CN109592439B

CN109592439B - Storage bin structure

Info

Publication number: CN109592439B
Application number: CN201811410207.0A
Authority: CN
Inventors: 李杨; 田凯; 鲁鹏; 王鹏鹏; 马鹰
Original assignee: Gree Electric Appliances Inc of Zhuhai; Zhuhai Gree Intelligent Equipment Co Ltd
Current assignee: Gree Electric Appliances Inc of Zhuhai; Zhuhai Gree Intelligent Equipment Co Ltd
Priority date: 2018-11-23
Filing date: 2018-11-23
Publication date: 2020-10-30
Anticipated expiration: 2038-11-23
Also published as: CN109592439A

Abstract

The invention provides a material bin structure, comprising: a body portion including a first storage chamber and a second storage chamber; the first material ejecting assembly comprises a first material ejecting portion, the first material ejecting portion is movably arranged along the direction from the bottom of the first storage cavity to the opening of the first storage cavity, and therefore the preset pipe in the first storage cavity is driven to be separated from the first storage cavity and enter the second storage cavity. The storage bin structure solves the problem that the storage bin is difficult to take materials in the prior art.

Description

Storage bin structure

Technical Field

The invention relates to the field of storage bins, in particular to a storage bin structure.

Background

In the prior art, aiming at the storage of pipe materials, a large amount of pipe materials are mostly placed in a storage bin, and when the pipe materials are used specifically, the pipe materials are taken out from the storage cavity of the storage bin and then are sent to a preset station.

However, the existing storage bin only has a simple storage function, and in the material taking process of the pipe material, the existing material is mostly taken manually or grabbed by using a manipulator, and no matter which material taking mode is adopted, the outside is required to participate in taking the pipe material out of the storage bin. Because there are a large amount of pipe fittings in the feed bin, the manual work is got the material or is utilized the manipulator to get the material and all extremely inconvenient, not only can cause the damage to the pipe fitting also can influence the efficiency of getting the material.

Disclosure of Invention

The invention mainly aims to provide a storage bin structure to solve the problem that the storage bin is difficult to take in materials in the prior art.

In order to achieve the above object, the present invention provides a silo structure, comprising: a body portion including a first storage chamber and a second storage chamber; the first material ejecting assembly comprises a first material ejecting portion, the first material ejecting portion is movably arranged along the direction from the bottom of the first storage cavity to the opening of the first storage cavity, and therefore the preset pipe in the first storage cavity is driven to be separated from the first storage cavity and enter the second storage cavity.

Furthermore, the second storage cavity is provided with a first cavity wall and a second cavity wall which are connected, the first cavity wall and the second cavity wall both extend along the extending direction of the preset pipe fitting in the second storage cavity, and a V-shaped cavity is arranged between the first cavity wall and the second cavity wall; the first cavity wall is connected with the side wall of the first storage cavity, and after the first material ejecting part drives the preset pipe fitting to be separated from the first storage cavity, the preset pipe fitting moves along the first cavity wall until the preset pipe fitting is contacted with the second cavity wall.

Furthermore, the first cavity wall has a first connecting end for connecting with the side wall of the first storage cavity and a second connecting end for connecting with the second cavity wall; wherein, the height of the first connecting end is higher than that of the second connecting end.

Further, the feed bin structure still includes: the material clamping plate is arranged on the body part, a material clamping gap is formed between the material clamping plate and the body part, and the material clamping gap is positioned on one side, away from the first storage cavity, of the second storage cavity; and the second ejection assembly comprises a second ejection part, and the second ejection part is movably arranged to drive the preset pipe fitting in the second storage cavity to be separated from the second storage cavity and enter the material clamping gap.

Further, the feed bin structure still includes: the clamping plate driving part is in driving connection with the clamping plate so that the clamping plate can clamp or release the preset pipe fitting when the clamping plate driving part drives the clamping plate to rotate around the preset axis.

Further, the feed bin structure still includes: the clamping plate is arranged on the driving rod, and the clamping plate driving part is in driving connection with the driving rod so as to drive the clamping plate to rotate around a preset axis through the driving rod; the clamping plate is adjustably arranged on the driving rod to adjust the size of the clamping gap according to the pipe diameter of the preset pipe, so that the preset pipe is accommodated in the clamping gap.

