CN220466898U - Engineering dregs recycling treatment transfer storage warehouse - Google Patents

Abstract

The utility model provides a transfer storage warehouse for engineering residue soil recycling treatment, which comprises a canopy, a support column, a storage bin cluster, a feeding conveying device and a discharging conveying device; the feed bin cluster includes a plurality of storage units of arranging side by side, and the storage unit includes storage cylinder and vibration feeder, and storage cylinder top is equipped with the feed inlet, and storage cylinder bottom is the inverted cone frustum shape structure, and storage cylinder bottom intercommunication vibration feeder, and vibration feeder is located storage cylinder bottom, and vibration feeder bottom is equipped with the blanking mouth. The utility model realizes multi-group classified storage of engineering slag soil semi-finished products and first-in first-out of slag soil material storage and transportation, is particularly suitable for storing engineering slag soil semi-finished products, improves the production flexibility of regenerated filler finished products of factories, and improves the scale benefit of the factories.

Description

Engineering dregs recycling treatment transfer storage warehouse

Technical Field

The utility model relates to a storage warehouse, in particular to a transfer storage warehouse for recycling treatment of engineering dregs, and belongs to the technical field of engineering dregs treatment.

Background

With the continuous promotion of urban construction in China, the construction waste generated by urban construction is continuously increased, wherein engineering dregs are taken as typical construction waste, and become an important subject for recycling treatment and utilization. The engineering dregs are recycled by sieving, crushing, mixing and other means, and the recycled filler is produced in a factory processing mode and then applied to town road roadbed filling so as to achieve recycling of resources.

The existing engineering dregs recycling treatment is generally a continuous process, and the engineering dregs are prepared into different groups of regenerated fillers for storage through continuous treatment. In actual operation, the road construction with different geographical environments and design conditions needs different groups of regenerated fillers, and then the road construction is overlapped with the regenerated fillers, so that the capacity of the regenerated fillers of the factory is easy to conflict with the road construction requirements, the regenerated filler products of the factory are accumulated during the road construction interruption period, and the regenerated filler products of the factory are insufficient in supply or are not matched in groups during the road construction peak period, so that the scale benefit of the factory is influenced. In addition, in the prior art, the storage of the dregs or the sand and stone usually adopts a special area stacking mode, the materials which are put in storage firstly are stacked at the bottom, the materials which are put in storage later are positioned at the upper layer, and when the materials are required to be transported for subsequent mixing treatment, first-in first-out is difficult to achieve, so that partial dregs semi-finished products are stacked for a long time.

Therefore, research and development of a novel engineering residue recycling treatment transfer storage warehouse have important significance in the field.

Disclosure of Invention

Based on the background, the utility model aims to provide the engineering muck recycling treatment transfer storage warehouse, so that the first-in first-out of muck material storage and transfer is realized, the storage warehouse is particularly suitable for storing engineering muck semi-finished product materials, the production flexibility of a regenerated filler finished product of a factory is improved, and the scale benefit of the factory is improved.

In order to achieve the above object, the present utility model provides the following technical solutions:

the utility model provides an engineering dregs recycling transfer storage warehouse, includes canopy, pillar, feed bin cluster, feeding conveyor and ejection of compact conveyor, the canopy is located the pillar top, the feed bin cluster is located the canopy below, feeding conveyor locates the canopy below and is located the feed bin cluster top, ejection of compact conveyor locates the feed bin cluster below;

the storage bin cluster comprises a plurality of storage units which are arranged in parallel, each storage unit comprises a storage cylinder and a vibration feeding device, a feeding hole is formed in the top of each storage cylinder, the bottom of each storage cylinder is of an inverted frustum-shaped structure, the bottom of each storage cylinder is communicated with the vibration feeding device, the vibration feeding device is located at the bottom of each storage cylinder, and a blanking hole is formed in the bottom of each vibration feeding device;

the number of the feeding conveying devices is matched with the number of the storage units, the outlet of each feeding conveying device corresponds to the feeding port of one storage unit, the number of the discharging conveying devices is matched with the number of the vibrating feeding devices, and the inlet of each discharging conveying device corresponds to the blanking port of one vibrating feeding device.

