CN216539399U - Particle sieve processing device - Google Patents

Abstract

The utility model discloses a particle screening device, which relates to the field of particle screening and comprises a device main body, wherein discharge holes are formed in the lower parts of two sides of the device main body. According to the utility model, through the arrangement of the material blocking assembly, the materials can be prevented from falling onto the discharge plate during turning due to the arrangement of the baffle plate, so that the materials can be continuously turned in the screen mesh, the screen mesh is prevented from being blocked by the materials, the materials can be thoroughly screened in the screen mesh, the screening efficiency of the materials is further improved, meanwhile, when the remaining materials in the screen mesh need to be cleaned, the second motor can be started, the second motor works to drive the winding wheel to rotate, then the pull rope is wound, then the sliding plate is pulled to move upwards, the spring can be extruded and the baffle plate is driven to move upwards after the sliding plate moves upwards, after the baffle plate is no longer in contact with the screen mesh, the remaining materials in the screen mesh can be wound up after the rotating of the material turning plate, and when the material turning plate is in an inclined state, the materials can slide to the discharge plate and are discharged through the discharge port, and the cleaning efficiency of the materials in the screen mesh is further improved.

Description

Particle sieve processing device

Technical Field

The utility model relates to the field of particle screening, in particular to a particle screening treatment device.

Background

Particles are a scientific term referring to geometric bodies having a specific shape within a size range, wherein the size is generally between millimeters and nanometers, and the particles refer not only to solid particles but also to liquid particles such as fog drops, oil drops and the like, and a particle screening device is required in the process of treating the solid particles.

Most of existing particle screening processing devices put materials into the device, so that the materials slide through the inclined guide plate to be screened, but the rolling speed of the materials in the screening mode is too high, so that the rolling time of the materials on the guide plate is short, the materials are difficult to be screened completely, and the screening efficiency of the materials is reduced; when the material after the screening slided along the play flitch simultaneously, because the less material of part can be attached to on the play flitch, lead to this part material to be difficult to slide out in the quick through play flitch slave unit main part, reduced the ejection of compact efficiency to the material then.

SUMMERY OF THE UTILITY MODEL

Based on this, the utility model aims to provide a particle screening treatment device to solve the technical problems of poor screening effect on materials and low discharging speed of partial materials.

In order to achieve the purpose, the utility model provides the following technical scheme: granule sieve processing apparatus, including the device main part, the discharge gate has all been seted up to the both sides below of device main part, the inside intermediate position department of device main part installs the screen cloth, first motor is installed to the surface top of device main part, the output of first motor is connected with the drive shaft that extends to the device main part inside, the bottom of drive shaft is fixed with the material turning plate, the inside top of device main part is provided with and keeps off the material subassembly, the inside below of device main part is provided with the stock guide respectively and strikes the subassembly.

Through adopting above-mentioned technical scheme, first motor work can drive the drive shaft and rotate, drives the material turning plate then and rotates, can turn the material after the material turning plate rotates to the material can carry out the screen cloth through the screen cloth, and prevents that the material from piling up on the screen cloth and causing the jam.

Further, the material blocking assembly comprises a second motor, two fixing plates and discharge plates, the second motor is installed on two sides of the top of the device body, the two fixing plates are installed above the inside of the device body, the discharge plates are installed on two sides of the inside of the device body, a containing cavity is formed in the fixing plates, a spring is fixed above the inside of the containing cavity, the bottom end of the spring is connected with a sliding plate, the bottom of the sliding plate is connected with a baffle extending to the outside of the containing cavity, the output end of the second motor is connected with a winding wheel, and the outer surface of the winding wheel is connected with a pull rope extending to the inside of the containing cavity.

Through adopting above-mentioned technical scheme, second motor work drives the take-up pulley and rotates, and then the rolling stay cord, and the slide that redraws shifts up again, can extrude the spring and drive the baffle and shift up after shifting up on the slide, after the baffle no longer contacts with the screen cloth, the material turning plate rotates the back and can play remaining material winding in the screen cloth, and when the material turning plate is the tilt state the material can slide to a play flitch department to discharge through the bin outlet.

