CN117943385A - Civil engineering construction waste material processing apparatus - Google Patents

Abstract

The present invention discloses a device for treating construction waste in civil engineering in the technical field of treating construction waste, comprising a shell, a second crushing frame is arranged inside the top of the shell, a first crushing frame offset from the second crushing frame is arranged on one side of the second crushing frame, a second crushing frame for sliding connection with the shell is fixedly connected to one side of the first crushing frame and the second crushing frame, a waste crushing and screening assembly is arranged on the first crushing frame, the waste crushing and screening assembly is used for separating metal and non-metal in the waste, a crushing wheel is rotatably connected inside the shell, the present invention adopts two groups of different crushing assemblies to classify and treat waste containing metal and waste not containing metal, and after the waste containing metal is treated by the waste crushing and screening assembly, the separated non-metal waste will be crushed again by the crushing assembly of non-metallic materials.

Description

A device for treating construction waste in civil engineering

Technical Field

The invention relates to the technical field of construction waste treatment, in particular to a civil engineering construction waste treatment device.

Background technique

When people are engaged in production activities in the construction industry such as demolition, construction, and decoration, construction waste such as slag, waste concrete, waste bricks and stones, and other waste will be generated. Since the composition of construction waste is diverse and the volume is generally large, in order not to pollute the environment, construction waste needs to be treated in a pollution-free manner.

Construction waste can be divided into slag, concrete blocks, rubble, brick and tile fragments, waste mortar, mud, asphalt blocks, waste plastics, waste metal, waste bamboo and wood, etc. Except for waste metal, the remaining waste can be processed by direct crushing. Scrap metal has a high cost and can be recycled. Scrap metal needs to be separated for recycling, but the scrap metal in construction waste is usually fixed together with concrete or other bamboo and wood. When recycling, the scrap metal needs to be separated from the rest of the waste, but there is a lack of equipment for separating and recycling scrap metal in construction waste.

Summary of the invention

The object of the present invention is to provide a device for treating construction waste in civil engineering to solve the problems raised in the above-mentioned background technology.

To achieve the above-mentioned purpose, the present invention provides the following technical solutions: a civil engineering construction waste treatment device, comprising a shell, a second crushing frame is arranged inside the top of the shell, a first crushing frame is arranged on one side of the second crushing frame, which is offset from the first crushing frame, and a second crushing frame for sliding connection with the shell is fixedly connected to one side of the first crushing frame and the second crushing frame, a waste crushing and screening assembly is arranged on the first crushing frame, and the waste crushing and screening assembly is used to separate metal and non-metal in the waste, a crushing wheel is rotatably connected inside the shell, a discharge plate is fixedly connected inside the shell at the bottom of the crushing wheel, a side discharge port is opened on one side of the shell, and one end of the discharge plate is connected to the side discharge port.

As a further solution of the present invention, the waste crushing and screening assembly includes threaded rods, several of the threaded rods are equidistantly slidably arranged on the second crushing frame, several of the threaded rods are respectively threadedly sleeved with threaded rings, several of the threaded rings are commonly meshed with chains, a fixed rack is fixedly connected to the inner wall of the shell, one end of the second crushing frame is rotatably connected to a transmission gear meshed with the fixed rack, a first bevel gear is arranged on the top of the transmission gear, the transmission gear and the first bevel gear are commonly connected with a transmission belt, one end of the first bevel gear is meshed with a second bevel gear, and one end of the second bevel gear is meshed with the threaded The ring is fixedly connected, one end of the threaded rod is fixedly connected to a push plate, one end of the push plate is fixedly connected to a connecting plate, a magnetic plate is fixedly connected to the inner wall of the shell at the lower side of the second crushing frame, one end of the magnetic plate is fixedly connected to an insulating plate, a first cylinder is fixedly connected to the outside of the shell, an oblique push plate is slidably connected to the upper end of the magnetic plate, the output end of the first cylinder passes through the shell and is fixedly connected to the oblique push plate, a fixed funnel is provided on the lower side of the insulating plate, a shaping and transporting component is provided at the bottom of the fixed funnel, and the shaping and transporting component is used to fix the separated metal waste into the same shape and discharge it from the inside of the shell.

