CN221317695U - Storage bin device - Google Patents

Abstract

The utility model relates to the technical field of feeding devices, and discloses a bin device, which comprises a primary bin assembly and a secondary bin assembly, wherein the primary bin assembly comprises a primary feeding bin and a feeding inner bin movably arranged in the primary feeding bin along the vertical direction, an inner bin feeding port is arranged at the top of the feeding inner bin, and an inner bin discharging port is arranged at the bottom of the feeding inner bin; the second grade feed bin subassembly sets up in the below of first grade feed bin subassembly to set up with interior storehouse discharge gate relatively, the reinforced interior storehouse can stretch into or stretch out second grade feed bin subassembly. The bin device is used for lifting the feeding inner bin by adjusting the height of the feeding inner bin, so that the situation that the secondary bin assembly cannot be pushed into the bottom of the primary bin assembly is avoided; before feeding, the feeding inner bin is lowered, gaps between the feeding inner bin and the secondary feeding bin are reduced, powder is prevented from scattering outside the bin device, and environmental influence and material loss are avoided.

Description

Storage bin device

Technical Field

The utility model relates to the technical field of feeding devices, in particular to a bin device.

Background

In the glass production field, raw materials need to be put into batch materials through a first-stage feed bin assembly, and then the raw materials can enter the furnace body only through a second-stage feed bin assembly, so that the problem of connection between the first-stage feed bin assembly and the second-stage feed bin assembly exists in the process, and if the gap between the first-stage feed bin assembly and the second-stage feed bin assembly is too small, the second-stage feed bin assembly can not be pushed into the lower part of the first-stage feed bin assembly directly; if the gap between the first-level bin assembly and the second-level bin assembly is too large, a large amount of dust or powder can be scattered to the outside due to the fact that raw materials belong to powder, and environmental influence and material loss are caused.

Disclosure of utility model

The utility model aims to provide a bin device, which solves the problem that if the gap between a primary bin assembly and a secondary bin assembly is too small in the prior art, the secondary bin assembly cannot be pushed below the primary bin assembly directly; if the clearance between first level feed bin subassembly and the second grade feed bin subassembly is too big, because raw and other materials belong to powdered, can lead to a large amount of dust or powder to scatter outside, cause environmental impact and the technical problem of material loss condition.

To achieve the purpose, the utility model adopts the following technical scheme:

the present utility model provides a magazine arrangement comprising:

the first-level bin assembly comprises a first-level feeding bin and a feeding inner bin movably arranged in the first-level feeding bin along the vertical direction, an inner bin feeding port is arranged at the top of the feeding inner bin, and an inner bin discharging port is arranged at the bottom of the feeding inner bin;

The secondary feed bin assembly is arranged below the primary feed bin assembly and opposite to the inner bin discharge hole, and the feeding inner bin can extend into or out of the secondary feed bin assembly.

According to the bin device, the feeding inner bin which moves along the vertical direction is arranged in the primary feeding bin, the feeding inner bin is arranged opposite to the secondary bin assembly and can extend into or extend out of the secondary bin assembly, and the feeding inner bin is lifted before the secondary bin assembly is pushed into the primary bin assembly by adjusting the height of the feeding inner bin, so that the situation that the secondary bin assembly cannot be pushed into the bottom of the primary bin assembly is avoided; before feeding, the feeding inner bin is lowered, gaps between the feeding inner bin and the secondary feeding bin are reduced, and further powder is prevented from scattering outside the bin device due to overlarge gaps between the primary bin assembly and the secondary bin assembly, and environmental influence and material loss are avoided.

As a preferable scheme of the bin device, two opposite side walls of the primary feeding bin are respectively provided with a hanging component, each group of hanging components comprises a plurality of hooks, the hooks are arranged at intervals along the vertical direction, and the hooks on the two opposite side walls of the primary feeding bin are arranged in a one-to-one correspondence manner;

Hanging rods are arranged on two opposite side walls of the feeding inner bin, and each hanging rod is in hanging fit with a group of hanging components.

