KR102135845B1 - Fly ash distribution device - Google Patents

Abstract

The present invention provides a distribution apparatus for a fly ash mixer, which installs a conveyor reciprocating when fly ash generated in case of incineration treatment falls and is discharged to be stored in a storage tank after the fly ash generated in case of incineration treatment is stabilized with heavy metal in the fly ash mixer, thereby allowing the fly ash to be evenly stored in the storage tank as a whole.

Description

Fly ash distribution device

The present invention relates to a distribution device for a fly ash kneader, and more specifically, a fly ash is installed by installing a conveyor that reciprocates when stabilizing heavy metal in a fly ash kneader and then dropping it and storing it in a storage tank. It relates to a distribution device for a fly ash kneader that can be stored evenly throughout.

Generally, heavy metals such as mercury, cadmium, zinc, and lead are contained in fly ash generated from incinerators, thermal power plants, and ironworks. Therefore, when the fly ash containing heavy metals is buried as it is, there is a problem of contaminating the soil and water, so that the heavy metals are stabilized and treated in a state of environmental protection.

As an example of a method for stabilizing a heavy metal in a fly ash, it is disclosed in Korean Patent Publication No. 1998-71946, Registered Patent No. 10-0327826, Registered Patent No. 10-0201520, and the like.

Referring to this, the method of stabilizing the heavy metals in the fly ash guides the fly ashes generated during incineration to the fly ash kneader, adds water and chelate, and mixes and mixes them to mix and mix them, and then post-process such as reclaiming them by storing them in a storage tank and reclaiming them. Is done.

However, in the prior art, when the solidified fly ash discharged from the fly ash kneader is stored in a storage tank in a dropping manner only in one place, the solidified fly ash is stored in a manner of accumulating like a mountain in a storage tank and flowing down. Therefore, there is a problem in that the fly ash is not evenly stored in the storage tank and the storage space is wasted. That is, when the solidified fly ash is stored in the storage tank, only 60% to 70% of the storage space is stored, and thus there is a problem in that efficiency and economic efficiency are deteriorated.

For reference, since the storage tank has a deep storage depth and a viscosity of the solidified fly ash, it is dangerous and impossible to perform an operation that allows an operator to enter the reservoir and spread the solidified fly ash evenly.

1) Republic of Korea Registered Patent No. 10-0327826 (Registration Date: February 26, 2002), Name of the invention: "Processing method of heavy metal-containing incinerator" 2) Republic of Korea Patent No. 10-0201520 (Registration Date: March 15, 1999), Title of the invention: "Processing and treatment device for wastes containing heavy metals" 3) Republic of Korea Patent No. 10-0613493 (Registration Date: August 09, 2006), Title of the invention: "Pre-treatment method and device for flooring generated when incinerating household waste" 4) Republic of Korea Patent No. 10-0506331 (Registration Date: July 28, 2005), Name of the invention: "Stabilization treatment method of incineration fly ash"

The present invention has been proposed to improve the above-mentioned problems, the purpose of which is installed in the discharge port of the fly ash kneader, and the heavy metal stabilized fly ash is stored in a manner of dropping and discharging to the storage tank through the outlet of the fly ash kneader. It is to provide a distribution device for a fly ash kneader that can efficiently use a storage space by allowing it to be spread and distributed evenly over a storage tank rather than being put in one place.