As a further solution of the present invention, the shaping and transporting component includes a compacting frame, the compacting frame is fixed on the inner wall of the shell, the bottom of the compacting frame is slidably connected to a sliding plate, one end of the compacting frame is fixedly connected to a fixing rod, one end of the sliding plate is fixedly connected to a telescopic rod, the telescopic rod passes through the compacting frame and is slidably arranged inside the fixing rod, the telescopic rod is fixedly connected to a first spring for resetting the telescopic rod, the inside of the shell is fixedly connected to a second cylinder, the output shaft of the second cylinder is fixedly connected to a compacting plate, the outer wall of the bottom end of the compacting plate can fit with the top end of the sliding plate, and a sealing plate is arranged on the top end of the compacting plate. A sliding groove for sliding connection with a sealing plate is provided on the top of the compacting plate, a positioning rod is fixedly connected to the bottom of the compacting plate, a second cone block is slidably connected to the outside of the positioning rod, a second spring for resetting the second cone block is provided on the positioning rod, convex plates are fixedly connected to both side walls of the second cone block, slide rails for docking with the convex plates are provided on both sides of the compacting frame, a reset frame is fixedly connected to one end of the compacting frame, one end of the convex plate is slidably arranged inside the reset frame, a first cone block with one side wall being an inclined wall is embedded on one side of the top of the sliding plate, and a third spring for resetting the first cone block is fixedly connected inside the sliding plate.

As a further solution of the present invention, a discharge frame is fixedly connected to the bottom of the compaction frame, a side discharge port is opened on one side of the shell, and the bottom of the discharge frame is fixedly connected to the bottom of the side discharge port.

As a further solution of the present invention, an upper feed inlet is provided at the top of the shell, and a side feed inlet is provided at one side of the shell.

As a further solution of the present invention, the top of the magnetic attraction plate is a smooth wall, and the bottom of the inclined push plate can be completely fitted with the outer wall of the top of the magnetic attraction plate.

As a further solution of the present invention, both side walls of the compaction plate are completely in contact with both side inner walls of the compaction frame respectively, and the top outer wall of the sealing plate and the top outer wall of the compaction frame are in the same horizontal plane.

As a further solution of the present invention, an adsorption sound insulation board is fixedly connected to the inner wall of the shell.

As a further solution of the present invention, one side wall of the first crushing frame and the second crushing frame are respectively fixedly connected with a protrusion for sliding connection with the shell, and both sides of the inner top of the shell are respectively fixedly connected with a third cylinder, and the output ends of the two third cylinders are respectively fixedly connected with the first crushing frame and the second crushing frame.

Compared with the prior art, the present invention has the following beneficial effects:

1. The present invention adopts two groups of different crushing components to classify and process metal-containing waste and non-metal-containing waste. After the metal-containing waste is processed by the waste crushing and screening component, the separated non-metallic waste will be crushed again by the non-metallic material crushing component. The screened metal waste will be shaped by the shaping and transportation component, which further separates other impurities in the metal and can shape the metal waste to facilitate subsequent collection.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a schematic diagram of the overall structure of the present invention;

FIG2 is a schematic diagram of the internal structure of the housing;

Figure 3 is a schematic diagram of the structures of the first crushing frame and the second crushing frame;

FIG4 is an enlarged schematic diagram of the structure at A in FIG3 ;

Figure 5 is a schematic diagram of the structure of the standardized transport component;

FIG. 6 is a schematic diagram of the bottom structure of the compaction plate.

