CN219463208U - Mixing device and mixing equipment for feed products - Google Patents

Abstract

The utility model relates to the technical field of feed product mixing and discloses a feed product mixing device and mixing equipment, wherein the mixing device comprises a plurality of mixing plates which are sequentially arranged between adjacent roller shafts of a roller line, and the height of each mixing plate is smaller than that of each roller shaft; the stirring rods are arranged at the bottoms of the corresponding stirring plates. According to the stirring device and the stirring equipment for the feed product, when the feed product is positioned on the roller line, the stirring assembly is started and drives the long strip plates to reciprocate, the long strip plates drive the arc plates to reciprocate, the arc plates sequentially jack up the stirring rods and the stirring plates, the stirring plates drive the feed product to swing in an arc shape, the filling area of the feed product is filled into the empty area, so that the poured feed product gradually presents a uniform state, the gradual stirring of the feed product can be stably realized, the stirring process is smooth, and the stirring effect is good.

Description

Mixing device and mixing equipment for feed products

Technical Field

The utility model relates to the technical field of feed product mixing, in particular to a feed product mixing device and mixing equipment.

Background

Feed products are often used for cultivation or other industrial production. At present, the production of feed products is generally automated, i.e. automatic bagging, packaging, transportation, etc. Because the bagging of the feed product adopts a mode of injecting the feed product, the bottom of the feed product is relatively more abundant, and the top of the feed product is relatively empty, after the feed product is poured, the feed products at the two ends of the feed product are uneven, and the follow-up feed product stacking and transportation are not facilitated, so that the poured feed product needs to be uniformly shaken in advance, and then concentrated stacking and transportation are carried out.

In the prior art, a square rod is generally arranged on a conveying line and is driven to rotate so as to shake the feed product on the square rod. However, the method is more random for uniformly stirring the feed product, the uniformly stirring effect is not ideal enough, and the stability is poor.

Disclosure of Invention

The utility model aims to solve the problems of unsatisfactory stirring effect and poor stability of feed products in the prior art, and provides a stirring device and stirring equipment for the feed products.

In order to achieve the above object, according to one aspect of the present utility model, there is provided a stirring device for a feed product, comprising:

the stirring plates are sequentially arranged between adjacent roller shafts of the roller lines, and the heights of the stirring plates are smaller than the heights of the roller shafts;

the stirring rods are arranged at the bottoms of the corresponding stirring plates;

the evenly mixing seat comprises:

the long strip plate is arranged below the stirring rod;

the arc-shaped plate is arranged at the top of the long strip plate and is positioned on an extension line of the connecting lines of the plurality of stirring rods, and the top end of the arc-shaped plate is higher than the bottom end of the stirring rods;

and the stirring component is arranged on one side of the long strip plate and used for driving the long strip plate to reciprocate so that the arc-shaped plate can jack up a plurality of stirring rods in a reciprocating and sequential mode.

Optionally, two stirring rods are arranged at the bottom of each stirring plate, and the two stirring rods are respectively positioned at two ends of the bottom of each stirring plate; the stirring seats are two, and are respectively arranged below a plurality of stirring rods positioned at the same end of the stirring plates.

Optionally, the blending assembly includes:

the two support plates are respectively arranged on the opposite side walls of the two bases of the roller line, and the long slat is arranged above the corresponding support plate;

the two driving screws are respectively arranged at one side of the two long strips far away from each other;

the plurality of thread lantern rings are respectively sleeved on the outer sides of the two driving screws, and are respectively connected with the corresponding long strip plates;

and the reciprocating assembly is arranged between the two supporting plates and used for driving the two driving screws to synchronously reciprocate.

Optionally, the reciprocating assembly comprises:

the driving shafts are arranged at one ends of the two driving screws and are perpendicular to the two driving screws;

two first bevel gears respectively fixedly sleeved near two ends of the driving shaft;

the two second bevel gears are respectively arranged at one ends of the two driving screws, and the second bevel gears are in meshed connection with the corresponding first bevel gears;

the driving box is arranged between the two supporting plates and connected with the two supporting plates, and the driving shaft movably penetrates through the driving box;

the first gear is arranged in the driving box and fixedly sleeved on the outer side of the driving shaft;

the second gear is in meshed connection with the first gear and is in rotary connection with the inner wall of the driving box through a rotary shaft;

the rack is arranged on one side, far away from the first gear, of the second gear, and is in meshed connection with the second gear;

the baffle sets up the inner wall of drive case, the rack sets up on the baffle, and with baffle sliding connection.