The above-mentioned object is to be installed in a fly ash kneader having a structure for stabilizing the heavy metals and discharging them through a discharge port and storing them in a storage tank by mixing and mixing water and chelate into the fly ash inputted through the input port. Conveyor belt at one end is supported by a driving drum and the other end is supported by a driven drum and installed in a circulating motion, a side frame installed side by side on both sides of the conveyor, and connected to the drive drum and rotatably installed on the side frame A drive shaft, a driven shaft connected to the driven drum and rotatably installed on a side frame, a wheel shaft installed to be rotatably supported on a side frame at the front and rear sides of the conveyor, and wheels installed at both ends of the wheel shaft And, the bottom frame installed on the rail is mounted long along the longitudinal direction from the bottom of the conveyor, the wheel is mounted on the rail, and a driving means for selectively rotating the drive shaft and the wheel shaft in the forward or reverse direction, the drive When the means is operated in the forward direction, the upper surface of the conveyor belt rotates clockwise, and the conveyor moves forward along the rail. When the driving means is operated in the reverse direction, the upper surface of the conveyor belt rotates counterclockwise and the conveyor moves backward along the rail. As it is configured, when the heavy metal stabilized fly ash is discharged through the outlet of the fly ash kneader, the driving means operates in the forward direction to operate the conveyor belt clockwise and at the same time stabilize the heavy metal falling onto the conveyor while the conveyor moves forward. The treated fly ash is continuously dropped to the front of the storage tank to spread and spread evenly in front of the storage tank to be input and stored. When the conveyor reaches the forefront, the driving means operates in the reverse direction, the conveyor belt operates counterclockwise and the conveyor moves backward. As the heavy metal stabilized fly ash falling onto the conveyor while moving continuously falls to the rear of the storage tank, it spreads evenly across the rear of the storage tank to be input and stored, and when the conveyor reaches the rear end, the driving means moves back to the forward direction. As it operates, the conveyor reciprocates back and forth, and when the conveyor reaches the fore or aft end, the end of the conveyor is separated from the outlet. It is configured to be, the drive means is connected to a drive motor fixed to a portion of the side frame, a gearbox for connecting the shaft and the drive shaft of the drive motor to transmit power to the drive shaft to rotate the drive shaft, and the drive shaft It consists of a drive gear, a driven gear connected to the wheel shaft, and a timing belt that connects the drive gear and the driven gear to transmit power of the drive shaft to the wheel shaft so that the wheel rotates, and the diameter of the driven gear is larger than that of the drive gear. It is formed is achieved by a distribution device for a fly ash kneader characterized in that the circulating speed of the conveyor belt is operated faster than the moving speed of the conveyor, and the heavy metal stabilized fly ash is configured to stably operate when falling into the storage tank through the conveyor.

delete

delete

delete

In addition, the side frame is provided with a side cover that prevents flying ash from protruding upwards and covers a part of the conveyor belt so that a wall that prevents the heavy metal stabilized fly ash from falling to both sides when moving along the conveyor belt is formed. It is characterized by being configured.

In addition, a limit switch is installed at the front and rear of the floor frame, and when the conveyor reaches the front, the front limit switch detects this and operates the driving means in the reverse direction. When the conveyor reaches the rear, the limit switch at the rear is used. It is characterized in that it is configured to detect and operate the driving means in the forward direction to make repeated forward and backward movements.

The dispensing device for the fly ash kneader according to the present invention is additionally installed at the outlet of the fly ash kneader so that the heavy metal stabilized fly ash is stored in the storage tank as the conveyor reciprocates and distributes the fly ash evenly back and forth to the storage tank. It does not fall only to the place, but spreads evenly throughout and falls and is stored. As a result, more than 90% of the storage space of the storage tank is used, and efficiency and economic efficiency are improved when post-processing.

1 is a front view showing the configuration of a distribution device for a fly ash kneader according to the present invention,
Figure 2 is a plan view showing the configuration of a distribution device for fly ash kneader according to the present invention,
Figure 3 is a side view showing the configuration of a distribution device for a fly ash kneader according to the present invention,
Figure 4 is a front view showing a state in which the distribution device for a fly ash kneader according to the present invention is installed in a fly ash kneader,
Figure 5 is a side view showing a state in which the distribution device for a fly ash kneader according to the present invention is installed in a fly ash kneader,
6 to 8 is an operation diagram for explaining the operating state of the dispensing device for a fly ash kneader according to the present invention.

The present invention will be described in detail with reference to the accompanying drawings.

1 to 5, the distribution device for the fly ash kneader according to the present invention is installed at the bottom of the fly ash kneader 10, and when the heavy metal stabilized fly ash falls through the outlet 14, it is forward and backward through a conveyor method. It is configured to disperse the scattering material evenly while moving reciprocatingly, so as to be input and stored in the storage tank 20.