In the accompanying drawings, the components represented by the reference numerals are listed as follows:

1. Shell; 2. Upper feed port; 3. Side feed port; 4. Discharge port; 5. First cylinder; 6. Oblique push plate; 7. Magnetic plate; 8. Insulation plate; 9. Crushing wheel; 10. Fixed hopper; 11. Discharge frame; 12. Second cylinder; 13. Bump; 14. First crushing frame; 15. Threaded ring; 16. Connecting plate; 17. Push plate; 18. Second crushing frame; 19. Chain; 20. Threaded rod; 21. Third cylinder; 22. Fixed rack; 23. Transmission gear; 24. Transmission belt; 25. First bevel gear; 26. Second bevel gear; 27. Fixed rod; 28. Telescopic rod; 29. Compacting frame; 30. Sliding plate; 31. Slide rail; 32. Reset frame; 33. First cone block; 34. Closing plate; 35. Compacting plate; 36. Slide groove; 37. Bump plate; 38. Positioning rod; 39. Second cone block.

Detailed ways

Please refer to Figures 1-6. The present invention provides a technical solution: a civil engineering construction waste treatment device, including a shell 1, a second crushing frame 18 is arranged inside the top of the shell 1, a first crushing frame 14 is arranged on one side of the second crushing frame 18 and is offset therefrom, the first crushing frame 14 and the second crushing frame 18 are respectively fixedly connected to the second crushing frame 18 for sliding connection with the shell 1, a waste crushing and screening assembly is arranged on the first crushing frame 14, and the waste crushing and screening assembly is used to separate metal and non-metal in the waste, a crushing wheel 9 is rotatably connected inside the shell 1, a discharge plate is fixedly connected inside the shell 1 at the bottom of the crushing wheel 9, a side discharge port 4 is opened on one side of the shell 1, and one end of the discharge plate is connected to the side discharge port 4;

When the above scheme is put into practical use, the collected construction waste is first classified and processed, and the waste not containing metal is directly put in from one side of the shell 1, and the waste is directly crushed by the crushing wheel 9, and the crushed waste is discharged from the discharge port 4. The metal and mixed waste containing metal are put into the shell 1 from the top of the shell 1, and the metal and non-metal are separated by extrusion of the first crushing frame 14 and the second crushing frame 18, and the metal is extruded and deformed to change its shape for easier collection. The extruded waste passes through the waste crushing and screening assembly to separate the metal from the non-metal, thereby realizing the separation of metal in the mixed waste containing metal, which is convenient for the subsequent recycling of metal waste.

As a further solution of the present invention, the waste crushing and screening assembly includes a threaded rod 20, several of the threaded rods 20 are equidistantly slidably arranged on the second crushing frame 18, several of the threaded rods 20 are respectively threadedly sleeved with a threaded ring 15, and several of the threaded rings 15 are commonly meshed with a chain 19, a fixed rack 22 is fixedly connected to the inner wall of the shell 1, one end of the second crushing frame 18 is rotatably connected to a transmission gear 23 meshed with the fixed rack 22, a first bevel gear 25 is arranged on the top of the transmission gear 23, the transmission gear 23 and the first bevel gear 25 are commonly connected to a transmission belt 24, one end of the first bevel gear 25 is meshed with a second bevel gear 26, one end of the second bevel gear 26 is fixedly connected to the threaded ring 15, one end of the threaded rod 20 is fixedly connected to a push plate 17, and one end of the push plate 17 is fixedly connected to a connecting plate 16. A magnetic plate 7 is fixedly connected to the inner wall of the shell 1 at the lower side of the second crushing frame 18, and an insulating plate 8 is fixedly connected to one end of the magnetic plate 7. A first cylinder 5 is fixedly connected to the outer side of the shell 1, and an oblique push plate 6 is slidably connected to the upper end of the magnetic plate 7. The output end of the first cylinder 5 passes through the shell 1 and is fixedly connected to the oblique push plate 6. A fixed funnel 10 is provided on the lower side of the insulating plate 8, and a shaping and transporting assembly is provided at the bottom of the fixed funnel 10. The shaping and transporting assembly is used to fix the separated metal waste into the same shape and discharge it from the inside of the shell 1. One side wall of the first crushing frame 14 and the second crushing frame 18 are respectively fixedly connected to a protrusion 13 for sliding connection with the shell 1, and both sides of the inner top of the shell 1 are respectively fixedly connected to the third cylinder 21, and the output ends of the two third cylinders 21 are respectively fixedly connected to the first crushing frame 14 and the second crushing frame 18;