Optionally, the reciprocating assembly further comprises:

the hollow ring plate is arranged on the side wall of the rack and is perpendicular to the rack;

the sliding block is arranged in the hollow annular plate and is in sliding connection with the inner wall of the hollow annular plate;

the rocker is arranged on one side, far away from the rack, of the hollow annular plate, and one end of the hollow annular plate is hinged with the sliding block;

one end of the connecting shaft is fixedly connected with the other end of the rocker;

the support column is movably sleeved on the outer side of the connecting shaft and is connected with the inner wall of the driving box;

the driving motor is arranged on the inner wall of the driving box, and the output end of the driving motor is connected with the other end of the connecting shaft.

Optionally, the number of teeth of the second gear is greater than the number of teeth of the first gear.

Optionally, the mixing device further includes:

the support rings are respectively sleeved on the outer sides of the uniformly stirring rods and are connected with the base;

the convex rings are respectively and fixedly sleeved on the outer sides of the stirring rods and are positioned above the corresponding supporting rings, and the shaft diameter of each convex ring is larger than that of the corresponding supporting ring.

Optionally, the mixing device further includes:

the grooves are formed in the tops of the long strip plates and the arc-shaped plates;

the wedge blocks are respectively arranged at the bottoms of the uniformly stirring rods, the wedge surfaces of the wedge blocks are close to the arc-shaped plates, and the bottom ends of the wedge blocks extend to the inner parts of the grooves.

Optionally, the mixing device further includes:

the inverted U-shaped bracket is arranged above the inlet end of the roller line and is connected with the top of the base;

the infrared sensor is arranged at the inner bottom of the inverted U-shaped bracket and is used for detecting the feed product on the roller line;

the material guiding frame is arranged above the inlet end of the roller line and is connected with the base.

On the other hand, the utility model also discloses a stirring device for the feed product, which comprises the following components:

the roller line comprises two bases and a plurality of uniformly distributed roller shafts, the roller shafts are arranged between the two bases, and two ends of the roller shafts are respectively and rotatably connected with the two bases;

the stirring device according to any one of the above.

According to the stirring device and the stirring equipment for the feed product, when the feed product is positioned on the roller line, the stirring assembly is started and drives the long slat to reciprocate, the long slat drives the arc plate to reciprocate, so that the arc plate sequentially jacks up a plurality of stirring rods and the stirring plates, the stirring plates drive the feed product to swing forwards in an arc shape, the filling area of the feed product is filled into a relatively empty area, the poured feed product gradually presents a uniform state, progressive stirring of the feed product can be stably realized, the stirring process is smooth, and the stirring effect is good.

Drawings

FIG. 1 is a schematic structural view of a mixing apparatus for a feed product according to one embodiment of the utility model;

fig. 2 is a schematic view of the position of an infrared sensor in a mixing device for a feed product according to one embodiment of the utility model;

FIG. 3 is a schematic view of the structure of a kneading seat in a kneading device for a feed product according to an embodiment of the present utility model;

FIG. 4 is an enlarged schematic view according to area A of FIG. 3;

FIG. 5 is an enlarged schematic view according to region B of FIG. 3;

FIG. 6 is a schematic view of the structure of the inside of a drive box in a mixing device for feed products according to one embodiment of the utility model;

FIG. 7 is a schematic view of the structure of the inside of a drive box in a mixing device for feed products according to one embodiment of the utility model;

fig. 8 is an enlarged schematic view according to region C in fig. 7.

Description of the reference numerals

1. Guide frame 2 and inverted U-shaped support

3. Base 4 and stirring plate

5. Roller shaft 6, drive screw

7. Support plate 8, infrared sensor

9. Drive shaft 10, drive box

11. Mixing seat 12, strip

13. Arcuate plate 14, second bevel gear

15. First bevel gear 16, threaded collar

17. Wedge 18, mixing rod

19. Support ring 20, collar

21. First gear 22, second gear

23. Rotating shaft 24, rack

25. Baffle 26, hollow annular plate

27. Drive motor 28, slider

29. Rocker 30, connecting shaft

31. Support column 32, groove

Detailed Description

The following describes the detailed implementation of the embodiments of the present utility model with reference to the drawings. It should be understood that the detailed description and specific examples, while indicating and illustrating the utility model, are not intended to limit the utility model.

