a vertical ball mill main body; 7. a heat dissipation cover; 8. a frame body; 9. a servo motor; 10. a rotating shaft; 11. a helical blade; 12. a control panel; 13. heat dissipation fins; 14. a grinding media; 15. a discharge port; 16. a fan; 17. a liner plate; 18. a fastener; 19. a reinforcing layer; 20. reinforcing ribs; 21. a rigid spring housing; 22. a pressure resistant layer; 23. a vibration motor.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides an embodiment: a vertical ball mill for processing ceramic tableware comprises a screening chamber 1, a vertical ball mill main body 6, a heat dissipation cover 7 and a lining plate 17, wherein a third sieve plate 4, a second sieve plate 3 and a first sieve plate 2 are sequentially arranged in the screening chamber 1 through a spring support frame, vibrating motors 23 are respectively arranged at the central positions of the bottoms of the third sieve plate 4, the second sieve plate 3 and the first sieve plate 2, and the sizes of sieve pores on the third sieve plate 4, the second sieve plate 3 and the first sieve plate 2 are sequentially reduced;

the ground materials enter the screening chamber 1 through the material guide pipe 5, and the vibration motor 23 drives the third screen plate 4, the second screen plate 3 and the first screen plate 2 to shake and screen, so that classification and derivation according to the fineness of the ground materials are facilitated;

the third sieve plate 4, the second sieve plate 3 and the first sieve plate 2 are inclined, and discharge ports 15 are formed in the sieving chambers 1 on one sides of the third sieve plate 4, the second sieve plate 3 and the first sieve plate 2, so that discharging is facilitated;

a frame body 8 is fixed at the top end of the screening chamber 1, a control panel 12 is arranged on one side of the frame body 8, a vertical ball mill main body 6 is arranged inside the frame body 8, a heat dissipation cover 7 is arranged on the outer side of the vertical ball mill main body 6, fans 16 are uniformly distributed on the outer side of the heat dissipation cover 7, heat dissipation fins 13 are distributed on the outer side of the vertical ball mill main body 6 in a concentric circle structure, and the heat dissipation fins 13 are all made of copper alloy materials with high heat conductivity coefficients;

the heat dissipation fins 13 transfer and absorb heat generated in the grinding process into the heat dissipation cover 7 in the grinding process, the fans 16 are uniformly distributed on the outer side of the heat dissipation cover 7, and the fans 16 generate suction force when running to guide the heat out of the heat dissipation cover, so that the functions of ventilation, heat dissipation and temperature reduction are facilitated;

the bottom end of the inside of the vertical ball mill main body 6 is uniformly filled with grinding media 14, the bottom end of the vertical ball mill main body 6 is communicated with the screening chamber 1 through a material guide pipe 5, a servo motor 9 is fixed at the central position of the top of the frame body 8, the output end of the servo motor 9 is provided with a rotating shaft 10, the rotating shaft 10 extends to the inside of the vertical ball mill main body 6, and helical blades 11 are uniformly distributed on the rotating shaft 10;

the inner wall of the vertical ball mill main body 6 is uniformly fixed with lining plates 17 through fasteners 18, the lining plates 17 are all in an arc structure, and the lining plates 17 are distributed around the vertical ball mill main body 6 in a concentric circle structure, so that the inner wall of the vertical ball mill main body 6 is protected from direct impact and friction of the grinding medium 14 and materials;

reinforcing layers 19 are arranged inside the side walls of the lining plates 17, and reinforcing ribs 20 are uniformly distributed inside the reinforcing layers 19, so that the structural strength of the lining plates 17 is improved;

the lining plates 17 on the two sides of the reinforcing layer 19 are internally provided with the compression-resistant layers 22, and the compression-resistant layers 22 are composed of rigid spring sleeves 21 which are uniformly arranged, so that the compression resistance of the lining plates 17 is improved, the lining plates are not easy to damage when being extruded and collided, and the replacement frequency is reduced;

the specific models and specifications of the servo motor 9, the fan 16 and the vibration motor 23 need to be calculated and determined according to the model selection of the specification parameters and the like of the device, and the model selection calculation method is the prior art, so detailed description is omitted.