For reference, the fly ash kneader 10 is provided with an inlet 12 at the rear upper part, an outlet 14 at the front lower part, and water and chelate mixed with the fly ash introduced through the inlet 12 to mix it. It is configured to discharge the fly ash in a dropping manner through the outlet 14 after stabilizing the heavy metal. Since the fly ash kneader 10 is a known technique, detailed description will be omitted.

According to the present invention, the distribution device for the fly ash kneader is installed at the bottom of the fly ash kneader 10, the conveyor 100, the side frame 200, the wheel 310, the floor frame 400, the driving means 500 ).

First, the conveyor 100 is installed to be able to reciprocate back and forth from the bottom of the outlet 14 of the fly ash kneader 10, and the conveyor belt 110 is installed to rotate in a clockwise or counterclockwise direction. That is, the conveyor 100 is installed to be able to reciprocate back and forth through the wheel 310 to be described later, the conveyor belt 110 has one end supported by the driving drum 120 and the other end supported by the driven drum 130 for driving It is installed to circulate by the rotational force of the drum 120. In addition, a plurality of guide rollers 140 are installed in the middle of the conveyor belt 110 so that the conveyor belt 110 is stably operated without partially sagging.

Next, the side frame 200 is installed side by side on both sides of the conveyor 100, and the drive drum 120 and the driven drum 130 are installed to be supported on the side frame 200. That is, on both sides of the drive drum 120, the drive shaft 122 is connected to protrude, and the drive shaft 122 is rotatably installed on the side frame 200. In addition, the driven shaft 132 is protrudedly connected to both sides of the driven drum 130, and the driven shaft 132 is also rotatably installed on the side frame 200.

In addition, the upper side of the side frame 200 is installed to cover the portion of the conveyor belt 110 protruding upwardly from the conveyor belt 110, and to cover a part of the conveyor belt 110, the heavy metal stabilized fly ash is conveyor belt It is configured to form a wall that does not fall to both sides when moving along the (110).

Next, in the lower part of the conveyor 100, the wheel axle 300 is installed to be rotatably supported by the side frame 200 at the front and rear, respectively, and wheels 310 are provided at both ends of the wheel axle 300. It is installed to rotate with the shaft (300). And the bottom frame 400 is installed along the longitudinal direction in the lower portion of the conveyor 100, the upper surface of the floor frame 400 is installed to protrude on the rail 410, the wheel 310 rides and moves. Therefore, the conveyor 100 is installed to be moved back and forth along the rail 410 through the wheel 310. At this time, when the conveyor 100 reaches the forefront or the rear end, the end portion of the conveyor 100 is installed spaced apart from the outlet 14 and the heavy metal stabilized fly ash discharged through the outlet 14 does not pass through the conveyor 100 It is configured to fall directly to the storage tank 20 without.

Next, the conveyor 100 is configured to operate through the driving means 500. That is, when the driving means 500 is connected to the driving shaft 122 and the wheel shaft 300 and the driving means 500 is operated, the driving shaft 122 and the wheel shaft 300 are selectively rotated together in the forward or reverse direction. .

Here, the driving means 500 is connected to the drive motor 510 fixed to a part of the side frame 200, the shaft of the drive motor 510 and the drive shaft 122 to drive the power of the drive motor 510 ( Gearbox 520 to be transmitted to the drive shaft 122 to rotate, a drive gear 520 connected to the opposite side of the drive shaft 122, a driven gear 540 connected to the wheel shaft 300, and a drive gear It is composed of a timing belt 550 that connects the 520 and the driven gear 540 to transmit the power of the drive shaft to the wheel shaft 300 so that the wheel 310 rotates.

Accordingly, when the driving means 500 is operated in the forward direction, the upper surface of the conveyor belt 110 rotates clockwise while the driving shaft 122 rotates clockwise, and at the same time, the power of the driving shaft 122 and the driving gear 520 It is transferred to the wheel shaft 300 through the driven gear 540 and the conveyor 100 rotates along the rail 410 while the wheel 310 rotates. And when the driving means 500 is operated in the reverse direction, while the driving shaft 122 rotates counterclockwise, the upper surface of the conveyor belt 110 circulates counterclockwise, and at the same time, the power of the driving shaft 122 is driven. ) And transferred to the wheel shaft 300 through the driven gear 540 while the wheel 310 rotates, the conveyor 100 reverses along the rail 410.