FIG. 1 is a schematic structural view of a mixing apparatus for a feed product according to one embodiment of the utility model; FIG. 3 is a schematic view of the structure of a kneading seat in a kneading device for a feed product according to an embodiment of the present utility model; fig. 5 is an enlarged schematic view according to the region B of fig. 3, and in fig. 1, 3 and 5, the kneading device may include a plurality of kneading plates 4, a plurality of kneading bars 18, a kneading block 11 and a kneading assembly. Specifically, the kneading seat 11 may include a lath 12 and an arc 13.

The plurality of stirring plates 4 are sequentially arranged between the adjacent roller shafts 5 of the roller line, and the height of the stirring plates 4 is smaller than that of the roller shafts 5. A plurality of kneading bars 18 are provided at the bottom of the corresponding kneading plate 4. The lath 12 is arranged below the stirring rod 18, the arc-shaped plate 13 is arranged at the top of the lath 12 and is positioned on an extension line of a connecting line of a plurality of stirring rods 18, and the top end of the arc-shaped plate 13 is higher than the bottom end of the stirring rod 18. The mixing assembly is disposed at one side of the lath 12, and is used for driving the lath 12 to reciprocate so that the arc 13 reciprocally and sequentially jacks up the plurality of mixing rods 18.

As the feed product enters along the inlet end of the drum line, the feed product is progressively moved forward by the drive of the plurality of drum shafts 5. In the moving process of the feed product, the stirring component is started and drives the long slat 12 to reciprocate, and then the long slat 12 drives the arc-shaped plate 13 to reciprocate. Because the top of arc 13 is higher than the bottom of stirring rod 18, when arc 13 is close to a plurality of stirring rods 18, jack-up a plurality of stirring rods 18 in proper order and make the top of a plurality of stirring rods 18 be the arc and distribute, stir the stirring rod 18 and drive a plurality of stirring plates 4 and be the arc and distribute promptly. The poured feed product forms a certain inclination angle, namely gradient, when passing through the uniformly stirring plate 4 distributed in an arc shape, and the relatively filled area in the feed product is filled into the relatively empty area, so that the aim of uniformly stirring the feed product can be fulfilled.

The traditional stirring device is realized by driving the square rods to rotate so as to shake the feed product, but the square rods are distributed in parallel, no gradient with a larger angle is formed, and the shaking effect on the feed product is poor; and square pole is comparatively random to the stirring of fodder product, only relies on shake stirring, and stability is poor. In the embodiment of the utility model, the arc-shaped plate 13 is adopted to drive the plurality of stirring plates 4 to form an arc shape, so that the larger gradient can be improved to realize the stirring of the feed product, and the stirring effect of the feed product is improved; in addition, through the mode of mixing the even subassembly drive arc 13 reciprocating motion, can provide the synchronous mode of mixing of shake and slope to the fodder product, further improved the efficiency of mixing the fodder product. Furthermore, the stirring device can be directly installed on a roller line, a line body does not need to be modified, and the stirring device is wider in applicability and more practical.

In this embodiment of the present utility model, as shown in fig. 2 and 3, in order to further improve the stability and effectiveness of the lifting of the stirring rod 18 against the stirring plate 4, two stirring rods 18 are provided at the bottom of each stirring plate 4, and the two stirring rods 18 are respectively located at both ends of the bottom of the stirring plate 4. Specifically, the mixing seats 11 are provided in two, and are respectively disposed below the plurality of mixing bars 18 located at the same end of the plurality of mixing plates 4.

When the arc 13 lifts up the stirring rod 18, the two opposite stirring rods 18 support the corresponding stirring plate 4, so that the support strength and the support stability of the stirring plate 4 can be improved.

