CN221714091U - Stirring dispersion all-in-one - Google Patents

Abstract

The utility model belongs to the technical field of mixing equipment, and specifically discloses an all-in-one mixing and dispersing machine, comprising a frame, a material cylinder placed in an activity space of the frame, a beam plate arranged on the top of the frame, and a first driving mechanism and a second driving mechanism installed on the beam plate, as well as a mixing mechanism and a dispersing mechanism, wherein the top end of the mixing mechanism is transmission-connected with the first driving mechanism so that the mixing mechanism can revolve along the central axis of the material cylinder, and the bottom end of the mixing mechanism extends into the material cylinder, the top end of the dispersing mechanism is transmission-connected with the second driving mechanism so that the dispersing mechanism can rotate, and the bottom end of the dispersing mechanism extends into the material cylinder, the mixing mechanism is driven to revolve along the central axis of the material cylinder by the first driving mechanism, thereby mixing the material in the material cylinder, and the dispersing mechanism is driven to rotate by the second driving mechanism, thereby dispersing the material in the material cylinder, the mixing and dispersing functions are integrated in the all-in-one machine, and the equipment purchase cost is reduced.

Description

A stirring and dispersing machine

Technical Field

The utility model relates to the technical field of stirring equipment, in particular to an all-in-one stirring and dispersing machine.

Background Art

The current mixers mainly include planetary mixers and powerful dispersers, which are used to mix and disperse materials. The two machines can achieve the functions of low-speed mixing and high-speed dispersion respectively. However, the functions of the two machines are relatively simple, and two devices need to be used separately to mix and disperse the materials, but the functions of mixing and dispersing at the same time cannot be achieved. The use process is relatively troublesome, and the purchase cost of the two devices is high.

Utility Model Content

In order to overcome the defects of the prior art, the utility model provides a stirring and dispersing all-in-one machine.

The technical solution adopted by the utility model to solve its technical problems is: an all-in-one stirring and dispersing machine, including a frame, a material cylinder placed in the activity space of the frame, a beam plate arranged on the top of the frame and a first drive mechanism and a second drive mechanism installed on the beam plate, and a stirring mechanism and a dispersing mechanism, the top end of the stirring mechanism is transmission-connected with the first drive mechanism so that the stirring mechanism can revolve along the central axis of the material cylinder, and the bottom end of the stirring mechanism extends into the material cylinder, the top end of the dispersing mechanism is transmission-connected with the second drive mechanism so that the dispersing mechanism can rotate, and the bottom end of the dispersing mechanism extends into the material cylinder.

As a further solution, the first driving mechanism includes a first driving member, a first driving shaft and a planetary box, the first driving member is installed on the beam plate, the first driving shaft is penetrated and rotatably arranged in the middle of the beam plate, and the top end of the first driving shaft is transmission-connected to the first driving member through a first transmission unit, the bottom end of the first driving shaft is fixedly connected to the middle of the planetary box, and the top end of the stirring mechanism is connected to the part of the planetary box away from the first driving shaft.

As a further solution, the top end of the stirring mechanism is rotatably connected to the part of the planetary box away from the first drive shaft, and the top end of the stirring mechanism is sleeved with a first planetary gear, the bottom end of the first drive shaft is sleeved with a first sun gear, and the first planetary gear is meshed with the first sun gear.

As a further solution, the second driving mechanism includes a second driving member and a second driving shaft, the second driving member is installed on the beam plate, the second driving shaft penetrates and is rotatably arranged on the beam plate, and the top end of the second driving shaft is transmission-connected to the second driving member through a second transmission unit, and the bottom end of the second driving shaft is transmission-connected to the top end of the dispersion mechanism.

As a further solution, the first drive shaft is a through-core structure, and the second drive shaft penetrates and is rotatably disposed in the through-core structure of the first drive shaft;

The top end of the dispersion mechanism is rotationally connected to the part of the planetary box away from the first drive shaft, and the top end of the dispersion mechanism is sleeved with a second planetary gear, the bottom end of the second drive shaft is sleeved with a second sun gear, and the second planetary gear is meshed with the second sun gear.

As a further solution, the stirring mechanism and the dispersing mechanism are each provided with two groups, the two stirring mechanisms and the two dispersing mechanisms are mirror-symmetrical about the central axis of the material cylinder, and the two stirring mechanisms and the two dispersing mechanisms are evenly and alternately distributed along the circumference of the material cylinder.

