KR200208475Y1 - Pelletizer - Google Patents

Abstract

The present invention relates to a drum-type granule manufacturing apparatus, characterized in that the cake is put into a rotating iron circular housing to produce granules and coated inside the housing, thereby enabling mass production of granular products as a simple facility. In that,

A main body comprising a first molded part formed of a housing in the form of a round iron pipe, and a second molded part formed in the form of a round iron pipe; A spiral blade portion inserted into and fixed to the inside of the second molding portion of the main body so that the nucleus passing through the first molding portion may gradually move inside the second molding portion and be subjected to friction and impact at the same time; A coating part attached to an end of the second molding part of the main body and putting dry powder to form a material having passed through the second molding part into granules of a composite component; A scraper that scrapes the cake that is tightly fixed to the inner circumference of the housing of the first molding part of the main body and does not form a nucleus and adheres to the inner wall of the first molding part; It is characterized in that it comprises a drive unit for being in close contact with the outer periphery of the housing constituting the main body to rotate the first molded part and the second molded part.

Description

Drum-type granule manufacturing device {Pelletizer}

The present invention relates to a drum-type granulator manufacturing apparatus, and in particular, by inserting a cake into a rotating steel circular molding machine to produce granules, and coating the granules in the molding machine, it is possible to mass-produce granular products as a simple equipment It relates to a drum-type granules manufacturing apparatus characterized in that.

Conventionally, in the production of granular products, extrusion molding was used as a pot pelletizer or a small amount of production, but the production volume was large, expensive, difficult to transport, and difficult to manufacture. Installation required a lot of cost, technology and time.

The present invention is to solve the above problems,

Waste sludge produced as a large amount of industrial waste is made into granules and recycled as raw materials, and sludge, powdered lime, powder siliceous fertilizer, powder slag siliceous fertilizer, powdered clay fertilizer, etc. are made into granular products. The purpose is to be able to produce granules from all powders, such as to produce a complex fertilizer by mixing with.

As a means for achieving the above object,

The first molded part made of a housing made of a circular iron pipe so that the material introduced into it by the self-rotation is formed by agglomeration of fine particles, and the core is passed through the self-rotation so that the core is subjected to friction and impact. A drum-shaped main body comprising a second molded part in the form of a circular steel pipe connected to the housing of the first molded part so as to have a round shape in the form of large and hard granules;

A spiral blade portion inserted into and fixed to the inside of the second molding portion of the drum body so that the nucleus passing through the first molding portion may gradually move inside the second molding portion and be subjected to friction and impact at the same time;

A coating part attached to an end of the second molding part of the drum-type body and putting dry powder to form a material having passed through the second molding part into granules of a composite component;

A scraper which scrapes the cake which is tightly fixed to the inner circumference of the housing of the first molding part of the drum-shaped body and does not form a nucleus and adheres to the inner wall of the first molding part;

It is characterized in that it comprises a drive unit which is in close contact with the outer periphery of the housing constituting the drum-like body to rotate the first molding portion and the second molding portion at the same time.

1 is a first embodiment showing the overall configuration of the present invention.

Figure 2 is a second embodiment showing the overall configuration of the present invention.

Figure 3 is a third embodiment showing the overall configuration of the present invention.

Figure 4 is a first embodiment of a drum-shaped body of the present invention.

5 is also a second embodiment of the drum-shaped body of the present invention.

Figure 6 is a third embodiment of the drum-shaped body of the present invention.

7 is a block diagram of the main body drive unit of the present invention.

8 is a helical wing configuration of the present invention.

9 is a block diagram of the present invention.

Explanation of symbols on the main parts of the drawings

10: first molding part 20: second molding part

30: spiral wing 40: coating

50: scraper 60: drive unit

70: third molding part 100: drum-shaped body

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

1 is a first embodiment showing the overall configuration of the present invention.

Figure 2 is a second embodiment showing the overall configuration of the present invention.

3 is a third embodiment showing the overall configuration of the present invention,

The first molded part 10 is formed of a housing made of a circular steel pipe so that the material introduced therein by the self-rotation is formed by agglomeration of fine particles, and friction and impact are generated while the nucleus is passed by the self-rotation. A drum-shaped main body (100) consisting of a second molded part (20) in the form of a round iron pipe connected to the housing of the first molded part (10) so as to receive a round shape of a complete shape and become large, hard granules;

The core of the drum-shaped body 100 is helically inserted into the second molding part 20 and the nucleus passing through the first molding part 10 gradually moves inside the second molding part 20 while simultaneously rubbing. Spiral wing portion 30 to be subjected to shock and;

A coating part 40 attached to an end of the second molding part 20 of the drum-type body 100 and putting dry powder to form a material having passed through the second molding part 20 into granules of a composite component; ;

A scraper (50) which scrapes the cake which is tightly fixed to the inner circumference of the housing of the first molding part (10) of the drum-shaped body (100) and does not form a nucleus and sticks to the inner wall of the first molding part (10);

It comprises a drive unit 60 in close contact with the outer periphery of the housing constituting the drum-shaped body 100 to rotate the first molding unit 10 and the second molding unit 20 at the same time.

