CN213726119U - Double-cone mixing device - Google Patents

Abstract

The utility model provides a bipyramid mixing arrangement, bipyramid mixing arrangement includes: the device comprises a supporting seat, a bearing seat, a tank body, a rotating shaft, a bearing, a driven wheel, a motor, a driving wheel, a belt, a feeding hole, a dispersing shaft, a first connecting rod, a blade, a second connecting rod and a discharging hole; the two supporting seats are symmetrically arranged; the two bearing blocks are respectively fixed on the two supporting seats; the two ends of the tank body are conical, and the tank body is positioned between the two supporting seats; one ends of the two rotating shafts are simultaneously connected with the side wall of the tank body, and the other ends of the two rotating shafts are respectively embedded into the two bearing blocks; the two bearings are respectively sleeved on the outer sides of the two rotating shafts and are respectively embedded into the two bearing blocks; the driven wheel is sleeved on the outer side of one of the rotating shafts and synchronously rotates with one of the rotating shafts; the motor includes the motor shaft, and the motor is fixed on one of them supporting seat.

Description

Double-cone mixing device

Technical Field

The utility model relates to a material mixing technical field particularly, relates to a bipyramid mixing arrangement.

Background

At present, in the related art, the existing mixing device has more dead corners, and materials accumulated in corners cannot be stirred and mixed. In addition, materials are accumulated in dead corners and cannot be cleaned, and bacteria are easily grown in the stirring device in the past, so that the cleanliness is low. Therefore, the design of the double-cone mixing device which is easy to have no dead angle enables materials to be uniformly mixed, and the mixing quality and efficiency are improved, which is particularly important.

SUMMERY OF THE UTILITY MODEL

The present invention aims at least solving one of the technical problems existing in the prior art or the related art.

Therefore, the utility model provides a bipyramid mixing arrangement.

In view of this, the utility model provides a bipyramid mixing arrangement, bipyramid mixing arrangement includes: the device comprises a supporting seat, a bearing seat, a tank body, a rotating shaft, a bearing, a driven wheel, a motor, a driving wheel, a belt, a feeding hole, a dispersing shaft, a first connecting rod, a blade, a second connecting rod and a discharging hole; the two supporting seats are symmetrically arranged; the two bearing blocks are respectively fixed on the two supporting seats; the two ends of the tank body are conical, and the tank body is positioned between the two supporting seats; one ends of the two rotating shafts are simultaneously connected with the side wall of the tank body, and the other ends of the two rotating shafts are respectively embedded into the two bearing blocks; the two bearings are respectively sleeved on the outer sides of the two rotating shafts and are respectively embedded into the two bearing blocks; the driven wheel is sleeved on the outer side of one of the rotating shafts and synchronously rotates with one of the rotating shafts; the motor comprises a motor shaft, and the motor is fixed on one of the supporting seats; the driving wheel is sleeved on the outer side of the motor shaft, and the driving wheel and the motor shaft do not rotate relatively; the belt is wound on the outer sides of the driving wheel and the driven wheel simultaneously; the feed inlet is arranged at one end of the tank body; the dispersion shaft is parallel to the rotating shaft, embedded into the tank body and connected with the inner wall of the tank body; the first connecting rod is vertical to the dispersing shaft and is connected with the dispersing shaft after penetrating through the dispersing shaft; one end of each of the at least two paddles is connected with two ends of the first connecting rod respectively; the second connecting rod is perpendicular to the first connecting rod, and after the second connecting rod penetrates through the dispersing shaft, the second connecting rod is simultaneously connected with the other ends of the at least two blades, and the length of the second connecting rod is greater than that of the first connecting rod; the discharge hole is symmetrically arranged at the other end of the tank body relative to the feed inlet.

