CN220011396U - Puffing aggregate bin structure - Google Patents

Abstract

The utility model discloses a puffing gathering bin structure, which relates to the technical field of fiber material manufacturing equipment and comprises a base, a vibrating screen assembly fixed on the base and a gathering bin body assembly fixed on the base, wherein the vibrating screen assembly and the gathering bin body assembly are arranged at intervals, the vibrating screen assembly is provided with a cylindrical discharge hole, the gathering bin body assembly is provided with a cylindrical feed inlet, and the tail end of the discharge hole is positioned in the feed inlet; the shielding cloth is connected with the discharge hole and the feed inlet, and covers the annular gap between the discharge hole and the feed inlet. In order to avoid the material to leak and spill out of the production line, the annular gap between the discharge hole and the feed inlet is covered by the shielding cloth, and the shielding cloth is soft, does not transmit torque and pressure and does not transmit vibration to the aggregate bin body assembly. In addition, this scheme sets up the end of discharge gate in the inside of feed inlet, still further avoids the material to reveal.

Description

Puffing aggregate bin structure

Technical Field

The utility model belongs to the technical field of fiber material manufacturing equipment, and further relates to a puffing collecting bin structure.

Background

In the oil and gas exploitation process, fracturing is an important technical measure for increasing the yield of an oil and gas well and increasing the injection of a water injection well. The fracturing fluid used in the fracturing process generally needs a plurality of components in the field, wherein the components comprise glass fibers for fracturing, as described in paper glass chopped fiber reinforced technology for controlling the flowback of hydraulic fracturing propping agent, the glass chopped fiber reinforced technology is superior to the existing resin coated sand technology widely applied in the field in the aspects of application range, cost, technical index, construction process and the like, and the backflow of propping agent can be effectively prevented.

The manufacturing process flow of the glass fiber comprises the following steps: the bagged fiber raw materials are manually broken and disassembled, are put into a feeding port, the raw materials fall into a belt conveyor and are sent to a crusher for crushing, and then are finally sent to an upper port of a sand mixing device through links such as puffing, blowing, humidifying and the like, and the puffed materials fall down. Puffing is a key link, and the puffing process further breaks small lumps through high-frequency and high-amplitude vibration and forces single fibers to be fully separated, so that a puffing effect is achieved. The puffing process generally uses a crusher, a vibrating screen, or the like.

The puffing aggregate bin is a device for collecting finished products processed after a complete vibration puffing process, and the aggregate bin body or the box body is usually positioned at the lower side of the vibrating screen. If gaps exist between the aggregate bin and the vibrating screen, the puffed finished product can be leaked, and the workshop environment is polluted.

Disclosure of Invention

For this reason, this patent application provides a popped aggregate bin structure, has the advantage of difficult revealing the processing finished product. The technical essential solves the problem with the following scheme:

the utility model provides a popped collection silo structure, includes the base, fixes the shale shaker subassembly on the base and fixes the collection silo body subassembly on the base, and the shale shaker subassembly and collection silo body subassembly interval set up, the shale shaker subassembly has the discharge gate of tube-shape the collection silo body subassembly has the feed inlet of tube-shape, the end of discharge gate is located the inside of feed inlet; the shielding cloth is connected with the discharge hole and the feed inlet, and covers the annular gap between the discharge hole and the feed inlet.

As described above, the present utility model provides a bulking aggregate bin structure, which mainly comprises a vibrating screen assembly and an aggregate bin body assembly. The vibrating screen component vibrates in a high amplitude, the small glass fiber aggregates are crushed, and single fibers are forced to be fully separated, so that the puffing effect is achieved. The puffed fiber leaves from the discharge hole and falls into the collecting bin body assembly through the feed inlet for collection. The two components are fixed on the base at the same time, so that the integrity is strong. Because the vibrating screen component vibrates at high frequency in the working process, the structure of the vibrating screen component is destroyed in order to avoid vibration affecting the aggregate bin body component, and the vibrating screen component is set as: the shaker assemblies and the bin body assemblies are spaced apart, i.e., are not in rigid contact with each other. Because do not contact between two subassemblies, but the material needs to be transmitted between two subassemblies, for avoiding the material to leak and spill out the production line, this scheme uses and shelters from the annular clearance between cloth cover discharge gate and the feed inlet, shelters from cloth softness, does not transmit moment and pressure, can not give the vibration transmission to the aggregate bin body subassembly. In addition, this scheme sets up the end of discharge gate in the inside of feed inlet, still further avoids the material to reveal. In conclusion, compared with the prior art, the structure has the advantage that a finished product is difficult to leak.

