CN211707479U - Dust collector is used in nanometer powder ceramic manufacture - Google Patents

Abstract

The utility model discloses a dust removal device for the production of nanometer powder ceramics, which relates to the technical field of ceramic dust removal, in particular to a dust removal device for the production of nanometer powder ceramics. A drain pipe is fixedly installed on one side of the device shell, an elastic net is arranged inside the device shell, and a discharge port is opened on one side of the device shell. The dust removal device for the production of nano-powder ceramics, through the setting of the micro motor on the top of the device shell, can make the micro motor drive the rotating brush at the bottom of the micro motor to perform the first step of dust removal for the ceramic passing through the top of the conveyor belt. After the first step of dust removal, Then, the water is output from the micro nozzle at the bottom of the water outlet on one side of the micro motor, and the water is used to dedust the ceramics on the top of the conveyor belt in the second step, which achieves the effect of double dedusting of the ceramics, and solves the problem that the existing device has poor dedusting effect on the ceramics. question.

Description

A dust removal device for the production of nano-powder ceramics

technical field

The utility model relates to the technical field of ceramic dust removal, in particular to a dust removal device for the production of nanometer powder ceramics.

Background technique

In the ceramic production process, after the raw material mud is pressed and formed, the surface of the green body must be evenly coated with a glaze layer and then fired before the final product can be made into an industrial product. Water spray treatment to remove the dirt and oil on the surface of the green body and make the surface of the green body fully wet, so that the glaze can be fully and evenly attached to the surface of the green body after the green body is glazed. An essential step in production.

In the existing ceramic production line, it is still only possible to use manual dust removal operations on the embryonic body. The efficiency of manual dust removal is low, and the effect of dust removal is also poor, which has a certain impact on the production process of ceramics. A lot of water will be wasted during cleaning. For this reason, we have developed a dust removal device for the production of nano-powder ceramics.

Utility model content

In view of the deficiencies of the prior art, the utility model provides a dust removal device for the production of nano-powder ceramics, which solves the problems raised in the above-mentioned background technology.

In order to achieve the above purpose, the present utility model is achieved through the following technical solutions: a dust removal device for the production of nano-powder ceramics, comprising a device bottom plate, the top of the device bottom plate is provided with a device shell, and one side of the device shell is fixedly installed There is a drain pipe, an elastic net is arranged inside the device shell, a discharge port is opened on one side of the device shell, and a feed port opposite to the discharge port is opened on the other side of the device shell. A conveyor belt is fixedly installed inside the device shell, an asynchronous motor is installed on one side of the device shell, a micro-motor is fixedly installed on the top of the device shell, and a micro-spray head is fixedly installed at the bottom of the inner cavity of the device shell. The top of the casing is provided with a rotating brush on one side of the micro-spray head, and the bottom of the inner cavity of the device casing is provided with a trapezoidal baffle.

Optionally, a left-rotating pulley is fixedly installed inside the left side of the device shell, and a right-rotating pulley having the same specification as the left-rotating pulley is arranged on a relative position on the right side of the device shell. The pulley and the right rotating pulley are placed inside the discharge port and the feeding port, and the outer movable sleeve of the left rotating pulley and the right rotating pulley is connected with a conveyor belt.

Optionally, the output end of the asynchronous motor is fixedly sleeved with a belt, and the asynchronous motor is movably connected with a right rotating pulley through the belt.

Optionally, the top of the drainage pipe is fixedly connected with a water outlet, the top of the drainage pipe is provided with a water inlet located above the water outlet, and the tail end of the drainage pipe is provided with a drainage outlet located at the bottom of the trapezoidal baffle, The outside of the drain pipe is fixedly sleeved with a water pump located in the inner cavity of the device shell, and the outside of the drain pipe is provided with a water purification chamber located outside the device shell.

Optionally, an adsorption net is fixedly installed inside the water purification chamber, a filter screen located below the adsorption net is arranged inside the water purification chamber, and the material of the adsorption net is an activated carbon adsorption net.

Optionally, a telescopic rod is fixedly connected to the output end of the micro motor, a rotating brush is fixedly connected to the bottom end of the telescopic rod, a movable round sleeve is fixedly connected to the bottom of the rotating brush, and the movable round sleeve is The bottom end is provided with a brush head.

The utility model provides a dust removal device for the production of nano-powder ceramics, which has the following beneficial effects:

1. The dust removal device for the production of nano-powder ceramics, through the setting of the micro motor on the top of the device shell, can enable the micro motor to drive the rotating brush at the bottom of the micro motor to perform the first step of dust removal on the ceramic passing through the top of the conveyor belt. After that, the water is output from the micro nozzle at the bottom of the water outlet on one side of the micro motor, and the water is used to dedust the ceramics on the top of the conveyor belt in the second step, which achieves the effect of double dedusting of ceramics, and solves the effect of existing devices on ceramic dedusting. Bad question.