In the technical scheme, firstly, two supporting seats are symmetrically arranged, and two bearing blocks are respectively fixed on the two supporting seats so as to stably support a bearing; secondly, two ends of the tank body are conical, and the tank body is positioned between the two supporting seats, so that when materials collide with the conical inner wall of the tank body, the materials do complex impact motion, and the mixing degree of the materials is improved; thirdly, one ends of the two rotating shafts are simultaneously connected with the side wall of the tank body, and the other ends of the two rotating shafts are respectively embedded into the two bearing blocks, so that the bearing blocks can support the tank body; thirdly, the two bearings are respectively sleeved on the outer sides of the two rotating shafts and are respectively embedded into the two bearing seats, so that the tank body is rotatably connected with the bearing seats, the flexibility of the tank body is improved, and materials are driven to rotate through the rotation of the tank body to be mixed; thirdly, the driven wheel is sleeved on the outer side of one of the rotating shafts and synchronously rotates with the one of the rotating shafts, so that the driven wheel drives the tank body to rotate; thirdly, the motor is fixed on one support seat to improve the stability of the motor; thirdly, the driving wheel is sleeved on the outer side of the motor shaft, and the driving wheel and the motor shaft do not rotate relatively, so that the driving wheel is driven to rotate by the motor; thirdly, the belt is wound on the outer sides of the driving wheel and the driven wheel at the same time, so that the driven wheel and the driving wheel synchronously rotate, the tank body is driven to rotate, and materials are mixed; thirdly, a feeding hole is formed in one end of the tank body, so that materials can be conveniently added into the tank body; thirdly, the dispersing shaft is parallel to the rotating shaft, is embedded into the tank body and is connected with the inner wall of the tank body, so that the dispersing shaft and the tank body synchronously rotate, and the mixing effect of the materials is improved; thirdly, after the first connecting rod penetrates through the dispersing shaft, the first connecting rod is connected with the dispersing shaft so as to be stably connected with the dispersing shaft and synchronously rotate; thirdly, one ends of at least two blades are respectively connected with two ends of the first connecting rod, so that the materials in the tank body are mixed again, and the mixing effect is improved; thirdly, after the second connecting rod is perpendicular to the first connecting rod and penetrates through the dispersing shaft, the second connecting rod is simultaneously connected with the other ends of the at least two blades, the length of the second connecting rod is larger than that of the first connecting rod, so that the blades have a certain inclination angle, the stirring effect is improved, the other ends of the blades are fixed, the stability of the blades is improved, and the blades and the rotating shaft synchronously rotate; thirdly, the discharge hole is symmetrically arranged at the other end of the tank body relative to the feed inlet, so that the mixed materials are directly discharged. By adopting the connection mode, the structure is simple, the two ends of the tank body are conical, powder or granular materials are conveyed into the double-conical tank body through vacuum or manually fed into the double-conical tank body, and the materials are subjected to complex impact motion in the container along with the continuous rotation of the tank body; and the rotating shaft rotates at a low speed, the tank body overturns to enable the materials in the full circumferential direction to be continuously updated and diffused, the two materials at the upper part are merged to the central recess again to form a downward material flow, and the vacancy at the bottom is supplemented, so that a convection circulation mixing effect is formed, the materials are uniformly mixed, and the operation is convenient, the labor intensity is low, and the working efficiency is high. Compared with a common mixing device, the double-cone tank body has fewer dead corners, and materials are not easy to accumulate in the tank body, so that all the materials are uniformly mixed; the tank has the advantages that no dead angle exists, the tank is easy to clean, water is added into the hopper, the tank is started to rotate, then the water is discharged, the tank body can be cleaned completely, and the cleanliness of the tank body is ensured.

Specifically, a jacket can be added outside the tank body according to the process requirements, and the cooling or heating of the material can be realized by injecting cold and hot media into the jacket; the industrial water is pumped in for cooling, and the steam or the electric heating heat conduction oil can be introduced for heating, so as to meet the temperature of material mixing and diffusion.

In addition, the utility model provides a bipyramid mixing arrangement among the above-mentioned technical scheme can also have following additional technical characterstic:

in the above technical solution, preferably, the double-cone mixing device further includes: a speed reducer; the speed reducer comprises an input shaft and an output shaft, the speed reducer is fixed on one of the supporting seats, the input shaft is connected with the motor shaft, and the output shaft is connected with one of the rotating shafts.

In this technical scheme, through fixing the speed reducer on one of them supporting seat, the input shaft is connected with the motor shaft, and the output shaft is connected with one of them pivot to reduce the rotational speed of motor, thereby reduce the rotational speed of pivot, thereby reduce the centrifugal force that the internal material of jar received when rotating, ensure that the material can receive gravity whereabouts, intensive mixing.

