CN114471938A - Solar photovoltaic glass production equipment and production process - Google Patents

Abstract

The invention belongs to the technical field of photovoltaic glass production, and particularly relates to solar photovoltaic glass production equipment and a production process, aiming at the technical problems that most silica sand magnetic separation devices for solar photovoltaic glass production in the current market are poor in screening effect and low in removal rate of magnetic impurities, the solar photovoltaic glass production equipment comprises a box body, wherein a feeding channel is fixedly connected to the top of the box body, a feeding mechanism is arranged on the inner wall of the feeding channel, a discharging plate is fixedly connected to the bottom of the feeding mechanism, and the discharging plate is in a circular truncated cone shape. According to the silicon sand screening device, the silicon sand can be guided into the material throwing box through the material guide plate, the silicon sand in the material throwing box can be thrown out from the discharge chute at the bottom through the driving mechanism, the silicon sand can be subjected to rotary magnetic attraction treatment through the rotary magnetic attraction mechanism, the silicon sand can be subjected to screening treatment through the screening box, and the final silicon sand can be collected through the material collecting mechanism.

Description

Solar photovoltaic glass production equipment and production process

Technical Field

The invention relates to the technical field of photovoltaic glass production, in particular to solar photovoltaic glass production equipment and a production process.

Background

The solar photovoltaic glass consists of low-iron glass, a solar cell piece, a film, back glass, a special metal wire and the like, wherein the solar cell piece is sealed between the low-iron glass and the back glass through the film, and the solar photovoltaic glass is the most novel high-tech glass product for buildings. The solar photovoltaic glass is covered on the solar cell by low-iron glass so as to ensure that more light rays are transmitted and more electric energy is generated. The low-iron glass after being toughened has higher strength and can bear larger wind pressure and larger day and night temperature difference change.

Silica sand needs to be used in present solar photovoltaic glass production, but often sneak into magnetic impurity in the silica sand, if do not clean up these impurity in production, can influence follow-up operation, also can influence photovoltaic glass's quality, silica sand magnetic separation device is used in solar photovoltaic glass production on the market at present, it is not good that most screening effect is not, and magnetic impurity's clearance is not high, so proposes a silica sand magnetic separation device for solar photovoltaic glass production and solves foretell problem.

Disclosure of Invention

Based on the technical problems that most silica sand magnetic separation devices for solar photovoltaic glass production in the market are poor in screening effect and low in removal rate of magnetic impurities, the invention provides solar photovoltaic glass production equipment and a production process.

The invention provides solar photovoltaic glass production equipment and a production process, which comprises a box body, wherein the top of the box body is fixedly connected with a feeding channel, the inner wall of the feeding channel is provided with a feeding mechanism, the bottom of the feeding mechanism is fixedly connected with a discharging plate, the discharging plate is arranged in a round table shape, the bottom of the discharging plate is provided with a processing tank, the inner wall of the processing tank is provided with a multilayer magnetic suction mechanism, the bottom of the inner wall of the processing tank is provided with a material guide plate, the material guide plate is fixedly connected with a rotating shaft, the top of the rotating shaft is fixedly connected with the discharging plate, the bottom of the rotating shaft is fixedly connected with a motor, the bottom of the material guide plate is provided with a material throwing box, the outer wall of the material throwing box is provided with a driving mechanism, the bottom of the material throwing box is fixedly connected with a discharging tank, the bottom of the discharging tank is provided with a rotating magnetic suction mechanism, the rotating magnetic suction mechanism is provided with a screening box, a plurality of sieve meshes have been seted up to screening bottom of the case portion outer wall, screening bottom of the case portion is provided with the mechanism that gathers materials.

Preferably, the feeding mechanism comprises a material guiding channel and a vertical rod, the outer wall of the material feeding channel is fixedly connected with a plurality of supporting rods, the bottom of each supporting rod is fixedly connected with the box body, the bottom of the material feeding channel is rotatably connected with the material guiding channel, the bottom of the material guiding channel is fixedly connected with the material discharging plate, the rotating shaft and the vertical rod are hollow, the vertical rod is fixedly connected with the top of the rotating shaft, the inner wall of the material feeding channel is provided with a plurality of second scraping plates, one end of each second scraping plate is fixedly connected with a third connecting rod, the other end of each third connecting rod is fixedly connected with the vertical rod, the inner wall of the material guiding channel is provided with a plurality of breathable net covers, the breathable net covers are fixedly connected with the vertical rods, the inner wall of each breathable net cover is provided with a material sucking pipe, the material sucking pipe is fixedly connected with the vertical rod, the bottom of the rotating shaft is rotatably connected with a transfer box, the bottom of the transfer box is fixedly connected with the inner wall of the box body, the bottom of the box body is fixedly connected with a dust sucking mechanism, the dust sucking mechanism is fixedly connected with a plurality of material guiding pipes, the passage other end and transfer box fixed connection, a plurality of through-holes have been seted up to the axis of rotation outer wall, and the through-hole is located the transfer box.