In this embodiment of the utility model, there may be a plurality of arcuate plates 13 for a single lath 12. In particular, the spacing between adjacent arcuate plates 13 on a single elongated plate 12 should be greater than the spacing between a plurality of mixing bars 18 at the same end. Specifically, a plurality of mixing plates 4 may be used as a set, and a plurality of sets of mixing plates 4 may be provided on the drum line. As shown in fig. 3, two groups of stirring plates 4 and three arc plates 13 are provided, so that the stirring effect of the feed product can be further improved.

In this embodiment of the utility model, as shown in fig. 2, 3 and 5, the blending assembly may include two support plates 7, two drive screws 6, a plurality of threaded collars 16, and a reciprocating assembly.

The two support plates 7 are respectively arranged on the opposite side walls of the two bases 3 of the roller line, and the strip plate 12 is arranged above the corresponding support plate 7. The two driving screws 6 are respectively arranged at one side of the two long strips 12 away from each other, a plurality of thread lantern rings 16 are respectively sleeved at the outer sides of the two driving screws 6, and the thread lantern rings 16 are respectively connected with the corresponding long strips 12. The reciprocating assembly is arranged in the middle of the two support plates 7 and is used for driving the two driving screws 6 to synchronously and reciprocally rotate.

When two long strips 12 need to be driven to move synchronously, the reciprocating assembly is started to drive the two driving screws 6 to rotate synchronously, and when the two driving screws 6 rotate, the corresponding threaded lantern rings 16 move along the extending direction of the driving screws 6, namely, the corresponding long strips 12 are driven to move, so that the aim of synchronously moving the two long strips 12 can be fulfilled.

In this embodiment of the utility model, the lath 12 is slidingly connected to the top of the corresponding support plate 7 in order to further increase the stability and reliability of the movement of the lath 12.

In this embodiment of the present utility model, as shown in fig. 4, 6, 7 and 8, the reciprocating assembly may include a driving shaft 9, two first bevel gears 15, two second bevel gears 14, a driving case 10, a first gear 21, a second gear 22, a rack 24, a partition 25, a hollow slide 26, a slider 28, a rocker 29, a connection shaft 30, a support column 31 and a driving motor 27.

The drive shaft 9 is arranged at one end of the two drive screws 6, and the drive shaft 9 is perpendicular to the two drive screws 6, and two ends of the drive shaft 9 are rotatably connected with a first fixing plate which is arranged at the top of the two support plates 7 in a protruding mode. Two first bevel gears 15 are fixedly sleeved near two ends of the driving shaft 9 respectively, two second bevel gears 14 are arranged at one ends of the two driving screws 6 respectively, the other ends of the driving screws 6 are in rotary connection with second fixing plates protruding from the tops of the corresponding supporting plates 7, and the second bevel gears 14 are in meshed connection with the corresponding first bevel gears 15. The driving box 10 is arranged between the two supporting plates 7 and is connected with the two supporting plates 7, and the driving shaft 9 penetrates through the driving box 10. The first gear 21 is arranged inside the driving box 10, and is fixedly sleeved outside the driving shaft 9, the second gear 22 is meshed with the first gear 21, and the second gear 22 is rotatably connected with the inner wall of the driving box 10 through a rotating shaft 23. The rack 24 is disposed on a side of the second gear 22 remote from the first gear 24, and the rack 24 is engaged with the second gear 22. The partition plate 25 is provided on the inner wall of the drive box 10, and the rack 24 is provided on the partition plate 25 and is slidably connected with the partition plate 25. The hollow ring plate 26 is provided at a side wall of the rack gear 24 and is perpendicular to the rack gear 24. The slider 28 is disposed inside the hollow ring plate 26 and is slidably connected to the inner wall of the hollow ring plate 26. The rocker 29 is arranged on the side of the hollow ring plate 26 remote from the rack 24, and one end of the hollow ring plate 26 is hinged with the sliding block 28. One end of the connecting shaft 30 is fixedly connected with the other end of the rocker 29, specifically, the other end of the rocker 29 is positioned at the axial center position of the hollow annular plate 26. The supporting column 31 is movably sleeved on the outer side of the connecting shaft 30 and is connected with the inner wall of the driving box 10. The driving motor 27 is provided on the inner wall of the driving case 10, and an output end of the driving motor 27 is connected to the other end of the connecting shaft 30.

