CN216396610U - Sand washing mechanism for recycling production of construction waste - Google Patents

Abstract

The utility model discloses a sand washing mechanism for recycling production of construction waste, and aims to provide a sand washing mechanism for recycling production of construction waste, which can recycle large blocks of muck. It includes pay-off conveyer belt, cutting conveyer, smashes case, washs pond and exit conveyor, and the output of pay-off conveyer belt is connected with the input of cutting conveyer, and the top of the feed inlet of smashing the case is arranged in to the output of cutting conveyer, and the top of wasing the pond is arranged in to the discharge gate of smashing the case, and exit conveyor's input and washing pond are connected. The utility model has the beneficial effects that: the purpose of recovering large blocks of dregs is achieved; the large piece of muck is effectively cut, and the clamping and striking type cutting efficiency is high; the effective cutting is ensured, and the grinding effect on the muck is realized; the crushing effect is good.

Description

Sand washing mechanism for recycling production of construction waste

Technical Field

The utility model relates to the technical field related to machinery, in particular to a sand washing mechanism for recycling and producing construction waste.

Background

After the building construction is dismantled, some construction wastes are generated, the most important is the lumpy muck of concrete and the like, the muck is thrown into the nature to pollute the environment, a better treatment mode is to reuse the muck, but the muck is in the shape of blocks with different sizes, the current treatment mode is to filter out fine muck, then wash the muck and then make the muck into the building material, most of the large muck is thrown away to pollute the environment and waste, so that the large muck is necessary to be smashed and then recycled.

SUMMERY OF THE UTILITY MODEL

The utility model provides a sand washing mechanism for recovering and producing construction wastes, which can recover massive dregs, in order to overcome the defect that the massive dregs can not be recovered in the prior art.

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

the utility model provides a sand washing mechanism of construction waste recovery production usefulness, includes pay-off conveyer belt, cutting conveyer, smashes the case, washs pond and exit conveyor, the output of pay-off conveyer belt is connected with the input of cutting conveyer, the top of the feed inlet of smashing the case is arranged in to the output of cutting conveyer, the top of wasing the pond is arranged in to the discharge gate of smashing the case, exit conveyor's input and washing pond are connected.

The feeding conveyor belt is used for conveying large-sized dregs to the cutting conveyor, the cutting conveyor can repeatedly cut the large-sized dregs in the process of conveying the large-sized dregs, the large-sized dregs are crushed and reduced, then the cutting conveyor conveys the crushed dregs into the crushing box to be further crushed to reach a usable size, and then the crushing box is cleaned by the cleaning pool, and the cleaned dregs are conveyed out and recovered by the discharging conveyor belt.

Preferably, the cutting conveyer comprises a cutting conveyer belt, side plates, cutters and a plurality of cutting hydraulic rods, the output end of the feeding conveyer belt is connected with the input end of the cutting conveyer belt, the output end of the cutting conveyer belt is arranged above the feed inlet of the crushing box, the two sides of the cutting conveyer belt are respectively provided with one side plate, the side plates are perpendicular to the belt surface of the cutting conveyer belt, the cutting hydraulic rods are arranged on the inner sides of the two side plates and vertically penetrate through the side plates, one end of each cutting hydraulic rod is connected with the corresponding side plate in a sliding mode, the other end of each cutting hydraulic rod is suspended in the air, the cutting hydraulic rods are uniformly distributed on the side plates along the direction of the cutting conveyer belt, the cutting hydraulic rods on the two side plates are distributed in a staggered mode, and one cutter is arranged at the other end of each cutting hydraulic rod. The bold dregs are stopped after being conveyed a section of distance on the cutting conveyer belt, and the cutting hydraulic stem on the curb plate of both sides drives the cutter and presss from both sides the cutting once to the dregs, then the dregs is stopped after being conveyed a section of distance again, cuts again, so relapse, and the cutting hydraulic stem dynamics can effectively cut bold dregs greatly, presss from both sides and hits the formula cutting efficiently.

Preferably, the cutter is arc-shaped, and the arc surface of the cutter is connected with the other end of the cutting hydraulic rod. The arc cutter can buckle the dregs when cutting the dregs and cut, the dregs can not slide away, and the smooth cutting is ensured.