2. The dust removal device for the production of nano-powder ceramics, through the setting of the drain pipe at the bottom of the device shell, can use the water pump outside the drain pipe to extract the wastewater after cleaning at the bottom of the device shell, and extract the wastewater to the inside of the drain pipe. The water purification chamber inside the drain pipe purifies the waste water, and then the purified water is discharged from the water outlet at the top of the drain pipe. The effect of circulating the water used for cleaning ceramics solves the problem of serious waste of water resources in the dust removal process of the existing device.

Description of drawings

Fig. 1 is the structural representation of the utility model;

Fig. 2 is the structural representation of the water purification chamber of the present utility model;

FIG. 3 is an enlarged schematic structural diagram of the position A in FIG. 1 of the present utility model.

In the figure: 1. Device bottom plate; 2. Water pump; 3. Water purification room; 4. Drain pipe; 5. Device shell; 6. Conveyor belt; 7. Left rotation pulley; 8. Material outlet; 10, water inlet; 11, micro motor; 12, telescopic rod; 13, rotating brush; 14, brush head; 15, right rotating pulley; 16, feeding port; 17, elastic net; 18, asynchronous motor; 19. Trapezoidal baffle; 20. Drainage outlet; 21. Adsorption net; 22. Filter net; 23. Micro-sprinkler; 24. Active round sleeve.

Detailed ways

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. Obviously, the described embodiments are only a part of the embodiments of the present utility model, rather than all the implementations. example.

Please refer to FIGS. 1 to 3 , the present utility model provides a technical solution: a dust removal device for the production of nano-powder ceramics, comprising a device bottom plate 1 , a device casing 5 is arranged on the top of the device bottom plate 1 , and a A left rotating pulley 7 is fixedly installed inside, and a right rotating pulley 15 with the same specification as the left rotating pulley 7 is arranged on the relative position on the right side of the device casing 5. The left rotating pulley 7 and the right rotating pulley 15 are placed on the outlet. Inside the material port 8 and the feed port 16, and the outer movable sleeves of the left rotating pulley 7 and the right rotating pulley 15 are the conveyor belts 6, and the conveyor belt 6 can be set to mechanically convey the ceramic embryos. The dedusting of the ceramic body by the micro-nozzle 23 can achieve the effect of high-efficiency mechanical dedusting of the ceramic body, which solves the problem that the existing device can only mechanically dedust the ceramic body and the dedusting effect is poor. A drain pipe 4 is fixedly installed on one side, the top of the drain pipe 4 is fixedly connected with a water outlet 9, the top of the drain pipe 4 is provided with a water inlet 10 located above the water outlet 9, and the tail end of the drain pipe 4 is provided with a trapezoidal baffle plate. 19 The water outlet 20 at the bottom of the drain pipe 4 is fixedly sleeved with the water pump 2 located in the inner cavity of the device shell 5, and the outside of the drain pipe 4 is provided with a water purification chamber 3 located outside the device shell 5. An adsorption net 21 is fixedly installed inside, and a filter net 22 located below the adsorption net 21 is arranged inside the water purification chamber 3, and the material of the adsorption net 21 is an activated carbon adsorption net. The setting can purify the waste water inside the drain pipe 4, and the purified water is discharged from the top of the drain pipe 4 to achieve the effect of recycling the waste water, which solves the problem of serious waste of water resources in the existing device, and the setting of the water pump 2 can The waste water at the bottom of the inner cavity of the device shell 5 is extracted into the drain pipe 4 and the waste water is double-purified by the water purification chamber 3 outside the drain pipe 4. The purified water is then discharged from the water outlet 9 at the top of the drain pipe 4. The water can dedust the ceramic body again, achieve the effect of water circulation, and solve the problem of serious waste of water resources in the existing device. The material port 8, the other side of the device shell 5 is provided with a feed port 16 opposite to the discharge port 8, the conveyor belt 6 is fixedly installed inside the device shell 5, and one side of the device shell 5 is provided with an asynchronous motor 18. The asynchronous motor The output end of 18 is fixedly sleeved with a belt, and the asynchronous motor 18 is movably connected with a right rotating pulley 15 through the belt. The setting of the asynchronous motor 18 can drive the right rotating pulley 15 to rotate, and the right rotating pulley 15 uses the belt to drive the left rotating. The pulley 7 rotates to achieve the effect of driving the conveyor belt 6. The setting of the conveyor belt 6 can achieve the effect of mechanical transportation and dust removal of the ceramic body. The top of the device casing 5 is fixedly installed with a micro motor 11. The output of the micro motor 11 The end is fixedly connected with a telescopic rod 12, the bottom end of the telescopic rod 12 is fixedly connected with a rotating brush 13, and the bottom of the rotating brush 13 is fixedly connected with The movable circular sleeve 24, and the bottom end of the movable circular sleeve 24 is provided with a brush head 14, the setting of the rotating brush 13 can firstly dedust the ceramic body passing through the top of the conveyor belt 6, and the movable circular sleeve 24 inside the rotating brush 13 The arrangement can increase the contact area of the brush head 14 to the ceramic embryo, increase the dust removal effect of the device on the ceramic embryo, achieve the effect of increasing the dust removal efficiency of the device on the ceramic embryo, and solve the problem of the existing device on the ceramic embryo. In order to solve the problem of poor dust removal effect, the bottom of the inner cavity of the device casing 5 is fixedly installed with a micro-spray head 23, the top of the device casing 5 is provided with a rotating brush 13 on one side of the micro-spray head 23, and the bottom of the inner cavity of the device casing 5 is provided with a Trapezoidal baffle 19.

