CN218690167U - Gasification slag resource utilization device - Google Patents

Abstract

The utility model discloses a gasification sediment utilization equipment, including being used for carrying out the casing that the utilization was handled to gasification sediment, frame fixedly connected with bottom plate is passed through to the below of casing, and the top of casing is passed through feeding storehouse fixedly connected with and is used for carrying out the charge-in pipeline of defeated material to gasification sediment. The gasification slag resource utilization device can screen gasification slag aggregates with different thicknesses so as to ensure that screened gasification slag particles can be used as aggregates and admixtures in the production process of concrete, thereby realizing resource reutilization of gasification slag; and the screened large coarse slag can be further crushed, so that the large coarse slag is consistent with the blending material for resource recycling after being crushed, the condition that a lot of screened large coarse slag is discarded and causes resource waste in the past is avoided, the resource recycling efficiency is higher, and the existing use requirements are greatly met.

Description

Gasification slag resource utilization device

Technical Field

The utility model relates to a gasification sediment processing apparatus technical field especially relates to a gasification sediment utilization device.

Background

The gasified slag is solid slag formed by incomplete combustion of coal and oxygen or oxygen-enriched air to generate C0 and H2, and inorganic mineral substances in the coal are subjected to different physical and chemical transformations along with residual carbon particles in the coal in the process, and the solid slag can be divided into coarse slag and fine slag. At present, the research on the application of gasified slag at home and abroad mainly focuses on the following aspects: (1) preparing building materials: aggregate, cementing material, wall material, baking-free brick and the like; (2) soil and water body remediation: soil improvement, water body remediation and the like; (3) utilization of residual carbon: residual carbon property, residual carbon quality improvement, circular blending combustion and the like; (4) preparing a high value-added material: catalyst carrier, rubber and plastic filler, ceramic material, silicon-based material and the like.

The application of the gasification slag in the aspect of building materials at present mainly comprises the preparation of ceramsite, cement, concrete wall materials, brick materials and the like, and is an important way for large-scale consumption of the gasification slag. The gasified slag contains a large amount of silicon-aluminum oxide, has certain volcanic ash activity and can be used as a cement raw material; as the gasified slag particles have a certain gradation, the gasified slag particles can be used as aggregate and admixture in the production process of concrete so as to realize the recycling of the gasified slag. However, as the aggregates of the gasified slag have specifications with different thicknesses, people are still required to screen the coarse slag and the fine slag before resource utilization, but the traditional screening only needs to perform simpler screening treatment, and cannot further process the larger aggregates of the coarse slag, so that a lot of oversize coarse slag which is screened off is discarded, and some resource waste is still caused.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the defects existing in the prior art and providing a gasification slag resource utilization device.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a gasification slag resource utilization device comprises a shell for resource utilization treatment of gasification slag, wherein a bottom plate is fixedly connected below the shell through a rack, and the top of the shell is fixedly connected with a feeding pipeline for conveying the gasification slag through a feeding bin;

a feeding hole is formed in the bottom side of the feeding bin, and a feeding valve plate is movably mounted in the feeding hole; a screening frame is arranged below the feeding bin, and a screening net for screening the gasified slag is fixedly sleeved at the bottom side of the screening frame; the bottom of the right side of the screening frame is fixedly sleeved with a discharge pipeline, and the right end of the discharge pipeline movably penetrates to the outside of the right side of the shell; a baffle is movably arranged in the left end of the discharging pipeline; a hydraulic telescopic cylinder is fixedly arranged on the left side of the shell, and the output end of the hydraulic telescopic cylinder movably penetrates into the shell and is fixedly arranged with the screening frame through a mounting plate; the right side of the screening frame is fixedly connected with a sliding rod, and the right end of the sliding rod penetrates the outer part of the right side of the shell in a sliding manner;

a feed hopper and a crushing box are fixedly connected to the right side of the shell below the discharge pipeline in sequence, a first rotating rod and a second rotating rod are rotatably mounted in the crushing box respectively, and a plurality of crushing knives are fixedly mounted on the first rotating rod and the second rotating rod respectively; a double-shaft motor is fixedly installed on the right side of the crushing box, a left output shaft of the double-shaft motor is fixedly connected with the first rotating rod, a right output shaft of the double-shaft motor is fixedly sleeved with a driving wheel, a driving wheel is connected below the driving wheel through chain transmission, and the driving wheel is fixedly sleeved at the right end of the second rotating rod; the bottom of the crushing box is also fixedly provided with a filter screen.