Further, this somatic part still includes the blowpit, and the blowpit setting is kept away from one side of second storage chamber in pressing from both sides the material clearance to after pressing from both sides the release of flitch and predetermineeing the pipe fitting, predetermine the pipe fitting and get into the blowpit.

Further, the feed bin structure still includes: the first detection part is arranged on the body part and is used for detecting whether a preset pipe fitting is arranged at a preset part in the second storage cavity or not; when the first detection part detects that a preset position in the second storage cavity is provided with a preset pipe fitting, the first detection part controls the first material ejecting part to stop running; when the first detection part does not detect that the preset part in the second storage cavity is provided with the preset pipe fitting, the first detection part controls the first material ejecting part to start running.

Further, first liftout subassembly still includes: the ejection driving part is arranged below the first storage cavity and is in driving connection with the first ejection part to drive the first ejection part to stretch into the first storage cavity, so that the first ejection part drives the preset pipe in the first storage cavity to separate from the first storage cavity and enter the second storage cavity.

Further, be provided with first wear-to-establish hole on this body portion, first wear-to-establish hole is linked together with first storage chamber, and first liftout portion includes: the ejection rod, the ejection drive division is connected with the ejection rod drive to drive the ejection rod and pass and stretch into first storage intracavity behind the first hole of establishing, make the first storage intracavity of ejection rod drive predetermine the pipe fitting and break away from first storage chamber.

Furthermore, first wear to establish the hole and be a plurality of, a plurality of first wear to establish the hole along the extending direction interval setting of predetermineeing the pipe fitting in the first storage chamber, and the ejector beam is a plurality of, and a plurality of ejector beams set up with a plurality of first wear to establish the hole one-to-one.

Further, a plurality of first through holes are formed in one side, close to the second storage cavity, of the body, the ejector rod and one end, contacting with the preset pipe, of the ejector rod are provided with a first contact surface, the extending direction of the first contact surface is inclined to the extending direction of the ejector rod, and after the ejector rod drives the preset pipe to be separated from the first storage cavity, the preset pipe is separated from the ejector rod along the first contact surface and enters the second storage cavity.

According to the storage bin structure, the preset pipe fitting in the first storage cavity can be pushed out of the first storage cavity through the first material ejecting part of the first material ejecting assembly, so that the preset pipe fitting enters the second storage cavity, and subsequent material taking or processing is facilitated. Wherein, this somatic part includes first storage chamber and second storage chamber, at specific ejection of compact in-process, the direction removal of mouth of first storage chamber is reached at the bottom of first liftout portion along the chamber of first storage chamber, thereby drive the interior predetermined pipe fitting of first storage chamber and break away from first storage chamber and get into the second storage chamber, at this moment, owing to predetermine the first storage chamber that the pipe fitting breaks away from, just also avoided outside feeding agencies directly to get the material from first storage chamber, and first storage chamber ejection of compact process is the inside drive ejection of compact, need not outside feeding agencies, can not consider the space problem that the feed bin structure brought and with outside feeding agencies's cooperation problem, thereby make whole discharging processes simple more high-efficient, the comparatively difficult problem of material is got from the feed bin among the prior art has been solved.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, together with the description, serve to explain the invention and not to limit the invention. In the drawings:

figure 1 shows a schematic structural view of an embodiment of a silo structure according to the invention;

figure 2 shows a schematic structural view of a first topping assembly and a second topping assembly of a silo structure according to the present invention;

figure 3 shows a schematic view of part of the construction of a silo according to the invention;

figure 4 shows a first partial structural view of a silo structure according to the invention;

figure 5 shows a second partial structural view of the silo structure according to the invention.