Further, the bottom of stay cord is connected with the top of slide, the bottom and the screen cloth of baffle contact, the baffle passes through slide and accomodates chamber sliding connection.

Through adopting above-mentioned technical scheme, the baffle can prevent that the material from just sliding to going out the flitch when not thoroughly sieving, and baffle accessible slide from top to bottom in accomodating the intracavity.

Further, strike the subassembly including installing in two bearings at device main part surface and back and cup jointing in the first drive belt pulley and the second drive belt pulley of drive shaft one end, per two be connected with the loose axle between the bearing, two driven pulley has all been cup jointed to the one end of loose axle, all cup jointed the drive belt between first drive belt pulley and a driven pulley and between second drive belt pulley and another driven pulley, the outer wall of loose axle is fixed with a plurality of storage barrels, the spout has been seted up to the inside of storage barrel, the inside of spout is fixed with reset spring, reset spring's one end is connected with the slider, the bottom of slider is fixed with the movable rod that extends to the spout outside, the ball is beaten to the one end of movable rod is installed and is beaten the ball.

Through adopting above-mentioned technical scheme, can drive first drive pulley and second drive pulley and rotate when the drive shaft rotates, then can drive driven pulley and rotate, it rotates to drive the loose axle again, can drive the movable rod after the loose axle rotates and rotate, and reset spring can be tensile and then promote the movable rod and remove, the movable rod can drive and strike the ball and remove, so that strike the ball and constantly strike the stock guide, thereby make the stock guide take place the vibration, so that the material can pass through the stock guide fast and slide to discharge gate department, thereby the discharging efficiency of material has been improved.

Furthermore, the knocking ball is positioned under the material guide plate, the knocking ball and the movable rod are both connected with the sliding groove in a sliding mode through the sliding block, and two sides of the material guide plate are inclined downwards along the direction of the material outlet.

Through adopting above-mentioned technical scheme, strike the batting and can constantly strike the stock guide to make the stock guide vibration, and then can make the material on the stock guide discharge through the discharge gate fast, improved the discharging efficiency of material then.

Further, the screen cloth is the arc, the bottom and the screen cloth of turn-over material board contact, the both sides of screen cloth all are connected with the play flitch.

Through adopting above-mentioned technical scheme, can turn up the material on the screen cloth when the material turning plate rotates to the material can roll and avoid blockking up the screen cloth, thereby improves the screening efficiency to the material.

Further, the feeder hopper is installed to the top intermediate position department of device main part, operating panel is installed to one side of device main part, operating panel respectively with first motor and second motor electric connection.

Through adopting above-mentioned technical scheme, material accessible feeder hopper enters into the inside of device main part, and user's accessible operating panel opens or closes first motor and second motor simultaneously.

In summary, the utility model mainly has the following beneficial effects:

1. the utility model can prevent the material from falling onto the discharging plate when turning over due to the arrangement of the baffle plate by arranging the material blocking component, so that the materials can be continuously turned in the screen, the screen is prevented from being blocked by the materials, the time of the materials in the screen is prolonged, the materials can be thoroughly screened in the screen, thereby improving the screening efficiency of the materials, and simultaneously when the materials left in the screen are required to be cleaned, the second motor can be started, the second motor works to drive the winding wheel to rotate, then the pull rope is wound, the sliding plate is pulled to move upwards, the sliding plate can extrude the spring and drive the baffle plate to move upwards after moving upwards, when the baffle is not contacted with the screen any more, the material turning plate can roll the residual materials in the screen after rotating, when the material turning plate is in an inclined state, the material slides to the discharge plate and is discharged through the discharge port, so that the cleaning efficiency of the material in the screen is improved;

2. according to the utility model, through the arrangement of the knocking component, when the driving shaft rotates, the first driving belt pulley and the second driving belt pulley are driven to rotate, the driven belt pulley is driven to rotate, the movable shaft is driven to rotate, the movable rod is driven to rotate after the movable shaft rotates, the return spring is stretched to push the movable rod to move, the movable rod drives the knocking ball to move, so that the knocking ball continuously impacts the material guide plate, the material guide plate vibrates, the material can rapidly slide to the discharge port through the material guide plate, the material discharge efficiency is improved, and partial material is prevented from being accumulated on the material guide plate and being difficult to discharge through the discharge port.

