CN111608059A - Old and useless road cleaning equipment is used to engineering - Google Patents

Abstract

The invention relates to waste road cleaning equipment, in particular to waste road cleaning equipment for engineering, which comprises a road crushing mechanism, a conveying mechanism, a secondary crushing mechanism and an equipment moving mechanism, wherein the equipment can crush waste roads, can convey crushed materials into a crushing barrel, can secondarily crush the crushed materials into small blocks, can move forwards or backwards, is connected with the equipment moving mechanism, is connected with the conveying mechanism, and is connected with the equipment moving mechanism.

Description

Old and useless road cleaning equipment is used to engineering

Technical Field

The invention relates to waste road cleaning equipment, in particular to waste road cleaning equipment for engineering.

Background

When the waste road is cleaned, large cement concrete blocks often cannot be sufficiently crushed, but no good waste road cleaning equipment is available in the market, so the waste road cleaning equipment for engineering is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing engineering waste road cleaning equipment, the equipment can crush waste roads, the equipment can convey crushed materials into a crushing barrel, the equipment can secondarily crush the crushed materials into small blocks, and the equipment can move forwards or backwards.

In order to solve the technical problems, the invention relates to waste road cleaning equipment, in particular to engineering waste road cleaning equipment which comprises a road crushing mechanism, a conveying mechanism, a secondary crushing mechanism and an equipment moving mechanism.

The road crushing mechanism is connected with the equipment moving mechanism, the conveying mechanism is connected with the equipment moving mechanism, and the secondary crushing mechanism is connected with the equipment moving mechanism.

As a further optimization of the technical scheme, the invention relates to a waste road cleaning device for engineering, the road crushing mechanism comprises an air pump mounting plate, an air pump, an air outlet pipe, an air distribution pipe, an air inlet barrel, a sealing plate, a sliding column a, a reset spring, crushed blocks, a mode switching connecting plate a, a mode switching connecting plate b, a sliding column b, a sliding spring and a device mounting plate, the air pump mounting plate is connected with the air pump, the air pump is connected with the air outlet pipe, the air outlet pipe is connected with the air distribution pipe, the air distribution pipe is connected with the air inlet barrel, the air inlet barrel is connected with the sealing plate, the sliding plate is connected with the air inlet barrel in a sliding manner, the sliding column a is connected with the sliding plate, the reset spring is sleeved on the sliding column a and limited at the lower end table port of the sliding plate and the air inlet barrel, a crushing, mode switches connecting plate b and sliding column b sliding connection, and sliding column b is connected with the equipment mounting panel, and the slip spring housing is on sliding column b and spacing in mode switches connecting plate b and equipment mounting panel, and the equipment mounting panel is connected with the air pump mounting panel, and mode switches connecting plate a and equipment mounting panel sliding connection.

As a further optimization of the technical scheme, the invention relates to engineering waste road cleaning equipment, wherein a conveying mechanism comprises a conveying power motor, a motor shaft, a conveying belt, a conveying inclined plate, an inclined plate sliding plate, a feeding inclined plate, a conveying mounting plate a, a motor mounting plate and a conveying mounting plate b, wherein the conveying power motor is connected with the motor shaft, the motor shaft is connected with the conveying shaft, the conveying shaft is connected with the conveying belt in a sliding manner, the conveying belt is connected with the conveying inclined plate, the conveying inclined plate is connected with the inclined plate sliding plate, the inclined plate sliding plate is connected with the conveying mounting plate a, the feeding inclined plate is connected with the conveying inclined plate in a sliding manner, the conveying mounting plate a is connected with a motor shaft bearing, the motor mounting plate is connected with the conveying power motor, the conveying mounting plate b is connected with the conveying inclined plate in a sliding manner, the feeding inclined plate is connected with the conveying mounting plate a, and the feeding inclined plate is connected with the conveying mounting plate b.