Through set up a plurality of couples on the lateral wall of one-level adds the feed bin, a plurality of couples set up along vertical direction interval, set up the hanging rod on the lateral wall of reinforced interior storehouse, hanging rod and different couple articulates the cooperation to realize the regulation of the height in reinforced interior storehouse, above-mentioned couple and hanging rod's simple structure, easy preparation.

As a preferable scheme of the storage bin device, hanging holes are formed in two opposite side walls of the primary feeding bin, a plurality of hooks are arranged in each hanging hole, and the hanging rods extend out of the primary feeding bin from the hanging holes and are hung on any hook.

The hanging holes can enable the hanging rod to move in the hanging hole so as to be hung on different hooks, and the hanging position can be conveniently adjusted.

As a preferable scheme of the bin device, a plurality of hooks are arranged on two opposite side walls of the hanging hole, and the hooks on two opposite side walls of the hanging hole are arranged in a staggered mode along the vertical direction.

The hanging rod can be hung to different positions of two side walls of the hanging hole through the arrangement, acting force of the hanging rod can be dispersed to the two side walls of the hanging hole, and the condition that a hook is arranged on one side of the hanging hole to cause damage to the single side wall of the hanging hole easily is avoided.

As a preferable scheme of the bin device, the hanging hole penetrates through the bottom of the primary feeding bin to form a hanging inlet, and the hanging rod extends into the hanging hole from the hanging inlet.

The hanging connection hole is provided with a hanging connection hole, and the hanging connection hole is provided with a hanging connection inlet.

As a preferable scheme of the bin device, the inner bin feeding hole is higher than the top end of the primary feeding bin, and the inner bin discharging hole is lower than the bottom end of the primary feeding bin.

The arrangement enables feeding through the feeding inner bin during feeding, feeding is smooth, and throttling of powder is avoided.

As a preferable scheme of the bin device, the shape of the feeding inner bin is the same as that of the primary feeding bin.

The shape of the feeding inner bin is the same as that of the primary feeding bin, and the primary feeding bin can play a role in guiding lifting movement of the feeding inner bin, so that shaking or skewing of the feeding inner bin is avoided.

As a preferred scheme of the bin device, the secondary bin assembly comprises a secondary feeding bin, a secondary feeding hole is formed in the top end of the secondary feeding bin, a secondary discharging hole is formed in the bottom end of the secondary feeding bin, the secondary feeding hole is opposite to the inner bin discharging hole, and the secondary discharging hole is communicated with an output pipeline.

The secondary bin assembly gathers powder into an output pipeline through a secondary feeding bin, and outputs the powder through the output pipeline.

As a preferable scheme of the bin device, the projection of the inner bin feed opening along the vertical direction falls into the secondary feed opening.

The powder in the first-level feed bin assembly can completely enter the second-level feed bin assembly through the arrangement, and the powder is prevented from falling into the outside of the second-level feed inlet.

As a preferable scheme of the bin device, the secondary feed inlet is round, and the inner bin discharge outlet is rectangular.

The structure is simple and easy to prepare; and the projection of the feeding hole of the inner bin along the vertical direction is convenient to fall into the secondary feeding hole.

The utility model has the beneficial effects that:

According to the bin device, the feeding inner bin which moves along the vertical direction is arranged in the first-stage feeding bin, the feeding inner bin is opposite to the second-stage bin assembly and can extend into or extend out of the second-stage bin assembly, and the feeding inner bin is lifted before the second-stage bin assembly is pushed into the first-stage bin assembly by adjusting the height of the feeding inner bin, so that the situation that the second-stage bin assembly cannot be pushed into the bottom of the first-stage bin assembly is avoided; before feeding, the feeding inner bin is lowered, gaps between the feeding inner bin and the secondary feeding bin are reduced, and further powder is prevented from scattering outside the bin device due to overlarge gaps between the primary bin assembly and the secondary bin assembly, and environmental influence and material loss are avoided.

Drawings

FIG. 1 is a schematic view of a bin assembly according to the present utility model;

fig. 2 is a front view of the bin assembly provided by the utility model.

