CN211282737U - Different model material is unloader respectively - Google Patents

Abstract

The utility model relates to a different model material is unloader respectively. Comprises a supporting plate fixedly connected with supporting legs, and two groups of mandrels are fixedly connected on the supporting plate; a first storage bin device and a second storage bin device are respectively and rotatably connected to the two groups of mandrels, and a first shifting block assembly and a second shifting block assembly which are in meshed transmission with each other are respectively sleeved on the first storage bin device and the second storage bin device; a rotary driving component is fixedly connected on the bearing plate; the first storage bin device comprises a first core barrel and a first material barrel, a plurality of groups of first partition plates are fixedly connected between the first core barrel and the first material barrel, and a first material placing space is defined by the first material barrel, the first core barrel and two adjacent groups of first partition plates; the second storage bin device comprises a second core barrel and a second material barrel, a plurality of groups of second partition plates are fixedly connected between the second core barrel and the second material barrel, and a second material containing space is defined by the second material barrel, the second core barrel and two adjacent groups of second partition plates; the bearing plate is provided with a discharge hole. The utility model discloses the unloading operation in the time of accomplishing two kinds of different materials, operation process is simple convenient.

Description

Different model material is unloader respectively

Technical Field

The utility model belongs to the technical field of mechanical automation equipment, especially, relate to a different model material is unloader respectively.

Background

In the industrial field, there are many occasions where mechanical feeding by a blanking device is required. The blanking machine is also called as a charging machine, and refers to a machine which can uniformly, regularly and continuously feed blocky and granular materials from a storage bin to a receiving device in the production process.

The conventional blanking device comprises a vibrating disc, a feeder and the like. The vibrating disk is an auxiliary feeding device for automatic assembly or automatic processing machinery. The principle is to make the hopper vibrate vertically, and the parts in the hopper rise along a spiral track due to the vibration. During the ascending process, the parts can automatically enter the assembling or machining position in a uniform state according to the assembling or machining requirements through screening or posture change of a series of tracks. The feeder is a machine which applies force to materials by means of the acting force of the movement of the machine to move and transport the materials, and is commonly used for the automatic, numerical control and precise conveying of materials such as granular materials, powder materials, flaky materials, strip materials and the like.

In actual production, two materials of different types are required to be simultaneously discharged, but the vibration disc and the feeder can only automatically supply one material or supply different types of materials at staggered time intervals, so that a discharging device capable of simultaneously supplying different types of materials is urgently needed to be designed.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a solve the technical problem who exists among the well-known art and provide a different model material of different kinds of materials of ability simultaneous supply unloader respectively.

The utility model discloses a solve the technical scheme that technical problem that exists among the well-known technique took and be: a device for respectively discharging different types of materials comprises a transversely arranged bearing plate, the bottom of which is fixedly connected with a plurality of groups of supporting legs, and two groups of longitudinally arranged mandrels are fixedly connected on the bearing plate; the outer peripheral walls of the two groups of mandrels are respectively and rotatably connected with a first storage bin device and a second storage bin device, the outer peripheral walls of the first storage bin device and the second storage bin device are respectively sleeved with a first shifting block assembly and a second shifting block assembly, and the first shifting block assembly and the second shifting block assembly are in meshed transmission; a rotary driving component which is used for driving the first bin device/the second bin device to rotate for a certain angle and has a non-return function is fixedly connected to the bearing plate; the first storage bin device comprises a first core barrel which is coaxially sleeved outside a group of mandrels and is rotationally connected with the group of mandrels, and further comprises a first material barrel which is coaxially arranged with the first core barrel, a plurality of groups of longitudinally arranged first partition plates are fixedly connected between the outer peripheral wall of the first core barrel and the inner peripheral wall of the first material barrel, the plurality of groups of first partition plates are circumferentially distributed at equal angles, and a first material placing space is defined by the first material barrel, the first core barrel and two adjacent groups of first partition plates; the bottom of the first charging barrel is contacted with the top of the bearing plate; the second storage bin device comprises a second core barrel coaxially sleeved outside the other group of mandrels and rotatably connected with the second core barrel, and further comprises a second material barrel coaxially arranged with the second core barrel, a plurality of groups of second partition plates longitudinally arranged are fixedly connected between the outer peripheral wall of the second core barrel and the inner peripheral wall of the second material barrel, the plurality of groups of second partition plates are circumferentially distributed at equal angles, and the second material barrel, the second core barrel and the two adjacent groups of second partition plates jointly enclose a second material placing space; the bottom of the second charging barrel is contacted with the top of the bearing plate; and the bearing plate is provided with a discharge hole corresponding to the positions of the first material placing space and the second material placing space.