In the above, FIG. 1 illustrates a linear body configuration, FIG. 2 illustrates a main body configuration including a third molding part, and FIG. 3 illustrates a conical body configuration.

4 illustrates the main body in the configuration diagram of FIG. 1, FIG. 5 illustrates the main body in the configuration diagram of FIG. 2, and FIG. 6 illustrates the main body in the configuration diagram of FIG. 3.

And, Figure 7 shows a drive unit for driving the granules manufacturing apparatus of Figures 1 and 2 and 3, Figure 8 shows a spiral blade embedded in the granules manufacturing apparatus of Figures 1 and 2 and 3 and 9 shows a scraper inserted into the granule manufacturing apparatus of FIGS. 1 and 2 and 3.

In the present invention configured as described above, the material for making granules has a powder level of 100 mesh to 200 mesh (of which 60% or more will be 200 mesh or less), and a water content of 15 to 18% (weight) of cake state It is preferable to use a chain that is smaller than the diameter of the granules to make the powder of.

When the material is introduced into the first molding part 10, the material is rotated along the inner wall of the first molding part 10 by the centrifugal force of the rotating main body 100. Since the gravity of the material becomes greater than the centrifugal force and the frictional force at an enlarged angle), the material is rolled down while being subjected to the friction of the inner wall surface of the first molding part 10.

At this time, by the surface tension caused by the moisture of the material, the microparticles are attracted to each other to form a nucleus, which is a small grain, and the nucleus continues to attract other small particles around it and becomes larger and larger.

However, the cake in which the nucleus is not formed as described above is attached to the inner wall surface of the first molding part 10. In order to prevent this, the scraper 50 scraping off the attached material is attached to the first molding part. It should be installed in close contact with the inner circumference of (10).

In addition, the input of the material is a high production efficiency when a certain amount of continuous input, the injected material is the first molding part 10 at a constant speed by the installation inclination angle of the machine (about 5 degrees, the inlet and outlet side) Passing through and passing through the second molding part 20 by the rotation of the spiral blade 30 is a continuous process is made.

And, if given a constant inclination angle when installing the machine as described above, each time the main body 100 is rotated by 1 to 300 ~ 400mm material moves toward the outlet.

When the first molded part 10 is formed in a tapered cone shape as shown in FIG. 3, the material is smoothly moved without providing an inclination angle, and the spiral molded part 30 is formed in the second molded part 20. It is moved to the action of the continuous process is made.

The rotational speed of the main body 100 is to be adjusted according to the size of the material viscosity and the diameter of the drum, so that the rotational speed of the drum-type main body 100 can be adjusted, and the rotational speed per minute is about 15-20 rpm.

The input amount of the material varies slightly depending on the input material and the feed rate of the material in the main body by the inclination of the main assembly, but the experimental results are as follows.

That is, the determination formula of the input amount of the material,

Input amount of material per hour = Radius of the main body of the inlet (M) * Feeding speed per second (M) of the material by the inclination of the drum * 0.05 (The accumulated thickness of the injected material, M) * 3600 (Converts the time in seconds) * Specific gravity of the material

In the above formula, the drum-type main body 100 uses a pipe of 2400 mm in diameter, the specific gravity of the material is 1.5, and the inclination of the main body 100 is installed so that the material injected in one rotation of the main body is transferred 300 mm toward the rear of the drum. If so, the input of material per hour and the output of the product are:

1.2 * 0.1 * 0.05 * 3600 * 1.5 = 32.4 tons / hour.

When the material is first introduced into the first molding part 10, small particles cling to the inner wall of the first molding part 10, and the particles grow and grow faster and stick to each other. It must be removed, but if it is removed continuously, the yield of granules is increased and there is no stoppage.

Therefore, as mentioned above, a scraper 50 having a rubber plate attached to the steel frame is installed therein to remove particles adhering to the inner wall of the housing.

On the other hand, between the first molded part 10 and the second molded part 20 is a third formed part consisting of a circular iron pipe of about 200 mm in diameter and shorter in length than the first molded part 10 and the second molded part. Can be produced by inserting the 70 bar, which is intended to produce a large diameter granules, reducing the input amount of the material in the first molding portion 10, if the second input of the material to the first input The second injected material is coated on the surface of the granules made of granules and the diameter of the granules is increased.