When the above scheme is put into practical use, when the waste containing metal is squeezed, the initial state of the first crushing frame 14 and the second crushing frame 18 is shown in FIG. 3. Before the waste is put in, the first crushing frame 14 and the second crushing frame 18 are pushed to slide toward each other by the third cylinder 21 until there is no gap between the first crushing frame 14 and the second crushing frame 18. At this time, the sliding of the second crushing frame 18 drives the transmission gear 23 to rotate on the fixed rack 22, and the transmission of the transmission belt 24 drives the first bevel gear 25 to rotate synchronously, and the first bevel gear 25 drives the second bevel gear 26 to rotate. The second bevel gear 26 drives the threaded ring 15 to rotate, and several threaded rings 15 rotate synchronously through the chain 19. Since the threaded rod 20 is restricted on the second crushing frame 18 and can only slide but not rotate, the threaded rod 20 slides inside the threaded ring 15 as the threaded ring 15 rotates. The threaded rod 20 slides the push plate 17 and the connecting plate 16 to the inside of the second crushing frame 18, and then the waste is placed from the top of the shell 1 on the first crushing frame 14 and the second crushing frame 18, and then the third cylinder 21 is started to drive the first crushing frame 14 and the second crushing frame 18 to continue to slide toward each other. , the waste can be crushed and squeezed. After the squeezing is completed, the third cylinder 21 drives the first crushing frame 14 and the second crushing frame 18 to reset. At this time, the rotation direction of the transmission gear 23 on the fixed rack 22 changes. After a series of transmissions, the sliding direction of the threaded rod 20 changes. The threaded rod 20 pushes the connecting plate 16 and the push plate 17 to slide to the outside of the second crushing frame 18. The purpose of this is that the waste can be easily stuck inside the first crushing frame 14 and the second crushing frame 18 after squeezing. The push plate 17 and the connecting plate 16 can push the waste stuck in the second crushing frame 18 The waste inside is pushed out and falls on the magnetic plate 7 under the action of gravity. If it is metal material, it will be adsorbed by the magnetic plate 7. If it is non-metal material, it will fall on the crushing wheel 9 along the inclined magnetic plate 7. In this way, the non-metal material will be crushed by the crushing wheel 9, and then the first cylinder 5 is started to push the inclined push plate 6 to slide on the magnetic plate 7, and the metal material attached to the magnetic plate 7 is slowly moved to the insulating plate 8. After the metal material is separated from the adsorption of the magnetic plate 7, it will fall into the inside of the shaping and transportation component along the insulating plate 8, and the metal material will be further processed by the shaping and transportation component.