The utility model has the advantages that: the utility model provides a different type material respectively-discharging device, which can place two different materials by arranging a first material bin device and a second material bin device, namely, the two materials are respectively placed in a plurality of groups of first material placing spaces and a plurality of groups of second material placing spaces; the first storage bin device and the second storage bin device can rotate around the two groups of mandrels respectively, and the outer peripheral walls of the first storage bin device and the second storage bin device are sleeved with a first shifting block assembly and a second shifting block assembly which are meshed with each other respectively, so that the first storage bin device and the second storage bin device can rotate synchronously; the first bin device/the second bin device can be driven to rotate in a stepping mode for a certain angle in a certain direction by arranging the rotary driving assembly; the first feed bin device of rotary driving subassembly drive and the synchronous step-by-step rotation of second feed bin device to make each first material space of putting and the second material space of putting rotate the discharge gate in proper order, place in the first two kinds of materials of putting in material space and second material space and remove the top to the discharge gate in proper order, then fall in the discharge gate, the unloading operation when accomplishing two kinds of different materials, operation process is simple convenient.

Preferably: the rotary driving component comprises a linear driving piece which is fixedly connected with the bearing plate and is transversely arranged, a U-shaped seat is fixedly connected with the extending end of the linear driving piece, and a transverse moving seat is fixedly connected with the bottom of the U-shaped seat; a transversely arranged guide rail is fixedly connected to the top surface of the bearing plate, the extension direction of the guide rail is consistent with the extension direction of the extension end of the linear driving piece, and a sliding block matched with the guide rail is fixedly connected to the bottom of the transverse moving seat; the U-shaped seat is rotatably connected with a rotating shaft which is transversely arranged, and the inner end part of the rotating shaft is fixedly connected with a pushing block which is used for pushing the first shifting block assembly/the second shifting block assembly to rotate for a certain angle.

Preferably: the outer peripheral wall of the rotating shaft is sleeved with a torsion spring, and two end parts of the torsion spring are respectively connected with the rotating shaft and the U-shaped seat in the axial direction; and a limiting block which is matched with the top of the U-shaped seat in a collision way is fixedly connected to the peripheral wall of the rotating shaft.

Preferably: the top surface of the pushing block is an inclined surface which inclines from the free end to the rotating end towards the rotating shaft.

Preferably: the first shifting block assembly comprises a first shifting block sleeve which is sleeved on the outer peripheral wall of the first charging barrel and is in interference fit with the first shifting block sleeve, and a plurality of groups of first shifting blocks which are distributed at equal angles along the circumferential direction are fixedly connected to the outer peripheral wall of the first shifting block sleeve; the second shifting block assembly comprises a second shifting block sleeve which is sleeved on the outer peripheral wall of the second charging barrel and is in interference fit with the second shifting block sleeve, and a plurality of groups of second shifting blocks which are distributed at equal angles along the circumferential direction are fixedly connected to the outer peripheral wall of the second shifting block sleeve; the first shifting block is meshed with the second shifting block.

Preferably: the bearing plate is fixedly connected with a wear-resistant plate made of wear-resistant materials, and the bottom surfaces of the first charging barrel and the second charging barrel are both contacted with the top surface of the wear-resistant plate.

Preferably: the bottom of the bearing plate is fixedly connected with a discharge channel which is used for aligning with the discharge hole.

Preferably: a feeding frame is fixedly connected on the bearing plate.

Drawings

Fig. 1 is a schematic perspective view of the present invention;

fig. 2 is a schematic perspective view of the rotary driving assembly of the present invention;

FIG. 3 is a schematic perspective view of a support plate of the present invention;

fig. 4 is a schematic top view of the feeding frame of the present invention;

fig. 5 is a schematic sectional structure view of a-a in fig. 4.