Wherein the figures include the following reference numerals:

10. a body portion; 11. a first storage chamber; 111. a first side wall; 112. a second side wall; 113. a bottom wall; 12. a first through hole; 13. a second through hole; 14. a second storage chamber; 141. a first chamber wall; 142. a second chamber wall; 15. a discharge chute; 20. a first ejector assembly; 21. a first ejector part; 211. a lifter bar; 2111. a first contact surface; 212. a support block; 22. a material ejecting drive part; 23. a first connection portion; 30. an adjustment section;

40. a material clamping plate; 41. a clamping plate driving part; 43. a drive rod; 44. a first detection unit; 50. a second ejector assembly; 51. and a second material ejecting part.

Detailed Description

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present invention will be described in detail below with reference to the embodiments with reference to the attached drawings.

It should be noted that the following detailed description is exemplary and is intended to provide further explanation of the disclosure. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of example embodiments according to the present application. As used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, and it should be understood that when the terms "comprises" and/or "comprising" are used in this specification, they specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof, unless the context clearly indicates otherwise.

The present invention provides a storage bin structure, please refer to fig. 1 to 5, the storage bin structure includes: a body portion 10, the body portion 10 including a first storage chamber 11 and a second storage chamber 14; the first material ejecting assembly 20, the first material ejecting assembly 20 includes a first material ejecting portion 21, and the first material ejecting portion 21 is movably disposed along a direction from the bottom of the first storage cavity 11 to the opening of the first storage cavity 11, so as to drive the preset pipe fitting in the first storage cavity 11 to be separated from the first storage cavity 11 and enter the second storage cavity 14.

The storage bin structure of the invention can push the preset pipe fittings in the first storage cavity 11 out of the first storage cavity 11 through the first material ejecting part 21 of the first material ejecting assembly 20, so that the preset pipe fittings enter the second storage cavity 14 to facilitate subsequent material taking or processing. Wherein, this somatic part 10 includes first storage chamber 11 and second storage chamber 14, at specific ejection of compact in-process, the direction removal of the chamber mouth of first storage chamber 11 is at the bottom of first liftout portion 21 along the chamber of first storage chamber 11, thereby predetermine the pipe fitting in the first storage chamber 11 of drive and break away from first storage chamber 11 and get into second storage chamber 14, at this moment, owing to predetermine the first storage chamber 11 that the pipe fitting breaks away from, also avoided outside feeding agencies directly to get the material in

first storage chamber

11, and 11 ejection of compact processes in first storage chamber are the inside drive ejection of compact, need not outside feeding agencies, can not consider the space problem that the feed bin structure brought and with outside feeding agencies's cooperation problem, thereby make whole ejection of compact process more simple and efficient, the comparatively difficult problem of getting the material from the feed bin among the prior art has been solved.

For the specific structure of the second storage chamber 14, the second storage chamber 14 has a first chamber wall 141 and a second chamber wall 142 connected to each other, the first chamber wall 141 and the second chamber wall 142 both extend along the extending direction of the preset pipe in the second storage chamber 14, and a V-shaped chamber is arranged between the first chamber wall 141 and the second chamber wall 142; wherein, the first cavity wall 141 is connected with the side wall of the first storage cavity 11, and after the first material ejecting part 21 drives the preset pipe fitting to separate from the first storage cavity 11, the preset pipe fitting moves along the first cavity wall 141 until contacting with the second cavity wall 142.

In this embodiment, the longitudinal section of the second storage chamber 14 has a V-shape.

In order to be able to easily slide the pre-set tubular element into the second storage chamber 14, the first chamber wall 141 has a first connection end for connecting to the side wall of the first storage chamber 11 and a second connection end for connecting to the second chamber wall 142; wherein, the height of the first connecting end is higher than that of the second connecting end.

In this embodiment, the second storage chamber 14 is a V-shaped chamber inclined upward so that the predetermined pipe can slide along the first chamber wall 141 along the lowermost end of the V-shaped chamber.

In order to ensure that the preset pipe can be discharged according to the production requirement, as shown in fig. 1, the storage bin structure further comprises: the material clamping plate 40 is arranged on the body part 10, a material clamping gap is formed between the material clamping plate 40 and the body part 10, and the material clamping gap is positioned on one side, away from the first storage cavity 11, of the second storage cavity 14; and the second ejection assembly 50, the second ejection assembly 50 comprises a second ejection part 51, and the second ejection part 51 is movably arranged so as to drive the preset pipe fittings in the second storage cavity 14 to be separated from the second storage cavity 14 and enter the material clamping gap.