Specifically, the speed reducer and the motor adopt an integrated speed reducing motor SZG-28H produced by Yongkun motor factory.

In the above technical solution, preferably, the tank further includes: the device comprises a cylinder, a first cone and a second cone; the barrel is a hollow cavity with openings at two ends, and is connected with the two rotating shafts; the first cone and the cover are arranged at one opening end of the cylinder body, and the first cone is connected with the cylinder body; the second cone and the cover are arranged at the other opening end of the cylinder body, and the second cone is connected with the cylinder body.

In the technical scheme, the barrel is a hollow cavity with openings at two ends, and the barrel is connected with the two rotating shafts, so that the barrel and the rotating shafts synchronously rotate; the first cone and the cover are arranged at one opening end of the barrel body, the first cone is connected with the barrel body, the second cone and the cover are arranged at the other opening end of the barrel body, the second cone is connected with the barrel body, and the first cone and the second cone have slopes, so that materials fall under gravity and then collide with the first cone or the second cone to bounce in different directions in the rotating and mixing process and continuously diffuse; the two materials at the upper part are converged to the central recess to form a downward material flow, and the vacancy at the bottom is supplemented, so that the mixing effect of convection circulation is formed, and the mixing effect of the materials is improved again.

In the above technical solution, preferably, the double-cone mixing device further includes: a connecting portion; connecting portion are the arc, and one side of two connecting portion is connected with two pivots respectively, and the opposite side of two connecting portion is connected with the outer wall of barrel simultaneously.

In this technical scheme, be the arc through making connecting portion, one side of two connecting portions is connected with two pivots respectively, and the opposite side of two connecting portions is connected with the outer wall of barrel simultaneously to the shape of adaptation barrel, the area of contact of increase and barrel is convenient for be connected pivot and barrel stability, avoids connecting not hard up, reduces the maintenance number of times.

In the above technical solution, preferably, the double-cone mixing device further includes: a first dispersion rib and a second dispersion rib; the plurality of first dispersion ribs are arranged on the side wall of the first cone; and the plurality of second dispersion ribs are arranged on the side wall of the second cone.

In this technical scheme, through making the setting of the first dispersion muscle of a plurality of on the lateral wall of first cone to set up the vortex effect of the material of gathering together is realized to the lateral wall of a plurality of second dispersion muscle on the second cone, promotes the dispersion effect to the material, thereby improves the degree of mixing.

In the above technical solution, preferably, the feed inlet further includes: a first body and a sealing cover; the first body penetrates through the first cone and protrudes in a direction departing from the first body; the sealing cover is arranged above the first body in a covering mode, and the sealing cover is rotatably connected with the first body.

In this technical scheme, through making first body run through first cone, and first body is protruding to the direction that deviates from first body to seal the lid and establish the top at first body, and sealed lid rotates with first body to be connected, so as to seal first body, thereby when avoiding jar body inversion, the material spills, reduces extravagantly.

In above-mentioned technical scheme, preferably, the discharge gate still includes: a second body and a butterfly valve; the second body penetrates through the second cone and protrudes in the direction departing from the second body; the butterfly valve is connected with the second body.

In the technical scheme, the second body penetrates through the second cone, the second body protrudes in the direction away from the second body, the butterfly valve is connected with the second body, the mixed materials can be discharged by opening the butterfly valve, the raw materials do not need to be contacted by hands, and the device is simple and sanitary; when the butterfly valve is closed, the discharge hole is sealed, no material is discharged, and the operation is simple.

Specifically, the butterfly valve is a D71X model manual butterfly valve with rubber lining manufactured by Shanghai Zhasen self-control valve manufacturing Limited.

Additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 shows a schematic structural view of a double cone mixing device according to an embodiment of the present invention;

FIG. 2 shows a schematic structural view of a double cone mixing device according to another embodiment of the present invention;

wherein, the correspondence between the reference numbers and the component names in fig. 1 and fig. 2 is:

10 supporting seats, 12 bearing seats, 14 tank bodies, 141 cylinder bodies, 142 first cones, 143 second cones, 16 rotating shafts, 18 bearings, 20 driven wheels, 22 motors, 24 driving wheels, 26 belts, 28 feed inlets, 281 first bodies, 282 sealing covers, 30 dispersing shafts, 32 first connecting rods, 34 blades, 36 second connecting rods, 38 discharge outlets, 381 second bodies, 382 butterfly valves, 40 speed reducers, 42 connecting parts, 44 first dispersing ribs and 46 second dispersing ribs.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention more clearly understood, the present invention will be described in further detail with reference to the accompanying drawings and detailed description. It should be noted that the embodiments and features of the embodiments of the present application may be combined with each other without conflict.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced in other ways than those specifically described herein, and therefore the scope of the present invention is not limited by the specific embodiments disclosed below.

A double cone mixing device according to some embodiments of the present invention is described below with reference to fig. 1 and 2.

In an embodiment of the present invention, as shown in fig. 1 and 2, the present invention provides a double-cone mixing device, comprising: the device comprises a supporting seat 10, a bearing seat 18, a tank body 14, a rotating shaft 16, a bearing 18, a driven wheel 20, a motor 22, a driving wheel 24, a belt 26, a feeding hole 28, a dispersing shaft 30, a first connecting rod 32, a blade 34, a second connecting rod 36 and a discharging hole 38; the two supporting seats 10 are symmetrically arranged; the two bearing blocks 18 are respectively fixed on the two supporting seats 10; the two ends of the tank body 14 are conical, and the tank body 14 is positioned between the two supporting seats 10; one end of each of the two rotating shafts 16 is connected with the side wall of the tank 14, and the other end of each of the two rotating shafts 16 is embedded into each of the two bearing blocks 18; the two bearings 18 are respectively sleeved on the outer sides of the two rotating shafts 16, and the two bearings 18 are respectively embedded into the two bearing seats 18; the driven wheel 20 is sleeved on the outer side of one of the rotating shafts 16, and the driven wheel 20 and one of the rotating shafts 16 rotate synchronously; the motor 22 comprises a motor 22 shaft, and the motor 22 is fixed on one of the supporting seats 10; the driving wheel 24 is sleeved outside the shaft of the motor 22, and the driving wheel 24 and the shaft of the motor 22 do not rotate relatively; the belt 26 is wound on the outer sides of the driving wheel 24 and the driven wheel 20; the feed inlet 28 is arranged at one end of the tank body 14; the dispersing shaft 30 is parallel to the rotating shaft 16, the dispersing shaft 30 is embedded in the tank body 14, and the dispersing shaft 30 is connected with the inner wall of the tank body 14; the first connecting rod 32 is perpendicular to the dispersion shaft 30, and after the first connecting rod 32 passes through the dispersion shaft 30, the first connecting rod 32 is connected with the dispersion shaft 30; one ends of at least two paddles 34 are connected to both ends of the first connecting rod 32, respectively; the second connecting rod 36 is perpendicular to the first connecting rod 32, after the second connecting rod 36 passes through the dispersion shaft 30, the second connecting rod 36 is simultaneously connected with the other ends of the at least two paddles 34, and the length of the second connecting rod 36 is greater than that of the first connecting rod 32; the discharge port 38 is symmetrically disposed at the other end of the tank 14 with respect to the feed port 28.