In the figure: 1. a discharge channel; 2. a support plate; 3. a support leg; 4. a wear plate; 5. a feeding frame; 6. a first bin device; 6-1, a first barrel; 6-2, a first divider plate; 6-3, a first core barrel; 6-4, a first material placing space; 7. a mandrel; 8. a first shifting block assembly; 8-1, a first shifting block sleeve; 8-2, a first shifting block; 9. a second bin device; 9-1, a second barrel; 9-2, a second partition plate; 9-3, a second core barrel; 9-4, a second material placing space; 10. a rotary drive assembly; 10-1, a transverse moving seat; 10-2, a torsion spring mounting member; 10-3, a U-shaped seat; 10-4, a rotating shaft; 10-5, a torsion spring; 10-6, a limiting block; 10-7, a linear driving piece; 10-8, a pushing block; 10-9, guide rails; 11. a second paddle assembly; 11-1 and a second shifting block sleeve; 11-2, a second shifting block; 12. and (4) a discharge port.

Detailed Description

In order to further understand the contents, features and effects of the present invention, the following embodiments are described in detail:

referring to fig. 1, the separate blanking device for different types of materials of the present invention comprises a transversely disposed support plate 2 having a plurality of sets of legs 3 fixed to the bottom thereof, and two sets of vertically disposed mandrels 7 fixed to the support plate 2; and a first storage bin device 6 and a second storage bin device 9 are respectively and rotatably connected to the peripheral walls of the two groups of mandrels 7. A feeding frame 5 is fixedly connected on the bearing plate 2. The utility model discloses use with the cooperation of feed conveyor, feed conveyor carries different types of material respectively to in first feed bin device 6 and the second feed bin device 9.

With further reference to fig. 4 and 5, the first bunker device 6 includes a first core barrel 6-3 coaxially sleeved outside the set of mandrels 7 and rotatably connected therewith, and further includes a first material barrel 6-1 coaxially arranged with the first core barrel 6-3, wherein a plurality of sets of longitudinally arranged first partition plates 6-2 are fixedly connected between the outer peripheral wall of the first core barrel 6-3 and the inner peripheral wall of the first material barrel 6-1, the plurality of sets of first partition plates 6-2 are circumferentially equiangularly distributed, and the first material barrel 6-1, the first core barrel 6-3 and two adjacent sets of first partition plates 6-2 jointly enclose a first material accommodating space 6-4; the bottom of the first cartridge 6-1 is in contact with the top of the support plate 2.

The second storage bin device 9 comprises a second core barrel 9-3 coaxially sleeved outside the other group of core shafts 7 and rotatably connected with the same, and further comprises a second material barrel 9-1 coaxially arranged with the second core barrel 9-3, a plurality of groups of second partition plates 9-2 longitudinally arranged are fixedly connected between the outer peripheral wall of the second core barrel 9-3 and the inner peripheral wall of the second material barrel 9-1, the plurality of groups of second partition plates 9-2 are circumferentially distributed at equal angles, and the second material barrel 9-1, the second core barrel 9-3 and the two adjacent groups of second partition plates 9-2 jointly enclose a second material containing space 9-4; the bottom of the second cartridge 9-1 is in contact with the top of the support plate 2.

As shown in fig. 1 and 3, the supporting plate 2 is provided with a discharge hole 12 corresponding to the positions of the first material placing spaces 6-4 and the second material placing spaces 9-4. The discharge ports corresponding to the group of first material placing spaces 6-4 and the discharge ports corresponding to the group of second material placing spaces 9-4 can be communicated with each other to form a discharge port 12; the discharge ports corresponding to the group of first material placing spaces 6-4 and the discharge ports corresponding to the group of second material placing spaces 9-4 can also form the discharge ports 12 respectively.

The bearing plate 2 is fixedly connected with a wear-resistant plate 4 made of wear-resistant materials, and the wear-resistant plate 4 is provided with notches with the same size corresponding to the discharge hole 12. The bottom surfaces of the first cartridge 6-1 and the second cartridge 9-1 are in contact with the top surface of the wear plate 4. The bottom of the bearing plate 2 is fixedly connected with a discharge channel 1 which is aligned with the discharge hole 12.