Preferably, the mechanism is inhaled to multilayer magnetism includes first magnetic sheet and first scraper blade, a plurality of baffles of treatment trough inner wall fixedly connected with, the baffle sets up to the array from last down distributing, and be provided with the space between the coplanar baffle, first magnetic sheet respectively with baffle both ends outer wall fixed connection, first scraper blade is located between the baffle, first scraper blade and treatment trough inner wall natural contact, first scraper blade other end fixedly connected with second connecting rod, the second connecting rod other end and axis of rotation fixed connection, treatment trough outer wall top fixedly connected with movable block, the activity groove has been seted up to the box inner wall, the movable block is located the activity inslot, a plurality of first springs of fixedly connected with between movable block and the activity groove, a plurality of vibrating motor of treatment trough bottom outer wall fixedly connected with.

Preferably, actuating mechanism is including rotating wheel and clutch blocks, the clutch blocks with get rid of workbin outer wall fixed connection, and be the annular, the scarce groove has all been seted up at box inner wall both ends, it is located the scarce inslot to rotate the wheel, it contacts with the clutch blocks naturally to rotate wheel and friction blocks, it drives pole to rotate wheel bottom fixedly connected with, it is connected with the belt to drive pole bottom one end transmission, the belt other end passes the transfer box and is connected with rotation axis transmission, transfer incasement wall fixedly connected with plywood, the belt is located the plywood top, get rid of workbin top outer wall fixedly connected with baffle, the baffle sets up to the annular.

Preferably, rotate magnetism and inhale mechanism and include first frame and second frame, first frame and second frame respectively with axis of rotation both ends outer wall fixed connection, first frame and second frame inner wall rotate and are connected with a plurality of movable rods, movable rod outer wall fixedly connected with second magnetic sheet, the movable rod sets up to horizontal in the first frame, the movable rod sets up to vertical in the second frame.

Preferably, screening incasement wall is provided with a plurality of puddlers, puddler top fixedly connected with dwang, dwang and axis of rotation fixed connection, and the axis of rotation passes the screening case, a plurality of second springs of screening bottom of the case portion fixedly connected with, second spring bottom fixedly connected with fixed plate, fixed plate and box inner wall fixed connection.

Preferably, the mechanism of gathering materials includes bottom plate and collecting tank, bottom plate and axis of rotation fixed connection, and the bottom plate sets up to coniform, and a plurality of discharge gates have been seted up to the box outer wall, and a plurality of fixed magnet poles of discharge gate inner wall fixedly connected with, discharge gate are located bottom plate outer wall, collecting tank and box outer wall fixed connection, and collecting tank sets up to the annular, and collecting tank is located discharge gate other end bottom.

Preferably, puddler and dwang all set up to cavity, puddler inner wall fixedly connected with dead lever, dead lever bottom fixedly connected with third spring, third spring bottom fixedly connected with movable ball, and movable ball external diameter and puddler internal diameter are the same, and puddler inner wall both ends are all seted up flutedly, and the recess is located the movable ball top.

Preferably, the top of the bottom plate is fixedly connected with a first connecting rod, the top of the first connecting rod is fixedly connected with a ball, the other end of the top of the ball is provided with a driving plate, and the top of the driving plate is fixedly connected with the bottom of the screening box.

A solar photovoltaic glass production process adopts the solar photovoltaic glass production equipment, and comprises the following process steps:

s1, introducing silica sand into the feeding channel, guiding the silica sand into the discharging plate through the conveying of the material guiding channel, driving the discharging plate to rotate through a rotating shaft by arranging a motor, and collecting the silica sand to be thrown out from the edge of the outer wall;

s2, allowing silica sand to enter the treatment tank from the top edge of the treatment tank, performing magnetic absorption treatment on the silica sand passing through the treatment tank by using a first magnetic plate on the outer wall through a plurality of partition plates arranged in the treatment tank, scraping the silica sand between the partition plates by using a first scraper connected with a second connecting rod through a rotating shaft, and promoting the silica sand to sequentially move downwards through gaps between the partition plates, so that the aim of multilayer magnetic absorption treatment is fulfilled;

s3, guiding the silica sand flowing down from the processing tank by using a guide plate to enable the silica sand to enter a material throwing box, limiting the silica sand by arranging a baffle plate, and enabling the material throwing box and a rotating shaft to rotate oppositely by arranging a driving mechanism to enable the silica sand entering the material throwing box to be evenly thrown out from a discharge tank at the bottom;

