CN220310975U - Vibrating screen with multistage screening function for carbon powder processing - Google Patents

Abstract

The utility model relates to the technical field of carbon powder processing equipment, and provides a vibrating screen with multistage screening for a carbon powder processing device, which comprises a device main body and a screening mechanism, wherein the screening mechanism comprises a discharge hole, a feed inlet, an infrared dryer, a feed distribution hole, a chute, a slide bar, bristles, a fixed block, a first filter screen, a discharge guide plate, a second filter screen, a third filter screen and a recovery drawer. The utility model provides a vibrating screen with multistage screening for a carbon powder processing tool, wherein a case is arranged on the left side of a device main body, a switch is arranged on the left side of the case, a spring is arranged at the bottom of the device main body, a bottom plate is connected below the spring, unscreened carbon powder is poured into a screening mechanism from a feed inlet, the carbon powder is dried by an infrared drier, the possibility of blocking a filter screen is reduced, the carbon powder is sequentially dropped on three layers of filter screens by vibration, the carbon powder with the smallest particles is collected in a grading manner and is dropped on a recycling drawer, and after the end, the filter screen is cleaned by utilizing brush hair to roll along a chute above the filter screen, so that the filter screen is prevented from being blocked.

Description

Vibrating screen with multistage screening function for carbon powder processing

Technical Field

The utility model relates to the technical field of carbon powder treatment equipment, in particular to a vibrating screen with multistage screening for a carbon powder processing tool.

Background

The main component of toner (also called carbon powder) is not carbon, but most is composed of resin and carbon black, a charge agent, magnetic powder, and the like. The toner melts into the paper fibers at high temperature and the resin oxidizes to form a gas with a pungent odor, known as "ozone". This gas has only one benefit, namely protection of the earth and reduction of the damage from solar radiation. Aiming at different requirements, the carbon powder production is developed to be finer, colorized and high-speed.

According to the search of Chinese utility model publication number: CN212702938U discloses a four-layer vibrating screen, which comprises a housin, the left side fixedly connected with discharge gate of casing, the inside fixedly connected with of discharge gate is four baffle, the top fixedly connected with fixture block on baffle right side, the right side intercommunication at casing top has the inlet pipe, the positive fixedly connected with of inlet pipe prevents stifled motor, prevent the output shaft fixedly connected with pivot of stifled motor, the surface fixedly connected with of pivot is a plurality of separation blades, the inside joint of fixture block has the sieve, the positive and the equal fixedly connected with slider in back of sieve. This four layers shale shaker not only conveniently carries out dismouting and maintenance to the sieve, when feeding the material simultaneously, can not take place the jam condition for the material is orderly enters into inside the casing, has ensured the normal work of this shale shaker, and has improved the quality and the efficiency of sieve during operation, facilitates the use, is applicable to various situations.

However, when implementing the above technical solution, the following problems exist: the scheme on the machine can realize multistage screening, but in the actual use process, the stability of equipment is poor, and the filter screen is easy to be blocked by carbon powder, so that the cleaning difficulty is high, and the service life of the equipment is short.

Disclosure of Invention

The utility model provides a vibrating screen with multistage screening for a carbon powder processing tool, which solves the problems that in the related art, in the using process, equipment stability is poor, a filter screen is easy to be blocked by carbon powder, cleaning difficulty is high, and the service life of the equipment is short.

The technical scheme of the utility model is as follows: a shale shaker for carbon dust processing is with having multistage screening, including device main part and screening mechanism, device main part left side is provided with the machine case, the machine case left side is provided with the switch, the spring is installed to device main part bottom, the spring below is connected with the bottom plate, the bottom plate bottom is provided with the slipmat, device main part top and inside are provided with screening mechanism, screening mechanism includes pan feeding mouth, infrared dryer, fixed block, first filter screen and retrieves the drawer, the pan feeding mouth is installed to device main part top, infrared dryer is installed to the pan feeding mouth inboard, the fixed block top is provided with first filter screen, the inside below of device main part is provided with retrieves the drawer.

Preferably, the device main body and the springs are welded, and the springs are uniformly distributed at the bottom of the device main body.

Preferably, the bottom plate is in adhesive connection with the anti-skid pad, and the bottom plate is tightly attached to the anti-skid pad.

Preferably, the discharge gate has been seted up to device main part left and right sides, the pan feeding mouth is installed to device main part top, infrared dryer is installed to the pan feeding mouth inboard, the inside top of device main part is connected with the feed divider, the spout is installed to the inside rear side of device main part, the inside slide bar that is provided with of spout, the brush hair is installed in the slide bar outside, the inside both sides of device main part are provided with the fixed block, the fixed block top is provided with first filter screen, first filter screen one side is connected with ejection of compact baffle, first filter screen below is provided with the second filter screen, the second filter screen below is provided with the third filter screen, the inside below of device main part is provided with the recovery drawer.

Preferably, the sliding groove is in sliding connection with the sliding rod, and the inner diameter of the sliding groove is matched with the outer diameter of the tail end of the sliding rod.