As a further solution, the stirring mechanism includes a first rotating shaft and a stirring paddle, the top end of the first rotating shaft is rotationally connected to the part of the planetary box away from the first driving shaft, and the bottom end of the first rotating shaft is connected to the top end of the stirring paddle.

As a further solution, the dispersion mechanism includes a second rotating shaft and a dispersion gear disk, the top end of the second rotating shaft is rotationally connected to the part of the planetary box away from the first drive shaft, and the bottom end of the second rotating shaft is connected to the dispersion gear disk.

As a further solution, a bottom wall scraper is connected to the bottom of the stirring paddle, and the bottom wall scraper can be against the bottom wall of the material cylinder;

An inner wall scraper is provided at a portion of the planetary box away from the first drive shaft, and the inner wall scraper can be pressed against the inner wall of the material cylinder.

As a further solution, a pulley is provided at the bottom of the cylinder;

The beam plate is movably arranged on the top of the frame through a lifting unit, so that the material cylinder can move into the activity space of the frame through a pulley.

The beneficial effects of the utility model are as follows: the utility model drives the stirring mechanism to revolve along the central axis of the material cylinder through the first driving mechanism, thereby stirring the material in the material cylinder through the stirring mechanism, and drives the dispersing mechanism to rotate through the second driving mechanism, thereby dispersing the material in the material cylinder through the dispersing mechanism, integrating the stirring and dispersing functions in an integrated machine, increasing the use function of the equipment, eliminating the trouble of separate stirring and dispersing, and reducing the equipment purchase cost.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic cross-sectional view of an embodiment of the present utility model;

Figure 2 is an enlarged view of point A in Figure 1;

FIG. 3 is a schematic diagram showing the positions of the stirring mechanism and the dispersing mechanism in the embodiment of the present utility model.

In the figure, a frame 1, a movable space 11, a sealing cover 12, a material cylinder 2, a pulley 21, a beam 3, a first driving mechanism 4, a first driving member 41, a first driving shaft 42, a planetary box 43, a first transmission unit 44, a first planetary gear 45, a first sun gear 46, a second driving mechanism 5, a second driving member 51, a second driving shaft 52, a second transmission unit 53, a second planetary gear 54, a second sun gear 55, a stirring mechanism 6, a first rotating shaft 61, a stirring paddle 62, a dispersing mechanism 7, a second rotating shaft 71, a dispersing toothed disc 72, a bottom wall scraper 8, an inner wall scraper 9, and a lifting unit 10.

DETAILED DESCRIPTION

The specific implementation methods of the present invention are further described below in conjunction with the accompanying drawings. It should be noted that the description of these implementation methods is used to help understand the present invention, but does not constitute a limitation of the present invention. In addition, the technical features involved in each implementation method of the present invention described below can be combined with each other as long as they do not conflict with each other.

As shown in Figure 1, the utility model provides a stirring and dispersing integrated machine, comprising a frame 1, a material cylinder 2 placed in an active space 11 of the frame 1, and a beam plate 3 arranged on the top of the frame 1. Preferably, a pulley 21 is provided at the bottom of the material cylinder 2, and the beam plate 3 is movably arranged on the top of the frame 1 through a lifting unit 10. The lifting unit 10 drives the beam plate 3 to rise, so that the material cylinder 2 can be moved from the side to the active space 11 of the frame 1 through the pulley 21. Among them, the lifting unit 10 can be selected as an oil cylinder, or other conventional mechanical lifting structures, as long as the beam plate 3 can be raised and lowered.

It should be noted that, as shown in FIG1 , a sealing cover 12 is provided between the material cylinder 2 and the beam plate 3. Specifically, the sealing cover 12 is fixed to the lower surface of the beam plate 3 and covers the planetary box 43. The lower end of the sealing cover 12 can be against the opening edge of the material cylinder 2 to prevent the material in the material cylinder 2 from splashing into the activity space 11 of the frame 1 during the mixing and dispersing process.