s4, the first frame and the second frame are driven to rotate by the rotating shaft, so that the thrown silica sand can be subjected to rotary magnetic absorption treatment by the second magnetic plate connected by the movable rod inside, and the magnetic absorption range and effect of the silica sand are ensured by arranging the movable rods in the first frame and the second frame to be horizontal and vertical;

s5, screening the silica sand by using the screen holes at the bottom of the screening box, and driving the rotating rod to rotate by using the rotating shaft so as to stir the silica sand by using the stirring rod at the bottom and improve the screening effect;

and S6, driving the bottom plate to rotate through the rotating shaft, so that the silica sand on the top of the bottom plate is subjected to centrifugal force and thrown out from the edge of the bottom plate, and finally thrown into the material collecting groove from a discharge port formed in the box body, and finally performing magnetic absorption treatment on the silica sand through the fixed magnetic rod arranged in the discharge port.

Compared with the prior art, the invention provides solar photovoltaic glass production equipment and a production process, and the solar photovoltaic glass production equipment and the production process have the following beneficial effects:

this solar photovoltaic glass production facility and production technology, can be with inside the silica sand is leading-in to the box through setting up feedstock channel and inside feed mechanism, inhale the mechanism through the multilayer magnetism that sets up in the treatment trough and can carry out multilayer magnetism to the silica sand and inhale the processing, can be with leading-in to get rid of the workbin with the silica sand through setting up the stock guide, can make the silica sand that gets rid of in the workbin throw away from the blown down tank of bottom through setting up actuating mechanism, inhale the mechanism through setting up rotation magnetism and can rotate magnetism to the silica sand and inhale the processing, can carry out screening process to the silica sand through setting up the screening case, can collect final silica sand through setting up the mechanism that gathers materials.

Drawings

FIG. 1 is a schematic cross-sectional structure diagram of a solar photovoltaic glass production apparatus according to the present invention;

FIG. 2 is a schematic cross-sectional view of a feeding mechanism of a solar photovoltaic glass production apparatus according to the present invention;

FIG. 3 is a schematic structural diagram of a feeding mechanism of a solar photovoltaic glass production apparatus according to the present invention;

FIG. 4 is a schematic view of a partial cross-sectional structure of a material throwing box of the solar photovoltaic glass production equipment provided by the invention;

FIG. 5 is a schematic view of the main structure of a material throwing box of the solar photovoltaic glass production equipment provided by the invention

FIG. 6 is a schematic cross-sectional view of an adapter box of a solar photovoltaic glass production apparatus according to the present invention

FIG. 7 is a schematic view of a partial cross-sectional structure of a solar photovoltaic glass production apparatus according to embodiment 2 of the present invention

Fig. 8 is a schematic partial sectional structure view of a solar photovoltaic glass production apparatus according to embodiment 3 of the present invention.

In the figure: 1 box body, 2 movable blocks, 3 movable grooves, 4 first springs, 5 rotating shafts, 6 supporting rods, 7 feeding channels, 8 discharging plates, 9 processing grooves, 10 first magnetic plates, 11 partition plates, 12 vibration motors, 13 material guide plates, 14 material throwing boxes, 15 discharging grooves, 16 first frames, 17 spheres, 18 second springs, 19 fixing plates, 20 first connecting rods, 21 bottom plates, 22 motors, 23 dust suction mechanisms, 24 driving plates, 25 fixed magnetic rods, 26 discharging ports, 27 material collecting grooves, 28 screening boxes, 29 stirring rods, 30 rotating rods, 31 movable rods, 32 second magnetic plates, 33 second frames, 34 second connecting rods, 35 first scraping plates, 36 third connecting rods, 37 vertical rods, 38 second scraping plates, 39 air permeable net covers, 40 material suction pipes, 41 material guide channels, 42 baffle plates, 43 notch grooves, 44 rotating wheels, 45 driving material guide plates, 46 friction blocks, 47 transfer boxes, 48 belts, 49 material guide pipes, 50 through holes, 51 layers, 52 fixed rods, 53 third springs, 54 grooves and 55 movable balls.