The working principle is as follows: when in use, materials for producing ceramic tableware to be ground are led into the vertical ball mill main body 6, the servo motor 9 drives the rotating shaft 10 and the helical blade 11 to rotate, the grinding medium 14 spirally rises on the surface of the helical blade 11, and the grinding medium 14 spirally descends between the lining plate 17 and the outer edge of the helical blade 11, so that the materials are strongly extruded, and the materials are efficiently ground, the heat generated in the grinding process is transferred and absorbed into the heat dissipation cover 7 by the heat dissipation fins 13 in the grinding process, the fans 16 are uniformly distributed on the outer side of the heat dissipation cover 7, the fans 16 generate suction force when running, the heat is led out of the outside, and the functions of ventilation, heat dissipation and temperature reduction are favorably realized, in addition, the lining plates 17 are all arc-shaped structures, the inner wall of the vertical ball mill main body 6 is favorably protected from direct impact and friction of the grinding medium 14 and the materials, and reinforcing layers 19 and pressure-resistant layers 22 are arranged in the side walls of the lining plates 17, do benefit to the structural strength and the compressive property that improve welt 17, be difficult to damage when receiving the extrusion collision, do benefit to the reduction and change the frequency, the material after the grinding passes through passage 5 and enters into screening room 1, at first fall on third sieve 4, vibrating motor 23 drives the shake of third sieve 4, the material that accords with the 4 sieve meshes of third sieve falls down on second sieve 3, the material that does not conform is derived by the discharge gate 15 of one side, third sieve 4, sieve mesh size on second sieve 3 and the first sieve 2 steadilys decrease in proper order, do benefit to and classify according to the careful degree that the material ground and derive.

Claims (8)

1. The vertical ball mill for processing the ceramic tableware is characterized by comprising a screening chamber (1), a vertical ball mill main body (6), a heat dissipation cover (7) and a lining plate (17), wherein a third sieve plate (4), a second sieve plate (3) and a first sieve plate (2) are sequentially arranged inside the screening chamber (1) through a spring support frame, a frame body (8) is fixed at the top end of the screening chamber (1), a control panel (12) is arranged on one side of the frame body (8), the vertical ball mill main body (6) is arranged inside the frame body (8), grinding media (14) are uniformly filled at the bottom end inside the vertical ball mill main body (6), the bottom end of the vertical ball mill main body (6) is communicated with the screening chamber (1) through a guide pipe (5), and a servo motor (9) is fixed at the central position of the top of the frame body (8), and the output of servo motor (9) is provided with pivot (10), pivot (10) extend to the inside of vertical ball mill main part (6), and evenly distributed has helical blade (11) on pivot (10), evenly be fixed with welt (17) through fastener (18) on the inner wall of vertical ball mill main part (6).

2. The attritor mill for ceramic tableware processing according to claim 1, wherein: the central position department of third sieve (4), second sieve (3) and first sieve (2) bottom all is provided with vibrating motor (23), and sieve mesh size on third sieve (4), second sieve (3) and first sieve (2) diminishes in proper order.

3. The attritor mill for ceramic tableware processing according to claim 1, wherein: third sieve (4), second sieve (3) and first sieve (2) are the slope form, and all are provided with discharge gate (15) on the screening room (1) of third sieve (4), second sieve (3) and first sieve (2) one side.

4. The attritor mill for ceramic tableware processing according to claim 1, wherein: the outer side of the vertical ball mill main body (6) is provided with heat dissipation fins (13) in a concentric circle structure, and the heat dissipation fins (13) are made of copper alloy materials with high heat conductivity coefficients.

5. The attritor mill for ceramic tableware processing according to claim 1, wherein: the vertical ball mill is characterized in that a heat dissipation cover (7) is arranged on the outer side of the vertical ball mill main body (6), and fans (16) are uniformly distributed on the outer side of the heat dissipation cover (7).

6. The attritor mill for ceramic tableware processing according to claim 1, wherein: the lining plates (17) are all arc-shaped structures, and the lining plates (17) are distributed around the vertical ball mill main body (6) in a concentric circle structure.

7. The attritor mill for ceramic tableware processing according to claim 1, wherein: reinforcing layers (19) are arranged inside the side walls of the lining plates (17), and reinforcing ribs (20) are uniformly distributed inside the reinforcing layers (19).

8. The vertical ball mill for ceramic tableware processing according to claim 7, wherein: and the lining plates (17) on two sides of the reinforcing layer (19) are internally provided with pressure resistant layers (22), and the pressure resistant layers (22) are composed of rigid spring sleeves (21) which are uniformly arranged.

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