In this embodiment, first, the two support seats 10 are symmetrically arranged, and the two bearing blocks 18 are respectively fixed on the two support seats 10, so as to stably support the bearings 18; secondly, two ends of the tank body 14 are conical, and the tank body 14 is positioned between the two supporting seats 10, so that when materials collide with the conical inner wall of the tank body 14, the materials do complex impact motion to improve the mixing degree of the materials; thirdly, one ends of the two rotating shafts 16 are simultaneously connected with the side wall of the tank body 14, and the other ends of the two rotating shafts 16 are respectively embedded into the two bearing seats 18, so that the bearing seats 18 can support the tank body 14; thirdly, the two bearings 18 are respectively sleeved on the outer sides of the two rotating shafts 16, and the two bearings 18 are respectively embedded into the two bearing seats 18, so that the tank body 14 is rotatably connected with the bearing seats 18, the flexibility of the tank body 14 is improved, and materials are driven to rotate by the rotation of the tank body 14 to be mixed; thirdly, the driven wheel 20 is sleeved on the outer side of one of the rotating shafts 16, and the driven wheel 20 rotates synchronously with one of the rotating shafts 16, so that the driven wheel 20 drives the tank 14 to rotate; thirdly, the motor 22 is fixed on one of the supporting seats 10, so that the stability of the motor 22 is improved; thirdly, the driving wheel 24 is sleeved outside the shaft of the motor 22, and the driving wheel 24 and the shaft of the motor 22 do not rotate relatively, so that the driving wheel 24 is driven to rotate by the motor 22; thirdly, the belt 26 is wound on the outer sides of the driving wheel 24 and the driven wheel 20 at the same time, so that the driven wheel 20 and the driving wheel 24 synchronously rotate, the tank body 14 is driven to rotate, and materials are mixed; again, by locating feed inlet 28 at one end of tank 14, the addition of material to tank 14 is facilitated; thirdly, the dispersing shaft 30 is parallel to the rotating shaft 16, the dispersing shaft 30 is embedded into the tank body 14, and the dispersing shaft 30 is connected with the inner wall of the tank body 14, so that the dispersing shaft 30 and the tank body 14 rotate synchronously, and the mixing effect of the materials is improved; thirdly, by making the first connecting rod 32 perpendicular to the dispersion shaft 30, after the first connecting rod 32 passes through the dispersion shaft 30, the first connecting rod 32 is connected with the dispersion shaft 30, so that the first connecting rod 32 and the dispersion shaft 30 are stably connected and synchronously rotate; thirdly, one ends of at least two paddles 34 are respectively connected with two ends of the first connecting rod 32 to mix the materials in the tank 14 again, so that the mixing effect is improved; thirdly, the second connecting rod 36 is perpendicular to the first connecting rod 32, after the second connecting rod 36 passes through the dispersion shaft 30, the second connecting rod 36 is simultaneously connected with the other ends of the at least two paddles 34, and the length of the second connecting rod 36 is greater than that of the first connecting rod 32, so that the paddles 34 have a certain inclination angle, the stirring effect is improved, the other ends of the paddles 34 are fixed, the stability of the paddles 34 is improved, and the paddles 34 and the rotating shaft 16 synchronously rotate; again, the discharge port 38 is symmetrically arranged at the other end of the tank 14 relative to the feed port 28, so that the mixed materials can be directly discharged. By adopting the connection mode, the structure is simple, the two ends of the tank body 14 are conical, powder or granular materials are conveyed into the double-conical tank body 14 through vacuum or manually fed into the double-conical tank body 14, and the materials are subjected to complex impact motion in the container along with the continuous rotation of the tank body 14; and the rotating shaft 16 rotates at a slow speed, the tank body 14 is turned over, so that the materials in the full circumferential direction are continuously updated and diffused, the two materials at the upper part are converged to the central recess to form a downward material flow, and the vacancy at the bottom is supplemented, so that a convection circulation mixing effect is formed, the materials are uniformly mixed, and the operation is convenient, the labor intensity is low, and the working efficiency is high. Compared with a common mixing device, the double-cone tank body 14 has less dead angles, materials are not easy to accumulate in the tank body 14, and the uniform mixing of all the materials is ensured; no dead angle and easy cleaning, and the tank body 14 can be cleaned only by adding water into the hopper, starting the machine to rotate and then discharging the water, thereby ensuring the cleanliness in the tank body 14.

Specifically, a jacket can be added outside the tank 14 according to the process requirements, and the material can be cooled or heated by injecting cold and hot media into the jacket; the industrial water is pumped in for cooling, and the steam or the electric heating heat conduction oil can be introduced for heating, so as to meet the temperature of material mixing and diffusion.

In an embodiment of the present invention, preferably, as shown in fig. 1 and 2, the double-cone mixing device further comprises: a speed reducer 40; the speed reducer 40 comprises an input shaft and an output shaft, the speed reducer 40 is fixed on one of the support seats 10, the input shaft is connected with the motor 22, and the output shaft is connected with one of the rotating shafts 16.