Detailed Description

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

Example 1

Referring to fig. 1-6, a solar photovoltaic glass production device and a production process thereof, comprising a box body 1, wherein the top of the box body 1 is fixedly connected with a feeding channel 7, the inner wall of the feeding channel 7 is provided with a feeding mechanism, the bottom of the feeding mechanism is fixedly connected with a discharging plate 8, the discharging plate 8 is arranged in a round table shape, the bottom of the discharging plate 8 is provided with a processing tank 9, the inner wall of the processing tank 9 is provided with a multilayer magnetic suction mechanism, the bottom of the inner wall of the processing tank 9 is provided with a material guide plate 13, the material guide plate 13 is fixedly connected with a rotating shaft 5, the top of the rotating shaft 5 is fixedly connected with the discharging plate 8, the bottom of the rotating shaft 5 is fixedly connected with a motor 22, the bottom of the material guide plate 13 is provided with a material throwing tank 14, the outer wall of the material throwing tank 14 is provided with a driving mechanism, the bottom of the material throwing tank 14 is fixedly connected with a discharging tank 15, the bottom of the discharging tank 15 is provided with a rotating magnetic suction mechanism, and the screening tank 28 is arranged at the bottom of the rotating magnetic suction mechanism, screening 28 bottom outer walls of case have been seted up a plurality of sieve meshes, screening 28 bottom is provided with the mechanism of gathering materials, can be with the leading-in 1 insides of box with the silica sand through setting up feedstock channel 7 and inside feed mechanism, inhale the mechanism through the multilayer that sets up in the treatment trough 9 and can carry out multilayer magnetism to the silica sand and inhale the processing, can be with leading-in 14 insides of getting rid of the workbin with the silica sand through setting up stock guide 13, can make the silica sand that gets rid of in the workbin 14 throw away from the blown down tank of bottom through setting up actuating mechanism, inhale the mechanism through setting up rotation magnetism and can rotate magnetism to the silica sand and inhale the processing, can carry out screening process to the silica sand through setting up screening box 28, can collect final silica sand through setting up the mechanism of gathering materials.

In the invention, a feeding mechanism comprises a material guiding channel 41 and a vertical rod 37, the outer wall of the material feeding channel 7 is fixedly connected with a plurality of supporting rods 6, the bottoms of the supporting rods 6 are fixedly connected with a box body 1, the bottom of the material feeding channel 7 is rotatably connected with the material guiding channel 41, the bottom of the material guiding channel 41 is fixedly connected with a material discharging plate 8, a rotating shaft 5 and the vertical rod 37 are hollow, the tops of the vertical rod 37 and the rotating shaft 5 are fixedly connected, the inner wall of the material feeding channel 7 is provided with a plurality of second scraping plates 38, one end of each second scraping plate 38 is fixedly connected with a third connecting rod 36, the other end of each third connecting rod 36 is fixedly connected with the vertical rod 37, the inner wall of the material guiding channel 41 is provided with a plurality of air permeable net covers 39, the air permeable net covers 39 are fixedly connected with the vertical rods 37, the inner wall of each air permeable net cover 39 is provided with a material absorbing pipe 40, the material absorbing pipe 40 is fixedly connected with the vertical rod 37, the bottom of the rotating shaft 5 is rotatably connected with a transfer box 47, and the transfer box 47 is fixedly connected with the bottom of the inner wall of the box body 1, the bottom of the box body 1 is fixedly connected with a dust collection mechanism 23, the dust collection mechanism 23 is fixedly connected with a plurality of material guide pipes 49, the other ends of the material guide pipes 49 are fixedly connected with the adapter box 47, the outer wall of the rotating shaft 5 is provided with a plurality of through holes 50, the through holes 50 are positioned in the adapter box 47, the dust collection mechanism 23 and the rotating shaft 5 are used for collecting dust of silica sand in the material guide channel 41, the second scraper 38 is used for scraping the silica sand in the material feed channel 7, and the efficiency of the material feed box is improved;

the multilayer magnetic suction mechanism comprises a first magnetic plate 10 and a first scraper 35, the inner wall of a processing groove 9 is fixedly connected with a plurality of clapboards 11, the clapboards 11 are arranged in an array and distributed from top to bottom, a gap is arranged between the clapboards 11 on the same plane, the first magnetic plate 10 is respectively fixedly connected with the outer walls of two ends of the clapboards 11, the first scraper 35 is positioned between the clapboards 11, the first scraper 35 is naturally contacted with the inner wall of the processing groove 9, the other end of the first scraper 35 is fixedly connected with a second connecting rod 34, the other end of the second connecting rod 34 is fixedly connected with a rotating shaft 5, the top of the outer wall of the processing groove 9 is fixedly connected with a movable block 2, the inner wall of a box body 1 is provided with a movable groove 3, the movable block 2 is positioned in the movable groove 3, a plurality of first springs 4 are fixedly connected between the movable block 2 and the movable groove 3, the outer wall of the bottom of the processing groove 9 is fixedly connected with a plurality of vibrating motors 12, silica sand enters the processing groove 9 from the edge of the top of the processing groove 9, the silica sand passing through is subjected to magnetic absorption treatment by arranging a plurality of partition plates 11 in the treatment tank 9 and utilizing the first magnetic plates 10 on the outer wall, the silica sand between the partition plates 11 is scraped by arranging the rotating shaft 5 and utilizing the first scraper 35 connected by the second connecting rod 34, and the silica sand is promoted to sequentially move downwards through gaps between the partition plates 11, so that the aim of multilayer magnetic absorption treatment is fulfilled, the treatment tank 9 is driven to vibrate by arranging the vibrating motor 12, and the treatment tank 9 and the movable tank 3 of the box body 1 are connected by the movable block 2 and the first spring 4, so that the treatment tank 9 has higher vibration amplitude, and the silica sand passing and magnetic absorption efficiency are promoted;