The further technical scheme is as follows:

the vibrating screen assembly comprises a frame, a damping spring and a vibrating screen, wherein the vibrating screen is fixedly provided with a vibrating motor, the vibrating screen is horizontally arranged and connected with the frame through the damping spring, and the discharge port is fixedly connected with the vibrating screen and extends downwards from the vibrating screen; the aggregate bin body assembly comprises a box body, the feed inlet is communicated with the box body, and the box body is located below the vibrating screen. The technical characteristics respectively limit the components of the vibrating screen component and the aggregate bin body component, and the vibrating motor drives the vibrating screen to vibrate. In some embodiments, the vibrating screen consists of a group of screens in the warp and weft directions at proper intervals, and the screens are in the same direction and form a two-layer structure. Under the drive of the vibration motor, the screen is vibrated at high frequency and high amplitude, the small lumps are further crushed, and single fibers are forced to be fully separated, so that the puffing effect is achieved. And because the box body is positioned below the vibrating screen, the puffed fiber falls into the lower feed inlet to the box body under the drive of dead weight.

The shielding cloth is annular, the outer side of the shielding cloth is fixedly connected with the feeding hole, and the inner side of the shielding cloth is detachably connected with the discharging hole. This characteristic has given one kind and has sheltered from an embodiment of cloth, will shelter from cloth setting to be connected with the discharge gate can be dismantled, shelter from the cloth and dismantle the back, make things convenient for the inspection between feed inlet and the discharge gate clean.

The inside of shielding cloth is provided with a plurality of mounting holes, the discharge gate is provided with a plurality of connection buttons that match with the mounting hole. This characteristic has given a mode of connection between shielding cloth and the discharge gate.

The connecting button is higher than the top end of the feed inlet. This feature allows the shielding cloth, after being attached to the connecting button, to completely cover the gap between the discharge opening and the feed opening.

The shielding cloth is in a strip shape, one side of the shielding cloth is provided with a first magic tape connecting part used for being connected with the discharge hole, and the other side of the shielding cloth is provided with a second magic tape connecting part used for being connected with the feed inlet. This characteristic gives the other implementation mode of shielding cloth, shielding cloth and discharge gate and feed inlet homoenergetic split, and the shielding cloth after thoroughly taking off is easily cleaned alone.

In order to avoid installing and taking the in-process of shielding cloth, the magic tape of the shielding cloth which is continuously moved is connected with the adhering glass fiber, and is set as: the magic tape connecting part arranged on the shielding cloth is a magic tape female buckle. The female buckle of the magic tape is the rough surface of the magic tape.

For the smooth and easy of material ejection of compact, set up to, the discharge gate is the funnel-shaped tube-shape discharge gate that the bore diminishes in the pay-off direction.

The beneficial effects of the utility model are as follows:

the utility model provides a puffing aggregate bin structure. Because the vibrating screen component and the material collecting bin body component are not contacted, the material outlet and the material inlet which are respectively arranged on the vibrating screen component and the material collecting bin body component are not contacted. But the material needs to be transmitted between two subassemblies, in order to avoid the material to leak out the production line, this scheme uses to shelter from the annular clearance between cloth cover discharge gate and the feed inlet, shelter from cloth softness, not transmission moment and pressure, can not give the vibration transmission to collection silo body subassembly. In addition, this scheme sets up the end of discharge gate in the inside of feed inlet, still further avoids the material to reveal. In conclusion, compared with the prior art, the structure has the advantage that a finished product is difficult to leak.

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.

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

FIG. 2 is an enlarged schematic view of a shielding cloth according to the present utility model;

in the figure: 1. a base; 2. a vibrating screen assembly; 201. a discharge port; 202. a frame; 203. a damping spring; 204. a vibration motor; 205. vibrating the screen; 3. a collection bin body assembly; 301. a feed inlet; 302. a case; 4. a shielding cloth; 5. a mounting hole; 6. and connecting buttons.

Detailed Description

For the purpose of making apparent the objects, technical solutions and advantages of the present utility model, the present utility model will be further described in detail with reference to the following examples and the accompanying drawings, wherein the exemplary embodiments of the present utility model and the descriptions thereof are for illustrating the present utility model only and are not to be construed as limiting the present utility model.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present utility model. However, it will be apparent to one of ordinary skill in the art that: no such specific details are necessary to practice the utility model. In other instances, well-known structures, circuits, materials, or methods have not been described in detail in order not to obscure the utility model.