When the two driving screws 6 need to be driven to synchronously rotate, the driving motor 27 is started, the connecting shaft 30 drives the other end of the rocker 29 to rotate, and the rocker 29 rotates to drive the sliding block 28 to rotate. In the rotating process of the sliding block 28, as the rack 24 is slidably connected with the partition 25, the sliding block 28 drives the hollow ring plate 26 and the rack 24 to reciprocate along the extending direction of the hollow ring plate, so as to drive the second gear 22 to reciprocate, and the second gear 22 drives the first gear 21 to reciprocate, that is, the first gear 21 drives the driving shaft 9 to reciprocate. The driving shaft 9 drives the two driving screws 6 to synchronously rotate through the meshing action of the two first bevel gears 15 and the two second bevel gears 14, so that the purpose of controlling the arc-shaped plates 13 to jack up a plurality of stirring rods 18 can be realized.

In this embodiment of the present utility model, the relative positional relationship of the two second bevel gears 14 may be determined according to the rotational directions of the two drive screws 6. If the rotation directions of the two driving screws 6 are the same, the two second bevel gears 14 should be arranged in parallel; if the rotation directions of the two drive screws 6 are opposite, the two second bevel gears 14 should be arranged in parallel.

In this embodiment of the present utility model, in order to ensure that the arc 13 can jack up a set of a plurality of kneading bars 18, the number of teeth of the second gear 22 is larger than that of the first gear 21.

In this embodiment of the utility model, the mixing device may further comprise a plurality of support rings 19 and a plurality of collars 20, as shown in fig. 5.

The plurality of support rings 19 are respectively sleeved on the outer sides of the plurality of stirring rods 18, and the support rings 19 are connected with the base 3. The convex rings 20 are respectively and fixedly sleeved on the outer sides of the stirring rods 18 and are positioned above the corresponding support rings 19, and the shaft diameter of the convex rings 20 is larger than that of the corresponding support rings 19.

In the normal state of the plurality of kneading bars 18, the convex ring 20 is limited in position by the support ring 19 to ensure that the corresponding kneading plate 4 is positioned at the initial position. In addition, when the arc-shaped plate 13 jacks up the stirring rod 18, the supporting ring 19 can also limit the stirring rod 18 to only move vertically and directly, so that the reliability of jacking up the feed product by the stirring plate 4 is further improved.

In this embodiment of the utility model, the blending means may further comprise a recess 32 and a plurality of wedges 17, as shown in fig. 5.

The groove 32 is formed in the tops of the strip plate 12 and the arc plate 13, the wedges 17 are respectively arranged at the bottoms of the uniformly stirring rods 18, the inclined surfaces of the wedges 17 are close to the arc plate 13, and the bottom ends of the wedges 17 extend to the inside of the groove 32.

The wedge surface of the wedge block 17 can facilitate the arc-shaped plate 13 to jack up the stirring rod 18, so that the flexibility and the reliability of the stirring device are improved. In addition, the groove 32 can limit the position of the wedge block 17, and the stability and the overall strength of the stirring device can be further improved.

In this embodiment of the present utility model, as shown in fig. 1 and 2, the mixing device may further include an inverted U-shaped bracket 2, an infrared sensor 8, and a guide frame 1.

The inverted U-shaped bracket 2 is arranged above the inlet end of the roller wire and is connected with the top of the base 3. An infrared sensor 8 is arranged at the inner bottom of the inverted U-shaped bracket 2 for detecting the feed product on the roller line. The material guiding frame 1 is arranged above the inlet end on the roller line and is connected with the base 3.

When the feed product enters along the inlet end of the roller line, it can be detected by the infrared sensor 8 and the drive motor 27 is controlled to start, and the feed guide frame 1 can adjust the dumping direction of the feed product so as to effectively mix the feed product subsequently.

In another aspect, the present utility model also provides a mixing apparatus for a feed product, as shown in figures 1 and 2. In particular, in fig. 1 and 2, the blending apparatus may include a drum line and a blending device. Specifically, the blending device may include a plurality of blending plates 4, a plurality of blending rods 18, a blending seat 11, and a blending assembly; the drum line may comprise two bases 3 and a plurality of drum shafts 5. Specifically, the kneading seat 11 may include a lath 12 and an arc 13.