the driving mechanism comprises a rotating wheel 44 and a friction block 46, the friction block 46 is fixedly connected with the outer wall of the material throwing box 14 and is annular, two ends of the inner wall of the box body 1 are respectively provided with a notch 43, the rotating wheel 44 is positioned in the notch 43, the rotating wheel 44 is naturally contacted with the friction block 46, the bottom of the rotating wheel 44 is fixedly connected with a driving rod 45, one end of the bottom of the driving rod 45 is in transmission connection with a belt 48, the other end of the belt 48 penetrates through an adapter box 47 and is in transmission connection with the rotating shaft 5, the inner wall of the adapter box 47 is fixedly connected with a layer plate 51, the belt 48 is positioned on the top of the layer plate 51, the outer wall of the top of the material throwing box 14 is fixedly connected with a baffle plate 42, the baffle plate 42 is annular, the silicon sand flowing down from the processing groove 9 can be guided by utilizing the guide plate 13, the silicon sand enters the material throwing box 14 and can be limited by arranging the baffle plate 42, the material throwing box 14 and the rotating shaft 5 can be reversely rotated by arranging the driving mechanism, the silica sand entering the material throwing box 14 is evenly thrown out from the discharge chute 15 at the bottom;

the rotary magnetic attraction mechanism comprises a first frame 16 and a second frame 33, the first frame 16 and the second frame 33 are respectively and fixedly connected with the outer walls of two ends of a rotating shaft 5, the inner walls of the first frame 16 and the second frame 33 are rotatably connected with a plurality of movable rods 31, the outer wall of each movable rod 31 is fixedly connected with a second magnetic plate 32, the movable rods 31 in the first frame 16 are arranged in a transverse direction, the movable rods 31 in the second frame 33 are arranged in a vertical direction, the rotating shaft 5 is utilized to drive the first frame 16 and the second frame 33 to rotate, so that the thrown silica sand can be subjected to rotary magnetic attraction treatment by the second magnetic plates 32 connected with the movable rods 31 inside, and the magnetic attraction range and effect of the silica sand are ensured by arranging the movable rods 31 in the first frame 16 and the second frame 33 in the transverse direction and the vertical direction;

a plurality of stirring rods 29 are arranged on the inner wall of the screening box 28, the top of each stirring rod 29 is fixedly connected with a rotating rod 30, the rotating rods 30 are fixedly connected with a rotating shaft 5, the rotating shaft 5 penetrates through the screening box 28, the bottom of the screening box 28 is fixedly connected with a plurality of second springs 18, the bottom of each second spring 18 is fixedly connected with a fixing plate 19, the fixing plates 19 are fixedly connected with the inner wall of the box body 1, silica sand can be screened by using sieve holes in the bottom of the screening box 28, the rotating rods 30 are driven to rotate by using the rotating shafts 5, and therefore the bottom stirring rods 29 are used for stirring the silica sand, and the screening effect is improved;

the collecting mechanism comprises a bottom plate 21 and a collecting groove 27, the bottom plate 21 is fixedly connected with a rotating shaft 5, the bottom plate 21 is arranged to be conical, the outer wall of the box body 1 is provided with a plurality of discharging holes 26, the inner wall of each discharging hole 26 is fixedly connected with a plurality of fixed magnetic rods 25, each discharging hole 26 is positioned at the bottom of the outer wall of the bottom plate 21, the collecting groove 27 is fixedly connected with the outer wall of the box body 1, the collecting groove 27 is arranged to be annular, the collecting groove 27 is positioned at the bottom of the other end of each discharging hole 26, the rotating shaft 5 is arranged to drive the bottom plate 21 to rotate, so that silica sand on the top of the bottom plate 21 is subjected to centrifugal force and is thrown out from the edge of the bottom plate 21, finally, the silica sand is thrown into the collecting groove 27 from the discharging holes 26 formed in the box body 1, and final magnetic attraction treatment can be carried out on the silica sand through the fixed magnetic rods 25 arranged in the discharging holes 26;

a solar photovoltaic glass production process adopts the solar photovoltaic glass production equipment, and comprises the following process steps:

s1, introducing silica sand into the feeding channel, guiding the silica sand into the discharging plate through the conveying of the material guiding channel, driving the discharging plate to rotate through a rotating shaft by arranging a motor, and collecting the silica sand to be thrown out from the edge of the outer wall;

s2, allowing silica sand to enter the treatment tank from the top edge of the treatment tank, performing magnetic absorption treatment on the silica sand passing through the treatment tank by using a first magnetic plate on the outer wall through a plurality of partition plates arranged in the treatment tank, scraping the silica sand between the partition plates by using a first scraper connected with a second connecting rod through a rotating shaft, and promoting the silica sand to sequentially move downwards through gaps between the partition plates, so that the aim of multilayer magnetic absorption treatment is fulfilled;

s3, guiding the silica sand flowing down from the processing tank by using a guide plate to enable the silica sand to enter a material throwing box, limiting the silica sand by arranging a baffle plate, and enabling the material throwing box and a rotating shaft to rotate oppositely by arranging a driving mechanism to enable the silica sand entering the material throwing box to be evenly thrown out from a discharge tank at the bottom;

s4, the first frame and the second frame are driven to rotate by the rotating shaft, so that the thrown silica sand can be subjected to rotary magnetic absorption treatment by the second magnetic plate connected by the movable rod inside, and the magnetic absorption range and effect of the silica sand are ensured by arranging the movable rods in the first frame and the second frame to be horizontal and vertical;

s5, screening the silica sand by using the screen holes at the bottom of the screening box, and driving the rotating rod to rotate by using the rotating shaft so as to stir the silica sand by using the stirring rod at the bottom and improve the screening effect;

and S6, driving the bottom plate to rotate through the rotating shaft, so that the silica sand on the top of the bottom plate is subjected to centrifugal force and thrown out from the edge of the bottom plate, and finally thrown into the material collecting groove from a discharge port formed in the box body, and finally performing magnetic absorption treatment on the silica sand through the fixed magnetic rod arranged in the discharge port.

During the use, can be with leading-in box 1 inside with the silica sand through setting up feedstock channel 7 and inside feed mechanism, inhale the mechanism through the multilayer magnetism that sets up in the treatment trough 9 and can carry out multilayer magnetism to the silica sand and inhale the processing, can inhale the leading-in workbin 14 of getting rid of the silica sand through setting up stock guide 13, can make the silica sand that gets rid of in the workbin 14 throw away from the blown down tank of bottom through setting up actuating mechanism, inhale the mechanism through setting up rotation magnetism and can rotate magnetism to the silica sand and inhale the processing, can carry out screening process to the silica sand through setting up screening box 28, can collect final silica sand through setting up the mechanism that gathers materials.

Example 2

Referring to fig. 7, a solar photovoltaic glass production facility and production technology, puddler 29 and dwang 30 all set up to cavity, and puddler 29 inner wall fixedly connected with dead lever 52, the fixedly connected with third spring 53 in dead lever 52 bottom, and the fixedly connected with movable ball 55 in third spring 53 bottom, and movable ball 55 external diameter is the same with puddler 29 internal diameter, and recess 54 has all been seted up at puddler 29 inner wall both ends, and recess 54 is located movable ball 55 top.

When the silicon sand dust collector is used, when the movable ball 55 is extruded by the silicon sand, the movable ball 55 compresses the third spring 53, so that the movable ball 55 enters the groove 54, a gap is formed between the movable ball 55 and the groove 54, and the stirring rod 29 can perform open-close dust collection treatment on the silicon sand in the screening box 28.

Example 3

Referring to fig. 8, a solar photovoltaic glass production device and a production process thereof, a first connecting rod 20 is fixedly connected to the top of a bottom plate 21, a sphere 17 is fixedly connected to the top of the first connecting rod 20, a driving plate 24 is arranged at the other end of the top of the sphere 17, and the top of the driving plate 24 is fixedly connected to the bottom of a screening box 28.

When the ball 17 is driven by the first connecting rod 20 and the bottom plate 21 to rotate, when the ball 17 contacts with the driving plate 24 at the bottom of the screening box 28, the driving plate 24 is pressed, so that the screening box 28 moves upwards and then falls down again, and a vertical movement state is formed, thereby promoting the screening effect.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical scope of the present invention and the equivalent alternatives or modifications according to the technical solution and the inventive concept of the present invention within the technical scope of the present invention.