As a further optimization of the technical scheme, the invention relates to waste road cleaning equipment for engineering, wherein the secondary crushing mechanism comprises an air pump mounting plate, an air pump a, an air pipe a, a rotating plate, a rotating shaft, a secondary crushing column, a connecting plate b, a connecting plate c, a connecting plate d and a crushing barrel, the air pump mounting plate is connected with the air pump a, the air pump a is connected with the air pipe a, the air pipe a is connected with the crushing barrel, the rotating plate is connected with the rotating shaft, the rotating shaft is connected with the secondary crushing column, the connecting plate a is connected with a rotating shaft bearing, the connecting plate b is connected with the rotating shaft bearing, the connecting plate c is connected with the rotating shaft bearing, the connecting plate d is connected, with rotor plate sliding connection, the air pump mounting panel is connected with connecting plate d, and connecting plate a is connected with broken bucket, and connecting plate b is connected with broken bucket, and connecting plate c is connected with broken bucket, and connecting plate d is connected with broken bucket.

As a further optimization of the technical scheme, the invention relates to a waste road cleaning device for engineering, wherein the device moving mechanism comprises a moving air inlet pipe, a moving rotating plate, a moving connecting shaft a, a moving belt a, a moving connecting shaft b, a sealing plate, a moving mounting plate a, an air outlet pipe, a moving belt b, a moving connecting shaft c, a moving mounting plate b, a cam, a moving mounting plate c, a moving mounting plate d, a moving wheel and a sealing barrel, the moving air inlet pipe is connected with the sealing barrel, the moving rotating plate is connected with the moving connecting shaft a, the moving connecting shaft a is in friction connection with the moving belt a, the moving belt a is in friction connection with the moving connecting shaft b, the moving connecting shaft b is connected with the moving wheel, the sealing plate is connected with the sealing barrel, the moving mounting plate a is connected with the sealing barrel, the air outlet pipe is connected with the, the movable connecting shaft c is connected with the movable mounting plate b through a bearing, the movable mounting plate b is connected with the movable mounting plate c, the cam is connected with the movable connecting shaft c, the movable mounting plate c is connected with the movable mounting plate d, the movable mounting plate d is connected with the movable connecting shaft b through a bearing, the movable connecting shaft a is connected with the sealing plate bearing, the movable connecting shaft a is connected with the movable mounting plate a through a bearing, and the cam is connected with the mode switching connecting plate a in a sliding mode.

As a further optimization of the technical scheme, the engineering waste road cleaning equipment is characterized in that the conveying belt is made of high-elasticity rubber.

The waste road cleaning equipment for engineering has the beneficial effects that:

according to the engineering waste road cleaning equipment, waste roads can be crushed by the equipment, crushed materials can be conveyed into the crushing barrel by the equipment, the crushed materials can be secondarily crushed into small blocks by the equipment, and the equipment can move forwards or backwards.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic structural diagram of a waste road cleaning device for engineering.

Fig. 2 is a schematic structural diagram of the waste road cleaning equipment for engineering of the invention.

Fig. 3 is a schematic structural diagram of the waste road cleaning equipment for engineering of the present invention.

Fig. 4 is a schematic structural diagram of the waste road cleaning equipment for engineering of the present invention.

Fig. 5 is a schematic structural diagram of the waste road cleaning equipment for engineering of the present invention.

Fig. 6 is a schematic structural diagram of a waste road cleaning device for engineering.

Fig. 7 is a schematic structural diagram of a waste road cleaning device for engineering.

Fig. 8 is a schematic structural diagram of a waste road cleaning device for engineering.

Fig. 9 is a schematic structural diagram of a waste road cleaning device for engineering.

Fig. 10 is a schematic structural diagram of a waste road cleaning device for engineering.

Fig. 11 is a schematic structural diagram of a waste road cleaning device for engineering.