At this time, since the diameter of the driven gear 540 is larger than that of the driving gear 520, the circulation speed of the conveyor belt 110 operates faster than the moving speed of the conveyor 100, so that the heavy metal stabilized fly ash conveyor 100 It is preferably configured to operate stably when falling to the reservoir 20 through.

In addition, limit switches 420 are installed at the front and rear of the bottom frame 400, respectively, and when the conveyor 100 reaches the front, the front limit switch 420 detects this and operates the driving means 500 in the reverse direction. When the conveyor 100 reaches the rear end, the limit switch 420 at the rear end senses this and operates the driving means 500 in the forward direction to be repeatedly moved back and forth. Here, the limit switch 420 may be replaced by another sensor having the same function.

Now, the operation and effect of the distribution device for a fly ash kneader according to the present invention configured as described above will be described.

When the fly ash is introduced into the inlet 12 of the fly ash kneader 10, the fly ash is mixed with water and chelate in the fly ash kneader 10, stabilized by heavy metals, and then discharged through the outlet 14. Then, the distribution device for the fly ash kneader according to the present invention can be spread and distributed evenly throughout the storage tank 20 while reciprocating the heavy metal stabilized fly ash back and forth.

That is, when the heavy metal stabilized fly ash is discharged through the outlet 14 of the fly ash kneader 10, first, as shown in FIG. 6, the driving means 500 operates in the forward direction, and the conveyor belt 110 operates clockwise. At the same time, while the conveyor 100 moves forward, the heavy metal stabilized fly ash falling on the conveyor 100 is continuously dropped to the front of the storage tank 20 and spreads evenly in front of the storage tank 20 to be input and stored. And when the conveyor 100 reaches the foremost, the limit switch 420 in the foremost senses this and operates the driving means 500 in the reverse direction. Then, as shown in FIG. 8, while the driving means 500 operates in the reverse direction, the conveyor belt 110 operates counterclockwise, and at the same time, the heavy metal stabilized fly ash falling onto the conveyor 100 while the conveyor 100 moves backwards. It is continuously dropped to the rear of the storage tank 20 and spreads evenly behind the storage tank 20 to be input and stored. And when the conveyor 100 reaches the rear end, the limit switch 420 at the rear end senses this and operates the driving means 500 again in the forward direction. Therefore, the conveyor 100 is repeatedly reciprocated back and forth repeatedly and spreads the heavy metal stabilized fly ash evenly back and forth in the storage tank 20 to be input and stored. At this time, when the conveyor 100 reaches the front or rear end, as shown in FIG. 7, since the end of the conveyor 100 is spaced from the outlet 14, the heavy metal stabilized fly ash is directly dropped into the middle portion of the storage tank 20 It is spread evenly throughout the storage tank 20 and is input and stored.

Briefly explaining this operation, when the driving means 500 is operated, the conveyor 100 first moves to the front and guides the heavy metal stabilized fly ash to the front of the storage tank 20 to be evenly stored in the front of the storage tank 20. And, when the conveyor 100 reaches the forefront, the heavy metal stabilized fly ash is dropped to the middle portion of the storage tank 20 to be evenly stored in the middle portion of the storage tank 20, and the conveyor 100 is moved back to the rear. When moving, the heavy metal stabilized fly ash is guided to the rear of the storage tank 20 to be evenly stored in the rear of the storage tank 20, and when the conveyor 100 reaches the rear end, the heavy metal stabilized fly ash is stored in the storage tank ( The operation of repeatedly dropping to the middle portion of the 20) and evenly storing the middle portion of the storage tank 20 is repeated, and the heavy metal stabilizing scattering material is evenly spread throughout the storage tank 20 to be input and stored.

Meanwhile, according to the present invention, it is preferable that the conveyor belt 110 is coated with a liquid composition to enhance durability.