As a further solution of the present invention, the shaping and transporting component includes a compacting frame 29, the compacting frame 29 is fixed on the inner wall of the shell 1, and a sliding plate 30 is slidably connected to the bottom of the compacting frame 29, one end of the compacting frame 29 is fixedly connected to a fixed rod 27, and one end of the sliding plate 30 is fixedly connected to a telescopic rod 28, the telescopic rod 28 passes through the compacting frame 29 and is slidably arranged inside the fixed rod 27, and a first spring for resetting the telescopic rod 28 is fixedly connected to the telescopic rod 28, a second cylinder 12 is fixedly connected to the inside of the shell 1, and a compacting plate 35 is fixedly connected to the output shaft of the second cylinder 12, the outer wall of the bottom end of the compacting plate 35 can fit with the top of the sliding plate 30, a sealing plate 34 is arranged on the top of the compacting plate 35, and a sliding groove 36 for sliding connection with the sealing plate 34 is opened on the top of the compacting plate 35, A positioning rod 38 is fixedly connected to the bottom of the solid plate 35, and a second cone block 39 is slidably connected to the outside of the positioning rod 38. A second spring for resetting the second cone block 39 is arranged on the positioning rod 38, and convex plates 37 are fixedly connected to the two side walls of the second cone block 39 respectively. Slide rails 31 for docking with the convex plates 37 are provided on both sides of the compacting frame 29. A reset frame 32 is fixedly connected to one end of the compacting frame 29, and one end of the convex plate 37 is slidably arranged inside the reset frame 32. A first cone block 33 with a side wall as an inclined wall is embedded on one side of the top of the sliding plate 30, and a third spring for resetting the first cone block 33 is fixedly connected to the inside of the sliding plate 30. A discharge frame 11 is fixedly connected to the bottom of the compacting frame 29, and a side discharge port is provided on one side of the shell 1, and the bottom of the discharge frame 11 is fixedly connected to the bottom of the side discharge port.

When the above scheme is put into practical use, as shown in Figures 2, 5, and 6, the metal waste passing through the insulating plate 8 will enter the fixed funnel 10, and then pass through the fixed funnel 10 and fall on the sliding plate 30 inside the compacting frame 29, and then the second cylinder 12 is started to push the compacting plate 35 to slide, and the convex plate 37 enters the slide rail 31 along the reset frame 32, and the compacting plate 35 squeezes the internal metal waste from one side of the compacting frame 29. At this time, the compacting plate 35 will contact the inclined surface of the first cone block 33 when sliding, and the first cone block 33 will be squeezed into the compacting frame 29 under the action of pressure. The sealing plate 34 is sealed from the top of the compacting frame 29. The purpose of this is to seal the extrusion space through the sealing plate 34 to ensure the uniform shape of the metal material after extrusion. After the extrusion is completed, the second cylinder 12 drives the compacting plate 35 to reset. When the compacting plate 35 retreats to the point where the first cone block 33 contacts the groove at the bottom of the compacting plate 35, the first cone block 33 is inserted into the groove under the elastic force of the third spring. When the compacting plate 35 slides, it drives the first cone block 33 to slide together. The first cone block 33 drives the sliding plate 30 to stretch the telescopic rod 28, so that the compacting frame 29 The bottom is opened. As the sliding plate 30 continues to slide, the bottom opening of the compacting frame 29 is large enough to allow the extruded metal block to fall into the discharge frame 11 and be discharged from the side discharge port through the discharge frame 11. When the compacting plate 35 slides until the convex plate 37 contacts the end of the reset frame 32, the convex plate 37 cannot slide further. The convex plate 37 will pull the second cone block 39 to slide in the opposite direction relative to the compacting plate 35, and the first cone block 33 will be squeezed into the sliding plate 30 through the compacting plate 35, thereby disconnecting the compacting plate 35 from the sliding plate 30. The first spring on the telescopic rod 28 The sliding plate 30 is pulled back to its original position under the elastic force of the compacting plate 35, thereby realizing the action of discharging the squeezed metal blocks on the sliding plate 30 from the inside of the compacting frame 29 under the resetting action of the compacting plate 35. The advantage of this is that the metal material after screening by the first crushing frame 14 and the second crushing frame 18 may still have a small amount of other materials attached to the surface. After being squeezed by the compacting plate 35, the pressure of the compacting plate 35 and the deformation effect of the metal material can further separate the metal and non-metal in the waste, and the metal waste after extrusion molding is more convenient to collect.