Drawings

FIG. 1 is a schematic perspective view of a device body according to the present invention;

FIG. 2 is a front view of the device body of the present invention;

FIG. 3 is a schematic front sectional view of the main body of the apparatus of the present invention;

FIG. 4 is a schematic perspective view of a screen panel according to the present invention;

FIG. 5 is an enlarged view of the utility model at A in FIG. 3;

fig. 6 is an enlarged view of the utility model at B in fig. 3.

In the figure: 1. a device main body; 2. a discharge port; 3. a material guide plate; 4. an operation panel; 5. a discharge outlet; 6. a feed hopper; 7. a first motor; 8. the material blocking component; 801. a second motor; 802. a winding wheel; 803. pulling a rope; 804. a fixing plate; 805. a baffle plate; 806. a receiving cavity; 807. a spring; 808. a slide plate; 809. a discharge plate; 9. a knocking component; 901. knocking and hitting the ball; 902. a storage cylinder; 903. a return spring; 904. a chute; 905. a slider; 906. a movable rod; 907. a movable shaft; 908. a bearing; 909. a first drive pulley; 910. a second drive pulley; 911. a transmission belt; 912. a driven pulley; 10. a screen mesh; 11. a material turning plate; 12. a drive shaft.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

The following describes an embodiment of the present invention based on its overall structure.

A particle sieve processing device is shown in figures 1-4 and comprises a device main body 1, discharge holes 2 are formed below two sides of the device main body 1, a screen 10 is installed at the middle position inside the device main body 1, a first motor 7 is installed above the outer surface of the device main body 1, the output end of the first motor 7 is connected with a driving shaft 12 extending into the device main body 1, a material turning plate 11 is fixed at the bottom of the driving shaft 12, the first motor 7 can drive the driving shaft 12 to rotate and then drive the material turning plate 11 to rotate, the material can be turned after the material turning plate 11 rotates, so that the material can pass through the screen 10 to be sieved, the material is prevented from being accumulated on the screen 10 to cause blockage, the screen 10 is arc-shaped, the bottom of the material turning plate 11 is in contact with the screen 10, two sides of the screen 10 are both connected with discharge plates 809, a material blocking assembly 8 is arranged above the inside of the device main body 1, feeder hopper 6 is installed to the top intermediate position department of device main part 1, and operating panel 4 is installed to one side of device main part 1, and operating panel 4 respectively with first motor 7 and second motor 801 electric connection, material accessible feeder hopper 6 gets into the inside to device main part 1, and user's accessible operating panel 4 opens or closes first motor 7 and second motor 801 simultaneously, and the inside below of device main part 1 is provided with stock guide 3 and strikes subassembly 9 respectively.

Referring to fig. 1, 2, 3, 4 and 6, the material stopping assembly 8 includes a second motor 801 installed on two sides of the top of the device body 1, two fixing plates 804 installed on the upper portion of the inside of the device body 1, and a material discharging plate 809 installed on two sides of the inside of the device body 1, a receiving cavity 806 is formed in the fixing plate 804, a spring 807 is fixed on the upper portion of the inside of the receiving cavity 806, a sliding plate 808 is connected to the bottom of the spring 807, a baffle 805 extending to the outside of the receiving cavity 806 is connected to the bottom of the sliding plate 808, a wire winding wheel 802 is connected to the output end of the second motor 801, the second motor 801 drives the wire winding wheel 802 to rotate, then a pulling rope 803 is wound, the sliding plate 808 is pulled to move upwards, the sliding plate 808 presses the spring 807 and drives the baffle 805 to move upwards, when the baffle 805 is no longer contacted with the screen cloth 10, the material remaining in the screen cloth 10 can be taken up after the material overturning plate 11 rotates, when the material turning plate 11 is in an inclined state, the material slides to the discharging plate 809 and is discharged through the discharge port 5, the outer surface of the winding wheel 802 is connected with a pulling rope 803 extending to the inside of the containing cavity 806, the bottom end of the pulling rope 803 is connected with the top of the sliding plate 808, the bottom of the baffle 805 is in contact with the screen 10, the baffle 805 is in sliding connection with the containing cavity 806 through the sliding plate 808, the baffle 805 can prevent the material from sliding to the discharging plate 809 without completely screening, and the baffle 805 can slide up and down in the containing cavity 806 through the sliding plate 808.