In the embodiment, a material clamping gap is formed between the material clamping plate 40 and the body portion 10, so that a preset pipe ejected by the second ejection portion 51 of the second ejection assembly 50 can enter the material clamping gap for buffering, and then the pipe can be discharged according to the subsequent production requirement.

In the present embodiment, the specific structure of the second topping assembly 50 and the specific structure of the first topping assembly 20 may be completely identical.

In order to guarantee to press from both sides the material clearance and carry out the buffer memory to predetermineeing the pipe fitting, the feed bin structure still includes: and the clamping plate driving part 41, the clamping plate driving part 41 and the clamping plate 40 are in driving connection, so that when the clamping plate driving part 41 drives the clamping plate 40 to rotate around the preset axis, the clamping plate 40 clamps or releases the preset pipe.

In the present embodiment, the material clamping plate driving part 41 is an air cylinder or an oil cylinder.

Preferably, the silo structure further includes: the driving rod 43 is provided with the material clamping plate 40, and the material clamping plate driving part 41 is in driving connection with the driving rod 43 so as to drive the material clamping plate 40 to rotate around a preset axis through the driving rod 43; the material clamping plate 40 is adjustably arranged on the driving rod 43 to adjust the size of the material clamping gap according to the pipe diameter of the preset pipe, so that the preset pipe is accommodated in the material clamping gap.

In the present embodiment, the retainer plate 40 is a V-shaped plate, and a part of the plate section of the retainer plate 40 is disposed above the second storage chamber 14.

In order to be able to facilitate the final production of the pre-set tubular element, the body part 10 further comprises a discharge chute 15, the discharge chute 15 being arranged at the side of the clamping gap remote from the second storage chamber 14, so that the pre-set tubular element enters the discharge chute 15 after the clamping plate 40 releases the pre-set tubular element.

Considering that the second storage chamber 14 needs to be sufficiently filled, as shown in fig. 4, the cartridge structure further includes: a first detecting portion 44, the first detecting portion 44 being provided on the main body portion 10, the first detecting portion 44 being configured to detect whether a predetermined portion in the second storage chamber 14 has a predetermined pipe; when the first detection part 44 detects that a preset position in the second storage cavity 14 has a preset pipe, the first detection part 44 controls the first material ejecting part 21 to stop running; when the first detecting part 44 does not detect that the preset position in the second storage chamber 14 has the preset pipe, the first detecting part 44 controls the first ejector 21 to start operating.

In the present embodiment, the predetermined pipe members in the second storage chamber 14 need to satisfy a certain number, and thus, are monitored by the first detection portion 44.

In the present embodiment, the first detection unit 44 may be a photoelectric sensor or an infrared sensor.

Correspondingly, the feed bin structure still includes: the second detection part is arranged on the body part 10 and is used for detecting whether a preset pipe fitting exists in the material clamping gap; when the second detection part detects that a preset part is arranged in the material clamping gap, the second detection part controls the second material ejecting part 51 to stop running, and the material clamping plate 40 releases a preset pipe fitting; when the second detection part does not detect that the preset part is arranged in the material clamping gap, the second detection part controls the second material ejecting part 51 to start to operate.

In the present embodiment, the second detection unit may be a photoelectric sensor or an infrared sensor.

In order to enable the first ejector 21 to be movably disposed in the direction from the bottom of the first storage chamber 11 to the opening of the first storage chamber 11, as shown in fig. 2, the first ejector assembly 20 further includes: liftout drive division 22, liftout drive division 22 set up in the below of first storage chamber 11, and liftout drive division 22 is connected with first liftout 21 drive to drive first liftout 21 and stretch into first storage chamber 11 in, make first liftout 21 drive the pipe fitting of predetermineeing in the first storage chamber 11 break away from first storage chamber 11 and get into second storage chamber 14.

In this embodiment, the ejector driving part 22 drives the first ejector part 21 to extend into the first storage chamber 11, thereby pushing the predetermined pipe in the first storage chamber 11 out of the first storage chamber 11.