The roller line comprises two bases 3 and a plurality of evenly distributed roller shafts 5, the roller shafts 5 are arranged between the two bases 3, and two ends of the roller shafts 5 are respectively connected with the two bases 3 in a rotating mode. The plurality of stirring plates 4 are sequentially arranged between the adjacent roller shafts 5 of the roller line, and the height of the stirring plates 4 is smaller than that of the roller shafts 5. A plurality of kneading bars 18 are provided at the bottom of the corresponding kneading plate 4. The lath 12 is arranged below the stirring rod 18, the arc-shaped plate 13 is arranged at the top of the lath 12 and is positioned on an extension line of a connecting line of a plurality of stirring rods 18, and the top end of the arc-shaped plate 13 is higher than the bottom end of the stirring rod 18. The mixing assembly is disposed at one side of the lath 12, and is used for driving the lath 12 to reciprocate so that the arc 13 reciprocally and sequentially jacks up the plurality of mixing rods 18.

As the feed product enters along the inlet end of the drum line, the feed product is progressively moved forward by the drive of the plurality of drum shafts 5. In the moving process of the feed product, the stirring component is started and drives the long slat 12 to reciprocate, and then the long slat 12 drives the arc-shaped plate 13 to reciprocate. Because the top of arc 13 is higher than the bottom of stirring rod 18, when arc 13 is close to a plurality of stirring rods 18, jack-up a plurality of stirring rods 18 in proper order and make the top of a plurality of stirring rods 18 be the arc and distribute, stir the stirring rod 18 and drive a plurality of stirring plates 4 and be the arc and distribute promptly. The poured feed product forms a certain inclination angle, namely gradient, when passing through the uniformly stirring plate 4 distributed in an arc shape, and the relatively filled area in the feed product is filled into the relatively empty area, so that the aim of uniformly stirring the feed product can be fulfilled.

According to the stirring device and the stirring equipment for the feed product, when the feed product is positioned on the roller line, the stirring assembly is started and drives the long slat 12 to reciprocate, the long slat 12 drives the arc plate 13 to reciprocate, the arc plate 13 sequentially jacks up the plurality of stirring rods 18 and the stirring plates 4, the plurality of stirring plates 4 drive the feed product to swing forwards in an arc shape, and the filled area of the feed product is filled into a relatively empty area, so that the poured feed product gradually presents a uniform state, gradual stirring of the feed product can be stably realized, the stirring process is smooth, and the stirring effect is good.

The preferred embodiments of the present utility model have been described in detail above with reference to the accompanying drawings, but the present utility model is not limited to the specific details of the above embodiments, and various simple modifications can be made to the technical solution of the present utility model within the scope of the technical concept of the present utility model, and all the simple modifications belong to the protection scope of the present utility model. In addition, the specific features described in the above embodiments may be combined in any suitable manner, and in order to avoid unnecessary repetition, various possible combinations are not described further.

Moreover, any combination of the various embodiments of the utility model can be made without departing from the spirit of the utility model, which should also be considered as disclosed herein.

Claims (10)

1. A mixing device for a feed product, comprising:

the stirring plates (4) are sequentially arranged between adjacent roller shafts (5) of the roller line, and the height of each stirring plate (4) is smaller than that of each roller shaft (5);

a plurality of stirring rods (18) arranged at the bottom of the corresponding stirring plate (4);

mixing seat (11), mixing seat (11) include:

a long strip plate (12) arranged below the stirring rod (18);

the arc-shaped plates (13) are arranged at the top of the long strip plates (12) and are positioned on extension lines of connecting lines of the plurality of stirring rods (18), and the top ends of the arc-shaped plates (13) are higher than the bottom ends of the stirring rods (18);

the stirring component is arranged on one side of the long strip plate (12) and is used for driving the long strip plate (12) to reciprocate so that the arc-shaped plate (13) can jack up a plurality of stirring rods (18) in sequence in a reciprocating mode.

2. The stirring device according to claim 1, characterized in that the bottom of each stirring plate (4) is provided with two stirring rods (18), and the two stirring rods (18) are respectively positioned at two ends of the bottom of the stirring plate (4); the stirring seats (11) are two, and are respectively arranged below a plurality of stirring rods (18) positioned at the same end of the stirring plates (4).