Referring to fig. 1, 2, 3 and 5, the knocking assembly 9 includes two bearings 908 mounted on the outer surface and the back of the device body 1, and a first driving pulley 909 and a second driving pulley 910 sleeved on one end of the driving shaft 12, a movable shaft 907 is connected between each two bearings 908, a driven pulley 912 is sleeved on one end of each of the two movable shafts 907, a driving belt 911 is sleeved between the first driving pulley 909 and one driven pulley 912 and between the second driving pulley 910 and the other driven pulley 912, a plurality of receiving cylinders 902 are fixed on the outer wall of the movable shaft 907, sliding slots 904 are formed inside the receiving cylinders 902, a return spring 903 is fixed inside the sliding slots 904, a slider 905 is connected to one end of the return spring 903, a movable rod 906 extending to the outside of the sliding slot 904 is fixed on the bottom of the slider 905, when the driving shaft 12 rotates, the first driving pulley 909 and the second driving pulley 910 are driven to rotate, the driven belt pulley 912 is driven to rotate, the movable shaft 907 drives the movable rod 906 to rotate after rotating, the reset spring 903 stretches to push the movable rod 906 to move, the movable rod 906 drives the knocking ball 901 to move, so that the knocking ball 901 continuously impacts the material guide plate 3, the material guide plate 3 vibrates, materials can rapidly slide to the discharge port 2 through the material guide plate 3, the discharging efficiency of the materials is improved, the knocking ball 901 is installed at one end of the movable rod 906, the knocking ball 901 is located under the material guide plate 3, the knocking ball 901 and the movable rod 906 are both in sliding connection with the sliding groove 904 through the sliding block 905, the two sides of the material guide plate 3 are inclined downwards along the direction of the discharge port 2, and the knocking ball 91 can continuously knock the material guide plate 3, so that the material guide plate 3 vibrates.

The implementation principle of the embodiment is as follows: firstly, a user installs the device and switches on a power supply, then materials are added into the device main body 1 through the feed hopper 6, then the first motor 7 is started through the operation panel 4, the first motor 7 works to drive the driving shaft 12 to rotate, then the material turning plate 11 is driven to rotate, the materials are turned after the material turning plate 11 rotates, the materials with smaller particle size fall onto the material guide plate 3 through the screen mesh 10, meanwhile, the driving shaft 12 rotates to drive the first driving belt pulley 909 and the second driving belt pulley 910 to rotate, then the driven belt pulley 912 is driven to rotate, then the movable shaft 907 is driven to rotate, the movable shaft 907 rotates to drive the movable rod 906 to rotate, the reset spring 903 stretches to drive the movable rod 906 to move, the movable rod 906 drives the knocking ball 901 to move, so that the knocking ball 901 continuously hits the material guide plate 3, thereby the material guide plate 3 vibrates, so that the materials can rapidly slide to the material guide plate 3 to the material outlet 2, and discharge through discharge gate 2, and the material is in the in-process of turning over because of the blockking of baffle 805, it can not drop to ejection of compact board 809, and when the surplus material in the screen cloth 10 needs to be cleared up, can start second motor 801, second motor 801 work drives the take-up reel 802 and rotates, then rolling stay cord 803, pull slide 808 and shift up again, slide 808 can push down spring 807 and drive baffle 805 and shift up after shifting up, after baffle 805 no longer contacts with screen cloth 10, can roll up the surplus material tape in the screen cloth 10 after turning over flitch 11 and rotating, and when turning over flitch 11 and being the tilt state the material can slide to ejection of compact board 809, and discharge through bin outlet 5.