In this embodiment, the ejector driving unit 22 is a cylinder or an oil cylinder.

As for the specific structure of the first ejecting portion 21, as shown in fig. 5, a first through hole 12 is provided on the main body portion 10, the first through hole 12 is communicated with the first storage cavity 11, and the first ejecting portion 21 includes: ejector beam 211, ejector beam drive division 22 are connected with ejector beam 211 drive to drive ejector beam 211 and pass and stretch into first storage chamber 11 behind the first through-going hole 12, make the first pipe fitting of predetermineeing in the storage chamber 11 of ejector beam 211 drive break away from first storage chamber 11.

In this embodiment, the first ejecting portion 21 includes an ejecting rod 211, that is, the ejecting driving portion 22 drives the ejecting rod 211 to pass through the first through hole 12 and then extend into the first storage cavity 11, so as to eject the preset pipe out of the first storage cavity 11 through the end of the ejecting rod 211.

In order to guarantee that first liftout portion 21 is ejecting predetermineeing the pipe fitting reliably, be provided with second through-hole 13 on this somatic part 10, second through-hole 13 is linked together with first storage chamber 11, and second through-hole 13 sets up along the extending direction interval of predetermineeing the pipe fitting in first storage chamber 11 with first through-hole 12, and first liftout portion 21 still includes: the supporting block 212 is in driving connection with the ejection driving part 22 so as to drive the supporting block 212 to penetrate through the second through hole 13 and then extend into the first storage cavity 11; the ejector driving part 22 drives the ejector rod 211 and the supporting block 212 to move synchronously, so that the ejector rod 211 and the supporting block 212 drive the preset pipe fittings on the ejector rod 211 and the supporting block 212 to be separated from the first storage chamber 11.

In this embodiment, the first ejector part 21 is composed of a supporting block 212 and an ejector rod 211, wherein the supporting block 212 and the end of the ejector rod 211 are used for contacting with a preset pipe, and the supporting block 212 and the end of the ejector rod 211 are used for supporting and driving the preset pipe, i.e. the preset pipe does not depart from the ejector rod 211 and the supporting block 212 in the moving process, and the ejector rod 211 and the supporting block 212 can provide enough power for the preset pipe.

Preferably, the first topping assembly 20 further comprises: the first connecting part 23 is provided with the ejector rod 211 and the supporting block 212 at intervals, the ejector driving part 22 is in driving connection with the first connecting part 23 so as to drive the ejector rod 211 and the supporting block 212 to move through the first connecting part 23; wherein the first connecting portion 23 is disposed below the first storage chamber 11.

In this embodiment, in order to ensure that the first connecting portion 23 moves along the predetermined direction, the first connecting portion 23 is connected to a predetermined guiding assembly, i.e. a guiding post and a guiding sleeve are provided to ensure the moving direction.

Preferably, the first connection portion 23 is a plate body.

Preferably, the ejector pin 211 is a circular tube, and the support block 212 is a rectangular block.

Preferably, first through holes 12 are a plurality of, and a plurality of first through holes 12 set up along the extending direction interval of predetermineeing the pipe fitting in the first storage chamber 11, and ejector beam 211 is a plurality of, and a plurality of ejector beam 211 set up with a plurality of first through holes 12 one-to-one.

In the present embodiment, the supporting block 212 is located at one end of the first connecting portion 23, and the plurality of ejector rods 211 are disposed at intervals along the extending direction of the first connecting portion 23.

In order to ensure that the preset pipe can be separated from the ejector beam 211 after being separated from the first storage cavity 11, the first through holes 12 are formed in one side, close to the second storage cavity 14, of the body portion 10, the first contact surface 2111 is formed in one end, in contact with the preset pipe, of the ejector beam 211, the extending direction of the first contact surface 2111 is inclined to the extending direction of the ejector beam 211, so that after the ejector beam 211 drives the preset pipe to be separated from the first storage cavity 11, the preset pipe is separated from the ejector beam 211 along the first contact surface 2111 and enters the second storage cavity 14.