Preferably, the sliding rod is connected with the bristles through screws, and the sliding rod is tightly attached to the bristles.

Preferably, the welding is adopted between the device main body and the fixed block, and the device main body is tightly attached to the fixed block.

Preferably, the device main body is connected with the recovery drawer through a clamping groove, and the inner diameter of the device main body is matched with the outer diameter of the recovery drawer.

The working principle and the beneficial effects of the utility model are as follows:

according to the utility model, the vibrating motor is used for vibrating the device main body, the elasticity of the spring is utilized to enable the bottom plate and the anti-skid pad to be kept stable, unscreened carbon powder is poured into the screening mechanism from the feed inlet, the carbon powder is dried again through the infrared drier, the possibility of blocking the filter screen is reduced, the carbon powder is partitioned and falls on the inclined surface of the first filter screen through the material distributing port, accumulation is prevented, larger carbon powder falls on the material distributing guide plate along a slope through vibration, smaller particles are sequentially collected in the material distributing port and then fall on the second filter screen and the third filter screen respectively, the smallest carbon powder falls in the recycling drawer to be uniformly collected, and finally another switch is started to enable the slide bar to move along the chute, the filter screen is cleaned through rolling of the brush hair above the filter screens, so that the filter screen blocking is prevented.

Drawings

The utility model will be described in further detail with reference to the drawings and the detailed description.

FIG. 1 is a schematic diagram of a vibrating screen with multiple stages of screening for carbon powder processing according to the present utility model;

FIG. 2 is a schematic top view of a vibrating screen with multiple stages of screening for carbon powder processing according to the present utility model;

FIG. 3 is a schematic cross-sectional view of a vibrating screen with multiple stages of screening for carbon powder processing according to the present utility model;

FIG. 4 is a schematic view of a vibrating screen with multiple stages of screening for carbon powder processing according to the present utility model;

reference numerals in the drawings: 1. a device body; 2. a chassis; 3. a switch; 4. a spring; 5. a bottom plate; 6. an anti-slip pad; 7. a screening mechanism; 701. a discharge port; 702. a feed inlet; 703. an infrared dryer; 704. a material distributing port; 705. a chute; 706. a slide bar; 707. brushing; 708. a fixed block; 709. a first filter screen; 710. a discharge guide plate; 711. a second filter screen; 712. a third filter screen; 713. and (5) recovering the drawer.

Detailed Description

The technical solutions of the embodiments of the present utility model will be clearly and completely described below in conjunction with the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-4, the present utility model provides a vibrating screen with multi-stage screening for carbon powder processing, which comprises the following steps: including device main part 1 and screening mechanism 7, device main part 1 left side is provided with machine case 2, machine case 2 left side is provided with switch 3, device main part 1 installs spring 4 in the bottom, the spring 4 below is connected with bottom plate 5, the bottom plate 5 bottom is provided with slipmat 6, device main part 1 top and inside are provided with screening mechanism 7, screening mechanism 7 includes pan feeding mouth 702, infrared dryer 703, fixed block 708, first filter screen 709 and retrieve drawer 713, pan feeding mouth 702 is installed to device main part 1 top, infrared dryer 703 is installed to the pan feeding mouth 702 inboard, fixed block 708 top is provided with first filter screen 709, the inside below of device main part 1 is provided with retrieves drawer 713.

When the vibrating screen is used, firstly, the switch 3 is pressed to start the vibrating motor in the case 2, so that the device main body 1 starts vibrating, meanwhile, the bottom plate 5 and the anti-slip pad 6 are kept stable due to the elasticity of the spring 4, unscreened carbon powder is poured into the screening mechanism 7 from the feed inlet 702, the carbon powder is dried again through the infrared dryer 703, the possibility of blocking the filter screen is reduced, the carbon powder is separated and falls down through the feed distribution inlet 704, firstly, the carbon powder falls on the surface of the inclined first filter screen 709 supported by the fixed block 708, the carbon powder with larger particles falls on the discharge guide plate 710 along the inclined slope through vibration, the carbon powder with smaller particles is collected at the discharge outlet 701, the carbon powder with smaller particles falls into the second filter screen 711 and the third filter screen 712 in sequence, the carbon powder with the smallest particles is collected in the recovery drawer 713 uniformly, finally, the other switch 3 is started to enable the slide bar 706 to move along the chute 705, the filter screen is cleaned through the brush hair 707, and the use of the vibrating screen for processing equipment for multi-stage screening is completed.

Specifically, the device body 1 and the springs 4 are welded, the springs 4 are uniformly distributed at the bottom of the device body 1, and the device body 1 is kept stable during vibration through the support of the springs 4.

Specifically, the bottom plate 5 is in adhesive connection with the anti-slip pad 6, and the bottom plate 5 is tightly attached to the anti-slip pad 6, so that the equipment is prevented from moving during vibration, and an anti-slip effect is achieved.

