CN214794336U - Integral type coarse aggregate particle shape gradation analyzer - Google Patents

Abstract

The utility model belongs to the technical field of coarse aggregate proportion analysis and specifically relates to an analysis appearance is joined in marriage to integral type coarse aggregate grain shape gradation, it includes the organism, feed mechanism, aggregate shakeout mechanism, assembly line distance conveying mechanism and camera monitoring mechanism, feed mechanism installs in the organism, aggregate shakeout mechanism connects in the organism and is located feed mechanism below, assembly line distance conveying mechanism connects in the organism and is located the side below of the discharge end of aggregate shakeout mechanism, camera monitoring mechanism connects in the organism and is located assembly line distance conveying mechanism's top. This application has the effect that improves work efficiency.

Description

Integral type coarse aggregate particle shape gradation analyzer

Technical Field

The application relates to the field of coarse aggregate proportion analysis, in particular to an integrated coarse aggregate particle shape grading analyzer.

Background

Along with the development of the Chinese building industry, the requirement of the building on the grading ratio of the aggregate is more and more strict, and the grading ratio of various levels of coarse aggregates produced by the crusher needs to be calculated more quickly and accurately in a mine laboratory.

In the related technology, aggregate particle shapes are screened one by one after manual sampling, and the proportion of each grade is calculated.

For the above related technologies, the inventor thinks that manual detection, measurement and statistics require a long time, which results in a defect of low working efficiency.

SUMMERY OF THE UTILITY MODEL

In order to improve work efficiency, the application provides an integral type coarse aggregate particle shape gradation analysis appearance, adopts following technical scheme:

an integrated coarse aggregate particle size gradation analyzer comprising: organism, feed mechanism, aggregate shakeout mechanism, assembly line distance conveying mechanism and camera monitoring mechanism, feed mechanism installs in the organism, aggregate shakeout mechanism connects in the organism and is located feed mechanism below, assembly line distance conveying mechanism connects in the organism and is located the side below of the discharge end of aggregate shakeout mechanism, camera monitoring mechanism connects in the organism and is located assembly line distance conveying mechanism's top.

Through adopting above-mentioned technical scheme, the staff pours the coarse aggregate into feed mechanism, and coarse aggregate flows to the aggregate shakeouts the mechanism on, shakeouts by the aggregate shakeouts the mechanism, conveys by assembly line distance conveying mechanism again, and camera monitoring mechanism shoots monitoring, measurement and statistics when conveying, calculates all grades of ratios to shorten the time of analysis, improve work efficiency.

Optionally, aggregate shakeouts mechanism includes aggregate silo, bobbing machine and bearing subassembly, the bearing subassembly is connected in the interior bottom surface of organism, the bobbing machine is connected in the top of bearing subassembly, the aggregate silo is connected in the top of bobbing machine and is located the below of feed mechanism, the aggregate silo is slope downward setting, the discharge end of aggregate silo is close to and faces assembly line distance conveying mechanism.

Through adopting above-mentioned technical scheme, being provided with of aggregate silo does benefit to and accepts coarse aggregate, and the bobbing machine be provided with do benefit to and make the aggregate silo vibration, realize carrying out shakeout operation fast to coarse aggregate, will be shakeout simultaneously on the coarse aggregate removes to assembly line distance conveying mechanism.

Optionally, the bearing subassembly includes bearing board and spliced pole, the bottom surface is equipped with two relative bearing pieces in the organism, the bearing piece is located the below of bobbing machine, the both ends of bearing board are connected respectively in the top surface of two bearing pieces, the bottom of spliced pole is connected in the top surface of bearing board, the bobbing machine bottom is connected in the top of spliced pole.

Through adopting above-mentioned technical scheme, the setting of connecting post is favorable to bearing board and bobbing machine to be connected, and the connected mode of bearing board and two bearing blocks is favorable to when the bobbing machine during operation, and bearing board plays certain cushioning effect.

Optionally, the organism is equipped with control panel and display screen, control panel and display screen all are located the top of organism, control panel is connected with display screen, camera monitoring mechanism electricity, the display screen is connected with camera monitoring mechanism electricity.

Through adopting above-mentioned technical scheme, being provided with of control panel and display screen does benefit to the staff and carries out human-computer interaction, the control instrument of being convenient for to improve work efficiency.