In the figure: a road crushing mechanism 1; an air pump mounting plate 1-1; an air pump 1-2; 1-3 parts of an air outlet pipe; 1-4 of a gas distributing pipe; 1-5 parts of an air inlet barrel; sealing plates 1-6; a slide plate 1-7; sliding column a 1-8; 1-9 of a return spring; 1-10 parts of a crushing block; mode switching connection board a 1-11; a mode switching connection board b 1-12; sliding column b 1-13; sliding springs 1-14; equipment mounting plates 1-15; a conveying mechanism 2; a transmission power motor 2-1; a motor shaft 2-2; a transmission shaft 2-3; 2-4 of a conveyor belt; a transmission sloping plate 2-5; an inclined plate sliding plate 2-6; a feeding inclined plate 2-7; a transfer installation plate a 2-8; 2-9 parts of a motor mounting plate; the delivery mounting plate b 2-10; a secondary crushing mechanism 3; an air pump mounting plate 3-1; an air pump a 3-2; trachea a 3-3; rotating a plate 3-4; 3-5 of a rotating shaft; 3-6 parts of a secondary crushing column; connecting plate a 3-7; connecting plate b 3-8; connecting plate c 3-9; connecting plate d 3-10; 3-11 parts of a crushing barrel; an apparatus moving mechanism 4; a movable air inlet pipe 4-1; moving the rotating plate 4-2; the movable connecting shaft a 4-3; a moving belt a 4-4; the movable connecting shaft b 4-5; 4-6 of a sealing plate; moving the mounting plate a 4-7; 4-8 parts of an air outlet pipe; a moving belt b 4-9; the movable connecting shaft c 4-10; the movable mounting plate b 4-11; 4-12 of a cam; moving the mounting plate c 4-13; moving the mounting plate d 4-14; 4-15 of moving wheels; and sealing barrels 4-16.

Detailed Description

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, and fig. 11, the present invention relates to a waste road cleaning apparatus, and more specifically, to a waste road cleaning apparatus for engineering, including a road crushing mechanism 1, a conveying mechanism 2, a secondary crushing mechanism 3, and an apparatus moving mechanism 4, the apparatus being capable of crushing a waste road, the apparatus being capable of conveying crushed materials into a crushing barrel, the apparatus being capable of secondarily crushing the crushed materials into small pieces, and the apparatus being capable of moving forward or backward.

The road crushing mechanism 1 is connected with the equipment moving mechanism 4, the conveying mechanism 2 is connected with the equipment moving mechanism 4, and the secondary crushing mechanism 3 is connected with the equipment moving mechanism 4.

The second embodiment is as follows:

the present embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, and fig. 11, and the present embodiment further describes the present embodiment, where the road breaking mechanism 1 includes an air pump mounting plate 1-1, an air pump 1-2, an air outlet pipe 1-3, an air distribution pipe 1-4, an air inlet barrel 1-5, a sealing plate 1-6, a sliding plate 1-7, a sliding column a1-8, a return spring 1-9, a breaking block 1-10, a mode switching connecting plate a1-11, a mode switching connecting plate 1-12, a sliding column b1-13, a sliding spring 1-14, and an equipment mounting plate 1-15, the air pump mounting plate 1-1 is connected to the air pump 1-2, the air pump 1-2 is connected to the air outlet pipe 1-3, an air outlet pipe 1-3 is connected with an air distribution pipe 1-4, the air distribution pipe 1-4 is connected with an air inlet barrel 1-5, the air inlet barrel 1-5 is connected with a sealing plate 1-6, a sliding plate 1-7 is slidably connected with the air inlet barrel 1-5, a sliding column a1-8 is connected with the sliding plate 1-7, a reset spring 1-9 is sleeved on the sliding column a1-8 and limited at the lower port of the sliding plate 1-7 and the air inlet barrel 1-5, broken pieces 1-10 are connected with the sliding column a1-8, a mode switching connecting plate a1-11 is connected with a mode switching connecting plate b1-12, a mode switching connecting plate b1-12 is slidably connected with the sliding column b1-13, a sliding column b1-13 is connected with an equipment mounting plate 1-15, a sliding spring 1-14 is sleeved on the sliding column b1-13 and limited at the mode switching connecting plate b1-12 and the connecting plate b1- The device mounting plates 1-15, the device mounting plates 1-15 are connected with the air pump mounting plate 1-1, and the mode switching connecting plate a1-11 is connected with the device mounting plates 1-15 in a sliding mode.