These liquid compositions include 2.5% by weight of ethylene glycol, 3.5% by weight of dichloromethane-oic acid, 3.0% by weight of pyromethic acid, and methylsiliconate 5.0 to maintain surface protection, contamination prevention, scratch resistance and discoloration resistance. It consists of weight percent, 2.5 weight percent of polycarbonate resin, 2.5 weight percent of titanium oxide, 3.0 weight of sulfolapan (C ₆ H ₁₁ NOS ₂ ) and the remaining PET resin.

At this time, the ethylene glycol is to increase the occlusality between the conveyor belt and the coated surface while controlling the viscosity. In addition, the dichloromethane-oic acid contributes to suppress layer separation at the occlusal surface by eroding the coated surface to form anchoring. In addition, the pyromeric acid is added to suppress heat shrinkage of the conveyor belt and enhance slip resistance to maintain sticky resistance. In addition, the methylsiliconate also provides an anti-fouling function to keep the surface smooth to prevent contamination while providing strong water repellency. In addition, the polycarbonate resin is added to increase durability and enhance scratch resistance. In addition, the titanium oxide maintains a UV shielding function, and the sulforaphane is added to enhance resistance to discoloration by increasing resistance to UV rays. And, the PET resin is added to enhance the interface bonding property while maintaining durability.

In addition, the conveyor belt 110 may further perform an antibacterial antifouling layer coating step after coating the liquid composition, so that heat dissipation, moisture resistance, and antifouling properties are enhanced. At this time, in the antibacterial antifouling layer coating step, the resin composition for implementing the antibacterial antifouling layer may be coated with a uniform thickness by a spray method.

Here, the resin composition for forming the antibacterial antifouling layer is 10% by weight of boron nitride (BN) powder, 2.5% by weight of graphite, 5% by weight of octamethylcyclotetrasiloxane, 2.5% by weight of methacrylic acid, and palmitic acid It consists of 3.5% by weight, 5% by weight of chitosan oxide, 5% by weight of isoquinoline alkaloid, 5% by weight of epoxy resin and polypropylene resin in which the remaining CNTs are dispersed.

At this time, the boron nitride is a material having a hexagonal crystal structure, high thermal conductivity, good heat dissipation properties, and excellent chemical stability. In addition, the graphite is added to increase the dispersion effect while obtaining light weight and high emissivity, and in particular, by allowing the particle shape to have a flake type, it is closely mixed between the polymer resin (polypropylene resin, which is the base resin), and the thermal conductivity and smoothness are improved. It is added to obtain a dispersion effect. This is to achieve long life by preventing deformation caused by thermal expansion of a portion installed and used while exposed to the outside. In addition, octamethylcyclotetrasiloxane (octamethylcyclotetrasiloxane) is intended to increase the dispersion stability and water resistance of the resin composition, in particular, since octamethylcyclotetrasiloxane is a waterproof organic material, it is also added to enhance water repellency and suppress adhesion of contaminants. In addition, since methacrylic acid is strong in acid, it is added to maintain corrosion resistance, and the palmitic acid formula is a waxy solid fatty acid having the formula CH ₃ (CH ₂ ) ₁₄ COOH. ) In order to be able to slide smoothly without sticky. In addition, the chitosan oxide and isoquinoline alkaloids are natural antibacterial agents that enhance antibacterial and immunity properties. In the present invention, it is configured to suppress the harmfulness of the human body by using a natural antibacterial agent without using a chemical type antibacterial agent. In particular, isoquinoline alkaloids are extracts extracted from Bitter Melon, barberry roots, and barberry roots, and are natural antibacterial agents against fungi as well as fungi, such as Salmonella. In addition, the epoxy resin is added to enhance the adhesion to prevent interfacial separation and to secure a stable adhesion, and polypropylene resin in which CNT (Carbon Nano Tube) is dispersed induces uniform dispersion of CNT to enhance heat dissipation characteristics, Base resin for increasing adhesion stability and durability. In particular, CNT has a hexagonal honeycomb-shaped graphene sheet that has a diameter of several nanometers and is rounded to form a tube, and by ultrasonic dispersion, 5-10 parts by weight based on 100 parts by weight of this resin in polypropylene resin. Use a uniform dispersion in the range. This is to maintain the heat dissipation improvement properties of CNTs.