Further referring to fig. 1, a first shifting block assembly 8 and a second shifting block assembly 11 are respectively sleeved on the peripheral walls of the first bin device 6 and the second bin device 9, and the first shifting block assembly 8 and the second shifting block assembly 11 are in meshing transmission with each other. The first shifting block assembly 8 comprises a first shifting block sleeve 8-1 which is sleeved on the outer peripheral wall of the first charging barrel 6-1 and is in interference fit with the first shifting block sleeve, and a plurality of groups of first shifting blocks 8-2 which are distributed at equal angles along the circumferential direction are fixedly connected to the outer peripheral wall of the first shifting block sleeve 8-1; the second shifting block assembly 11 comprises a second shifting block sleeve 11-1 which is sleeved on the outer peripheral wall of the second charging barrel 9-1 and is in interference fit with the second shifting block sleeve, and a plurality of groups of second shifting blocks 11-2 which are distributed at equal angles along the circumferential direction are fixedly connected to the outer peripheral wall of the second shifting block sleeve 11-1; the first shifting block 8-2 is engaged with the second shifting block 11-2.

The included angle between two adjacent groups of first shifting blocks 8-2 is equal to alpha, and the included angle between two adjacent groups of second shifting blocks 11-2 is equal to beta.

As shown in fig. 1 and 4, a rotation driving assembly 10 for driving the first bin device 6/the second bin device 9 to rotate at a certain angle and having a non-return function is fixedly connected to the supporting plate 2.

In this embodiment, an included angle between two adjacent sets of first partition plates 6-2 is denoted by α, and an included angle between two adjacent sets of second partition plates 9-2 is denoted by β. The sizes of the first barrel 6-1, the first core barrel 6-3, the second barrel 9-1, and the second core barrel 9-3 and the numbers of the first partition plate 6-2 and the second partition plate 9-2 may be selected according to actual circumstances.

In this embodiment, the rotation driving component 10 can drive the second bin device 9 to rotate, that is, the rotation driving component 10 drives the second shifting block component 11 to rotate by β degrees and further drive the second bin device 9 to rotate by β degrees, because the first shifting block component 8 and the second shifting block component 11 are engaged with each other, the second shifting block component 11 rotates by β degrees and can drive the first shifting block component 8 to rotate by α degrees, and the first bin device 6 rotates by α degrees under the driving of the first shifting block component 8. In the rotating process of the first storage bin device 6 and the second storage bin device 9, the first material placing space 6-4 and the second material placing space 9-4 sequentially rotate through the discharge port 12, and two materials placed in the first material placing space 6-4 and the second material placing space 9-4 sequentially move to the position above the discharge port 12 and then fall into the discharge port 12.

As shown in FIG. 2, the rotary driving assembly 10 comprises a transversely disposed linear driving member 10-7 fixedly connected to the supporting plate 2, a U-shaped seat 10-3 fixedly connected to an extending end of the linear driving member 10-7, and a traverse seat 10-1 fixedly connected to a bottom of the U-shaped seat 10-3; a transversely arranged guide rail 10-9 is fixedly connected to the top surface of the bearing plate 2, the extension direction of the guide rail 10-9 is consistent with the extension direction of the extension end of the linear driving piece 10-7, and a sliding block matched with the guide rail 10-9 is fixedly connected to the bottom of the transverse moving seat 10-1; a rotating shaft 10-4 which is transversely arranged is rotatably connected on the U-shaped seat 10-3, a pushing block 10-8 which is used for pushing the first shifting block assembly 8/the second shifting block assembly 11 to rotate for a certain angle is fixedly connected at the inner end part of the rotating shaft 10-4, the top surface of the pushing block 10-8 is an inclined surface which inclines from a free end to a rotating end towards the rotating shaft 10-4, and a right-angle notch which is communicated with the top surface and the side surface of the pushing block 10-8 is formed in the pushing block 10-8. The outer peripheral wall of the rotating shaft 10-4 is sleeved with a torsion spring 10-5, two end parts of the torsion spring 10-5 are respectively connected with the rotating shaft 10-4 and the U-shaped seat 10-3 in the direction, and the concrete steps are as follows: a torsion spring mounting piece 10-2 is fixedly connected to the U-shaped seat 10-3, one end of a torsion spring 10-5 is inserted into a notch formed in the rotating shaft 10-4, the other end of the torsion spring is connected with the torsion spring mounting piece 10-2, and the pushing block 10-8 keeps a head-up state under the action of the torsion spring 10-5. The outer peripheral wall of the rotating shaft 10-4 is fixedly connected with a limiting block 10-6 which is in collision fit with the top of the U-shaped seat 10-3.