In summary, the dust removal device for the production of nano-powder ceramics, when in use, transports the ceramic embryos from the feed port 16 to the conveyor belt 6 inside the device shell 5, and when the ceramics are transported on the top of the conveyor belt 6, the device is used. The micro motor 11 on the top of the housing 5 drives the rotating brush 13 to remove the ceramics in the first step, and then use the micro nozzle 23 at the bottom of the water outlet 9 to remove the ceramics on the top of the conveyor belt 6 in the second step. The wheel 7 outputs the ceramics, and the dedusted waste water will fall at the bottom of the inner cavity of the device casing 5, and then turn on the water pump 2, the waste water can be pumped into the inside of the drain pipe 4, and the water purification chamber 3 inside the drain pipe 4 purifies the waste water. After purification, the purified water will be transported to the water outlet 9 at the top of the drain pipe 4, and output by the micro-spray head 23 again to achieve the effect of recycling the water. The filter screen 22 can be disassembled and cleaned.

The above are only the preferred specific embodiments of the present invention, but the protection scope of the present invention is not limited to this. Equivalent replacement or modification of the new technical solution and its utility model concept shall be included within the protection scope of the present utility model.

Claims (6)

1. The utility model provides a dust collector for nanometer powder ceramic manufacture, includes device bottom plate (1), its characterized in that: the device comprises a device base plate (1), a device shell (5) is arranged at the top of the device base plate (1), a drain pipe (4) is fixedly arranged on one side of the device shell (5), an elastic net (17) is arranged in the device shell (5), a discharge hole (8) is formed in one side of the device shell (5), a feed inlet (16) opposite to the discharge hole (8) is formed in the other side of the device shell (5), a conveying belt (6) is fixedly arranged in the device shell (5), an asynchronous motor (18) is arranged on one side of the device shell (5), a micro motor (11) is fixedly arranged at the top of the device shell (5), a micro spray head (23) is fixedly arranged at the bottom of an inner cavity of the device shell (5), and a rotating brush (13) located on one side of the micro spray head (23) is arranged at, the bottom of the inner cavity of the device shell (5) is provided with a trapezoidal baffle (19).

2. The dust removing device for the production of nano-powder ceramics according to claim 1, which is characterized in that: the device is characterized in that a left rotating belt wheel (7) is fixedly mounted inside the left side of a device shell (5), a right rotating belt wheel (15) with the same specification as the left rotating belt wheel (7) is arranged on the right side of the device shell (5) in a relative position, the left rotating belt wheel (7) and the right rotating belt wheel (15) are placed inside a discharge hole (8) and a feed hole (16), and a conveying belt (6) is sleeved outside the left rotating belt wheel (7) and the right rotating belt wheel (15) in a movable mode.

3. The dust removing device for the production of nano-powder ceramics according to claim 1, which is characterized in that: the output end of the asynchronous motor (18) is fixedly sleeved with a belt, and the asynchronous motor (18) is movably connected with a right rotating belt wheel (15) through the belt.

4. The dust removing device for the production of nano-powder ceramics according to claim 1, which is characterized in that: the water purifier is characterized in that a water outlet (9) is fixedly connected to the top end of the drain pipe (4), a water inlet (10) located above the water outlet (9) is formed in the top of the drain pipe (4), a water outlet (20) located at the bottom of the trapezoid baffle (19) is formed in the tail end of the drain pipe (4), a water pump (2) located in an inner cavity of the device shell (5) is sleeved on the external fixing of the drain pipe (4), and a water purifying chamber (3) located outside the device shell (5) is arranged outside the drain pipe (4).

5. The dust removing device for producing nano-powder ceramics according to claim 4, characterized in that: the inside fixed mounting of water purification room (3) has adsorption net (21), the inside of water purification room (3) is provided with filter screen (22) that are located adsorption net (21) below, and the material of adsorption net (21) is activated carbon adsorption net.

6. The dust removing device for the production of nano-powder ceramics according to claim 1, which is characterized in that: the output fixedly connected with telescopic link (12) of micro motor (11), the bottom fixedly connected with rotary brush (13) of telescopic link (12), the bottom fixedly connected with activity cover (24) of rotary brush (13), and the bottom of activity cover (24) is provided with brush head (14).

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