Claims (10)

1. The solar photovoltaic glass production equipment comprises a box body (1) and is characterized in that a feeding channel (7) is fixedly connected to the top of the box body (1), a feeding mechanism is arranged on the inner wall of the feeding channel (7), a discharging plate (8) is fixedly connected to the bottom of the feeding mechanism, the discharging plate (8) is in a round table shape, a processing groove (9) is arranged at the bottom of the discharging plate (8), a multilayer magnetic suction mechanism is arranged on the inner wall of the processing groove (9), a guide plate (13) is arranged at the bottom of the inner wall of the processing groove (9), a rotating shaft (5) is fixedly connected to the guide plate (13), the top of the rotating shaft (5) is fixedly connected to the discharging plate (8), a motor (22) is fixedly connected to the bottom of the rotating shaft (5), a material throwing box (14) is arranged at the bottom of the guide plate (13), and a driving mechanism is arranged on the outer wall of the material throwing box (14), get rid of workbin (14) bottom fixedly connected with blown down tank (15), blown down tank (15) bottom is provided with rotates magnetism and inhales the mechanism, it is provided with screening case (28) to rotate magnetism and inhale mechanism bottom, a plurality of sieve meshes have been seted up to screening case (28) bottom outer wall, screening case (28) bottom is provided with the mechanism that gathers materials.

2. The solar photovoltaic glass production equipment according to claim 1, wherein the feeding mechanism comprises a material guiding channel (41) and a vertical rod (37), the outer wall of the material guiding channel (7) is fixedly connected with a plurality of support rods (6), the bottom of each support rod (6) is fixedly connected with the box body (1), the bottom of the material guiding channel (7) is rotatably connected with the material guiding channel (41), the bottom of the material guiding channel (41) is fixedly connected with the material discharging plate (8), the rotating shaft (5) and the vertical rod (37) are hollow, the vertical rod (37) is fixedly connected with the top of the rotating shaft (5), the inner wall of the material guiding channel (7) is provided with a plurality of second scraping plates (38), one end of each second scraping plate (38) is fixedly connected with a third connecting rod (36), the other end of each third connecting rod (36) is fixedly connected with the vertical rod (37), the inner wall of the material guiding channel (41) is provided with a plurality of air permeable mesh enclosures (39), ventilative screen panel (39) and montant (37) fixed connection, ventilative screen panel (39) inner wall is provided with inhales material pipe (40), inhale material pipe (40) and montant (37) fixed connection, axis of rotation (5) bottom is rotated and is connected with adapter box (47), adapter box (47) and box (1) inner wall bottom fixed connection, box (1) bottom fixedly connected with dust absorption mechanism (23), a plurality of passage (49) of dust absorption mechanism (23) fixedly connected with, passage (49) other end and adapter box (47) fixed connection, a plurality of through-holes (50) have been seted up to axis of rotation (5) outer wall, through-hole (50) are located adapter box (47).

3. The solar photovoltaic glass production equipment according to claim 1, wherein the multilayer magnetic attraction mechanism comprises a first magnetic plate (10) and a first scraper (35), a partition plate (11) is fixedly connected to the inner wall of the treatment tank (9), the partition plates (11) are arranged in an array and distributed from top to bottom, gaps are arranged between the partition plates (11) on the same plane, the first magnetic plate (10) is fixedly connected with the outer walls of the two ends of the partition plate (11), the first scraper (35) is positioned between the partition plates (11), the first scraper (35) is naturally contacted with the inner wall of the treatment tank (9), the other end of the first scraper (35) is fixedly connected with a second connecting rod (34), the other end of the second connecting rod (34) is fixedly connected with the rotating shaft (5), a movable block (2) is fixedly connected to the top of the outer wall of the treatment tank (9), a movable groove (3) is formed in the inner wall of the box body (1), the movable block (2) is positioned in the movable groove (3), a plurality of first springs (4) are fixedly connected between the movable block (2) and the movable groove (3), and a plurality of vibrating motors (12) are fixedly connected to the outer wall of the bottom of the processing groove (9).

4. The solar photovoltaic glass production apparatus according to claim 2, the driving mechanism comprises a rotating wheel (44) and a friction block (46), the friction block (46) is fixedly connected with the outer wall of the material throwing box (14), and be the annular, scarce groove (43) have all been seted up at box (1) inner wall both ends, it is located scarce groove (43) to rotate wheel (44), it contacts naturally to rotate wheel (44) and clutch blocks (46), it drives pole (45) to rotate wheel (44) bottom fixedly connected with, it is connected with belt (48) to drive pole (45) bottom one end transmission, belt (48) other end passes transfer box (47) and is connected with axis of rotation (5) transmission, transfer box (47) inner wall fixedly connected with plywood (51), belt (48) are located plywood (51) top, get rid of workbin (14) top outer wall fixedly connected with baffle (42), baffle (42) set up to the annular.