During the storage, the engineering dregs semi-manufactured goods of single group falls into the storage section of thick bamboo by feeding conveyor from the feed inlet at single storage unit top, is piled up gradually, when needs the ejection of compact to carry out follow-up processing, starts vibration feeder, blanking storage section of thick bamboo bottom material to ejection of compact conveyor with vibration ejection of compact mode, transport to follow-up processing shop, realize the first in first out that dregs material was stored and was transported to vibration feeder combines gravity action to make storage section of thick bamboo bottom ejection of compact with vibration mode, and the ejection of compact is smooth and easy, and the material is piled up in storage section of thick bamboo bottom and influence smooth and easy ejection of compact when avoiding ejection of compact.

Preferably, the bottom of each storage cylinder is provided with at least two vibration feeding devices, the number of the inverted cone-shaped structures at the bottom of each storage cylinder is matched with the number of the vibration feeding devices corresponding to the storage cylinder, and the intersection parts of the inverted cone-shaped structures correspond to the feeding holes.

Preferably, the cross section of the storage cylinder and the cross section of the inverted cone-shaped structure are both circular.

Preferably, the position, adjacent to the feed inlet, inside the storage cylinder is further provided with a humidifying device, the humidifying device comprises a fixed frame and a plurality of atomizing nozzles arranged on the fixed frame, the atomizing nozzles are distributed at the bottom of the fixed frame in a linear array mode, the atomizing nozzles are used for being connected with an external water supply device and spraying water mist towards the bottom direction of the storage cylinder, and the side part of the fixed frame is detachably and fixedly connected with the inner wall of the storage cylinder.

Preferably, an avoidance opening corresponding to the feeding hole is formed in the middle of the fixed frame, and the cross section area of the avoidance opening is larger than that of the feeding hole.

Preferably, the vibration feeding device comprises a blanking groove, an activating block, an exciting motor, an exciting spring, a vibration isolation spring and a first base, wherein the top of the blanking groove is communicated with the bottom of the inverted cone table-shaped structure of the storage cylinder, the periphery of the bottom of the blanking groove is connected with the first base through the vibration isolation spring, the side part of the blanking groove is connected with the exciting motor through the exciting spring, and the activating block is arranged in the blanking groove and is fixedly connected with the inner wall of the blanking groove, and a space is reserved between the activating block and the inner wall of the blanking groove.

Preferably, the top of the activation block is in a conical structure, and the activation block is at least partially positioned at the bottom of the storage cylinder.

Preferably, a part of the inner wall of the blanking groove is spherical.

Preferably, a second base is arranged at the periphery of the bottom of the storage cylinder and is used for fixedly connecting the storage cylinder with the ground.

Preferably, the feeding conveyor and the discharging conveyor are both belt conveyors.

Compared with the prior art, the utility model has the following advantages:

according to the engineering slag soil recycling treatment transfer storage warehouse, the storage units with the top feeding and the bottom discharging form a storage bin cluster, so that multi-component classified storage of engineering slag soil semi-finished products and first-in first-out of slag soil material storage and transportation are realized, the engineering slag soil semi-finished product storage warehouse is particularly suitable for storing engineering slag soil semi-finished product materials, the production flexibility of regenerated filler finished products of factories is improved, and the scale benefit of the factories is improved.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required to be used in the embodiments or the description of the prior art will be briefly described below, and it is obvious that the drawings in the following description are only embodiments of the present utility model, and that other drawings can be obtained according to the provided drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of a construction of a transfer storage warehouse for engineering muck reclamation treatment;

FIG. 2 is a schematic diagram of a storage unit according to the present utility model;

FIG. 3 is a schematic top view of the bottom of the cartridge of the present utility model;

FIG. 4 is a schematic view of the bottom structure of the top of the cartridge of the present utility model;

fig. 5 is a schematic view of a vibratory feeding device according to the present utility model.

In the figure: 1. a canopy cover; 2. a support post; 3. a storage unit; 4. a feed conveyor; 5. a discharge conveying device; 11. a storage cylinder; 12. a humidifying device; 13. a vibratory feeding device; 111. a feed inlet; 112. an inverted cone-shaped structure; 113. a second base; 121. a fixed frame; 122. an atomizing nozzle; 123. an avoidance opening; 131. a blanking port; 132. discharging groove; 133. an activation block; 134. exciting a motor; 135. exciting a spring; 136. a vibration isolation spring; 137. a first base.