The third concrete implementation mode:

the present embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, and fig. 11, and the present embodiment further describes the present embodiment, where the conveyor mechanism 2 includes a conveying power motor 2-1, a motor shaft 2-2, a conveying shaft 2-3, a conveyor belt 2-4, a conveying inclined plate 2-5, an inclined plate sliding plate 2-6, a feeding inclined plate 2-7, a conveying mounting plate a2-8, a motor mounting plate 2-9, a conveying mounting plate b2-10, the conveying power motor 2-1 is connected to the motor shaft 2-2, the motor shaft 2-2 is connected to the conveying shaft 2-3, the conveying shaft 2-3 is slidably connected to the conveyor belt 2-4, the conveyor belt 2-4 is connected to the conveying inclined plate 2-5, the conveying inclined plate 2-5 is connected with the inclined plate sliding plate 2-6 in a sliding mode, the inclined plate sliding plate 2-6 is connected with the conveying installation plate a2-8, the feeding inclined plate 2-7 is connected with the conveying inclined plate 2-5 in a sliding mode, the conveying installation plate a2-8 is connected with a motor shaft 2-2 bearing, the motor installation plate 2-9 is connected with the conveying power motor 2-1, the conveying installation plate b2-10 is connected with the conveying inclined plate 2-5 in a sliding mode, the conveying belt 2-4 is connected with the installation plate a2-8 in a sliding mode, the conveying inclined plate 2-5 is connected with the installation plate a2-8 in a sliding mode, the feeding inclined plate 2-7 is connected with the conveying installation plate a2-8, and the feeding inclined plate 2-7.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, and fig. 11, and the embodiment will be further described, where the secondary crushing mechanism 3 includes an air pump mounting plate 3-1, an air pump a3-2, an air pipe a3-3, a rotating plate 3-4, a rotating shaft 3-5, a secondary crushing column 3-6, a connecting plate b3-8, a connecting plate c3-9, a connecting plate d3-10, a crushing barrel 3-11, an air pump mounting plate 3-1 connected to an air pump a3-2, an air pump a3-2 connected to an air pipe a3-3, an air pipe a3-3 connected to a crushing barrel 3-11, a rotating plate 3-4 connected to a rotating shaft 3-5, a rotating shaft 3-5 connected to a secondary crushing column 3-6, the connecting plate a3-7 is connected with a rotating shaft 3-5 through a bearing, the connecting plate b3-8 is connected with a rotating shaft 3-5 through a bearing, the connecting plate c3-9 is connected with a rotating shaft 3-5 through a bearing, the connecting plate d3-10 is connected with the connecting plate a3-7 and is in sliding connection with the rotating plate 3-4, the air pump mounting plate 3-1 is connected with the connecting plate d3-10, the connecting plate a3-7 is connected with the crushing barrel 3-11, the connecting plate b3-8 is connected with the crushing barrel 3-11, the connecting plate c3-9 is connected with the crushing barrel 3-11, and the connecting plate d3-10 is connected with the crushing barrel 3-11.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, and fig. 11, and the embodiment is further described, where the apparatus moving mechanism 4 includes a moving air inlet pipe 4-1, a moving rotating plate 4-2, a moving connecting shaft a4-3, a moving belt a4-4, a moving connecting shaft b4-5, a sealing plate 4-6, a moving mounting plate a4-7, an air outlet pipe 4-8, a moving belt b4-9, a moving connecting shaft c4-10, a moving mounting plate b4-11, a cam 4-12, a moving mounting plate c4-13, a moving mounting plate d4-14, a moving wheel 4-15, and a sealing barrel 4-16, the moving air inlet pipe 4-1 is connected to the sealing barrel 4-16, the movable rotating plate 4-2 is connected with a movable connecting shaft a4-3, the movable connecting shaft a4-3 is in frictional connection with a movable belt a4-4, the movable belt a4-4 is in frictional connection with a movable connecting shaft b4-5, the movable connecting shaft b4-5 is connected with a movable wheel 4-15, the sealing plate 4-6 is connected with the sealing barrel 4-16, the movable mounting plate a4-7 is connected with the sealing plate 4-6, the air outlet pipe 4-8 is connected with the sealing barrel 4-16, the