In this embodiment, the speed reducer 40 is fixed on one of the support bases 10, the input shaft is connected with the motor 22, and the output shaft is connected with one of the rotating shafts 16, so as to reduce the rotating speed of the motor 22, and thus the rotating speed of the rotating shaft 16, and thus the centrifugal force received when the materials in the tank 14 rotate is reduced, and the materials can fall under the gravity and be fully mixed.

Specifically, the speed reducer 40 and the motor 22 adopt an integrated speed reducing motor 22SZG-28H produced by the Yongkun motor factory.

In an embodiment of the present invention, preferably, as shown in fig. 1, the tank 14 further includes: a barrel 141, a first cone 142 and a second cone 143; the cylinder 141 is a hollow cavity with openings at two ends, and the cylinder 141 is connected with the two rotating shafts 16; the first cone 142 and the cover are arranged at one opening end of the cylinder body 141, and the first cone 142 is connected with the cylinder body 141; the second cone 143 and the cover are provided at the other opening end of the cylinder 141, and the second cone 143 is connected to the cylinder 141.

In this embodiment, the cylinder 141 is a hollow cavity with openings at two ends, and the cylinder 141 is connected to the two rotating shafts 16, so that the cylinder 141 and the rotating shafts 16 rotate synchronously; the first cone 142 and the cover are arranged at one opening end of the cylinder body 141, the first cone 142 is connected with the cylinder body 141, the second cone 143 and the cover are arranged at the other opening end of the cylinder body 141, the second cone 143 is connected with the cylinder body 141, and the first cone 142 and the second cone 143 have slopes, so that materials fall under gravity and collide with the first cone 142 or the second cone 143 to bounce in different directions in the rotating and mixing process and are continuously diffused; the two materials at the upper part are converged to the central recess to form a downward material flow, and the vacancy at the bottom is supplemented, so that the mixing effect of convection circulation is formed, and the mixing effect of the materials is improved again.

In an embodiment of the present invention, preferably, as shown in fig. 1 and 2, the double-cone mixing device further comprises: a connecting portion 42; the connecting portions 42 are arc-shaped, one sides of the two connecting portions 42 are respectively connected with the two rotating shafts 16, and the other sides of the two connecting portions 42 are simultaneously connected with the outer wall of the cylinder 141.

In this embodiment, by making the connecting portions 42 arc, one side of each of the two connecting portions 42 is connected to the two rotating shafts 16, and the other side of each of the two connecting portions 42 is connected to the outer wall of the barrel 141, so as to adapt to the shape of the barrel 141, increase the contact area with the barrel 141, facilitate stable connection between the rotating shafts 16 and the barrel 141, avoid loose connection, and reduce the number of maintenance times.

In an embodiment of the present invention, preferably, as shown in fig. 1, the double-cone mixing device further comprises: the first dispersion ribs 44 and the second dispersion ribs 46; a plurality of first dispersion ribs 44 are arranged on the side wall of the first cone 142; a plurality of second dispersion ribs 46 are provided on the side wall of the second cone 143.

In this embodiment, the first dispersing ribs 44 are disposed on the side wall of the first cone 142, and the second dispersing ribs 46 are disposed on the side wall of the second cone 143, so that the turbulent flow effect on the gathered materials is realized, the dispersing effect on the materials is improved, and the mixing degree is improved.

In an embodiment of the present invention, preferably, as shown in fig. 1 and fig. 2, the feed inlet 28 further includes: a first body 281 and a sealing cover 282; the first body 281 penetrates the first cone 142, and the first body 281 is convex in a direction away from the first body 281; the sealing cover 282 covers the first body 281, and the sealing cover 282 is rotatably connected to the first body 281.

In this embodiment, the first body 281 penetrates through the first cone 142, the first body 281 protrudes in a direction away from the first body 281, the sealing cover 282 is disposed above the first body 281, and the sealing cover 282 is rotatably connected to the first body 281 to seal the first body 281, so that the material is prevented from being spilled when the can body 14 is inverted, and waste is reduced.