In this embodiment, the end of the ejector pin 211 contacting the predetermined tubular member has a first contact surface 2111, and the first contact surface 2111 is an inclined surface, that is, after the ejector pin 211 ejects the predetermined tubular member out of the first storage chamber 11, the predetermined tubular member is separated from the ejector pin 211 along the first contact surface 2111 and moves to a predetermined position along a direction away from the opening of the first storage chamber 11.

In this embodiment, the top end of the supporting block 212 includes a flat surface and an inclined surface, which can ensure the supporting function of the predetermined pipe and ensure the predetermined pipe to be separated from the supporting block 212 and the ejector pin 211.

In order to be able to adapt the first storage chamber 11 to preset pipes of different lengths, the magazine structure further comprises, as shown in fig. 1: the adjusting part 30 is arranged in the first storage cavity 11, the preset pipe is positioned on one side of the adjusting part 30, and the adjusting part 30 is used for dividing the first storage cavity 11 into two storage cavity sections; the adjusting portion 30 is movably disposed along an extending direction of the preset pipe in the first storage chamber 11, so as to adjust the size of the storage chamber section where the preset pipe is located according to the length of the preset pipe.

In this embodiment, the adjusting portion 30 is a plate, the adjusting portion 30 is disposed in the first storage chamber 11 through a guide rod, and the adjusting portion 30 is driven to move along the guide rod by a manual or driving mechanism, so as to adjust the size of the storage chamber section where the preset pipe is located.

Preferably, the first storage chamber 11 has a first side wall 111, a second side wall 112 and a bottom wall 113, the first side wall 111 and the second side wall 112 are arranged oppositely, the bottom wall 113 is used for connecting the first side wall 111 and the second side wall 112, and both the first side wall 111 and the second side wall 112 extend along the extending direction of the preset pipe in the first storage chamber 11; wherein, one end of the bottom wall 113 connected with the first side wall 111 is higher than the other end of the bottom wall 113 connected with the second side wall 112, and the first material ejecting part 21 is arranged on one side of the bottom wall 113 close to the second side wall 112.

In this embodiment, the first storage chamber 11 has an inclined bottom surface, thereby ensuring that the predetermined pipe can be slid over the first ejector 21.

From the above description, it can be seen that the above-described embodiments of the present invention achieve the following technical effects:

first storage chamber

It should be noted that the terms "first," "second," and the like in the description and claims of this application and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the application described herein are, for example, capable of operation in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

Spatially relative terms, such as "above … …," "above … …," "above … …," "above," and the like, may be used herein for ease of description to describe one device or feature's spatial relationship to another device or feature as illustrated in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if a device in the figures is turned over, devices described as "above" or "on" other devices or configurations would then be oriented "below" or "under" the other devices or configurations. Thus, the exemplary term "above … …" can include both an orientation of "above … …" and "below … …". The device may be otherwise variously oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

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

Claims

1. A bin structure, comprising:

a body portion (10), the body portion (10) comprising a first storage chamber (11) and a second storage chamber (14);

a first material ejecting assembly (20), wherein the first material ejecting assembly (20) comprises a first material ejecting part (21), and the first material ejecting part (21) is movably arranged along the direction from the bottom of the first storage cavity (11) to the opening of the first storage cavity (11) so as to drive preset pipes in the first storage cavity (11) to be separated from the first storage cavity (11) and enter the second storage cavity (14);

the material clamping plate (40) is arranged on the body part (10), a material clamping gap is formed between the material clamping plate (40) and the body part (10), and the material clamping gap is positioned on one side, away from the first storage cavity (11), of the second storage cavity (14);

the second material ejecting assembly (50) comprises a second material ejecting part (51), and the second material ejecting part (51) is movably arranged to drive a preset pipe fitting in the second storage cavity (14) to be separated from the second storage cavity (14) and enter the material clamping gap.