movable belt b4-9 is connected with a movable connecting shaft c4-10, the movable connecting shaft c4-10 is in bearing connection with a movable mounting plate b4-11, the movable mounting plate b4-11 is connected with a movable mounting plate c4-13, the cam 4-12 is connected with a movable connecting shaft c4-10, the movable mounting plate c4-13 is connected with a movable mounting plate d4-14, the movable mounting plate d4-14 is connected with a movable connecting shaft b4-5 through a bearing, the movable connecting shaft a4-3 is connected with a sealing plate 4-6 through a bearing, the movable connecting shaft a4-3 is connected with a movable mounting plate a4-7 through a bearing, a cam 4-12 is connected with a mode switching connecting plate a1-11 in a sliding mode, the waste road can be broken through equipment, the air pump 1-2 works, the air pump 1-2 blows air into the air inlet barrel 1-5 through the air outlet pipe 1-3 and the air distribution pipe 1-4, the air pressure sliding plate in the air inlet barrel 1-5 forces 1-7 and the sliding column a1-8 to enable the sliding plate 1-7 and the sliding column a1-8 to move downwards, and the sliding plate 1-7 and the sliding column a1-8 drive the broken fragments to move downwards when moving downwards, when the broken pieces 1-10 move downwards, the waste pavement is broken, the equipment can convey the broken materials into a breaking barrel, a conveying power motor 2-1 rotates, the conveying power motor 2-1 rotates to drive a motor shaft 2-2, the motor shaft 2-2 rotates to drive a conveying shaft 2-3 to rotate, the conveying shaft 2-3 rotates to drive the conveying shaft 2-3 to rotate, the conveying shaft 2-3 rotates to drive a conveying belt 2-4 to move upwards or downwards, when the conveying belt 2-4 moves upwards, a conveying inclined plate 2-5 moves upwards, the broken materials when the equipment moves forwards are conveyed to an inclined plate sliding plate 2-6 through a feeding inclined plate 2-7, the conveying inclined plate 2-5 is conveyed to the inclined plate sliding plate 2-6 and is inclined into the breaking barrel 3-11 through the inclined plate sliding plate 2-6, the equipment can crush crushed materials into small blocks for the second time, the air pump a3-2 works to blow air into a space formed by the crushing barrel 3-11, the connecting plate a3-7 and the connecting plate b3-8 through the air pipe a3-3, the air blows the rotating plate 3-4 to rotate in the space, the rotating plate 3-4 rotates to drive the rotating shaft 3-5 to rotate, the rotating shaft 3-5 rotates to drive the secondary crushing column 3-6 to rotate, the secondary crushing column 3-6 rotates to crush the materials conveyed into the crushing barrel 3-11 for the second time, the equipment can move forwards or backwards, the air pump a3-2 blows the rotating plate 3-4 to rotate the rotating plate 3-4, the rotating plate 3-4 rotates to transmit the air into the moving plate 4-1, and the moving air inlet pipe 4-1 blows the air into a space formed by the sealing plate 4-6 and the sealing barrel 4-16 In the device, the gas blows the movable rotating plate 4-2 to make the movable rotating plate 4-2 rotate by taking the movable connecting shaft a4-3 as an axis, the movable connecting shaft a4-3 rotates by driving the movable belt a4-4 to move the connecting shaft b4-5 to rotate, the movable connecting shaft b4-5 rotates to drive the movable wheel 4-15 to rotate, the movable wheel 4-15 rotates to make the equipment box move forwards or backwards, the movable connecting shaft a4-3 rotates and simultaneously drives the movable connecting shaft c4-10 to rotate by driving the movable belt b4-9, the movable connecting shaft c4-10 rotates to drive the cam 4-12 to rotate, the cam 4-12 rotates to press the mode switching connecting plate a1-11 and reciprocates up and down under the action of the sliding spring 1-14, and when the mode switching connecting plate a1-11 moves downwards, the mode switching connecting plate a1-11 is connected with the circular hole 1 of the air outlet pipe 3, the air of the air pump 1-2 can be blown into the air distribution pipe 1-4, and the broken blocks 1-10 reciprocate up and down when reciprocating, thereby further increasing the function of breaking waste roads.