In the figure:

1. A first-stage stock bin assembly;

11. a first-stage feeding bin; 111. a hook; 112. a hanging hole; 1121. a hanging inlet;

12. a feeding inner bin; 121. an inner bin feed inlet; 122. a discharge hole of the inner bin; 123. a connecting rod is hung;

2. A secondary bin assembly; 21. a second-stage feeding bin; 211. a secondary feed inlet; 212. a second-stage discharge port; 22. and an output pipeline.

Detailed Description

The utility model is described in further detail below with reference to the drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the utility model and are not limiting thereof. It should be further noted that, for convenience of description, only some, but not all of the structures related to the present utility model are shown in the drawings.

In the description of the present utility model, unless explicitly stated and limited otherwise, the terms "connected," "connected," and "fixed" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

In the present utility model, unless expressly stated or limited otherwise, a first feature "above" or "below" a second feature may include both the first and second features being in direct contact, as well as the first and second features not being in direct contact but being in contact with each other through additional features therebetween. Moreover, a first feature being "above," "over" and "on" a second feature includes the first feature being directly above and obliquely above the second feature, or simply indicating that the first feature is higher in level than the second feature. The first feature being "under", "below" and "beneath" the second feature includes the first feature being directly under and obliquely below the second feature, or simply means that the first feature is less level than the second feature.

In the description of the present embodiment, the terms "upper", "lower", "right", etc. orientation or positional relationship are based on the orientation or positional relationship shown in the drawings, and are merely for convenience of description and simplicity of operation, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the utility model. Furthermore, the terms "first," "second," and the like, are used merely for distinguishing between descriptions and not for distinguishing between them.

In the glass production field, raw materials need to be put into batch materials through a first-stage feed bin assembly, and then the raw materials can enter the furnace body only through a second-stage feed bin assembly, so that the problem of connection between the first-stage feed bin assembly and the second-stage feed bin assembly exists in the process, and if the gap between the first-stage feed bin assembly and the second-stage feed bin assembly is too small, the second-stage feed bin assembly can not be pushed into the lower part of the first-stage feed bin assembly directly; if the gap between the first-level bin assembly and the second-level bin assembly is too large, a large amount of dust or powder can be scattered to the outside due to the fact that raw materials belong to powder, and environmental influence and material loss are caused.

In order to solve the above problems, as shown in fig. 1 and 2, the present embodiment provides a bin device, which includes a primary bin assembly 1 and a secondary bin assembly 2, wherein the primary bin assembly 1 includes a primary feeding bin 11 and a feeding inner bin 12 movably arranged in the primary feeding bin 11 along a vertical direction, the primary feeding bin 11 is fixedly arranged, an inner bin feeding port 121 is arranged at the top of the feeding inner bin 12, and an inner bin discharging port 122 is arranged at the bottom of the feeding inner bin 12; the secondary feed bin assembly 2 is arranged below the primary feed bin assembly 1 and opposite to the inner bin discharge port 122, and the feeding inner bin 12 can extend into or out of the secondary feed bin assembly 2.

The height of the feeding inner bin 12 is adjusted, so that the feeding inner bin 12 is lifted before the secondary bin assembly 2 is pushed into the primary bin assembly 1, and the condition that the secondary bin assembly 2 cannot be pushed into the bottom of the primary bin assembly 1 is avoided; before feeding, the feeding inner bin 12 is lowered, gaps between the feeding inner bin 12 and the secondary feeding bin 21 are reduced, and further powder is prevented from scattering outside the bin device due to overlarge gaps between the primary bin assembly 1 and the secondary bin assembly 2, and environmental influence and material loss are avoided.

Specifically, hanging components are arranged on two opposite side walls of the first-stage feeding bin 11, each group of hanging components comprises a plurality of hooks 111, the hooks 111 are arranged at intervals along the vertical direction, and the hooks 111 on the two opposite side walls of the first-stage feeding bin 11 are arranged in a one-to-one correspondence manner; hanging rods 123 are arranged on opposite side walls of the feeding inner bin 12, and each hanging rod 123 is in hanging fit with a group of hanging components. Through set up a plurality of couples 111 on the lateral wall of first order adding feed bin 11, a plurality of couples 111 set up along vertical direction interval, set up the hanging rod 123 on the lateral wall of reinforced interior storehouse 12, the cooperation is hung with different couples 111 to the hanging rod 123 to realize the regulation of the height of reinforced interior storehouse 12, the simple structure of above-mentioned couple 111 and hanging rod 123, easy preparation.