Although embodiments of the present invention have been shown and described, the present embodiments are merely illustrative of the present invention and are not intended to limit the present invention, and the described specific features, structures, materials or characteristics may be combined in any suitable manner in any one or more embodiments or examples, and those skilled in the art can make modifications, substitutions, variations, etc. of the embodiments as required without departing from the principle and spirit of the present invention, but within the scope of the claims of the present invention.

Claims (7)

1. Granule sieve processing apparatus, including device main part (1), its characterized in that: discharge gate (2) have all been seted up to the both sides below of device main part (1), the inside intermediate position department of device main part (1) installs screen cloth (10), first motor (7) are installed to the surface top of device main part (1), the output of first motor (7) is connected with and extends to the inside drive shaft (12) of device main part (1), the bottom of drive shaft (12) is fixed with material turning plate (11), the inside top of device main part (1) is provided with and keeps off material subassembly (8), the inside below of device main part (1) is provided with stock guide (3) and strikes subassembly (9) respectively.

2. The particle screen processing apparatus of claim 1, wherein: keep off material subassembly (8) including installing in second motor (801) of device main part (1) top both sides, installing in two fixed plate (804) of device main part (1) inside top and installing in play flitch (809) of device main part (1) inside both sides, the inside of fixed plate (804) has been seted up and has been accomodate chamber (806), the inside top of accomodating chamber (806) is fixed with spring (807), the bottom of spring (807) is connected with slide (808), the bottom of slide (808) is connected with baffle (805) that extend to accomodating chamber (806) outside, the output of second motor (801) is connected with reel (802), the surface of reel (802) is connected with stay cord (803) that extend to accomodating chamber (806) inside.

3. The particle screen handling device of claim 2, wherein: the bottom end of the pull rope (803) is connected with the top of the sliding plate (808), the bottom of the baffle plate (805) is in contact with the screen (10), and the baffle plate (805) is in sliding connection with the containing cavity (806) through the sliding plate (808).

4. The particle screen processing apparatus of claim 1, wherein: the knocking component (9) comprises two bearings (908) arranged on the outer surface and the back of the device body (1), a first driving belt pulley (909) and a second driving belt pulley (910) sleeved at one end of a driving shaft (12), a movable shaft (907) is connected between every two bearings (908), driven belt pulleys (912) are sleeved at one ends of the two movable shafts (907), a transmission belt (911) is sleeved between the first driving belt pulley (909) and one driven belt pulley (912) and between the second driving belt pulley (910) and the other driven belt pulley (912), a plurality of containing barrels (902) are fixed on the outer wall of the movable shaft (907), a sliding groove (904) is formed in the containing barrel (902), a return spring (903) is fixed in the sliding groove (904), and a sliding block (905) is connected at one end of the return spring (903), a movable rod (906) extending to the outside of the sliding groove (904) is fixed at the bottom of the sliding block (905), and a knocking ball (901) is mounted at one end of the movable rod (906).

5. The particle screen processing apparatus of claim 4, wherein: the knocking balls (901) are located under the material guide plate (3), the knocking balls (901) and the movable rod (906) are connected with the sliding groove (904) in a sliding mode through the sliding block (905), and two sides of the material guide plate (3) are inclined downwards along the direction of the material outlet (2).

6. The particle screening apparatus of claim 2, wherein: the screen (10) is arc-shaped, the bottom of the material turning plate (11) is in contact with the screen (10), and the two sides of the screen (10) are connected with the material discharging plate (809).

7. The particle screen processing apparatus of claim 1, wherein: feeder hopper (6) are installed to the top intermediate position department of device main part (1), operating panel (4) are installed to one side of device main part (1), operating panel (4) respectively with first motor (7) and second motor (801) electric connection.

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