As a further solution of the present invention, an upper feed port 2 is provided on the top of the shell 1, and a side feed port 3 is provided on one side of the shell 1;

When the above scheme is put into practical use, the upper feed port 2 at the top is used to feed metal and waste containing metal, and the side feed port 3 is the feed port for waste not containing metal, so as to classify the construction waste and crush it.

As a further solution of the present invention, the top of the magnetic attraction plate 7 is a smooth wall, and the bottom of the inclined push plate 6 can be completely fitted with the outer wall of the top of the magnetic attraction plate 7;

When the above solution is put into actual use, all the metal materials attached to the surface of the magnetic attraction plate 7 can be pushed to the insulating plate 8 on one side through the inclined push plate 6 to reduce wear.

As a further solution of the present invention, both side walls of the compacting plate 35 are completely in contact with both side inner walls of the compacting frame 29, and the top outer wall of the sealing plate 34 is in the same horizontal plane as the top outer wall of the compacting frame 29.

When the above solution is put into practical use, it can be ensured that there will be no gap inside the compacting frame 29 when it is squeezed by the compacting plate 35, so that the metal waste inside the compacting frame 29 can be fully squeezed.

As a further solution of the present invention, an adsorption sound insulation board is fixedly connected to the inner wall of the housing 1;

When the above solution is put into actual use, the debris generated during the crushing process is absorbed by the adsorption sound insulation board to reduce the spread of dust, and at the same time it can absorb noise, so that the shell 1 has less noise when working.

Working principle: When the waste containing metal is squeezed, the initial state of the first crushing frame 14 and the second crushing frame 18 is shown in FIG3. Before the waste is put in, the first crushing frame 14 and the second crushing frame 18 are pushed to slide toward each other by the third cylinder 21 until there is no gap between the first crushing frame 14 and the second crushing frame 18. At this time, the sliding of the second crushing frame 18 drives the transmission gear 23 to rotate on the fixed rack 22, and the transmission of the transmission belt 24 drives the first bevel gear 25 to rotate synchronously, and the first bevel gear 25 drives the second bevel gear 26 to rotate. The second bevel gear 26 drives the threaded ring 15 to rotate, and several threaded rings 15 rotate synchronously through the chain 19. Since the threaded rod 20 is restricted on the second crushing frame 18 and can only slide but not rotate, the threaded rod 20 slides inside the threaded ring 15 as the threaded ring 15 rotates. The threaded rod 20 slides the push plate 17 and the connecting plate 16 to the inside of the second crushing frame 18, and then the waste is placed from the top of the shell 1 on the first crushing frame 14 and the second crushing frame 18, and then the third cylinder 21 is started to drive the first crushing frame 14 and the second crushing frame 18. Continue to slide towards each other, and the waste can be crushed and squeezed. After the squeezing is completed, the third cylinder 21 drives the first crushing frame 14 and the second crushing frame 18 to reset. At this time, the rotation direction of the transmission gear 23 on the fixed rack 22 changes. After a series of transmissions, the sliding direction of the threaded rod 20 changes, and the threaded rod 20 pushes the connecting plate 16 and the push plate 17 to slide toward the outside of the second crushing frame 18. The purpose of this is that the waste is easily stuck inside the first crushing frame 14 and the second crushing frame 18 after squeezing. 6 can push out the waste stuck in the second crushing frame 18, so that it falls on the magnetic plate 7 under the action of gravity. If it is a metal material, it will be attracted by the magnetic plate 7. If it is a non-metal material, it will fall on the crushing wheel 9 along the inclined magnetic plate 7. In this way, the non-metal material will be crushed by the crushing wheel 9, and then the first cylinder 5 is started to push the inclined push plate 6 to slide on the magnetic plate 7, and the metal material attached to the magnetic plate 7 is slowly moved to the insulating plate 8. After the metal material is separated from the adsorption of the magnetic plate 7, it will fall into the interior of the stereotyped transportation component along the insulating plate 8.