Specifically, discharge ports 701 are formed in the left side and the right side of the device main body 1, a feed inlet 702 is formed in the upper portion of the device main body 1, an infrared dryer 703 is arranged on the inner side of the feed inlet 702, a feed distributing port 704 is connected to the top end inside the device main body 1, a sliding groove 705 is formed in the rear side inside the device main body 1, a sliding rod 706 is arranged in the sliding groove 705, bristles 707 are arranged on the outer side of the sliding rod 706, fixing blocks 708 are arranged on the two sides inside the device main body 1, a first filter screen 709 is arranged above the fixing blocks 708, a discharge guide plate 710 is connected to one side of the first filter screen 709, a second filter screen 711 is arranged below the first filter screen 709, a third filter screen 712 is arranged below the second filter screen 711, a recovery drawer 713 is arranged below the inner portion of the device main body 1, and powder with different sizes is separated through three-layer screen meshes.

Specifically, the sliding groove 705 is slidably connected with the sliding rod 706, and the inner diameter of the sliding groove 705 is matched with the outer diameter of the tail end of the sliding rod 706, so that the sliding rod 706 moves stably along the sliding groove 705.

Specifically, the sliding rod 706 is connected with the bristles 707 through screws, the sliding rod 706 is closely attached to the bristles 707, and the bristles 707 are driven by movement of the sliding rod 706, so that an automatic cleaning function is achieved.

Specifically, welding is adopted between the device main body 1 and the fixing block 708, the device main body 1 is tightly attached to the fixing block 708, and the fixing block 708 is used for placing the filter screen, so that the stability of the filter screen is improved.

Specifically, the device main body 1 is connected with the recovery drawer 713 through a clamping groove, the inner diameter of the device main body 1 is matched with the outer diameter of the recovery drawer 713, and carbon powder passing through the third filter screen 712 falls into the recovery drawer 713, so that the recovery is facilitated.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (8)

1. The utility model provides a shale shaker for multistage screening is equipped with to carbon dust processing is including device main part (1) and screening mechanism (7), a serial communication port, device main part (1) left side is provided with quick-witted case (2), quick-witted case (2) left side is provided with switch (3), spring (4) are installed to device main part (1) bottom, spring (4) below is connected with bottom plate (5), bottom plate (5) bottom is provided with slipmat (6), device main part (1) top and inside are provided with screening mechanism (7), screening mechanism (7) include pan feeding mouth (702), infrared dryer (703), fixed block (708), first filter screen (709) and retrieve drawer (713), pan feeding mouth (702) are installed to device main part (1) top, infrared dryer (703) are installed to fixed block (708) top recovery is provided with first filter screen (709), device main part (1) inside below is provided with drawer (713).

2. A vibrating screen with multi-stage screening for carbon powder processing according to claim 1, characterized in that the welding is between the device main body (1) and the springs (4), and the springs (4) are provided with a plurality of uniformly distributed at the bottom of the device main body (1).

3. The vibrating screen with multi-stage screening for carbon powder processing equipment according to claim 1, wherein the bottom plate (5) is in adhesive connection with the anti-slip pad (6), and the bottom plate (5) is tightly attached to the anti-slip pad (6).

4. The vibrating screen with multistage screening for carbon powder processing according to claim 1, characterized in that a discharge port (701) is formed in the left side and the right side of the device main body (1), a feed port (702) is formed in the upper portion of the device main body (1), an infrared dryer (703) is arranged in the inner side of the feed port (702), a material distributing port (704) is connected to the top end inside the device main body (1), a sliding groove (705) is formed in the rear side inside the device main body (1), a sliding rod (706) is arranged in the sliding groove (705), bristles (707) are arranged on the outer side of the sliding rod (706), fixing blocks (708) are arranged on the two sides inside the device main body (1), a first filter screen (709) is arranged above the fixing blocks (708), a discharge guide plate (710) is connected to one side of the first filter screen (709), a second filter screen (711) is arranged below the first filter screen (709), a third filter screen (712) is arranged below the second filter screen (711), and a drawer (713) is arranged below the inner portion of the device main body (1).

5. The vibrating screen with multi-stage screening for carbon powder processing equipment according to claim 4, wherein the sliding groove (705) is in sliding connection with the sliding rod (706), and the inner diameter of the sliding groove (705) is matched with the outer diameter of the tail end of the sliding rod (706).

6. A vibrating screen with multi-stage screening for carbon powder processing according to claim 4, wherein the sliding rod (706) is in screw connection with the bristles (707), and the sliding rod (706) is closely attached to the bristles (707).

7. A vibrating screen with multi-stage screening for carbon powder processing according to claim 4, wherein the welding is performed between the device main body (1) and the fixing block (708), and the device main body (1) is tightly attached to the fixing block (708).

8. A vibrating screen with multi-stage screening for carbon powder processing equipment according to claim 4, characterized in that the device main body (1) is connected with the recovery drawer (713) through a clamping groove, and the inner diameter of the device main body (1) is matched with the outer diameter of the recovery drawer (713).