Preferably, the bottom right-hand member in feeding storehouse has electric telescopic handle, electric telescopic handle's output and feeding valve plate fixed connection through mounting bracket fixed mounting.

Preferably, the inside installation cavity that still is equipped with of right-hand member of screening frame, installation cavity fixed mounting has hydraulic telescoping rod, and the top activity of baffle run through to the installation cavity and with hydraulic telescoping rod's output fixed connection.

Preferably, a transverse sliding sleeve is fixedly sleeved on the inner wall of the right side of the shell, and the sliding rod penetrates through the transverse sliding sleeve in a sliding mode along the horizontal direction.

Preferably, the below fixed mounting of screening net has the collecting hopper, and the flare opening of collecting hopper runs through to the below of casing, and first workbin has still been placed to the below of collecting hopper.

Preferably, a second bin is placed below the filter screen; the middle upper part of the front surface of the shell is provided with a transparent viewing port, and the lower side of the transparent viewing port is provided with a controller.

Adopt above-mentioned structure, the utility model discloses the beneficial effect who gains as follows:

the utility model provides a gasification sediment utilization equipment, not only can sieve gasification sediment aggregate of different thickness size when the utilization to resources to ensure that gasification sediment granule after the screening can regard as aggregate and admixture in the concrete production process, thereby can realize gasification sediment utilization again; in addition, the screened large coarse slag can be further crushed, so that the large coarse slag is crushed to be consistent with the blending material for resource recycling, the condition that a plurality of screened large coarse slag are discarded to cause resource waste in the past is avoided, the resource recycling efficiency is higher, and the existing use requirements are greatly met.

Drawings

FIG. 1 is a schematic structural view of a gasification slag resource utilization device provided by the utility model;

FIG. 2 is a schematic cross-sectional view of the present invention;

FIG. 3 is a schematic view of the structure of the part A in FIG. 2;

fig. 4 is a schematic structural diagram of the inside of the middle crushing box of the present invention.

In the figure: 1. a housing; 100. a collection hopper; 101. a frame; 102. a base plate; 103. a controller; 104. a transparent viewing port; 2. a feed conduit; 3. a feeding bin; 31. a feed inlet; 32. a feed valve plate; 33. an electric telescopic rod; 34. a mounting frame; 4. a discharge conduit; 5. a feed hopper; 6. a crushing box; 60. a crushing knife; 61. a first rotating lever; 62. a second rotating rod; 63. a double-shaft motor; 64. a drive wheel; 65. a chain; 66. a driving wheel; 67. filtering with a screen; 7. a second bin; 8. a first bin; 9. screening the frame; 91. a hydraulic telescopic cylinder; 92. mounting a plate; 93. a slide bar; 94. screening the net; 95. a baffle plate; 96. a mounting cavity; 97. a hydraulic telescopic rod; 98. and a transverse sliding sleeve.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-4, a gasification slag resource utilization device comprises a shell 1 for resource utilization treatment of gasification slag, wherein a bottom plate 102 is fixedly connected below the shell 1 through a rack 101, and a feeding pipeline 2 for conveying the gasification slag is fixedly connected at the top of the shell 1 through a feeding bin 3;

a feeding hole 31 is formed in the bottom side of the feeding bin 3, and a feeding valve plate 32 is movably mounted in the feeding hole 31; a screening frame 9 is arranged below the feeding bin 3, and a screening net 94 for screening the gasified slag is fixedly sleeved on the bottom side of the screening frame 9; the bottom of the right side of the screening frame 9 is fixedly sleeved with a discharge pipeline 4, and the right end of the discharge pipeline 4 movably penetrates to the outside of the right side of the shell 1; a baffle 95 is movably arranged in the left end of the discharge pipeline 4; a hydraulic telescopic cylinder 91 is fixedly arranged on the left side of the shell 1, and the output end of the hydraulic telescopic cylinder 91 movably penetrates into the shell 1 and is fixedly arranged with the screening frame 9 through a mounting plate 92; a sliding rod 93 is fixedly connected to the right side of the screening frame 9, and the right end of the sliding rod 93 penetrates through the right side of the shell 1 in a sliding manner;