In an embodiment of the present invention, preferably, as shown in fig. 1, the discharging hole 38 further includes: a second body 381 and a butterfly valve 382; the second body 381 penetrates through the second cone 143, and the second body 381 protrudes in a direction away from the second body 381; the butterfly valve 382 is connected to the second body 381.

In this embodiment, by making the second body 381 penetrate the second cone 143, making the second body 381 convex in a direction away from the second body 381, and connecting the butterfly valve 382 with the second body 381, the mixed material can be discharged by opening the butterfly valve 382, without touching the raw material by hand, which is simple and sanitary; when the butterfly valve 382 is closed, the discharge hole 38 is sealed, no material is discharged, and the operation is simple.

Specifically, the butterfly valve 382 is a D71X model manual butterfly valve with a rubber lining manufactured by shanghai shosen autonomous valve manufacturing ltd.

In the description of the present invention, the terms "plurality" or "a plurality" refer to two or more, and unless otherwise specifically limited, the terms "upper", "lower", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are merely for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention; the terms "connected," "mounted," "secured," and the like are to be construed broadly and include, for example, fixed connections, removable connections, or integral connections; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

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

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. A double-cone mixing device, comprising:

the two supporting seats are symmetrically arranged;

the two bearing blocks are respectively fixed on the two supporting seats;

the two ends of the tank body are conical, and the tank body is positioned between the two supporting seats;

one ends of the two rotating shafts are connected with the side wall of the tank body at the same time, and the other ends of the two rotating shafts are respectively embedded into the two bearing seats;

the two bearings are respectively sleeved on the outer sides of the two rotating shafts and are respectively embedded into the two bearing seats;

the driven wheel is sleeved on the outer side of one of the rotating shafts and synchronously rotates with one of the rotating shafts;

the motor comprises a motor shaft, and is fixed on one of the supporting seats;

the driving wheel is sleeved on the outer side of the motor shaft, and the driving wheel and the motor shaft do not rotate relatively;

the belt is wound on the outer sides of the driving wheel and the driven wheel simultaneously;

the feed inlet is arranged at one end of the tank body;

the dispersion shaft is parallel to the rotating shaft, is embedded into the tank body and is connected with the inner wall of the tank body;

the first connecting rod is perpendicular to the dispersing shaft, and is connected with the dispersing shaft after penetrating through the dispersing shaft;

one ends of at least two paddles are respectively connected with two ends of the first connecting rod;

the second connecting rod is perpendicular to the first connecting rod, and after penetrating through the dispersion shaft, the second connecting rod is simultaneously connected with the other ends of the at least two blades, and the length of the second connecting rod is greater than that of the first connecting rod;

and the discharge hole is symmetrically arranged at the other end of the tank body relative to the feed inlet.

2. A bi-conical mixing device according to claim 1, further comprising:

the speed reducer comprises an input shaft and an output shaft, the speed reducer is fixed on one of the supporting seats, the input shaft is connected with the motor shaft, and the output shaft is connected with one of the rotating shafts.

3. A dual cone mixing device according to claim 2, wherein said canister further comprises:

the cylinder body is a hollow cavity with openings at two ends, and the cylinder body is connected with the two rotating shafts;

the first cone and the cover are arranged at one opening end of the cylinder body, and the first cone is connected with the cylinder body;

the second cone and the cover are arranged at the other opening end of the barrel body, and the second cone is connected with the barrel body.

4. A bi-conical mixing device according to claim 3, further comprising:

the connecting portion, connecting portion are the arc, two one side of connecting portion is respectively with two the pivot is connected, and two the opposite side of connecting portion simultaneously with the outer wall of barrel is connected.

5. A dual cone mixing device according to claim 4, further comprising:

the first dispersing ribs are arranged on the side wall of the first cone;

and the second dispersing ribs are arranged on the side wall of the second cone.

6. A double cone mixing device according to claim 5, wherein said feed inlet further comprises:

the first body penetrates through the first cone and protrudes in a direction away from the first body;

the sealing cover is arranged above the first body in a covering mode, and the sealing cover is rotatably connected with the first body.

7. A dual cone mixing device according to claim 6, wherein said spout further comprises:

the second body penetrates through the second cone and protrudes in a direction departing from the second body;

a butterfly valve connected with the second body.

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