3. The blending apparatus of claim 2, wherein the blending assembly comprises:

the two support plates (7) are respectively arranged on the opposite side walls of the two bases (3) of the roller line, and the long strip plates (12) are arranged above the corresponding support plates (7);

two driving screws (6) respectively arranged at one side of the two long strips (12) away from each other;

the thread collars (16) are respectively sleeved on the outer sides of the two driving screws (6), and the thread collars (16) are respectively connected with the corresponding long strips (12);

the reciprocating assembly is arranged between the two supporting plates (7) and is used for driving the two driving screws (6) to synchronously and reciprocally rotate.

4. The blending apparatus of claim 3 wherein said reciprocating assembly comprises:

a driving shaft (9) arranged at one end of the two driving screws (6), wherein the driving shaft (9) is perpendicular to the two driving screws (6);

two first bevel gears (15) respectively fixedly sleeved near two ends of the driving shaft (9);

two second bevel gears (14) which are respectively arranged at one ends of the two driving screw rods (6), wherein the second bevel gears (14) are in meshed connection with the corresponding first bevel gears (15);

the driving box (10) is arranged between the two supporting plates (7) and is connected with the two supporting plates (7), and the driving shaft (9) movably penetrates through the driving box (10);

a first gear (21) which is arranged in the driving box (10) and fixedly sleeved on the outer side of the driving shaft (9);

the second gear (22) is in meshed connection with the first gear (21), and the second gear (22) is in rotary connection with the inner wall of the driving box (10) through a rotary shaft (23);

a rack (24) arranged on one side of the second gear (22) far away from the first gear (21), wherein the rack (24) is in meshed connection with the second gear (22);

the partition plate (25) is arranged on the inner wall of the driving box (10), and the rack (24) is arranged on the partition plate (25) and is in sliding connection with the partition plate (25).

5. The blending apparatus of claim 4, wherein said reciprocating assembly further comprises:

the hollow annular plate (26) is arranged on the side wall of the rack (24) and is perpendicular to the rack (24);

the sliding block (28) is arranged in the hollow annular plate (26) and is in sliding connection with the inner wall of the hollow annular plate (26);

the rocker (29) is arranged on one side, far away from the rack (24), of the hollow annular plate (26), and one end of the hollow annular plate (26) is hinged with the sliding block (28);

one end of the connecting shaft (30) is fixedly connected with the other end of the rocker (29);

the support column (31) is movably sleeved on the outer side of the connecting shaft (30) and is connected with the inner wall of the driving box (10);

the driving motor (27) is arranged on the inner wall of the driving box (10), and the output end of the driving motor (27) is connected with the other end of the connecting shaft (30).

6. The mixing device according to claim 4, characterized in that the number of teeth of the second gear (22) is greater than the number of teeth of the first gear (21).

7. The blending apparatus of claim 3, wherein the blending apparatus further comprises:

a plurality of support rings (19) respectively sleeved on the outer sides of the plurality of stirring rods (18), wherein the support rings (19) are connected with the base (3);

the convex rings (20) are fixedly sleeved on the outer sides of the stirring rods (18) respectively and are located above the corresponding supporting rings (19), and the shaft diameter of each convex ring (20) is larger than that of the corresponding supporting ring (19).

8. The blending device of claim 1, wherein the blending device further comprises:

the grooves (32) are formed in the tops of the long strips (12) and the arc plates (13);

the wedge blocks (17) are respectively arranged at the bottoms of the stirring rods (18), the wedge surfaces of the wedge blocks (17) are close to the arc-shaped plates (13), and the bottom ends of the wedge blocks (17) extend to the inside of the grooves (32).

9. The blending apparatus of claim 3, wherein the blending apparatus further comprises:

the inverted U-shaped bracket (2) is arranged above the inlet end of the roller line and is connected with the top of the base (3);

the infrared sensor (8) is arranged at the inner bottom of the inverted U-shaped bracket (2) and is used for detecting the feed product on the roller line;

the material guiding frame (1) is arranged above the inlet end of the roller line and is connected with the base (3).

10. A mixing apparatus for a feed product, comprising:

the roller line comprises two bases (3) and a plurality of uniformly distributed roller shafts (5), the roller shafts (5) are arranged between the two bases (3), and two ends of the roller shafts (5) are respectively connected with the two bases (3) in a rotating way;

a blending apparatus according to any of claims 1 to 9.