Preferably, the opposite two side walls of the primary feeding bin 11 are respectively provided with a hanging hole 112, each hanging hole 112 is internally provided with a plurality of hooks 111, and the hanging rod 123 extends out of the primary feeding bin 11 from the hanging hole 112 and is hung on any hook 111. The hanging holes 112 are provided to enable the hanging rod 123 to move therein to be hung on different hooks 111, thereby facilitating adjustment of the hanging position. In this embodiment, the hanging hole 112 penetrates through the bottom of the primary feeding bin 11 to form a hanging port 1121, and the hanging rod 123 extends into the hanging hole 112 from the hanging port 1121. The hanging-in port 1121 is provided to facilitate the insertion of the hanging-up rod 123 into the hanging-up hole 112, facilitating the installation of the hanging-up rod 123.

In this embodiment, the two opposite side walls of the hanging hole 112 are provided with the plurality of hooks 111, the hooks 111 on the two opposite side walls of the hanging hole 112 are arranged in a staggered manner along the vertical direction, so that the hanging rod 123 can be hung at different positions of the two side walls of the hanging hole 112, the acting force of the hanging rod 123 can be dispersed at the two side walls of the hanging hole 112, and the condition that the single side wall of the hanging hole 112 is damaged due to the fact that the hooks 111 are arranged on one side of the hanging hole 112 is avoided.

In this embodiment, the inner bin feeding port 121 is higher than the top end of the primary feeding bin 11, and the inner bin discharging port 122 is lower than the bottom end of the primary feeding bin 11, i.e. both ends of the feeding inner bin 12 extend out of the primary feeding bin 11. The above arrangement makes the feeding through the feeding inner bin 12 during feeding, the feeding is smooth, and the throttling of the powder is avoided.

Optionally, the shape of the feeding inner bin 12 is the same as that of the primary feeding bin 11, and the primary feeding bin 11 can guide the lifting movement of the feeding inner bin 12, so that the feeding inner bin 12 is prevented from shaking or skewing. In this embodiment, the first-stage feeding bin 11 and the feeding inner bin 12 are both of a cylindrical structure, the section of the cylindrical structure is rectangular, the first-stage feeding bin 11 is sleeved on the outer side of the feeding inner bin 12, the size of the first-stage feeding bin 11 is slightly larger than that of the feeding inner bin 12, and the feeding inner bin 12 cannot rotate when lifting. In other embodiments, the shapes of the primary feeding bin 11 and the feeding inner bin 12 are not limited to the above-described shapes, but may be circular or polygonal in cross section, as long as the shapes of the primary feeding bin 11 and the feeding inner bin 12 are identical.

Optionally, the secondary feed bin assembly 2 includes a secondary feed bin 21, the secondary feed bin 21 is funnel-shaped, plays a role in gathering powder, a secondary feed port 211 is arranged at the top end of the secondary feed bin 21, a secondary discharge port 212 is arranged at the bottom end of the secondary feed bin 21, the size of the secondary feed port 211 is larger than that of the secondary discharge port 212, the secondary feed port 211 is arranged opposite to the inner bin discharge port 122, and the secondary discharge port 212 is communicated with an output pipeline 22. The secondary bin assembly 2 gathers powder into an output pipeline 22 through a secondary feeding bin 21, and outputs the powder through the output pipeline 22.

Alternatively, the projection of the inner bin feed port 121 along the vertical direction falls into the secondary feed port 211, so that the powder in the primary bin assembly 1 can completely enter the secondary bin assembly 2, and is prevented from falling into the outside of the secondary feed port 211. In this embodiment, the secondary feeding port 211 is circular, and the inner bin discharging port 122 is rectangular. The structure is simple and easy to prepare; but also facilitates the projection of the inner bin feed port 121 in the vertical direction to fall into the secondary feed port 211.

In the embodiment, the primary feeding bin 11, the feeding inner bin 12, the secondary feeding bin 21 and the output pipeline 22 are all made of stainless steel materials, so that the service life is long. Even if the feeding inner bin 12 is close to the furnace body when the furnace body is heated, the feeding inner bin 12 is not burnt.