The sixth specific implementation mode:

the following describes the embodiment with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, and fig. 11, and the embodiment further describes the first embodiment, in which the material of the conveyor belt 2-4 is high-elasticity rubber.

The working principle of the device is as follows: the equipment can crush the waste roads, the air pump 1-2 works, the air pump 1-2 blows air into the air inlet barrel 1-5 through the air outlet pipe 1-3 and the air distribution pipe 1-4, the air pressure in the air inlet barrel 1-5 forces the sliding plate 1-7 and the sliding column a1-8 to enable the sliding plate 1-7 and the sliding column a1-8 to move downwards, the sliding plate 1-7 and the sliding column a1-8 drive the crushed pieces 1-10 to move downwards when moving downwards, the waste roads are crushed when the crushed pieces 1-10 move downwards, the equipment can convey the crushed materials into the crushing barrel, the conveying power motor 2-1 rotates to drive the motor shaft 2-2, the motor shaft 2-2 rotates to drive the conveying shaft 2-3 to rotate, the conveying shaft 2-3 rotates to drive the conveying shaft 2-3 to rotate, the conveying shaft 2-3 rotates to drive the conveying belt 2-4 to move upwards or downwards, when the conveying belt 2-4 moves upwards, the conveying inclined plate 2-5 moves upwards, when equipment moves forwards, the crushed materials pass through the feeding inclined plate 2-7 and are conveyed to the inclined plate sliding plate 2-6 through the conveying inclined plate 2-5 and are inclined into the crushing barrel 3-11 through the inclined plate sliding plate 2-6, the equipment can crush the crushed materials into small blocks for the second time, the air pump a3-2 works to blow air into a space formed by the crushing barrel 3-11, the connecting plate a3-7 and the connecting plate b3-8 through the air pipe a3-3, the air blows the rotating plate 3-4 to rotate in the space, the rotating plate 3-4 rotates to drive the rotating shaft 3-5 to rotate, the rotating shaft 3-5 rotates to drive the secondary crushing column 3-6 to rotate, the secondary crushing column 3-6 rotates to crush the materials conveyed into the crushing barrel 3-11 for the second time, the equipment can move forwards or backwards, the air pump a3-2 blows the rotating plate 3-4 to rotate the rotating plate 3-4, the rotating plate 3-4 rotates to transfer air into the moving air inlet pipe 4-1, the moving air inlet pipe 4-1 blows air into a space formed by the sealing plate 4-6 and the sealing barrel 4-16, the air blows the moving rotating plate 4-2 to enable the moving rotating plate 4-2 to rotate by taking the moving connecting shaft 4-3 as a shaft, the moving connecting shaft a4-3 rotates by driving the moving belt a4-4 to move the connecting shaft b4-5 to rotate, the movable connecting shaft b4-5 rotates to drive the movable wheels 4-15 to rotate, the movable wheels 4-15 rotate to enable the equipment box to move forwards or backwards, the movable connecting shaft a4-3 rotates and drives the movable connecting shaft c4-10 to rotate by driving the movable belt b4-9, the movable connecting shaft c4-10 rotates to drive the cam 4-12 to rotate, the cam 4-12 rotates to press the mode switching connecting plate a1-11 and reciprocates up and down under the action of the sliding spring 1-14, when the mode switching connection plate a1-11 moves downwards, the round hole on the mode switching connection plate a1-11 is matched with the air outlet pipe 1-3, the air of the air pump 1-2 can be blown into the air outlet pipe 1-4, when reciprocating, the crushing blocks 1-10 reciprocate up and down, thereby further increasing the function of crushing the waste roads.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which can be made by those skilled in the art are also within the scope of the present invention.