As described above, the present invention has been illustrated and described in connection with specific embodiments, but various modifications and changes are possible within the limits without departing from the spirit and scope of the invention indicated by the claims. Anyone who grows up will know.

10: fly ash kneader 12: inlet
14: outlet 20: storage tank
100: conveyor 110: conveyor belt
120: drive drum 122: drive shaft
130: driven drum 132: driven shaft
200: side frame 210: scattering prevention side cover
300: wheel axle 310: wheel
400: bottom frame 410: rail
500: drive means 510: drive motor
520: gearbox 520: drive gear
540: driven gear 550: timing belt

Claims (4)

It is installed on a fly ash kneader having a structure in which water and chelate are added to the fly ash injected through the inlet to mix and stabilize the fly ash by heavy metal stabilization and then discharged through the outlet to be stored in the storage tank.
Conveyor belt at the bottom of the outlet is supported by a driving drum, the other end is supported by a driven drum, and a conveyor installed to circulate,
Side frames installed side by side on both sides of the conveyor,
A driving shaft connected to the driving drum and rotatably installed on a side frame;
A driven shaft connected to the driven drum and rotatably installed on a side frame,
Wheel axles are installed to be rotatably supported on the side frames at the front and rear, respectively, from the bottom of the conveyor,
Wheels installed at both ends of the wheel axle,
And a bottom frame installed on the rail is mounted long along the longitudinal direction from the bottom of the conveyor, wheels move on the upper surface,
Including the driving means for selectively rotating the drive shaft and the wheel shaft in the forward or reverse direction,
When the driving means is operated in the forward direction, the upper surface of the conveyor belt rotates in a clockwise direction while the conveyor advances along the rail. When the driving means is operated in the reverse direction, the upper surface of the conveyor belt rotates in a counterclockwise direction while the conveyor rotates the rail. As it is constructed backward,
When the heavy metal stabilized fly ash is discharged through the outlet of the fly ash kneader, the driving means operates in the forward direction to operate the conveyor belt clockwise and at the same time, the heavy metal stabilized fly ash falling onto the conveyor while the conveyor moves forward. It continuously falls to the front of the storage tank, spreads evenly in front of the storage tank, and is input and stored. When the conveyor reaches the foremost direction, the driving means operates in the reverse direction, the conveyor belt operates counterclockwise, and at the same time, the conveyor moves backwards. The heavy metal stabilized fly ash falling to the back is continuously dropped to the rear of the storage tank and spreads evenly at the rear of the storage tank to be input and stored. When the conveyor reaches the rear end, the driving means operates again in the forward direction, and the conveyor reciprocates back and forth. When the conveyor reaches the front end or the rear end, the end of the conveyor is separated from the outlet, and at this time, the heavy metal stabilized fly ash falls directly to the middle of the storage tank and is configured to be spread and evenly distributed throughout the storage tank.
The driving means is a drive motor fixed to a part of the side frame, a gearbox connecting the shaft and the drive shaft of the drive motor to transmit the power of the drive motor to the drive shaft, a drive box connected to the drive shaft, a drive gear connected to the drive shaft, and a wheel shaft It consists of a driven gear connected to, and a timing belt that connects the drive gear and the driven gear to transmit power from the drive shaft to the wheel axle so that the wheel rotates.
The diameter of the driven gear is formed larger than that of the drive gear, so that the circulation speed of the conveyor belt operates faster than the movement speed of the conveyor, and is configured to stably operate when the heavy metal stabilized fly ash falls to the storage tank through the conveyor. Dispensing device for fly ash kneader.
delete According to claim 1,
The side frame is provided with a side cover that prevents flying ash from protruding upwards than the conveyor belt and covers a part of the conveyor belt to form a wall that prevents heavy metal stabilized fly ash from falling to both sides when moving along the conveyor belt. Dispensing device for a fly ash kneader, characterized in that.
According to claim 1,
Limit switches are installed at the front and rear of the floor frame, respectively. When the conveyor reaches the front, the front limit switch detects it and operates the driving means in the reverse direction. When the conveyor reaches the rear, the rear limit switch detects it. Dispensing device for a fly ash kneader, characterized in that it is configured to repeat the forward and backward movement by operating the drive means in the forward direction.

Images