In order to inject the material into the secondary material, the conveyor belt is extended to the third molding part 70, and the conveyor belt is installed to pass through the hole center point of the first molding part 10. The technology to put into the three molding unit 70 is not shown in the present invention because the general conveyor belt is to be placed through the first molding unit 10.

On the other hand, the spiral wing 30 is attached to the inner wall of the second molded part 20, the wing 30 serves to receive a lot of friction and impact of the nucleus made in the first molded part 10 is complete It is made of round, large, hard granules in the form and makes the granules uniform.

However, if the spiral blade 30 is not provided as described above, a large amount of time is required because the granules are made with a flat inner circumference, and the resulting large-sized granules attract other small particles around them. The diameter of the granules is uneven, the strength is small, the roundness is not round, and the granules are formed in many shapes, the lengths of the molding parts 10 and 20 are lengthened, and the oversize granules are made a lot, so that the yield is high. It will fall a lot, if you install the spiral wing 30 as in the present invention can solve all the above disadvantages.

The spiral blade 30 is attached to the start portion is to increase the spacing of the blade to about 400mm to prevent the cake is attached and gradually narrow the gap to narrow to 250mm.

And, the width of the wing 30 is about 150mm is enough, but if the length of the housing is long, there is a risk that the housing may occur while rotating, it is preferable to advance the height of the wing to 200mm to prevent this.

Therefore, when the manufacture of the desired granules by installing the spiral blades 30 as described above, the fine cakes are attracted to each other by the surface tension caused by moisture and are subjected to impact and friction, thereby making granules uniform in size. When the granules are impacted, the moisture in the granules is released to the surface of the granules by capillary action.

Moisture is released from the water by increasing the surface tension and attracting other small particles around it. If you put dry powder without moisture, the dry powder is coated (coated) on the surface of the granules. Since the dry powder is dropped a lot, the drying cost is reduced, and the yield of the coated dry powder is increased, and the dry powder with different ingredients can be added to make a granulated product of a composite component.

For this process, the coating 40 having a larger diameter than the second molding part 20 is attached to the second molding part 20 so that the granules transferred from the second molding part 20 are coated with the coating part 40. Rotating in a stacked state about 4 times inside the) to allow the dry powder to be coated during rolling.

As described above, the present invention is characterized in that it is suitable for mass production at an inexpensive facility cost in the production of granules, and is expected to have a large effect on reducing production costs, thereby fertilizing industrial wastes such as sludge, slag, etc., generated in steel mills or thermal power plants. It can be recycled as a raw material or recycled as a raw material, and the machine spraying is possible by converting lime or siliceous powder fertilizer into granular form, which can reduce the inconvenience of blowing in the wind when spraying powder fertilizer.

Claims (6)

The first molded part made of a housing made of a circular iron pipe so that the material introduced into it by the self-rotation is formed by agglomeration of fine particles, and the core is passed through the self-rotation so that the core is subjected to friction and impact. A drum-shaped main body comprising a second molded part in the form of a circular steel pipe connected to the housing of the first molded part so as to have a round shape in the form of large and hard granules; A spiral blade portion inserted into and fixed to the inside of the second molding portion of the drum body so that the nucleus passing through the first molding portion may gradually move inside the second molding portion and be subjected to friction and impact at the same time; A coating part attached to an end of the second molding part of the drum-type body and putting dry powder to form a material having passed through the second molding part into granules of a composite component; A scraper which scrapes the cake which is tightly fixed to the inner circumference of the housing of the first molding part of the drum-shaped body and does not form a nucleus and adheres to the inner wall of the first molding part; Drum-type granulator manufacturing apparatus comprising a drive unit which is in close contact with the outer periphery of the housing constituting the drum-like body to rotate the first molding unit and the second molding unit at the same time. The method of claim 1, Drum-type granule manufacturing apparatus, characterized in that the third molded part of the circular steel pipe form further attached between the first molding portion and the second molding portion to form a large granule by the second injection of the material. The method of claim 1, Drum-type granule manufacturing apparatus, characterized in that the first molded part is a straight form. The method of claim 1, Drum-type granule manufacturing apparatus, characterized in that the first molded part is in the form of a tapered cone. The method of claim 1, Drum-type granules manufacturing apparatus characterized in that the height of the spiral wing portion is 150mm-200mm. The method of claim 1, Drum type granules manufacturing apparatus characterized in that the height of the spiral pitch is 250mm-400mm.