CN219125113U - Scallop early-stage automatic processor - Google Patents

Abstract

The utility model belongs to the technical field of shellfish processing equipment, in particular to an automatic scallop early-stage processor, which comprises a feeding bin supporting top plate and a scallop cage, wherein a first material passing device, a second material passing device and a third material passing device which are mutually connected are sequentially arranged above the supporting top plate from left to right, the feeding bin is communicated with the first material passing device, and one ends of the first material passing device and the third material passing device are respectively sleeved with a driving component; the bottom of the supporting top plate is connected with a supporting bottom plate, a plurality of distributing hoppers are arranged in the middle of the supporting top plate in a clamping mode, and a plurality of scallop cages are arranged in the middle of the supporting bottom plate. According to the scallop sorting machine, the plurality of groups of the material passing devices and the material distributing hoppers are arranged, so that on one hand, the rapid cage loading of the scallop can be realized, the workload of manual sorting is reduced, and on the other hand, the plurality of groups of the material passing devices with different material leakage gaps can realize the classified cage loading of the scallop with different sizes, so that the post-classification treatment of the scallop is facilitated.

Description

Scallop early-stage automatic processor

Technical Field

The utility model belongs to the technical field of shellfish processing equipment, and particularly relates to an automatic scallop early-stage processor.

Background

After the scallop is mature, the scallop culture cage is fished out of the sea water, and then an operator takes the scallop out of the opening of the net by hand and carries out sorting operation; at present, the common preliminary treatment means in China mainly adopts a manual operation mode, and a plurality of people are required to carry out cooperation operation, so that the operation process is large in workload, tedious in operation, time-consuming and labor-consuming, and low in working efficiency;

through investigation publication (bulletin) number: CN212436944U discloses a beating type scallop inverted cage machine, the device discloses a frame, a beating bed bracket and a cage supporting bridge, wherein the beating bed bracket is fixedly arranged at the lower part of the frame, and the cage supporting bridge is arranged above the beating bed bracket and hinged with the frame; a motor and a rotating shaft are arranged above the cage supporting bridge frame, the motor is fixedly arranged at the top of the frame, and the motor is connected with the rotating shaft through a transmission mechanism; the eccentric wheels are symmetrically and fixedly arranged at the front part and the rear part of the rotating shaft, and the other side of the eccentric wheels is connected with the striking mechanism and other technical characteristics, so that the novel rotary shaft has the technical effects of labor saving, time saving, labor saving, high working efficiency, low labor cost and the like;

however, when the device is in actual use, only the scallops are simply loaded in cages, but the scallops cannot be classified according to the sizes of the scallops, so that the scallops with different sizes cannot be packaged according to the needs, and the later classification treatment is not facilitated.

In order to solve the problems, the application provides an automatic scallop early-stage processor.

Disclosure of Invention

To solve the problems set forth in the background art. The utility model provides an automatic scallop early-stage processor which has the characteristic of classifying and loading cages according to the size of scallops.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the scallop early-stage automatic processor comprises a feeding bin supporting top plate and a scallop cage, wherein the feeding bin is fixed on one side of the top end of the supporting top plate through a first supporting column, a first material passing device, a second material passing device and a third material passing device which are connected with each other are sequentially arranged above the supporting top plate from left to right, the feeding bin is communicated with the first material passing device, and one ends of the first material passing device and the third material passing device are respectively sleeved with a driving component; the bottom of the supporting top plate is connected with a supporting bottom plate through a plurality of second supporting columns, a plurality of distributing hoppers which are respectively in one-to-one correspondence with the first material passing devices, the second material passing devices and the third material passing devices are clamped at the middle of the supporting top plate, and a plurality of scallop cages which are respectively in one-to-one correspondence with the distributing hoppers are arranged at the middle of the supporting bottom plate.

As an optimal choice of the scallop early-stage automatic processor, the supporting top plate is obliquely arranged, and the heights of the first material passing device, the second material passing device and the third material passing device are sequentially reduced.

As the scallop early-stage automatic processor, the first material passing device, the second material passing device and the third material passing device comprise two groups of mounting plates, a plurality of fixing rods are equidistantly arranged between the two groups of mounting plates, and the two groups of mounting plates which are mutually attached are connected through a plurality of fixing bolts.

Preferably, in the scallop pre-automatic processing machine according to the present utility model, a gap between the fixing bars of the first laminator is smaller than a gap between the fixing bars of the second laminator, and a gap between the fixing bars of the second laminator is smaller than a gap between the fixing bars of the third laminator.

As the scallop early-stage automatic processor, the middle parts of the mounting plates of the first material passing device and the second material passing device are respectively provided with a material passing hole, the middle part of one group of mounting plates of the third material passing device is provided with a material passing hole, and the other group of mounting plates are blind plates.