a feed hopper 5 and a crushing box 6 are fixedly connected to the right side of the shell 1 below the discharge pipeline 4 in sequence, a first rotating rod 61 and a second rotating rod 62 are rotatably mounted in the crushing box 6 respectively, and a plurality of crushing cutters 60 are fixedly mounted on the first rotating rod 61 and the second rotating rod 62 respectively; a double-shaft motor 63 is fixedly installed on the right side of the crushing box 6, a left output shaft of the double-shaft motor 63 is fixedly connected with the first rotating rod 61, a driving wheel 64 is fixedly sleeved on a right output shaft of the double-shaft motor 63, a driving wheel 66 is connected below the driving wheel 64 in a transmission manner through a chain 65, and the driving wheel 66 is fixedly sleeved on the right end of the second rotating rod 62; the bottom of the crushing box 6 is also fixedly provided with a filter screen 67.

In this example, an electric telescopic rod 33 is fixedly installed at the right end of the bottom of the feeding bin 3 through an installation frame 34, and the output end of the electric telescopic rod 33 is fixedly connected with the feeding valve plate 32; the inside installation cavity 96 that still is equipped with of right-hand member of screening frame 9, fixed mounting has hydraulic telescoping rod 97 in the installation cavity 96, and the top activity of baffle 95 run through to in the installation cavity 96 and with hydraulic telescoping rod 97's output fixed connection.

Wherein, a transverse sliding sleeve 98 is fixedly sleeved on the inner wall of the right side of the shell 1, and the sliding rod 93 penetrates through the transverse sliding sleeve 98 in a sliding manner along the horizontal direction; a hopper 100 is fixedly arranged below the sieving net 94, a funnel opening of the hopper 100 penetrates below the shell 1, and a first material box 8 is further arranged below the hopper 100.

Wherein, a second feed box 7 is arranged below the filter screen 67; a transparent viewing port 104 is provided at the middle upper part of the front surface of the housing 1, and a controller 103 is provided at the lower side of the transparent viewing port 104.

As shown in fig. 1-4, when the gasification slag needs to be subjected to resource treatment and utilization, the gasification slag is conveyed into the feeding bin 3 through the feeding pipeline 2, and the feeding valve plate 32 is driven to be closed leftwards or opened rightwards at the feeding port 31 by the extension and retraction of the electric telescopic rod 33; when the feeding valve plate 32 is opened rightward, the gasified slag material can be fed into the screening frame 9 through the feeding port 31, and then left-right screening operation can be performed on the gasified slag material in the screening frame 9 through the expansion of the output end of the hydraulic expansion cylinder 91, so that the finer slag in the gasified slag can be screened through the screening net 94 on the bottom side of the screening frame 9, and then the finer slag is collected by the collecting hopper 100 and then is loaded into the first material box 8; the larger coarse slag is screened and left on the screening net 94, the baffle 95 is driven to move upwards to be opened by the contraction of the hydraulic telescopic rod 97, and the screened larger coarse slag can be discharged into the feed hopper 5 and the crushing box 6 through the discharge pipeline (4); then, the first rotating rod 61 and the crushing cutter 60 are driven to rotate by the double-shaft motor 63, so that large coarse slag can be crushed; meanwhile, still drive wheel 64, chain 65, drive wheel 66 through the right output shaft of double-shaft motor 63 and rotate, and then drive the crushing sword 60 rotation on second bull stick 62 and the second bull stick 62, also can carry out the breakage to great coarse slag like this to can be quick carry out the breakage with great coarse slag, and the fine slag crushed aggregates among the crushing process still filters through filter screen 67 and fall to second workbin 7 and collect can.