The extension end of the linear driving piece 10-7 extends outwards to drive the U-shaped seat 10-3 to move transversely along the guide rail 10-9, meanwhile, the pushing block 10-8 moves transversely under the drive of the U-shaped seat 10-3, and the pushing block 10-8 can push the second shifting block 11-2 to rotate beta degrees around the mandrel 7 as the pushing block 10-8 keeps a head raising state under the action of the torsion spring 10-5; when the extending end of the linear driving piece 10-7 retracts, the pushing block 10-8 rotates around the axis of the rotating shaft 10-4 under the limiting and blocking action of the second shifting block 11-2 to be in a low-head state, so that the second shifting block 11-2 can be enabled to retract to an initial position from the lower part of the second shifting block 11-2 under the driving of the linear driving piece 10-7, the mass is large due to the fact that materials are filled in the second bin device 9, and the extending end of the linear driving piece 10-7 retracts to drive the second shifting block 11-2 to retract to the initial position, and the second bin device 9 cannot be disturbed to rotate.

The working process is as follows:

two materials are respectively placed in a first material placing space 6-4 of a first bin device 6 and a second material placing space 9-4 of a second bin device 9, the extending end of a linear driving piece 10-7 extends outwards so as to drive a U-shaped seat 10-3 to move transversely along a guide rail 10-9, meanwhile, a pushing block 10-8 is driven by the U-shaped seat 10-3 to move transversely, and the pushing block 10-8 keeps a head lifting state under the action of a torsion spring 10-5, so that the pushing block 10-8 can push a second shifting block 11-2 to rotate beta degrees around a core shaft 7; the second shifting block assembly 11 rotates by β degrees to drive the second bin device 9 and the first bin device 6 to rotate by β degrees and α degrees, respectively (the specific process is as described above, and is not described herein), in the rotating process of the first bin device 6 and the second bin device 9, the first material placing space 6-4 and the second material placing space 9-4 sequentially rotate through the discharge port 12, and the two materials placed in the first material placing space 6-4 and the second material placing space 9-4 sequentially move to the position above the discharge port 12 and then fall onto the discharge channel 1.

After the pushing block 10-8 pushes the second shifting block 11-2 to rotate by beta degrees, the extending end of the linear driving piece 10-7 retracts, the pushing block 10-8 can rotate around the axis of the rotating shaft 10-4 under the limiting and blocking effect of the second shifting block 11-2 to be in a low head state, then the pushing block 10-8 is driven by the linear driving piece 10-7 to retract to the initial position from the lower part of the second shifting block 11-2, and then the extending end of the linear driving piece 10-7 extends again to repeat the operation. The rotary driving component 10 drives the first bin device 6 and the second bin device 9 to synchronously rotate in a stepping manner, so that the first material placing space 6-4 and the second material placing space 9-4 sequentially rotate through the discharge port 12, and two materials placed in the first material placing space 6-4 and the second material placing space 9-4 sequentially move to the position above the discharge port 12 and then fall into the discharge port 12.

Claims (8)

1. The utility model provides a different model material is unloader respectively which characterized by: comprises a bearing plate (2) which is fixedly connected with a plurality of groups of supporting legs (3) at the bottom and is arranged transversely, and two groups of mandrels (7) which are arranged longitudinally are fixedly connected on the bearing plate (2); the outer peripheral walls of the two groups of mandrels (7) are respectively and rotatably connected with a first stock bin device (6) and a second stock bin device (9), the outer peripheral walls of the first stock bin device (6) and the second stock bin device (9) are respectively sleeved with a first shifting block assembly (8) and a second shifting block assembly (11), and the first shifting block assembly (8) and the second shifting block assembly (11) are in meshed transmission; a rotary driving component (10) which is used for driving the first bin device (6)/the second bin device (9) to rotate for a certain angle and has a non-return function is fixedly connected to the bearing plate (2);

the first storage bin device (6) comprises a first core barrel (6-3) which is coaxially sleeved outside a group of mandrels (7) and is rotationally connected with the group of mandrels (7), and further comprises a first storage bin (6-1) which is coaxially arranged with the first core barrel (6-3), a plurality of groups of longitudinally arranged first partition plates (6-2) are fixedly connected between the outer peripheral wall of the first core barrel (6-3) and the inner peripheral wall of the first storage bin (6-1), the plurality of groups of first partition plates (6-2) are circumferentially distributed at equal angles, and the first storage bin (6-1), the first core barrel (6-3) and two adjacent groups of first partition plates (6-2) jointly enclose a first storage space (6-4); the bottom of the first charging barrel (6-1) is contacted with the top of the bearing plate (2);