Detailed Description

The technical scheme of the utility model is further specifically described below through specific embodiments and with reference to the accompanying drawings. It should be understood that the practice of the utility model is not limited to the following examples, but is intended to be within the scope of the utility model in any form and/or modification thereof.

In the present utility model, unless otherwise specified, all parts and percentages are by weight, and the equipment, materials, etc. used are commercially available or are conventional in the art. The methods in the following examples are conventional in the art unless otherwise specified. The components and devices in the following examples are, unless otherwise indicated, all those components and devices known to those skilled in the art, and their structures and principles are known to those skilled in the art from technical manuals or by routine experimentation.

In the following detailed description of embodiments of the utility model, reference is made to the accompanying drawings, in which, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the embodiments of the utility model. However, one or more embodiments may be practiced by one of ordinary skill in the art without these specific details.

As shown in fig. 1, the embodiment of the utility model discloses a transfer storage warehouse for engineering muck recycling treatment, which comprises a canopy cover 1, a support column 2, a storage bin cluster, a feeding conveying device 4 and a discharging conveying device 5, wherein the canopy cover 1 is arranged at the top end of the support column 2, the storage bin cluster is arranged below the canopy cover 1, the storage bin cluster comprises a plurality of storage units 3 which are arranged in parallel, the feeding conveying device 4 is arranged below the canopy cover 1 and above the storage bin cluster, and the discharging conveying device 5 is arranged below the storage bin cluster.

In particular, ten storage units 3 are arranged to form a storage bin cluster in the embodiment and are used for respectively storing different groups of crushed engineering dregs semi-finished products required by road construction under different geographic environments and design conditions. Of course, according to the actual factory production scale and the use requirement, the quantity of the storage units 3 can be adjusted, and the area of the canopy 1, the quantity of the support posts 2, the quantity of the feeding conveying devices 4 and the quantity of the discharging conveying devices 5 are correspondingly adjusted.

As shown in fig. 2, each storage unit 3 includes a storage cylinder 11, a humidifying device 12, and a vibratory feeding device 13. The top of the storage cylinder 11 is provided with a feed inlet 111, the bottom of the storage cylinder 11 is of an inverted cone table-shaped structure 112, and the bottom of the storage cylinder 11 is communicated with the vibration feeding device 13. The humidifying device 12 is located in the cartridge 11 and is disposed adjacent to the feed inlet 111. The vibration feeding device 13 is positioned at the bottom of the storage cylinder 11, and a blanking port 131 is arranged at the bottom of the vibration feeding device 13. Two vibrating feeding devices 13 are arranged at the bottom of each storage cylinder 11, the number of the inverted cone-shaped structures 112 at the bottom of each storage cylinder 11 is matched with that of the corresponding vibrating feeding devices 13 of the storage cylinder 11, and the intersection parts of the inverted cone-shaped structures 112 correspond to the feeding openings 111. Of course, in other embodiments, the storage unit 3 may be provided without the humidifying device 12, i.e. the storage unit 3 only comprises the storage drum 11 and the vibratory feeding device 13.

As shown in fig. 3, the cross section of the storage cylinder 11 and the cross section of the inverted cone-shaped structure 112 are both circular, that is, the storage cylinder 11 is a cylinder, the inverted cone-shaped structure 112 is an inverted cone-shaped cylinder, the number of the inverted cone-shaped structures 112 is two, and the connection parts of the inverted cone-shaped structures are exactly located on the axis of the storage cylinder 11, so that the two inverted cone-shaped structures 112 are symmetrical with the axis of the storage cylinder 11 as the center, and the feed inlet 111 of the storage cylinder 11 is also centered on the axis of the storage cylinder 11, so that the engineering residue soil semi-finished product material falling from the feed inlet 111 can be approximately uniformly distributed in the storage cylinder 11.

The number of feed conveyors 4 matches the number of storage units 3, also ten, whereas the outlet of each feed conveyor 4 corresponds to the feed opening 111 of one storage unit 3. The number of the discharge conveyor 5 is twenty, which is matched to the number of the vibratory feeder 13, and the inlet of each discharge conveyor 5 corresponds to the blanking port 131 of one vibratory feeder 13.