As the scallop early-stage automatic processor, the driving assemblies comprise gear plates fixedly sleeved on the outer sides of the mounting plates, the outer sides of the gear plates are sleeved with fixing rings fixedly connected with the supporting top plate, the front surfaces of the fixing rings are rotatably provided with a plurality of gears meshed with the gear plates, and one end of one group of gears is connected with a driving motor fixedly connected with the supporting top plate.

Compared with the prior art, the utility model has the beneficial effects that: according to the scallop sorting machine, the plurality of groups of the material passing devices and the material distributing hoppers are arranged, so that on one hand, the rapid cage loading of the scallop can be realized, the workload of manual sorting is reduced, and on the other hand, the plurality of groups of the material passing devices with different material leakage gaps can realize the classified cage loading of the scallop with different sizes, so that the post-classification treatment of the scallop is facilitated.

Drawings

The accompanying drawings are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate the utility model and together with the embodiments of the utility model, serve to explain the utility model. In the drawings:

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a cross-sectional view of the present utility model;

FIG. 3 is a schematic view of the structure of the material feeder of the present utility model;

fig. 4 is a schematic structural diagram of a driving assembly in the present utility model.

In the figure: 1. a feeding bin; 2. a supporting top plate; 3. a scallop cage; 4. a first support column; 5. a first material passing device; 6. a second material feeder; 7. a third material passing device; 8. a drive assembly; 801. a gear plate; 802. a fixing ring; 803. a gear; 9. a second support column; 10. a support base plate; 11. a distributing hopper; 12. a mounting plate; 13. a fixed rod; 14. a fixing bolt; 15. and driving the motor.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1

As shown in fig. 1 and 2;

FIG. 1 is a schematic diagram of the structure of the present utility model;

fig. 2 is a cross-sectional view of the present utility model.

The scallop early-stage automatic processor comprises a feeding bin 1, a supporting top plate 2 and a scallop cage 3, wherein the feeding bin 1 is fixed on one side of the top end of the supporting top plate 2 through a first supporting column 4, a first material passing device 5, a second material passing device 6 and a third material passing device 7 which are mutually connected are sequentially arranged above the supporting top plate 2 from left to right, the feeding bin 1 is communicated with the first material passing device 5, and one ends of the first material passing device 5 and the third material passing device 7 are respectively sleeved with a driving component 8; the bottom of the supporting top plate 2 is connected with a supporting bottom plate 10 through a plurality of second supporting columns 9, a plurality of distributing hoppers 11 which are respectively in one-to-one correspondence with the first material passing device 5, the second material passing device 6 and the third material passing device 7 are clamped at the middle part of the supporting top plate 2, and a plurality of scallop cages 3 which are respectively in one-to-one correspondence with the distributing hoppers 11 are arranged at the middle part of the supporting bottom plate 10.

It should be noted that: in this embodiment, the bottom of the feeding bin 1 is provided with a feeding pipe, the feeding pipe extends to the inside of the first material passing device 5, the bottoms of the feeding bin 1 and the distributing hopper 11 are of inverted trapezoid structures, and the bottom opening of the distributing hopper 11 is opposite to the top opening of the scallop cage 3.

In this embodiment: by arranging a plurality of groups of material passing devices and material distributing hoppers 11, on one hand, the scallop can be quickly caged, so that the workload of manual sorting is reduced.

In an alternative embodiment, the supporting top plate 2 is arranged obliquely, and the heights of the first, second and third blenders 5, 6 and 7 are sequentially reduced.

In this embodiment: the obliquely arranged support top plate 2 can ensure that scallops sequentially enter the first material passing device 5, the second material passing device 6 and the third material passing device 7, thereby ensuring smooth cage loading operation.

As shown in fig. 3;

fig. 3 is a schematic structural view of the material feeder in the present utility model.

In an alternative embodiment, the first discharger 5, the second discharger 6 and the third discharger 7 each comprise two groups of mounting plates 12, a plurality of fixing rods 13 are equidistantly arranged between the two groups of mounting plates 12, and the two groups of mounting plates 12 which are mutually attached are connected through a plurality of fixing bolts 14.

In this embodiment: the mounting plates 12 are connected by the fixing bolts 14, so that the plurality of groups of material passing devices can be conveniently mounted and dismounted, and the material passing devices can be conveniently maintained and cleaned.

In an alternative embodiment, the gap between the fixing bars 13 of the first overgrate 5 is smaller than the gap between the fixing bars 13 of the second overgrate 6, and the gap between the fixing bars 13 of the second overgrate 6 is smaller than the gap between the fixing bars 13 of the third overgrate 7.

In this embodiment: the different bleedons of multiunit hourglass material clearance can realize classifying the dress cage to the scallop of size difference to guarantee that the post-treatment of scallop is more smooth.

In an alternative embodiment, the middle parts of the mounting plates 12 of the first and second blenders 5, 6 are provided with material passing holes, the middle part of one set of mounting plates 12 of the third blenders 7 is provided with material passing holes, and the other set of mounting plates 12 is a blind plate.

In this embodiment: the fixed rod 13 is flush with the inner wall of the material passing hole, so that the scallop material clamping can be prevented, and the mounting plate 12 furthest away from the feeding bin 1 is a blind plate, so that the scallop can be prevented from falling.