As shown in Figures 1 and 2, the stirring and dispersing machine also includes a first driving mechanism 4 and a second driving mechanism 56 installed on the beam plate 3, as well as a stirring mechanism 6 and a dispersing mechanism 7. The top end of the stirring mechanism 6 is connected to the first driving mechanism 4 so that the stirring mechanism 6 can revolve along the central axis of the material cylinder 2, and the bottom end of the stirring mechanism 6 extends into the material cylinder 2, so that the material in the material cylinder 2 is stirred by the stirring mechanism 6; the top end of the dispersing mechanism 7 is connected to the second driving mechanism 56 so that the dispersing mechanism 7 can rotate, and the bottom end of the dispersing mechanism 7 extends into the material cylinder 2, so that the material in the material cylinder 2 is dispersed by the dispersing mechanism 7.

The utility model drives the stirring mechanism 6 to revolve along the central axis of the material cylinder 2 through the first driving mechanism 4, so that the material in the material cylinder 2 is stirred by the stirring mechanism 6, and drives the dispersing mechanism 7 to rotate through the second driving mechanism 56, so that the material in the material cylinder 2 is dispersed by the dispersing mechanism 7. The functions of stirring and dispersing are integrated into an integrated machine, the use function of the equipment is increased, the trouble of separate stirring and dispersing is eliminated, and the purchase cost of the equipment is reduced.

As shown in FIG. 2 , the first driving mechanism 4 includes a first driving member 41, a first driving shaft 42 and a planetary box 43. The first driving member 41 can be a motor. The first driving member 41 is installed on the beam plate 3. The first driving shaft 42 is rotatably arranged in the middle of the beam plate 3, and the top of the first driving shaft 42 is connected to the first driving member 41 through a first transmission unit 44. The first transmission unit 44 can be a sprocket and chain structure or a synchronous wheel and synchronous belt structure. Because the resistance is large during stirring, the coordinated force of the sprocket and chain is large, so the first transmission unit 44 is preferably a sprocket and chain structure in this scheme. The bottom end of the first driving shaft 42 is fixedly connected to the middle of the planetary box 43, thereby driving the planetary box 43 to rotate along the first driving shaft 42, and the top end of the stirring mechanism 6 is connected to the part of the planetary box 43 away from the first driving shaft 42, so that the stirring mechanism 6 revolves along the first driving shaft 42. The first driving member 41 drives the first driving shaft 42 and the planetary box 43 to rotate, so that the stirring mechanism 6 revolves along the first driving shaft 42 , that is, the stirring mechanism 6 revolves along the central axis of the material cylinder 2 , so as to stir the material in the material cylinder 2 .

As a further improvement, as shown in Appendix 2, the top of the stirring mechanism 6 is rotatably connected to the part of the planetary box 43 away from the first drive shaft 42, and the top of the stirring mechanism 6 is sleeved with a first planetary gear 45, and the bottom of the first drive shaft 42 is sleeved with a first sun gear 46, and the first planetary gear 45 is meshed with the first sun gear 46. When the first drive shaft 42 rotates, the first planetary gear 45 is meshed with the first sun gear 46 to drive the stirring mechanism 6 to rotate in the planetary box 43, so that the stirring mechanism 6 rotates while revolving, so that the material is stirred more evenly.

Preferably, as shown in Figures 1 and 2, the second drive mechanism 56 includes a second drive member 51 and a second drive shaft 52, the first drive member 41 can be a motor, the second drive member 51 is installed on the beam plate 3, the second drive shaft 52 is rotatably arranged on the beam plate 3, and the top of the second drive shaft 52 is connected to the second drive member 51 through the second transmission unit 53, and the bottom of the second drive shaft 52 is connected to the top of the dispersion mechanism 7. The second transmission unit 53 can be a sprocket and chain structure or a synchronous wheel and synchronous belt structure. Because the dispersion requires a fast speed, the synchronous wheel and the synchronous belt are more closely matched, so the second transmission unit 53 in this solution is preferably a synchronous wheel and synchronous belt structure. The second drive shaft 52 is driven to rotate by the second drive member 51, so that the dispersion mechanism 7 rotates along the second drive shaft 52, thereby dispersing the material in the cylinder 2.