Preferably, the cutting hydraulic rod is provided with a pushing hydraulic rod, the axis of the pushing hydraulic rod coincides with the axis of the cutting hydraulic rod, one end of the pushing hydraulic rod is connected with the side plate in a sliding mode, the other end of the pushing hydraulic rod is suspended, a baffle is installed at the other end of the pushing hydraulic rod and perpendicular to the pushing hydraulic rod, one side face of the baffle is connected with the pushing hydraulic rod, and the other side face of the baffle faces the cutter. Push away and keep off the hydraulic stem and cut the hydraulic stem simultaneous working, push away and keep off the hydraulic stem and drive the baffle, carry out the centre gripping to bold dregs together with the cutter, prevent that dregs from running to one side on the cutting conveyer belt, guarantee effective cutting, have the effect of rolling to dregs simultaneously.

Preferably, the baffle is provided with a plurality of barbed rods, the barbed rods are parallel to the pushing and blocking hydraulic rods, one end of each barbed rod is connected with the other side face of the baffle, and the other end of each barbed rod is suspended in the air. The barbed rod has the effect of disassembling and decomposing the massive dregs, so that the massive dregs are guaranteed to be small, and the cutting efficiency is high.

As preferred, be equipped with in the crushing case and smash roller and grinding roller, crushing roller is parallel with grinding roller, it all respectively has two to smash roller and grinding roller, the top of grinding roller is arranged in to the crushing roller, the both ends of smashing the roller and the both ends of grinding the roller all are rotated with the both sides wall of crushing case and are connected, two are smashed roller parallel arrangement on the horizontal direction, two are ground roller parallel arrangement on the horizontal direction, be equipped with on the crushing roller and smash the pole, the one end of smashing the pole is connected with the outside cylinder of smashing the roller, the other end of smashing the pole is unsettled. The dregs after cutting fall into two in the crushing case smash the roller on, smash the pole and can smash the dregs, smash the dregs after the sediment fall down to two grinding rollers from two crushing rollers, the dregs is smashed through the extrusion grinding in the gap between two grinding rollers, smashes effectually.

The utility model has the beneficial effects that: the purpose of recovering large blocks of dregs is achieved; the large piece of muck is effectively cut, and the clamping and striking type cutting efficiency is high; the effective cutting is ensured, and the grinding effect on the muck is realized; the crushing effect is good.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present invention;

FIG. 2 is a perspective view of a cutting conveyor;

fig. 3 is a schematic view of the crushing and grinding rollers.

In the figure: 1. the automatic grinding machine comprises a feeding conveyor belt, 2 a cutting conveyor, 3 a grinding box, 4 a cleaning pool, 5 a discharging conveyor belt, 6 a cutting conveyor belt, 7 a side plate, 8 a cutter, 9 a cutting hydraulic rod, 10 a pushing and blocking hydraulic rod, 11 a baffle, 12 a thorn rod, 13 a grinding roller, 14 a grinding roller and 15 a grinding rod.

Detailed Description

The utility model is further described with reference to the following figures and detailed description.

In the embodiment shown in fig. 1, the sand washing mechanism for recycling and producing construction waste comprises a feeding conveyor belt 1, a cutting conveyor 2, a crushing box 3, a cleaning pool 4 and an discharging conveyor belt 5, wherein the output end of the feeding conveyor belt 1 is connected with the input end of the cutting conveyor 2, the output end of the cutting conveyor 2 is arranged above the feeding hole of the crushing box 3, the discharging hole of the crushing box 3 is arranged above the cleaning pool 4, and the input end of the discharging conveyor belt 5 is connected with the cleaning pool 4.

As shown in fig. 2, the cutting conveyer 2 includes a cutting conveyer belt 6, side plates 7, a cutter 8 and a plurality of cutting hydraulic rods 9, the output end of the feeding conveyer belt 1 is connected with the input end of the cutting conveyer belt 6, the output end of the cutting conveyer belt 6 is arranged above the feed inlet of the crushing box 3, both sides of the cutting conveyer belt 6 are provided with one side plate 7, the side plate 7 is perpendicular to the belt surface of the cutting conveyer belt 6, the cutting hydraulic rods 9 are arranged inside the two side plates 7, the cutting hydraulic rods 9 are vertically arranged on the side plates 7 in a penetrating manner, one end of each cutting hydraulic rod 9 is connected with the side plate 7 in a sliding manner, the other end of each cutting hydraulic rod 9 is suspended, the cutting hydraulic rods 9 are uniformly arranged and distributed on the side plates 7 along the direction of the cutting conveyer belt 6, the cutting hydraulic rods 9 on the two side plates 7 are distributed in a staggered manner, and the other end of each cutting hydraulic rod 9 is provided with one cutter 8.

The cutter 8 is arc-shaped, and the arc surface of the cutter 8 is connected with the other end of the cutting hydraulic rod 9.