As shown in fig. 4;

fig. 4 is a schematic structural diagram of a driving assembly in the present utility model.

In an alternative embodiment, the driving assemblies 8 each comprise a gear plate 801 fixedly sleeved on the outer side of the mounting plate 12, a fixing ring 802 fixedly connected with the supporting top plate 2 is sleeved on the outer side of the gear plate 801, a plurality of gears 803 meshed with the gear plate 801 are rotatably arranged on the front surface of the fixing ring 802, and one end of one group of gears 803 is connected with a driving motor 15 fixedly connected with the supporting top plate 2.

In this embodiment: the driving motor 15 is started, the driving motor 15 drives one group of gears 803 to rotate, the gears 803 drive the gear disc 801 and the mounting plate 12 to rotate, the other gears 803 rotate in a driven manner and limit the gear disc 801, and at the moment, the first material passing device 5, the second material passing device 6 and the third material passing device 7 synchronously rotate.

The working principle and the using flow of the utility model are as follows: the scallop to be separated is placed in the feeding bin 1, the scallop enters the first material passing device 5 through a feeding pipe at the bottom of the feeding bin 1, a driving motor 15 is started, the driving motor 15 drives one group of gears 803 to rotate, the gears 803 drive a gear disc 801 and a mounting plate 12 to rotate, other gears 803 rotate in a driven mode and limit the gear disc 801, at the moment, the first material passing device 5, the second material passing device 6 and the third material passing device 7 synchronously rotate, the scallop sequentially enters the second material passing device 6 and the third material passing device 7 through the first material passing device 5, at the moment, the smaller-sized scallop enters the distributing hopper 11 below through the fixing rod 13 of the first material passing device 5, finally enters the scallop cage 3 through the distributing hopper 11, meanwhile, the scallop with the medium size and the largest size enters the scallop cage 3 below through the fixing rods 13 of the second material passing device 6 and the third material passing device 7, and the worker takes down the scallop cage 3 and sews openings at the top of the scallop cage 3, and then the classification processing work of the scallop can be completed.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present utility model has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (6)

1. The utility model provides an automatic processor in earlier stage of scallop, includes feeding storehouse (1) supporting roof (2) and scallop cage (3), its characterized in that:

the feeding bin (1) is fixed on one side of the top end of the supporting top plate (2) through a first supporting column (4), a first material passing device (5), a second material passing device (6) and a third material passing device (7) which are connected with each other are sequentially arranged above the supporting top plate (2) from left to right, the feeding bin (1) is communicated with the first material passing device (5), and one ends of the first material passing device (5) and one end of the third material passing device (7) are respectively sleeved with a driving component (8);

the bottom of the supporting top plate (2) is connected with a supporting bottom plate (10) through a plurality of second supporting columns (9), a plurality of distributing hoppers (11) which are respectively in one-to-one correspondence with the first material passing devices (5), the second material passing devices (6) and the third material passing devices (7) are connected with the middle part of the supporting top plate (2) in a clamping mode, and a plurality of scallop cages (3) which are respectively in one-to-one correspondence with the distributing hoppers (11) are arranged in the middle of the supporting bottom plate (10).

2. The scallop pre-automatic processor of claim 1 wherein: the supporting top plate (2) is obliquely arranged, and the heights of the first material passing device (5), the second material passing device (6) and the third material passing device (7) are sequentially reduced.

3. The scallop pre-automatic processor of claim 2 wherein: the first material passing device (5), the second material passing device (6) and the third material passing device (7) comprise two groups of mounting plates (12), a plurality of fixing rods (13) are equidistantly arranged between the two groups of mounting plates (12), and the two groups of mounting plates (12) which are mutually attached are connected through a plurality of fixing bolts (14).

4. A scallop prophase automatic processor according to claim 3, wherein: the gap between the fixing bars (13) of the first overfeeding device (5) is smaller than the gap between the fixing bars (13) of the second overfeeding device (6), and the gap between the fixing bars (13) of the second overfeeding device (6) is smaller than the gap between the fixing bars (13) of the third overfeeding device (7).

5. The scallop pre-automatic processor of claim 4 wherein: the middle parts of the mounting plates (12) of the first material passing device (5) and the second material passing device (6) are provided with material passing holes, one group of the mounting plates (12) of the third material passing device (7) is provided with material passing holes, and the other group of the mounting plates (12) is a blind plate.

6. The scallop pre-automatic processor of claim 5 wherein: the driving assembly (8) comprises a gear disc (801) fixedly sleeved on the outer side of the mounting plate (12), a fixing ring (802) fixedly connected with the supporting top plate (2) is sleeved on the outer side of the gear disc (801), a plurality of gears (803) meshed with the gear disc (801) are rotatably arranged on the front face of the fixing ring (802), and one end of one group of gears (803) is connected with a driving motor (15) fixedly connected with the supporting top plate (2).

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