Further, as shown in FIG. 2 , the first drive shaft 42 is a through-hole structure, that is, the first drive shaft 42 is provided with through holes penetrating both ends thereof, and the second drive shaft 52 penetrates and is rotatably arranged in the through-hole structure of the first drive shaft 42, indicating that the first drive shaft 42 and the second drive shaft 52 are coaxial. The top end of the dispersion mechanism 7 is rotatably connected to the part of the planetary box 43 away from the first drive shaft 42, that is, the dispersion mechanism 7 will revolve along the first drive shaft 42 and will also rotate relative to the planetary box 43. The top end of the dispersion mechanism 7 is sleeved with a second planetary gear 54, and the bottom end of the second drive shaft 52 is sleeved with a second sun gear 55, and the second planetary gear 54 is meshed with the second sun gear 55. When the second drive shaft 52 rotates, the second planetary gear 54 meshes with the second sun gear 55 to drive the dispersion mechanism 7 to rotate, and the first drive shaft 42 and the planetary box 43 are driven to rotate through the first drive member 41, so that the dispersion mechanism 7 revolves along the first drive shaft 42, so that the dispersion mechanism 7 revolves while rotating, so that the material is dispersed more evenly.

As shown in Figures 1 to 3, two groups of stirring mechanisms 6 and two groups of dispersing mechanisms 7 are respectively provided, and the two groups of stirring mechanisms 6 and the two groups of dispersing mechanisms 7 are mirror-symmetrical with respect to the central axis of the material cylinder 2, and the two groups of stirring mechanisms 6 and the two groups of dispersing mechanisms 7 are evenly and alternately distributed along the circumference of the material cylinder 2, so that the force is more symmetrical when the integrated machine is stirring and dispersing.

As an embodiment thereof, as shown in FIG. 1 , the stirring mechanism 6 includes a first rotating shaft 61 and a stirring paddle 62. The top end of the first rotating shaft 61 is rotatably connected to the part of the planetary box 43 away from the first driving shaft 42, and the bottom end of the first rotating shaft 61 is connected to the top end of the stirring paddle 62. The stirring paddle 62 is used to stir the material, which is convenient for disassembly and cleaning. The stirring paddle 62 is preferably a folding paddle, which has a better stirring effect. It should be noted that the stirring mechanism 6 can also adopt other traditional mechanical structures as long as it can play a stirring role.

As an embodiment thereof, as shown in FIG. 1 , the dispersion mechanism 7 includes a second rotating shaft 71 and a dispersion toothed disc 72. The top end of the second rotating shaft 71 is rotatably connected to the part of the planetary box 43 away from the first driving shaft 42, and the bottom end of the second rotating shaft 71 is connected to the dispersion toothed disc 72. The material is dispersed by the dispersion toothed disc 72, which is also convenient for disassembly and cleaning. It should be noted that the dispersion mechanism 7 may also adopt other traditional mechanical structures as long as it can play a dispersing role.

As shown in Figure 1, the bottom of the stirring paddle 62 is connected to a bottom wall scraper 8, which can be against the bottom wall of the material cylinder 2. When the stirring paddle 62 revolves, the bottom wall scraper 8 scrapes off the material adhering to the bottom wall of the material cylinder 2, so that the material can be stirred and dispersed evenly; the part of the planetary box 43 away from the first drive shaft 42 is provided with an inner wall scraper 9, which drives the inner wall scraper 9 to revolve, and the inner wall scraper 9 can be against the inner wall of the material cylinder 2. The inner wall scraper 9 scrapes off the material adhering to the inner wall of the material cylinder 2, so that the material can be stirred and dispersed evenly.

The embodiments of the present invention are described in detail above with reference to the accompanying drawings, but the present invention is not limited to the described embodiments. For those skilled in the art, various changes, modifications, substitutions and variations of these embodiments are made without departing from the principles and spirit of the present invention, and still fall within the scope of protection of the present invention.

Claims (10)

1. The utility model provides a stirring dispersion all-in-one which characterized in that: including frame (1), place feed cylinder (2) in activity space (11) of frame (1), set up beam slab (3) at frame (1) top and install first actuating mechanism (4) and second actuating mechanism (56) on beam slab (3), and including rabbling mechanism (6) and dispersion mechanism (7), the top of rabbling mechanism (6) with first actuating mechanism (4) transmission is connected, so that rabbling mechanism (6) can revolve around the axis of feed cylinder (2), and in the bottom of rabbling mechanism (6) extends into feed cylinder (2), the top of dispersion mechanism (7) with second actuating mechanism (56) transmission is connected, so that dispersion mechanism (7) can rotate, and in the bottom of dispersion mechanism (7) extends into feed cylinder (2).