Specifically, as shown in fig. 4, the humidifying device 12 includes a fixed frame 121 and a plurality of atomizing nozzles 122 disposed on the fixed frame 121, the atomizing nozzles 122 are distributed at the bottom of the fixed frame 121 in a linear array manner, the atomizing nozzles 122 are used for connecting an external water supply device and spraying water mist toward the bottom direction of the storage barrel 11, and the side of the fixed frame 121 is detachably and fixedly connected with the inner wall of the storage barrel 11. Because of the intermittent nature of the plant production subject to road construction, some of the engineering muck semi-finished products may be stored in the storage drum 11 for a long period of time, long-term storage results in excessive water loss of muck and excessive drying, dust lifting thereof affects the environment, and excessive drying of the engineering muck semi-finished products may affect subsequent mixed production, so that the engineering muck semi-finished products stored in the storage and storage drum 11 are sprayed with water mist periodically through the atomizing nozzle 122, proper humidity of muck is maintained, and dust lifting is prevented.

The middle part of the fixed frame 121 is provided with an avoidance opening 123 corresponding to the feed inlet 111, and the cross-sectional area of the avoidance opening 123 is larger than that of the feed inlet 111, so that blanking is prevented from being influenced. Further, the side wall of the feed port 111 can be extended downward to be lower than the setting position of the fixed frame 121 in the storage barrel 11, so that the influence of the fixed frame 121 on blanking is further reduced.

As shown in fig. 5, the vibration feeding device 13 includes a blanking groove 132, an activation block 133, an excitation motor 134, an excitation spring 135, a vibration isolation spring 136 and a first base 137, wherein the top of the blanking groove 132 is communicated with the bottom of the inverted cone table-shaped structure 112 of the storage barrel 11, the outer periphery of the bottom of the blanking groove 132 is connected with the first base 137 through the vibration isolation spring 136, the side of the blanking groove 132 is connected with the excitation motor 134 through the excitation spring 135, and part of the inner wall of the blanking groove 132 is spherical. The activation block 133 is disposed in the lower trough 132 and fixedly connected to the inner wall of the lower trough 132, and a space is provided between the activation block 133 and the inner wall of the lower trough 132. Wherein the top of the activation block 133 is a conical structure, and the activation block 133 is at least partially located at the bottom of the storage cylinder 11.

The second base 113 is further arranged on the periphery of the bottom of the storage barrel 11, and the second base 113 is used for fixedly connecting the storage barrel 11 with the ground, so that the storage barrel 11 is supported and stabilized.

The feeding conveying device 4 and the discharging conveying device 5 are both belt conveyors, and the belt conveyors are of the prior art, and specific structures are not described herein.

The dump material warehouse in the engineering residue soil recycling treatment is provided with the shed cover 1, so that the shed cover is rainproof and sun-shading, the storage bin clusters are protected, and the service life is prolonged. The storage bin clusters adopt a plurality of storage units 3 which are arranged in parallel, so that the storage capacity and the processing capacity are increased, and the multi-group classified storage is realized. Each storage unit 3 is provided with a special feeding and discharging system, flexible and stable feeding and discharging are realized, and the top of the storage cylinder 11 is fed and the bottom is discharged, so that first-in first-out is realized. The storage cylinder 11 adopts an inverted cone-shaped structure 112, can smoothly discharge the storage bin by means of the gravity self-flow principle, is matched with the bottom vibration feeding device 13, and is used for placing materials to be piled up at the bottom of the storage cylinder 11, so that the discharging is smooth. The humidifying device 12 can perform dust suppression treatment on the raised dust, so that the raised dust pollution is reduced.

The principles and embodiments of the present utility model have been described herein with reference to specific examples, the description of which is intended only to facilitate an understanding of the method of the present utility model and its core ideas. It should be noted that it will be apparent to those skilled in the art that various modifications and adaptations of the utility model can be made without departing from the principles of the utility model and these modifications and adaptations are intended to be within the scope of the utility model as defined in the following claims.