Optionally, assembly line distance conveying mechanism includes drive assembly and belt line subassembly, the belt line subassembly is connected in the interior bottom surface of organism, wherein one end of belt line subassembly is located the side below of aggregate silo discharge end for order about the drive assembly that the belt line subassembly realized the distance and carries connects in the bottom of belt line subassembly.

Through adopting above-mentioned technical scheme, belt line subassembly be provided with do benefit to more conveniently carry coarse aggregate, and make coarse aggregate keep the state of shakeout, drive assembly be provided with do benefit to the work of better control belt line subassembly to work efficiency has been improved.

Optionally, the belt line subassembly includes frame, initiative cylinder, driven cylinder and conveyer belt, the frame is connected in the organism bottom surface and is close to the discharge end of aggregate silo, the initiative cylinder rotates to be connected in the frame and keeps away from the aggregate silo, driven cylinder rotates to be connected in the frame, driven cylinder is located the side below of aggregate silo discharge end, the conveyer belt cover is located between initiative cylinder and the driven cylinder, drive assembly connects in the frame and is close to the initiative cylinder, and the user orders about initiative cylinder pivoted drive assembly is connected with the initiative cylinder.

Through adopting above-mentioned technical scheme, the frame supplies initiative cylinder and driven cylinder to provide the position of installation to the one end of conveyer belt is close to the discharge end of aggregate silo, and then improves conveying efficiency, thereby improves work efficiency.

Optionally, still include aggregate recovery mechanism, the organism has seted up the discharge gate near the side of initiative cylinder, aggregate recovery mechanism connects in the frame and is close to in the initiative cylinder, aggregate recovery mechanism is and stretches out the discharge gate setting.

Through adopting above-mentioned technical scheme, aggregate recovery mechanism is concentrated the aggregate and is carried out the ejection of compact, has improved ejection of compact speed, has shortened the time of collection aggregate of repairment to improve work efficiency.

Optionally, the frame is provided with an assembly line cleaning mechanism for cleaning the conveyor belt, and the assembly line cleaning mechanism is located below the conveyor belt and is abutted against the conveyor belt.

By adopting the technical scheme, the belt is favorable for reducing attachments on the surface of the belt and reducing the influence on the photographing effect.

Drawings

Fig. 1 is a schematic structural diagram of an integral coarse aggregate particle size grading analyzer in the embodiment of the present application.

Fig. 2 is a sectional view of an integrated coarse aggregate particle size gradation analyzer in an example of the present application.

Fig. 3 is a partially enlarged schematic view of a portion a in fig. 2.

Fig. 4 is a partially enlarged schematic view of a portion B in fig. 2.

Fig. 5 is another angular cross-sectional view of an integrated coarse aggregate particle size gradation analyzer in an example of the present application.

Fig. 6 is a partially enlarged schematic view of a portion C in fig. 5.

Fig. 7 is a partially enlarged schematic view of a portion D in fig. 2.

Description of reference numerals:

1. a body; 2. a control panel; 3. a display screen; 4. a feed inlet; 5. a console; 6. a boss portion; 7. a feeding mechanism; 71. a cover plate; 711. a handle; 72. a hopper; 73. a guide tube; 8. an aggregate flattening mechanism; 81. an aggregate trough; 82. a vibrator; 83. a holding assembly; 831. a support plate; 832. connecting columns; 9. a bearing block; 10. the assembly line fixed-distance conveying mechanism; 101. a belt line assembly; 1011. a frame; 1012. a driving roller; 1013. a driven drum; 1014. a conveyor belt; 102. a drive assembly; 1021. a first motor; 1022. a first pulley module; 11. a rectangular plate; 12. a camera monitoring mechanism; 121. a computer host; 122. a shooting camera; 123. a keyboard; 124. a mouse; 13. a mounting frame; 14. a drawer; 15. a discharge port; 16. an aggregate recovery mechanism; 161. a connecting assembly; 1611. a vertical plate; 1612. a connecting plate; 162. a discharge chute; 17. an assembly line cleaning mechanism; 171. cleaning the roller; 172. a second motor; 173. a second pulley module; 18. a collection box; 19. a first door body; 20. a second door body; 21. a first heat dissipation fan; 22. a second heat dissipation fan; 23. a handrail; 24. a universal caster; 25. support the feet.

Detailed Description

The present application is described in further detail below with reference to figures 1-7.