the second storage bin device (9) comprises a second core barrel (9-3) which is coaxially sleeved outside the other group of core shafts (7) and is rotationally connected with the other group of core shafts (7), and further comprises a second material barrel (9-1) which is coaxially arranged with the second core barrel (9-3), a plurality of groups of second partition plates (9-2) which are longitudinally arranged are fixedly connected between the outer peripheral wall of the second core barrel (9-3) and the inner peripheral wall of the second material barrel (9-1), the plurality of groups of second partition plates (9-2) are circumferentially distributed at equal angles, and the second material barrel (9-1), the second core barrel (9-3) and the two adjacent groups of second partition plates (9-2) jointly enclose a second material containing space (9-4); the bottom of the second charging barrel (9-1) is contacted with the top of the bearing plate (2);

a discharge hole (12) corresponding to the positions of the group of first material placing spaces (6-4) and the group of second material placing spaces (9-4) is arranged on the bearing plate (2).

2. The separate blanking device for different types of materials as claimed in claim 1, which is characterized in that: the rotary driving component (10) comprises a linear driving piece (10-7) which is fixedly connected with the bearing plate (2) and is transversely arranged, a U-shaped seat (10-3) is fixedly connected with the extending end of the linear driving piece (10-7), and a transverse moving seat (10-1) is fixedly connected with the bottom of the U-shaped seat (10-3); a transversely arranged guide rail (10-9) is fixedly connected to the top surface of the bearing plate (2), the extension direction of the guide rail (10-9) is consistent with the extension direction of the extension end of the linear driving piece (10-7), and a sliding block matched with the guide rail (10-9) is fixedly connected to the bottom of the transverse moving seat (10-1); a rotating shaft (10-4) which is transversely arranged is rotatably connected on the U-shaped seat (10-3), and a pushing block (10-8) which is used for pushing the first shifting block component (8)/the second shifting block component (11) to rotate for a certain angle is fixedly connected at the inner end part of the rotating shaft (10-4).

3. The separate blanking device for different types of materials as claimed in claim 2, which is characterized in that: the outer peripheral wall of the rotating shaft (10-4) is sleeved with a torsion spring (10-5), and two end parts of the torsion spring (10-5) are respectively connected with the rotating shaft (10-4) and the U-shaped seat (10-3) in the axial direction; a limiting block (10-6) which is in collision fit with the top of the U-shaped seat (10-3) is fixedly connected to the peripheral wall of the rotating shaft (10-4).

4. The separate blanking device for different types of materials as claimed in claim 3, which is characterized in that: the top surface of the pushing block (10-8) is an inclined surface which inclines from the free end to the rotating end towards the rotating shaft (10-4).

5. The separate blanking device for different types of materials as claimed in claim 1, which is characterized in that: the first shifting block assembly (8) comprises a first shifting block sleeve (8-1) which is sleeved on the outer peripheral wall of the first charging barrel (6-1) and is in interference fit with the first shifting block sleeve, and a plurality of groups of first shifting blocks (8-2) which are distributed at equal angles along the circumferential direction are fixedly connected to the outer peripheral wall of the first shifting block sleeve (8-1); the second shifting block assembly (11) comprises a second shifting block sleeve (11-1) which is sleeved on the outer peripheral wall of the second charging barrel (9-1) and is in interference fit with the second shifting block sleeve, and a plurality of groups of second shifting blocks (11-2) which are distributed at equal angles along the circumferential direction are fixedly connected to the outer peripheral wall of the second shifting block sleeve (11-1); the first shifting block (8-2) is meshed with the second shifting block (11-2).

6. The separate blanking device for different types of materials as claimed in claim 1, which is characterized in that: an abrasion-resistant plate (4) made of abrasion-resistant materials is fixedly connected to the bearing plate (2), and the bottom surfaces of the first charging barrel (6-1) and the second charging barrel (9-1) are in contact with the top surface of the abrasion-resistant plate (4).

7. The separate blanking device for different types of materials as claimed in claim 1, which is characterized in that: the bottom of the bearing plate (2) is fixedly connected with a discharge channel (1) which is opposite to the discharge hole (12).

8. The separate blanking device for different types of materials as claimed in claim 1, which is characterized in that: a feeding frame (5) is fixedly connected on the bearing plate (2).

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