The metal waste that passes through the insulating plate 8 will enter the fixed funnel 10, and then pass through the fixed funnel 10 and fall above the sliding plate 30 inside the compacting frame 29, and then the second cylinder 12 is started to push the compacting plate 35 to slide, and the convex plate 37 enters the slide rail 31 along the reset frame 32, and the compacting plate 35 squeezes the internal metal waste from one side of the compacting frame 29. At this time, the compacting plate 35 will contact the inclined surface of the first cone block 33 when sliding, and the first cone block 33 will be squeezed into the compacting frame 29 under the action of pressure, and the sealing plate 34 will cover from the top of the compacting frame 29. The purpose of this is to seal the extrusion space through the sealing plate 34 to ensure the uniform shape of the metal material after extrusion. After the extrusion is completed, the second cylinder 12 drives the compacting plate 35 to reset. When the compacting plate 35 retreats to the point where the first cone block 33 contacts the bottom groove of the compacting plate 35, the third Under the action of the spring force, the first cone block 33 will be inserted into the groove, so that when the compacting plate 35 slides, the first cone block 33 will be driven to slide together, and the first cone block 33 drives the sliding plate 30 to stretch the telescopic rod 28, so that the bottom of the compacting frame 29 is opened. As the sliding plate 30 continues to slide, the bottom opening of the compacting frame 29 is large enough to allow the extruded metal block to fall into the discharge frame 11 and be discharged from the side discharge port through the discharge frame 11. When the compacting plate 35 slides until the convex plate 37 contacts the end of the reset frame 32, the convex plate 37 cannot continue to slide, and the convex plate 37 will pull the second cone block 39 to slide in the opposite direction relative to the compacting plate 35, and squeeze the first cone block 33 into the inside of the sliding plate 30 through the compacting plate 35, thereby disconnecting the connection between the compacting plate 35 and the sliding plate 30, and pulling the sliding plate 30 to reset under the action of the elastic force of the first spring on the telescopic rod 28.

Claims (9)

1. Civil engineering construction waste treatment device, including casing (1), its characterized in that: a second crushing frame (18) is arranged in the top end of the shell (1), a first crushing frame (14) staggered with the second crushing frame (18) is arranged on one side of the second crushing frame (18), the second crushing frames (18) which are respectively and fixedly connected with one side of the first crushing frame (14) and one side of the second crushing frame (18) are respectively and slidably connected with the shell (1), a waste crushing and screening assembly is arranged on the first crushing frame (14), the waste crushing and screening assembly is used for separating metal from nonmetal in waste, a crushing wheel (9) is connected to the inside rotation of the shell (1), a discharging plate is fixedly connected to the inside of the shell (1) at the bottom of the crushing wheel (9), a side discharging hole (4) is formed in one side of the shell (1), and one end of the discharging plate is in butt joint with the side discharging hole (4).

2. The civil engineering construction waste treatment device according to claim 1, wherein: the waste crushing and screening assembly comprises a threaded rod (20), a plurality of threaded rods (20) are respectively and equidistantly arranged on a second crushing frame (18) in a sliding mode, a plurality of threaded rings (15) are respectively sleeved on the threaded rods (20) in a threaded mode, chains (19) are meshed with the threaded rings (15) jointly, a fixed rack (22) is fixedly connected to the inner wall of a shell (1), a transmission gear (23) meshed with the fixed rack (22) is connected to one end of the second crushing frame (18) in a rotating mode, a first bevel gear (25) is arranged at the top of the transmission gear (23), a transmission belt (24) is connected to one end of the transmission gear (23) and the first bevel gear (25) jointly, a second bevel gear (26) is meshed to one end of the first bevel gear (25), one end of the second bevel gear (26) is fixedly connected with the threaded rings (15), a pushing plate (17) is fixedly connected to one end of the threaded rod, a connecting plate (16) is fixedly connected to one end of the pushing plate, a magnetic suction plate (7) is fixedly connected to the inner wall (7) of the shell (1) below the second crushing frame (18), a magnetic suction plate (7) is fixedly connected to the outer side of the magnetic suction plate (8), the upper end of the magnetic suction plate (7) is connected with an inclined push plate (6) in a sliding manner, the output end of the first air cylinder (5) penetrates through the shell (1) and is fixedly connected with the inclined push plate (6), a fixed funnel (10) is arranged on the lower side of the insulating plate (8), the bottom of the fixed funnel (10) is provided with a shaping transportation assembly, and the shaping transportation assembly is used for fixing the separated metal waste into the same shape and discharging the metal waste from the inside of the shell (1).