The embodiment of the application discloses an integral type coarse aggregate particle shape gradation analysis appearance. Referring to fig. 1 and 2, an integrated coarse aggregate particle size grading analyzer comprises a machine body 1, a control panel 2, a display screen 3, a feeding mechanism 7, an aggregate flattening mechanism 8, an assembly line distance conveying mechanism 10 and a camera monitoring mechanism 12.

Referring to fig. 1 and 2, the machine body 1 is hollow, the top of the machine body 1 is provided with a feed port 4, a control console 5 and a protruding part 6, and the feed port 4, the control console 5 and the protruding part 6 are sequentially arranged along the length direction of the machine body 1. Display screen 3 is connected in the top surface of control cabinet 5, and control panel 2 installs in the side of control cabinet 5, and control panel 2 is connected with display screen 3, camera monitoring mechanism 12 electricity, and display screen 3 is connected with camera monitoring mechanism 12 electricity. The feeding mechanism 7 is installed at the feeding hole 4, and the aggregate flattening mechanism 8 is connected to the inner bottom surface of the machine body 1, is located below the feeding mechanism 7, and is used for receiving coarse aggregates flowing down from the feeding mechanism 7 and flattening the coarse aggregates. The feeding end of the aggregate flattening mechanism 8 is close to the feeding mechanism 7, and the discharging end of the aggregate flattening mechanism 8 is far away from the feeding mechanism 7. The assembly line fixed-distance conveying mechanism 10 is connected to the inner bottom surface of the machine body 1, is located below the side of the discharge end of the aggregate flattening mechanism 8, and is used for receiving the coarse aggregates falling from the discharge end of the aggregate flattening mechanism 8 and conveying the flattened coarse aggregates. Camera monitoring mechanism 12 is connected in organism 1, and the top of camera monitoring mechanism 12 is located bellying 6, and is located the top of assembly line distance conveying mechanism 10 for shoot the monitoring to the coarse aggregate that conveys.

Referring to fig. 2, the feeding mechanism 7 includes a cover plate 71, a hopper 72 and a guide pipe 73, the cover plate 71 is hinged to the feeding port 4, and a handle 711 is provided on the top surface of the cover plate 71. The top of the hopper 72 is fixed on the inner top surface of the machine body 1 and is positioned below the feed port 4. The top of stand pipe 73 communicates in the bottom of hopper 72, and stand pipe 73 is the slope setting, and the incline direction is the direction of transfer towards the aggregate, and the bottom of stand pipe 73 is close to the pan feeding end of aggregate shakeout mechanism 8 to in with coarse aggregate direction aggregate shakeout mechanism 8.

Referring to fig. 2, the aggregate flattening mechanism 8 includes an aggregate chute 81, a vibrator 82, and a support member 83, and the support member 83 is connected to the inner bottom surface of the machine body 1 and located below the guide pipe 73. The bobbing machine 82 is connected in the top of bearing subassembly 83, and aggregate silo 81 is connected in the top of bobbing machine 82 and is located the below of stand pipe 73, and aggregate silo 81 is the slope and sets up downwards, and stand pipe 73 is close to the pan feeding end of aggregate silo 81, and the discharge end of aggregate silo 81 is close to and towards assembly line distance conveying mechanism 10.

Referring to fig. 2, in order to reduce noise, a PU coating is provided on the bottom of the aggregate groove 81.

Referring to fig. 3, it should be clear that the number of the supporting members 83 in this embodiment is three. The three supporting members 83 are sequentially arranged at equal intervals along the length direction of the machine body 1. The bearing component 83 includes a bearing plate 831 and two connection posts 832, three sets of bearing blocks 9 are fixed on the inner bottom surface of the machine body 1, and each set of bearing blocks 9 is two opposite bearing blocks 9. The three sets of supporting blocks 9 are sequentially arranged at equal intervals along the length direction of the machine body 1 and are located below the supporting component 83. The three supporting plates 831 are respectively connected with the three groups of supporting blocks 9. The supporting plate 831 is horizontally disposed, and two ends of the supporting plate 831 are respectively fixed to top surfaces of two supporting blocks 9 in the same group. The bottom ends of the two connecting columns 832 are fixed to the top surface of the supporting plate 831, and the bottom of the vibrator 82 is fixed to the top ends of the six connecting columns 832.