5. The solar photovoltaic glass production equipment according to claim 1, wherein the rotary magnetic attraction mechanism comprises a first frame (16) and a second frame (33), the first frame (16) and the second frame (33) are respectively fixedly connected with the outer walls of the two ends of the rotating shaft (5), the inner walls of the first frame (16) and the second frame (33) are rotatably connected with a plurality of movable rods (31), the outer wall of each movable rod (31) is fixedly connected with a second magnetic plate (32), the movable rods (31) in the first frame (16) are arranged in a transverse direction, and the movable rods (31) in the second frame (33) are arranged in a vertical direction.

6. The solar photovoltaic glass production equipment according to claim 1, wherein a plurality of stirring rods (29) are arranged on the inner wall of the screening box (28), a rotating rod (30) is fixedly connected to the top of each stirring rod (29), the rotating rod (30) is fixedly connected with the rotating shaft (5), the rotating shaft (5) penetrates through the screening box (28), a plurality of second springs (18) are fixedly connected to the bottom of the screening box (28), a fixing plate (19) is fixedly connected to the bottom of each second spring (18), and the fixing plate (19) is fixedly connected with the inner wall of the box body (1).

7. The solar photovoltaic glass production equipment according to claim 1, wherein the collecting mechanism comprises a bottom plate (21) and a collecting groove (27), the bottom plate (21) is fixedly connected with the rotating shaft (5), the bottom plate (21) is arranged in a conical shape, the outer wall of the box body (1) is provided with a plurality of discharge holes (26), the inner wall of each discharge hole (26) is fixedly connected with a plurality of fixed magnetic rods (25), each discharge hole (26) is positioned at the bottom of the outer wall of the bottom plate (21), the collecting groove (27) is fixedly connected with the outer wall of the box body (1), the collecting groove (27) is arranged in an annular shape, and the collecting groove (27) is positioned at the bottom of the other end of each discharge hole (26).

8. The solar photovoltaic glass production equipment according to claim 6, wherein the stirring rod (29) and the rotating rod (30) are both hollow, a fixed rod (52) is fixedly connected to the inner wall of the stirring rod (29), a third spring (53) is fixedly connected to the bottom of the fixed rod (52), a movable ball (55) is fixedly connected to the bottom of the third spring (53), the outer diameter of the movable ball (55) is the same as the inner diameter of the stirring rod (29), grooves (54) are formed in both ends of the inner wall of the stirring rod (29), and the grooves (54) are located at the top of the movable ball (55).

9. The solar photovoltaic glass production equipment according to claim 7, wherein a first connecting rod (20) is fixedly connected to the top of the bottom plate (21), a ball (17) is fixedly connected to the top of the first connecting rod (20), a driving plate (24) is arranged at the other end of the top of the ball (17), and the top of the driving plate (24) is fixedly connected to the bottom of the screening box (28).

10. A solar photovoltaic glass production process adopts the solar photovoltaic glass production equipment, and comprises the following process steps:

s1, introducing silica sand into the feeding channel, guiding the silica sand into the discharging plate through the conveying of the material guiding channel, driving the discharging plate to rotate through a rotating shaft by arranging a motor, and collecting the silica sand to be thrown out from the edge of the outer wall;

s2, allowing silica sand to enter the treatment tank from the top edge of the treatment tank, performing magnetic absorption treatment on the silica sand passing through the treatment tank by using a first magnetic plate on the outer wall through a plurality of partition plates arranged in the treatment tank, scraping the silica sand between the partition plates by using a first scraper connected with a second connecting rod through a rotating shaft, and promoting the silica sand to sequentially move downwards through gaps between the partition plates, so that the aim of multilayer magnetic absorption treatment is fulfilled;

s3, guiding the silica sand flowing down from the processing tank by using a guide plate to enable the silica sand to enter a material throwing box, limiting the silica sand by arranging a baffle plate, and enabling the material throwing box and a rotating shaft to rotate oppositely by arranging a driving mechanism to enable the silica sand entering the material throwing box to be evenly thrown out from a discharge tank at the bottom;

s4, the first frame and the second frame are driven to rotate by the rotating shaft, so that the thrown silica sand can be subjected to rotary magnetic absorption treatment by the second magnetic plate connected by the movable rod inside, and the magnetic absorption range and effect of the silica sand are ensured by arranging the movable rods in the first frame and the second frame to be horizontal and vertical;

s5, screening the silica sand by using the screen holes at the bottom of the screening box, and driving the rotating rod to rotate by using the rotating shaft so as to stir the silica sand by using the stirring rod at the bottom and improve the screening effect;

and S6, driving the bottom plate to rotate through the rotating shaft, so that the silica sand on the top of the bottom plate is subjected to centrifugal force and thrown out from the edge of the bottom plate, and finally thrown into the material collecting groove from a discharge port formed in the box body, and finally performing magnetic absorption treatment on the silica sand through the fixed magnetic rod arranged in the discharge port.

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