3. The civil engineering construction waste treatment device according to claim 2, wherein: the shaping transportation assembly comprises a compaction frame (29), the compaction frame (29) is fixed on the inner wall of a shell (1), a sliding plate (30) is fixedly connected to the bottom of the compaction frame (29), a fixed rod (27) is fixedly connected to one end of the compaction frame (29), a telescopic rod (28) is fixedly connected to one end of the sliding plate (30), the telescopic rod (28) penetrates through the compaction frame (29) and is arranged inside the fixed rod (27) in a sliding manner, a first spring for resetting the telescopic rod (28) is fixedly connected to the telescopic rod, a second cylinder (12) is fixedly connected to the inner part of the shell (1), a compaction plate (35) is fixedly connected to the output shaft of the second cylinder (12), the outer wall of the bottom of the compaction plate (35) can be attached to the top end of the sliding plate (30), a sliding groove (36) for sliding connection with a sealing plate (34) is formed in the top of the compaction plate (35), a positioning rod (38) is fixedly connected to the bottom of the compaction plate (35), a second conical block (39) is connected to the second conical block (39) and is fixedly connected to the second conical block (39), the utility model discloses a compression frame, compaction frame (29) both sides have been seted up and have been used for with slide rail (31) of flange (37) butt joint, compaction frame (29) one end fixedly connected with frame (32) that resets, flange (37) one end slip sets up inside frame (32) that resets, first awl piece (33) that a lateral wall is the inclined wall are embedded to slide board (30) top one side, the inside fixedly connected with of slide board (30) is used for the third spring that first awl piece (33) reset.

4. A civil engineering construction waste treatment device according to claim 3, wherein: the compacting device is characterized in that a discharging frame (11) is fixedly connected to the bottom of the compacting frame (29), a side discharging hole is formed in one side of the shell (1), and the bottom of the discharging frame (11) is fixedly connected with the bottom of the side discharging hole.

5. The civil engineering construction waste treatment device according to claim 1, wherein: an upper feed inlet (2) is formed in the top of the shell (1), and a side feed inlet (3) is formed in one side of the shell (1).

6. The civil engineering construction waste treatment device according to claim 2, wherein: the top end of the magnetic suction plate (7) is smooth, and the bottom of the inclined push plate (6) can be completely attached to the outer wall of the top end of the magnetic suction plate (7).

7. A civil engineering construction waste treatment device according to claim 3, wherein: the two side walls of the compaction plate (35) are completely attached to the inner walls of the two sides of the compaction frame (29), and the outer wall of the top end of the sealing plate (34) and the outer wall of the top end of the compaction frame (29) are positioned on the same horizontal plane.

8. The civil engineering construction waste treatment device according to claim 1, wherein: an adsorption sound insulation plate is fixedly connected to the inner wall of the shell (1).

9. The civil engineering construction waste treatment device according to claim 1, wherein: the utility model discloses a crushing device, including first crushing frame (14), second crushing frame (18), lug (13) that are used for with casing (1) sliding connection are all fixedly connected with respectively to first crushing frame (14), second crushing frame (18) lateral wall, inside both sides in casing (1) top are fixedly connected with third cylinder (21) respectively, two the output of third cylinder (21) all respectively with first crushing frame (14), second crushing frame (18) fixed connection.