Throughout the specification, references to "one embodiment," "an embodiment," "one example," or "an example" mean: a particular feature, structure, or characteristic described in connection with the embodiment or example is included within at least one embodiment of the utility model. Thus, the appearances of the phrases "in one embodiment," "in an example," or "in an example" in various places throughout this specification are not necessarily all referring to the same embodiment or example. Furthermore, the particular features, structures, or characteristics may be combined in any suitable combination and/or sub-combination in one or more embodiments or examples. Moreover, those of ordinary skill in the art will appreciate that the illustrations provided herein are for illustrative purposes and that the illustrations are not necessarily drawn to scale. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

In the description of the present utility model, the terms "front", "rear", "left", "right", "upper", "lower", "vertical", "horizontal", "high", "low", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, merely to facilitate description of the present utility model and simplify description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the scope of the present utility model.

Examples

1-2, a puffing aggregate bin structure comprises a base 1, a vibrating screen assembly 2 fixed on the base 1 and an aggregate bin body assembly 3 fixed on the base 1, wherein the vibrating screen assembly 2 and the aggregate bin body assembly 3 are arranged at intervals, the vibrating screen assembly 2 is provided with a cylindrical discharge hole 201, the aggregate bin body assembly 3 is provided with a cylindrical feed hole 301, and the tail end of the discharge hole 201 is positioned in the feed hole 301; still include shielding cloth 4, shielding cloth 4 connects discharge gate 201 and feed inlet 301, shielding cloth 4 covers the annular clearance between discharge gate 201 and the feed inlet 301.

As described above, the present utility model provides a bulking aggregate bin structure mainly comprising a vibrating screen assembly 2 and an aggregate bin body assembly 3. The vibrating screen assembly 2 vibrates in a high amplitude, the small glass fiber aggregates are crushed, and single fibers are forced to be fully separated, so that the puffing effect is achieved. The puffed fibers leave from the discharge port 201 and fall into the collecting bin body assembly 3 through the feed port 301 for collection. The two components are fixed on the base 1 at the same time, so that the integrity is strong. Because the vibrating screen assembly 2 vibrates at high frequency in the working process, the structure of the vibrating screen assembly is destroyed in order to avoid the vibration to influence the aggregate bin body assembly 3, and the vibrating screen assembly is set as follows: the vibrating screen assembly 2 and the collector bin body assembly 3 are arranged at intervals, i.e. the vibrating screen assembly 2 and the collector bin body assembly 3 are in non-rigid contact. Because the two components are not contacted, but the material needs to be transmitted between the two components, in order to avoid the material from leaking out of the production line, the shielding cloth 4 is used for covering the annular gap between the discharge hole 201 and the feed inlet 301, the shielding cloth 4 is soft, torque and pressure are not transmitted, and vibration cannot be transmitted to the collecting bin body component 3. In addition, this scheme sets up the end of discharge gate 201 in the inside of feed inlet 301, still further avoids the material to reveal. In conclusion, compared with the prior art, the structure has the advantage that a finished product is difficult to leak.

The vibrating screen assembly 2 comprises a frame 202, a damping spring 203 and a vibrating screen 205 fixedly provided with a vibrating motor 204, wherein the vibrating screen 205 is horizontally arranged and connected with the frame 202 through the damping spring 203, and the discharge port 201 is fixedly connected with the vibrating screen 205 and extends downwards from the vibrating screen 205; the aggregate bin body assembly 3 includes a bin 302, the feed inlet 301 communicates with the bin 302, and the bin 302 is located below the vibratory screen 205. The technical characteristics respectively define the components of the vibrating screen assembly 2 and the collecting bin body assembly 3, and the vibrating motor 204 drives the vibrating screen 205 to vibrate. In some embodiments, the vibrating screen 205 is formed by a set of screens in the warp and weft directions at appropriate intervals, and the screens are in the same direction and form a two-layer structure. Under the drive of the vibration motor 204, the screen is vibrated at high frequency and high amplitude to further crush the small lumps and force the individual fibers to be fully separated, so that the puffing effect is achieved. And because the box 302 is positioned below the vibrating screen 205, the puffed fiber falls into the lower feed inlet 301 to the box 302 under the driving of the dead weight.