Claims (6)

1. The utility model provides an old and useless road cleaning equipment is used to engineering, includes broken mechanism of road (1), transport mechanism (2), secondary crushing mechanism (3), equipment moving mechanism (4), its characterized in that: the road crushing mechanism (1) is connected with the equipment moving mechanism (4), the conveying mechanism (2) is connected with the equipment moving mechanism (4), and the secondary crushing mechanism (3) is connected with the equipment moving mechanism (4).

2. The engineering waste road cleaning equipment as claimed in claim 1, characterized in that: the road crushing mechanism (1) comprises an air pump mounting plate (1-1), an air pump (1-2), an air outlet pipe (1-3), an air distribution pipe (1-4), an air inlet barrel (1-5), a sealing plate (1-6), a sliding plate (1-7), a sliding column a (1-8), a return spring (1-9), crushed blocks (1-10), a mode switching connecting plate a (1-11), a mode switching connecting plate b (1-12), a sliding column b (1-13), a sliding spring (1-14) and an equipment mounting plate (1-15), wherein the air pump mounting plate (1-1) is connected with the air pump (1-2), the air pump (1-2) is connected with the air outlet pipe (1-3), and the air outlet pipe (1-3) is connected with the air distribution pipe (1-4), the gas distribution pipe (1-4) is connected with the gas inlet barrel (1-5), the gas inlet barrel (1-5) is connected with the sealing plate (1-6), the sliding plate (1-7) is connected with the gas inlet barrel (1-5) in a sliding way, the sliding column a (1-8) is connected with the sliding plate (1-7), the reset spring (1-9) is sleeved on the sliding column a (1-8) and limited at the lower port of the sliding plate (1-7) and the gas inlet barrel (1-5), the broken block (1-10) is connected with the sliding column a (1-8), the mode switching connecting plate a (1-11) is connected with the mode switching connecting plate b (1-12), the mode switching connecting plate b (1-12) is connected with the sliding column b (1-13) in a sliding way, the sliding column b (1-13) is connected with the equipment mounting plate (1-15), the sliding springs (1-14) are sleeved on the sliding columns b (1-13) and limited on the mode switching connecting plates b (1-12) and the equipment mounting plates (1-15), the equipment mounting plates (1-15) are connected with the air pump mounting plates (1-1), and the mode switching connecting plates a (1-11) are connected with the equipment mounting plates (1-15) in a sliding mode.

3. The engineering waste road cleaning equipment as claimed in claim 1, characterized in that: the conveying mechanism (2) comprises a conveying power motor (2-1), a motor shaft (2-2), a conveying shaft (2-3), a conveying belt (2-4), a conveying inclined plate (2-5), an inclined plate sliding plate (2-6), a feeding inclined plate (2-7), a conveying mounting plate a (2-8), a motor mounting plate (2-9) and a conveying mounting plate b (2-10), wherein the conveying power motor (2-1) is connected with the motor shaft (2-2), the motor shaft (2-2) is connected with the conveying shaft (2-3), the conveying shaft (2-3) is connected with the conveying belt (2-4) in a sliding manner, the conveying belt (2-4) is connected with the conveying inclined plate (2-5), and the conveying inclined plate (2-5) is connected with the inclined plate sliding plate (2-6) in a sliding manner, the inclined plate sliding plate (2-6) is connected with a conveying installation plate a (2-8), the feeding inclined plate (2-7) is connected with a conveying inclined plate (2-5) in a sliding mode, the conveying installation plate a (2-8) is connected with a motor shaft (2-2) through a bearing, a motor installation plate (2-9) is connected with a conveying power motor (2-1), a conveying installation plate b (2-10) is connected with the conveying inclined plate (2-5) in a sliding mode, a conveying belt (2-4) is connected with the installation plate a (2-8) in a sliding mode, the conveying inclined plate (2-5) is connected with the installation plate a (2-8) in a sliding mode, the feeding inclined plate (2-7) is connected with the conveying installation plate a (2-8), and the feeding inclined plate (2-7) is connected with the conveying installation plate b (2-.