In use, the height of the feeding inner bin 12 is adjusted so as to lift the feeding inner bin 12 before the secondary bin assembly 2 is pushed into the primary bin assembly 1, and then the secondary bin assembly 2 is pushed into the bottom of the primary bin assembly 1.

Before feeding, the height of the feeding inner bin 12 is reduced, the feeding inner bin 12 stretches into the secondary feeding bin 21, gaps between the feeding inner bin 12 and the secondary feeding bin 21 are reduced, powder is prevented from scattering outside the bin device due to overlarge gaps between the primary bin assembly 1 and the secondary bin assembly 2, environmental influence and material loss are avoided, and the service life of the feeding device is prolonged.

It is to be understood that the above examples of the present utility model are provided for clarity of illustration only and are not limiting of the embodiments of the present utility model. Various obvious changes, rearrangements and substitutions can be made by those skilled in the art without departing from the scope of the utility model. It is not necessary here nor is it exhaustive of all embodiments. Any modification, equivalent replacement, improvement, etc. which come within the spirit and principles of the utility model are desired to be protected by the following claims.

Claims (10)

1. The feed bin device, its characterized in that includes:

The primary feed bin assembly (1) comprises a primary feed bin (11) and a feeding inner bin (12) movably arranged in the primary feed bin (11) along the vertical direction, wherein an inner bin feed inlet (121) is formed in the top of the feeding inner bin (12), and an inner bin discharge outlet (122) is formed in the bottom of the feeding inner bin (12);

The secondary feed bin assembly (2), secondary feed bin assembly (2) set up in the below of one-level feed bin assembly (1), and with interior storehouse discharge gate (122) set up relatively, in the reinforced storehouse (12) can stretch into or stretch out secondary feed bin assembly (2).

2. The bin device according to claim 1, wherein the opposite side walls of the primary feeding bin (11) are provided with hanging components, each group of hanging components comprises a plurality of hooks (111), the hooks (111) are arranged at intervals along the vertical direction, and the hooks (111) on the opposite side walls of the primary feeding bin (11) are arranged in a one-to-one correspondence;

opposite side walls of the feeding inner bin (12) are provided with hanging rods (123), and each hanging rod (123) is in hanging fit with a group of hanging components.

3. The bin device according to claim 2, wherein two opposite side walls of the primary feeding bin (11) are provided with hanging holes (112), the hanging holes (112) extend in a vertical direction, a plurality of hooks (111) are arranged in each hanging hole (112), and the hanging rods (123) extend out of the primary feeding bin (11) from the hanging holes (112) and are hung on any one of the hooks (111).

4. A silo device according to claim 3, wherein the hooks (111) are arranged on two opposite side walls of the hanging hole (112), and the hooks (111) on two opposite side walls of the hanging hole (112) are arranged in a staggered manner along the vertical direction.

5. A silo device according to claim 3, wherein the hooking hole (112) penetrates through the bottom of the primary silo (11) to form a hooking port (1121), and the hooking rod (123) extends from the hooking port (1121) into the hooking hole (112).

6. The silo device of any one of claims 1-5, wherein the inner silo feed port (121) is above the top end of the primary silo (11) and the inner silo discharge port (122) is below the bottom end of the primary silo (11).

7. The silo device of any one of claims 1-5, wherein the shape of the charging inner silo (12) is the same as the shape of the primary charging silo (11).

8. The bin arrangement according to any of the claims 1-5, characterized in that the secondary bin assembly (2) comprises a secondary feeding bin (21), a secondary feeding port (211) is arranged at the top end of the secondary feeding bin (21), a secondary discharging port (212) is arranged at the bottom end of the secondary feeding bin (21), the secondary feeding port (211) is arranged opposite to the inner bin discharging port (122), and the secondary discharging port (212) is communicated with an output pipeline (22).

9. The silo device of claim 8, wherein the projection of the inner silo feed port (121) in the vertical direction falls into the secondary feed port (211).

10. The silo device of claim 9, wherein the secondary feed port (211) is circular and the inner silo discharge port (122) is rectangular.