Referring to fig. 2, the assembly line distance conveying mechanism 10 includes a driving assembly 102 and a belt line assembly 101, and the belt line assembly 101 is connected to the inner bottom surface of the machine body 1 and is located below the camera monitoring mechanism 12. One end of the belt line assembly 101 is located laterally below the discharge end of the aggregate chute 81. The driving assembly 102 is connected to the bottom of the belt line assembly 101 and is used for driving the belt line assembly 101 to realize fixed-distance conveying.

Referring to fig. 2 and 4, the belt line assembly 101 includes a frame 1011, a driving roller 1012, a driven roller 1013, and a conveyor belt 1014, wherein the bottom of the frame 1011 is fixed to the inner bottom surface of the machine body 1, and is located below the camera monitoring mechanism 12 and near the discharge end of the aggregate chute 81. The driving roller 1012 is horizontally arranged, and the driving roller 1012 is rotatably connected to the frame 1011 and is far away from the discharge end of the aggregate chute 81. The driven roller 1013 is horizontally disposed, and the driven roller 1013 is rotatably connected to the frame 1011 and located below the discharge end of the aggregate chute 81. The belt 1014 is disposed between the driving roller 1012 and the driven roller 1013, the driving assembly 102 is connected to the frame 1011 and close to the driving roller 1012, and the driving assembly 102 for driving the driving roller 1012 to rotate is connected to the driving roller 1012.

Referring to fig. 4, in order to improve the leveling effect, the conveying speed of the conveyor belt 1014 is greater than the dropping speed of the aggregates from the aggregate chute 81.

Referring to fig. 5 and 6, in order to increase the bearing force of the conveyor belt 1014 and facilitate the conveyor belt 1014 to convey aggregates, a rectangular plate 11 is arranged on the top of the frame 1011, and the rectangular plate 11 is horizontally arranged. The rectangular plate 11 is located within the conveyor belt 1014. The top surface of the rectangular plate 11 is at a distance from the conveyor belt 1014.

Referring to fig. 4, the driving assembly 102 includes a first motor 1021 and a first belt pulley module 1022, the first motor 1021 is fixed at the bottom of the frame 1011 and is close to the driving roller 1012, and the output shaft of the first motor 1021 is parallel to the driving roller 1012. The first pulley module 1022 is connected to the frame 1011 and located between the first motor 1021 and the driving roller 1012, and an output shaft of the first motor 1021 is connected to the driving roller 1012 through the first pulley module 1022 for driving the driving roller 1012 to rotate.

Referring to fig. 4 and 7, the camera monitoring mechanism 12 includes a host computer 121, a photographing camera 122, a keyboard 123, and a mouse 124. The bottom surface is equipped with mounting bracket 13 in organism 1, and mounting bracket 13 is located the below of bellying 6, and the top of mounting bracket 13 is located bellying 6. The photographing camera 122 is detachably mounted on the top of the mounting frame 13 such that the photographing camera 122 is positioned above the conveyor belt 1014. The lens of the camera 122 is directed toward the top surface of the conveyor belt 1014. The computer host 121 is connected to the inner side of the body 1 and located below the protruding portion 6.

Referring to fig. 1 and 7, the computer host 121 is electrically connected to the camera 122, the display screen 3, the control panel 2, the keyboard 123, and the mouse 124. The drawer 14 is slidably connected to one of the side surfaces of the boss portion 6 perpendicular to the aggregate conveying direction, and the keyboard 123 and the mouse 124 are placed in the drawer 14. When the analysis instrument needs to be controlled, a worker can use the keyboard 123 and the mouse 124 by pulling out the drawer 14, and simultaneously, the analysis instrument is controlled to analyze the coarse aggregate by matching with the control panel 2.

Referring to fig. 7, the photographing camera 122 is compatible with photographing dry and wet aggregates.

Referring to fig. 4, in order to facilitate the collection of coarse aggregate, a discharge port 15 is formed in a side surface of the machine body 1 close to the driving roller 1012, an aggregate recovery mechanism 16 is disposed on the machine frame 1011, the aggregate recovery mechanism 16 is close to the discharge port 15, and the aggregate recovery mechanism 16 is disposed to extend out of the discharge port 15 and is used for discharging the coarse aggregate out of the machine body 1 in a concentrated manner.