2. The silo structure of claim 1, characterized in that the second storage chamber (14) has a first chamber wall (141) and a second chamber wall (142) connected, the first chamber wall (141) and the second chamber wall (142) each extending in the direction of extension of the predetermined tubular element inside the second storage chamber (14), the first chamber wall (141) and the second chamber wall (142) having a V-shaped cavity therebetween; the first cavity wall (141) is connected with the side wall of the first storage cavity (11), and after the first material ejecting part (21) drives the preset pipe fitting to be separated from the first storage cavity (11), the preset pipe fitting moves along the first cavity wall (141) until the preset pipe fitting is contacted with the second cavity wall (142).

3. The silo structure of claim 2, characterized in that the first chamber wall (141) has a first connection end for connection with a side wall of the first storage chamber (11) and a second connection end for connection with the second chamber wall (142); the height of the first connecting end is higher than that of the second connecting end.

4. The silo structure of claim 1, further comprising:

the material clamping plate driving part (41), the material clamping plate driving part (41) is in driving connection with the material clamping plate (40), so that when the material clamping plate driving part (41) drives the material clamping plate (40) to rotate around a preset axis, the material clamping plate (40) clamps or releases the preset pipe fitting.

5. The silo structure of claim 4, wherein the silo structure further comprises:

the material clamping plate (40) is arranged on the driving rod (43), and the material clamping plate driving part (41) is in driving connection with the driving rod (43) so as to drive the material clamping plate (40) to rotate around the preset axis through the driving rod (43);

the material clamping plate (40) is adjustably arranged on the driving rod (43) in position, so that the size of the material clamping gap can be adjusted according to the pipe diameter of the preset pipe, and one preset pipe is accommodated in the material clamping gap.

6. The storage bin construction according to claim 4, characterised in that the body part (10) further comprises a discharge chute (15), the discharge chute (15) being arranged at a side of the material clamping gap remote from the second storage chamber (14) for the predetermined tubular to enter the discharge chute (15) after the material clamping plate (40) releases the predetermined tubular.

7. The silo structure of claim 1, further comprising:

a first detection part (44), wherein the first detection part (44) is arranged on the main body part (10), and the first detection part (44) is used for detecting whether a preset part in the second storage cavity (14) has a preset pipe or not;

when the first detection part (44) detects that a preset position in the second storage cavity (14) is provided with a preset pipe, the first detection part (44) controls the first material ejecting part (21) to stop running; when the first detection part (44) does not detect that the preset position in the second storage cavity (14) has the preset pipe fitting, the first detection part (44) controls the first material ejecting part (21) to start to operate.

8. The silo structure of claim 1, wherein the first topping assembly (20) further comprises:

liftout drive division (22), liftout drive division (22) set up the below in first storage chamber (11), liftout drive division (22) with first liftout portion (21) drive is connected, in order to drive first liftout portion (21) stretch into in first storage chamber (11), make first liftout portion (21) drive predetermine the pipe fitting in first storage chamber (11) break away from first storage chamber (11) and enter second storage chamber (14).

9. The storage bin structure according to claim 8, wherein the body portion (10) is provided with a first through hole (12), the first through hole (12) is communicated with the first storage chamber (11), and the first liftout portion (21) comprises:

ejector beam (211), ejector beam drive division (22) with ejector beam (211) drive is connected, in order to drive ejector beam (211) pass stretch into behind first wear to establish hole (12) in first storage chamber (11), make ejector beam (211) drive predetermine the pipe fitting in first storage chamber (11) breaks away from first storage chamber (11).

10. The storage bin structure according to claim 9, wherein the first through holes (12) are provided in plurality, the first through holes (12) are arranged at intervals along an extending direction of a preset pipe in the first storage chamber (11), the ejector pins (211) are provided in plurality, and the ejector pins (211) and the first through holes (12) are arranged in a one-to-one correspondence manner.

11. The storage bin structure according to claim 10, wherein a plurality of the first through holes (12) are formed in one side of the body portion (10) close to the second storage chamber (14), one end of the ejector beam (211) contacting the preset pipe fitting is provided with a first contact surface (2111), and the extension direction of the first contact surface (2111) is inclined to the extension direction of the ejector beam (211), so that the preset pipe fitting is separated from the ejector beam (211) along the first contact surface (2111) and enters the second storage chamber (14) after the ejector beam (211) drives the preset pipe fitting to be separated from the first storage chamber (11).