The shielding cloth 4 is annular, the outer side of the shielding cloth 4 is fixedly connected with the feeding hole 301, and the inner side of the shielding cloth 4 is detachably connected with the discharging hole 201. This feature gives one embodiment of the shielding cloth 4, and the shielding cloth 4 is detachably connected with the discharge port 201, and after the shielding cloth 4 is detached, the inspection between the feed port 301 and the discharge port 201 is convenient to clean.

The inside of shielding cloth 4 is provided with a plurality of mounting holes 5, discharge gate 201 is provided with a plurality of connection buttons 6 that match with mounting holes 5. This feature gives a way of connecting the barrier cloth 4 to the outlet opening 201.

The connecting button 6 is higher than the top end of the feed inlet 301. This feature enables the shielding cloth 4 attached to the attachment button 6 to completely cover the gap between the discharge port 201 and the feed port 301.

The shielding cloth 4 is in a strip shape, one side of the shielding cloth 4 is provided with a first magic tape connecting part used for being connected with the discharge hole 201, and the other side of the shielding cloth 4 is provided with a second magic tape connecting part used for being connected with the feed inlet 301. This feature gives another embodiment of the shielding cloth 4, and the shielding cloth 4 can be detached from both the discharge port 201 and the feed port 301, and the shielding cloth 4 after being completely removed is easy to be cleaned individually.

In order to avoid installing and taking the shielding cloth 4, the magic tape of the shielding cloth 4 which is continuously moved is connected with the adhering glass fiber, and is set as follows: the magic tape connecting part arranged on the shielding cloth 4 is a magic tape female buckle. The female buckle of the magic tape is the rough surface of the magic tape.

For the convenience of smooth material discharge, the discharge port 201 is a funnel-shaped cylindrical discharge port 201 with a smaller caliber in the feeding direction.

The above is a preferred embodiment of the present utility model, and a person skilled in the art can also make alterations and modifications to the above embodiment, so that the present utility model is not limited to the above specific embodiment, and any obvious improvements, substitutions or modifications made by a person skilled in the art on the basis of the present utility model are all within the scope of the present utility model.

Claims (8)

1. The utility model provides a popped collection silo structure, its characterized in that includes base (1), fixes vibrating screen assembly (2) on base (1) and fixes collection silo body subassembly (3) on base (1), vibrating screen assembly (2) and collection silo body subassembly (3) interval set up, vibrating screen assembly (2) have tubular discharge gate (201), collection silo body subassembly (3) have tubular feed inlet (301), the end of discharge gate (201) is located the inside of feed inlet (301); still include shielding cloth (4), shielding cloth (4) connect discharge gate (201) and feed inlet (301), shielding cloth (4) cover the annular clearance between discharge gate (201) and feed inlet (301).

2. The puffing and collecting bin structure according to claim 1, characterized in that the vibrating screen assembly (2) comprises a frame (202), a damping spring (203) and a vibrating screen (205) fixedly provided with a vibrating motor (204), the vibrating screen (205) is horizontally arranged and connected with the frame (202) through the damping spring (203), and the discharging port (201) is fixedly connected with the vibrating screen (205) and extends downwards from the vibrating screen (205); the aggregate bin body assembly (3) comprises a box body (302), the feeding hole (301) is communicated with the box body (302), and the box body (302) is located below the vibrating screen (205).

3. The puffing aggregate bin structure according to claim 2, wherein the shielding cloth (4) is annular, the outer side of the shielding cloth (4) is fixedly connected with the feeding port (301), and the inner side of the shielding cloth (4) is detachably connected with the discharging port (201).

4. A puffed aggregate bin structure according to claim 3, characterized in that the inner side of the shielding cloth (4) is provided with a plurality of mounting holes (5), and the discharge hole (201) is provided with a plurality of connecting buttons (6) matched with the mounting holes (5).

5. The puffing aggregate bin structure according to claim 4, wherein the connecting button (6) is higher than the top end of the feed port (301).

6. The puffing aggregate bin structure according to claim 2, wherein the shielding cloth (4) is in a strip shape, one side of the shielding cloth (4) is provided with a first magic tape connecting part used for being connected with the discharge port (201), and the other side of the shielding cloth (4) is provided with a second magic tape connecting part used for being connected with the feed port (301).

7. The puffing aggregate bin structure according to claim 6, wherein the hook and loop fastener connecting part arranged on the shielding cloth (4) is a hook and loop fastener.

8. The puffing aggregate bin structure according to claim 2, wherein the discharge port (201) is a funnel-shaped cylindrical discharge port (201) with a smaller diameter in the feeding direction.