Referring to fig. 4, the aggregate recycling mechanism 16 includes a connection assembly 161 and a discharge chute 162, the connection assembly 161 is connected to the frame 1011 and close to the discharge port 15, the discharge chute 162 is inclined, and the higher end of the discharge chute 162 is connected to the connection assembly 161, and the lower end of the discharge chute 162 extends out of the discharge port 15.

Referring to fig. 4, the connecting assembly 161 includes two vertical plates 1611 and two connecting plates 1612, the two vertical plates 1611 are oppositely disposed and fixed at one end of the frame 1011 near the discharge port 15, and the driving roller 1012 is located between the two vertical plates 1611. Two connecting plates 1612 are fixed in two vertical boards 1611 respectively, and connecting plate 1612 is vertical setting and is perpendicular with vertical board 1611, and connecting plate 1612 is close to in discharge gate 15. The upper end of the discharge chute 162 is removably attached to two attachment plates 1612. The width of the discharge chute 162 is equal to the width of the conveyor belt 1014.

Referring to fig. 4, in order to reduce the adhesion on the belt surface and the influence on the photographing effect, the frame 1011 is provided with a line cleaning mechanism 17 for cleaning the conveyor belt 1014, and the line cleaning mechanism 17 is located below the conveyor belt 1014 and abuts against the conveyor belt 1014.

Referring to fig. 4 and 6, the in-line cleaning mechanism 17 includes a cleaning roller 171, a second motor 172, and a second pulley module 173, the cleaning roller 171 is horizontally disposed, and the cleaning roller 171 is rotatably connected to the frame 1011 and located below the conveyor belt 1014. The cleaning roller 171 is parallel to the driving roller 1012, and the brush of the cleaning roller 171 abuts against the belt 1014. The second motor 172 is fixed to the frame 1011, and the second motor 172 is located below the conveyor belt 1014 and near the cleaning roller 171. An output shaft of the second motor 172 is parallel to the cleaning roller 171, and the second pulley module 173 is connected between the output shaft of the second motor 172 and one end of the cleaning roller 171, and is used for driving the cleaning roller 171 to rotate by the output shaft of the second motor 172, so as to clean the surface of the conveyor belt 1014.

Referring to fig. 6, in order to collect the attachments swept off the surface of the conveyor belt 1014, a collecting box 18 is detachably attached to the bottom of the frame 1011, and the collecting box 18 is disposed to cover the cleaning roller 171.

Referring to fig. 1 and 4, the first door 19 is disposed on both sides of the machine body 1 parallel to the aggregate conveying direction, the second door 20 is disposed on a side of the machine body 1 close to the driving roller 1012, and the second door 20 is located above the discharging chute 162. The arrangement of the first door body 19 and the second door body 20 is beneficial for workers to overhaul or clean the equipment.

Referring to fig. 1 and 4, the two side surfaces of the machine body 1 parallel to the aggregate conveying direction are both provided with first cooling fans 21, and the first cooling fans 21 on the same side are located above the first door body 19 and used for cooling the inside of the machine body 1. The side of the body 1 close to the driving roller 1012 is provided with a second heat dissipation fan 22, and the second heat dissipation fan 22 is located above the second door 20 for dissipating heat from the computer host 121.

Referring to fig. 1, in order to move the analyzer, a handrail 23 is connected to a side surface close to the discharge port 15, and four casters 24 are connected to a bottom surface of the body 1, and the four casters 24 are arranged in a matrix. The bottom surface of the machine body 1 is further connected with four supporting feet 25, the four supporting feet 25 are close to four universal casters 24 respectively, the top ends of the supporting feet 25 are in threaded connection with the bottom surface of the machine body 1, and the bottom ends of the supporting feet 25 are used for abutting against the ground when the instrument is stopped and stabilized, so that the machine body 1 is supported.