Claims (10)

1. The utility model provides a engineering dregs resource treatment transfer storage storehouse which characterized in that: the dumping warehouse in the engineering muck recycling treatment comprises a canopy cover (1), a support column (2), a bin cluster, a feeding conveying device (4) and a discharging conveying device (5), wherein the canopy cover (1) is arranged at the top end of the support column (2), the bin cluster is arranged below the canopy cover (1), the feeding conveying device (4) is arranged below the canopy cover (1) and above the bin cluster, and the discharging conveying device (5) is arranged below the bin cluster;

the storage bin cluster comprises a plurality of storage units (3) which are arranged in parallel, each storage unit (3) comprises a storage cylinder (11) and a vibration feeding device (13), a feeding hole (111) is formed in the top of each storage cylinder (11), an inverted frustum-shaped structure (112) is arranged at the bottom of each storage cylinder (11), the bottoms of the storage cylinders (11) are communicated with the vibration feeding devices (13), the vibration feeding devices (13) are located at the bottoms of the storage cylinders (11), and blanking holes (131) are formed in the bottoms of the vibration feeding devices (13);

the number of the feeding conveying devices (4) is matched with the number of the storage units (3), the outlet of each feeding conveying device (4) corresponds to the feeding port (111) of one storage unit (3), the number of the discharging conveying devices (5) is matched with the number of the vibrating feeding devices (13), and the inlet of each discharging conveying device (5) corresponds to the blanking port (131) of one vibrating feeding device (13).

2. The engineering residue soil recycling treatment transfer storage warehouse of claim 1, wherein: at least two vibrating feeding devices (13) are arranged at the bottom of each storage cylinder (11), the number of the inverted cone-shaped structures (112) at the bottom of each storage cylinder (11) is matched with the number of the vibrating feeding devices (13) corresponding to the storage cylinder (11), and the intersection parts of the inverted cone-shaped structures (112) correspond to the feeding holes (111).

3. The engineering residue soil recycling treatment transfer storage warehouse of claim 1, wherein: the cross section of the storage cylinder (11) and the cross section of the inverted cone-shaped structure (112) are both circular.

4. The engineering residue soil recycling treatment transfer storage warehouse of claim 1, wherein: the position adjacent to the feeding hole in the storage barrel is further provided with a humidifying device (12), the humidifying device (12) comprises a fixed frame (121) and a plurality of atomizing nozzles (122) arranged on the fixed frame (121), the atomizing nozzles (122) are distributed at the bottom of the fixed frame (121) in a linear array mode, the atomizing nozzles (122) are used for being connected with an external water supply device and spraying water mist towards the bottom direction of the storage barrel (11), and the side part of the fixed frame (121) is detachably and fixedly connected with the inner wall of the storage barrel (11).

5. The engineering residue soil recycling treatment transfer storage warehouse of claim 4, wherein: the middle part of the fixed frame (121) is provided with an avoidance opening (123) corresponding to the feeding hole (111), and the cross section area of the avoidance opening (123) is larger than that of the feeding hole (111).

6. The engineering residue soil recycling treatment transfer storage warehouse of claim 1, wherein: the vibration feeding device (13) comprises a blanking groove (132), an activating block (133), an exciting motor (134), an exciting spring (135), a vibration isolation spring (136) and a first base (137), wherein the top of the blanking groove (132) is communicated with the bottom of an inverted cone-shaped structure (112) of the storage cylinder (11), the periphery of the bottom of the blanking groove (132) is connected with the first base (137) through the vibration isolation spring (136), the side part of the blanking groove (132) is connected with the exciting motor (134) through the exciting spring (135), and the activating block (133) is arranged in the blanking groove (132) and fixedly connected with the inner wall of the blanking groove (132) with a distance between the activating block (133) and the inner wall of the blanking groove (132).

7. The engineering residue soil recycling treatment transfer storage warehouse of claim 6, wherein: the top of the activation block (133) is of a conical structure, and the activation block (133) is at least partially positioned at the bottom of the storage cylinder (11).

8. The engineering residue soil recycling treatment transfer storage warehouse of claim 6, wherein: part of the inner wall of the blanking groove (132) is spherical.

9. The engineering residue soil recycling treatment transfer storage warehouse of claim 1, wherein: the periphery part of the bottom of the storage cylinder (11) is provided with a second base (113), and the second base (113) is used for fixedly connecting the storage cylinder (11) with the ground.

10. The engineering residue soil recycling treatment transfer storage warehouse of claim 1, wherein: the feeding conveying device (4) and the discharging conveying device (5) are both belt conveyors.