4. The engineering waste road cleaning equipment as claimed in claim 1, characterized in that: the secondary crushing mechanism (3) comprises an air pump mounting plate (3-1), an air pump a (3-2), an air pipe a (3-3), a rotating plate (3-4), a rotating shaft (3-5), a secondary crushing column (3-6), a connecting plate a (3-7), a connecting plate b (3-8), a connecting plate c (3-9), a connecting plate d (3-10) and a crushing barrel (3-11), wherein the air pump mounting plate (3-1) is connected with the air pump a (3-2), the air pump a (3-2) is connected with the air pipe a (3-3), the air pipe a (3-3) is connected with the crushing barrel (3-11), the rotating plate (3-4) is connected with the rotating shaft (3-5), and the rotating shaft (3-5) is connected with the secondary crushing column (3-6), the connecting plate a (3-7) is connected with the rotating shaft (3-5) through a bearing, the connecting plate b (3-8) is connected with the rotating shaft (3-5) through a bearing, the connecting plate c (3-9) is connected with the rotating shaft (3-5) through a bearing, the connecting plate d (3-10) is connected with the connecting plate a (3-7) and is connected with the rotating plate (3-4) in a sliding mode, the air pump mounting plate (3-1) is connected with the connecting plate d (3-10), the connecting plate a (3-7) is connected with the crushing barrel (3-11), the connecting plate b (3-8) is connected with the crushing barrel (3-11), the connecting plate c (3-9) is connected with the crushing barrel (3-11), and the connecting plate d (3-10) is connected with the crushing barrel (3-11).

5. The engineering waste road cleaning equipment as claimed in claim 1, characterized in that: the equipment moving mechanism (4) comprises a moving air inlet pipe (4-1), a moving rotating plate (4-2), a moving connecting shaft a (4-3), a moving belt a (4-4), a moving connecting shaft b (4-5), a sealing plate (4-6), a moving mounting plate a (4-7), an air outlet pipe (4-8), a moving belt b (4-9), a moving connecting shaft c (4-10), a moving mounting plate b (4-11), a cam (4-12), a moving mounting plate c (4-13), a moving mounting plate d (4-14), a moving wheel (4-15) and a sealing barrel (4-16), wherein the moving air inlet pipe (4-1) is connected with the sealing barrel (4-16), the moving rotating plate (4-2) is connected with the moving connecting shaft a (4-3), the movable connecting shaft a (4-3) is in friction connection with the movable belt a (4-4), the movable belt a (4-4) is in friction connection with the movable connecting shaft b (4-5), the movable connecting shaft b (4-5) is connected with the movable wheel (4-15), the sealing plate (4-6) is connected with the sealing barrel (4-16), the movable mounting plate a (4-7) is connected with the sealing plate (4-6), the air outlet pipe (4-8) is connected with the sealing barrel (4-16), the movable belt b (4-9) is connected with the movable connecting shaft c (4-10), the movable connecting shaft c (4-10) is in bearing connection with the movable mounting plate b (4-11), the movable mounting plate b (4-11) is connected with the movable mounting plate c (4-13), and the cam (4-12) is connected with the movable connecting shaft c (4-10), the movable mounting plate c (4-13) is connected with the movable mounting plate d (4-14), the movable mounting plate d (4-14) is in bearing connection with the movable connecting shaft b (4-5), the movable connecting shaft a (4-3) is in bearing connection with the sealing plate (4-6), the movable connecting shaft a (4-3) is in bearing connection with the movable mounting plate a (4-7), and the cam (4-12) is in sliding connection with the mode switching connecting plate a (1-11).

6. The engineering waste road cleaning equipment as claimed in claim 1, characterized in that: the material of the conveyor belt (2-4) is high-elastic rubber.

Images