Finally, in the utility model, the gasification slag aggregates with different thicknesses can be screened during resource utilization, so as to ensure that the screened gasification slag particles can be used as aggregates and admixtures in the concrete production process, thereby realizing resource recycling of the gasification slag; and the screened large coarse slag can be further crushed, so that the large coarse slag is consistent with the blending material for resource recycling after being crushed, the condition that a lot of screened large coarse slag is discarded and causes resource waste in the past is avoided, the resource recycling efficiency is higher, and the existing use requirements are greatly met.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (6)

1. The gasification slag resource utilization device is characterized by comprising a shell (1) for resource utilization treatment of gasification slag, wherein a bottom plate (102) is fixedly connected below the shell (1) through a rack (101), and the top of the shell (1) is fixedly connected with a feeding pipeline (2) for conveying the gasification slag through a feeding bin (3);

a feeding hole (31) is formed in the bottom side of the feeding bin (3), and a feeding valve plate (32) is movably mounted in the feeding hole (31); a screening frame (9) is arranged below the feeding bin (3), and a screening net (94) for screening the gasified slag is fixedly sleeved on the bottom side of the screening frame (9); the bottom of the right side of the screening frame (9) is fixedly sleeved with a discharge pipeline (4), and the right end of the discharge pipeline (4) movably penetrates to the outside of the right side of the shell (1); a baffle (95) is movably arranged in the left end of the discharge pipeline (4); a hydraulic telescopic cylinder (91) is fixedly arranged on the left side of the shell (1), and the output end of the hydraulic telescopic cylinder (91) movably penetrates into the shell (1) and is fixedly arranged with the screening frame (9) through a mounting plate (92); a sliding rod (93) is fixedly connected to the right side of the screening frame (9), and the right end of the sliding rod (93) penetrates through the right side of the shell (1) in a sliding manner;

a feed hopper (5) and a crushing box (6) are sequentially and fixedly connected to the right side of the shell (1) below the discharging pipeline (4), a first rotating rod (61) and a second rotating rod (62) are rotatably mounted in the crushing box (6) respectively, and a plurality of crushing cutters (60) are fixedly mounted on the first rotating rod (61) and the second rotating rod (62) respectively; a double-shaft motor (63) is fixedly mounted on the right side of the crushing box (6), a left output shaft of the double-shaft motor (63) is fixedly connected with the first rotating rod (61), a driving wheel (64) is fixedly sleeved on a right output shaft of the double-shaft motor (63), a driving wheel (66) is connected below the driving wheel (64) in a transmission manner through a chain (65), and the driving wheel (66) is fixedly sleeved at the right end of the second rotating rod (62); the bottom of the crushing box (6) is also fixedly provided with a filter screen (67).

2. The gasification slag resource utilization device as claimed in claim 1, wherein an electric telescopic rod (33) is fixedly mounted at the right end of the bottom of the feeding bin (3) through a mounting frame (34), and the output end of the electric telescopic rod (33) is fixedly connected with the feeding valve plate (32).

3. The gasification slag resource utilization device according to claim 1, wherein an installation cavity (96) is further formed inside the right end of the screening frame (9), a hydraulic telescopic rod (97) is fixedly installed in the installation cavity (96), and the top end of the baffle (95) movably penetrates into the installation cavity (96) and is fixedly connected with the output end of the hydraulic telescopic rod (97).

4. A gasification slag resource utilization device according to claim 1, characterized in that a transverse sliding sleeve (98) is fixedly sleeved on the right inner wall of the housing (1), and the sliding rod (93) slides in the horizontal direction to penetrate through the transverse sliding sleeve (98).

5. A gasification slag resource utilization device according to claim 1, characterized in that a material collecting hopper (100) is fixedly installed below the screening net (94), a hopper opening of the material collecting hopper (100) penetrates below the shell (1), and a first material box (8) is further placed below the material collecting hopper (100).

6. A gasification slag resource utilization device according to claim 1, characterized in that a second bin (7) is placed below the filter screen (67); a transparent observation port (104) is arranged at the middle upper part of the front surface of the shell (1), and a controller (103) is arranged at the lower side of the transparent observation port (104).

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