Cutting hydraulic stem 9 is equipped with pushes away and keeps off hydraulic stem 10, pushes away the axis coincidence that keeps off hydraulic stem 10 and cutting hydraulic stem 9, pushes away the one end and the curb plate 7 sliding connection that keep off hydraulic stem 10, and the other end that pushes away and keeps off hydraulic stem 10 is unsettled, pushes away to install baffle 11 on the other end that keeps off hydraulic stem 10, and baffle 11 is perpendicular with pushing away and keeping off hydraulic stem 10, and a side of baffle 11 is connected with pushing away and keeping off hydraulic stem 10, and another side of baffle 11 is towards cutter 8.

The baffle 11 is provided with a plurality of thorn rods 12, the thorn rods 12 are parallel to the pushing hydraulic rod 10, one end of the thorn rod 12 is connected with the other side surface of the baffle 11, and the other end of the thorn rod 12 is suspended.

As shown in fig. 3, a crushing roller 13 and a grinding roller 14 are arranged in the crushing box 3, the crushing roller is parallel to the grinding roller 14, two crushing rollers 13 and two grinding rollers 14 are respectively arranged, the crushing roller 13 is arranged above the grinding roller 14, two ends of the crushing roller 13 and two ends of the grinding roller 14 are rotatably connected with two side walls of the crushing box 3, the two crushing rollers 13 are arranged in parallel in the horizontal direction, the two grinding rollers 14 are arranged in parallel in the horizontal direction, a crushing rod 15 is arranged on the crushing roller 13, one end of the crushing rod 15 is connected with the outer side cylindrical surface of the crushing roller 13, and the other end of the crushing rod 15 is suspended.

As shown in fig. 1, the output end of the feeding conveyor belt 1 is arranged above the input end of the cutting conveyor 2, large dregs enter the cutting conveyor 2 from the feeding conveyor belt 1, the output end of the cutting conveyor 2 is arranged above the crushing box 3, the large dregs are cut and smashed when passing through the cutting conveyor 2, then the dregs come out from the cutting conveyor 2 and enter the crushing box 3 from the feed inlet above the crushing box 3, the dregs further crushed by the crushing box 3 come out from the discharge outlet of the crushing box 3, the dregs are just thick and thin, the cleaning pool 4 is arranged below the crushing box 3, the crushed dregs fall into the cleaning pool 4 for cleaning, the input end of the discharging conveyor belt 5 is arranged at the bottom of the cleaning pool 4, the output end is arranged outside the cleaning pool 4, and the dregs accumulated at the bottom of the cleaning pool 4 are sent out by the discharging conveyor belt 5.

As shown in fig. 2, the side plates 7 are mounted on two sides of the cutting conveyor belt 6, a plurality of cutting hydraulic rods 9 are arranged on the inner sides of the two side plates 7, the cutting hydraulic rods 9 are mounted on the side plates 7, the cutting hydraulic rods 9 are uniformly arranged on the two side plates 7 along the direction of the cutting conveyor belt 6, a pushing hydraulic rod 10 is arranged between the two adjacent cutting hydraulic rods 9, the pushing hydraulic rod 10 is mounted on the side plates 7, namely, the cutting hydraulic rods 9 and the pushing hydraulic rods 10 on each side plate 7 are distributed at intervals, the cutting hydraulic rods 9 and the pushing hydraulic rods 10 on the two side plates 7 are opposite one to one another, a cutter 8 is mounted on the end of each cutting hydraulic rod 9, a baffle 11 is mounted on the end of each pushing hydraulic rod 10, and a plurality of barbed rods 12 are mounted on the baffle 11.

As shown in fig. 3, two crushing rollers 13 are horizontally and parallelly mounted on the inner side of the upper end of the crushing box 3, two grinding rollers 14 are horizontally and parallelly mounted on the inner side of the lower end of the crushing box 3, the two crushing rollers 13 and the two grinding rollers 14 vertically correspond to each other, a plurality of crushing rods 15 are mounted on the cylindrical surface of the outer side of each crushing roller 13, and the crushing rods 15 on the two crushing rollers 13 are distributed in a staggered manner.