The implementation principle of the integral coarse aggregate particle shape grading analyzer in the embodiment of the application is as follows: the staff removes analytical instrument to suitable position earlier, set up analytical instrument through control panel 2, keyboard 123 and mouse 124, open apron 71 again, empty the coarse aggregate in hopper 72, the coarse aggregate flows to aggregate silo 81 through stand pipe 73 on, bobbing machine 82 drives aggregate silo 81 vibration, flatten the coarse aggregate, and vibrate the coarse aggregate to conveyer belt 1014, the speed that conveyer belt 1014 transmitted is greater than the coarse aggregate speed that drops, and then realize further flattening, shoot the monitoring by shooting camera 122 again, computer 121 measures and makes statistics up, calculate all levels of ratio, the coarse aggregate is followed blown down tank 162 discharge organism 1 finally, thereby shorten the time of analysis, and the operating efficiency is improved.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides an integral type coarse aggregate particle shape gradation analysis appearance which characterized in that: including organism (1), feed mechanism (7), aggregate shakeout mechanism (8), assembly line distance conveying mechanism (10) and camera monitoring mechanism (12), install in organism (1) feed mechanism (7), aggregate shakeout mechanism (8) are connected in organism (1) and are located feed mechanism (7) below, assembly line distance conveying mechanism (10) are connected in organism (1) and are located the side below of the discharge end of aggregate shakeout mechanism (8), camera monitoring mechanism (12) are connected in organism (1) and are located the top of assembly line distance conveying mechanism (10).

2. The integrated coarse aggregate particle size gradation analyzer according to claim 1, characterized in that: aggregate shakeouts mechanism (8) and includes aggregate silo (81), bobbing machine (82) and bearing subassembly (83), interior bottom surface in organism (1) is connected in bearing subassembly (83), bobbing machine (82) are connected in the top of bearing subassembly (83), aggregate silo (81) are connected in the top of bobbing machine (82) and are located the below of feed mechanism (7), aggregate silo (81) are slope downward setting, the discharge end of aggregate silo (81) is close to and towards assembly line distance conveying mechanism (10).

3. The integrated coarse aggregate particle size gradation analyzer according to claim 2, characterized in that: bearing subassembly (83) are including bearing board (831) and spliced pole (832), the bottom surface is equipped with two relative bearing pieces (9) in organism (1), bearing piece (9) are located the below of bobbing machine (82), the both ends of bearing board (831) are connected respectively in the top surface of two bearing pieces (9), the bottom of spliced pole (832) is connected in the top surface of bearing board (831), bobbing machine (82) bottom is connected in the top of spliced pole (832).

4. The integrated coarse aggregate particle size gradation analyzer according to claim 1, characterized in that: organism (1) is equipped with control panel (2) and display screen (3), control panel (2) and display screen (3) all are located the top of organism (1), control panel (2) are connected with display screen (3), camera monitoring mechanism (12) electricity, display screen (3) are connected with camera monitoring mechanism (12) electricity.

5. The integrated coarse aggregate particle size gradation analyzer according to claim 2, characterized in that: assembly line distance conveying mechanism (10) are including drive assembly (102) and belt line subassembly (101), belt line subassembly (101) are connected in the interior bottom surface of organism (1), wherein one end of belt line subassembly (101) is located the side below of aggregate silo (81) discharge end for order about drive assembly (102) that belt line subassembly (101) realized the distance and carry are connected in the bottom of belt line subassembly (101).

6. The integrated coarse aggregate particle size gradation analyzer according to claim 5, wherein: belt line subassembly (101) includes frame (1011), driving roll (1012), driven cylinder (1013) and conveyer belt (1014), frame (1011) is connected in organism (1) bottom surface and is close to the discharge end of aggregate silo (81), driving roll (1012) rotate to be connected in frame (1011) and keep away from aggregate silo (81), driven cylinder (1013) rotate to be connected in frame (1011), driven cylinder (1013) are located the side below of aggregate silo (81) discharge end, between driving roll (1012) and driven cylinder (1013) are located to conveyer belt (1014) cover, drive assembly (102) are connected in frame (1011) and are close to driving roll (1012), and the user orders about driving roll (1012) pivoted drive assembly (102) is connected with driving roll (1012).

7. The integrated coarse aggregate particle size gradation analyzer according to claim 6, wherein: still include aggregate recovery mechanism (16), discharge gate (15) have been seted up to the side that organism (1) is close to initiative cylinder (1012), aggregate recovery mechanism (16) are connected in frame (1011) and are close to initiative cylinder (1012), aggregate recovery mechanism (16) are and stretch out discharge gate (15) and set up.

8. The integrated coarse aggregate particle size gradation analyzer according to claim 6, wherein: the machine frame (1011) is provided with a production line cleaning mechanism (17) for cleaning the conveyor belt (1014), and the production line cleaning mechanism (17) is located below the conveyor belt (1014) and is abutted to the conveyor belt (1014).

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