2. The stirring and dispersing integrated machine according to claim 1, wherein: the first driving mechanism (4) comprises a first driving piece (41), a first driving shaft (42) and a planetary box (43), the first driving piece (41) is arranged on the beam plate (3), the first driving shaft (42) penetrates through and is rotatably arranged in the middle of the beam plate (3), the top end of the first driving shaft (42) is in transmission connection with the first driving piece (41) through a first transmission unit (44), the bottom end of the first driving shaft (42) is fixedly connected with the middle of the planetary box (43), and the top end of the stirring mechanism (6) is connected with the part, far away from the first driving shaft (42), of the planetary box (43).

3. The stirring and dispersing integrated machine according to claim 2, wherein: the top of rabbling mechanism (6) with the part that planet case (43) kept away from first drive shaft (42) rotates to be connected, and first planet wheel (45) have been cup jointed on the top of rabbling mechanism (6), first sun gear (46) have been cup jointed to the bottom of first drive shaft (42), first planet wheel (45) and first sun gear (46) meshing.

4. The stirring and dispersing integrated machine according to claim 2, wherein: the second driving mechanism (56) comprises a second driving piece (51) and a second driving shaft (52), the second driving piece (51) is arranged on the beam plate (3), the second driving shaft (52) penetrates through and is rotatably arranged on the beam plate (3), the top end of the second driving shaft (52) is in transmission connection with the second driving piece (51) through a second transmission unit (53), and the bottom end of the second driving shaft (52) is in transmission connection with the top end of the dispersing mechanism (7).

5. The stirring and dispersing integrated machine according to claim 4, wherein:

The first driving shaft (42) is of a through-core structure, and the second driving shaft (52) penetrates through and is rotatably arranged on the through-core structure of the first driving shaft (42);

The top of dispersion mechanism (7) with part that planet case (43) kept away from first drive shaft (42) rotates to be connected, and second planet wheel (54) have been cup jointed on the top of dispersion mechanism (7), second sun gear (55) have been cup jointed to the bottom of second drive shaft (52), second planet wheel (54) and second sun gear (55) meshing.

6. The stirring and dispersing integrated machine according to claim 1, wherein: the stirring mechanism (6) and the dispersing mechanism (7) are respectively provided with two groups, the two groups of stirring mechanisms (6) and the two groups of dispersing mechanisms (7) are mirror symmetry with the central axis of the material cylinder (2), and the two groups of stirring mechanisms (6) and the two groups of dispersing mechanisms (7) are uniformly and alternately distributed along the circumferential direction of the material cylinder (2).

7. The stirring and dispersing integrated machine according to claim 2, wherein: the stirring mechanism (6) comprises a first rotating shaft (61) and a stirring paddle (62), the top end of the first rotating shaft (61) is rotationally connected with the part, far away from the first driving shaft (42), of the planetary box (43), and the bottom end of the first rotating shaft (61) is connected with the top end of the stirring paddle (62).

8. The stirring and dispersing integrated machine according to claim 2, wherein: the dispersing mechanism (7) comprises a second rotating shaft (71) and a dispersing fluted disc (72), the top end of the second rotating shaft (71) is rotationally connected with the part, far away from the first driving shaft (42), of the planetary box (43), and the bottom end of the second rotating shaft (71) is connected with the dispersing fluted disc (72).

9. The stirring and dispersing integrated machine according to claim 7, wherein: the bottom of the stirring paddle (62) is connected with a bottom wall edge scraper (8), and the bottom wall edge scraper (8) can be abutted against the bottom wall of the material cylinder (2);

the part of the planetary box (43) far away from the first driving shaft (42) is provided with an inner wall edge scraper (9), and the inner wall edge scraper (9) can be abutted against the inner wall of the material cylinder (2).

10. The stirring and dispersing integrated machine according to claim 1, wherein:

The bottom of the material cylinder (2) is provided with a pulley (21);

The beam plate (3) is movably arranged at the top of the frame (1) through the lifting unit (10), so that the material cylinder (2) moves into the movable space (11) of the frame (1) through the pulley (21).