When the cutting machine is used, large pieces of muck are fed onto the cutting conveyor belt 6 from the feeding conveyor belt 1, the large pieces of muck are conveyed from the cutting conveyor belt 6 and then stop, the cutting hydraulic rod 9 drives the cutter 8 to move, the pushing hydraulic rod 10 drives the baffle 11 to move, the cutter 8 cuts the large pieces of muck, the baffle 11 blocks the large pieces of muck to prevent the large pieces of muck from sliding off, the barbed rod 12 on the baffle 11 is inserted into the large pieces of muck to decompose and break up the large pieces of muck, then the cutting hydraulic rod 9 drives the cutter 8 to withdraw, the pushing hydraulic rod 10 drives the baffle 11 to withdraw, the cutting conveyor belt 6 drives the muck to convey for a certain distance and then stop, then the muck is cut again, the cut muck is repeatedly smashed in such a way, the cut muck falls into the two smashing rollers 13 in the smashing box 3, the two smashing rollers 13 rotate oppositely, and the muck is pushed to the space between the two smashing rollers 13 through the smashing rod 15, broken dregs fall between the two grinding rollers 14, the two grinding rollers 14 rotate oppositely, the dregs are extruded between the two grinding rollers 14, and finally the dregs fall into the cleaning pool 4 and are conveyed out of the cleaning pool 4 by the discharge conveyor belt 5.

Claims (6)

1. The utility model provides a sand washing mechanism of construction waste recovery production usefulness, characterized by, includes pay-off conveyer belt (1), cutting conveyer (2), smashes case (3), washs pond (4) and exit conveyor (5), the output of pay-off conveyer belt (1) is connected with the input of cutting conveyer (2), the top of the feed inlet of smashing case (3) is arranged in to the output of cutting conveyer (2), the top of wasing pond (4) is arranged in to the discharge gate of smashing case (3), the input and the washing pond (4) of exit conveyor (5) are connected.

2. The sand washing mechanism for the construction waste recycling production according to claim 1, wherein the cutting conveyor (2) comprises a cutting conveyor belt (6), side plates (7), a cutter (8) and a plurality of cutting hydraulic rods (9), the output end of the feeding conveyor belt (1) is connected with the input end of the cutting conveyor belt (6), the output end of the cutting conveyor belt (6) is arranged above the feed port of the crushing box (3), one side plate (7) is arranged on each of two sides of the cutting conveyor belt (6), the side plates (7) are perpendicular to the belt surface of the cutting conveyor belt (6), the cutting hydraulic rods (9) are arranged on the inner sides of the two side plates (7), the cutting hydraulic rods (9) vertically penetrate through the side plates (7), one end of each cutting hydraulic rod (9) is slidably connected with the side plate (7), and the other end of each cutting hydraulic rod (9) is suspended, the cutting hydraulic rods (9) are uniformly distributed on the side plates (7) along the direction of the cutting conveyor belt (6), the cutting hydraulic rods (9) on the two side plates (7) are distributed in a staggered mode, and a cutter (8) is mounted at the other end of each cutting hydraulic rod (9).

3. The sand washing mechanism for the construction waste recycling production as claimed in claim 2, wherein the cutter (8) is arc-shaped, and the arc-shaped surface of the cutter (8) is connected with the other end of the cutting hydraulic rod (9).

4. The sand washing mechanism for the construction waste recycling production according to claim 2, wherein the cutting hydraulic rod (9) is provided with a pushing and blocking hydraulic rod (10), the axis of the pushing and blocking hydraulic rod (10) coincides with the axis of the cutting hydraulic rod (9), one end of the pushing and blocking hydraulic rod (10) is slidably connected with the side plate (7), the other end of the pushing and blocking hydraulic rod (10) is suspended, a baffle (11) is installed at the other end of the pushing and blocking hydraulic rod (10), the baffle (11) is perpendicular to the pushing and blocking hydraulic rod (10), one side face of the baffle (11) is connected with the pushing and blocking hydraulic rod (10), and the other side face of the baffle (11) faces the cutter (8).

5. The sand washing mechanism for the construction waste recycling production as claimed in claim 4, wherein a plurality of pricking rods (12) are arranged on the baffle (11), the pricking rods (12) are parallel to the pushing hydraulic rod (10), one end of each pricking rod (12) is connected with the other side surface of the baffle (11), and the other end of each pricking rod (12) is suspended.

6. The sand washing mechanism for the construction waste recycling production as claimed in claim 1, a crushing roller (13) and a grinding roller (14) are arranged in the crushing box (3), the crushing rollers (13) are parallel to the grinding rollers (14), two crushing rollers (13) and two grinding rollers (14) are arranged respectively, the crushing roller (13) is arranged above the grinding roller (14), both ends of the crushing roller (13) and both ends of the grinding roller (14) are rotatably connected with both side walls of the crushing box (3), the two crushing rollers (13) are arranged in parallel in the horizontal direction, the two grinding rollers (14) are arranged in parallel in the horizontal direction, the crushing roller (13) is provided with a crushing rod (15), one end of the crushing rod (15) is connected with the outer side cylindrical surface of the crushing roller (13), and the other end of the crushing rod (15) is suspended.

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